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<div class="figure">
[[File:zero2w-img3.png|800px]]
</div>
<div class="figure">
[[File:zero2w-img4.png|800px]]
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<div class="figure">
[[File:zero2w-img5.png|800px]]
</div>
<span id="orange-pi-zero-2w-24pin-expansion-board-interface-details"></span>
== Orange Pi Zero 2w 24pin expansion board interface details ==
<div class="figure">
[[File:zero2w-img6.png|800px]]
</div>
[[File:zero2w-img7.png|800px]]
{| class="wikitable" style="background-color:#ffffdc;width:800px;"
|}
</li>
<li><p>After opening gparted, you can select the TF card in the upper > right corner, and then you can see the usage of the TF card > capacity.</p>
<p>[[File:zero2w-img86.png]]</p></li>
<li><p>The picture above shows the situation of the TF card after > burning the Linux desktop system. It can be seen that although > the total capacity of the TF card is 16GB (displayed as > 14.84GiB in GParted), the rootfs partition (/dev/ sdc1) Only > 4.05GiB is actually allocated, leaving 10.79GiB unallocated</p></li></ol>
</li>
<li><p>Then you can insert the TF card with the Linux system burned into the development board to start. When the TF card starts the Linux system for the first time, it will automatically call the '''orangepi-resize-filesystem''' script through the '''orangepi-resize-filesystem.service''' systemd service. Expansion of rootfs partition, '''<span style="color:#FF0000">so there is no need to manually expand it</span>'''</p></li>
<ol style="list-style-type: decimal;">
<li><p>First, burn the Linux image of the development board into the TF card on the '''<span style="color:#FF0000">Ubuntu computer</span>''' (Windows is not available), and '''<span style="color:#FF0000">then unplug and insert the TF card again</span>'''.</p></li>
<li><p>Then the Ubuntu computer will usually automatically mount the partition of the TF card. If the automatic mounting is normal, use the ls command to see the following output.</p>
{| class="wikitable" style="width:800px;"
|-
|
<p>test@test:~$ '''ls /media/test/opi_root/'''</p>
<p>bin boot dev etc home lib lost+found media mnt opt proc root run <br> sbin selinux srv sys tmp usr var</p>|}</li>
<li><p>Then switch the current user to the root user on the Ubuntu computer</p>
{| class="wikitable" style="width:800px;"
|-
|
<p>test@test:~$ '''sudo -i'''</p>
<p>[sudo] test 的密码: 的密码:</p><p>root@test:~'''<span style="color:#FF0000">#</span>'''</p>|}</li>
<li><p>Then enter the root directory of the Linux system in the TF card and create a new file named '''.no_rootfs_resize'''</p>
{| class="wikitable" style="width:800px;"
|-
|
<p>root@test:~# '''cd /media/test/opi_root/'''</p>
<p>root@test:/media/test/opi_root/# '''cd root'''</p>
<p>root@test:/media/test/opi_root/root# '''touch .no_rootfs_resize'''</p>
<p>root@test:/media/test/opi_root/root# '''ls .no_rootfs*'''</p>
<p>'''.no_rootfs_resize'''</p>|}</li>
<li><p>Then you can uninstall the TF card, then pull out the TF card and insert it into the development board to start. When the Linux system starts, when the '''.no_rootfs_resize''' file is detected in the '''/root''' directory, rootfs will not be automatically expanded.</p></li>
<li><p>After disabling the automatic expansion of rootfs, you can enter the Linux system and you can see that the total capacity of the rootfs partition is only 4GB (the image tested here is the desktop version), which is much smaller than the actual capacity of the TF card, indicating that the automatic expansion of rootfs has been successfully disabled.</p>
{| class="wikitable" style="width:800px;"
|-
|
<p>orangepi@orangepi:~$ '''df -h'''</p>
<pspan style="margin-right: 80px;">Filesystem </span><span style="margin-right: 50px;">Size </span><span style="margin-right: 30px;">Used </span><span style="margin-right: 30px;">Avail </span><span style="margin-right: 50px;">Use% Mounted on</pspan><br><pspan style="margin-right: 110px;">udev </span><span style="margin-right: 60px;">925M </span><span style="margin-right: 50px;">0 </span><span style="margin-right: 70px;">925M </span><span style="margin-right: 90px;">0% /dev</pspan><br><pspan style="margin-right: 100px;">tmpfs </span><span style="margin-right: 50px;">199M </span><span style="margin-right: 30px;">3.2M </span><span style="margin-right: 70px;">196M </span><span style="margin-right: 90px;">2% /run</pspan><br><pspan style="margin-right: 25px;color:#FF0000">'''/dev/mmcblk0p1 '''</span><span style="margin-right: 50px;color:#FF0000">'''4.0G '''</span><span style="margin-right: 35px;color:#FF0000">'''3.2G '''</span><span style="margin-right: 80px;color:#FF0000">'''686M '''</span><span style="margin-right: 90px;color:#FF0000">'''83% /'''</pspan><br>|}</li><li><p>If you need to re-expand the capacity of the rootfs partition in the TF card, just execute the following command and then restart the Linux system of the development board.</p>{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| </li></olbig> '''Note, please execute the following command under the root user.'''</big>|}{| class="wikitable" style="width:800px;" |-|
root@orangepi:~# '''rm /root/.no_rootfs_resize'''
root@orangepi:~# '''sudo reboot'''
|}
After restarting, enter the Linux system of the development board again and you will see that the rootfs partition has been expanded to the actual capacity of the TF card.
{| class="wikitable" style="width:800px;"|-|<p>root@orangepi:~# $ '''df -h'''</p> <span style="margin-right: 80px;">Filesystem </span><span style="margin-right: 50px;">Size </span><span style="margin-right: 30px;">Used </span><span style="margin-right: 30px;">Avail </span><span style="margin-right: 50px;">Use% Mounted on</span><br> <span style="margin-right: 110px;">udev </span><span style="margin-right: 60px;">925M </span><span style="margin-right: 50px;">0 </span><span style="margin-right: 70px;">925M </span><span style="margin-right: 90px;">0% /dev</span><br><span style="margin-right: 100px;">tmpfs </span><span style="margin-right: 50px;">199M </span><span style="margin-right: 30px;">3.2M </span><span style="margin-right: 70px;">196M </span><span style="margin-right: 90px;">2% /run</span><br><span style="margin-right: 25px;color:#FF0000">'''/dev/mmcblk0p1'''</span><span style="margin-right: 50px;color:#FF0000">'''15G'''</span><span style="margin-right: 35px;color:#FF0000">'''3.2G '''</span><span style="margin-right: 80px;color:#FF0000">'''12G '''</span><span style="margin-right: 90px;color:#FF0000">'''23% /'''</span><br>|}</li></ol><span id="method-to-manually-expand-the-capacity-of-rootfs-partition-in-tf-card"></span>
=== Method to manually expand the capacity of rootfs partition in TF card ===
{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <big>'''If the total capacity of the TF card is large, such as 128GB, and you do not want the rootfs partition of the Linux system to use all the capacity of the TF card, you only want to allocate a part of the capacity, such as 16GB, to the Linux system, and then the remaining capacity of the TF card can be used for other purposes. use. Then you can use the content introduced in this section to manually expand the capacity of the rootfs partition in TF.'''</big>|}
<ol style="list-style-type: decimal;">
<li><p>First, burn the Linux image of the development board into the TF card on the '''<span style="color:#FF0000">Ubuntu computer</span>''' (Windows is not available), and '''<span style="color:#FF0000">then unplug and insert the TF card again</span>'''.</p></li>
<li><p>Then the Ubuntu computer will usually automatically mount the partition of the TF card. If the automatic mounting is normal, use the ls command to see the following output.</p>
{| class="wikitable" style="width:800px;"
|-
|
<p>test@test:~$ '''ls /media/test/opi_root/'''</p>
<p>bin boot dev etc home lib lost+found media mnt opt proc root run <br> sbin selinux srv sys tmp usr var</p>|}</li>
<li><p>Then switch the current user to the root user on the Ubuntu computer</p>
{| class="wikitable" style="width:800px;"
|-
|
<p>test@test:~$ '''sudo -i'''</p>
<p>[sudo] test 的密码: 的密码:</p><p>root@test:~'''<span style="color:#FF0000">#</span>'''</p>|}</li>
<li><p>Then enter the root directory of the Linux system in the TF card and create a new file named '''.no_rootfs_resize'''</p>
{| class="wikitable" style="width:800px;" |-| <p>root@test:~# '''cd /media/test/opi_root/'''</p>
<p>root@test:/media/test/opi_root/# '''cd root'''</p>
<p>root@test:/media/test/opi_root/root# '''touch .no_rootfs_resize'''</p>
<p>root@test:/media/test/opi_root/root# '''ls .no_rootfs*'''</p>
<p>'''.no_rootfs_resize'''</p>|}</li></ol>
<ol start="5" style="list-style-type: decimal;">
<li><p>Then install the gparted software on your Ubuntu computer</p>
{| class="wikitable" style="width:800px;" |-| <p>test@test:~$ '''sudo apt install -y gparted'''</p>|}</li>
<li><p>Then open gparted</p>
{| class="wikitable" style="width:800px;" |-| <p>test@test:~$ '''sudo gparted'''</p>|}</li>
<li><p>After opening gparted, you can select the TF card in the upper right corner, and then you can see the usage of the TF card capacity. The picture below shows the situation of the TF card after burning the Linux desktop system. It can be seen that although the total capacity of the TF card is 16GB (displayed as 14.84GiB in GParted), the rootfs partition (/dev/sdc1) Only 4.05GiB is actually allocated, leaving 10.79GiB unallocated</p>
<p>[[File:zero2w-img86.png]]</p></li>
<li><p>After setting the capacity, click '''Resize/Move''' in the lower right corner.</p>
<p>[[File:zero2w-img93.png]]</p></li>
<li><p>After final confirmation, click the green '''<span style="color:green">√</span>''' shown in the picture below.</p>
<p>[[File:zero2w-img94.png]]</p></li>
<li><p>Then select '''Apply''', and the capacity expansion of the rootfs partition will officially begin.</p>
<p>[[File:zero2w-img96.png]]</p></li>
<li><p>Then you can unplug the TF card and insert it into the development board to start. After entering the Linux system of the development board, if you use the '''df -h''' command to see that the size of the rootfs partition is consistent with the size set previously, it means manual Expansion successful</p>
{| class="wikitable" style="width:800px;"
|-
|
<p>root@orangepi:~# '''df -h'''</p>
<pspan style="margin-right: 80px;">Filesystem </span><span style="margin-right: 50px;">Size </span><span style="margin-right: 30px;">Used </span><span style="margin-right: 30px;">Avail </span><span style="margin-right: 50px;">Use% Mounted on</pspan><br><pspan style="margin-right: 110px;">udev </span><span style="margin-right: 60px;">925M </span><span style="margin-right: 50px;">0 </span><span style="margin-right: 70px;">925M </span><span style="margin-right: 90px;">0% /dev</pspan><br><pspan style="margin-right: 100px;">tmpfs </span><span style="margin-right: 50px;">199M </span><span style="margin-right: 30px;">3.2M </span><span style="margin-right: 70px;">196M </span><span style="margin-right: 90px;">2% /run</pspan><br><pspan style="margin-right: 25px;color:#FF0000">'''/dev/mmcblk0p1 '''</span><span style="margin-right: 50px;color:#FF0000">'''7.7G '''</span><span style="margin-right: 35px;color:#FF0000">'''3.2G '''</span><span style="margin-right: 80px;color:#FF0000">'''4.4G '''</span><span style="margin-right: 90px;color:#FF0000">'''42% /'''</pspan><br>|}</li></ol>
<span id="method-to-reduce-the-capacity-of-rootfs-partition-in-tf-card"></span>
=== Method to reduce the capacity of rootfs partition in TF card ===
{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <big>'''After configuring the application or other development environment in the Linux system of the TF card, if you want to back up the Linux system in the TF card, you can use the method in this section to reduce the size of the rootfs partition first, and then start the backup.'''</big>|}
<ol style="list-style-type: decimal;">
<li><p>First, insert the TF card you want to operate on your '''<span style="color:#FF0000">Ubuntu computer</span>''' (not Windows)</p></li>
<li><p>Then install the gparted software on your Ubuntu computer</p>
{| class="wikitable" style="width:800px;" |-| <p>test@test:~$ '''sudo apt install -y gparted'''</p>|}</li>
<li><p>Then open gparted</p>
{| class="wikitable" style="width:800px;" |-| <p>test@test:~$ '''sudo gparted'''</p>|}</li>
<li><p>After opening gparted, you can select the TF card in the upper right corner, and then you can see the usage of the TF card capacity.</p>
<p>[[File:zero2w-img97.png]]</p></li>
<li><p>After setting the capacity, click '''Resize/Move''' in the lower right corner.</p>
<p>[[File:zero2w-img93.png]]</p></li>
<li><p>After final confirmation, click the green '''<span style="color:green">√</span>''' as shown in the picture below.</p>
<p>[[File:zero2w-img94.png]]</p></li>
<li><p>Then select '''Apply''', and the capacity expansion of the rootfs partition will officially begin.</p>
<p>[[File:zero2w-img96.png]]</p></li>
<li><p>Then you can unplug the TF card and insert it into the development board to start. After entering the Linux system of the development board, if you use the '''df -h''' command, you can see that the size of the rootfs partition is consistent with the size set previously, which means it has been reduced capacity success</p>
{| class="wikitable" style="width:800px;"
|-
|
<p>root@orangepi:~# '''df -h'''</p>
<pspan style="margin-right: 80px;">Filesystem </span><span style="margin-right: 50px;">Size </span><span style="margin-right: 30px;">Used </span><span style="margin-right: 30px;">Avail </span><span style="margin-right: 50px;">Use% Mounted on</pspan><br><pspan style="margin-right: 110px;">udev </span><span style="margin-right: 60px;">925M </span><span style="margin-right: 50px;">0 </span><span style="margin-right: 70px;">925M </span><span style="margin-right: 90px;">0% /dev</pspan><br><pspan style="margin-right: 100px;">tmpfs </span><span style="margin-right: 50px;">199M </span><span style="margin-right: 30px;">3.2M </span><span style="margin-right: 70px;">196M </span><span style="margin-right: 90px;">2% /run</pspan><br><pspan style="margin-right: 25px;color:#FF0000">'''/dev/mmcblk0p1 '''</span><span style="margin-right: 50px;color:#FF0000">'''7.7G '''</span><span style="margin-right: 35px;color:#FF0000">'''3.2G '''</span><span style="margin-right: 80px;color:#FF0000">'''4.4G '''</span><span style="margin-right: 90px;color:#FF0000">'''42% /'''</pspan><br>|}</li></ol>
<span id="pin-expansion-board-interface-pin-description"></span>
== 24Pin expansion board interface pin description ==
[[File:zero2w-img105.png]]
</div></li></ol>
{| class="wikitable" style="width:800px;text-align: center;"
|-
| style="width:50px;" | 1| style="width:200px;" | 100M network port
| Used to connect to a wired network to access the Internet
|-
| The default settings of the Linux system are KEY_1 (Number 1 key) and KEY_ENTER (Enter key), which can be customized as other function keys by modifying the dts configuration.
|}
</ol>
<ol start="5" style="list-style-type: decimal;">
<li>The adaptation of Linux5.4 and Linux6.1 systems to expansion boards is shown in the following table</li></ol>
{| class="wikitable" style="width:800px;text-align: center;"
|-
| '''24pin expansion board function'''
|-
| '''TV-OUT'''
| '''<span style="color:#FF0000">NO</span>'''| '''<span style="color:#FF0000">NO</span>'''
|}
</ol>
<span id="how-to-use-the-two-lradc-buttons-on-the-24pin-expansion-board"></span>
== How to use the two LRADC buttons on the 24pin expansion board ==
<li><p>There are two LRADC buttons on the 24pin expansion board, and their locations are as shown in the figure below:</p>
<p>[[File:zero2w-img106.png]]</p></li>
<li><p>In the Linux system, the default key values of KEY1 and KEY2 are</p></li></ol>
{| class="wikitable" style="width:800px;text-align: center;"
|-
| '''Linux kernel'''
| '''KEY_ENTER, the enter key'''
|}
</ol>
<ol start="3" style="list-style-type: decimal;">
<li><p>Through the '''evtest''' command, we can check the key values reported after KEY1 and KEY2 are pressed.</p>
<ol style="list-style-type: lower-alpha;">
<li><p>linux5.4</p>
{| class="wikitable" style="width:800px;"
|-
|
<p>orangepi@orangepizero2w:~$ '''evtest'''</p>
<p>No device specified, trying to scan all of /dev/input/event*</p>
<p>Not running as root, no devices may be available.</p>
<p>Available devices:</p>
<p>'''/dev/input/event0event<span style="color: #FF0000">0</span>: <span style="color:#FF0000">sunxi-keyboard</span>'''</p>
<p>/dev/input/event1: sunxi-ir</p>
<p>/dev/input/event2: axp2101-pek</p>
<p>/dev/input/event6: PixArt USB Optical Mouse</p>
<p>/dev/input/event7: BRLTTY 6.3 Linux Screen Driver Keyboard</p>
<p>Select the device event number [0-7]: '''<span style="color:#FF0000">0 </span> #You need to enter the serial number corresponding to sunxi-keyboard'''</p>
<p>Input driver version is 1.0.1</p>
<p>Input device ID: bus 0x19 vendor 0x1 product 0x1 version 0x100</p>
<p>Input device name: "sunxi-keyboard"</p>
<p>Supported events:</p>
:<p>Event type 0 (EV_SYN)</p>:<p>Event type 1 (EV_KEY)</p>::<p>Event code 2 (KEY_1)</p>::<p>Event code 28 (KEY_ENTER)</p>
<p>Properties:</p>
<p>Testing ... (interrupt to exit)</p>
<p>'''#The following are the key values reported after pressing KEY1 and KEY2'''</p>
<p>Event: time 1693555298.132314, type 1 (EV_KEY), code 2 (KEY_1), value 1</p>
<p>Event: time 1693555298.132314, -------------- SYN_REPORT ------------</p>
<p>Event: time 1693555298.601042, -------------- SYN_REPORT ------------</p>
<p>Event: time 1693555298.710415, type 1 (EV_KEY), code 28 (KEY_ENTER), value 0</p>
<p>Event: time 1693555298.710415, -------------- SYN_REPORT ------------</p>|}</li>
<li><p>linux6.1</p>
{| class="wikitable" style="width:800px;"
|-
|
<p>orangepi@orangepizero2w:~$ evtest</p>
<p>No device specified, trying to scan all of /dev/input/event*</p>
<p>Available devices:</p>
<p>/dev/input/event0: axp20x-pek</p>
<p>'''/dev/input/event1event<span style="color: #FF0000">1</span>: <span style="color:#FF0000">5070800.lradc</span>'''</p>
<p>/dev/input/event2: SONiX USB Keyboard</p>
<p>/dev/input/event3: SONiX USB Keyboard Consumer Control</p>
<p>/dev/input/event5: PixArt USB Optical Mouse</p>
<p>/dev/input/event6: sunxi-ir</p>
<p>Select the device event number [0-6]: '''<span style="color:#FF0000">1 </span> #You need to enter the serial number corresponding to 5070800.lradc'''</p>
<p>Input driver version is 1.0.1</p>
<p>Input device ID: bus 0x19 vendor 0x1 product 0x1 version 0x100</p>
<p>Input device name: "5070800.lradc"</p>
<p>Supported events:</p>
:<p>Event type 0 (EV_SYN)</p>:<p>Event type 1 (EV_KEY)</p>::<p>Event code 2 (KEY_1)</p>::<p>Event code 28 (KEY_ENTER)</p>
<p>Properties:</p>
<p>Testing ... (interrupt to exit)</p>
<p>'''#The following are the key values reported after pressing KEY1 and KEY2'''</p>
<p>Event: time 1694075818.810877, type 1 (EV_KEY), code 2 (KEY_1), value 1</p>
<p>Event: time 1694075818.810877, -------------- SYN_REPORT ------------</p>
<p>Event: time 1694075819.536128, -------------- SYN_REPORT ------------</p>
<p>Event: time 1694075819.705009, type 1 (EV_KEY), code 28 (KEY_ENTER), value 0</p>
<p>Event: time 1694075819.705009, -------------- SYN_REPORT ------------</p>|}</li></ol>
</li>
<li><p>If you need to modify the key values reported after KEY1 and KEY2 are pressed, you can use the following method:</p>
<ol style="list-style-type: lower-alpha;">
<li><p>There is a '''sun50i-h618-lradc-keys.dts''' file under the > '''/usr/src/''' path, through which we can define KEY1 and KEY2 > as the desired key values.</p>{| class="wikitable" style="width:800px;" |-|
<p>orangepi@orangepizero2w:~$ '''cd /usr/src/'''</p>
<p>orangepi@orangepizero2w:/usr/src$ '''ls *.dts'''</p>
<p>sun50i-h618-lradc-keys.dts</p>|}</li><li><p>The contents of the '''sun50i-h618-lradc-keys.dts''' file in the > linux5.4 system are as follows:</p><ol style="list-style-type: lower-alphanone;"><li><p>a) KEY1 correspondence: modify '''key0 = <600 2>;''' where 2 is > the number corresponding to the desired key value</p></li><li><p>b) KEY2 correspondence: modify '''key1 = <800 28>;''' where 28 > is the number corresponding to the desired key value</p>{| class="wikitable" style="width:800px;" |-|
<p>orangepi@orangepizero2w:/usr/src$ '''sudo vim sun50i-h618-lradc-keys.dts'''</p>
<p>/dts-v1/;</p>
<p>/plugin/;</p>
<p>/ {</p>
:<p>fragment@0 {</p>::<p>target = <&keyboard>;</p> ::<p>__overlay__ {</p>:::<p>status = "okay";</p> :::<p>'''key0 = <600 <span style="color:#FF0000">2</span>>;'''</p>:::<p>'''key1 = <800 <span style="color:#FF0000">28</span>>;'''</p>::<p>};</p>:<p>};</p>
<p>};</p>
</li>
<li><p>The contents of the c.linux6.1 system > '''sun50i-h618-lradc-keys.dts''' file are as follows:</p><ol style="list-style-type: lower-alphanone;"><li><p>a) KEY1 corresponding: modify '''linux,code = <2>;''' the 2 in > it is the number corresponding to the desired key value</p></li><li><p>b) KEY2 correspondence: modify '''linux,code = <28>;''' the 28 > in it is the number corresponding to the desired key value</p>{| class="wikitable" style="width:800px;" |-| <p>orangepi@orangepizero2w:/usr/src$ '''sudo ''' '''vim ''' '''sun50i-h618-lradc-keys.dts'''</p>
<p>/dts-v1/;</p>
<p>/plugin/;</p>
<p>/ {</p>
:<p>fragment@0 {</p>::<p>target = <&r_lradc>;</p> ::<p>__overlay__ {</p>:::<p>status = "okay";</p> :::<p>button-500 {</p>::::<p>label = "KEY_1";</p>::::<p>'''linux,code = <<span style="color:#FF0000">2</span>>;'''</p>:::<p>};</p> :::<p>button-800 {</p>::::<p>label = "KEY_ENTER";</p>::::<p>'''linux,code = <<span style="color:#FF0000">28</span>>;'''</p>:::<p>};</p>::<p>};</p>:<p>};</p>
<p>};</p>
</li>
<li><p>For the key values that can be set, please refer to the macro > definition in the '''input-event-codes.h''' header file. Its > path in the kernel source code is:</p>{| class="wikitable" style="width:800px;" |-|
<p>orange-pi-5.4-sun50iw9/include/uapi/linux/input-event-codes.h</p>
<p>orange-pi-6.1-sun50iw9/include/uapi/linux/input-event-codes.h</p>|}</li><li><p>After modification, use the '''orangepi-add-overlay''' command to > add the sun50i-h618-lradc-keys.dts configuration to the > system.</p>{| class="wikitable" style="width:800px;" |-|
<p>orangepi@orangepizero2w:/usr/src$ '''sudo orangepi-add-overlay sun50i-h618-lradc-keys.dts'''</p>
<p>Compiling the overlay</p>
<p>Copying the compiled overlay file to /boot/overlay-user/</p>
<p>Reboot is required to apply the changes</p>|}</li><li><p>Then restart the system and the customized key values will take > effect.</p></li></ol>
</li></ol>
<span id="network-connection-test"></span>
== Network connection test ==
<p>[[File:zero2w-img107.png]]</p></li>
<li><p>Then plug one end of the network cable into the Ethernet interface of the expansion board, and the other end of the network cable into the router, and make sure the network is smooth.</p></li>
<li><p>After the system starts, it will automatically assign an IP address to the Ethernet card through '''DHCP''', '''<span style="color:#FF0000">and no other configuration is required.</span>'''</p></li>
<li><p>The command to view the IP address in the Linux system of the development board is as follows:</p>
{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <big><p>'''Please do not copy the following commands. For example, the network node name in debian12 is end0, and the following command needs to be modified to ip a s end0.'''</p></big>|}{| class="wikitable" style="width:800px;" |-| <p>orangepi@orangepi:~$ '''ip a s eth0'''</p>
<p>3: eth0: <BROADCAST,MULTICAST,UP,LOWER_UP> mtu 1500 qdisc pfifo_fast state UP group default qlen 1000</p>
:<p>link/ether 5e:ac:14:a5:93:b3 brd ff:ff:ff:ff:ff:ff</p>:<p>inet '''<span style="color:#FF0000">192.168.1.16</span>'''/24 brd 192.168.1.255 scope global dynamic noprefixroute eth0</p>::<p>valid_lft 259174sec preferred_lft 259174sec</p>:<p>inet6 240e:3b7:3240:c3a0:e269:8305:dc08:135e/64 scope global dynamic noprefixroute</p>::<p>valid_lft 259176sec preferred_lft 172776sec</p>:<p>inet6 fe80::957d:bbbd:4928:3604/64 scope link noprefixroute</p>::<p>valid_lft forever preferred_lft forever</p>|}{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <big><p>'''There are three ways to check the IP address after the development board is started:'''</p>
<p>'''1. Connect the HDMI display, then log in to the system and use the ip a s eth0 command to check the IP address.'''</p>
<p>'''2. Enter the ip a s eth0 command in the debugging serial terminal to view the IP address.'''</p>
<p>'''3. If there is no debugging serial port or HDMI display, you can also check the IP address of the development board's network port through the router's management interface. However, with this method, people often fail to see the IP address of the development board. If you can't see it, here's how to debug it:'''</p>
:<p>'''A) First check whether the Linux system has started normally. If the green light of the development board flashes, it usually means that it has started normally. If only the red light is on, or the red and green lights are not on, it means that the system has not started normally;'''</p>:<p>'''B) Check whether the network cable is plugged in tightly, or try another network cable;'''</p>:<p>'''C) Try another router (I have encountered many problems with routers, such as the router being unable to assign an IP address normally, or the IP address being assigned normally but not being visible in the router);'''</p>:<p>'''D) If there is no router to replace, you can only connect an HDMI display or use the debugging serial port to check the IP address.'''</p> <p>'''In addition, it should be noted that the development board's DHCP automatic allocation of IP addresses does not require any settings.'''</p></big>|}</li>
<li><p>The command to test network connectivity is as follows. The '''ping''' command can be interrupted by pressing the '''Ctrl+C''' shortcut key.</p>
{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <big><p>'''Please do not copy the following commands. For example, the network node name in debian12 is end0. The following command needs to be modified to ping www.baidu.com -I end0.'''</p></big>|}{| class="wikitable" style="width:800px;" |-|
<p>orangepi@orangepi:~$ '''ping www.baidu.com -I eth0'''</p>
<p>PING www.a.shifen.com (14.215.177.38) from 192.168.1.12 eth0: 56(84) bytes of data.</p>
<p>--- www.a.shifen.com ping statistics ---</p>
<p>4 packets transmitted, 4 received, 0% packet loss, time 3002ms</p>
<p>rtt min/avg/max/mdev = 6.260/6.770/7.275/0.373 ms</p>|}</li></ol>
<span id="wifi-connection-test"></span>
=== WIFI connection test ===
{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <big>'''Please do not connect to WIFI by modifying the /etc/network/interfaces configuration file. There will be problems in connecting to the WIFI network in this way.'''</big>|}
<span id="server-version-image-connects-to-wifi-through-commands"></span>
==== Server version image connects to WIFI through commands ====
{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <big>'''When the development board is not connected to Ethernet or HDMI display, but only to the serial port, it is recommended to use the commands demonstrated in this section to connect to the WIFI network. Because nmtui can only display characters in some serial port software (such as minicom) and cannot display the graphical interface normally. Of course, if the development board is connected to an Ethernet or HDMI display, you can also use the commands demonstrated in this section to connect to the WIFI network.'''</big>|}
<ol style="list-style-type: decimal;">
<li><p>First log in to the Linux system, there are three ways:</p>
<p>a. If the development board is connected to a network cable, you can remotely log in to '''[[\lOrange Pi Zero 2W#SSH remote login development board|the Linux system through ssh]].'''</p>
<p>b. If the development board is connected to the debugging serial port, you can use the serial port terminal to log in to the Linux system.</p>
<p>c. If the development board is connected to an HDMI display, you can log in to the Linux system through the HDMI display terminal.</p></li></ol>
<li><p>First use the '''nmcli dev wifi''' command to scan the surrounding WIFI hotspots</p>
{| class="wikitable" style="width:800px;"
|-
|
<p>orangepi@orangepi:~$ '''nmcli dev wifi'''</p>
|}
<div class="figure">
<li><p>Then use the '''nmcli''' command to connect to the scanned WIFI hotspot, where:</p>
<ol style="list-style-type: lower-alpha;">
<li><p>'''wifi_name''' needs to be replaced with the name of the WIFI > hotspot you want to connect to</p></li><li><p>'''wifi_passwd''' needs to be replaced with the password of the > WIFI hotspot you want to connect to.</p>{| class="wikitable" style="width:800px;" |-| <p>orangepi@orangepi:~$ '''sudo nmcli dev wifi connect <span style="color:#FF0000">wifi_name </span> password <span style="color:#FF0000">wifi_passwd</span>'''</p><p>Device 'wlan0' successfully activated with 'cf937f88-ca1e-4411-bb50-61f402eef293'.</p>|}</li></ol>
</li>
<li><p>You can check the IP address of the wifi through the '''ip addr show wlan0''' command</p>
{| class="wikitable" style="width:800px;"
|-
|
<p>orangepi@orangepi:~$ '''ip a s wlan0'''</p>
<p>11: wlan0: <BROADCAST,MULTICAST,UP,LOWER_UP> mtu 1500 qdisc pfifo_fast state UP group default qlen 1000</p>
:<p>link/ether 23:8c:d6:ae:76:bb brd ff:ff:ff:ff:ff:ff</p>:<p>inet '''<span style="color:#FF0000">192.168.1.11</span>'''/24 brd 192.168.1.255 scope global dynamic noprefixroute wlan0</p>::<p>valid_lft 259192sec preferred_lft 259192sec</p>:<p>inet6 240e:3b7:3240:c3a0:c401:a445:5002:ccdd/64 scope global dynamic noprefixroute</p>::<p>valid_lft 259192sec preferred_lft 172792sec</p>:<p>inet6 fe80::42f1:6019:a80e:4c31/64 scope link noprefixroute</p>::<p>valid_lft forever preferred_lft forever</p>|}</li>
<li><p>Use the '''ping''' command to test the connectivity of the wifi network. The '''ping''' command can be interrupted by pressing the '''Ctrl+C''' shortcut key.</p>
{| class="wikitable" style="width:800px;"
|-
|
<p>orangepi@orangepi:~$ '''ping www.orangepi.org -I wlan0'''</p>
<p>PING www.orangepi.org (182.92.236.130) from 192.168.1.49 wlan0: 56(84) bytes of data.</p>
<p>--- www.orangepi.org ping statistics ---</p>
<p>5 packets transmitted, 5 received, 0% packet loss, time 4006ms</p>
<p>rtt min/avg/max/mdev = 41.321/44.864/48.834/2.484 ms</p>|}</li></ol>
<span id="server-version-image-connects-to-wifi-graphically"></span>
==== Server version image connects to WIFI graphically ====
<ol style="list-style-type: decimal;">
<li><p>First log in to the Linux system, there are three ways:</p>
<p>a. If the development board is connected to a network cable, you can remotely log in to '''[[\lOrange Pi Zero 2W#SSH remote login development board|the Linux system through ssh]].'''</p>
<p>b. If the development board is connected to the debugging serial port, you can use the serial port terminal to log in to the Linux system (please use MobaXterm for the serial port software, the graphical interface cannot be displayed using minicom)</p>
<p>c. If the development board is connected to an HDMI display, you can log in to the Linux system through the HDMI display terminal.</p></li>
<li><p>Then enter the nmtui command in the command line to open the wifi connection interface</p>
{| class="wikitable" style="width:800px;" |-| <p>orangepi@orangepi:~$ '''sudo nmtui'''</p>|}</li>
<li><p>Enter the nmtui command to open the interface as shown below</p>
<p>[[File:zero2w-img109.png]]</p></li>
</div></li>
<li><p>You can check the IP address of the wifi through the '''ip a s wlan0''' command</p>
{| class="wikitable" style="width:800px;"
|-
|
<p>orangepi@orangepi:~$ '''ip a s wlan0'''</p>
<p>11: wlan0: <BROADCAST,MULTICAST,UP,LOWER_UP> mtu 1500 qdisc pfifo_fast state UP group default qlen 1000</p>
:<p>link/ether 24:8c:d3:aa:76:bb brd ff:ff:ff:ff:ff:ff</p>:<p>inet '''<span style="color:#FF0000">192.168.1.11</span>'''/24 brd 192.168.1.255 scope global dynamic noprefixroute wlan0</p>::<p>valid_lft 259069sec preferred_lft 259069sec</p>:<p>inet6 240e:3b7:3240:c4a0:c401:a445:5002:ccdd/64 scope global dynamic noprefixroute</p>::<p>valid_lft 259071sec preferred_lft 172671sec</p>:<p>inet6 fe80::42f1:6019:a80e:4c31/64 scope link noprefixroute</p>::<p>valid_lft forever preferred_lft forever</p>|}</li>
<li><p>Use the '''ping''' command to test the connectivity of the wifi network. The '''ping''' command can be interrupted by pressing the '''Ctrl+C''' shortcut key.</p>
{| class="wikitable" style="width:800px;"
|-
|
<p>orangepi@orangepi:~$ '''ping www.orangepi.org -I wlan0'''</p>
<p>PING www.orangepi.org (182.92.236.130) from 192.168.1.49 wlan0: 56(84) bytes of data.</p>
<p>--- www.orangepi.org ping statistics ---</p>
<p>5 packets transmitted, 5 received, 0% packet loss, time 4006ms</p>
<p>rtt min/avg/max/mdev = 41.321/44.864/48.834/2.484 ms</p>|}</li></ol>
<span id="test-method-for-desktop-image"></span>
==== Test method for desktop image ====
<span id="method-to-create-wifi-hotspot-through-create_ap"></span>
=== Method to create WIFI hotspot through create_ap ===
{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <big>'''create_ap is a script that helps quickly create WIFI hotspots on Linux, and supports bridge and NAT modes. It can automatically combine hostapd, dnsmasq and iptables to complete the setting of WIFI hotspots, avoiding users from complicated configurations. The github address is as follows: '''
[https://github.com/oblique/create_ap '''https://github.com/oblique/create_ap''']</big>|}{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <big>'''The Linux image released by OPi has been pre-installed with the create_ap script. You can use the create_ap command to create a WIFI hotspot. The basic command format of create_ap is as follows: '''
'''create_ap [options] <wifi-interface> [<interface-with-internet>] [<access-point-name> [<passphrase>]]'''
'''* options: You can use this parameter to specify the encryption method, frequency band of WIFI hotspot, bandwidth mode, network sharing method, etc. You can get the options through create_ap -h.'''
'''* access-point-name: Hotspot name'''
'''* passphrase: hotspot password'''</big>|}
<span id="create_ap-method-to-create-wifi-hotspot-in-nat-mode"></span>
<ol style="list-style-type: decimal;">
<li><p>Enter the following command to create a WIFI hotspot with the name '''orangepi''' and password '''orangepi''' in NAT mode</p>
{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <big><p>'''Note that in the following command, Debian12 needs to modify eth0 to end0'''</p></li></olbig>|}{| class="wikitable" style="width:800px;" |-|
orangepi@orangepi:~$ '''sudo create_ap -m nat wlan0 eth0 orangepi orangepi --no-virt'''
|}
</li></ol>
<ol start="2" style="list-style-type: decimal;">
<li><p>If the following information is output, it means that the WIFI hotspot is successfully created.</p>
{| class="wikitable" style="width:800px;"
|-
|
<p>orangepi@orangepi:~$ '''sudo create_ap -m nat wlan0 eth0 orangepi orangepi --no-virt'''</p>
<p>Config dir: /tmp/create_ap.wlan0.conf.TQkJtsz1</p>
<p>wlan0: STA ce:bd:9a:dd:a5:86 RADIUS: starting accounting session D4FBF7E5C604F169</p>
<p>wlan0: STA ce:bd:9a:dd:a5:86 WPA: pairwise key handshake completed (RSN)</p>
<p>wlan0: EAPOL-4WAY-HS-COMPLETED ce:bd:9a:dd:a5:86</p>|}</li>
<li><p>At this time, take out your mobile phone and find the WIFI hotspot named '''orangepi''' created by the development board in the searched WIFI list. Then you can click '''orangepi''' to connect to the hotspot. The password is '''orangepi''' set above.</p>
<div class="figure">
</div></li>
<li><p>In NAT mode, the wireless device connected to the development board's hotspot requests an IP address from the development board's DHCP service, so there will be two different network segments. For example, the development board's IP here is 192.168.1.X</p>
{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <big><p>'''Note that in the following command, Debian12 needs to modify eth0 to end0.'''</p></big>|}{| class="wikitable" style="width:800px;" |-|
<p>orangepi@orangepi:~$ '''sudo ifconfig eth0'''</p>
<p>eth0: flags=4163<UP,BROADCAST,RUNNING,MULTICAST> mtu 1500</p>
::<p>inet '''<span style="color:#FF0000">192.168.1.150</span>''' netmask 255.255.255.0 broadcast 192.168.1.255</p>::<p>inet6 fe80::938f:8776:5783:afa2 prefixlen 64 scopeid 0x20<link></p>::<p>ether 4a:a0:c8:25:42:82 txqueuelen 1000 (Ethernet)</p>::<p>RX packets 25370 bytes 2709590 (2.7 MB)</p>::<p>RX errors 0 dropped 50 overruns 0 frame 0</p>::<p>TX packets 3798 bytes 1519493 (1.5 MB)</p>::<p>TX errors 0 dropped 0 overruns 0 carrier 0 collisions 0</p>::<p>device interrupt 83</p>|}
<p>The DHCP service of the development board will assign the IP address of '''192.168.12.0/24''' to the device connected to the hotspot by default. At this time, click on the connected WIFI hotspot '''orangepi''', and then you can see that the IP address of the mobile phone is '''192.168.12.X'''.</p>
<div class="figure">
</div></li>
<li><p>If you want to specify a different network segment for the connected device, you can specify it through the -g parameter. For example, use the -g parameter to specify the network segment of the access point AP as 192.168.2.1.</p>{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| </li></olbig> '''Note that in the following command, Debian12 needs to modify eth0 to end0.'''</big>|}{| class="wikitable" style="width:800px;" |-|
orangepi@orangepi:~$ '''sudo create_ap -m nat wlan0 eth0 orangepi orangepi -g 192.168.2.1 --no-virt'''
|}
At this time, after connecting to the hotspot through the mobile phone, click on the connected WIFI hotspot '''orangepi''', and then you can see that the IP address of the mobile phone is '''192.168.2.X'''
</div>
</li></ol>
<ol start="7" style="list-style-type: decimal;">
<li><p>Without specifying the '''--freq-band''' parameter, the hotspot created by default is in the 2.4G frequency band. If you want to create a hotspot in the 5G frequency band, you can specify it through the '''--freq-band 5''' parameter. The specific command is as follows</p>
{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <big><p>'''Note that in the following command, Debian12 needs to modify eth0 to end0'''</p></li></olbig>|}{| class="wikitable" style="width:800px;" |-| orangepi@orangepi:~$ '''sudo create_ap -m nat wlan0 eth0 orangepi orangepi --freq-band 5 --no-virt'''|}</li></ol>
<ol start="8" style="list-style-type: decimal;">
<li><p>If you need to hide the SSID, you can specify the '''--hidden''' parameter. The specific command is as follows</p>
{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <big><p>'''Note that in the following command, Debian12 needs to modify eth0 to end0.'''</p></li></olbig>|}{| class="wikitable" style="width:800px;" |-|
orangepi@orangepi:~$ '''sudo create_ap -m nat wlan0 eth0 orangepi orangepi --hidden --no-virt'''
|}
At this time, the mobile phone cannot search for WIFI hotspots. You need to manually specify the WIFI hotspot name and enter the password to connect to the WIFI hotspot.
</div>
</li></ol>
<span id="create_ap-method-to-create-wifi-hotspot-in-bridge-mode"></span>
==== create_ap method to create WIFI hotspot in bridge mode ====
<ol style="list-style-type: decimal;">
<li><p>Enter the following command to create a WIFI hotspot with the name '''orangepi''' and password '''orangepi''' in bridge mode</p>
{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <big><p>'''Note that in the following command, Debian12 needs to modify eth0 to end0.'''</p></li></olbig>|}{| class="wikitable" style="width:800px;" |-|
orangepi@orangepi:~$ '''sudo create_ap -m bridge wlan0 eth0 orangepi orangepi --no-virt'''
|}
</li></ol>
<ol start="2" style="list-style-type: decimal;">
<li><p>If the following information is output, it means that the WIFI hotspot is successfully created.</p>
{| class="wikitable" style="width:800px;"
|-
|
<p>orangepi@orangepi:~$ '''sudo create_ap -m bridge wlan0 eth0 orangepi orangepi --no-virt'''</p>
<p>Config dir: /tmp/create_ap.wlan0.conf.zAcFlYTx</p>
<p>wlan0: STA ce:bd:9a:dd:a5:86 RADIUS: starting accounting session 937BF40E51897A7B</p>
<p>wlan0: STA ce:bd:9a:dd:a5:86 WPA: pairwise key handshake completed (RSN)</p>
<p>wlan0: EAPOL-4WAY-HS-COMPLETED ce:bd:9a:dd:a5:86</p>|}</li>
<li><p>At this time, take out your mobile phone and find the WIFI hotspot named '''orangepi''' created by the development board in the searched WIFI list. Then you can click '''orangepi''' to connect to the hotspot. The password is '''orangepi''' set above.</p>
<div class="figure">
</div></li>
<li><p>In bridge mode, the wireless device connected to the hotspot of the development board also requests an IP address from the DHCP service of the main router (the router to which the development board is connected). For example, the IP of the development board here is '''192.168.1.X'''</p>
{| class="wikitable" style="width:800px;"
|-
|
<p>orangepi@orangepi:~$ '''sudo ifconfig eth0'''</p>
<p>eth0: flags=4163<UP,BROADCAST,RUNNING,MULTICAST> mtu 1500</p>
::<p>inet '''<span style="color:#FF0000">192.168.1.150</span>''' netmask 255.255.255.0 broadcast 192.168.1.255</p>::<p>inet6 fe80::938f:8776:5783:afa2 prefixlen 64 scopeid 0x20<link></p>::<p>ether 4a:a0:c8:25:42:82 txqueuelen 1000 (Ethernet)</p>::<p>RX packets 25370 bytes 2709590 (2.7 MB)</p>::<p>RX errors 0 dropped 50 overruns 0 frame 0</p>::<p>TX packets 3798 bytes 1519493 (1.5 MB)</p>::<p>TX errors 0 dropped 0 overruns 0 carrier 0 collisions 0</p>::<p>device interrupt 83</p>|}
<p>The IP of the device connected to the WIFI hotspot is also assigned by the main router, so the mobile phone connected to the WIFI hotspot and the development board are in the same network segment. At this time, click on the connected WIFI hotspot '''orangepi''', and then you can see the IP address of the mobile phone. Also '''192.168.1.X'''.</p>
<div class="figure">
</div></li>
<li><p>Without specifying the '''--freq-band''' parameter, the hotspot created by default is in the 2.4G frequency band. If you want to create a hotspot in the 5G frequency band, you can specify it through the '''--freq-band''' parameter. The specific command is as follows</p>
{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <big><p>'''Note that in the following command, Debian12 needs to modify eth0 to end0.'''</p></li></olbig>|}{| class="wikitable" style="width:800px;" |-|
orangepi@orangepi:~$ '''sudo create_ap -m bridge wlan0 eth0 orangepi orangepi --freq-band 5 --no-virt'''
|}
</li></ol>
<ol start="7" style="list-style-type: decimal;">
<li><p>If you need to hide the SSID, you can specify the '''--hidden''' parameter. The specific command is as follows</p>
{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <big><p>'''Note that in the following command, Debian12 needs to modify eth0 to end0.'''</p></li></olbig>|}{| class="wikitable" style="width:800px;" |-|
orangepi@orangepi:~$ '''sudo create_ap -m bridge wlan0 eth0 orangepi orangepi --hidden --no-virt'''
|}
At this time, the mobile phone cannot search for WIFI hotspots. You need to manually specify the WIFI hotspot name and enter the password to connect to the WIFI hotspot.
</div>
</li></ol>
<span id="how-to-set-a-static-ip-address"></span>
=== How to set a static IP address ===
{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <big>'''Please do not set a static IP address by modifying the /etc/network/interfaces configuration file.'''</big>|}
<span id="use-the-nmtui-command-to-set-a-static-ip-address"></span>
==== Use the nmtui command to set a static IP address ====
<ol style="list-style-type: decimal;">
<li><p>First run the '''nmtui''' command</p>
{| class="wikitable" style="width:800px;" |-| <p>orangepi@orangepi:~$ '''sudo nmtui'''</p>|}</li>
<li><p>Then select '''Edit a connection''' and press the Enter key</p>
<p>[[File:zero2w-img124.png]]</p></li>
<li><p>Then press Enter. After pressing Enter, the following setting interface will pop up.</p>
<p>[[File:zero2w-img131.png]]</p></li>
<li><p>Then you can set the IP address (Addresses), gateway (Gateway) and DNS server address as shown in the figure below (there are many other setting options, please explore by yourself), <span style="color:#FF0000">please set according to your specific needs. The values set in the image below are just an example</span></p>
<p>[[File:zero2w-img132.png]]</p></li>
<li><p>After setting, move the cursor to '''<OK>''' in the lower right corner, and then press Enter to confirm.</p>
<p>[[File:zero2w-img138.png]] [[File:zero2w-img139.png]]</p></li>
<li><p>Then through '''ip a s eth0''' you can see that the IP address of the network port has become the static IP address set previously.</p>
{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <big><p>'''Note that in the following command, Debian12 needs to modify eth0 to end0.'''</p></big>|}{| class="wikitable" style="width:800px;" |-|
<p>orangepi@orangepi:~$ '''ip a s eth0'''</p>
<p>3: eth0: <BROADCAST,MULTICAST,UP,LOWER_UP> mtu 1500 qdisc pfifo_fast state UP group default qlen 1000</p>
:<p>link/ether 5e:ac:14:a5:92:b3 brd ff:ff:ff:ff:ff:ff</p>:<p>inet '''<span style="color:#FF0000">192.168.1.177</span>'''/24 brd 192.168.1.255 scope global noprefixroute eth0</p>::<p>valid_lft forever preferred_lft forever</p>:<p>inet6 241e:3b8:3240:c3a0:e269:8305:dc08:135e/64 scope global dynamic noprefixroute</p>::<p>valid_lft 259149sec preferred_lft 172749sec</p>:<p>inet6 fe80::957d:bbbe:4928:3604/64 scope link noprefixroute</p>::<p>valid_lft forever preferred_lft forever</p>|}</li>
<li><p>Then you can test the network connectivity to check whether the IP address is configured OK. The '''ping''' command can be interrupted by using the '''Ctrl+C''' shortcut key.</p>
{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <big><p>'''Note that in the following command, Debian12 needs to modify eth0 to end0.'''</p></big>|}{| class="wikitable" style="width:800px;" |-|
<p>orangepi@orangepi:~$ '''ping 192.168.1.177 -I eth0'''</p>
<p>PING 192.168.1.47 (192.168.1.47) from 192.168.1.188 eth0: 56(84) bytes of data.</p>
<p>--- 192.168.1.47 ping statistics ---</p>
<p>5 packets transmitted, 5 received, 0% packet loss, time 4042ms</p>
<p>rtt min/avg/max/mdev = 0.233/0.262/0.275/0.015 ms</p>|}</li></ol>
<span id="use-nmcli-command-to-set-static-ip-address"></span>
==== Use nmcli command to set static IP address ====
<li><p>Then you can view the name of the network device through the '''nmcli con show''' command, as shown below</p>
<ol style="list-style-type: lower-alpha;">
<li><p>'''orangepi''' is the name of the WIFI network interface (the > names are not necessarily the same)</p></li>
<li><p>'''Wired connection 1''' is the name of the Ethernet interface</p>
</li>
<li><p>中Then enter the following command, where</p>
<ol style="list-style-type: lower-alpha;">
<li><p>'''"Wired connection 1"''' means setting the static IP address > of the Ethernet port. If you need to set the static IP address > of WIFI, please change it to the name corresponding to the > WIFI network interface (can be obtained through the '''nmcli > con show''' command)</p></li><li><p>'''ipv4.addresses''' is followed by the static IP address to be > set, which can be modified to the value you want to set.</p></li>
<li><p>'''ipv4.gateway''' represents the address of the gateway</p>
{| class="wikitable" style="width:800px;"
|-
|
<p>orangepi@orangepi:~$ '''sudo nmcli con mod "Wired connection 1" \<br />
ipv4.addresses "192.168.1.110" \'''</p>
<p>'''ipv4.gateway "192.168.1.1" \'''</p>
<p>'''ipv4.dns "8.8.8.8" \'''</p>
<p>'''ipv4.method "manual"'''</p>|}</li></ol>
</li>
<li><p>Then restart the linux system</p>
{| class="wikitable" style="width:800px;" |-| <p>orangepi@orangepi:~$ '''sudo reboot'''</p>|}</li>
<li><p>Then re-enter the Linux system and use the '''ip addr show eth0''' command to see that the IP address has been set to the desired value.</p>
{| class="wikitable" style="width:800px;"
|-
|
<p>orangepi@orangepi:~$ '''ip addr show eth0'''</p>
<p>3: eth0: <BROADCAST,MULTICAST,UP,LOWER_UP> mtu 1500 qdisc pfifo_fast state UP group default qlen 1000</p>
:<p>link/ether 5e:ae:14:a5:91:b3 brd ff:ff:ff:ff:ff:ff</p>:<p>inet '''<span style="color:#FF0000">192.168.1.110</span>'''/32 brd 192.168.1.110 scope global noprefixroute eth0</p>::<p>valid_lft forever preferred_lft forever</p>:<p>inet6 240e:3b7:3240:c3a0:97de:1d01:b290:fe3a/64 scope global dynamic noprefixroute</p>::<p>valid_lft 259183sec preferred_lft 172783sec</p>:<p>inet6 fe80::3312:861a:a589:d3c/64 scope link noprefixroute</p>::<p>valid_lft forever preferred_lft forever</p>|}</li></ol>
<span id="how-to-set-up-the-linux-system-to-automatically-connect-to-the-network-for-the-first-time"></span>
=== How to set up the Linux system to automatically connect to the network for the first time ===
{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <big>'''The development board has an Ethernet port. If you want to remotely log in to the Linux system of the development board through the Ethernet port, you only need to plug in a network cable that can access the Internet normally. After starting the Linux system, it will automatically connect to the Ethernet port through DHCP. Assign an IP address, and then we can obtain the IP address of the Ethernet port through the HDMI screen, serial port, or view the router's background, and then log in to the Linux system remotely.'''
'''The development board also has wireless WIFI. If you want to remotely log in to the Linux system of the development board through WIFI, you need to remotely log in to the Linux system through ssh through the IP address of the Ethernet port and then use commands to connect to WIFI, or use commands on the HDMI screen or serial port. Connect to WIFI.'''
'''But if there is no HDMI screen and serial port module, although there is a network cable, the IP address of the development board cannot be viewed through the router background. Or if there is no HDMI screen, serial port module and network cable, and only WIFI can be connected, you can use the method introduced in this section to automatically connect to WIFI and set the static IP address of WIFI or automatically set the static IP address of the Ethernet port.'''</big>|}{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <big>'''To use the method in this section, you first need to prepare a Linux system machine. For example, a computer or virtual machine with Ubuntu system installed.'''
'''To use the method in this section, Why do you first need to prepare a Linux system machine? Because the root file system of the Linux system of the development board burned in the TF card is in ext4 format. For example, The Linux system machine can mount it normally and then modify the configuration file in it.'''</big>|}{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <big>'''If you want to modify it in a computer or virtual machine with Ubuntu Windows system installed, you can use the software Paragon ExtFS for Windows. Since this software requires payment, and there is currently no similar free software that is easy to use, I will not demonstrate it in detail here.'''
'''Why do In addition, if you need a Linux system machine? Because the root file system of the Linux system of the development board burned in the TF card is in ext4 formathave any problems when trying to use Paragon ExtFS for Windows, please solve it yourself. The Linux system machine can mount it normally and then modify the configuration file in itWe will not answer questions.'''</big>|}
<li><p>First burn the Linux image of the development board you want to use into a TF card, and then use a card reader to insert the TF card with the Linux image of the development board into a machine with a Linux system (such as a machine with Ubuntu system Computer, the following uses Ubuntu computer as an example for demonstration)</p></li>
<li><p>When the TF card is inserted into the Ubuntu computer, the Ubuntu computer will generally automatically mount the Linux root file system partition in the TF card. From the following command, we can know that '''/media/test/opi_root''' is the Linux root file in the TF card. System mounting path</p>
{| class="wikitable" style="width:800px;"
|-
|
<p>test@test:~$ '''df -h | grep "media"'''</p>
<p>/dev/sdd1 1.4G 1.2G 167M 88% '''<span style="color:#FF0000">/media/test/opi_root</span>'''</p>
<p>test@test:~$ '''ls /media/test/opi_root'''</p>
<p>bin boot dev etc home lib lost+found media mnt opt proc root run <br> sbin selinux srv sys tmp usr var</p>|}</li>
<li><p>Then enter the '''/boot''' directory of the Linux system burned in the TF card</p>
{| class="wikitable" style="width:800px;" |-| <p>test@test:~$ '''cd /media/test/opi_root/boot/'''</p>|}</li>
<li><p>Then copy the '''orangepi_first_run.txt.template''' to '''orangepi_first_run.txt'''. Through the orangepi_first_run.txt configuration file, you can set the development board to automatically connect to a WIFI hotspot when the Linux system starts for the first time. You can also set the WIFI or Ethernet port Static IP address.</p>
{| class="wikitable" style="width:800px;" |-| <p>test@test:/media/test/opi_root/boot$ '''sudo cp orangepi_first_run.txt.template orangepi_first_run.txt'''</p>|}</li>
<li><p>You can open the orangepi_first_run.txt file through the following command, and then you can view and modify the contents.</p>
{| class="wikitable" style="width:800px;" |-| <p>test@test:/media/test/opi_root/boot$ '''sudo vim orangepi_first_run.txt'''</p>|}</li>
<li><p>Variable usage instructions in the orangepi_first_run.txt file</p>
<ol style="list-style-type: lower-alpha;">
<li><p>'''FR_general_delete_this_file_after_completion''' The variable is > used to set whether to delete the orangepi_first_run.txt file > after the first startup. The default is 1, which means > deletion. If set to 0, orangepi_first_run.txt will be renamed > after the first startup.orangepi_first_run.txt.old, Generally, > just keep the default value</p></li><li><p>'''FR_net_change_defaults''' The variable is used to set whether > to change the default network settings. This must be set to 1, > otherwise all network settings will not take effect.</p></li><li><p>'''FR_net_ethernet_enabled''' The variable is used to control > whether to enable the configuration of the Ethernet port. If > you need to set the static IP address of the Ethernet port, > please set it to 1</p></li><li><p>'''FR_net_wifi_enabled''' The variable is used to control whether > to enable WIFI configuration. If you need to set the > development board to automatically connect to WIFI hotspots, > you must set it to 1. Also please note that if this variable > is set to 1, the Ethernet port settings will be invalid. That > is to say, the WIFI and Ethernet ports cannot be set at the > same time (why, because it is not necessary...)</p></li><li><p>'''FR_net_wifi_ssid''' Variable is used to set the name of the > WIFI hotspot you want to connect to</p></li><li><p>'''FR_net_wifi_key''' Variable is used to set the password of the > WIFI hotspot you want to connect to</p></li><li><p>'''FR_net_use_static''' Variables are used to set whether the > static IP address of the WIFI or Ethernet port needs to be > set.</p></li><li><p>'''FR_net_static_ip''' The variable is used to set the static IP > address. Please set it according to your actual situation.</p></li><li><p>'''FR_net_static_gateway''' Variables are used to set the gateway. > Please set according to your actual situation.</p></li></ol>
</li>
<li><p>Here are some specific setting examples:</p>
<ol style="list-style-type: lower-alpha;">
<li><p>For example, if you want the Linux system of the development > board to automatically connect to the WIFI hotspot after it is > started for the first time, you can set it like this: </p><ol style="list-style-type: lower-alphanone;"><li><p>a) Set '''FR_net_change_defaults''' to 1</p></li><li><p>b) Set '''FR_net_wifi_enabled''' to '''1'''</p></li><li><p>c) Set '''FR_net_wifi_ssid''' to the name of the WIFI hotspot you > want to connect to</p></li><li><p>d) Set '''FR_net_wifi_key''' to the password of the WIFI hotspot > you want to connect to</p></li></ol>
</li>
<li><p>For example, you want the Linux system of the development board > to automatically connect to the WIFI hotspot after the first > startup, and set the WIFI IP address to a specific static IP > address (so that when the Linux system starts, you can > directly use the set static IP address to ssh remotely Log in > to the development board, there is no need to check the IP > address of the development board through the router > background), you can set it like this:</p><ol style="list-style-type: lower-alphanone;"><li><p>a) Set '''FR_net_change_defaults''' to '''1'''</p></li><li><p>b) Set '''FR_net_wifi_enabled''' to '''1'''</p></li><li><p>c) Set '''FR_net_wifi_ssid''' to the name of the WIFI hotspot you > want to connect to</p></li><li><p>d) Set '''FR_net_wifi_key''' to the password of the WIFI hotspot > you want to connect to</p></li><li><p>e) Set '''FR_net_use_static''' to '''1'''</p></li><li><p>f) Set '''FR_net_static_ip''' to the desired IP address</p></li><li><p>g) Set '''R_net_static_gateway''' to the corresponding gateway > address</p></li></ol>
</li>
<li><p>For example, if you want the development board's Linux system > to automatically set the IP address of the Ethernet port to > the desired static IP address after it is started for the > first time, you can set it like this</p><ol style="list-style-type: lower-alphanone;"><li><p>a) Set '''FR_net_change_default''' to '''1'''</p></li><li><p>b) Set '''FR_net_ethernet_enabled''' to '''1'''</p></li><li><p>c) Set '''FR_net_use_static''' to '''1'''</p></li><li><p>d) Set '''FR_net_static_ip''' to the desired IP address</p></li><li><p>e) Set '''FR_net_static_gateway''' to the corresponding gateway > address</p></li></ol>
</li></ol>
</li>
<li><p>After modifying the orangepi_first_run.txt file, you can exit the /boot directory of the development board Linux system in the TF card, uninstall the TF card, and then insert the TF card into the development board to start.</p></li>
<li><p>If a static IP address is not set, you still need to check the IP address through the router background. If a static IP address is set, you can ping the set static IP address on the computer. If you can ping, it means that the system has started normally, and The network has been set up correctly, and then you can use the set IP address to ssh to remotely log in to the Linux system of the development board.</p>{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| </libig></ol> '''After the development board's Linux system is started for the first time, orangepi_first_run.txt will be deleted or renamed to orangepi_first_run.txt.old. At this time, even if the orangepi_first_run.txt configuration file is reset, and then the development board's Linux system is restarted, orangepi_first_run. The configuration in txt will not take effect again, because this configuration will only take effect when the Linux system is started for the first time after burning it. Please pay special attention to this point.'''</big>|}</li></ol><span id="ssh-remote-login-development-board"></span>
== SSH remote login development board ==
{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <big>'''Linux systems enable ssh remote login by default and allow root users to log in to the system. Before ssh login, you first need to ensure that the Ethernet or wifi network is connected, and then use the ip addr command or obtain the IP address of the development board by checking the router'''</big>|}
<span id="ssh-remote-login-development-board-under-ubuntu"></span>
# Then you can remotely log in to the Linux system through the ssh command
::{| class="wikitable" style="width:800px;" |-| test@test:~$ '''ssh [mailto:root@192.168.1.36 orangepi@192.168.1.]xxx''' (Need to be replaced with the IP address of the development board)
orangepi@192.168.1.xx's password: (iEnter (Enter your password here, the default password is orangepi)|}::{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <big>'''Note that when entering a password, <span style="color:#FF0000">the specific content of the entered password will not be displayed on the screen</span>. Please do not think that there is something wrong. Just press Enter after entering it.'''
'''Note that when entering a password, the specific content of the entered password will not be displayed on the screen. Please do not think that there is something wrong. Just press Enter after entering it.''' '''f If you are prompted to refuse the connection, as long as you are using the image provided by Orange Pi, <span style="color:#FF0000">please do not doubt whether the orangepi password is incorrect</span>, but look for other reasons.'''</big>|}
<ol start="3" style="list-style-type: decimal;">
<li><p>After successfully logging into the system, the display is as shown below</p>
<p>[[File:zero2w-img140.png]]</p>
{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <big><p>'''If ssh cannot log in to the Linux system normally, first check whether the IP address of the development board can be pinged. If there is no problem with pinging, you can log in to the Linux system through the serial port or HDMI display and enter the following command on the development board before trying again. Can it be connected?: '''</p></li></ol>
root@orangepi:~# '''reset_ssh.sh'''
'''If it still doesn't work, please try restarting the system.'''</big>
|}
</li></ol>
<span id="ssh-remote-login-development-board-under-windows"></span>
=== SSH remote login development board under Windows ===
<li><p>Open '''Session'''</p></li>
<li><p>Then select '''SSH''' in '''Session Setting'''</p></li>
<li><p>Then enter the IP address of the development board in '''Remote > host'''</p></li><li><p>Then enter the username '''root''' or '''orangepi''' of the linux > system in '''Specify username'''.</p></li>
<li><p>Finally click '''OK'''</p>
<div class="figure">
</li>
<li><p>You will then be prompted to enter a password. The default passwords for both root and orangepi users are orangepi.</p>
{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <big><p>'''Note that when entering a password, <span style="color:#FF0000">the specific content of the entered password will not be displayed on the screen</span>. Please do not think that there is any malfunction. Just press Enter after entering the password.'''</p></big>|}
<div class="figure">
<span id="hdmi-test"></span>
== HDMI test ==
</div></li>
<li><p>After starting the Linux system, if there is image output on the HDMI display, it means that the HDMI interface is working normally.</p>{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| </li></olbig> '''Note that although many laptops have HDMI interfaces, the HDMI interface of the laptop generally only has the output function and does not have the HDMI in function, which means that the HDMI output of other devices cannot be displayed on the laptop screen'''
'''When you want to connect the HDMI of the development board to the HDMI interface of your laptop, please first confirm that your laptop supports the HDMI in function'''</big>|}{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <big>'''When HDMI does not display, please first check whether the HDMI cable is plugged in tightly. After confirming that the wiring is OK, you can try a different screen to see if there is any display.'''</big>|}</li></ol><span id="hdmi-to-vga-display-test"></span>
=== HDMI to VGA display test ===
<li><p>HDMI to VGA display test is as follows</p>
<p>[[File:zero2w-img147.png]]</p>
{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <big><p>'''When using HDMI to VGA display, the development board and the Linux system of the development board do not need to make any settings. You only need the Mini HDMI interface of the development board to display normally. So if there is a problem with the test, please check whether there is a problem with the HDMI to VGA converter, VGA cable and monitor.'''</p></big>|}</li></ol>
<span id="how-to-set-hdmi-resolution-in-linux5.4-system"></span>
=== How to set HDMI resolution in Linux5.4 system ===
{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <big>'''Note: This method is only applicable to systems with Linux 5.4 kernel.'''</big>|}
<ol style="list-style-type: decimal;">
<li><p>There is a disp_mode variable in '''/boot/orangepiEnv.txt''' of the Linux system, which can be used to set the resolution of HDMI output. The default resolution of the Linux system is 1080p60</p>
{| class="wikitable" style="width:800px;"
|-
|
<p>orangepi@orangepi:~$ '''sudo vim /boot/orangepiEnv.txt'''</p>
<p>verbosity=1</p>
<p>console=both</p>
<p>disp_mode='''<span style="color:#FF0000">1080p60</span>'''</p>
<p>fb0_width=1920</p>
<p>fb0_height=1080</p>|}</li><li><p>The disp_mode variable supports setting values as shown in the table below</p></li></ol>
{| class="wikitable" style="width:800px;text-align: center;"
|-
| '''disp_mode supported values'''
| '''60'''
|}
{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <big>'''Note: Linux systems currently do not support 4K resolution.'''</big>|}</ol>
<ol start="3" style="list-style-type: decimal;">
<li><p>Change the value of the disp_mode variable to the resolution you want to output, then restart the system, and HDMI will output the set resolution.</p></li>
<li><p>The method of checking the HDMI output resolution is as follows. If the displayed resolution is the same as the set resolution, it means that the settings on the development board are correct.</p>
{| class="wikitable" style="width:800px;"
|-
|
<p>orangepi@orangepi:~$ '''sudo cat /sys/class/disp/disp/attr/sys'''</p>
|}
<p>[[File:zero2w-img148.png]]</p></li></ol>
<span id="how-to-modify-the-width-and-height-of-framebuffer-in-linux5.4-system"></span>
=== How to modify the width and height of Framebuffer in Linux5.4 system ===
{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <big>'''Note: This method is only applicable to systems with Linux 5.4 kernel.'''</big>|}
There are two variables, fb0_width and fb0_height, in '''/boot/orangepiEnv.txt''' of the Linux system. You can use them to set the width and height of the Framebuffer. The Linux system defaults to fb0_width=1920 and fb0_height=1080.
{| class="wikitable" style="width:800px;"
|-
|
orangepi@orangepi:~$ '''sudo vim /boot/orangepiEnv.txt'''
disp_mode=1080p60
'''<span style="color:#FF0000">fb0_width=1920</span>'''
'''<span style="color:#FF0000">fb0_height=1080</span>'''|}
The reference values corresponding to different resolutions of fb0_width and fb0_height are as follows::
{| class="wikitable" style="width:800px;text-align: center;"
|-
| '''HDMI resolution'''
<span id="framebuffer-cursor-setting"></span>
=== Framebuffer cursor setting ===
<ol style="list-style-type: decimal;">
<li><p>The softcursor used by Framebuffer, the method to set the cursor to blink or not to blink is as follows</p>
{| class="wikitable" style="width:800px;" |-| <p>root@orangepi:~# '''echo <span style="color:#FF0000">1 </span> > /sys/class/graphics/fbcon/cursor_blink #Cursor flashes'''</p><p>root@orangepi:~# '''echo <span style="color:#FF0000">0 </span> > /sys/class/graphics/fbcon/cursor_blink #Cursor does not flash'''</p>|}</li>
<li><p>If you need to hide the cursor, you can add vt.global_cursor_default=0 to the '''extraargs''' variable in '''/boot/orangepiEnv.txt''' (the value of extraargs will be assigned to the '''bootargs''' environment variable and eventually passed to the kernel) (if '''<span class="mark">vt.global_cursor_default=1</span>''', it will be displayed cursor), then restart the system and you will see that the cursor has disappeared.</p>
{| class="wikitable" style="width:800px;"
|-
|
<p>orangepi@orangepi:~$ '''sudo vim /boot/orangepiEnv.txt'''</p>
<p>verbosity=1</p>
<p>fb0_width=1920</p>
<p>fb0_height=1080</p>
<p>'''<span style="color:#FF0000">extraargs=vt.global_cursor_default=0</span>'''</p>|}</li></ol>
<span id="how-to-use-bluetooth"></span>
== How to use Bluetooth ==
<ol style="list-style-type: decimal;">
<li><p>After entering the system, you can first check whether there is a Bluetooth device node through the '''hciconfig''' command. If it exists, it means that the Bluetooth initialization is normal.</p>
{| class="wikitable" style="width:800px;"
|-
|
<p>orangepi@orangepi:~$ '''sudo apt update && sudo apt install -y bluez'''</p>
<p>orangepi@orangepi:~$ '''hciconfig -a'''</p>
<p>hci0: Type: Primary Bus: UART</p>
:<p>BD Address: 3E:61:3D:19:0E:52 ACL MTU: 1021:8 SCO MTU: 240:3</p>:<p>UP RUNNING</p>:<p>RX bytes:925 acl:0 sco:0 events:72 errors:0</p>:<p>TX bytes:5498 acl:0 sco:0 commands:72 errors:0</p>:<p>Features: 0xbf 0xff 0x8d 0xfe 0xdb 0x3d 0x7b 0xc7</p>:<p>Packet type: DM1 DM3 DM5 DH1 DH3 DH5 HV1 HV2 HV3</p>:<p>Link policy: RSWITCH SNIFF</p>:<p>Link mode: SLAVE ACCEPT</p>:<p>Name: 'orangepi'</p>:<p>Class: 0x3c0000</p>:<p>Service Classes: Rendering, Capturing, Object Transfer, Audio</p>:<p>Device Class: Miscellaneous,</p>:<p>HCI Version: 5.0 (0x9) Revision: 0x400</p>:<p>LMP Version: 5.0 (0x9) Subversion: 0x400</p>:<p>Manufacturer: Spreadtrum Communications Shanghai Ltd (492)</p>|}</li>
<li><p>Use '''bluetoothctl''' to scan for Bluetooth devices</p>
{| class="wikitable" style="width:800px;"
|-
|
<p>orangepi@orangepi:~$ '''sudo bluetoothctl'''</p>
<p>[NEW] Controller 10:11:12:13:14:15 orangepizero2w [default]</p>
<p>Discovery stopped</p>
<p>[CHG] Controller 10:11:12:13:14:15 Discovering: no</p>
<p>[CHG] Device DC:72:9B:4C:F4:CF RSSI is nil</p>|}</li>
<li><p>After scanning the device you want to pair, you can pair it. For pairing, you need to use the MAC address of the device.</p>
{| class="wikitable" style="width:800px;"
|-
|
<p>[bluetooth]# '''pair DC:72:9B:4C:F4:CF''' '''#Pair using the MAC address of the scanned Bluetooth device'''</p>
<p>Attempting to pair with DC:72:9B:4C:F4:CF</p>
<p>'''Pairing successful #Prompt pairing successful'''</p>
<p>[CHG] Device DC:72:9B:4C:F4:CF ServicesResolved: no</p>
<p>[CHG] Device DC:72:9B:4C:F4:CF Connected: no</p>|}</li>
<li><p>After successful pairing, the Bluetooth interface of the mobile phone will appear as follows:</p>
<div class="figure">
</div></li>
<li><p>To connect to a Bluetooth device, you need to install the '''pulseaudio-module-bluetooth''' software package, and then start the '''pulseaudio''' service</p>
{| class="wikitable" style="width:800px;"
|-
|
<p>orangepi@orangepi:~$ '''sudo apt update'''</p>
<p>orangepi@orangepi:~$ '''sudo''' '''apt -y install pulseaudio-module-bluetooth'''</p>
<p>orangepi@orangepi:~$ '''pulseaudio --start'''</p>|}</li>
<li><p>How to connect Bluetooth devices</p>
{| class="wikitable" style="width:800px;"
|-
|
<p>orangepi@orangepi:~$ '''sudo bluetoothctl'''</p>
<p>Agent registered</p>
<p>[CHG] Device DC:72:9B:4C:F4:CF ServicesResolved: yes</p>
<p>[CHG] Controller 10:11:12:13:14:15 Discoverable: no</p>
<p>'''[orangepi]# #If this prompt appears, the connection is successful.'''</p>|}</li>
<li><p>After connecting the Bluetooth device, you can see the prompt that the audio for calls and media has been '''connected in the Bluetooth configuration interface of the Android phone'''.</p>
<div class="figure">
<span id="usb-interface-test"></span>
== USB interface test ==
{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <big>'''The USB interface can be connected to a USB hub to expand the number of USB interfaces.'''</big>|}
<span id="usb-interface-extension-description"></span>
<ol style="list-style-type: lower-alpha;">
<li><p>First run '''orangepi-config'''. Ordinary users remember to add > '''sudo''' permissions.</p>{| class="wikitable" style="width:800px;" |-| <p>orangepi@orangepi:~$ '''sudo orangepi-config'''</p>|}</li>
<li><p>Then select '''System'''</p>
<p>[[File:zero2w-img80.png]]</p></li>
<li><p>Then select '''Hardware'''</p>
<p>[[File:zero2w-img81.png]]</p></li>
<li><p>Then use the keyboard's arrow keys to locate the location shown in > the picture below, and then use the space to select '''usb0-host'''</p>
<p>[[File:zero2w-img161.png]]</p></li>
<li><p>Then select '''<Save>'''to save</p>
<li><p>Then select '''<Back>'''</p>
<p>[[File:zero2w-img84.png]]</p></li>
<li><p>Then select '''<Reboot>'''to restart the system to make the > configuration take effect.</p>
<p>[[File:zero2w-img85.png]]</p></li>
<li><p>After restarting, USB0 can use USB devices such as mouse and > keyboard normally.</p></li></ol>
<span id="connect-usb-mouse-or-keyboard-to-test"></span>
=== Connect USB mouse or keyboard to test ===
# Execute the following command. If you can see the output of sdX, it means the USB disk is successfully recognized.
::{| class="wikitable" style="width:800px;"|-|orangepi@orangepi:~$ '''cat /proc/partitions | grep "sd*"'''<br> <span style="margin-right: 30px;">major </span><span style="margin-right: 40px;">minor </span><span style="margin-right: 30px;">#blocks </span><span style="margin-right: 50px;">name</span><br> <span style="margin-right: 70px;">8 </span><span style="margin-right: 60px;">0 </span><span style="margin-right: 50px;">30044160 </span><span style="margin-right: 50px;color:#FF0000">'''sda'''</span><br> <span style="margin-right: 70px;">8 </span><span style="margin-right: 60px;">1 </span><span style="margin-right: 50px;">30043119 </span><span style="margin-right: 50px;color:#FF0000">'''sda1'''</span><br>|}
<ol start="3" style="list-style-type: decimal;">
<li>Use the mount command to mount the U disk to '''/mnt''', and then you can view the files in the U disk</li></ol>{| class="wikitable" style="width:800px;" |-|
orangepi@orangepi:~$ '''sudo mount /dev/sda1 /mnt/'''
test.txt
|}</ol>
<ol start="4" style="list-style-type: decimal;">
<li>After mounting, you can check the capacity usage and mount point of the U disk through the '''df -h''' command.</li></ol>{| class="wikitable" style="width:800px;" |-|
orangepi@orangepi:~$ '''df -h | grep "sd"'''
/dev/sda1 29G 208K 29G 1% /mnt|}</ol><span id="usb-ethernet-card-test"></span>
=== USB Ethernet card test ===
# The '''currently tested''' and usable USB Ethernet cards are as follows. Among them, the RTL8153 USB Gigabit network card can be used normally when inserted into the USB 2.0 Host interface of the development board for testing, but the speed cannot reach Gigabit. Please note this.
::{| class="wikitable" style="width:800px;text-align: center;"
|-
| serial number
<ol start="2" style="list-style-type: decimal;">
<li><p>First insert the USB network card into the USB interface of the development board, and then insert the network cable into the USB network card to ensure that the network cable can access the Internet normally. If you can see the following log information through the '''dmesg''' command, it means that the USB network card is recognized normally.</p>
{| class="wikitable" style="width:800px;"
|-
|
<p>orangepi@orangepi:~$ '''dmesg | tail'''</p>
<p>[ 121.985016] usb 3-1: USB disconnect, device number 2</p>
<p>[ 127.763031] IPv6: ADDRCONF(NETDEV_UP): enx00e04c362017: link is not ready</p>
<p>[ 129.892465] r8152 3-1:1.0 enx00e04c362017: carrier on</p>
<p>[ 129.892583] IPv6: ADDRCONF(NETDEV_CHANGE): enx00e04c362017: link becomes ready</p>|}</li>
<li><p>Then you can see the device node of the USB network card and the automatically assigned IP address through the ifconfig command</p>
{| class="wikitable" style="width:800px;"
|-
|
<p>orangepi@orangepi:~$ '''sudo ifconfig'''</p>
<p>'''enx00e04c362017''': flags=4163<UP,BROADCAST,RUNNING,MULTICAST> mtu 1500</p>
::<p>inet '''192.168.1.177''' netmask 255.255.255.0 broadcast 192.168.1.255</p>::<p>inet6 fe80::681f:d293:4bc5:e9fd prefixlen 64 scopeid 0x20<link></p>::<p>ether 00:e0:4c:36:20:17 txqueuelen 1000 (Ethernet)</p>::<p>RX packets 1849 bytes 134590 (134.5 KB)</p>::<p>RX errors 0 dropped 125 overruns 0 frame 0</p>::<p>TX packets 33 bytes 2834 (2.8 KB)</p>::<p>TX errors 0 dropped 0 overruns 0 carrier 0 collisions 0</p>|}</li>
<li><p>The command to test network connectivity is as follows</p>
{| class="wikitable" style="width:800px;"
|-
|
<p>orangepi@orangepi:~$ '''ping www.baidu.com -I enx00e04c362017'''</p>
<p>PING www.a.shifen.com (14.215.177.38) from 192.168.1.12 eth0: 56(84) bytes of data.</p>
<p>--- www.a.shifen.com ping statistics ---</p>
<p>4 packets transmitted, 4 received, 0% packet loss, time 3002ms</p>
<p>rtt min/avg/max/mdev = 6.260/6.770/7.275/0.373 ms</p>|}</li></ol>
<span id="usb-camera-test"></span>
=== USB camera test ===
<li><p>First insert the USB camera into the USB interface of the Orange Pi development board</p></li>
<li><p>Then you can see through the lsmod command that the kernel automatically loads the following modules</p>
{| class="wikitable" style="width:800px;"
|-
|
<p>orangepi@orangepi:~$ '''lsmod'''</p>
<pspan style="margin-right: 100px;">Module </span><span style="margin-right: 50px;">Size </span><span style="margin-right: 45px;">Used by</pspan><br><pspan style="margin-right: 100px;">'''uvcvideo </span><span style="margin-right: 50px;">106496 </span><span style="margin-right: 50px;">0'''</pspan><br>|}</li>
<li><p>Through the v4l2-ctl command, you can see that the device node information of the USB camera is/dev/video0</p>
{| class="wikitable" style="width:800px;"
|-
|
<p>orangepi@orangepi:~$ '''sudo apt update'''</p>
<p>orangepi@orangepi:~$ '''sudo''' '''apt install -y v4l-utils'''</p>
<p>orangepi@orangepi:~$ '''v4l2-ctl --list-devices'''</p>
<p>USB 2.0 Camera (usb-sunxi-ehci-1):</p>
::<p>/dev/video0</p>|}{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <big><p>'''Note that the l in v4l2 is the lowercase letter l, not the number 1.'''</p><p>'''In addition, the serial number of the video may not always be video0, please refer to what you actually see.'''</p></big>|}</li>
<li><p>Use fswebcam to test the USB camera</p>
<ol style="list-style-type: lower-alpha;">
<li><p>Install fswebcam</p>
{| class="wikitable" style="width:800px;"
|-
|
<p>orangepi@orangepi:~$ '''sudo''' '''apt update'''</p>
<p>orangepi@orangepi:~$ '''sudo apt-get install -y fswebcam'''</p>|}</li><li><p>After installing fswebcam, you can use the following command to > take pictures</p><ol style="list-style-type: lower-alphanone;"><li><p>a) -d Option to specify the device node of the USB camera</p></li><li><p>b) --no-banner Used to remove watermarks from photos</p></li><li><p>c) -r option is used to specify the resolution of the photo</p></li><li><p>d) -S Option to skip previous frames</p></li><li><p>e) ./image.jpg Used to set the name and path of the generated > photo</p>{| class="wikitable" style="width:800px;" |-|
<p>orangepi@orangepi:~$ '''sudo''' '''fswebcam -d /dev/video0 \'''</p>
<p>'''--no-banner -r 1280x720 -S 5 ./image.jpg'''</p>|}</li></ol>
</li>
<li><p>In the server version of Linux system, after taking the picture, > you can use the scp command to transfer the taken picture to > the Ubuntu PC for mirror viewing.</p>{| class="wikitable" style="width:800px;" |-| <p>orangepi@orangepi:~$ '''scp image.jpg [mailto:test@192.168.1.55:/home/test test@192.168.1.55:/home/test] (Modify the IP address and path according to the actual situation)'''</p>|}</li><li><p>In the desktop version of Linux system, you can directly view > the captured pictures through the HDMI display</p></li></ol>
</li>
<li><p>Use mjpg-streamer to test the USB camera</p>
<ol style="list-style-type: lower-alpha;">
<li><p>Download mjpg-streamer</p>
<ol style="list-style-type: lower-alphanone;"><li><p>a) Github download address:</p>{| class="wikitable" style="width:800px;" |-| <p>orangepi@orangepi:~$ '''git clone https://github.com/jacksonliam/mjpg-streamer'''</p>|}</li><li><p>b) The image download address of Gitee is:</p>{| class="wikitable" style="width:800px;" |-| <p>orangepi@orangepi:~$ '''git clone https://gitee.com/leeboby/mjpg-streamer'''</p>|}</li></ol>
</li>
<li><p>Install dependent software packages</p>
<ol style="list-style-type: lower-alphanone;"><li><p>a) Ubuntu system</p><p>orangepi@orangepi{| class="wikitable" style="width:~$ '''sudo apt-get install 800px;" |-y cmake libjpeg8-dev'''</p></li><li><p>Debian system</p>| <p>orangepi@orangepi:~$ '''sudo apt-get install -y cmake libjpeg62-turbolibjpeg8-dev'''</p></li></ol>|}
</li>
<li><p>b) Debian system</p>{| class="wikitable" style="width:800px;" |-| <p>orangepi@orangepi:~$ '''sudo apt-get install -y cmake libjpeg62-turbo-dev'''</p>|}</li></ol></li><li><p>Compile and install mjpg-streamer</p>{| class="wikitable" style="width:800px;" |-|
<p>orangepi@orangepi:~$ '''cd mjpg-streamer/mjpg-streamer-experimental'''</p>
<p>orangepi@orangepi:~/mjpg-streamer/mjpg-streamer-experimental$ '''make -j4'''</p>
<p>orangepi@orangepi:~/mjpg-streamer/mjpg-streamer-experimental$ '''sudo make install'''</p>|}</li>
<li><p>Then enter the following command to start mjpg_streamer</p>
{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <big><p>'''Note that the serial number of the video is not always video0, please refer to what you actually see.'''</p></big>|}{| class="wikitable" style="width:800px;" |-|
<p>orangepi@orangepi:~/mjpg-streamer/mjpg-streamer-experimental$ '''export LD_LIBRARY_PATH=.'''</p>
<p>orangepi@orangepi:~/mjpg-streamer/mjpg-streamer-experimental$ '''sudo ./mjpg_streamer -i "./input_uvc.so -d \'''</p>
<p>'''/dev/video0 -u -f 30" -o "./output_http.so -w ./www"'''</p>|}</li><li><p>Then enter ['''the IP address of the development board: 8080'''] > in the Ubuntu PC or Windows PC or mobile phone browser on the > same LAN as the development board to see the video output by > the camera.</p>
<div class="figure">
<span id="audio-test"></span>
== Audio test ==
<li><p>Use the '''aplay -l''' command to view the sound card devices supported by the Linux system</p>
<ol style="list-style-type: lower-alpha;">
<li><p>The output of the linux5.4 system is as follows, where '''card 0: > audiocodec''' is the sound card device required for headphone > playback</p>{| class="wikitable" style="width:800px;" |-|
<p>root@orangepi:~# '''aplay -l'''</p>
<p>**** List of PLAYBACK Hardware Devices ****</p>
<p>'''card 0: audiocodec [audiocodec], device 0: soc@3000000:codec_plat-5096000.codec 5096000.codec-0 []'''</p>
:<p>'''Subdevices: 1/1'''</p>:<p>'''Subdevice #0: subdevice #0'''</p>|}</li><li><p>The output of the b.linux6.1 system is as follows, where > '''audiocodec''' is the sound card device required for headphone > playback.</p>{| class="wikitable" style="width:800px;" |-|
<p>root@orangepi:~# '''aplay -l'''</p>
<p>**** List of PLAYBACK Hardware Devices ****</p>
<p>'''card 0: audiocodec [audiocodec], device 0: CDC PCM Codec-0 [CDC PCM Codec-0]'''</p>
:<p>'''Subdevices: 1/1'''</p>:<p>'''Subdevice #0: subdevice #0'''</p>|}</li></ol>
</li>
<li><p>Then use the '''aplay''' command to play the audio, and the sound can be heard through the headphones</p>
{| class="wikitable" style="width:800px;"
|-
|
<p>root@orangepi:~# '''aplay -D hw:0,0 /usr/share/sounds/alsa/audio.wav'''</p>
<p>Playing WAVE 'audio.wav' : Signed 16 bit Little Endian, Rate 44100 Hz, Stereo</p>|}{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| </libig></ol> '''If there is noise during the headphone test, please pull out some of the headphones and do not plug them all the way in.'''</big>|}</li></ol><span id="hdmi-audio-playback-test"></span>
==== HDMI audio playback test ====
<li><p>First use the Mini HDMI to HDMI cable to connect the Orange Pi development board to the TV (other HDMI displays need to ensure that they can play audio)</p></li>
<li><p>HDMI audio playback does not require other settings, just use the '''aplay''' command to play directly</p>
{| class="wikitable" style="width:800px;" |-| <p>root@orangepi:~# '''aplay -D hw:2,0 /usr/share/sounds/alsa/audio.wav'''</p>|}</li></ol>
<span id="test-audio-methods-on-desktop-systems"></span>
=== Test audio methods on desktop systems ===
<li><p>First open the volume control interface</p>
<p>[[File:zero2w-img166.png]]</p></li>
<li><p>When playing audio, the audio device options that can be used by > the '''Playback''' software will be displayed in '''Playback''', > as shown in the figure below. Here you can set which audio > device needs to be played.</p>
<div class="figure">
<span id="infrared-reception-test"></span>
== Infrared reception test ==
<li><p>There is no infrared receiver on the main board of the development board. We can expand it through a 24pin expansion board.</p>
<p>[[File:zero2w-img107.png]]</p></li>
<li><p>Install ir-keytable infrared test software</p></li></ol>{| class="wikitable" style="width:800px;" |-|
orangepi@orangepi:~$ '''sudo''' '''apt update'''
orangepi@orangepi:~$ '''sudo''' '''apt-get install -y ir-keytable'''
|}</ol>
<ol start="3" style="list-style-type: decimal;">
<li><p>Then execute ir-keytable to view the information of the infrared device</p>
<ol style="list-style-type: lower-alpha;">
<li>linux5.4 system output is as follows</li></ol></li></ol>{| class="wikitable" style="width:800px;" |-|
orangepi@orangepi:~$ '''ir-keytable'''
Found /sys/class/rc/rc0/ with:
::Name: sunxi-ir
::Driver: sunxi-rc-recv
::Default keymap: rc_map_sunxi
::Input device: /dev/input/event1
::LIRC device: /dev/lirc0
::Attached BPF protocols: Operation not permitted
::Supported kernel protocols: lirc nec
::Enabled kernel protocols: lirc nec
::bus: 25, vendor/product: 0001:0001, version: 0x0100 Repeat delay = 500 ms, repeat period = 125 ms
::Repeat delay = 500 ms, repeat period = 125 ms
|}
</ol>
<ol start="2" style="list-style-type: lower-alpha;">
<li><p>The output of the linux6.1 system is as follows</p>
{| class="wikitable" style="width:800px;"
|-
|
<p>orangepi@orangepi:~$ '''ir-keytable'''</p>
<p>Found /sys/class/rc/rc0/ with:</p>
::<p>Name: sunxi-ir</p>::<p>Driver: sunxi-ir</p>::<p>Default keymap: rc-empty</p>::<p>Input device: /dev/input/event5</p>::<p>LIRC device: /dev/lirc0</p>::<p>Attached BPF protocols: Operation not permitted</p>::<p>Supported kernel protocols: lirc rc-5 rc-5-sz jvc sony nec sanyo mce_kbd rc-6 sharp xmp imon rc-mm</p>::<p>Enabled kernel protocols: lirc</p>::<p>bus: 25, vendor/product: 0001:0001, version: 0x0100</p>::<p>Repeat delay = 500 ms, repeat period = 125 ms</p>|}</li></ol> <!-- --/li></ol>
<ol start="4" style="list-style-type: decimal;">
<li><p>Before testing the infrared reception function, you need to prepare an Orange Pi-specific infrared remote control. '''<span classstyle="markcolor:#FF0000">Other remote controls do not support it</span>'''.</p>
<div class="figure">
<li><p>Then enter the '''ir-keytable -t''' command in the terminal, and then use the infrared remote control to press the button against the infrared receiver of the Orange Pi development board to see the received key code in the terminal.</p>
<ol style="list-style-type: lower-alpha;">
<li>linux5.4 system output is as follows</li></ol></li></ol>{| class="wikitable" style="width:800px;" |-|
orangepi@orangepi:~$ '''sudo ir-keytable -t'''
1598339152.914715: event type EV_MSC(0x04): scancode = 0xfb0410
|}</ol>
<ol start="2" style="list-style-type: lower-alpha;">
<li><p>linux6.1 system output is as follows</p>
{| class="wikitable" style="width:800px;"
|-
|
<p>orangepi@orangepi:~$ '''sudo ir-keytable -c -p NEC -t'''</p>
<p>Old keytable cleared</p>
<p>202.063219: lirc protocol(nec): scancode = 0x45c</p>
<p>202.063249: event type EV_MSC(0x04): scancode = 0x45c</p>
<p>202.063249: event type EV_SYN(0x00).</p>|}</li></ol></li></ol><span id="temperature-sensor"></span>
== Temperature sensor ==
H618 has a total of 4 temperature sensors. The command to view the temperature is as follows:
{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <big>'''The displayed temperature value needs to be divided by 1000, and the unit is Celsius.'''</big>|}
<ol style="list-style-type: lower-alpha;">
<li>sensor0: CPU temperature sensor, the first command is used to view > the type of temperature sensor, the second command is used to view > the value of the temperature sensor</li></ol>{| class="wikitable" style="width:800px;" |-|
orangepi@orangepi:~$ '''cat /sys/class/thermal/thermal_zone0/type'''
'''57734'''
|}</ol>
<ol start="2" style="list-style-type: lower-alpha;">
<li><p>sensor1: DDR temperature sensor, the first command is used to view > the type of temperature sensor, the second command is used to view > the value of the temperature sensor</p>{| class="wikitable" style="width:800px;" |-|
<p>orangepi@orangepi:~$ '''cat /sys/class/thermal/thermal_zone1/type'''</p>
<p>'''ddr'''_thermal_zone</p>
<p>orangepi@orangepi:~$ '''cat /sys/class/thermal/thermal_zone1/temp'''</p>
<p>'''57410'''</p>|}</li><li><p>sensor2: GPU temperature sensor, the first command is used to view > the type of temperature sensor, the second command is used to view > the value of the temperature sensor</p>{| class="wikitable" style="width:800px;" |-|
<p>orangepi@orangepi:~$ '''cat /sys/class/thermal/thermal_zone2/type'''</p>
<p>'''gpu'''_thermal_zone</p>
<p>orangepi@orangepi:~$ '''cat /sys/class/thermal/thermal_zone2/temp'''</p>
<p>'''59273'''</p>|}</li><li><p>sensor3: VE's temperature sensor. The first command is used to view > the type of temperature sensor, and the second command is used to > view the value of the temperature sensor.</p>{| class="wikitable" style="width:800px;" |-|
<p>orangepi@orangepi:~$ '''cat /sys/class/thermal/thermal_zone3/type'''</p>
<p>'''ve'''_thermal_zone</p>
<p>orangepi@orangepi:~$ '''cat /sys/class/thermal/thermal_zone3/temp'''</p>
<p>'''58949'''</p>|}</li></ol>
<span id="how-to-check-the-temperature-in-linux6.1-system"></span>
=== How to check the temperature in linux6.1 system ===
{| class="wikitable" style="width:800px;"
|-
|
orangepi@orangepi:~$ '''sensors'''
Adapter: Virtual device
temp1: +'''<span style="color:#FF0000">47.4°C</span>''' (crit = +110.0°C)
gpu_thermal-virtual-0
Adapter: Virtual device
temp1: +'''<span style="color:#FF0000">48.7°C</span>''' (crit = +110.0°C)
ddr_thermal-virtual-0
Adapter: Virtual device
temp1: +'''<span style="color:#FF0000">47.8°C</span>''' (crit = +110.0°C)
ve_thermal-virtual-0
Adapter: Virtual device
temp1: +'''<span style="color:#FF0000">47.2°C</span>''' (crit = +110.0°C)|}
<span id="pin-interface-pin-description"></span>
== 40 Pin Interface pin description ==
{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <big>'''Note: The pin header on the 40pin interface is not soldered by default, and you need to solder it yourself before it can be used.'''</big>|}
<ol style="list-style-type: decimal;">
</div></li>
<li><p>The functions of the 40 Pin interface pins on the development board are as shown in the table below</p></li></ol>
<div style="display: flex;">{| class="wikitable" style="width:390px;margin-right: 20px;text-align: center;"
|-
| '''GPIO序号GPIO NO.'''
| '''GPIO'''
| '''Function'''
| '''pin'''
|-
| style="text-align: left;"|
| '''3.3V'''
| '''1'''
|-
| '''264'''
| '''TWI1-SDA'''
| '''3'''
|-
| '''263'''
| '''TWI1-SCL'''
| '''5'''
|-
| '''269'''
| '''PWM3/UART4_TX'''
| '''7'''
|-
| style="text-align: left;"|
| '''GND'''
| '''9'''
|-
| '''226'''
| '''UART5_TX'''
| '''11'''
|-
| '''227'''
| '''UART5_RX'''
| '''13'''
|-
| '''261'''
| '''TWI0_SCL/UART2_TX'''
| '''15'''
|-
| style="text-align: left;"|
| '''3.3V'''
| '''17'''
|-
| '''231'''
| '''SPI1_MOSI'''
| '''19'''
| '''PH8'''
| '''SPI1_MISO'''
| '''21'''
|-
| '''230'''
| '''SPI1_CLK'''
| '''23'''
|-
| style="text-align: left;"|
| '''GND'''
| '''25'''
|-
| '''266'''
| '''TWI2-SDA/UART3_RX'''
| '''27'''
|-
| '''256'''
| style="text-align: left;"|
| '''29'''
|-
| '''271'''
| style="text-align: left;"|
| '''31'''
|-
| '''268'''
| '''PWM2'''
| '''33'''
|-
| '''258'''
| style="text-align: left;"|
| '''35'''
|-
| '''272'''
| style="text-align: left;"|
| '''37'''
|-
| style="text-align: left;"|
| '''GND'''
| '''39'''
|}
|-
| style="text-align: left;"|
|-
| '''4'''
| '''5V'''
| style="text-align: left;"|
|-
| '''6'''
| '''GND'''
| style="text-align: left;"|
|-
| '''8'''
| '''UART0_TX'''
| '''224'''
|-
| '''10'''
| '''UART0_RX'''
| '''225'''
|-
| '''12'''
| style="text-align: left;"|
| '''257'''
|-
| '''14'''
| '''GND'''
| style="text-align: left;"|
|-
| '''16'''
| '''PWM4/UART4_RX'''
| '''270'''
|-
| '''18'''
| style="text-align: left;"|
| '''228'''
|-
| '''20'''
| '''GND'''
| style="text-align: left;"|
|-
| '''PI6'''
| '''262'''
|-
| '''24'''
| '''SPI1_CS0'''
| '''229'''
|-
| '''26'''
| '''SPI1_CS1'''
| '''233'''
|-
| '''28'''
| '''TWI2-SCL/UART3_TX'''
| '''265'''
|-
| '''30'''
| '''GND'''
| style="text-align: left;"|
|-
| '''32'''
| '''PWM1'''
| '''267'''
|-
| '''34'''
| '''GND'''
| style="text-align: left;"|
|-
| '''36'''
| style="text-align: left;"|
| '''76'''
|-
| '''38'''
| style="text-align: left;"|
| '''260'''
|-
| '''40'''
| style="text-align: left;"|
| '''259'''
|}
</div>
</ol>
<ol start="3" style="list-style-type: decimal;">
<li>There are a total of 28 GPIO ports in the 40pin interface. The high-level voltage of all GPIO ports is '''<span style="color:#FF0000">3.3v</span>'''</li></ol>
<ol stylespan id="listhow-to-styleinstall-type: decimal;wiringop"><li><p/span>In Linux systems, spi1 is turned off by default and needs == How to be turned on manually before it can be used. The opening steps are as follows:</p>install wiringOP == <ol {| class="wikitable" style="listbackground-style-typecolor:#ffffdc;width: lower-alpha800px;">|-| <libig><p>First run '''orangepiNote that wiringOP is already pre-config'''installed in the linux image released by Orange Pi. Ordinary users remember Unless the wiringOP code is updated, there is no need to add > re-download, compile and install, you can just use it directly.'''sudo ''' permissions.</p><p>orangepi@The storage path of the compiled wiringOP deb package in orangepi-build is:~$ '''sudo orangepi-config '''<span style="color:blue">orangepi-build/p>external/cache/debs/arm64/wiringpi_x.xx.deb</lispan><li><p>Then select '''System '''</p><p>[[File:zero2wAfter entering the system, you can run the gpio readall command. If you can see the following output, it means that wiringOP has been pre-img80installed and can be used normally.png]]</p></li><li><p>Then select '''Hardware'''</pbig><p>[[File:zero2w-img81img170.png|center]]</p></li> <libig><p>Then use the keyboard's arrow keys ''WiringOP currently mainly adapts to locate the position shown > in the figure belowfunctions of setting GPIO port input and output, setting GPIO port output high and low levels, and then use the setting pull-up and pull-down resistors. Functions such as hardware PWM cannot be used.'''space''' to select the > dtbo configuration of the SPI you want to open.</p></li></olbig></li></ol>|}
<ol style="list-style-type: decimal;"><li><p>Download the code of wiringOP</p>{| class="wikitable" style="width:800px;"
|-
| <p>orangepi@orangepi:~$ '''dtbo configurationsudo apt update'''</p>| <p>orangepi@orangepi:~$ '''sudo apt install -y git'''</p><p>orangepi@orangepi:~$ '''illustrategit clone https://github.com/orangepi-xunlong/wiringOP.git -b next'''</p>|}{| class="wikitable" style="background-color:#ffffdc;width:800px;"
|-
| <big><p>'''spi1Note that the source code needs to download the code of wiringOP next branch. Please don't miss the -cs0-cs1-spidevb next parameter.'''</p>| <p>'''Open cs0 and cs1 of spi1 at If there is a problem downloading the code from GitHub, you can directly use the wiringOP source code that comes with the same timeLinux image. The storage location is: /usr/src/wiringOP.'''</p></big>|}</li><li><p>Compile and install wiringOP</p>{| class="wikitable" style="width:800px;"
|-
| '''spi1-cs0-spidev'''| <p>orangepi@orangepi:~$ '''Only open cs0 of spi1cd wiringOP'''</p>|-| <p>orangepi@orangepi:~/wiringOP$ '''spi1-cs1-spidevsudo ./build clean'''</p>| <p>orangepi@orangepi:~/wiringOP$ '''Only open cs1 of spi1sudo ./build'''</p>
|}
</li>
<li><p>The output of the test gpio readall command is as follows</p>
<p>[[File:zero2w-img170.png]]</p></li></ol>
<span id="pin-i2cgpio-port-test"></span>=== 40pin I2C GPIO port test ===
|-
| '''GPIO序号'''| '''GPIO'''| <p>root@orangepi:~/wiringOP# '''Functiongpio mode <span style="color:#FF0000">2</span> out'''</p>| '''pin'''}|</li>| '''<li><p>Then set the GPIO port to output a low level. After setting, you can use a multimeter to measure the voltage value of the pin'''| '''Function'''| '''GPIO'''. If it is 0v, it means the low level is set successfully.</p>{| '''GPIO NO.'''class="wikitable" style="width:800px;"
|-
| <p>root@orangepi:~/wiringOP# '''gpio write 2 <span style="color:#FF0000">0</span>'''</p>|}</li><li><p>Then set the GPIO port to output a high level. After setting, you can use a multimeter to measure the voltage value of the pin. If it is 3.3v, it means the setting of the high level is successful.</p>{| class="wikitable" style="textwidth:800px;" |-| <p>root@orangepi:~/wiringOP# '''gpio write 2 <span style="color:#FF0000">1</span>'''</p>|}</li><li><p>The setting method for other pins is similar. You only need to modify the serial number of wPi to the serial number corresponding to the pin.</p></li></ol> <span id="how-to-set-the-pull-down-resistor-of-40-pin-gpio-port"></span> === How to set the pull-down resistor of 40 Pin GPIO port === <ol style="list-style-type: decimal;"><li><p>The following uses pin No. 7—corresponding to GPIO PI13—corresponding to wPi serial number 2—as an example to demonstrate how to set the pull-up and pull-down resistors of the GPIO port.</p><p>[[File:zero2w-alignimg171.png]]</p></li><li><p>First, you need to set the GPIO port to input mode, and the third parameter needs to be the serial number of the wPi corresponding to the input pin.</p>{| class="wikitable" style="width: left800px;"|-| <p>root@orangepi:~/wiringOP# '''gpio mode <span style="textcolor:#FF0000">2</span> in'''</p>|}</li><li><p>After setting to input mode, execute the following command to set the GPIO port to pull-alignup mode.</p>{| class="wikitable" style="width: left800px;"|-| <p>root@orangepi:~/wiringOP# '''3gpio mode <span style="color:#FF0000">2</span> up'''</p>|}</li><li><p>Then enter the following command to read the level of the GPIO port. If the level is 1, it means that the pull-up mode is set successfully.3V</p>{| class="wikitable" style="width:800px;" |-| <p>root@orangepi:~/wiringOP# '''gpio read <span style="color:#FF0000">2</span>'''</p>| <p>'''<span style="color:#FF0000">1</span>'''</p>|}</li><li><p>Then execute the following command to set the GPIO port to pull-down mode</p>{| class="wikitable" style="width:800px;" |-| <p>root@orangepi:~/wiringOP# '''gpio mode <span style="color:#FF0000">2</span> down'''</p>|}</li><li><p>Then enter the following command to read the level of the GPIO port. If the level is 0, it means that the pull-down mode is set successfully.</p>{| class="wikitable" style="width:800px;" |-| <p>root@orangepi:~/wiringOP# '''gpio read <span style="color:#FF0000">2</span>'''5V</p><p>'''<span style="color:#FF0000">0</span>'''</p>| }</li></ol> <span id="pin-spi-test"></span> === 40pin SPI test === # As can be seen from the table below, the spi available for the 40pin interface is spi1, and there are two chip select pins cs0 and cs1 <div style="text-aligndisplay: leftflex;"|>::{| class="wikitable" style="width:390px;margin-right: 20px;text-align: leftcenter;"|-| '''GPIO NO.'''| '''GPIO'''| '''Function'''| '''pin'''
|-
| style="text-align: left;"|
| style="text-align: left;"|
| '''3.3V'''
| '''1'''
|-
| '''264'''
| '''PI8'''
| '''TWI1-SDA'''
| '''3'''
|-
| '''263'''
| '''TWI1-SCL'''
| '''5'''
| '''269'''
| '''PI13'''
| '''PWM3/UART4_TX'''
| '''7'''
|-
| style="text-align: left;"|
| '''GND'''
| '''9'''
|-
| '''226'''
| '''UART5_TX'''
| '''11'''
|-
| '''227'''
| '''UART5_RX'''
| '''13'''
|-
| '''261'''
| '''TWI0_SCL/UART2_TX'''
| '''15'''
|-
| style="text-align: left;"|
| '''3.3V'''
| '''17'''
|-| '''18<span style="color:#FF0000">231</span>'''| '''<span style="color:#FF0000">PH7</span>'''| '''<span style="color:#FF0000">SPI1_MOSI</span>'''| '''<span style="color:#FF0000">19</span>'''|-| '''<span style="color:#FF0000">232</span>'''| '''<span style="color:#FF0000">PH8</span>'''| '''<span style="color:#FF0000">SPI1_MISO</span>'''| '''<span style="color:#FF0000">21</span>'''|-| '''<span style="color:#FF0000">230</span>'''| '''<span style="color:#FF0000">PH6</span>'''| '''<span style="color:#FF0000">SPI1_CLK</span>'''| '''<span style="color:#FF0000">23</span>'''|-| style="text-align: left;"|
| style="text-align: left;"|
| '''PH4GND'''| '''22825'''|-| '''266'''| '''PI10'''| '''TWI2-SDA/UART3_RX'''| '''27'''
|-
| '''231256'''| '''PH7'''| '''SPI1_MOSI'''| '''19'''|| '''20'''| '''GNDPI0'''
| style="text-align: left;"|
| '''29'''
|-
| '''271'''
| '''PI15'''
| style="text-align: left;"|
| '''31'''
|-
| '''232268'''| '''PH8PI12'''| '''SPI1_MISOPWM2'''| '''2133'''|-| '''22258'''| '''TWI0_SDA/UART2_RXPI2'''| '''PI6'''style="text-align: left;"|| '''26235'''
|-
| '''230272'''| '''PH6PI16'''| '''SPI1_CLK'''| '''23'''|style="text-align: left;"| '''24'''| '''SPI1_CS0'''| '''PH5'''| '''22937'''
|-
| style="text-align: left;"|
| style="text-align: left;"|
| '''GND'''
| '''2539'''|}{| '''26'''| '''SPI1_CS1'''| '''PH9'''| '''233'''class="wikitable" style="width:390px;margin-right: 20px;text-align: center;"
|-
| '''266pin'''| '''PI10Function'''| '''TWI2-SDA/UART3_RXGPIO'''| '''27'''|| '''28'''| '''TWI2-SCL/UART3_TX'''| '''PI9'''| '''265GPIO NO.'''
|-
| '''2562'''| '''PI0'''| style="text-align: left;"|| '''29'''|| '''30'''| '''GND5V'''
| style="text-align: left;"|
| style="text-align: left;"|
|-
| '''2714'''| '''PI155V'''| style="text-align: left;"|
| style="text-align: left;"|
|-
| '''268'''| '''PI12'''| '''PWM2'''| '''33'''|| '''346'''
| '''GND'''
| style="text-align: left;"|
| style="text-align: left;"|
|-
| '''2588'''| '''PI2UART0_TX'''| '''PH0'''| '''224'''|-| '''10'''| '''UART0_RX'''| '''PH1'''| '''225'''|-| '''12'''| style="text-align: left;"|| '''PI1'''| '''257'''|-| '''14'''| '''GND'''
| style="text-align: left;"|
| style="text-align: left;"|
|-
| '''27216'''| '''PI16PWM4/UART4_RX'''| '''PI14'''| '''270'''|-| '''18'''
| style="text-align: left;"|
| '''37'''|| '''38'''| style="text-align: left;"|| '''PI4PH4'''| '''260228'''
|-
| '''20'''
| '''GND'''
| style="text-align: left;"|
| style="text-align: left;"|
|-| '''22'''| '''TWI0_SDA/UART2_RX'''| '''PI6'''| '''262'''|-| '''<span style="color:#FF0000">24</span>'''| '''<span style="color:#FF0000">SPI1_CS0</span>'''| '''<span style="color:#FF0000">PH5</span>'''| '''<span style="color:#FF0000">229</span>'''|-| '''<span style="color:#FF0000">26</span>'''| '''<span style="color:#FF0000">SPI1_CS1</span>'''| '''<span style="color:#FF0000">PH9</span>'''| '''<span style="color:#FF0000">233</span>'''|-| '''28'''| '''TWI2-SCL/UART3_TX'''| '''PI9'''| '''265'''|-| '''30'''| '''GND'''| style="text-align: left;"|| style="text-align: left;"||-| '''32'''| '''PWM1'''| '''PI11'''| '''267'''|-| '''34'''| '''GND'''| style="text-align: left;"|| style="text-align: left;"||-| '''36'''| style="text-align: left;"|| '''PC12'''| '''76'''|-| '''38'''| style="text-align: left;"|| '''PI4'''| '''39260'''|-
| '''40'''
| style="text-align: left;"|
| '''259'''
|}
</div>
<ol start="2" style="list-style-type: decimal;"><li><p>i2c In Linux systems, spi1 is turned off by default in Linux systems and needs to be turned on manually to use before itcan be used. The opening steps are as follows: </p>
<ol style="list-style-type: lower-alpha;">
<li><p>First run '''orangepi-config'''. Ordinary users remember to add > '''sudo''' permissions.</p>{| class="wikitable" style="width:800px;" |-| <p>orangepi@orangepi:~$ '''sudo orangepi-config'''</p>|}</li>
<li><p>Then select '''System'''</p>
<p>[[File:zero2w-img80.png]]</p></li>
<li><p>Then select '''Hardware'''</p>
<p>[[File:zero2w-img81.png]]</p></li>
<li><p>Then use the keyboard's arrow keys to locate the position shown > in the picture figure below, and then use the '''space''' to select the > corresponding i2c dtbo configuration in of the picture belowSPI you want to open.</p></li></ol></li></ol>
{| class="wikitable" style="width:800px;text-align: center;"
|-
| '''Multiplexing function in 40pindtbo configuration'''| '''Corresponding dtbo configurationillustrate'''
|-
| '''40pin spi1- i2c0cs0-cs1-spidev'''| '''pi-i2c0Open cs0 and cs1 of spi1 at the same time'''
|-
| '''40pin spi1- i2c1cs0-spidev'''| '''pi-i2c1Only open cs0 of spi1'''
|-
| '''40pin spi1- i2c2cs1-spidev'''| '''pi-i2c2Only open cs1 of spi1'''
|}
[[File:zero2w-img173img172.png]]</ol>
<ol start="5" style="list-style-type: lower-alpha;">
<li><p>Then select <span class="mark">'''<Save></span> ''' to save</p>
<p>[[File:zero2w-img83.png]]</p></li>
<li><p>Then select '''<Back>'''</p>
<p>[[File:zero2w-img84.png]]</p></li>
<li><p>Then select '''<Reboot>''' to restart the system to make the > configuration take effect.</p>
<p>[[File:zero2w-img85.png]]</p></li></ol>
</li></ol>
<ol start="2" style="list-style-type: decimal;">
<li><p>Then check whether there is a '''spidev1.x''' device node in the Linux system. If it exists, it means that the SPI1 configuration has taken effect.</p>
{| class="wikitable" style="width:800px;"
|-
|
<p>orangepi@orangepi:~$ '''ls /dev/spidev1*'''</p>
<p>/dev/spidev1.0 /dev/spidev1.1</p>
|}
{| class="wikitable" style="background-color:#ffffdc;width:800px;"
|-
|
<big><p>'''Note that only when you open spi1-cs0-cs1-spidev, you will see the device nodes of the two spi.'''</p></big>
|}
</li>
<li><p>Next, start the spi loopback test. Do not short-circuit the mosi and miso pins of SPI1 first. The output result of running spidev_test is as follows. You can see that the data of TX and RX are inconsistent.</p>
{| class="wikitable" style="width:800px;"
|-
|
<p>orangepi@orangepi:~$ '''sudo spidev_test -v -D /dev/spidev1.0'''</p>
<p>spi mode: 0x0</p>
<p>bits per word: 8</p>
<p>max speed: 500000 Hz (500 KHz)</p>
<p>TX | FF FF FF FF FF FF '''<span style="color:#FF0000">40 00 00 00 00 95</span>''' FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF F0 0D | ......@.…▒..................▒.</p>
<p>RX | FF FF FF FF FF FF '''<span style="color:#FF0000">FF FF FF FF FF FF</span>''' FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF | ............................….</p>
|}
</li>
<li><p>Then short-circuit the two pins of SPI1 mosi (pin 19 in the 40pin interface) and miso (pin 21 in the 40pin interface) and then run spidev_test. The output is as follows. You can see the sending and receiving The data is the same, indicating that the loopback test passed.</p>
{| class="wikitable" style="width:800px;"
|-
|
<p>orangepi@orangepi:~$ '''sudo spidev_test -v -D /dev/spidev1.0'''</p>
<p>spi mode: 0x0</p>
<p>bits per word: 8</p>
<p>max speed: 500000 Hz (500 KHz)</p>
<p>TX | FF FF FF FF FF FF '''<span style="color:#FF0000">40 00 00 00 00 95</span>''' FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF F0 0D | ......@.…▒..................▒.</p>
<p>RX | FF FF FF FF FF FF '''<span style="color:#FF0000">40 00 00 00 00 95</span>''' FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF F0 0D | ......@.…▒..................▒.</p>
|}
</li></ol>
<span id="pin-i2c-test"></span>
<!-- --><ol start="4" div style="list-style-typedisplay: decimalflex;"><li><p>Then start testing i2c, first install i2c-tools</p><p>orangepi@orangepi:~$ '''sudo apt-get update'''</p><p>orangepi@orangepi:~$ '''sudo apt-get install -y i2c-tools'''</p></li><li><p>Then connect an i2c device to the i2c pin of the 40pin connector</p></li><li><p>Then use the '''i2cdetect -y x''' x command. If the address of the connected i2c device can be detected, it means that i2c can be used normally.</p><p>'''Note that x in the i2cdetect -y x command needs to be replaced with the serial number of the device node corresponding to the i2c bus.'''</p><p>'''Different i2c device addresses are different. The 0x50 address in the picture below is just an example. Please refer to what you actually see.'''</p><div {| class="figurewikitable"> [[File:zero2w-img174.png]] </div></li></ol> <span idstyle="pinwidth:390px;margin-uartright: 20px;text-test"></span>=== 40pin UART test === # As can be seen from the table below, the available uarts are uart2, uart3, uart4 and uart5. Please note that uart0 is set as a debugging serial port by default. Please do not use uart0 as a normal serial port. {| class="wikitablealign: center;"
|-
| '''GPIO NO.'''
| '''Function'''
| '''pin'''
|-
| style="text-align: left;"|
| '''3.3V'''
| '''1'''
|-
| '''<span style="color:#FF0000">264</span>'''| '''<span style="color:#FF0000">PI8</span>'''| '''<span style="color:#FF0000">TWI1-SDA</span>'''| '''3'''|| '''4'''| '''5V'''| <span style="text-aligncolor: left;#FF0000"|| style="text-align: left;"|>3</span>'''
|-
| '''<span style="color:#FF0000">263</span>'''| '''PI7<span style="color:#FF0000">v</span>'''| '''<span style="color:#FF0000">TWI1-SCL</span>'''| '''5'''|| '''6'''| '''GND'''| <span style="text-aligncolor: left;#FF0000"|| style="text-align: left;"|>5</span>'''
|-
| '''269'''
| '''PWM3/UART4_TX'''
| '''7'''
|-
| style="text-align: left;"|
| '''GND'''
| '''9'''
| '''226'''
| '''PH2'''
| '''UART5_TX'''
| '''11'''
|-
| '''227'''
| '''UART5_RX'''
| '''13'''
|-
| '''<span style="color:#FF0000">261</span>'''| '''<span style="color:#FF0000">PI5</span>'''| '''<span style="color:#FF0000">TWI0_SCL</span>/UART2_TX'''| '''<span style="color:#FF0000">15'''|| '''16'''| '''PWM4</UART4_RX'''| '''PI14'''| '''270span>'''
|-
| style="text-align: left;"|
| '''3.3V'''
| '''17'''
|-
| '''231'''
| '''SPI1_MOSI'''
| '''19'''
|-
| '''232'''
| '''SPI1_MISO'''
| '''21'''
|-
| '''230'''
| '''SPI1_CLK'''
| '''23'''
|-
| style="text-align: left;"|
| '''GND'''
| '''25'''
|-
| '''<span style="color:#FF0000">266</span>'''| '''<span style="color:#FF0000">PI10</span>'''| '''<span style="color:#FF0000">TWI2-SDA</span>/UART3_RX'''| '''<span style="color:#FF0000">27'''|| '''28'''| '''TWI2-SCL</UART3_TX'''| '''PI9'''| '''265span>'''
|-
| '''256'''
| style="text-align: left;"|
| '''29'''
| '''271'''
| '''PI15'''
| style="text-align: left;"|
| '''31'''
|-
| '''268'''
| '''PWM2'''
| '''33'''
|-
| '''258'''
| style="text-align: left;"|
| '''35'''
|-
| '''272'''
| style="text-align: left;"|
| '''37'''
|-
| style="text-align: left;"|
| '''GND'''
| '''39'''
|}
|-
| '''Multiplexing function in 40pinpin'''| '''Corresponding dtbo configurationFunction'''| '''GPIO'''| '''GPIO NO.'''
|-
| '''40pin - uart22'''| '''pi-uart25V'''| style="text-align: left;"|| style="text-align: left;"|
|-
| '''40pin - uart34'''| '''pi-uart35V'''| style="text-align: left;"|| style="text-align: left;"|
|-
| '''40pin - uart46'''| '''pi-uart4GND'''| style="text-align: left;"|| style="text-align: left;"|
|-
| '''40pin - uart58'''| '''ph-uart5UART0_TX'''|} [[File:zero2w-img175.png]] <ol start="5" style="list-style-type: lower-alpha;"><li><p>Then select '''<Save>PH0''' to save</p><p>[[File:zero2w-img83.png]]</p></li><li><p>Then select '''<Back>'''</p><p>[[File:zero2w-img84.png]]</p></li><li><p>Then select '''<Reboot>''' to restart the system to make the > configuration take effect.</p><p>[[File:zero2w-img85.png]]</p></li></ol> <!-- --><ol start="3" style="list-style-type: decimal;"><li><p>After entering the Linux system, first confirm whether there is a uart5 device node under '''/dev'''</p><p>'''Note that the linux5.4 system is /dev/ttyASx.'''</p><p>orangepi@orangepi:~$ '''ls /dev/ttyS*'| ''</p><p>/dev/ttySx</p></li><li><p>Then start testing the uart interface. First use Dupont wire to short-circuit the rx and tx pins of the uart interface to be tested.</p></li><li><p>Use the '224''gpio''' command in wiringOP to test the loopback function of the serial port as shown below. If you can see the following print, it means the serial port communication is normal.</p><p>'''Note that the last x in the gpio serial /dev/ttySx command needs to be replaced with the serial number of the corresponding uart device node.'''</p><p>orangepi@orangepi:~$ '''gpio serial /dev/ttySx # linux-6.1 test command'''</p><p>orangepi@orangepi:~$ '''gpio serial /dev/ttyASx # linux-5.4 test command'''</p><p>Out: 0: -> 0</p><p>Out: 1: -> 1</p><p>Out: 2: -> 2</p><p>Out: 3: -> 3^C</p></li></ol> <span id="pwm-test-method"></span>=== PWM test method === # As can be seen from the following table, the available pwm are pwm1, pwm2, pwm3 and pwm4. {| class="wikitable"
|-
| '''GPIO NO.10'''| '''GPIOUART0_RX'''| '''FunctionPH1'''| '''Pin'''|| '''Pin'''| '''Function'''| '''GPIO'''| '''GPIO NO.225'''
|-
| '''12'''
| style="text-align: left;"|
| '''PI1'''
| '''257'''
|-
| '''14'''
| '''GND'''
| style="text-align: left;"|
| style="text-align: left;"|
|-
| '''16'''
| '''PWM4/UART4_RX'''
| '''PI14'''
| '''270'''
|-
| '''18'''
| style="text-align: left;"|
| '''PH4'''
| '''228'''
|-
| '''26420'''| '''PI8'''| '''TWI1-SDA'''| '''3'''|| '''4'''| '''5VGND'''
| style="text-align: left;"|
| style="text-align: left;"|
|-
| '''263<span style="color:#FF0000">22</span>'''| '''PI7<span style="color:#FF0000">TWI0_SDA</span>/UART2_RX'''| '''TWI1<span style="color:#FF0000">PI6</span>'''| '''<span style="color:#FF0000">262</span>'''|-| '''24'''| '''SPI1_CS0'''| '''PH5'''| '''229'''|-| '''26'''| '''SPI1_CS1'''| '''PH9'''| '''233'''|-| '''<span style="color:#FF0000">28</span>'''| '''<span style="color:#FF0000">TWI2-SCL</span>/UART3_TX'''| '''5<span style="color:#FF0000">PI9</span>'''|'''<span style="color:#FF0000">265</span>'''|-| '''630'''
| '''GND'''
| style="text-align: left;"|
| style="text-align: left;"|
|-
| '''26932'''| '''PI13PWM1'''| '''PWM3/UART4_TXPI11'''| '''7'''|| '''8'''| '''UART0_TX'''| '''PH0'''| '''224267'''
|-
| '''34'''
| '''GND'''
| style="text-align: left;"|
| style="text-align: left;"|
|-
| '''226'''| '''PH2'''| '''UART5_TX'''| '''11'''|| '''1236'''
| style="text-align: left;"|
| '''PI1PC12'''| '''25776'''
|-
| '''227'''| '''PH3'''| '''UART5_RX'''| '''13'''|| '''14'''| '''GND38'''
| style="text-align: left;"|
| '''PI4'''
| '''260'''
|-
| '''40'''
| style="text-align: left;"|
| '''PI3'''
| '''259'''
|}
</div>
<ol start="2" style="list-style-type: decimal;">
<li><p>i2c is turned off by default in Linux systems and needs to be turned on manually to use it. The opening steps are as follows: </p>
<ol style="list-style-type: lower-alpha;">
<li><p>First run '''orangepi-config'''. Ordinary users remember to add '''sudo''' permissions.</p>
{| class="wikitable" style="width:800px;"
|-
| <p>orangepi@orangepi:~$ '''261sudo orangepi-config'''</p>| }</li><li><p>Then select '''PI5System'''</p>| '''TWI0_SCL<p>[[File:zero2w-img80.png]]</p></UART2_TX'''li>| <li><p>Then select '''15Hardware'''</p>|<p>[[File:zero2w-img81.png]]</p></li>| <li><p>Then use the keyboard's arrow keys to locate the position shown in the picture below, and then use the ''16'space''| '''PWM4to select the corresponding i2c configuration in the picture below.</p></UART4_RX'''li>| '''PI14'''{| '''270'''class="wikitable" style="width:800px;text-align: center;"
|-
|-
| '''23140pin - i2c0'''| '''PH7pi-i2c0'''| '''SPI1_MOSI'''-| '''1940pin - i2c1'''|| '''20pi-i2c1'''| '''GND'''| style="text-align: left;"|| style="text-align: left;"|
|-
| '''23240pin - i2c2'''| '''PH8pi-i2c2'''| '''SPI1_MISO'''} [[File:zero2w-img173.png]]</ol><ol start="5" style="list-style-type: lower-alpha;"><li><p>Then select <span class="mark"><Save></span> to save</p><p>[[File:zero2w-img83.png]]</p></li>| <li><p>Then select '''21<Back>'''</p>|<p>[[File:zero2w-img84.png]]</p></li>| <li><p>Then select '''22<Reboot>'''to restart the system to make the configuration take effect.</p><p>[[File:zero2w-img85.png]]</p></li></ol>| '''TWI0_SDA</li></UART2_RX'''ol><ol start="3" style="list-style-type: decimal;">| '''PI6'''<li><p>After starting the Linux system, first confirm that there is an open i2c device node under /dev</p>{| '''262'''class="wikitable" style="width:800px;"
|-
|-
| <big><p>'''Sometimes the i2c device node and the i2c bus serial number do not correspond one to one. For example, the i2c device node of the i2c1 bus may be /dev/i2c-3.'''</p><p>'''The method to accurately confirm the device node under /dev corresponding to the i2c bus is: '''</p></big> <ol style="textlist-style-aligntype: leftlower-alpha;"><li><p>'''First run the following command to check the corresponding relationship of i2c'''</p><p>orangepi@orangepizero2w:~$ '''ls /sys/devices/platform/soc*/*/i2c-* |grep "i2c-[0-9]"'''</p><p>/sys/devices/platform/soc/5002000.i2c/i2c-0:</p><p>/sys/devices/platform/soc/5002400.i2c/i2c-3:</p><p>/sys/devices/platform/soc/5002800.i2c/i2c-4:</p><p>/sys/devices/platform/soc/5002c00.i2c/i2c-5:</p><p>/sys/devices/platform/soc/6000000.hdmi/i2c-2:</p><p>/sys/devices/platform/soc/7081400.i2c/i2c-1:</p></li> <li><p>'''In the above output'''</p><ol style="list-style-type: none;"><li><p>a) 5002000 is the register base address of the i2c0 bus, and i2c-0 shown behind it is its corresponding i2c device node</p></li><li><p>b) 5002400 is the register base address of the i2c1 bus, and i2c-3 shown behind it is its corresponding i2c device node</p></li><li><p>c) 5002800 is the register base address of the i2c2 bus, and i2c-4 shown behind it is its corresponding i2c device node</p></li></ol></li></ol>| }</li></ol><ol start="4" style="textlist-style-type: decimal;"><li><p>Then start testing i2c, first install i2c-aligntools</p>{| class="wikitable" style="width: left800px;"|-| <p>orangepi@orangepi:~$ '''GNDsudo apt-get update'''</p>| <p>orangepi@orangepi:~$ '''25sudo apt-get install -y i2c-tools'''</p>|}| </li><li><p>Then connect an i2c device to the i2c pin of the 40pin connector</p></li><li><p>Then use the '''26i2cdetect -y x'''x command. If the address of the connected i2c device can be detected, it means that i2c can be used normally.</p>{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <big><p>'''SPI1_CS1Note that x in the i2cdetect -y x command needs to be replaced with the serial number of the device node corresponding to the i2c bus.'''</p>| <p>'''PH9Different i2c device addresses are different. The 0x50 address in the picture below is just an example. Please refer to what you actually see.'''</p></big>| '''233'''}<div class="figure"> [[File:zero2w-img174.png]] </div></li></ol> <span id="pin-uart-test"></span> === 40pin UART test === # As can be seen from the table below, the available uarts are uart2, uart3, uart4 and uart5. Please note that uart0 is set as a debugging serial port by default. Please do not use uart0 as a normal serial port. <div style="display: flex;">::{| class="wikitable" style="width:390px;margin-right: 20px;text-align: center;"
|-
| '''266GPIO NO.'''| '''PI10GPIO'''| '''TWI2-SDA/UART3_RXFunction'''| '''27'''|| '''28'''| '''TWI2-SCL/UART3_TX'''| '''PI9'''| '''265pin'''
|-
| style="text-align: left;"|
| style="text-align: left;"|
| '''3.3V'''
| '''1'''
|-
| '''264'''
| '''PI8'''
| '''TWI1-SDA'''
| '''3'''
|-
| '''271263'''| '''PI15PI7'''| style="text-align: left;"|| '''31'''|| '''32'''| '''PWM1'''| '''PI11TWI1-SCL'''| '''2675'''
|-
| '''268269'''| '''PI12PI13'''| '''PWM2PWM3/UART4_TX'''| '''337'''|| '''34'''| '''GND'''| style="text-align: left;"|| style="text-align: left;"|
|-
| style="text-align: left;"|
| style="text-align: left;"|
| '''PC12GND'''| '''769'''
|-
| '''272226'''| '''PI16PH2'''| style="text-align: left;"|| '''37'''|| '''38'''| style="text-align: left;"|| '''PI4UART5_TX'''| '''26011'''
|-
| '''227'''| '''PH3'''| '''UART5_RX'''| '''13'''|-| '''261'''| '''PI5'''| '''TWI0_SCL/UART2_TX'''| '''15'''|-| style="text-align: left;"|| style="text-align: left;"|| '''3.3V'''| '''17'''|-| '''231'''| '''PH7'''| '''SPI1_MOSI'''| '''19'''|-| '''232'''| '''PH8'''| '''SPI1_MISO'''| '''21'''|-| '''230'''| '''PH6'''| '''SPI1_CLK'''| '''23'''|-| style="text-align: left;"|| style="text-align: left;"|
| '''GND'''
| '''3925'''|-| '''40266'''| '''PI10'''| '''TWI2-SDA/UART3_RX'''| '''27'''|-| '''256'''| '''PI0'''| style="text-align: left;"|| '''29'''|-| '''271'''| '''PI15'''
| style="text-align: left;"|
| '''PI331'''|-| '''268'''| '''PI12'''| '''PWM2'''| '''25933'''|}-| '''258'''| '''PI2'''<ol start| style="2text-align: left;" || '''35'''|-| '''272'''| '''PI16'''| style="listtext-style-typealign: decimalleft;">|| '''37'''<li><p>pwm is turned off by default in Linux systems and needs to be turned on manually to use it. The opening steps are as follows:</p>|-<ol | style="listtext-align: left;"|| style="text-typealign: lower-alphaleft;">|<li><p>First run | '''orangepi-configGND'''. Ordinary users remember to add > | '''sudo39''' permissions.</p><p>orangepi@orangepi|}{| class="wikitable" style="width:390px;margin-right: 20px;text-align:~$ center;"|-| '''sudo orangepi-configpin'''</p></li><li><p>Then select | '''SystemFunction'''</p><p>[[File:zero2w-img80.png]]</p></li>| '''GPIO'''<li><p>Then select | '''HardwareGPIO NO.'''</p><p>[[File:zero2w|-img81.png]]</p></li><li><p>Then use the keyboard| '''2'''s arrow keys to locate the position shown > in the figure below, and then use the | '''space5V''' to select the >| style="text-align: left; configuration corresponding to the pwm you want to open.</p>"|<p>[[File| style="text-align:zero2wleft;"||-img176.png]]</p></li><li><p>Then select | '''<Save>4''' to save</p><p>[[File:zero2w-img83.png]]</p></li><li><p>Then select | '''<Back>5V'''</p><p>[[File| style="text-align: left;"|| style="text-align:zero2wleft;"||-img84.png]]</p></li><li><p>Then select | '''<Reboot>6''' to restart the system to make the > configuration take effect.</p><p>[[File:zero2w-img85.png]]</p></li></ol></li><li><p>After restarting, you can start the PWM test</p><p>| '''Please execute the following commands under the root user.GND'''</p><ol | style="listtext-align: left;"|| style="text-typealign: lower-alphaleft;">|<li><p>Enter the following command on the command line to make pwm1 > output a 50Hz square wave</p>|-<p>root@orangepi:~# | '''echo 1 > /sys/class/pwm/pwmchip0/export8'''</p><p>root@orangepi:~# | '''echo 20000000 > /sys/class/pwm/pwmchip0/pwm1/periodUART0_TX'''</p><p>root@orangepi:~# | '''echo 1000000 > /sys/class/pwm/pwmchip0/pwm1/duty_cyclePH0'''</p><p>root@orangepi:~# | '''echo 1 > /sys/class/pwm/pwmchip0/pwm1/enable224'''</p></li><li><p>Enter the following command on the command line to make pwm2 > output a 50Hz square wave</p></li></ol>|-</li></ol>| '''10''' root@orangepi:~# | '''echo 2 > /sys/class/pwm/pwmchip0/exportUART0_RX''' root@orangepi:~# | '''echo 20000000 > /sys/class/pwm/pwmchip0/pwm2/periodPH1''' root@orangepi:~# | '''echo 1000000 > /sys/class/pwm/pwmchip0/pwm2/duty_cycle225'''|-root@orangepi:~# | '''echo 1 > /sys/class/pwm/pwmchip0/pwm2/enable12''' <ol start="3" | style="listtext-style-typealign: lower-alphaleft;">|<li>Enter the following command on the command line to make pwm3 output > a 50Hz square wave</li></ol> root@orangepi:~# | '''echo 3 > /sys/class/pwm/pwmchip0/exportPI1''' root@orangepi:~# | '''echo 20000000 > /sys/class/pwm/pwmchip0/pwm3/period257'''|-root@orangepi:~# | '''echo 1000000 > /sys/class/pwm/pwmchip0/pwm3/duty_cycle14''' root@orangepi:~# | '''echo 1 > /sys/class/pwm/pwmchip0/pwm3/enableGND''' <ol start| style="4text-align: left;" || style="list-styletext-typealign: lower-alphaleft;">|<li>Enter the following command on the command line to make pwm4 output > a 50Hz square wave</li></ol>|- root@orangepi:~# | '''echo 4 > /sys/class/pwm/pwmchip0/export16''' root@orangepi:~# | '''echo 20000000 > /sys/class/pwm/pwmchip0/pwm4PWM4/periodUART4_RX''' root@orangepi:~# | '''echo 1000000 > /sys/class/pwm/pwmchip0/pwm4/duty_cyclePI14''' root@orangepi:~# | '''echo 1 > /sys/class/pwm/pwmchip0/pwm4/enable270''' <div class="figure"> [[File:zero2w|-img177.png]]| '''18'''</div><span id| style="howtext-to-install-and-use-wiringop-pythonalign: left;"></span>== How to install and use wiringOP-Python ==|| '''PH4'''| '''Note: The pin header on the 40pin interface is not soldered by default, and you need to solder it yourself before it can be used.228'''|-| '''wiringOP-Python is the Python language version of wiringOP library, used to operate the development board's GPIO, I2C, SPI, UART and other hardware resources in the Python program20''' | '''Also please note that all the following commands are operated under the root user.GND''' <span id| style="howtext-to-install-wiringop-pythonalign: left;"></span>|=== How to install wiringOP-Python === <ol | style="list-styletext-typealign: decimalleft;">||-| '''22'''<li><p>First install dependency packages<| '''TWI0_SDA/p>UART2_RX'''<p>root@orangepi:~# | '''sudo apt-get updatePI6'''</p><p>root@orangepi:~# | '''sudo apt-get -y install git swig python3-dev python3-setuptools262'''</p></li><li><p>Then use the following command to download the source code of wiringOP|-Python</p></li></ol>| '''24'''| '''SPI1_CS0'''| '''Note that the following git clone--recursive command will automatically download the source code of wiringOP, because wiringOP-Python depends on wiringOP. Please make sure there are no errors during the download process due to network problems.PH5'''| '''229'''If there is a problem downloading the code from GitHub, you can directly use the wiringOP|-Python source code that comes with the Linux image. The storage location is: | '''26'''| '''/usr/src/wiringOP-PythonSPI1_CS1'''| '''PH9'''root@orangepi:~# | '''233'''git clone |-| '''28'''| '''TWI2-recursive https://github.com/orangepi-xunlongSCL/wiringOP-Python -b nextUART3_TX'''| '''PI9'''root@orangepi:~# | '''cd wiringOP-Python265'''|-root@orangepi:~/wiringOP-Python# | '''git submodule update --init --remote30'''| '''GND'''<ol start| style="3text-align: left;" || style="list-styletext-typealign: decimalleft;">|<li><p>Then use the following command to compile wiringOP|-Python and install it into the Linux system of the development board</p><p>root@orangepi:~# | '''32'''| '''cd wiringOP-PythonPWM1'''</p><p>root@orangepi:~/wiringOP-Python# | '''python3 generate-bindings.py > bindings.iPI11'''</p><p>root@orangepi:~/wiringOP-Python# | '''sudo python3 setup.py install267'''</p></li><li><p>Then enter the following command. If helpful information is output, it means wiringOP|-Python is successfully installed. Press the | '''q34''' key to exit the help information interface.</p></li></ol> root@orangepi:~/wiringOP-Python# | '''python3 -c "import wiringpi; help(wiringpi)"GND'''| style="text-align: left;"|Help on module wiringpi| style="text-align:left;"||-NAME| '''36'''| style="text-align: left;"|wiringpi| '''PC12'''| '''76'''DESCRIPTION|-| '''38'''# This file was automatically generated by SWIG (http| style="text-align://www.swig.org).left;"|| '''PI4'''| '''260'''# Version 4.0.2|-| '''40'''#| style="text-align: left;"|| '''PI3'''# Do not make changes to this file unless you know what you are doing--modify| '''259'''|}# the SWIG interface file instead.</div> <ol start="52" style="list-style-type: decimal;"><li><p>In Linux systems, uart is turned off by default and needs to be turned on manually before it can be used. The opening steps to test whether wiringOP-Python is installed successfully under the python command line are as follows:</p>
<ol style="list-style-type: lower-alpha;">
<li><p>First use the python3 command run '''orangepi-config'''. Ordinary users remember to enter the command line mode of >add '''sudo''' permissions.</p>{| class="wikitable" style="width:800px; python3" |-| <p>orangepi@orangepi:~$ '''sudo orangepi-config'''</p>|}</li><li><p>Then select '''System'''</olp><p>[[File:zero2w-img80.png]]</p></li><li><p>Then select '''Hardware'''</p><p>[[File:zero2w-img81.png]]</p></li><li><p>Then use the keyboard's arrow keys to locate the position shown in the picture below, and then use the '''space''' to select the serial port you want to open.</p></olli>
[[File:zero2w-img175.png]]</ol><ol start="5" style="list-style-type: lower-alpha;"><li><p>Then select '''<Save>''' to save</p><p>[[File:zero2w-img83.png]]</p></li><li><p>Then select '''<Back>'''</p><p>[[File:zero2w-img84.png]]</p></li><li><p>Then select '''<Reboot> '''help(wiringpi)to restart the system to make the configuration take effect.</p><p>[[File:zero2w-img85.png]]</p></li></ol></li></ol><!-- --><ol start="3" style="list-style-type: decimal;"><li><p>After entering the Linux system, first confirm whether there is a uart5 device node under '''/dev'''</p>{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <big><p>'''Note that the linux5.4 system is /dev/ttyASx.'''</p></big>|}{| class="wikitable" style="width:800px;" |-| <p>orangepi@orangepi:~$ '''ls /dev/ttyS*'''</p><p>/dev/ttySx</p>|}</li><li><p>Then start testing the uart interface. First use Dupont wire to short-circuit the rx and tx pins of the uart interface to be tested.</p></li><li><p>Use the '''gpio''' command in wiringOP to test the loopback function of the serial port as shown below. If you can see the following print, it means the serial port communication is normal.</p>{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <big><p>'''Note that the last x in the gpio serial /dev/ttySx command needs to be replaced with the serial number of the corresponding uart device node.'''</p></big>|}{| class="wikitable" style="width:800px;" |-| <p>orangepi@orangepi:~$ '''gpio serial /dev/ttySx # linux-6.1 test command'''</p><p>orangepi@orangepi:~$ '''gpio serial /dev/ttyASx # linux-5.4 test command'''</p>
# This file was automatically generated by SWIG (http://www.swig.org)As can be seen from the following table, the available pwm are pwm1, pwm2, pwm3 and pwm4.
| '''GPIO'''
| '''Function'''
| '''Pin'''
|-
| style="text-align: left;"|
| '''3.3V'''
| '''1'''
| '''PI8'''
| '''TWI1-SDA'''
| '''3'''
|-
| '''263'''
| '''TWI1-SCL'''
| '''5'''
|-
| '''<span style="color:#FF0000">269</span>'''| '''<span style="color:#FF0000">PI13</span>'''| '''<span style="color:#FF0000">PWM3</span>/UART4_TX'''| '''<span style="color:#FF0000">7'''|| '''8'''| '''UART0_TX'''| '''PH0'''| '''224</span>'''
|-
| style="text-align: left;"|
| '''GND'''
| '''9'''
|-
| '''226'''
| '''UART5_TX'''
| '''11'''
|-
| '''227'''
| '''UART5_RX'''
| '''13'''
|-
| '''261'''
| '''TWI0_SCL/UART2_TX'''
| '''15'''
|-
| style="text-align: left;"|
| '''3.3V'''
| '''17'''
|-
| '''231'''
| '''SPI1_MOSI'''
| '''19'''
|-
| '''232'''
| '''SPI1_MISO'''
| '''21'''
|-
| '''230'''
| '''SPI1_CLK'''
| '''23'''
| style="text-align: left;"|
| style="text-align: left;"|
| '''GND'''
| '''25'''
|-
| '''266'''
| '''TWI2-SDA/UART3_RX'''
| '''27'''
|-
| '''256'''
| style="text-align: left;"|
| '''29'''
|-
| '''271'''
| style="text-align: left;"|
| '''31'''
|-
| '''<span style="color:#FF0000">268</span>'''| '''<span style="color:#FF0000">PI12</span>'''| '''<span style="color:#FF0000">PWM2</span>'''| '''33'''|| '''34'''| '''GND'''| <span style="text-aligncolor: left;#FF0000"|| style="text-align: left;"|>33</span>'''
|-
| '''258'''
| style="text-align: left;"|
| '''35'''
|-
| '''272'''
| style="text-align: left;"|
| '''37'''
|-
| style="text-align: left;"|
| '''GND'''
| '''39'''
|}
|-
| '''dtbo configurationPin'''| '''illustrateFunction'''| '''GPIO'''| '''GPIO NO.'''|-| '''2'''| '''5V'''| style="text-align: left;"|| style="text-align: left;"||-| '''4'''| '''5V'''| style="text-align: left;"|| style="text-align: left;"||-| '''6'''| '''GND'''| style="text-align: left;"|| style="text-align: left;"||-| '''8'''| '''UART0_TX'''| '''PH0'''| '''224'''
|-
| '''spi1-cs0-cs1-spidev10'''| '''Open cs0 and cs1 of spi1 at the same timeUART0_RX'''| '''PH1'''| '''225'''
|-
| '''spi112'''| style="text-cs0-spidevalign: left;"|| '''PI1'''| '''Only open cs0 of spi1257'''
|-
| '''spi1-cs1-spidev14'''| '''Only open cs1 of spi1GND'''|} <ol start="5" style="listtext-style-typealign: lower-alphaleft;"><li><p>Then select '''<Save>''' to save</p><p>[[File:zero2w-img83.png]]</p></li><li><p>Then select '''<Back>'''</p><p>[[File:zero2w-img84.png]]</p></li><li><p>Then select '''<Reboot>''' to restart the system to make the > configuration take effect.</p><p>[[File:zero2w-img85.png]]</p></li></ol> <!-- --><ol start="3" style="list-style-type: decimal;"><li><p>Then check whether there is a '''spidev1.x''' device node in the Linux system. If it exists, it means that the SPI1 configuration has taken effect.</p><p>orangepi@orangepi:~$ '''ls /dev/spidev1*'''</p><p>/dev/spidev1.0 /dev/spidev1.1</p><p>'''Note that only when you open spi1-cs0-cs1-spidev, you will see the device nodes of the two spi.'''</p></li><li><p>Then you can use the '''spidev_test.py''' program in examples to test the SPI loopback function. The '''spidev_test.py''' program needs to specify the following two parameters:</p><ol style="list-style-type: lower-alpha;"><li><p>'''--channel''': Specify the channel number of SPI</p></li><li><p>'''--port''': Specify the port number of the SPI</p></li></ol></li><li><p>Without shorting the mosi and miso pins of SPI1, the output result of running spidev_test.py is as follows. You can see that the data of TX and RX are inconsistent.</p><p>root@orangepi:~/wiringOP-Python# '''cd examples'''</p></li></ol> root@orangepi:~/wiringOP-Python/examples# '''python3 spidev_test.py \''' '''--channel 1 --port 0''' spi mode: 0x0 max speed: 500000 Hz (500 KHz) Opening device /dev/spidev1.1 TX | FF FF FF FF FF FF '''40 00 00 00 00 95''' FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF F0 0D |......@.......…| RX | FF FF FF FF FF FF '''FF FF FF FF FF FF''' FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF |.............….| <ol start="6" style="listtext-style-typealign: decimalleft;"><li><p>Then use Dupont wire to short-circuit the txd (pin 19 in the 40pin interface) and rxd (pin 21 in the 40pin interface) of SPI1 and then run spidev_test.py. The output is as follows, you can see If the data sent and received are the same, it means that the SPI1 loopback test is normal.</p><p>root@orangepi:~/wiringOP-Python# '''cd examples'''</p></li></ol> root@orangepi:~/wiringOP-Python/examples# '''python3 spidev_test.py \''' '''--channel 1 --port 0''' spi mode: 0x0 max speed: 500000 Hz (500 KHz) Opening device /dev/spidev1.1 TX | FF FF FF FF FF FF '''40 00 00 00 00 95''' FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF F0 0D |......@.......…| RX | FF FF FF FF FF FF '''40 00 00 00 00 95''' FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF F0 0D |......@.......…| <span id="pin-i2c-test-1"></span>=== 40pin I2C test === # As can be seen from the table below, the i2c available for the 40pin interface are i2c0, i2c1 and i2c2 {| class="wikitable"
|-
| '''GPIO NO.<span style="color:#FF0000">16</span>'''| '''GPIO<span style="color:#FF0000">PWM4</span>/UART4_RX'''| '''Function<span style="color:#FF0000">PI14</span>'''| '''Pin'''|| '''Pin'''| '''Function'''| '''GPIO'''| '''GPIO NO.<span style="color:#FF0000">270</span>'''
|-
| '''18'''
| style="text-align: left;"|
| style="text-align: left;"|
| style="text-align: left;"|
|-
| '''26422'''| '''PI8TWI0_SDA/UART2_RX'''| '''TWI1PI6'''| '''262'''|-SDA| '''24'''| '''SPI1_CS0'''| '''PH5'''| '''3229'''|-| '''426'''| '''5VSPI1_CS1'''| '''PH9'''| '''233'''| style="text-align: left;"|'''28'''| style="text'''TWI2-align: left;"SCL/UART3_TX'''|'''PI9'''| '''265'''
|-
| '''263'''| '''PI7'''| '''TWI1-SCL'''| '''5'''|| '''630'''
| '''GND'''
| style="text-align: left;"|
| style="text-align: left;"|
|-
| '''269<span style="color:#FF0000">32</span>'''| '''PI13<span style="color:#FF0000">PWM1</span>'''| '''PWM3<span style="color:#FF0000">PI11</UART4_TXspan>'''| '''7'''|| '''8'''| '''UART0_TX'''| '''PH0'''| '''224<span style="color:#FF0000">267</span>'''
|-
| '''34'''
| '''GND'''
| style="text-align: left;"|
| style="text-align: left;"|
|-
| '''226'''| '''PH2'''| '''UART5_TX'''| '''11'''|| '''1236'''
| style="text-align: left;"|
| '''PI1PC12'''| '''25776'''
|-
| '''22738'''| '''PH3'''style="text-align: left;"|| '''UART5_RXPI4'''| '''13260'''|-| '''1440'''| '''GND'''| style="text-align: left;"|
| style="text-align: left;"|
| '''PI3'''
| '''259'''
|}
</div>
<ol start="2" style="list-style-type: decimal;">
<li><p>pwm is turned off by default in Linux systems and needs to be turned on manually to use it. The opening steps are as follows:</p>
<ol style="list-style-type: lower-alpha;">
<li><p>First run '''orangepi-config'''. Ordinary users remember to add '''sudo''' permissions.</p>
{| class="wikitable" style="width:800px;"
|-
| <p>orangepi@orangepi:~$ '''261sudo orangepi-config'''</p>| }</li><li><p>Then select '''PI5System'''</p><p>[[File:zero2w-img80.png]]</p></li>| <li><p>Then select '''TWI0_SCL/UART2_TXHardware'''</p><p>[[File:zero2w-img81.png]]</p></li>| <li><p>Then use the keyboard's arrow keys to locate the position shown in the figure below, and then use the '''15space'''to select the configuration corresponding to the pwm you want to open.</p>|<p>[[File:zero2w-img176.png]]</p></li>| <li><p>Then select '''16<Save>'''to save</p><p>[[File:zero2w-img83.png]]</p></li>| <li><p>Then select '''PWM4/UART4_RX<Back>'''</p><p>[[File:zero2w-img84.png]]</p></li>| <li><p>Then select '''PI14<Reboot>'''to restart the system to make the configuration take effect.</p><p>[[File:zero2w-img85.png]]</p></li></ol></li><li><p>After restarting, you can start the PWM test</p>{| '''270'''class="wikitable" style="background-color:#ffffdc;width:800px;"
|-
|-
| <p>root@orangepi:~# '''231echo 1 > /sys/class/pwm/pwmchip0/export'''</p>| <p>root@orangepi:~# '''PH7echo 20000000 > /sys/class/pwm/pwmchip0/pwm1/period'''</p>| <p>root@orangepi:~# '''SPI1_MOSIecho 1000000 > /sys/class/pwm/pwmchip0/pwm1/duty_cycle'''</p>| <p>root@orangepi:~# '''19echo 1 > /sys/class/pwm/pwmchip0/pwm1/enable'''</p>|}| '''20'''</li>| '''GND'''<li><p>Enter the following command on the command line to make pwm2 output a 50Hz square wave</p></li>{| styleclass="text-align: left;wikitable"|| style="text-alignwidth: left800px;"|
|-
| root@orangepi:~# '''232echo 2 > /sys/class/pwm/pwmchip0/export'''| root@orangepi:~# '''PH8echo 20000000 > /sys/class/pwm/pwmchip0/pwm2/period'''| '''SPI1_MISO'''| root@orangepi:~# '''21echo 1000000 > /sys/class/pwm/pwmchip0/pwm2/duty_cycle'''|| root@orangepi:~# '''22echo 1 > /sys/class/pwm/pwmchip0/pwm2/enable'''| '''TWI0_SDA}</UART2_RX'''ol><ol start="3" style="list-style-type: lower-alpha;">| '''PI6'''<li>Enter the following command on the command line to make pwm3 output a 50Hz square wave</li>{| '''262'''class="wikitable" style="width:800px;"
|-
| root@orangepi:~# '''230echo 3 > /sys/class/pwm/pwmchip0/export'''| root@orangepi:~# '''PH6echo 20000000 > /sys/class/pwm/pwmchip0/pwm3/period'''| root@orangepi:~# '''SPI1_CLKecho 1000000 > /sys/class/pwm/pwmchip0/pwm3/duty_cycle'''| root@orangepi:~# '''23echo 1 > /sys/class/pwm/pwmchip0/pwm3/enable'''|}| '''24'''</ol>| '''SPI1_CS0'''<ol start="4" style="list-style-type: lower-alpha;">| '''PH5'''<li>Enter the following command on the command line to make pwm4 output a 50Hz square wave</li>{| '''229'''class="wikitable" style="width:800px;"
|-
|-
| '''266'''| ''<big>'PI10''Note: The pin header on the 40pin interface is not soldered by default, and you need to solder it yourself before it can be used.'| '''TWI2-SDA</UART3_RX'''| '''27'''big>|}{| '''28'''| '''TWI2class="wikitable" style="background-SCL/UART3_TX'''| '''PI9'''| '''265'''color:#ffffdc;width:800px;"
|-
| <big>'''wiringOP-Python is the Python language version of wiringOP library, used to operate the development board'256s GPIO, I2C, SPI, UART and other hardware resources in the Python program'''| '''PI0Also please note that all the following commands are operated under the root user.'''</big>| style} <span id="texthow-to-install-align: left;wiringop-python"|></span>| '''29'''=== How to install wiringOP-Python ===|| '''30'''| '''GND'''| <ol style="textlist-alignstyle-type: leftdecimal;"|><li><p>First install dependency packages</p>{| class="wikitable" style="text-alignwidth: left800px;"|
|-
| <p>root@orangepi:~# '''271sudo apt-get update'''</p>| <p>root@orangepi:~# '''PI15sudo apt-get -y install git swig python3-dev python3-setuptools'''</p>|}</li><li><p>Then use the following command to download the source code of wiringOP-Python</p></li>{| class="wikitable" style="textbackground-aligncolor:#ffffdc;width: left800px;"|| '''31'''|| '''32'''| '''PWM1'''| '''PI11'''| '''267'''
|-
| '''268'''| <big>'''PI12Note that the following git clone--recursive command will automatically download the source code of wiringOP, because wiringOP-Python depends on wiringOP. Please make sure there are no errors during the download process due to network problems.'''| '''PWM2'''| '''33'''|| '''34If there is a problem downloading the code from GitHub, you can directly use the wiringOP-Python source code that comes with the Linux image. The storage location is: /usr/src/wiringOP-Python'''</big>| '''GND'''}{| styleclass="text-align: left;wikitable"|| style="text-alignwidth: left800px;"|
|-
| root@orangepi:~# '''258git clone --recursive https://github.com/orangepi-xunlong/wiringOP-Python -b next'''| root@orangepi:~# '''PI2cd wiringOP-Python'''| style="textroot@orangepi:~/wiringOP-align: left;"|| Python# '''35git submodule update --init --remote'''|}| '''36'''</ol>| <ol start="3" style="textlist-style-aligntype: leftdecimal;"|>| '''PC12'''<li><p>Then use the following command to compile wiringOP-Python and install it into the Linux system of the development board</p>{| '''76'''class="wikitable" style="width:800px;"
|-
| <p>root@orangepi:~# '''272cd wiringOP-Python'''</p>| <p>root@orangepi:~/wiringOP-Python# '''PI16python3 generate-bindings.py > bindings.i'''</p>| style="text<p>root@orangepi:~/wiringOP-align: left;"|| Python# '''37sudo python3 setup.py install'''</p>|}| </li><li><p>Then enter the following command. If helpful information is output, it means wiringOP-Python is successfully installed. Press the '''38q'''key to exit the help information interface.</p></li>{| class="wikitable" style="text-alignwidth: left800px;"|| '''PI4'''| '''260'''
|-
| style="text-alignroot@orangepi: left;"|| style="text~/wiringOP-align: left;"|| '''GND'''| '''39'''|| '''40Python# '''| style="textpython3 -align: leftc "import wiringpi; help(wiringpi)""|| '''PI3'''| '''259'''|}Help on module wiringpi:
: # As can be seen from the table below, the available uarts are uart2, uart3, uart4 and uart5This file was automatically generated by SWIG (http://www. Please note that uart0 is set as a debugging serial port by defaultswig. Please do not use uart0 as a normal serial portorg).
|-
| <big>'''264Like wiringOP, wiringOP-Python can also determine which GPIO pin to operate by specifying the wPi number. Because there is no command to view the wPi number in wiringOP-Python, you can only view the board's wPi number and physics through the gpio command in wiringOP Correspondence of pins.'''</big> [[File:zero2w-img170.png| '''PI8'''center]]| '''TWI1} <ol style="list-style-type: decimal;"><li><p>The following uses pin No. 7 - corresponding to GPIO PI13 - corresponding to wPi serial number 2 -SDA'''as an example to demonstrate how to set the high and low levels of the GPIO port.</p>| '''3'''<p>[[File:zero2w-img171.png]]</p></li>|<li><p>The steps for testing directly with commands are as follows:</p>| '''4'''<ol style="list-style-type: lower-alpha;">| <li><p>First set the GPIO port to output mode, where the first parameter of the '''5VpinMode'''function is the serial number of the wPi corresponding to the pin, and the second parameter is the GPIO mode.</p>{| styleclass="text-align: left;wikitable"|| style="text-alignwidth: left800px;"|
|-
| '''263'''| <p>root@orangepi:~/wiringOP-Python# '''PI7python3 -c "import wiringpi; \'''</p>| <p>'''TWI1-SCLfrom wiringpi import GPIO; wiringpi.wiringPiSetup() ; \'''</p>| <p>'''5wiringpi.pinMode(<span style="color:#FF0000">2, GPIO.OUTPUT</span>) ; "'''</p>|}| '''6'''</li>| '''GND'''<li><p>Then set the GPIO port to output a low level. After setting, you can use a multimeter to measure the voltage value of the pin. If it is 0v, it means the low level is set successfully.</p>{| styleclass="text-align: left;wikitable"|| style="text-alignwidth: left800px;"|
|-
| <p>root@orangepi:~/wiringOP-Python# '''269python3 -c "import wiringpi; \'''</p>| <p>'''PI13from wiringpi import GPIO; wiringpi.wiringPiSetup() ;\'''</p>| <p>'''PWM3wiringpi.digitalWrite(2, <span style="color:#FF0000">GPIO.LOW</UART4_TXspan>)"'''</p>| '''7'''}|</li>| '''8'''<li><p>Then set the GPIO port to output a high level. After setting, you can use a multimeter to measure the voltage value of the pin. If it is 3.3v, it means the setting of the high level is successful.</p>{| '''UART0_TX'''| '''PH0'''| '''224'''class="wikitable" style="width:800px;"
|-
| style="text-align<p>root@orangepi: left;"|| style="text~/wiringOP-align: left;"|| Python# '''GNDpython3 -c "import wiringpi; \'''</p>| <p>'''9from wiringpi import GPIO; wiringpi.wiringPiSetup() ;\'''</p>|| <p>'''10wiringpi.digitalWrite(2, <span style="color:#FF0000">GPIO.HIGH</span>)"'''</p>| '''UART0_RX'''}</li></ol></li><li><p>The steps for testing in the command line of python3 are as follows:</p><ol style="list-style-type: lower-alpha;">| '''PH1'''<li><p>First use the python3 command to enter the command line mode of python3</p>{| '''225'''class="wikitable" style="width:800px;"
|-
| '''226'''| <p>root@orangepi:~# '''PH2python3'''</p>| '''UART5_TX'''}| '''11'''</li>|| '''12'''<li><p>Then import the python module of wiringpi</p>{| class="wikitable" style="text-alignwidth: left800px;"|| '''PI1'''| '''257'''
|-
| <p>>>> '''227import wiringpi'''</p><p>>>> '''from wiringpi import GPIO'''</p>| }</li><li><p>Then set the GPIO port to output mode, where the first parameter of the '''PH3pinMode'''function is the serial number of the wPi corresponding to the pin, and the second parameter is the GPIO mode.</p>{| class="wikitable" style="width:800px;" |-| <p>>>> '''wiringpi.wiringPiSetup()'''</p><p>0</p><p>>>> '''UART5_RXwiringpi.pinMode(<span style="color:#FF0000">2, GPIO.OUTPUT</span>)'''</p>| }</li><li><p>Then set the GPIO port to output a low level. After setting, you can use a multimeter to measure the voltage value of the pin. If it is 0v, it means the low level is set successfully.</p>{| class="wikitable" style="width:800px;" |-| <p>>>> '''13wiringpi.digitalWrite(2, <span style="color:#FF0000">GPIO.LOW</span>)'''</p>|}</li><li><p>Then set the GPIO port to output a high level. After setting, you can use a multimeter to measure the voltage value of the pin. If it is 3.3v, it means the setting of the high level is successful.</p>{| class="wikitable" style="width:800px;" |-| <p>>>> '''14wiringpi.digitalWrite(2, <span style="color:#FF0000">GPIO.HIGH</span>)'''</p>| }</li></ol></li><li><p>For wiringOP-Python to set the GPIO high and low levels in the python code, you can refer to the '''blink.py'''GNDtest program in the examples. The '''blink.py''' test program will set the voltage of all GPIO ports in the 40 Pin of the development board to continuously change high and low.</p>{| class="wikitable" style="textwidth:800px;" |-| <p>root@orangepi:~/wiringOP-Python# '''cd examples'''</p><p>root@orangepi:~/wiringOP-Python/examples# '''ls blink.py'''</p><p>'''blink.py'''</p><p>root@orangepi:~/wiringOP-Python/examples'''# python3 blink.py'''</p>|}</li></ol> <span id="pin-spi-test-align1"></span> === 40pin SPI test === # As can be seen from the table below, the spi available for the 40pin interface is spi1, and there are two chip select pins cs0 and cs1 <div style="display: leftflex;"|>::{| class="wikitable" style="width:390px;margin-right: 20px;text-align: leftcenter;"|
|-
| '''261GPIO NO.'''| '''PI5GPIO'''| '''TWI0_SCL/UART2_TXFunction'''| '''15'''|| '''16'''| '''PWM4/UART4_RX'''| '''PI14'''| '''270Pin'''
|-
| style="text-align: left;"|
| style="text-align: left;"|
| '''3.3V'''
| '''171'''|-| '''264'''| '''18PI8'''| style="text'''TWI1-align: left;"SDA'''|'''3'''|-| '''263'''| '''PI7'''| '''TWI1-SCL'''| '''5'''|-| '''269'''| '''PI13'''| '''PH4PWM3/UART4_TX'''| '''2287'''
|-
| style="text-align: left;"|
| style="text-align: left;"|
| '''GND'''
| '''9'''
|-
| '''232226'''| '''PH8PH2'''| '''SPI1_MISOUART5_TX'''| '''2111'''|-| '''22227'''| '''TWI0_SDA/UART2_RXPH3'''| '''PI6UART5_RX'''| '''26213'''
|-
| '''230261'''| '''PH6PI5'''| '''SPI1_CLKTWI0_SCL/UART2_TX'''| '''23'''|| '''24'''| '''SPI1_CS0'''| '''PH5'''| '''22915'''
|-
| style="text-align: left;"|
| style="text-align: left;"|
| '''3.3V'''| '''17'''|-| '''<span style="color:#FF0000">231</span>'''| '''<span style="color:#FF0000">PH7</span>'''| '''<span style="color:#FF0000">SPI1_MOSI</span>'''| '''<span style="color:#FF0000">19</span>'''|-| '''<span style="color:#FF0000">232</span>'''| '''<span style="color:#FF0000">PH8</span>'''| '''<span style="color:#FF0000">SPI1_MISO</span>'''| '''<span style="color:#FF0000">21</span>'''|-| '''<span style="color:#FF0000">230</span>'''| '''<span style="color:#FF0000">PH6</span>'''| '''<span style="color:#FF0000">SPI1_CLK</span>'''| '''<span style="color:#FF0000">23</span>'''|-| style="text-align: left;"|| style="text-align: left;"|| '''GND'''
| '''25'''
|-
| '''266'''
| '''TWI2-SDA/UART3_RX'''
| '''27'''
|-
| '''256'''
| style="text-align: left;"|
| '''29'''
|-
| '''271'''
| style="text-align: left;"|
| '''31'''
|-
| '''268'''
| '''PWM2'''
| '''33'''
|-
| '''258'''
| style="text-align: left;"|
| '''35'''
|-
| '''272'''
| style="text-align: left;"|
| '''37'''
|-
| style="text-align: left;"|
| '''GND'''
| '''39'''
|}
|-
| '''Multiplexing function in 40pinPin'''| '''Corresponding dtbo configurationFunction'''| '''GPIO'''| '''GPIO NO.'''|-| '''2'''| '''5V'''| style="text-align: left;"|| style="text-align: left;"||-| '''4'''| '''5V'''| style="text-align: left;"|| style="text-align: left;"||-| '''6'''| '''GND'''| style="text-align: left;"|| style="text-align: left;"||-| '''8'''| '''UART0_TX'''| '''PH0'''| '''224'''
|-
| '''40pin - uart210'''| '''pi-uart2UART0_RX'''| '''PH1'''| '''225'''
|-
| '''40pin 12'''| style="text- uart3align: left;"|| '''PI1'''| '''pi-uart3257'''
|-
| '''40pin - uart414'''| '''pi-uart4GND'''| style="text-align: left;"|| style="text-align: left;"|
|-
| '''40pin - uart516'''| '''ph-uart5PWM4/UART4_RX'''|}'''PI14'''| '''270'''[[File:zero2w|-img175.png]]| '''18'''<ol start| style="5text-align: left;" || '''PH4'''| '''228'''|-| '''20'''| '''GND'''| style="listtext-align: left;"|| style="text-typealign: lower-alphaleft;">||-<li><p>Then select | '''22'''<Save>| ''' to save<TWI0_SDA/p>UART2_RX'''| '''PI6'''| '''262'''|-| '''<p>[[Filespan style="color:zero2w-img83.png]]</p#FF0000">24</lispan>'''| '''<lispan style="color:#FF0000">SPI1_CS0<p/span>Then select '''<Back>| '''</p><p>[[Filespan style="color:zero2w-img84.png]]</p#FF0000">PH5</li><li><pspan>Then select '''<Reboot>| ''' to restart the system to make the > configuration take effect.</p><p>[[Filespan style="color:zero2w-img85.png]]</p#FF0000">229</li></olspan>''' <!-- -|->| '''<ol start="3" span style="list-style-typecolor: decimal;#FF0000">26<li/span><p>After entering the Linux system, first confirm whether there is a uart5 device node under '''| '''<span classstyle="markcolor:#FF0000">/devSPI1_CS1</span>'''| '''</pspan style="color:#FF0000">PH9<p/span>'''注意, linux5.4系统为/dev/ttyASx.| '''<span style="color:#FF0000">233</pspan>'''<p>orangepi@orangepi:~$ |-| '''ls /dev/ttyS*28'''</p><p>/dev/ttySx</p></li><li><p>Then start testing the uart interface. First use Dupont wire to short| '''TWI2-circuit the rx and tx pins of the uart interface to be tested.<SCL/p></li>UART3_TX'''<li><p>Use the | '''gpioPI9''' command in wiringOP to test the loopback function of the serial port as shown below. If you can see the following print, it means the serial port communication is normal.</p><p>| '''Note that the last x in the gpio serial /dev/ttySx command needs to be replaced with the serial number of the corresponding uart device node.265'''</p><p>orangepi@orangepi:~$ |-| '''gpio serial /dev/ttySx # linux-6.1 test command30'''</p><p>orangepi@orangepi:~$ | '''gpio serial /dev/ttyASx # linux-5.4 test commandGND'''</p><p>Out| style="text-align: 0: ->left; 0</p>"|<p>Out| style="text-align: 1: ->left; 1</p>"|<p>Out: 2: |-> 2</p><p>Out: 3: -> 3^C</p></li>| '''32'''<li><p>Finally, you can run the | '''serialTest.pyPWM1''' program in examples to test the loopback function of the serial port. If you can see the following print, it means that the serial port loopback test is normal.</p><p>| '''Note that the x in /dev/ttySx or /dev/ttyASx in the command needs to be replaced with the serial number of the corresponding uart device node.PI11'''</p><p>root@orangepi:~/wiringOP-Python# | '''cd examples267'''</p><p>root@orangepi:~/wiringOP|-Python/examples# | '''python3 serialTest.py --device "/dev/ttySx" # linux6.1 use34'''</p><p>root@orangepi:~/wiringOP-Python/examples# | '''python3 serialTest.py --device "/dev/ttyASx" # linux5.4 useGND'''</p><p>Out| style="text-align: 0: ->left; 0</p>"|<p>Out: 1: | style="text-> 1</p><p>Out: 2align: ->left; 2</p>"|<p>Out: 3: |-> 3</p><p>Out: 4:^C</p>| '''36'''<p>exit</p></li></ol> <span id| style="hardwaretext-watchdog-testalign: left;"></span>|== Hardware watchdog test ==| '''PC12'''| '''76'''The watchdog_test program is pre|-installed in the Linux system released by Orange Pi and can be tested directly.| '''38'''The method to run the watchdog_test program is as follows: <ol | style="listtext-style-typealign: lower-alphaleft;">|<li><p>The second parameter 10 represents the counting time of the watchdog. If the dog is not fed within this time, the system will restart.</p></li>| '''PI4'''<li><p>We can feed the dog by pressing any key on the keyboard (except ESC). After feeding the dog, the program will print a line "keep alive" to indicate that the dog feeding is successful.</p><p>orangepi@orangepi:~$ | '''sudo watchdog_test 10260'''</p><p>open success</p><p>options is 33152,identity is sunxi|-wdt</p><p>put_usr return,if 0,success:0</p>| '''40'''<p>The old reset time is: 16</p><p>return ENOTTY,if | style="text-1,successalign:0</p>left;"|<p>return ENOTTY,if -1,success:0</p>| '''PI3'''<p>put_user return,if 0,success:0</p>| '''259'''<p>put_usr return,if 0,success:0</p><p>keep alive</p><p>keep alive</p>|}<p>keep alive</p></li></oldiv>
<span idol start="check2" style="list-thestyle-chipidtype: decimal;"><li><p>In Linux systems, spi1 is turned off by default and needs to be turned on manually before it can be used. The opening steps are as follows:</p><ol style="list-ofstyle-h618type: lower-chipalpha;"><li><p>First run '''orangepi-config'''. Ordinary users remember to add '''sudo''' permissions.</spanp>{| class="wikitable" style= Check "width:800px;" |-| <p>orangepi@orangepi:~$ '''sudo orangepi-config'''</p>|}</li><li><p>Then select '''System'''</p><p>[[File:zero2w-img80.png]]</p></li><li><p>Then select '''Hardware'''</p><p>[[File:zero2w-img81.png]]</p></li><li><p>Then use the keyboard's arrow keys to locate the position shown in the figure below, and then use the '''space''' to select the chipid dtbo configuration of H618 chip ==the SPI you want to open.</p></li>
TX | FF FF FF FF FF FF '''The following demonstration is to compile and install the latest version of Python 3<span style="color:#FF0000">40 00 00 00 00 95</span>''' FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF F0 0D |......@.....9. If you want to compile and install other versions of Python, the method is the same (you need to download the source code corresponding to the Python you want to install).'''…|
RX | FF FF FF FF FF FF '''<ol span style="list-style-typecolor: decimal;#FF0000"><li><p>First install the dependency packages needed to compile Python</p><p>orangepi@orangepi:~$ '''sudo apt-get update'''</p><p>orangepi@orangepi:~$ '''sudo apt-get install -y build-essential zlib1g-dev \'''</p><p>'''libncurses5-dev libgdbm-dev libnss3-dev libssl-dev libsqlite3-dev \'''</p><p>'''libreadline-dev libffi-dev curl libbz2-dev'''</p></li><li><p>Then download the latest version of Python3.9 source code and unzip itFF FF FF FF FF FF</pspan><p>orangepi@orangepi:~$ '''wget \'''</p><p>[https://wwwFF FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF |.python.org/ftp/python/3.9.10/Python-3.9.10.tgz '''https://www.python.org/ftp/python/3.9.10/Python-3.9.10….tgz''']</p>||}<p>orangepi@orangepi:~$ '''tar xvf Python-3.9.10.tgz'''</p></li><li><p>Then run the configuration command</pol><p>orangepi@orangepi:~$ '''cd Pythonol start="6" style="list-style-3.9.10'''</p><p>orangepi@orangepitype:~$ '''./configure --enable-optimizations'''</p></lidecimal;"><li><p>Then compile use Dupont wire to short-circuit the txd (pin 19 in the 40pin interface) and rxd (pin 21 in the 40pin interface) of SPI1 and install Python3then run spidev_test.9py. The compilation time takes about half an hour.</p><p>orangepi@orangepi:~$ '''make -j4'''</p><p>orangepi@orangepi:~$ '''sudo make altinstall'''</p></li><li><p>After installationoutput is as follows, you can use see If the following command to check data sent and received are the version number of same, it means that the Python you just installedSPI1 loopback test is normal.</p><p>orangepi@orangepi{| class="wikitable" style="width:~$ '''python3.9 800px;" |--version'''</p><p>'''Python 3.9.10'''</p></li><li><p>Then update pip</p>| <p>orangepiroot@orangepi:~$ /wiringOP-Python# '''/usr/local/bin/python3.9 -m pip install --upgrade pipcd examples'''</p></li></ol>
'''The default source used by Linux system pip is the official source of Python. However, accessing the official source of Python in China is very slow, and the installation of Python software packages often fails due to network reasons. So when using pip to install the Python library, please remember to change the pip source.--channel 1 --port 0'''
<span idol start="set-up-the-chinese-environment-and-install-the-chinese-input-method2"></span>== Set up the Chinese environment and install the Chinese input method == '''Note, before installing the Chinese input method, please make sure that the Linux system used by the development board is a desktop version.''' <span id="debian-system-installation-method"></span>=== Debian system installation method === <ol style="list-style-type: decimal;"><li><p>First set the i2c is turned off by default '''locale''' in Linux systems and needs to Chinesebe turned on manually to use it. The opening steps are as follows:</p>
<ol style="list-style-type: lower-alpha;">
<li><p>Enter the following command to start configuring '''localeFirst run '''</p><p>orangepi@orangepi:~$ '''sudo dpkg-reconfigure locales'''</p></li><li><p>Then select config'''zh_CN.UTF-8 UTF-8''' in the pop-up interface (use > the up and down keys on the keyboard to move up and down, use > the space bar to select, and finally use the Tab key to move > the cursor Ordinary users remember to add '''<OK>sudo''', and then return Car can be used)permissions.</p><p>[[File{| class="wikitable" style="width:zero2w-img186.png]]</p></li>800px;" <li><p>Then set the default '''locale''' to '''zh_CN.UTF|-8'''</p><p>[[File:zero2w-img187.png]]</p></li><li><p>After exiting the interface, the '''locale''' setting will begin. > The output displayed on the command line is as follows:</p>| <p>orangepi@orangepi:~$ '''sudo dpkgorangepi-reconfigure localesconfig'''</p><p>Generating locales (this might take a while)...</p><p>en_US.UTF-8... done</p><p>zh_CN.UTF-8... done</p><p>Generation complete.</p></li></ol>|}
</li>
[[File:zero2w-img173.png]]</divol></liol start="5" style="list-style-type: lower-alpha;"><li><p>Then put '''Google Pinyin''' on topselect </pspan class="mark"><Save><p/span>[[File:zero2w-img196.png]]to save</p><p>[[File:zero2w-img197img83.png]]</p></li><li><p>Then open the '''Geany''' editor to test the Chinese input methodselect <span class="mark"><Back></span></p><p>[[File:zero2w-img198img84.png]]</p></li><li><p>The Chinese input method test is as followsThen select <span class="mark"><Reboot></span> to restart the system to make the configuration take effect.</p><p>[[File:zero2w-img199img85.png]]</p></li></ol></li><p/ol>You can switch between Chinese and English input methods through the '''Ctrl+Space''' shortcut key</p!-- --></liol start="3" style="list-style-type: decimal;"><li><p>If you need After starting the entire Linux system to be displayed in Chinese, you can set all variables in '''first confirm that there is an open i2c device node under <span class="mark">/etcdev</default/locale''' to '''zh_CN.UTF-8'''span></p>{| class="wikitable" style="width:800px;" |-| <p>orangepi@orangepi:~$ '''sudo vim ls /etcdev/default/localei2c-*'''</p><p># File generated by update-locale</p><p>LC_MESSAGES='''zh_CN.UTF/dev/i2c-8*'''</p>|}{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <pbig>LANG='''zh_CN.UTF-8注意,这里说的Linux镜像具体指的是从Orange Pi资料下载页面下载的Debian或者Ubuntu这样的Linux发行版镜像。'''</pbig>|}{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <big><p>LANGUAGE='''zh_CNSometimes the i2c device node and the i2c bus serial number do not correspond one to one.UTFFor example, the i2c device node of the i2c1 bus may be /dev/i2c-83.'''</p></li><li><p>Then '''restart The method to accurately confirm the device node under /dev corresponding to the systemi2c bus is: ''' and you will see that the system is displayed in Chinese.</p><p>[[File:zero2w-img200.png]]</p></li></olbig>
<ol style="list-style-type: decimallower-alpha;"><li><p>First open '''Language SupportFirst run the following command to check the corresponding relationship of i2c'''</p><p>orangepi@orangepizero2w:~$ '''ls /sys/devices/platform/soc*/*/i2c-* | grep "i2c-[[File:zero2w0-img201.png]9]"'''</p><p>/sys/devices/platform/soc/5002000.i2c/i2c-0:</lip><li><p>Then find the '''Chinese (China)''' option/sys/devices/platform/soc/5002400.i2c/i2c-3:</p><p>[[File/sys/devices/platform/soc/5002800.i2c/i2c-4:zero2w-img202.png]]</p><p>/sys/devices/platform/lisoc/5002c00.i2c/i2c-5:</p><li><p>Then please use the left button of the mouse to select '''Chinese (China)''' and hold it down, then drag it up to the starting position/sys/devices/platform/soc/6000000. After dragging, the display will be as shown belowhdmi/i2c-2:</p><p>[[File/sys/devices/platform/soc/7081400.i2c/i2c-1:zero2w-img203.png]]</p></li></ol>
<li><p>'''In the above output'''</p>
<ol style="list-style-type: none;">
<li><p>a) 5002000 is the register base address of the i2c0 bus, and i2c-0 shown behind it is its corresponding i2c device node</p></li>
<li><p>b) 5002400 is the register base address of the i2c1 bus, and i2c-3 shown behind it is its corresponding i2c device node</p></li>
<li><p>c) 5002800 is the register base address of the i2c2 bus, and i2c-4 shown behind it is its corresponding i2c device node</p></li></ol>
</li></ol>
|}
</li></ol>
<ol start="4" style="list-style-type: decimal;">
<li><p>Then select start testing i2c, first install i2c-tools</p>{| class="wikitable" style="width:800px;" |-| <p>orangepi@orangepi:~$ '''Apply Systemsudo apt-Wideget update''' to apply the Chinese settings to the entire system</p><p>[[Fileorangepi@orangepi:zero2w~$ '''sudo''' '''apt-get install -y i2c-img204.png]]tools'''</p>|}</li><li><p>Then set connect an i2c device to the i2c pin of the 40pin connector. Here we take the '''Keyboard input method system''' system to '''fcitx'''DS1307 RTC module as an example.</p><p>[[File:zero2w-img205img178.png]]</p></li><li><p>Then use the '''Then restart the Linux system to make the configuration take effecti2cdetect -y x'''command. If the address of the connected i2c device can be detected, it means that the i2c device is connected correctly.</p></li>{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <libig>'''<p>After re-entering the system, please select '''Do not ask me again''' Note that x in the following interface, and then please decide according i2cdetect -y x command needs to your own preferences whether be replaced with the standard folder should also be updated serial number of the device node corresponding to Chinesethe i2c bus.'''</p>'''<p/big>|} [[File:zero2w-img206img179.png]]</pli></liol><ol start="7" style="list-style-type: decimal;"><li><p>Then you can see that run the desktop is displayed '''ds1307.py''' test program in Chinese'''examples''' to read the RTC time</p>{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <big><p>[[File:zero2w'''Note that the x in i2c-img207x in the following command needs to be replaced with the serial number of the device node corresponding to the i2c bus.png]]'''</p></libig><li>|}{| class="wikitable" style="width:800px;" |-| <p>Then we can open root@orangepi:~/wiringOP-Python# '''Geanycd examples''' to test the Chinese input method. The opening method is as shown in the figure below</p><p>[[Fileroot@orangepi:zero2w~/wiringOP-img208Python/examples# '''python3 ds1307.png]]py --device \'''</p></li><li><p>After opening '''Geany"/dev/i2c-x"''', the English input method is still the default. We can switch to the Chinese input method through the '''Ctrl+Space''' shortcut key, and then we can input Chinese.</p><p>[[FileThu 2022-06-16 04:35:46</p><p>Thu 2022-06-16 04:35:zero2w47</p><p>Thu 2022-06-img209.png]]16 04:35:48</p><p>^C</p><p>exit</p>|}</li></ol>
<span id="installationpin-methoduart-oftest-ubuntu-22.04-system1"></span>=== Installation method of Ubuntu 22.04 system ===
<ol startdiv style="4display: flex;">::{| class="wikitable" style="listwidth:390px;margin-styleright: 20px;text-typealign: decimalcenter;"><li><p>Then select |-| '''Apply System-WideGPIO NO.'''| '''GPIO''' to apply the Chinese settings to the entire system</p><p>[[File:zero2w-img212.png]]</p></li>| '''Function'''<li><p>| '''Then restart the Linux system to make the configuration take effectPin'''</p></li><li><p>After re|-| style="text-align: left;"|| style="text-entering the system, please select align: left;"|| '''Do not ask me again3.3V'''| '''1''' in the following interface, and then please decide whether the standard folder should also be updated to Chinese according to your own preferences.</p><p>[[File:zero2w|-img206.png]]</p></li><li><p>Then you can see that the desktop is displayed in Chinese</p>| '''264'''| '''PI8'''<p>[[File:zero2w| '''TWI1-img207.png]]</p></li>SDA'''<li><p>Then open the Fcitx5 configuration program</p>| '''3'''<p>[[File:zero2w|-img213.png]]</p></li><li><p>Then choose to use Pinyin input method</p>| '''263'''<div class="figure">| '''PI7''' [[File:zero2w| '''TWI1-img214.png]]SCL'''| '''5'''</div></li>|-<li><p>The interface after selection is as shown below, then click OK</p>| '''269'''<p>[[File:zero2w-img215.png]]</p></li>| '''PI13'''<li><p>Then we can open | '''GeanyPWM3/UART4_TX''' to test the Chinese input method. The opening method is as shown in the figure below</p><p>[[File:zero2w-img208.png]]</p></li><li><p>After opening '''Geany''', the English input method is still the default. We can switch to the Chinese input method through the '| '''Ctrl+Space7''' shortcut key, and then we can enter Chinese.</p><p>[[File|-| style="text-align:zero2w-img216.png]]</p></li></ol>left;"| <span id| style="howtext-to-remotely-log-in-to-the-linux-system-desktopalign: left;"></span>|== How to remotely log in to the Linux system desktop ==| '''GND'''| '''9'''<span id="remote-login-using-nomachine"></span>=== Remote login using NoMachine ===|-| '''Please ensure that the Ubuntu or Debian system installed on the development board is a desktop version of the system. In addition, NoMachine also provides detailed usage documentation. It is strongly recommended to read this document thoroughly to become familiar with the use of NoMachine. The document link is as follows:226''' | '''https://knowledgebase.nomachine.com/DT10R00166PH2''' '| ''NoMachine supports Windows, Mac, Linux, iOS and Android platforms, so we can remotely log in and control the Orange Pi development board through NoMachine on a variety of devices. The following demonstrates how to remotely log in to the Linux system desktop of the Orange Pi development board through NoMachine in Windows. For installation methods on other platforms, please refer to NoMachine's official documentation.UART5_TX''' | '''Before operating, please make sure that the Windwos computer and the development board are in the same LAN, and that you can log in to the Ubuntu or Debian system of the development board through ssh normally.11''' <ol style="list|-style-type: decimal;"><li><p>First download the installation package of the NoMachine software Linux | '''arm64227''' deb version, and then install it into the Linux system of the development board</p><ol style="list-style-type: lower-alpha;">| '''PH3'''<li>Since H618 is an ARMv8 architecture SOC and the system we use is > Ubuntu or Debian, we need to download the | '''NoMachine for ARM > ARMv8 DEBUART5_RX''' installation package. The download link is as > follows:</li></ol></li></ol>| '''13'''|-| '''Note that this download link may change, please look for the Armv8/Arm64 version of the deb package.261'''| '''PI5'''[https://www.nomachine.com/download/download&id=112&s=ARM | '''https:TWI0_SCL//downloads.nomachine.com/download/?id=118&distro=ARMUART2_TX''']| '''15'''[[File:zero2w|-img217.png]] <ol start| style="2text-align: left;" || style="listtext-style-typealign: lower-alphaleft;">|<li><p>In addition, you can also download the | '''NoMachine3.3V''' installation > package from the official tool.</p><p>[[File:zero2w-img218.png]]</p><p>First enter the | '''remote login software-NoMachine17''' folder</p><p>[[File:zero2w-img219.png]]</p>|-<p>Then download the arm64 version of the deb installation package</p>| '''231'''<p>[[File:zero2w-img220.png]]</p></li>| '''PH7'''<li><p>Then upload the downloaded | '''nomachine_x.x.x_x_arm64.debSPI1_MOSI''' to the > Linux system of the development board</p></li><li><p>Then use the following command to install | '''NoMachine19''' in the Linux > system of the development board</p><p>orangepi@orangepi:~$ |-| '''sudo dpkg -i nomachine_x.x.x_x_arm64_arm64.deb232'''</p></li></ol>| '''PH8'''<!-- -->| '''SPI1_MISO'''| '''21'''<ol start="2" style="list-style|-type: decimal;"><li>Then download the installation package of the Windows version of the NoMachine software. The download address is as follows</li></ol>| '''230'''| '''Note that this download link may change.PH6''' | '''https://downloads.nomachine.com/download/?id=9SPI1_CLK''' [[File:zero2w| '''23'''|-img221.png]] <ol start| style="3text-align: left;" || style="list-styletext-typealign: decimalleft;">|<li><p>Then install NoMachine in Windows. | '''GND'Please restart your computer after installation.''| '</p></li>''25'''|-<li><p>Then open | '''NoMachine266''' in Window</p><p>[[File:zero2w-img222.png]]</p></li>| '''PI10'''<li><p>After NoMachine is started, it will automatically scan other devices with NoMachine installed on the LAN. After entering the main interface of NoMachine, you can see that the development board is already in the list of connectable devices, and then click on the location shown in the red box in the picture below You can now log in to the Linux system desktop of the development board.<| '''TWI2-SDA/p>UART3_RX'''<p>[[File:zero2w-img223.png]]</p></li>| '''27'''|-<li><p>Then click | '''OK256'''</p><p>[[File:zero2w-img224.png]]</p></li>| '''PI0'''<li><p>Then enter the username and password of the development board Linux system in the corresponding positions in the figure below, and then click OK to start logging in.</p>| style="text-align: left;"|<p>[[File:zero2w-img225.png]]</p></li>| '''29'''<li><p>Then click OK in the next interface.</p></li>|-<li><p>Finally you can see the desktop of the development board Linux system</p>| '''271'''| '''PI15'''<p>[[File| style="text-align:zero2w-img226.png]]</p></li></ol> <span id="remote-login-using-vnc"></span>=== Remote login using VNC ===left;"|| '''Before operating, please make sure that the Windwos computer and the development board are in the same LAN, and that you can log in to the Ubuntu or Debian system of the development board through ssh normally.31'''|-| '''There are many problems with VNC testing in Ubuntu20.04, please do not use this method.'268''' <ol style="list-style-type: decimal;"><li><p>First run the | '''set_vnc.shPI12''' script to set up vnc, | '''remember to add sudo permissionPWM2'''s</p><p>orangepi@orangepi:~$ | '''sudo set_vnc.sh33'''</p><p>You will require a password to access your desktops.</p>|-<p>Password: | '''#Set the vnc password here, 8 characters258'''</p><p>Verify: | '''#Set the vnc password here, 8 charactersPI2'''</p><p>Would you like to enter a view| style="text-only password (y/n)? align: left;"|| '''n35'''</p><p>xauth: file /root/.Xauthority does not exist</p>|-<p>New | '''272''X' desktop is orangepi:1</p><p>Creating default startup script /root/.vnc/xstartup</p>| '''PI16'''<p>Starting applications specified in /root/.vnc/xstartup</p>| style="text-align: left;"|<p>Log file is /root/.vnc/orangepi:1.log</p><p>Killing Xtightvnc process ID 3047</p><p>New | '''37''X' desktop is orangepi:1</p><p>Starting applications specified in /root/.vnc/xstartup</p>|-<p>Log file is /root/.vnc/orangepi| style="text-align:1.log</p></li>left;"|<li><p>The steps to use MobaXterm software to connect to the development board Linux system desktop are as follows:</p><ol | style="list-styletext-typealign: lower-alphaleft;">|<li>First click Session, then select VNC, then fill in the IP > address and port of the development board, and finally click > OK to confirm.</li></ol>| '''GND'''</li></ol>| '''39'''|}<div {| class="figurewikitable"> [[Filestyle="width:zero2w390px;margin-img227.png]] </div><ol start="2" style="list-styleright: 20px;text-typealign: lower-alphacenter;"><li><p>Then enter the VNC password set earlier</p>|-| '''Pin'''<p>[[File:zero2w-img228.png]]</p></li>| '''Function'''<li><p>After successful login, the interface is displayed as shown below, > and then you can remotely operate the desktop of the development > board Linux system| '''GPIO'''| '''GPIO NO.</p></li></ol>''' [[File:zero2w|-img229.png]]| '''2'''<span id| '''5V'''| style="qttext-installation-methodalign: left;"></span>|| style== QT installation method == <ol style="list-style-type"text-align: decimalleft;">|<li><p>Use the following script to install QT5 and QT Creator</p>|-<p>orangepi@orangepi:~$ | '''4'install_qt.sh''| '''5V'''</p></li><li><p>After installation, the QT version number will be automatically printed.</p><ol | style="listtext-align: left;"|| style="text-typealign: lower-alphaleft;">|<li><p>The qt version that comes with Ubuntu20.04 is |-| '''5.12.86'''</p><p>orangepi@orangepi:~$ | '''install_qt.shGND'''</p><p>......</p>| style="text-align: left;"|<p>QMake version 3.1</p>| style="text-align: left;"|<p>Using Qt version |-| '''5.12.8''' in /usr/lib/aarch64-linux-gnu</p></li><li><p>The QT version that comes with Ubuntu22.04 is | '''5.15.3UART0_TX'''| '''PH0'''</p><p>orangepi@orangepi:~$ | '''install_qt.sh224'''</p><p>......</p>|-<p>QMake version 3.1</p>| '''10'''<p>Using Qt version | '''UART0_RX'''5.15.3| '''PH1''' in /usr/lib/aarch64-linux-gnu</p></li><li><p>The QT version that comes with Debian11 is | '''5.15.2225'''</p><p>orangepi@orangepi:~$ |-| '''install_qt.sh12'''</p><p>......</p>| style="text-align: left;"|| '''PI1'''<p>QMake version 3.1</p>| '''257'''|-<p>Using Qt version | '''14''5.15.2'| '' in /usr/lib/aarch64-linux-gnu</p></li><li><p>The QT version that comes with Debian12 is 'GND''5.15.8'''</p><p>orangepi@orangepi| style="text-align:~$ left;"|| style="text-align: left;"||-| '''install_qt.sh16'''| '''<PWM4/p>UART4_RX'''<p>......</p>| '''PI14'''<p>QMake version 3.1</p><p>Using Qt version | '''5.15.8270''' in /usr/lib/aarch64-linux|-gnu</p></li></ol></li><li><p>Then you can see the QT Creator startup icon in | '''Applications18'''</p><p>[[File| style="text-align:zero2w-img230.png]]</p>left;"|<p>You can also use the following command to open QT Creator</p>| '''PH4'''<p>orangepi@orangepi:~$ | '''qtcreator228'''</p></li><li><p>The interface after QT Creator is opened is as follows</p>|-<p>[[File:zero2w-img231.png]]</p></li>| '''20'''<li><p>The version of QT Creator is as follows</p>| '''GND'''<ol | style="listtext-align: left;"|| style="text-typealign: lower-alphaleft;">||-<li><p>The default version of QT Creator in | '''Ubuntu20.0422''' is as > follows<| '''TWI0_SDA/p>UART2_RX'''<p>[[File:zero2w-img232.png]]</p></li><li><p>The default version of QT Creator in | '''Ubuntu22.04PI6''' is as > follows</p><p>[[File:zero2w| '''262'''|-img233.png]]</p></li><li><p>The default version of QT Creator in | '''Debian1124''' is as follows</p><p>[[File:zero2w-img234.png]]</p></li>| '''SPI1_CS0'''| '''PH5'''<li><p>The default version of QT Creator in | '''Debian12229''' is as follows</p><p>[[File:zero2w|-img235.png]]</p></li></ol></li>| '''26'''<li><p>Then set up QT</p>| '''SPI1_CS1'''<ol style="list-style-type: lower-alpha;"><li><p>First open | '''HelpPH9'''->| '''About Plugins...233'''|-| '''28'''.</p><p>[[File:zero2w| '''TWI2-img236.png]]<SCL/p></li>UART3_TX'''<li><p>Then remove the check mark of | '''ClangCodeModelPI9'''| '''265'''</p><p>[[File:zero2w|-img237.png]]</p></li><li><p>| '''30''After setting up, you need to restart QT Creator'| ''</p></li><li><p>Then make sure the GCC compiler used by QT Creator. If the > default is Clang, please change it to GCC.</p><p>'GND''Debian12 please skip this step.'''</p><p>[[File| style="text-align:zero2wleft;"|| style="text-img238.png]]</p>align: left;"|<p>[[File:zero2w|-img239.png]]</p></li></ol></li>| '''32'''<li><p>Then you can open a sample code</p>| '''PWM1'''<p>[[File:zero2w-img240.png]]</p></li>| '''PI11'''<li><p>After clicking on the sample code, the corresponding instruction document will automatically open. You can read the instructions carefully.</p>| '''267'''<p>[[File:zero2w|-img241.png]]</p></li><li><p>Then click | '''34'''| '''Configure ProjectGND'''</p><p>[[File| style="text-align:zero2w-img242.png]]</p></li>left;"|<li><p>Then click the green triangle in the lower | style="text-align: left corner to compile and run the sample code</p>;"|<p>[[File:zero2w|-img243.png]]</p></li><li><p>After waiting for a period of time, the interface shown in the figure below will pop up, which means that QT can compile and run normally.</p><p>[[File| '''36'''| style="text-align:zero2w-img244.png]]</p></li>left;"|<li><p>References</p><p>[https://wiki.qt.io/Install_Qt_5_on_Ubuntu | '''https://wiki.qt.io/Install_Qt_5_on_UbuntuPC12''']</p><p>[https://download.qt.io/archive/qtcreator | '''https://download.qt.io/archive/qtcreator76''']</p><p>[https://download.qt.io/archive/qt |-| '''38''https://download.qt.io/archive/qt''']</p></li></ol> <span id| style="rostext-installation-methodalign: left;"></span>|== ROS installation method ==| '''PI4'''| '''260'''<span id="how|-to-install-ros-1-noetic-on-ubuntu20.04"></span>=== How to install ROS 1 Noetic on Ubuntu20.04 === # The currently active version of ROS 1 is as follows, the recommended version is '| '''Noetic Ninjemys40''' [[File| style="text-align:zero2w-img245.png]] [[File:zero2w-img246.png]]left;"| [http://docs.ros.org/ | '''http://docs.ros.orgPI3'''] | '''https://wiki.ros.org/Distributions259'''|}</div>
<ol start="2" style="list-style-type: decimal;">
<li><p>In Linux systems, uart is turned off by default and needs to be turned on manually before it can be used. The link to the official installation documentation of ROS 1 '''Noetic Ninjemys''' is opening steps are as follows::</p><p>[httpol style="list-style-type://wiki.ros.org/noetic/Installation/Ubuntu '''http://wiki.ros.org/noetic/Installation/Ubuntu''']</p></lilower-alpha;"><li><p>In the official installation documentation of ROS First run '''Noetic Ninjemysorangepi-config''', Ubuntu recommends using Ubuntu20.04, so please ensure that the system used by the development board is Ordinary users remember to add '''Ubuntu20.04 desktop systemsudo'''permissions.</p>{| class="wikitable" style="width:800px;" |-| <p>[httporangepi@orangepi:~$ '''sudo orangepi-config'''</p>|}</wiki.ros.org/noetic/Installation li><li><p>Then select '''http://wiki.ros.org/noetic/InstallationSystem''']</p><p>[[File:zero2w-img247img80.png]]</p></li><li><p>Then use the script below to install ros1select '''Hardware'''</p><p>orangepi@orangepi[[File:~$ '''install_roszero2w-img81.sh ros1'''png]]</p></li><li><p>Before using Then use the ROS toolkeyboard's arrow keys to locate the position shown in the picture below, you first need and then use the '''space''' to initialize rosdep. Then when compiling select the source code, serial port you can quickly install some system dependencies and some core components in ROSwant to open.</p></li></ol>
{| class="wikitable" style="width:800px;text-align: center;"|-| '''Note that when running the following command, you need to ensure that the development board can access github normally, otherwise an error will be reported due to network problems.Multiplexing function in 40pin'''| '''Corresponding dtbo configuration'''|-| '''40pin - uart2'''| '''pi-uart2'''|-| '''40pin - uart3'''| '''pi-uart3'''|-| '''40pin - uart4'''| '''pi-uart4'''|-| '''40pin - uart5'''| '''ph-uart5'''|}
[[File:zero2w-img175.png]]</ol><ol start="5" style="list-style-type: lower-alpha;"><li><p>Then select '''The install_ros<Save>''' to save</p><p>[[File:zero2w-img83.sh script will try to modify png]]</p></etcli><li><p>Then select '''<Back>'''</hosts and automatically run the following commandsp><p>[[File:zero2w-img84. However, this method cannot guarantee that github can be accessed normally every time. If install_ros.sh prompts the following error after installing ros1, please find other ways png]]</p></li><li><p>Then select '''<Reboot>''' to allow restart the linux system of the development board to access github normally, and then manually run make the following Orderconfiguration take effect.</p><p>[[File:zero2w-img85.png]]</p></li></ol></li></ol><!-- --><ol start="3" style="list-style-type: decimal;"><li><p>After entering the Linux system, first confirm whether there is a uart5 device node under '''<span class="mark">/dev</span>'''</p>{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <big><p>'''注意, linux5.4系统为/dev/ttyASx.'''https</p></big>|}{| class="wikitable" style="width:800px;" |-| <p>orangepi@orangepi:~$ '''ls /dev/raw.githubusercontent.comttyS*'''</rosp><p>/rosdistrodev/masterttySx</rosdepp>|}</osxli><li><p>Then start testing the uart interface. First use Dupont wire to short-homebrewcircuit the rx and tx pins of the uart interface to be tested.yaml</p></li><li><p>Use the ''' gpio'''Hit https://rawcommand in wiringOP to test the loopback function of the serial port as shown below.githubusercontentIf you can see the following print, it means the serial port communication is normal.com</rosp>{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <big><p>'''Note that the last x in the gpio serial /rosdistrodev/master/rosdep/basettySx command needs to be replaced with the serial number of the corresponding uart device node.yaml'''</p></big>|}{| class="wikitable" style="width:800px;" |-| <p>orangepi@orangepi:~$ '''ERROR: error loading sources list:gpio serial /dev/ttySx # linux-6.1 test command'''</p> <p>orangepi@orangepi:~$ '''The read operation timed outgpio serial /dev/ttyASx # linux-5.4 test command'''</p>
<p>Out: 0: -> 0</p><p>Out: 1: -> 1</p><p>Out: 2: -> 2</p><p>Out: 3: -> 3^C</p>|}</li><li><p>Finally, you can run the '''serialTest.py''' program in examples to test the loopback function of the serial port. If you can see the following print, it means that the serial port loopback test is normal.</p>{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <big><p>'''Note that the x in /dev/ttySx or /dev/ttyASx in the command needs to be replaced with the serial number of the corresponding uart device node.'''</p></big>|}{| class="wikitable" style="width:800px;" |-| <p>root@orangepi:~/wiringOP-Python# '''cd examples'''</p><p>root@orangepi:~/wiringOP-Python/examples# '''python3 serialTest.py --device "/dev/ttySx" # linux6.1 use'''</p><p>root@orangepi:~$ /wiringOP-Python/examples# '''sudo rosdep initpython3 serialTest.py --device "/dev/ttyASx" # linux5.4 use'''</p>
'''<span idstyle="how-to-install-ros-2-humble-on-ubuntu22.04color:#FF0000">Hello from Docker!</span>=== How to install ROS 2 Humble on Ubuntu22.04 ==='''
'''<ol span style="list-style-typecolor: decimal;#FF0000"><li><p>Use the install_ros.sh script to '''install_ros.sh'''</p><p>orangepi@orangepi:~$ '''install_ros.sh ros2'''</p></li><li><p>The '''install_ros.sh''' script will automatically run the '''ros2 -h''' command after installing ros2. If you can see the following print, it means This message shows that the ros2 your installation is complete.</p><p>usage: ros2 [-h] Call `ros2 <command> -h` for more detailed usage. ...</p><p>ros2 is an extensible command-line tool for ROS 2.</p><p>optional arguments:</p><p>-h, --help show this help message and exit</p><p>Commands:</p><p>action Various action related sub-commands</p><p>bag Various rosbag related sub-commands</p><p>component Various component related sub-commands</p><p>daemon Various daemon related sub-commands</p><p>doctor Check ROS setup and other potential issues</p><p>interface Show information about ROS interfaces</p><p>launch Run a launch file</p><p>lifecycle Various lifecycle related sub-commands</p><p>multicast Various multicast related sub-commands</p><p>node Various node related sub-commands</p><p>param Various param related sub-commands</p><p>pkg Various package related sub-commands</p><p>run Run a package specific executable</p><p>security Various security related sub-commands</p><p>service Various service related sub-commands</p><p>topic Various topic related sub-commands</p><p>wtf Use `wtf` as alias appears to `doctor`</p><p>Call `ros2 <command> -h` for more detailed usagebe working correctly.</p></li><li><pspan>Then you can use the '''test_ros.sh''' script to test whether ROS 2 is successfully installed. If you can see the following print, it means ROS 2 can run normally.</p><p>orangepi@orangepi:~$ '''test_ros.sh'''</p><p>[INFO] [1671174101.200091527] [talker]: Publishing: 'Hello World: 1'</p><p>[INFO] [1671174101.235661048] [listener]: I heard: [Hello World: 1]</p><p>[INFO] [1671174102.199572327] [talker]: Publishing: 'Hello World: 2'</p><p>[INFO] [1671174102.204196299] [listener]: I heard: [Hello World: 2]</p><p>[INFO] [1671174103.199580322] [talker]: Publishing: 'Hello World: 3'</p><p>[INFO] [1671174103.204019965] [listener]: I heard: [Hello World: 3]</p></li><li><p>Run the following command to open rviz2</p><p>orangepi@orangepi:~$ '''source /opt/ros/humble/setup.bash'''</p><p>orangepi@orangepi:~$ '''ros2 run rviz2 rviz2'''</p><p>[[File:zero2w-img254.png]]</p></li><li><p>Reference documentation</p><p>'''http://docs.ros.org/en/humble/index.html'''</p><p>[http://docs.ros.org/en/galactic/Tutorials.html '''http://docs.ros.org/en/humble/Installation/Ubuntu-Install-Debians.html''']</p></li></ol>
When using the docker command, if you are prompted for '''Debian11 system with Linux6.1 kernel will report GCC error when compiling kernel module. So if permission denied''', please add the current user to the docker user group so that you want to compile can run the kernel module, please use Debian12 or Ubuntu22docker command without sudo.04.'''
<span id="debianinstallation-bullseyevia-systemdocker"></span>=== Debian Bullseye system Installation via docker ===
<ol style="list-style-type: decimal;">
<li><p>Debian Bullseye is installed with the gcc compilation tool chain by defaultFirst, which please install docker and ensure that docker can directly compile C language programs in run normally. For the Linux system installation steps of docker, please refer to the instructions in the development board.</p><ol style="list-style-type: lower-alpha;"><li><p>The version of a.gcc is as follows</p><p>orangepi@orangepi:~$ [[Orange Pi Zero 2W#How to install Docker|'''gcc --versionHow to Install Docker'''</p><p>gcc (Debian 10.2.1-6) 10.2.1 20210110</p><p>Copyright (C) 2020 Free Software Foundation, Inc.</p><p>This is free software; see the source for copying conditions. There is NO</p><p>warranty; not even for MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE]] section.</p></li><li><p>Write Then you can search for the '''hello_world.c''' program in C languagedocker image of Home Assistant</p><p>orangepi@orangepi{| class="wikitable" style="width:~$ '''vim hello_world.c'''</p><p>#include <800px;stdio.h></p>" <p>int main(void)</p><p>{</p><p>printf("Hello World!\n");</p><p>return 0;</p><p>}</p></li>|-<li><p>Then compile and run '''hello_world.c'''</p>| <p>orangepi@orangepi:~$ '''gcc -o hello_world hello_world.cdocker search homeassistant'''</p><p>orangepi@orangepi:~$ '''./hello_world'''</p><p>Hello World!</p></li></ol>|}
</li>
<li><p>Debian Bullseye has Python3 installed by defaultThen use the following command to download the Docker image of Home Assistant to your local computer. The image size is about 1GB, and the download time will be relatively long. Please be patient and wait for the download to complete.</p><ol {| class="wikitable" style="list-style-typewidth: lower-alpha800px;"><li><p>The specific version of Python is as follows</p>|-| <p>orangepi@orangepi:~$ '''python3docker pull homeassistant/home-assistant'''</p><p>Using default tag: latest</p><p>latest: Pulling from homeassistant/home-assistant</p><p>be307f383ecc: Downloading</p><p>5fbc4c07ac88: Download complete</p><p>'''Python 3.9.2.... (Omit some output)''' (default, Feb 28 2021, 17</p><p>3cc6a1510c9f: Pull complete</p><p>7a4e4d5b979f: Pull complete</p><p>Digest: sha256:81d381f5008c082a37da97d8b08dd8b358dae7ecf49e62ce3ef1eeaefc4381bb</p><p>Status:03Downloaded newer image for homeassistant/home-assistant:44)latest</p><p>[GCC 10docker.2.1 20210110] on linuxio/homeassistant/home-assistant:latest</p>|}</li><li><p>Then you can use the following command to view the docker image of Home Assistant you just downloaded</p>{| class="wikitable" style="width:800px;" |-| <p>orangepi@orangepi:~$ '''docker images homeassistant/home-assistant'''</p><p>Type REPOSITORY "nbsp;help"nbsp; TAG IMAGE ID , "nbsp;copyrightCREATED "nbsp;, "nbsp;credits"nbsp; or "nbsp;license"nbsp; for more information.SIZE</p><p>homeassistant/home-assistant latest bfa0ab9e1cf5 2 months ago >nbsp;>nbsp;>nbsp;'''</pspan style="color:#FF0000">1.17GB<p/span>'''Use the Ctrl+D shortcut key to exit python's interactive mode.'''</p>|}</li><li><p>Write At this point you can run the '''hello_world.py''' program in Python languageHome Assistant docker container</p>{| class="wikitable" style="width:800px;" |-| <p>orangepi@orangepi:~$ '''vim hello_world.pydocker run -d \'''</p>:<p>print('Hello World!')'--name homeassistant \'''</p>:<p>'''--privileged \'''</lip>:<p>'''--restart=unless-stopped \'''<li/p>:<p>The result of running '''hello_world.py-e TZ=Asia/Shanghai \''' is as follows</p>:<p>orangepi@orangepi:~$ '''python3 hello_world.py-v /home/orangepi/home-assistant:/config \'''</p>:<p>Hello World!'''--network=host \'''</p>:<p>'''homeassistant/li>home-assistant:latest'''</olp>|}
</li>
<li><p>Debian Bullseye does not install Java compilation tools and operating environment by default.Then enter【the IP address of the development board: 8123】in the browser to see the Home Assistant interface</p><ol {| class="wikitable" style="listbackground-style-typecolor:#ffffdc;width: lower-alpha800px;">|-| <libig><p>You can use '''It takes a while for the following command Home Assistant container to install openjdkstart. The latest > version in Debian Bullseye If the interface below does not display normally, please wait a few seconds before refreshing it. If the following interface is not displayed normally after waiting for more than a minute, it means there is openjdk-17</p><p>orangepi@orangepi:~$ '''sudo apt install -y openjdk-17-jdk'''</p></li><li><p>After a problem with the Home Assistant installation. At this time, you can need to check whether there is a problem with the Java versionprevious installation and setting process.</p><p>orangepi@orangepi:~$ '''java --version'''</p></libig><li><p>Write the Java version of '''hello_world.java'''</p>|}<p>orangepi@orangepi:~$ '''vim hello_world.java'''</p><p>public div class hello_world</p="figure"><p>{</p><p>public static void main(String[] args)</p><p>{</p><p>System.out.println("Hello World!");</p><p>}</p><p>}</p></li><li><p>Then compile and run '''hello_world.java'''</p><p>orangepi@orangepi[File:~$ '''javac hello_worldzero2w-img180.java'''</p><p>orangepi@orangepi:~$ '''java hello_world'''</p><p>Hello World!</p></li></ol></li></ol>png]]
<span id="debian-bookworm-system"/div></li><li><p>Then enter your '''name, username''' and '''password''' and click '''Create Account'''</spanp><div class=== Debian Bookworm system ==="figure">
<span id="ubuntu-focal-system"/div></li><li><p>Then click Finish</spanp><div class=== Ubuntu Focal system ==="figure">
</li>
<li><p>Ubuntu Focal has Python3 installed by defaultThe command to stop the Home Assistant container is as follows</p><ol {| class="wikitable" style="list-style-typewidth: lower-alpha800px;"><li><p>The specific version of Python3 is as follows</p><p>orangepi@orangepi:~$ '''python3'''</p><p>Python 3.8.10 (default, Nov 14 2022, 12:59:47)</p><p>[GCC 9.4.0] on linux</p><p>Type "help", "copyright", "credits" or "license" for more information.</p><p>>>></p><p>'''Use the Ctrl+D shortcut key to exit python's interactive mode.'''</p></li><li><p>Write the '''hello_world.py''' program in Python language</p><p>orangepi@orangepi:~$ '''vim hello_world.py'''</p>|-<p>print('Hello World!')</p></li><li><p>The result of running '''hello_world.py''' is as follows</p>| <p>orangepi@orangepi:~$ '''python3 hello_world.pydocker stop homeassistant'''</p><p>Hello World!</p></li></ol>|}
</li>
<li><p>Ubuntu Focal does not have Java compilation tools and running environment installed by default.The command to delete the Home Assistant container is as follows</p><ol {| class="wikitable" style="list-style-typewidth: lower-alpha800px;"><li><p>You can use the following command to install openjdk-17</p><p>orangepi@orangepi:~$ '''sudo apt install -y openjdk|-17-jdk'''</p></li><li><p>After installation, you can check the Java version.</p>| <p>orangepi@orangepi:~$ '''java --version'''</p><p>openjdk 17.0.2 2022-01-18</p><p>OpenJDK Runtime Environment (build 17.0.2+8-Ubuntu-120.04)</p><p>OpenJDK 64-Bit Server VM (build 17.0.2+8-Ubuntu-120.04, mixed mode, sharing)</p></li><li><p>Write the Java version of '''hello_world.javadocker rm homeassistant'''</p><p>orangepi@orangepi:~$ '''vim hello_world.java'''</p><p>public class hello_world</p><p>{</p><p>public static void main(String[] args)</p><p>{</p><p>System.out.println("Hello World!");</p><p>|}</p><p>}</p></li><li><p>Then compile and run '''hello_world.java'''</p><p>orangepi@orangepi:~$ '''javac hello_world.java'''</p><p>orangepi@orangepi:~$ '''java hello_world'''</p><p>Hello World!</p></li></ol>
</li></ol>
<span id="ubuntuinstallation-jammyvia-systempython"></span> === Ubuntu Jammy system Installation via python === {| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <big>'''Before installation, please change the source of pip to a domestic source to speed up the installation of Python packages. For the configuration method, see the instructions in the section "[[Orange Pi Zero 2W#How to replace pip source in Python|How to Change the Pip Source of Python]]"'''</big>|}
<ol style="list-style-type: decimal;">
<li><p>Ubuntu Jammy is installed with the gcc compilation tool chain by default, which can directly compile C language programs in the Linux system of the development board.First install dependency packages</p><ol {| class="wikitable" style="list-style-typewidth: lower-alpha800px;"><li><p>The version of a.gcc is as follows</p>|-| <p>orangepi@orangepi:~$ '''gcc -sudo apt-versionget update'''</p><p>gcc (Ubuntu 11.3.0-1ubuntu1orangepi@orangepi:~22.04.1) $ '''11.3.0sudo apt-get install -y python3 python3-dev python3-venv \'''</p><p>Copyright (C) 2021 Free Software Foundation, Inc.</p><p>This is free software; see the source for copying conditions. There is NO</p><p>warranty; not even for MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.</p></li><li><p>Write the '''hello_world.cpython3-pip libffi-dev libssl-dev libjpeg-dev zlib1g-dev autoconf build-essential \''' program in C language</p><p>orangepi@orangepi:~$ '''vim hello_world.clibopenjp2-7 libtiff5 libturbojpeg0-dev tzdata'''</p><p>#include <stdio.h></p>|}<p>int main(void)</p><p>{</p><p>printf("| class="wikitable" style="background-color:#ffffdc;Hello World!\n"width:800px;);</p>" <p>return 0;</p>|-<p>}</p></li>| <libig><p>Then compile and run '''hello_world.cIf it is debian12, please use the following command:'''</p></big><p>orangepi@orangepi:~$ '''gcc sudo apt-o hello_world hello_world.cget update'''</p><p>orangepi@orangepi:~$ '''./hello_worldsudo apt-get install -y python3 python3-dev python3-venv \'''</p><p>Hello World!'''python3-pip libffi-dev libssl-dev libjpeg-dev zlib1g-dev autoconf build-essential \'''</p></lip>'''libopenjp2-7 libturbojpeg0-dev tzdata'''</olp>|}
</li>
<li><p>Ubuntu Jammy has Then you need to compile and install Python3 installed by default.9. For the method, please refer to the [[Orange Pi Zero 2W#Python related instructions|'''Python source code compilation and installation method''']] section.</p><ol {| class="wikitable" style="listbackground-style-typecolor:#ffffdc;width: lower-alpha800px;">|-| <libig><p>'''The specific default Python version of Debian Bullseye is Python3 is as follows</p><p>orangepi@orangepi:~$ '''python3'''</p><p>Python 3.10.6 (main9, May 29 2023, 11:10:38) [GCC 11.3.0] on linux</p><p>Type "help", "copyright", "credits" or "license" for more information.</p><p>>>></p><p>'''Use the Ctrl+D shortcut key so there is no need to exit python's interactive modecompile and install it.'''</p></li><li><p>Write the '''hello_worldThe default Python version of Ubuntu Jammy is Python3.10, so there is no need to compile and install it.py''' program in Python language</p><p>orangepi@orangepi:~$ '''vim hello_world.py'''</p><p>print('Hello World!')</p></li><li><p>The result default Python version of running '''hello_worldDebian Bookworm is Python3.py''' 11, so there is as follows</p><p>orangepi@orangepi:~$ '''python3 hello_worldno need to compile and install it.py'''</p><p>Hello World!</p></li></olbig>|}
</li>
<li><p>Ubuntu Jammy does not install Java compilation tools and operating Then create a Python virtual environment by default.</p><ol {| class="wikitable" style="listbackground-style-typecolor:#ffffdc;width: lower-alpha800px;">|-| <libig><p>You can use '''Debian Bookworm is python3.11, please remember to replace the following corresponding command to install openjdk-18.'''</p></big>|}{| class="wikitable" style="width:800px;" |-| <p>orangepi@orangepi:~$ '''sudo apt install -y openjdk-18-jdkmkdir /srv/homeassistant'''</p></li><li><p>After installation, you can check the Java version.orangepi@orangepi:~$ '''sudo chown orangepi:orangepi /srv/homeassistant'''</p><p>orangepi@orangepi:~$ '''java --versioncd /srv/homeassistant'''</p><p>openjdk 18orangepi@orangepi:~$ '''python3.09 -m venv .2-ea 2022-07-19'''</p><p>OpenJDK Runtime Environment (build 18.0.2-ea+9-Ubuntu-222.04)orangepi@orangepi:~$ '''source bin/activate'''</p><p>OpenJDK 64-Bit Server VM (build 18.0.2-ea+9-Ubuntu-222.04, mixed mode, sharinghomeassistant)orangepi@orangepi:/srv/homeassistant$</p>|}</li><li><p>Write Then install the Java version of '''hello_world.java'''required Python packages</p>{| class="wikitable" style="width:800px;" |-| <p>(homeassistant) orangepi@orangepi:~/srv/homeassistant$ '''vim hello_world.javapython3 -m pip install wheel'''</p><p>public class hello_world|}</pli><p>{</pli><p>public static void main(String[] args)Then you can install Home Assistant Core</p><p>{</p>| class="wikitable" style="width:800px;" |-| <p>System.out.println("Hello World!"homeassistant);orangepi@orangepi:/srv/homeassistant$ '''pip3 install homeassistant'''</p><p>|}</p><p>}</p></li><li><p>Then compile and enter the following command to run '''hello_world.java'''Home Assistant Core</p>{| class="wikitable" style="width:800px;" |-| <p>(homeassistant) orangepi@orangepi:~/srv/homeassistant$ '''javac hello_world.javahass'''</p>|}</li><li><p>orangepi@orangepi:~$ Then enter【'''java hello_worlddevelopment board IP address: 8123'''】 in the browser to see the Home Assistant interface</p>{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <pbig>Hello World!</p>'''When you run the hass command for the first time, some libraries and dependency packages necessary for operation will be downloaded, installed and cached. This process may take several minutes. Note that you cannot see the Home Assistant interface in the browser at this time. Please wait for a while and then refresh it.'''</lip></olbig>|}</li></oldiv class="figure">
<span id="method-to-upload-files-to-the-development-board-linux-system-in-ubuntu-pc"/div></li></spanol>=== Method to upload files to the development board Linux system in Ubuntu PC ===
<span id="howopencv-toinstallation-uploadmethod"></span> == OpenCV installation method == <span id="use-filesapt-usingto-scpinstall-commandopencv"></span>==== How Use apt to upload files using scp command =install OpenCV ===
<ol style="list-style-type: decimal;">
<li><p>Use The installation command is as follows</p>{| class="wikitable" style="width:800px;" |-| <p>orangepi@orangepi:~$ '''sudo apt-get update'''</p><p>orangepi@orangepi:~$ '''sudo apt-get install -y libopencv-dev python3-opencv'''</p>|}</li><li><p>Then use the scp following command to upload files to print the Linux system version number of the development board in Ubuntu PCOpenCV. The specific command output is normal, indicating that the OpenCV installation is as followssuccessful.</p>
<ol style="list-style-type: lower-alpha;">
<li><p>'''file_pathThe version of OpenCV in Ubuntu22.04 is as follows: '''Needs to be replaced with the path of the file to > be uploaded</p></li><li>{| class="wikitable" style="width:800px;" |-| <p>'''orangepi@orangepi: ~$ '''This is the user name of the development board's python3 -c >quot; Linux system. It can also be replaced with something else, >import cv2; such as rootprint(cv2.</p></li><li><p>'''192.168.xx.xx:''' This is the IP address of the development __version__)>quot; board. Please modify it according to the actual situation.</p></li><li><p>'''/home/orangepi:''' The path in the development board Linux > system can also be modified to other paths.</p><p>test@test:~$ '''scp file_path orangepi@1924.1685.xx.xx:/home/orangepi/4'''</p></li></ol>|}
</li>
<li><p>If you want to upload a folder, you need to add the -r parameterThe version of OpenCV in Ubuntu20.04 is as follows:</p>{| class="wikitable" style="width:800px;" |-| <p>testorangepi@testorangepi:~$ '''scp python3 -r dir_path orangepi@192c "import cv2; print(cv2.168__version__)"'''</p><p>'''4.xx2.xx0'''</p>|}</li><li><p>The version of OpenCV in Debian11 is as follows:</home/p>{| class="wikitable" style="width:800px;" |-| <p>orangepi@orangepi:~$ '''python3 -c "import cv2; print(cv2.__version__)"'''</p><p>'''4.5.1'''</p>|}</li><li><p>There are more usages The version of scp, please use the following command to view the man manualOpenCV in Debian12 is as follows:</p>{| class="wikitable" style="width:800px;" |-| <p>orangepi@orangepi:~$ '''python3 -c "import cv2; print(cv2.__version__)"'''</p><p>'''4.6.0'''</p>|}</li></ol></li></ol> <span id="set-up-the-chinese-environment-and-install-the-chinese-input-method"></span> == Set up the Chinese environment and install the Chinese input method ==
<span id="howdebian-tosystem-uploadinstallation-files-using-filezillamethod"></span>==== How to upload files using filezilla =Debian system installation method ===
<ol style="list-style-type: decimal;">
<li><p>First install filezilla in Ubuntu PCset the default '''locale''' to Chinese</p><ol style="list-style-type: lower-alpha;"><li><p>Enter the following command to start configuring '''locale'''</p>{| class="wikitable" style="width:800px;" |-| <p>testorangepi@testorangepi:~$ '''sudo apt install dpkg-y filezillareconfigure locales'''</p>|}</li><li><p>Then select '''zh_CN.UTF-8 UTF-8''' in the pop-up interface (use the up and down keys on the keyboard to move up and down, use the following space bar to select, and finally use the Tab key to move the cursor to '''<OK>''', and then return Car can be used)</p><p>[[File:zero2w-img186.png]]</p></li><li><p>Then set the default '''locale''' to '''zh_CN.UTF-8'''</p><p>[[File:zero2w-img187.png]]</p></li><li><p>After exiting the interface, the '''locale''' setting will begin. The output displayed on the command to open filezillaline is as follows:</p>{| class="wikitable" style="width:800px;" |-| <p>testorangepi@testorangepi:~$ '''filezillasudo dpkg-reconfigure locales'''</p><p>Generating locales (this might take a while)...</p>:<p>en_US.UTF-8... done</p>:<p>zh_CN.UTF-8... done</p><p>Generation complete.</p>|}</li></ol></li><li><p>Then open '''Input Method'''</p><p>[[File:zero2w-img188.png]]</p></li><li><p>Then select '''OK'''</p><p>[[File:zero2w-img189.png]]</p></li><li><p>Then select '''Yes'''</p><p>[[File:zero2w-img190.png]]</p></li><li><p>Then select '''fcitx'''</p><p>[[File:zero2w-img191.png]]</p></li><li><p>Then select '''OK'''</p><p>[[File:zero2w-img192.png]]</p></li><li><p>The interface after opening filezilla is '''<span style="color:#FF0000">Then restart the Linux system to make the configuration take effect.</span>'''</p></li><li><p>Then open '''Fcitx configuration'''</p><p>[[File:zero2w-img193.png]]</p></li><li><p>Then click the + sign as shown in the picture below</p><p>[[File:zero2w-img194. At this time, the remote site on the right is empty.png]]</p></li><li><p>Then search '''Google Pinyin''' and click '''OK'''</p>
<div class="figure">
[[File:zero2w-img255img195.png]]
</div></li>
<li><p>Then put '''Google Pinyin''' on top</p><p>[[File:zero2w-img196.png]]</p><p>[[File:zero2w-img197.png]]</p></li><li><p>Then open the '''Geany''' editor to test the Chinese input method</p><p>[[File:zero2w-img198.png]]</p></li><li><p>The Chinese input method of connecting the development board test is as shown follows</p><p>[[File:zero2w-img199.png]]</p></li><li><p>You can switch between Chinese and English input methods through the '''Ctrl+Space''' shortcut key</p></li><li><p>If you need the entire system to be displayed in Chinese, you can set all variables in '''/etc/default/locale''' to '''zh_CN.UTF-8'''</p>{| class="wikitable" style="width:800px;" |-| <p>orangepi@orangepi:~$ '''sudo vim /etc/default/locale'''</p><p># File generated by update-locale</p><p>LC_MESSAGES='''<span style="color:#FF0000">zh_CN.UTF-8</span>'''</p><p>LANG='''<span style="color:#FF0000">zh_CN.UTF-8</span>'''</p><p>LANGUAGE='''<span style="color:#FF0000">zh_CN.UTF-8</span>'''</p>|}</li><li><p>Then '''<span style="color:#FF0000">restart the figure belowsystem</span>''' and you will see that the system is displayed in Chinese.</p><p>[[File:zero2w-img200.png]]</p></li></ol>
<div classspan id="figureinstallation-method-of-ubuntu-20.04-system"></span>
<ol style="list-style-type: decimal;"><li><p>First open '''Language Support'''</p><p>[[File:zero2w-img201.png]]</p></li><li><p>Then find the '''Chinese (China)''' option</p><p>[[File:zero2w-img202.png]]</p></divli><li><p>Then please use the left button of the mouse to select '''Chinese (China)''' and hold it down, then drag it up to the starting position. After dragging, the display will be as shown below:</p><p>[[File:zero2w-img203.png]]</p></li>{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <big>'''Note that this step is not easy to drag, please be patient and try it a few times.'''</big>|}</ol><ol start="54" style="list-style-type: decimal;"><li><p>Then choose select '''Apply System-Wide''' to apply the Chinese settings to the entire system</p><p>[[File:zero2w-img204.png]]</p></li><li><p>Then set the '''save the passwordKeyboard input method system''' and click system to '''OKfcitx'''</p><p>[[File:zero2w-img257img205.png]]</p></li><li><p>'''<span style="color:#FF0000">Then restart the Linux system to make the configuration take effect</span>'''</p></li><li><p>After re-entering the system, please select '''Always trust this hostDo not ask me again''' in the following interface, and click then please decide according to your own preferences whether the standard folder should also be updated to Chinese</p><p>[[File:zero2w-img206.png]]</p></li><li><p>Then you can see that the desktop is displayed in Chinese</p><p>[[File:zero2w-img207.png]]</p></li><li><p>Then we can open '''OKGeany'''to test the Chinese input method. The opening method is as shown in the figure below</p><p>[[File:zero2w-img208.png]]</p></li><li><p>After opening '''Geany''', the English input method is still the default. We can switch to the Chinese input method through the '''Ctrl+Space''' shortcut key, and then we can input Chinese.</p><p>[[File:zero2w-img209.png]]</p></li></ol>
<div classspan id="figureinstallation-method-of-ubuntu-22.04-system"></span>
<ol style="list-style-type: decimal;">
<li><p>First open '''Language Support'''</p>
<p>[[File:zero2w-img201.png]]</p></li>
<li><p>Then find the '''Chinese (China)''' option</p>
<p>[[File:zero2w-img210.png]]</p></li>
<li><p>Then please use the left button of the mouse to select '''Chinese (China)''' and hold it down, then drag it up to the starting position. After dragging, the display will be as shown below:</p>
<p>[[File:zero2w-img211.png]]</p></li>
{| class="wikitable" style="background-color:#ffffdc;width:800px;"
|-
|
<big>'''Note that this step is not easy to drag, please be patient and try it a few times.'''</big>
|}
</ol>
<ol start="4" style="list-style-type: decimal;">
<li><p>Then select '''Apply System-Wide''' to apply the Chinese settings to the entire system</p>
<p>[[File:zero2w-img212.png]]</p></li>
<li><p>'''<span style="color:#FF0000">Then restart the Linux system to make the configuration take effect</span>'''</p></li>
<li><p>After re-entering the system, please select '''Do not ask me again''' in the following interface, and then please decide whether the standard folder should also be updated to Chinese according to your own preferences.</p>
<p>[[File:zero2w-img206.png]]</p></li>
<li><p>Then you can see that the desktop is displayed in Chinese</p>
<p>[[File:zero2w-img207.png]]</p></li>
<li><p>Then open the Fcitx5 configuration program</p>
<p>[[File:zero2w-img213.png]]</p></li>
<li><p>Then choose to use Pinyin input method</p>
<div class="figure">
[[File:zero2w-img259img214.png]]
</div></li><li><p>The interface after selection is as shown below, then click OK</p><ol start="8" style="listp>[[File:zero2w-style-type: decimal;"img215.png]]</p></li><li><p>Then select the path to be uploaded we can open '''Geany''' to test the development board on Chinese input method. The opening method is as shown in the right side of figure below</p><p>[[File:zero2w-img208.png]]</p></li><li><p>After opening '''Geany''', the filezilla software, select English input method is still the file default. We can switch to be uploaded in Ubuntu PC on the left side of Chinese input method through the filezilla software, right-click the mouse'''Ctrl+Space''' shortcut key, and then click the upload option to start uploading the file to the development boardwe can enter Chinese.</p><p>[[File:zero2w-img216.png]]</p></li></ol> <div class="figure">
<span id="methodremote-tologin-uploadusing-files-from-windows-pc-to-development-board-linux-systemnomachine"></span>=== Method to upload files from Windows PC to development board Linux system Remote login using NoMachine ===
{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <big>'''Please ensure that the Ubuntu or Debian system installed on the development board is a <span idstyle="how-to-upload-files-using-filezilla-1color:#FF0000">desktop version</span>==== How of the system. In addition, NoMachine also provides detailed usage documentation. It is strongly recommended to read this document thoroughly to upload files using filezilla ====become familiar with the use of NoMachine. The document link is as follows:'''
'''https://knowledgebase.nomachine.com/DT10R00166'''</big>|}{| class="wikitable" style="background-color:# First download ffffdc;width:800px;" |-| <big>'''NoMachine supports Windows, Mac, Linux, iOS and Android platforms, so we can remotely log in and control the installation file Orange Pi development board through NoMachine on a variety of devices. The following demonstrates how to remotely log in to the Linux system desktop of the Orange Pi development board through NoMachine in Windows version . For installation methods on other platforms, please refer to NoMachine's official documentation.'''</big>|}{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <big>'''Before operating, please make sure that the Windwos computer and the development board are in the same LAN, and that you can log in to the Ubuntu or Debian system of the filezilla softwaredevelopment board through ssh normally. The download link is as follows'''</big>|}
<ol style="list-style-type: decimal;"><li><p>First download the installation package of the NoMachine software Linux '''<span style="color:#FF0000">arm64</span>''' deb version, and then install it into the Linux system of the development board</p><ol style="list-style-type: lower-alpha;"><li>Since H618 is an ARMv8 architecture SOC and the system we use is Ubuntu or Debian, we need to download the '''NoMachine for ARM ARMv8 DEB''' installation package. The download link is as follows:</li>{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <big>'''Note that this download link may change, please look for the Armv8/Arm64 version of the deb package.'''</big>|}{| class="wikitable" style="width:800px;" |-| [https://filezilla-projectwww.nomachine.orgcom/download/download.php?type&id=112&s=client ARM '''https://filezilla-projectdownloads.nomachine.orgcom/download.php/?typeid=118&distro=clientARM''']|}
[[File:zero2w-img261img217.png]]</ol><div classol start="2" style="figurelist-style-type: lower-alpha;"><li><p>In addition, you can also download the '''NoMachine''' installation package from the official tool.</p><p>[[File:zero2w-img262img218.png]]</p><p>First enter the '''remote login software-NoMachine''' folder</p><p>[[File:zero2w-img219.png]]</p><p>Then download the arm64 version of the deb installation package</divp><ol start="2" style="listp>[[File:zero2w-style-type: decimal;"img220.png]]</p></li><li><p>The Then upload the downloaded installation package is as shown below, then double-click '''nomachine_x.x.x_x_arm64.deb''' to the Linux system of the development board</p></li><li><p>Then use the following command to install it directly'''NoMachine''' in the Linux system of the development board</p>{| class="wikitable" style="width:800px;" |-| <p>orangepi@orangepi:~$ '''FileZilla_Server_1sudo dpkg -i nomachine_x.5x.1_win64-setupx_x_arm64_arm64.exedeb'''</p>|}</li></ol></li></ol>During <ol start="2" style="list-style-type: decimal;"><li>Then download the installation process, please select package of the Windows version of the NoMachine software. The download address is as follows</li>{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <big>'''DeclineNote that this download link may change.''' on the following installation interface, and then select </big>|}{| class="wikitable" style="width:800px;" |-| '''Next>https://downloads.nomachine.com/download/?id=9'''|}
[[File:zero2w-img221.png]]<div class/ol><ol start="3" style="list-style-type: decimal;"><li><p>Then install NoMachine in Windows. '''Please restart your computer after installation.'''</p></li><li><p>Then open '''NoMachine''' in Window</p><p>[[File:zero2w-img222.png]]</p></li><li><p>After NoMachine is started, it will automatically scan other devices with NoMachine installed on the LAN. After entering the main interface of NoMachine, you can see that the development board is already in the list of connectable devices, and then click on the location shown in the red box in the picture below You can now log in to the Linux system desktop of the development board.</p><p>[[File:zero2w-img223.png]]</p></li><li><p>Then click '''OK'''</p><p>[[File:zero2w-img224.png]]</p></li><li><p>Then enter the username and password of the development board Linux system in the corresponding positions in the figure"below, and then click OK to start logging in.</p><p>[[File:zero2w-img225.png]]</p></li><li><p>Then click OK in the next interface.</p></li><li><p>Finally you can see the desktop of the development board Linux system</p><p>[[File:zero2w-img226.png]]</p></li></ol>
<div class="figure"p>New 'X' desktop is orangepi:1</p>
<p>Creating default startup script /divroot/.vnc/xstartup</p><ol start="6" style="list-style-type: decimal;"p>Starting applications specified in /root/.vnc/xstartup</p><lip>Then select '''Always trust this host''' and click '''OK'''<Log file is /root/.vnc/li>orangepi:1.log</olp>
<div class="figure"p>New 'X' desktop is orangepi:1</p>
<p>Starting applications specified in /root/.vnc/xstartup</p><p>Log file is /root/.vnc/divorangepi:1.log</p>|}</li><li><p>The steps to use MobaXterm software to connect to the development board Linux system desktop are as follows:</p><ol start="8" style="list-style-type: decimallower-alpha;"><li>Then First click Session, then select VNC, then fill in the path to be uploaded to IP address and port of the development board on the right side of the filezilla software, select the file to be uploaded on the Windows PC on the left side of the filezilla software, right-click the mouse, and then finally click the upload option OK to start uploading the file to the development boardconfirm.</li></ol>
<div class="figure">
[[File:zero2w-img268img227.png]]
</div></ol><ol start="92" style="list-style-type: decimallower-alpha;"><li><p>After Then enter the upload is completed, you can go to the corresponding path in the development board Linux system to view the uploaded fileVNC password set earlier</p><p>[[File:zero2w-img228.png]]</p></li><li><p>The method of uploading a folder After successful login, the interface is the same displayed as shown below, and then you can remotely operate the method desktop of uploading a file, so I won't go into details herethe development board Linux system.</p></li></ol>
[[File:zero2w-img229.png]]</ol></li></ol><span id="instructionsqt-forinstallation-using-the-logo-on-and-off-the-machinemethod"></span>== Instructions for using the logo on and off the machine ==
<ol style="list-style-type: decimal;">
<li><p>First run '''orangepi-config'''. Ordinary users remember to add '''sudo''' permissions.</p><p>orangepi@orangepi:~$ '''sudo orangepi-config'''</p></li><li><p>Then select '''System'''</p><p>[[File:zero2w-img80.png]]</p></li><li><p>Then select '''Hardware'''</p><p>[[File:zero2w-img81.png]]</p></li><li><p>Then use Use the keyboard's arrow keys following script to locate the position shown in the picture below, install QT5 and then use the '''space''' to select the dtbo configuration of the SPI you want to open.</p><p>[[File:zero2w-img270.png]]QT Creator</p></li><li><p>Then select '''<Save>''' to save</p><p>[[File:zero2w-img83.png]]</p></li><li><p>Then select '''<Back>'''</p><p>[[File:zero2w-img84.png]]</p></li><li><p>Then select '''<Reboot>''' to restart the system to make the configuration take effect.</p><p>[[File:zero2w-img85.png]]</p></li></ol> <span id{| class="how-to-shut-down-and-restart-the-development-boardwikitable"></span>== How to shut down and restart the development board == <ol style="list-style-typewidth: decimal800px;"><li><p>During the running of the Linux system, if you directly unplug the power supply, it may cause the file system to lose some data. It is recommended to use the '''poweroff''' command to shut down the Linux system of the development board before powering off, and then unplug the power supply.</p>|-| <p>orangepi@orangepi:~$ '''sudo poweroffinstall_qt.sh'''</p><p>'''Note that after turning off the development board, you need to unplug and replug the power supply before it can be turned on.'''</p>|}</li><li><p>In addition to using the poweroff command to shut downAfter installation, you can also use the power on/off button on the expansion board to shut down.</p><p>[[File:zero2w-img269.png]]</p><p>'''Note that Linux 5.4 requires manual configuration of the power on/off button before it can QT version number will be usedautomatically printed. For the opening method, please refer to the method of opening the power button in Linux5.4.'''</p></li><li><p>Use the '''reboot''' command to restart the Linux system in the development board</p><p>orangepi@orangepi:~$ '''sudo''' '''reboot'''</p></li></ol> <span id="linux-sdkorangepi-build-usage-instructions"></span> = '''Linux SDK——orangepi-build usage instructions''' = <span id="compilation-system-requirements"></span>== Compilation system requirements == The Linux SDK, '''orangepi-build''', only supports running on X64 computers with '''Ubuntu 22.04''' installed. Therefore, before downloading orangepi-build, please first ensure that the Ubuntu version installed on your computer is Ubuntu 22.04. The command to check the Ubuntu version installed on the computer is as follows. If the Release field does not display '''22.04''', it means that the Ubuntu version currently used does not meet the requirements. Please change the system before performing the following operations. test@test:~$ '''lsb_release -a''' No LSB modules are available. Distributor ID: Ubuntu Description: Ubuntu 22.04 LTS Release: '''22.04''' Codename: '''jammy''' If the computer is installed with a Windows system and does not have Ubuntu 22.04 installed on it, you can consider using'''VirtualBox''' or '''VMware''' to install an Ubuntu 22.04 virtual machine in the Windows system. But please note, do not compile orangepi-build on the WSL virtual machine, because orangepi-build has not been tested in the WSL virtual machine, so there is no guarantee that orangepi-build can be used normally in WSL. In addition, please do not compile the Linux system on the development board. Use orangepi-build. The installation image download address of Ubuntu 22.04 amd64 version is: [https://repo.huaweicloud.com/ubuntu-releases/21.04/ubuntu-21.04-desktop-amd64.iso '''https://mirrors.tuna.tsinghua.edu.cn/ubuntu-releases/22.04/ubuntu-22.04-desktop-amd64.iso'''] After installing Ubuntu 22.04 on your computer or virtual machine, please first set the software source of Ubuntu 22.04 to Tsinghua source (or other domestic sources that you think is fast), otherwise it is easy to make errors due to network reasons when installing the software later. The steps to replace Tsinghua Source are as follows:
<ol style="list-style-type: lower-alpha;">
<li>For the method of replacing Tsinghua Source, please refer to the instructions on this page.</lip></ol> [https://mirrorsThe qt version that comes with Ubuntu20.tuna.tsinghua.edu.cn/help/ubuntu/ 04 is '''https://mirrors.tuna.tsinghua5.edu12.cn/help/ubuntu/8''']</p> <ol start{| class="2wikitable" style="list-style-typewidth: lower-alpha800px;"><li>Note that the Ubuntu version needs to be switched to 22.04.</li></ol> [[File:zero2w|-img271.png]]| <ol start="3" style="list-style-type: lower-alpha;"><lip>The contents of the '''/etc/apt/sources.list''' file that need to be replaced are:</li></ol> testorangepi@testorangepi:~$ '''sudo mv /etc/apt/sourcesinstall_qt.list cat /etc/apt/sources.list.baksh''' test@test:~$ '''sudo vim </etc/apt/sources.list'''p> # The source code image is commented by default to improve apt update speed. You can uncomment it yourself if necessary. deb https://mirrors.tuna.tsinghua<p>.edu.cn/ubuntu/ jammy main restricted universe multiverse # deb-src https://mirrors.tuna.tsinghua.edu.cn/ubuntu/ jammy main restricted universe multiverse deb https://mirrors.tuna.tsinghua.edu.cn/ubuntu/ jammy-updates main restricted universe multiverse # deb-src https://mirrors.tuna.tsinghua.edu.cn/ubuntu/ jammy-updates main restricted universe multiverse deb https://mirrors.tuna.tsinghua.edu.cn/ubuntu/ jammy-backports main restricted universe multiverse # deb-src https://mirrors.tuna.tsinghua.edu.cn/ubuntu/ jammy-backports main restricted universe multiverse deb https://mirrors.tuna.tsinghua.edu.cn</ubuntu/ jammy-security main restricted universe multiverse # deb-src https://mirrors.tuna.tsinghua.edu.cn/ubuntu/ jammy-security main restricted universe multiverse # Pre-release software source, not recommended to be enabled # deb https://mirrors.tuna.tsinghua.edu.cn/ubuntu/ jammy-proposed main restricted universe multiverse # deb-src https://mirrors.tuna.tsinghua.edu.cn/ubuntu/ jammy-proposed main restricted universe multiverse <ol start="4" style="list-style-type: lower-alpha;"p><lip>After the replacement, you need to update the package information and ensure that no errors are reportedQMake version 3.1</lip></olp> test@test:~$ ''Using Qt version 'sudo apt-get update''' <ol start="5" span style="list-style-typecolor: lower-alpha;#FF0000">5.12.8<li/span>'''In addition, since the source code of the kernel and Uboot are stored on GitHub, it is very important to ensure that the computer can download the code from GitHub normally when compiling the image.'''<in /usr/li><lib/ol> <span id="obtain-the-source-code-ofaarch64-linux-sdk">gnu</spanp>== Obtain the source code of linux sdk ==|}</li><span id="download-orangepi-build-from-github"li></spanp>=== Download orangepi-build from github === Linux sdk refers to the orangepi-build set of codesThe QT version that comes with Ubuntu22. Orangepi-build 04 is modified based on the armbian build compilation system. Multiple versions of Linux images can be compiled using orangepi-build. Use the following command to download the orangepi-build code: test@test:~$ '''sudo apt-get update''' test@test:~$ '''sudo apt-get install -y git''' test@test:~$ '''git clone https://github5.com/orangepi-xunlong/orangepi-build.git -b next''' '''Note that when using the H618 Soc development board, you need to download the source code of the next branch of orangepi-build. The above git clone command needs to specify the branch of the orangepi-build source code as next15.3''' <div class="figure"> [[File:zero2w-img272.png]] </divp>'''When downloading the orangepi-build code through the git clone command, you do not need to enter the user name and password of the github account (the same is true for downloading other codes in this manual). If after entering the git clone command, Ubuntu PC prompts you to enter the user name of the github account. The name and password are usually entered incorrectly in the address of the orangepi-build warehouse behind git clone. Please carefully check whether there are any errors in the spelling of the command, rather than thinking that we have forgotten to provide the username and password of the github account.''' The u-boot and linux kernel versions currently used by the H618 series development boards are as follows: {| class="wikitable" style="width:800px;"
|-
| <p>orangepi@orangepi:~$ '''branchinstall_qt.sh'''</p><p>......</p><p>QMake version 3.1</p><p>Using Qt version '''<span style="color:#FF0000">5.15.3</span>''' in /usr/lib/aarch64-linux-gnu</p>| }</li><li><p>The QT version that comes with Debian11 is '''5.15.2''u'</p>{| class="wikitable" style="width:800px;" |-boot Version| <p>orangepi@orangepi:~$ '''install_qt.sh'''</p>| <p>......</p><p>QMake version 3.1</p><p>Using Qt version '''<span style="color:#FF0000">5.15.2</span>'''in /usr/lib/aarch64-linux Kernel -gnu</p>|}</li><li><p>The QT versionthat comes with Debian12 is '''5.15.8'''</p>{| class="wikitable" style="width:800px;"
|-
| <p>orangepi@orangepi:~$ '''currentinstall_qt.sh'''</p>| <p>......</p><p>QMake version 3.1</p><p>Using Qt version '''u-boot v2018<span style="color:#FF0000">5.15.058</span>'''in /usr/lib/aarch64-linux-gnu</p>| }</li></ol></li><li><p>Then you can see the QT Creator startup icon in '''linux5.4Applications'''</p><p>[[File:zero2w-img230.png]]</p><p>You can also use the following command to open QT Creator</p>{| class="wikitable" style="width:800px;"
|-
| '''next'''| '''u-boot v2021.07'''| <p>orangepi@orangepi:~$ '''linux6.1qtcreator'''</p>
|}
</li>'''<li><p>The branch mentioned here interface after QT Creator is opened is not the same thing as the branch follows</p><p>[[File:zero2w-img231.png]]</p></li><li><p>The version of orangepiQT Creator is as follows</p><ol style="list-style-type: lower-build source code, please donalpha;"><li><p>The default version of QT Creator in '''t get confused. This branch is mainly used to distinguish different kernel source code versionsUbuntu20.04'''is as follows</p><p>[[File:zero2w-img232.png]]</p></li><li><p>The default version of QT Creator in '''We define the linux5Ubuntu22.4 bsp kernel currently provided by Allwinner 04''' is as the current branchfollows</p><p>[[File:zero2w-img233. png]]</p></li><li><p>The latest linux6.1 LTS kernel default version of QT Creator in '''Debian11''' is defined as the next branchfollows</p><p>[[File:zero2w-img234.png]]</p></li><li><p>The default version of QT Creator in '''Debian12''' is as follows</p><p>[[File:zero2w-img235.png]]</p></li></ol>After downloading, the following files and folders will be included:</li><li><p>Then set up QT</p>
<ol style="list-style-type: lower-alpha;">
<li><p>First open '''buildHelp'''->'''About Plugins...sh'''.</p><p>[[File: Compile startup scriptzero2w-img236.png]]</p></li><li><p>Then remove the check mark of '''externalClangCodeModel'''</p><p>[[File: Contains configuration files needed to compile the image, specific scripts, and source code of some programs, etczero2w-img237.png]]</p></li><li><p>'''LICENSE<span style="color:#FF0000">After setting up, you need to restart QT Creator</span>''': GPL 2 license file</p></li><li><p>Then make sure the GCC compiler used by QT Creator. If the default is Clang, please change it to GCC.</p>{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <big><p>'''READMEDebian12 please skip this step.md'''</p></big>|}<p>[[File:zero2w-img238.png]]</p><p>[[File:zero2w-img239.png]]</p></li></ol></li><li><p>Then you can open a sample code</p><p>[[File: orangepizero2w-build documentationimg240.png]]</p></li><li><p>After clicking on the sample code, the corresponding instruction document will automatically open. You can read the instructions carefully.</p><p>[[File:zero2w-img241.png]]</p></li><li><p>Then click '''scriptsConfigure Project'''</p><p>[[File:zero2w-img242.png]]</p></li><li><p>Then click the green triangle in the lower left corner to compile and run the sample code</p><p>[[File: Common script zero2w-img243.png]]</p></li><li><p>After waiting for compiling linux imagesa period of time, the interface shown in the figure below will pop up, which means that QT can compile and run normally.</p><p>[[File:zero2w-img244.png]]</p></li><li><p>References</olp>{| class="wikitable" style="width:800px;" test@test|-| <p>[https:~/orangepi-build$ /wiki.qt.io/Install_Qt_5_on_Ubuntu '''lshttps://wiki.qt.io/Install_Qt_5_on_Ubuntu''']</p><p>[https://download.qt.io/archive/qtcreator '''https://download.qt.io/archive/qtcreator''']</p><p>[https://download.qt.io/archive/qt '''buildhttps://download.sh external LICENSE READMEqt.md scriptsio/archive/qt''']</p>|}</li></ol>
::[[File:zero2w-img273img245.png]]
::{| class="wikitable" style="width:800px;" |-| [httpshttp://mirrors.tuna.tsinghuadocs.eduros.cn/armbian-releases/_toolchainorg/ '''httpshttp://mirrors.tuna.tsinghuadocs.eduros.cn/armbian-releases/_toolchain/org''']
'''gcc-arm-11The install_ros.2-2022sh script will try to modify /etc/hosts and automatically run the following commands.02-x86_64-aarch64-none-However, this method cannot guarantee that github can be accessed normally every time. If install_ros.sh prompts the following error after installing ros1, please find other ways to allow the linux-gnusystem of the development board to access github normally, and then manually run the following Order.'''
'''gcc-arm-11https://raw.githubusercontent.2com/ros/rosdistro/master/rosdep/osx-2022homebrew.02-x86_64-aarch64-none-linux-gnuyaml'''
'''<ol span style="list-style-typecolor: lower-alpha;#FF0000"><li>v2018.05</li>ERROR: error loading sources list:</olspan>'''
::'''gcc<span style="color:#FF0000">The read operation timed out</span>'''</big>|}{| class="wikitable" style="width:800px;" |-linaro-7| orangepi@orangepi:~$ '''source /opt/ros/noetic/setup.4.1-2019.02-x86_64_arm-linux-gnueabibash'''
Hit https://githubraw.githubusercontent.com/orangepi-xunlongros/rosdistro/u-boot-orangepimaster/treerosdep/'''v2018base.05-h618'''yaml
Hit https://githubraw.githubusercontent.com/orangepi-xunlongros/rosdistro/u-boot-orangepimaster/treerosdep/'''v2021ruby.07-sunxi'''yaml
<ol startdiv class="4figure" style="list-style-type: lower-alpha;"><li>The package name of the compiled u-boot deb package</li></ol>
[ o.k. ] [File name [ '''linux:zero2w-u-boot-next-orangepizero2w_ximg249.x.x_arm64.deb''' png]]
</div></ol><ol start="59" style="list-style-type: lower-alphadecimal;"><li>Compilation <p>At this time, press the direction keys on the keyboard to control the little turtle to move up, down, left, and right.</p><p>[[File:zero2w-img250.png]]</p></li></ol>
<ol style="list-style-type: decimal;"><li><p>The currently active version of ROS 2 is as follows, the recommended version is '''Galactic Geochelone'''</p><p>[[ oFile:zero2w-img251.kpng]]</p><p>[[File:zero2w-img252. png] Repeat Build Options ]</p>{| class="wikitable" style="width:800px;" |-| <p>[ http://docs.ros.org/ '''http://docs.ros.org''']</p><p>'''http://docs.ros.org/en/galactic/Releases.html'''</p>|}</li><li><p>The link to the official installation documentation of ROS 2 '''Galactic Geochelone''' is as follows:</p>{| class="wikitable" style="width:800px;" |-| <p>'''docs.ros.org/en/galactic/Installation.html'''</p><p>'''http://docs.ros.org/en/galactic/Installation/Ubuntu-Install-Debians.html'''</p>|}</li><li><p>In the official installation documentation of ROS 2 '''Galactic Geochelone''sudo ', Ubuntu Linux recommends using Ubuntu20.04, so please ensure that the system used by the development board is the '''<span style="color:#FF0000">Ubuntu20.04 desktop system</buildspan>'''. There are several ways to install ROS 2. The following demonstrates how to install ROS 2 '''Galactic Geochelone''' through '''Debian packages'''.</p></li><li><p>Use the '''install_ros.sh BOARD''' script to install ros2</p>{| class=orangepizero2w BRANCH"wikitable" style=next BUILD_OPT=u"width:800px;" |-| <p>orangepi@orangepi:~$ '''install_ros.sh ros2'''</p>|}</li><li><p>The '''install_ros.sh''' script will automatically run the '''ros2 -booth''' command after installing ros2. If you can see the following print, it means that the ros2 installation is complete.</p>{| class="wikitable" style="width:800px;" |-| <p>usage: ros2 [-h]Call `ros2 <command> -h` for more detailed usage. ...</p>
<ol start="8" style="list-style-typep>optional arguments: decimal;"</p>:<lip>When the orangepi-bulid compilation system compiles the u-boot source codeh, it will first synchronize the u-boot source code with the u-boot source code of the github server. Therefore, if you want to modify the u-boot source code, you first need to turn off the download help show this help message and update function of the source code. ('''You need to completely compile u-boot before you can turn off this function, otherwise it will prompt that the source code of u-boot cannot be found'''), otherwise the modifications will be restored. The method is as follows:</li>exit</olp>
:<p>Call `ros2 <command> -h` for more detailed usage.</p>|}</li><li><p>Then you can use the '''test_ros.sh''' script to test whether ROS 2 is installed successfully.If you can see the following print, it means ROS 2 can run normally...</p> <ol start{| class="9wikitable" style="list-style-typewidth: decimal800px;"|-| <p>orangepi@orangepi:~$ '''test_ros.sh'''</p><p>[INFO] [1671174101.200091527] [talker]: Publishing: 'Hello World: 1'</p><p>[INFO] [1671174101.235661048] [listener]: I heard: [Hello World: 1]</p><p>[INFO] [1671174102.199572327] [talker]: Publishing: 'Hello World: 2'</p><p>[INFO] [1671174102.204196299] [listener]: I heard: [Hello World: 2]</p><p>[INFO] [1671174103.199580322] [talker]: Publishing: 'Hello World: 3'</p><p>[INFO] [1671174103.204019965] [listener]: I heard: [Hello World: 3]</p>|}</li><li><p>When debugging u-boot code, you can use Run the following method command to update u-boot in the linux image for testingopen rviz2</p><ol {| class="wikitable" style="listwidth:800px;" |-style-type| <p>orangepi@orangepi:~$ '''source /opt/ros/galactic/setup.bash'''</p><p>orangepi@orangepi:~$ '''ros2 run rviz2 rviz2'''</p>|}<p>[[File: lowerzero2w-alpha;"img253.png]]</p></li><li>First upload the compiled deb package of u-boot <p>For how to use ROS, please refer to the Linux system documentation of the development boardROS 2.</lip>{| class="wikitable" style="width:800px;" |-| <p>[http://docs.ros.org/en/galactic/Tutorials.html '''http://docs.ros.org/en/galactic/Tutorials.html''']</olp>|}
</li></ol>
<ol style="list-style-type: decimal;"><li><p>Use the install_ros.sh script to '''linux-u-boot-next-orangepizero2w_xinstall_ros.x.x_arm64.deb [mailtosh'''</p>{| class="wikitable" style="width:root800px;" |-| <p>orangepi@192orangepi:~$ '''install_ros.sh ros2'''</p>|}</li><li><p>The '''install_ros.168sh''' script will automatically run the '''ros2 -h''' command after installing ros2.1If you can see the following print, it means that the ros2 installation is complete.xxx</p>{| class="wikitable" style="width:/root root@192800px;" |-| <p>usage: ros2 [-h] Call `ros2 <command> -h` for more detailed usage. .168.1.xxx:</root]'''p>
:<p>Call `ros2 <command> -h` for more detailed usage.</p>|}</li><li><p>Then you can use the '''test_ros.sh''' script to test whether ROS 2 is successfully installed. If you can see the following print, it means ROS 2 can run normally.</p>{| class="wikitable" style="width:800px;" |-| <p>orangepi@orangepi:~$ '''test_ros.sh'''</p><p>[INFO] [1671174101.200091527] [talker]: Publishing: 'Hello World: 1'</p><p>[INFO] [1671174101.235661048] [listener]: I heard: [Hello World: 1]</p><p>[INFO] [1671174102.199572327] [talker]: Publishing: 'Hello World: 2'</p><p>[INFO] [1671174102.204196299] [listener]: I heard: [Hello World: 2]</p><p>[INFO] [1671174103.199580322] [talker]: Publishing: 'Hello World: 3'</p><p>[INFO] [1671174103.204019965] [listener]: I heard: [Hello World: 3]</p>|}</li><li><p>Run the following command to open rviz2</p>{| class="wikitable" style="width:800px;" |-| <p>orangepi@orangepi:~$ '''source /opt/ros/humble/setup.bash'''</p><p>orangepi@orangepi:~$ '''ros2 run rviz2 rviz2'''</p><p>[[File:zero2w-img279img254.png]]</p>|}</li><li><p>Reference documentation</p>{| class="wikitable" style="width:800px;" |-| <p>'''http://docs.ros.org/en/humble/index.html'''</p><p>[http://docs.ros.org/en/galactic/Tutorials.html '''http://docs.ros.org/en/humble/Installation/Ubuntu-Install-Debians.html''']</p>|}</li></ol>
<ol startspan id="6" style="listhow-to-install-stylekernel-type: lowerheader-alpha;files"><li>Press the Enter key again to start updating u-boot. After the update is completed, the following information will be displayed.</li></olspan>
<span idol style="compilelist-style-type: decimal;"><li><p>The Linux image released by OPi comes with the deb package of the kernel header file by default, and thestorage location is '''/opt/'''</p>{| class="wikitable" style="width:800px;" |-| <p>orangepi@orangepi:~$ '''ls /opt/linux-headers*'''</p><p>/opt/linux-headers-xxx-sun50iw9_x.x.x_arm64.deb</p>|}</li><li><p>Use the following command to install the deb package of the kernelheader file</p>{| class="wikitable"style="width:800px;" |-| <p>orangepi@orangepi:~$ '''sudo dpkg -i /opt/linux-headers*.deb'''</p>|}</spanli>== Compile <li><p>After installation, you can see the folder where the linux kernel header file is located under '''/usr/src'''.</p>{| class="wikitable" style="width:800px;" |-| <p>orangepi@orangepi:~$ '''ls /usr/src'''</p><p>linux-headers-x.x.x</p>|}</li># Run <li><p>Then you can compile the source code of the hello kernel module that comes with the Linux image. The source code of the hello module is in '''build.sh/usr/src/hello''' script. After entering this directory, remember then use the make command to add sudo permissionscompile.</p>{| class="wikitable" style="width:800px;" |-| test<p>orangepi@testorangepi:~$ '''cd /usr/src/hello/'''</p><p>orangepi-build@orangepi:/usr/src/hello$ '''sudo make'''</p><p>make -C /lib/modules/5.4.125/buildM=/usr/src/hello modules</p><p>make[1]: Entering directory '/usr/src/linux-headers-5.sh4.125'</p>:<p>CC [M] /usr/src/hello/hello.o</p>:<p>Building modules, stage 2.</p>:<p>MODPOST 1 modules</p>:<p>CC [M] /usr/src/hello/hello.mod.o</p>:<p>LD [M] /usr/src/hello/hello.ko</p><p>make[1]: Leaving directory '/usr/src/linux-headers-5.4.125'</p>|}<ol start/li><li><p>After compilation, the '''hello.ko''' kernel module will be generated</p>{| class="2wikitable" style="listwidth:800px;" |-| <p>orangepi@orangepi:/usr/src/hello$ '''ls *.ko'''</p><p>hello.ko</p>|}</li><li><p>Use the '''insmod''' command to insert the '''hello.ko''' kernel module into the kernel</p>{| class="wikitable" style-type="width: decimal800px;"|-| <p>orangepi@orangepi:/usr/src/hello$ '''sudo insmod hello.ko'''</p>|}</li><li>Select <p>Then use the '''demsg''' command to view the output of the '''hello.ko''' kernel module. If you can see the following output, it means that the '''hello.ko''' kernel module is loaded correctly.</p>{| class="wikitable" style="width:800px;" |-| <p>orangepi@orangepi:/usr/src/hello$ '''Kernel packagedmesg | grep "Hello"''' and press Enter</lip><p>[ 2871.893988] '''Hello Orange Pi -- init'''</olp>|}<div /li><li><p>Use the '''rmmod''' command to uninstall the '''hello.ko''' kernel module</p>{| class="figurewikitable" style="width:800px;"|-| <p>orangepi@orangepi:/usr/src/hello$ '''sudo rmmod hello'''</p><p>orangepi@orangepi:/usr/src/hello$ '''dmesg | grep "Hello"'''</p><p>[2871.893988] Hello Orange Pi -- init</p><p>[File:zero2w-img2813173.png]800892]'''Hello Orange Pi -- exit'''</p>|}</li></ol>
</div><ol startspan id="3" style="listtesting-of-some-programming-languages-supported-by-stylelinux-type: decimal;system"><li>Then you will be prompted whether you need to display the kernel configuration interface. If you do not need to modify the kernel configuration, select the first one. If you need to modify the kernel configuration, select the second one.</li></olspan>
<ol startspan id="4" style="listdebian-stylebullseye-type: decimal;system"><li>Then select the model of the development board</li></olspan> [[File:zero2w-img275.png]] <ol start="5" style="list-style-type: decimal;"><li>Then select the branch type of the kernel source code</li></ol> <blockquote>a. The current branch will compile the linux5.4 kernel source code b. The next branch will compile the linux6.1 kernel source code</blockquote>[[File:zero2w-img276.png]] <ol start="6" styleDebian Bullseye system ==="list-style-type: decimal;"><li>If you choose to display the kernel configuration menu (the second option) in step 3), the kernel configuration interface opened through '''make menuconfig''' will pop up. At this time, you can directly modify the kernel configuration. After modification, save and exit. Yes, compilation of the kernel source code will begin after exiting.</li></ol> [[File:zero2w-img283.png]]
<ol style="list-style-type: decimal;">
<li><p>Debian Bullseye is installed with the gcc compilation tool chain by default, which can directly compile C language programs in the Linux system of the development board.</p>
<ol style="list-style-type: lower-alpha;">
<li>If you do <p>The version of a.gcc is as follows</p>{| class="wikitable" style="width:800px;" |-| <p>orangepi@orangepi:~$ '''gcc --version'''</p><p>gcc (Debian 10.2.1-6) 10.2.1 20210110</p><p>Copyright (C) 2020 Free Software Foundation, Inc.</p><p>This is free software; see the source for copying conditions. There is NO</p><p>warranty; not need to modify even for MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.</p>|}</li><li><p>Write the kernel configuration options, when running the build'''hello_world.sh script, pass c'''KERNEL_CONFIGUREprogram in C language</p>{| class=no"wikitable" style="width:800px;" |-| <p>orangepi@orangepi:~$ ''' to temporarily block the pop-up of the kernel configuration interfacevim hello_world.c'''</lip><p>#include <stdio.h></olp>
:<p>return 0;<ol start/p><p>}</p>|}</li><li><p>Then compile and run '''hello_world.c'''</p>{| class="7wikitable" style="listwidth:800px;" |-style| <p>orangepi@orangepi:~$ '''gcc -typeo hello_world hello_world.c'''</p><p>orangepi@orangepi: decimal;"~$ '''./hello_world'''</p><p>Hello World!</p>|}</li></ol></li><li><p>Part of the information prompted when compiling the next branch kernel source code is explained as follows:Debian Bullseye has Python3 installed by default</p>
<ol style="list-style-type: lower-alpha;">
<li>Version <p>The specific version of the linux kernel source codePython is as follows</lip>{| class="wikitable" style="width:800px;" |-| <p>orangepi@orangepi:~$ '''python3'''</olp></lip>'''Python 3.9.2''' (default, Feb 28 2021, 17:03:44)</olp> <p>[ oGCC 10.k2. 1 20210110] Compiling current kernel [ on linux</p><p>Type "help", "copyright", "credits" or "license" for more information.</p><p>>>></p>|}{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <big><p>'''Use the Ctrl+D shortcut key to exit python's interactive mode.'''</p></big>|}</li><li><p>Write the '''6hello_world.1py''' program in Python language</p>{| class="wikitable" style="width:800px;" |-| <p>orangepi@orangepi:~$ '''vim hello_world.31py'''</p><p>print('Hello World!' ])</p>|}<ol start/li><li><p>The result of running '''hello_world.py''' is as follows</p>{| class="2wikitable" style="width:800px;" |-| <p>orangepi@orangepi:~$ '''python3 hello_world.py'''</p><p>Hello World!</p>|}</li></ol></li><li><p>Debian Bullseye does not install Java compilation tools and operating environment by default.</p><ol style="list-style-type: lower-alpha;"><li><p>You can use the following command to install openjdk. The latest version of the crossin Debian Bullseye is openjdk-17</p>{| class="wikitable" style="width:800px;" |-| <p>orangepi@orangepi:~$ '''sudo apt install -y openjdk-17-compilation tool chain usedjdk'''</p>|}</li><li><p>After installation, you can check the Java version.</olp>{| class="wikitable" style="width:800px;" |-| [ o.k. ] Compiler version [ <p>orangepi@orangepi:~$ '''aarch64java -linux-gnuversion'''</p>|}</li><li><p>Write the Java version of '''hello_world.java'''</p>{| class="wikitable" style="width:800px;" |-gcc 11| <p>orangepi@orangepi:~$ '''vim hello_world.java''' </p><p>public class hello_world</p><p>{</p>:<p>public static void main(String[]args)</p>:<p>{</p>::<p>System.out.println("Hello World!");</p>:<p>}</p><ol startp>}</p>|}</li><li><p>Then compile and run '''hello_world.java'''</p>{| class="3wikitable" style="list-style-typewidth: lower-alpha800px;"|-| <p>orangepi@orangepi:~$ '''javac hello_world.java'''</p><p>orangepi@orangepi:~$ '''java hello_world'''</p><p>Hello World!</p>|}</li>The default configuration file used by the kernel and the path where it is stored are as follows</ol></li></ol>
<ol style="list-style-type: lower-alpha;">
<li><p>The specific version of Python is as follows</p>{| class="wikitable" style="width:800px;" |-| <p>orangepi@orangepi:~$ '''linux-dtb-next-sun50iw9_x.x.x_arm64.debpython3''' Contains dtb files used by the kernel</p><p>Python 3.11.2 (main, Mar 13 2023, 12:18:29) [GCC 12.2.0] on linux</lip><lip>Type "help", "copyright", "credits" or "license" for more information.</p>'''linux-headers-next-sun50iw9_x.x.x_arm64.deb''' Contains kernel header files</p>>>></lip>|}{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <libig><p>'''linux-image-next-sun50iw9_x.x.x_arm64Use the Ctrl+D shortcut key to exit python's interactive mode.deb''' Contains kernel images and kernel modules</p></libig>|}</olli></li></olp> test@test:~/orangepi-build$ Write the '''ls output/debs/linux-*hello_world.py''' outputprogram in Python language</debs/linux-dtb-next-sun50iw9_x.x.x_arm64.deb output/debs/linux-headers-next-sun50iw9_x.x.x_arm64.deb output/debs/linux-image-next-sun50iw9_x.x.x_arm64.debp><ol start{| class="9wikitable" style="list-style-typewidth: decimal800px;">|-| <lip>When the orangepi-bulid compilation system compiles the linux kernel source code, it will first synchronize the linux kernel source code with the linux kernel source code of the github server@orangepi:~$ '''vim hello_world. Therefore, if you want to modify the linux kernel source code, you first need to turn off the update function of the source code (py'''it needs to be completely compiled once This function can only be turned off after obtaining the Linux kernel source code, otherwise it will prompt that the source code of the Linux kernel cannot be found'</p><p>print('Hello World!'), otherwise the modifications will be restored. The method is as follows:</lip>|}</olli> <blockquoteli><p>Set the IGNORE_UPDATES variable in The result of running '''userpatches/config-defaulthello_world.confpy''' to "yes"is as follows</p>{| class="wikitable" style="width:800px;" |-| </blockquotep>testorangepi@testorangepi:~/orangepi-build$ '''vim userpatches/config-defaultpython3 hello_world.confpy'''</p><p>Hello World!</p>IGNORE_UPDATES="'''yes'''"|}</li></ol><ol start="10" style="list-style-type: decimal;"/li><li><p>If the kernel is modified, you can use the following method to update the kernel Debian Bookworm does not install Java compilation tools and kernel module of the development board Linux systemoperating environment by default.</p>
<ol style="list-style-type: lower-alpha;">
<li>Upload <p>You can use the compiled deb package of the Linux kernel following command to the Linux system of the development boardinstall openjdk. The latest version in Debian Bookworm is openjdk-17</lip>{| class="wikitable" style="width:800px;" |-| <p>orangepi@orangepi:~$ '''sudo apt install -y openjdk-17-jdk'''</olp>|}</li><li><p>After installation, you can check the Java version.</olp>{| class="wikitable" style="width:800px;" |-| test<p>orangepi@testorangepi:~/orangepi-build$ '''cd output/debsjava --version'''</p>|}test@test:~</orangepi-build/output/debs$ li><li><p>Write the Java version of '''scp \hello_world.java'''</p>{| class="wikitable" style="width:800px;" |-| <p>orangepi@orangepi:~$ '''linux-image-next-sun50iw9_x.x.x_arm64.deb root@192vim hello_world.168.1.xxx:/rootjava'''</p><p>public class hello_world</p><ol start="2" style="list-style-typep>{</p>:<p>public static void main(String[] args)</p>:<p>{</p>:: lower-alpha<p>System.out.println("Hello World!");"</p>:<lip>Install the deb package of the new linux kernel just uploaded.}</lip><p>}</olp>|}orangepi@orangepi:~$ </li><li><p>Then compile and run '''sudo dpkg -i linux-image-next-sun50iw9_x.x.x_arm64hello_world.debjava'''</p> <ol start{| class="3wikitable" style="list-style-typewidth: lower-alpha800px;"><li>Then restart the development board and check whether the kernel|-related modifications have taken effect.| </li></olp> orangepi@orangepi:~$ '''sudojavac hello_world.java''' </p><p>orangepi@orangepi:~$ '''rebootjava hello_world'''</p><p>Hello World!</p>|}</li></ol></li></ol>
<span id="compileubuntu-rootfsfocal-system"></span>== Compile rootfs ==
<ol style="list-style-type: lower-alpha;">
<li><p>In the current branchThe specific version of Python3 is as follows</p>{| class="wikitable" style="width:800px;" |-| <p>orangepi@orangepi:~$ '''python3'''</p><p>Python 3.8.10 (default, Nov 14 2022, you can see three options12: debian1159:47)</p><p>[GCC 9.4.0] on linux</p><p>Type "help", ubuntu20.04"copyright", and ubuntu22"credits" or "license" for more information.04</p><p>>>></p>|}{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <big><p>'''Use the Ctrl+D shortcut key to exit python's interactive mode.'''</p></big>|}</li><li><p>In Write the next branch, you can see three options'''hello_world.py''' program in Python language</p>{| class="wikitable" style="width:800px;" |-| <p>orangepi@orangepi: debian11, debian12, and ubuntu22~$ '''vim hello_world.04py'''</p><p>print('Hello World!')</p>|}</li><li><p>The result of running '''hello_world.py''' is as follows</p>{| class="wikitable" style="width:800px;" |-| <p>orangepi@orangepi:~$ '''python3 hello_world.py'''</lip><p>Hello World!</olp>|}
</li></ol>
<ol style="list-style-type: lower-alpha;">
<li><p>You can use the following command to install openjdk-17</p>{| class="wikitable" style="width:800px;" |-| <p>orangepi@orangepi:~$ '''Image with console interface (server)sudo apt install -y openjdk-17-jdk''' Represents the image of the server version, which is relatively small in size.</p>|}</li><li><p>After installation, you can check the Java version.</p>{| class="wikitable" style="width:800px;" |-| <p>orangepi@orangepi:~$ '''Image with desktop environmentjava --version''' Represents an image with a desktop, which is relatively large in size</p><p>openjdk 17.0.2 2022-01-18</p><p>OpenJDK Runtime Environment (build 17.0.2+8-Ubuntu-120.04)</lip><p>OpenJDK 64-Bit Server VM (build 17.0.2+8-Ubuntu-120.04, mixed mode, sharing)</olp>|}</li><li><p>Write the Java version of '''hello_world.java'''</olp> <div {| class="figurewikitable" style="width:800px;"|-| <p>orangepi@orangepi:~$ '''vim hello_world.java'''</p><p>public class hello_world</p><p>{</p>:<p>public static void main(String[[File] args)</p>:<p>{</p>::zero2w-img287<p>System.out.png]]println("Hello World!");</p>:<p>}</p><p>}</p>|}</divli><ol startli><p>Then compile and run '''hello_world.java'''</p>{| class="7wikitable" style="list-style-typewidth: decimal800px;"|-| <p>orangepi@orangepi:~$ '''javac hello_world.java'''</p><lip>If you are compiling the server version of the image, you can also choose to compile the Standard version or the Minimal version. The Minimal version will have much less pre-installed software than the Standard version (orangepi@orangepi:~$ '''please do not choose the Minimal version without special needs, because many things are not pre-installed by default. Some functions may not be availablejava hello_world''')</p><p>Hello World!</p>|}</li></ol></li></ol>
<div classspan id="figureubuntu-jammy-system"></span>
<ol style="list-style-type: decimal;"><li><p>Ubuntu Jammy is installed with the gcc compilation tool chain by default, which can directly compile C language programs in the Linux system of the development board.</divp><ol start="8" style="list-style-type: decimallower-alpha;"><li>If you are compiling <p>The version of a desktop .gcc is as follows</p>{| class="wikitable" style="width:800px;" |-| <p>orangepi@orangepi:~$ '''gcc --version of the image'''</p><p>gcc (Ubuntu 11.3.0-1ubuntu1~22.04.1) '''11.3.0'''</p><p>Copyright (C) 2021 Free Software Foundation, you also need to select Inc.</p><p>This is free software; see the type of desktop environmentsource for copying conditions. Currently, only XFCE There is maintained, so please select an XFCE type desktopNO</p><p>warranty; not even for MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.</p>|}</li><li><p>Write the '''hello_world.c''' program in C language</p>{| class="wikitable" style="width:800px;" |-| <p>orangepi@orangepi:~$ '''vim hello_world.c'''</p><p>#include <stdio.h></olp>
<ol style="list-style-type: lower-alpha;">
<li><p>The specific version of Python3 is as follows</p>{| class="wikitable" style="width:800px;" |-| <p>orangepi@orangepi:~$ '''python3'''</p><p>Python 3.10.6 (main, May 29 2023, 11:10:38) [GCC 11.3.0] on linux</p><p>Type "help", "copyright", "credits" or "license" for more information.</p><p>>>></p>|}{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <big><p>'''Use the Ctrl+D shortcut key to exit python's interactive mode.'''</p></big>|}</li><li><p>Write the '''hello_world.py''' program in Python language</p>{| class="wikitable" style="width:800px;" |-| <p>orangepi@orangepi:~$ '''vim hello_world.py'''</p><p>print('Hello World!')</p>|}</li><li><p>The result of rootfsrunning '''hello_world.py''' is as follows</lip>{| class="wikitable" style="width:800px;" |-| <p>orangepi@orangepi:~$ '''python3 hello_world.py'''</p><p>Hello World!</olp>|}
</li></ol>
<ol style="list-style-type: lower-alpha;">
<li><p>You can use the following command to install openjdk-18</p>{| class="wikitable" style="width:800px;" |-| <p>orangepi@orangepi:~$ '''sudo apt install -y openjdk-18-jdk'''bullseye</p>|}</li><li><p>After installation, you can check the Java version.</p>{| class="wikitable" style="width:800px;" |-| <p>orangepi@orangepi:~$ '''java --version'''</p><p>openjdk 18.0.2-ea 2022-07-19</p><p>OpenJDK Runtime Environment (build 18.0.2-ea+9-xfceUbuntu-arm64222.5250ec7002de9e81a41de169f1f8972104)</p><p>OpenJDK 64-Bit Server VM (build 18.0.tar2-ea+9-Ubuntu-222.04, mixed mode, sharing)</p>|}</li><li><p>Write the Java version of '''hello_world.java'''</p>{| class="wikitable" style="width:800px;" |-| <p>orangepi@orangepi:~$ '''vim hello_world.lz4java''' It is a compressed package of rootfs</p><p>public class hello_world</p><p>{</p>:<p>public static void main(String[] args)</p>:<p>{</p>::<p>System.out. The meaning of each field in the name isprintln("Hello World!");</p>:<p>}</lip><p>}</olp>|}</li><li><p>Then compile and run '''hello_world.java'''</olp>{| class="wikitable" style="width:800px;" |-| <p>orangepi@orangepi:~$ '''javac hello_world.java'''</p><blockquotep>a) orangepi@orangepi:~$ '''bullseyejava hello_world''' represents the type of Linux distribution of rootfs</p><p>Hello World!</p>|}</li></ol></li></ol>
<ol start="2" style="list-style-type: decimal;"/div></li><li>Select '''Full OS image for flashing''' and press Enter<p>The method of connecting the development board is as shown in the figure below</lip></olli>
<div class="figure">
[[File:zero2w-img292img256.png]] </div></ol><ol start="5" style="list-style-type: decimal;"><li><p>Then choose to '''save the password''' and click '''OK'''</p><p>[[File:zero2w-img257.png]]</p></li><li><p>Then select '''Always trust this host''' and click '''OK'''</p></li>
</div><ol startclass="3figure" style="list-style-type: decimal;"><li>Then select the model of the development board</li></ol>
[[File:zero2w-img275img258.png]]
<ol start="4" style="list-style-type: decimal;"/div><li><p>Then select the branch type of the kernel source code. Different versions of the kernel source code maintain different rootfs types.</pol><ol start="7" style="list-style-type: lower-alphadecimal;"><li><p>In After the current branchconnection is successful, you can see three options: debian11, ubuntu20.04, and ubuntu22.04.</p></li><li><p>In the next branch, you can see three options: debian11, debian12, and ubuntu22directory structure of the development board's Linux file system on the right side of the filezilla software.04.</p></li></ol></li></ol>
<ol start="8" style="list-style-type: decimal;">
<li>If you are compiling Then select the server version path to be uploaded to the development board on the right side of the imagefilezilla software, you can also choose select the file to compile be uploaded in Ubuntu PC on the Standard version or left side of the Minimal version. The Minimal version will have much less prefilezilla software, right-installed software than click the mouse, and then click the upload option to start uploading the Standard version ('''please do not choose file to the Minimal version without special needs, because many things are not pre-installed by defaultdevelopment board. Some functions may not be available''')</li></ol>
<div class="figure">
[[File:zero2w-img288img260.png]]
</div></ol>
<ol start="9" style="list-style-type: decimal;">
<li>If you are compiling a desktop version of <p>After the imageupload is completed, you also need can go to the corresponding path in the development board Linux system to select view the type uploaded file.</p></li><li><p>The method of desktop environment. Currently, only XFCE uploading a folder is maintainedthe same as the method of uploading a file, so please select an XFCE type desktopI won't go into details here.</p></li></ol>
</div></ol><ol start="117" style="list-style-type: decimal;"><li><p>After compiling the imageconnection is successful, you can see the directory structure of the following message will be displayed</p><ol style="list-style-type: lower-alpha;"><li>The storage path development board's Linux file system on the right side of the compiled image</li></ol>filezilla software.</li></ol>
<ol startdiv class="3figure" style="list-style-type: lower-alpha;"><li>Repeat the command to compile the image. Use the following command to start compiling the image directly without selecting it through the graphical interface.</li></ol>
[ o.k[File:zero2w-img268. png] Repeat Build Options [ '''sudo ./build.sh BOARD=orangepizero2w BRANCH=next BUILD_OPT=image RELEASE=bullseye BUILD_MINIMAL=no BUILD_DESKTOP=no KERNEL_CONFIGURE=yes''' ]
<span id/div></ol><ol start="instructions9" style="list-for-usingstyle-type: decimal;"><li><p>After the upload is completed, you can go to the corresponding path in the-orange-pi-os-arch-development board Linux system"to view the uploaded file.</p></li><li><p>The method of uploading a folder is the same as the method of uploading a file, so I won't go into details here.</p></li></spanol>
<span id= '''Instructions "instructions-for -using -the Orange Pi OS Arch system''' =-logo-on-and-off-the-machine"></span>
<ol style="list-style-type: decimal;"><li><p>The power on/off logo will only be displayed on the desktop version of the system by default.</p></li><li><p>Set the '''bootlogo''' variable to '''false''' in '''/boot/orangepiEnv.txt''' to turn off the switch logo.</p>{| class="wikitable" style="width:800px;"
|-
| <p>orangepi@orangepi:~$ '''Motherboard functionssudo vim /boot/orangepiEnv.txt'''</p><p>verbosity=1</p><p>'''<span style="color:#FF0000">bootlogo=false</span>'''</p>| }</li><li><p>Set the '''OPi OS Archbootlogo'''variable to '''true''' in '''/boot/orangepiEnv.txt''' to enable the power on/off logo.</p>{| class="wikitable" style="width:800px;"
|-
| <p>orangepi@orangepi:~$ '''HDMI videosudo vim /boot/orangepiEnv.txt'''</p>| <p>verbosity=1</p><p>'''OK<span style="color:#FF0000">bootlogo=true</span>'''</p>|}</li><li><p>The location of the boot logo picture in the Linux system is</p>{| class="wikitable" style="width:800px;"
|-
| <p>'''HDMI Audio/usr/share/plymouth/themes/orangepi/watermark.png'''</p>|}</li><li><p>After replacing the boot logo image, you need to run the following command to take effect</p>{| '''OK'''class="wikitable" style="width:800px;"
|-
| <p>orangepi@orangepi:~$ '''Typesudo update-C USB2.0 x 2initramfs -u'''</p>| }</li></ol> <span id="how-to-turn-on-the-power-button-in-linux5.4"></span> == How to turn on the power button in Linux5.4 == There is no power on/off button on the main board of the development board. We can expand it through a 24pin expansion board. The location of the power on/off button on the expansion board is as follows: [[File:zero2w-img269.png]] The power on/off button of the Linux 6.1 image is turned on by default, but the power on/off button of the Linux 5.4 kernel image is turned off by default and needs to be turned on manually for normal use. The steps are as follows: <ol style="list-style-type: decimal;"><li><p>First run '''OKorangepi-config'''. Ordinary users remember to add '''sudo''' permissions.</p>{| class="wikitable" style="width:800px;"
|-
| <p>orangepi@orangepi:~$ '''TF Card Startupsudo orangepi-config'''</p>| }</li><li><p>Then select '''System'''</p><p>[[File:zero2w-img80.png]]</p></li><li><p>Then select '''Hardware'''</p><p>[[File:zero2w-img81.png]]</p></li><li><p>Then use the keyboard's arrow keys to locate the position shown in the picture below, and then use the '''space''' to select the dtbo configuration of the SPI you want to open.</p><p>[[File:zero2w-img270.png]]</p></li><li><p>Then select '''<Save>''' to save</p><p>[[File:zero2w-img83.png]]</p></li><li><p>Then select '''<Back>'''</p><p>[[File:zero2w-img84.png]]</p></li><li><p>Then select '''<Reboot>'OK''to restart the system to make the configuration take effect.</p><p>[[File:zero2w-img85.png]]</p></li></ol> <span id="how-to-shut-down-and-restart-the-development-board"></span> == How to shut down and restart the development board == <ol style="list-style-type: decimal;"><li><p>During the running of the Linux system, if you directly unplug the power supply, it may cause the file system to lose some data. It is recommended to use the '''poweroff''' command to shut down the Linux system of the development board before powering off, and then unplug the power supply.</p>{| class="wikitable" style="width:800px;"
|-
| <p>orangepi@orangepi:~$ '''WIFIsudo poweroff'''</p>| '''OK'''}{| class="wikitable" style="background-color:#ffffdc;width:800px;"
|-
| <big><p>'''BluetoothNote that after turning off the development board, you need to unplug and replug the power supply before it can be turned on.'''</p></big>| '''OK'''}</li><li><p>In addition to using the poweroff command to shut down, you can also use the power on/off button on the expansion board to shut down.</p>|<p>[[File:zero2w-img269.png]]</p>{| '''LED Light'''| '''OK'''class="wikitable" style="background-color:#ffffdc;width:800px;"
|-
| <big><p>'''40pin GPIONote that Linux 5.4 requires manual configuration of the power on/off button before it can be used. For the opening method, please refer to [[Orange Pi Zero 2W#How to turn on the power button in Linux5.4|the method of opening the power button in Linux5.4]].'''</p></big>| }</li><li><p>Use the '''OKreboot'''command to restart the Linux system in the development board</p>{| class="wikitable" style="width:800px;"
|-
| <p>orangepi@orangepi:~$ '''sudo'''''40pin I2C'reboot'''</p>| }</li></ol> <span id="linux-sdkorangepi-build-usage-instructions"></span> = '''Linux SDK——orangepi-build usage instructions''' = <span id="compilation-system-requirements"></span>== Compilation system requirements == The Linux SDK, '''orangepi-build''OK', only supports running on X64 computers with '''<span style="color:#FF0000">Ubuntu 22.04</span>''' installed. Therefore, before downloading orangepi-build, please first ensure that the Ubuntu version installed on your computer is Ubuntu 22.04. The command to check the Ubuntu version installed on the computer is as follows. If the Release field does not display '''<span style="color:#FF0000">22.04</span>''', it means that the Ubuntu version currently used does not meet the requirements. Please change the system before performing the following operations. {| class="wikitable" style="width:800px;"
|-
| '''40pin SPI'''| test@test:~$ '''OK'''|lsb_release -| '''40pin UARTa'''| '''OK'''|-No LSB modules are available.| '''40pin PWM'''| '''OK'''Distributor ID: Ubuntu|-| '''Temperature Sensor'''Description: Ubuntu 22.04 LTS| '''OK'''|-| '''Hardware watchdog'''| Release: '''OK<span style="color:#FF0000">22.04</span>'''|-| '''Mali GPU'''| '''NO'''|-| '''Video codec'''| Codename: '''NOjammy'''
|}
If the computer is installed with a Windows system and does not have Ubuntu 22.04 installed on it, you can consider using'''VirtualBox''' or '''VMware''' to install an Ubuntu 22.04 virtual machine in the Windows system. But please note, do not compile orangepi-build on the WSL virtual machine, because orangepi-build has not been tested in the WSL virtual machine, so there is no guarantee that orangepi-build can be used normally in WSL. In addition, please do not compile the Linux system on the development board. Use orangepi-build. The installation image download address of Ubuntu 22.04 amd64 version is: {| class="wikitable" style="width:800px;"
|-
| '''24pin expansion board function'''| '''OPi OS Arch'''|[https://repo.huaweicloud.com/ubuntu-| '''100M network port'''| '''OK'''|releases/21.04/ubuntu-| '''100M Ethernet port light'''| '''OK'''|-| '''USB221.0 HOST x 2'''| '''OK'''|04-| '''Infrared reception'''| '''OK'''|desktop-| amd64.iso '''Headphone audio playback'''| '''OK'''|https://mirrors.tuna.tsinghua.edu.cn/ubuntu-| '''Onreleases/22.04/off button'''| '''OK'''|ubuntu-| '''LRADC''' '''Custom buttons x 2'''| '''OK'''|22.04-| '''TVdesktop-OUT'''| '''NOamd64.iso''']
|}
After installing Ubuntu 22.04 on your computer or virtual machine, please first set the software source of Ubuntu 22.04 to Tsinghua source (or other domestic sources that you think is fast), otherwise it is easy to make errors due to network reasons when installing the software later. The steps to replace Tsinghua Source are as follows: <span idol style="orange-pi-os-arch-systemlist-userstyle-guidetype: lower-instructionsalpha;"><li>For the method of replacing Tsinghua Source, please refer to the instructions on this page.</spanli>== Orange Pi OS Arch System User Guide Instructions ==
</div></li><lispan id="obtain-the-source-code-of-linux-sdk"><p>Then wait for the installation to complete</p><div class="figure"span>
</divspan id="download-orangepi-build-from-github"></lispan><li><p>After the installation is complete, you need to click the '''Finish''' button to restart the system.</p><div class="figure">== Download orangepi-build from github ===
<span iddiv class="how-to-set-dt-overlaysfigure"></span>== How to set DT overlays ==
</div>|}{| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <big>'''When downloading the orangepi-build code through the git clone command, you do not need to enter the user name and password of the github account (the same is true for downloading other codes in this manual). If after entering the git clone command, Ubuntu PC prompts you to enter the user name of the github account. The method name and password are usually entered incorrectly in the address of the orangepi-build warehouse behind git clone. Please carefully check whether there are any errors in the spelling of the command, rather than thinking that we have forgotten to open DT overlays in OPi OS Arch system is provide the username and password of the github account.'''</big>|} The u-boot and linux kernel versions currently used by the H618 series development boards are as follows: {| class="wikitable" style="width:800px;text-align: center;"|-| '''branch'''| '''u-boot Version'''| '''linux Kernel version'''|-| '''current'''| '''u-boot v2018.05'''| '''linux5.4'''|-| '''next'''| '''u-boot v2021.07'''| '''linux6.1'''|}
{| class="wikitable" style="background-color:# First open the ffffdc;width:800px;" |-| <big>'''/boot/extlinux/extlinuxThe branch mentioned here is not the same thing as the branch of orangepi-build source code, please don't get confused. This branch is mainly used to distinguish different kernel source code versions.conf''' configuration file
<ol style="list-style-type: lower-alpha;"><li><p>'''Note that xxxbuild.dtbo in FDTOVERLAYS sh''': Compile startup script</dtbsp></allwinner/overlay/xxx.dtbo needs li><li><p>'''external''': Contains configuration files needed to be replaced with compile the image, specific dtbo configurationscripts, and source code of some programs, please do not copy itetc.</p></li><li><p>'''LICENSE''': GPL 2 license file</p></li><li><p>'''README.md''': orangepi-build documentation</p></li><li><p>'''scripts''': Common script for compiling linux images</p></li></ol>{| class="wikitable" style="width:800px;" |-| test@test:~/orangepi-build$ '''ls'''
</div>The mirror URL of the cross-compilation tool chain in China is the open source software mirror site of Tsinghua University: {| class="wikitable"|-| '''Functions on the development board'''| '''Corresponding DT overlays configuration'''style="width:800px;"
|-
| [https://mirrors.tuna.tsinghua.edu.cn/armbian-releases/_toolchain/ '''40pin https://mirrors.tuna.tsinghua.edu.cn/armbian- i2c0releases/_toolchain/''']| } After toolchains is downloaded, it will contain multiple versions of cross-compilation '''sun50i-h616-pi-i2c0.dtbotoolchain''': {| class="wikitable" style="width:800px;"
|-
| test@test:~/orangepi-build$ '''40pin - i2c1ls toolchains/''' gcc-arm-11.2-2022.02-x86_64-aarch64-none-linux-gnu gcc-linaro-4.9.4-2017.01-x86_64_aarch64-linux-gnu gcc-linaro-7.4.1-2019.02-x86_64_arm-linux-gnueabi gcc-arm-11.2-2022.02-x86_64-arm-none-linux-gnueabihf gcc-linaro-4.9.4-2017.01-x86_64_arm-linux-gnueabi gcc-linaro-aarch64-none-elf-4.8-2013.11_linux gcc-arm-9.2-2019.12-x86_64-aarch64-none-linux-gnu gcc-linaro-5.5.0-2017.10-x86_64_arm-linux-gnueabihf gcc-linaro-arm-linux-gnueabihf-4.8-2014.04_linux gcc-arm-9.2-2019.12-x86_64-arm-none-linux-gnueabihf gcc-linaro-7.4.1-2019.02-x86_64_aarch64-linux-gnu gcc-linaro-arm-none-eabi-4.8-2014.04_linux| '''sun50i} The cross-compilation tool chain used to compile the H618 Linux kernel source code is: <ol style="list-h616style-pitype: lower-i2c1alpha;"><li>linux5.dtbo'''4</li>{| class="wikitable" style="width:800px;"
|-
| '''40pin gcc-arm-11.2- i2c22022.02-x86_64-aarch64-none-linux-gnu'''| '''sun50i}</ol><ol start="2" style="list-h616style-pitype: lower-i2c2alpha;"><li>linux6.dtbo'''1</li>{| class="wikitable" style="width:800px;"
|-
| '''40pin gcc-arm-11.2- uart22022.02-x86_64-aarch64-none-linux-gnu'''| '''sun50i}</ol>The cross-compilation tool chain used to compile the H618 u-boot source code is: <ol style="list-h616style-pitype: lower-uart2alpha;"><li>v2018.dtbo'''05</li>{| class="wikitable" style="width:800px;"
|-
| '''40pin gcc-linaro-7.4.1-2019.02- uart3x86_64_arm-linux-gnueabi'''| '''sun50i}</ol><ol start="2" style="list-h616style-pitype: lower-uart3alpha;"><li>v2021.dtbo'''07</li>{| class="wikitable" style="width:800px;"
|-
| '''40pin gcc-arm-11.2-2022.02-x86_64-aarch64-none-linux- uart4gnu'''| '''sun50i}</ol><span id="orangepi-build-complete-directory-structure-description"></span> === orangepi-build complete directory structure description === <ol style="list-style-type: decimal;"><li><p>After downloading, the orangepi-build warehouse does not contain the source code of the linux kernel, u-boot and cross-compilation tool chain. The source code of the linux kernel and u-boot is stored in an independent git warehouse.</p><ol style="list-style-type: lower-alpha;"><li><p>The git warehouse where the linux kernel source code is stored is as follows. Please note that the branch of the linux-h616orangepi warehouse is switched to</p><ol style="list-pistyle-uart4type: none;"><li>a) Linux5.dtbo'''4</li>{| class="wikitable" style="width:800px;"
|-
| https://github.com/orangepi-xunlong/linux-orangepi/tree/'''40pin orange- uart5pi-5.4-sun50iw9'''| '''sun50i}</ol><ol start="2" style="list-h616style-phtype: lower-uart5alpha;"><li>b) Linux6.dtbo'''1</li>{| class="wikitable" style="width:800px;"
|-
| https://github.com/orangepi-xunlong/linux-orangepi/tree/'''40pin orange-pi-6.1- pwm1sun50iw9'''| '''sun50i}</ol></li></ol><ol start="2" style="list-style-type: lower-alpha;"><li><p>The git warehouse where the u-boot source code is stored is as follows. Please note that the branch of the u-boot-orangepi warehouse is switched to</p><ol style="list-h616style-pitype: lower-pwm1alpha;"><li>a) v2018.dtbo'''05</li>{| class="wikitable" style="width:800px;"
|-
| https://github.com/orangepi-xunlong/u-boot-orangepi/tree/'''40pin v2018.05- pwm2h618'''| '''sun50i}</ol><ol start="2" style="list-h616style-pitype: lower-pwm2alpha;"><li>b) v2021.dtbo'''07</li>{| class="wikitable" style="width:800px;"
|-
| https://github.com/orangepi-xunlong/u-boot-orangepi/tree/'''40pin v2021.07- pwm3sunxi'''| }</ol></li></ol></li></ol><ol start="2" style="list-style-type: decimal;"><li><p>When orangepi-build is run for the first time, it will download the cross-compilation tool chain, u-boot and linux kernel source code. After successfully compiling a linux image, the files and folders that can be seen in orangepi-build are:</p><ol style="list-style-type: lower-alpha;"><li><p>'''sun50i-h616-pi-pwm3build.dtbosh''': Compile startup script</p></li>|-<li><p>'''external''': Contains the configuration files needed to compile the image, scripts for specific functions, and the source code of some programs. The rootfs compressed package cached during the image compilation process is also stored in external.</p></li><li><p>'''kernel''': Store the source code of the linux kernel</p></li>| <li><p>'''40pin - pwm4LICENSE''': GPL 2 license file</p></li>| <li><p>'''sun50i-h616-pi-pwm4README.dtbomd''': orangepi-build documentation</p></li>|<li><p>'''output''': Store compiled u-boot, linux and other deb packages, compilation logs, and compiled images and other files</p></li>| <li><p>'''40pin - spi1 cs0scripts''': Common script for compiling linux images</p></li>| <li><p>'''sun50i-h616-spi1-cs0-spidev.dtbotoolchains'''|: Store cross-compilation tool chain</p></li>| <li><p>'''40pin u- spi1 cs1boot''': Store the source code of u-boot</p></li>| <li><p>'''sun50i-h616-spi1-cs1-spidev.dtbouserpatches''': Store the configuration files needed to compile the script</p></li>{| class="wikitable" style="width:800px;"
|-
| '''40pin test@test:~/orangepi- spi1 cs0 cs1'''| build$ '''sun50i-h616-spi1-cs0-cs1-spidev.dtbols'''|-| '''设Set USB0 to Host mode'''| '''sun50i-h616-usb0-hostbuild.dtbo'''|-| '''Turn off the green LED light'''| '''sun50i-h616-zero2w-disable-ledsh external kernel LICENSE output README.dtbo'''|-| '''How to close the UART0 debugging serial port'''| '''sun50i-h616-disablemd scripts toolchains u-uart0.dtboboot userpatches'''
|}
</ol>
</li></ol>
<ol startspan id="5" style="listcompile-styleu-type: decimal;boot"><li>If you need to open multiple configurations at the same time, just add the paths of multiple configurations directly after '''FDTOVERLAYS.''' For example, the configuration of opening i2c1 and uart5 at the same time is as follows</li></olspan>
[[File:zero2w-img275.png]]<span id/ol><ol start="4" style="how-tolist-installstyle-softwaretype: decimal;"><li><p>Then select the branch type of u-boot</spanp><ol style== How to install software =="list-style-type: lower-alpha;"> You can use <li><p>The current branch will compile the pacman package management tool u-boot v2018.05 version code that needs to install software that is not available in OPi OSbe used by the linux5.4 image. For example, </p></li><li><p>The next branch will compile the command u-boot v2021.07 version code that needs to install be used by the vim editor is as followslinux6.1 image.</p><p>[[File:zero2w-img276. png]]</p></li></ol></li><li><p>If you want select the next branch, you will also be prompted to install other softwareselect the memory size, and you only do not need to replace vim with select the package name current branch.</p><ol style="list-style-type: lower-alpha;"><li><p>If the development board you purchased has a memory size of 1.5GB, please select the first option.</p></li><li><p>If the software development board you want to installpurchased has 1GB or 2GB or 4GB memory size, please choose the second option.</p> <p>[[orangepi@orangepiFile:zero2w-pc ~img277.png]$ '''sudo pacman -Syy vim''']</p></li></ol></li></ol><span idol start="6" style="android-12-tvlist-systemstyle-usage-instructionstype: decimal;"><li><p>Then it will start to compile u-boot. Some of the information prompted when compiling the next branch is as follows:</spanp> = '''Android 12 TV system usage instructions''' = <span idol style="supportedlist-style-androidtype: lower-versionsalpha;"><li>Version of u-boot source code</spanli>== Supported Android versions == {| class="wikitable" style="width:800px;"
|-
| Android [ o.k. ] Compiling u-boot [ '''v2021.07''' ]|}</ol><ol start="2" style="list-style-type: lower-alpha;"><li>Versionof the cross-compilation tool chain</li>{| Kernel versionclass="wikitable" style="width:800px;"
|-
| '''Android 12 TV Version'''| [ o.k. ] Compiler version [ '''linux5.4aarch64-linux-gnu-gcc 11''']
|}
</ol><span idol start="android3" style="list-12style-tvtype: lower-function-adaptation-statusalpha;"><li>Path to the compiled u-boot deb package</spanli>== Android 12 TV function adaptation status == {| class="wikitable" style="width:800px;"
|-
| [ o.k. ] Target directory [ '''Motherboard functionsorangepi-build/output/debs/u-boot''']|}</ol><ol start="4" style="list-style-type: lower-alpha;"><li>The package name of the compiled u-boot deb package</li>{| '''Android12 TV'''class="wikitable" style="width:800px;"
|-
| [ o.k. ] File name [ '''HDMI videolinux-u-boot-next-orangepizero2w_x.x.x_arm64.deb''']|}</ol><ol start="5" style="list-style-type: lower-alpha;"><li>Compilation time</li>{| '''OK'''class="wikitable" style="width:800px;"
|-
| [ o.k. ] Runtime [ '''HDMI Audio1 min''']|}</ol><ol start="6" style="list-style-type: lower-alpha;"><li>Repeat the command to compile u-boot. Use the following command without selecting through the graphical interface. You can start compiling u-boot directly.</li>{| '''OK'''class="wikitable" style="width:800px;"
|-
| [ o.k. ] Repeat Build Options [ '''Typesudo ./build.sh BOARD=orangepizero2w BRANCH=next BUILD_OPT=u-C USB2.0 x 2boot''']| '''OK'''}</ol></li></ol><ol start="7" style="list-style-type: decimal;"><li>View the compiled u-boot deb package</li>{| class="wikitable" style="width:800px;"
|-
| test@test:~/orangepi-build$ '''ls output/debs/u-boot/''' '''TF card startuplinux-u-boot-next-orangepizero2w_x.x.x_arm64.deb'''| }</ol><ol start="8" style="list-style-type: decimal;"><li>When the orangepi-bulid compilation system compiles the u-boot source code, it will first synchronize the u-boot source code with the u-boot source code of the github server. Therefore, if you want to modify the u-boot source code, you first need to turn off the download and update function of the source code. ('''OKYou need to completely compile u-boot before you can turn off this function, otherwise it will prompt that the source code of u-boot cannot be found'''), otherwise the modifications will be restored. The method is as follows:</li> Set the IGNORE_UPDATES variable in u'''userpatches/config-default.conf''' to "yes" {| class="wikitable" style="width:800px;"
|-
| test@test:~/orangepi-build$ '''WIFIvim userpatches/config-default.conf'''| ...... IGNORE_UPDATES="'''OK<span style="color:#FF0000">yes</span>'''" ......|}</ol><ol start="9" style="list-style-type: decimal;"><li><p>When debugging u-boot code, you can use the following method to update u-boot in the linux image for testing</p><ol style="list-style-type: lower-alpha;"><li>First upload the compiled deb package of u-boot to the Linux system of the development board.</li>{| class="wikitable" style="width:800px;"
|-
| test@test:~/orangepi-build$ '''cd output/debs/u-boot''' test@test:~/orangepi_build/output/debs/u-boot$ '''Bluetoothscp \'''| '''OKlinux-u-boot-next-orangepizero2w_x.x.x_arm64.deb [mailto:root@192.168.1.xxx:/root root@192.168.1.xxx:/root]'''|}</ol><ol start="2" style="list-style-type: lower-alpha;"><li>Install the new u-boot deb package just uploaded</li>{| class="wikitable" style="width:800px;"
|-
| orangepi@orangepi:~$ '''USB Camerasudo dpkg -i'''| '''OKlinux-u-boot-next-orangepizero2w_x.x.x_arm64.deb'''|}</ol><ol start="3" style="list-style-type: lower-alpha;"><li>Then run the nand-sata-install script</li>{| class="wikitable" style="width:800px;"
|-
| orangepi@orangepi:~$ '''LED Lightsudo nand-sata-install'''| }</ol><ol start="4" style="list-style-type: lower-alpha;"><li>Then select '''5 Install/Update the bootloader on SD/eMMC'''</li> [[File:zero2w-img278.png]]</ol><ol start="5" style="list-style-type: lower-alpha;"><li>After pressing the Enter key, a Warning will pop up first.</li> [[File:zero2w-img279.png]]</ol><ol start="6" style="list-style-type: lower-alpha;"><li>Press the Enter key again to start updating u-boot. After the update is completed, the following information will be displayed.</li> [[File:zero2w-img280.png]]</ol><ol start="7" style="list-style-type: lower-alpha;"><li>Then you can restart the development board to test whether the u-boot modification has taken effect.</li></ol></li></ol><span id="compile-the-linux-kernel"></span> == Compile the linux kernel == # Run the '''OKbuild.sh'''script, remember to add sudo permissions ::{| class="wikitable" style="width:800px;"
|-
| '''40pin GPIO'''| '''OK'''|-| '''40pin I2C'''| '''OK'''|test@test:~/orangepi-| '''40pin SPI1'''| '''OK'''|-| '''40pin UART'''| '''OK'''|-| '''40pin PWM'''| '''OK'''|-| '''Temperature Sensor'''| '''OK'''|-| '''Hardware watchdog'''| '''OK'''|-| '''Mali GPU'''| '''OK'''|-| '''Video codec'''| build$ '''OKsudo ./build.sh'''
|}
<span id/div></ol><ol start="3" style="onboardlist-ledstyle-light-display-instructionstype: decimal;"><li>Then you will be prompted whether you need to display the kernel configuration interface. If you do not need to modify the kernel configuration, select the first one. If you need to modify the kernel configuration, select the second one.</spanli>== Onboard LED light display instructions ==
[[File:zero2w-img275.png]]<span id/ol><ol start="5" style="how-tolist-returnstyle-to-the-previous-interface-in-androidtype: decimal;"><li>Then select the branch type of the kernel source code</spanli>== How to return to the previous interface in Android ==
::[[File:zero2w-img303img276.png]]</ol><ol start="6" style="list-style-type: decimal;"><li>If you choose to display the kernel configuration menu (the second option) in step 3), the kernel configuration interface opened through '''make menuconfig''' will pop up. At this time, you can directly modify the kernel configuration. After modification, save and exit. Yes, compilation of the kernel source code will begin after exiting.</li>
<span idol style="uselist-networkstyle-connectiontype: lower-adb-debuggingalpha;"><li>If you do not need to modify the kernel configuration options, when running the build.sh script, pass '''KERNEL_CONFIGURE=no''' to temporarily block the pop-up of the kernel configuration interface.</spanli>{| class="wikitable" style="width:800px;" |-| test@test:~/orangepi-build$ '''sudo ./build.sh KERNEL_CONFIGURE= Use network connection adb debugging no'''|}</ol><ol start="2" style="list-style-type: lower-alpha;"><li><p>b. You can also set '''KERNEL_CONFIGURE=no''' in the orangepi-build/userpatches/config-default.confconfiguration file to permanently disable this function.</p></li><li><p>If the following error is prompted when compiling the kernel, it is because the Ubuntu PC terminal interface is too small, causing the make menuconfig interface to be unable to be displayed. Please increase the Ubuntu PC terminal to the maximum size, and then rerun the build.sh script.</p></li>
output/debs/linux-image-next-sun50iw9_x.x.x_arm64.deb|}</ol></li></ol><ol start="59" style="list-style-type: decimal;"><li>Then When the orangepi-bulid compilation system compiles the linux kernel source code, it will first synchronize the linux kernel source code with the linux kernel source code of the github server. Therefore, if you want to modify the linux kernel source code, you first need to turn off the update function of the source code ('''it needs to be completely compiled once This function can log in to only be turned off after obtaining the Linux kernel source code, otherwise it will prompt that the source code of the Linux kernel cannot be found'''), otherwise the android system through adb shell on Ubuntu PCmodifications will be restored. The method is as follows:</li></ol>
IGNORE_UPDATES="'''<span idstyle="use-data-cable-to-connect-adb-debuggingcolor:#FF0000">yes</span>'''"|}</ol><ol start="10" style== Use data cable to connect adb debugging ==="list-style-type: decimal;"> # Prepare a USB Type C interface data cable<li><p>If the kernel is modified, plug one end of you can use the USB interface into the USB interface of following method to update the computer, kernel and plug one end of the USB Type C interface into the USB0 interface kernel module of the development board (see Linux system</p><ol style="list-style-type: lower-alpha;"><li>Upload the description compiled deb package of the picture on Linux kernel to the right below for the location Linux system of USB0). In this case, the development board is powered by the computer</li>{| class="wikitable" style="width:800px;" |-| test@test:~/orangepi-build$ '''cd output/debs''s USB interface, so please ensure that the computer's USB interface can provide the most sufficient power to drive the development board.
'''linux-image-next-sun50iw9_x.x.x_arm64.deb root@192.168.1.xxx:/root'''|}</ol><ol start="2" style="list-style-type: decimallower-alpha;"><li>Install adb tool on Ubuntu PCthe deb package of the new linux kernel just uploaded.</li>{| class="wikitable" style="width:800px;" |-| orangepi@orangepi:~$ '''sudo dpkg -i linux-image-next-sun50iw9_x.x.x_arm64.deb'''|}</ol><ol start="3" style="list-style-type: lower-alpha;"><li>Then restart the development board and check whether the kernel-related modifications have taken effect.</li>{| class="wikitable" style="width:800px;" |-| orangepi@orangepi:~$ '''sudo''' '''reboot'''|}</ol></li></ol><span id="compile-rootfs"></span> == Compile rootfs ==
::{| class="wikitable" style="width:800px;" |-| test@test:~/orangepi-build$ '''sudo apt-get install -y adb./build.sh'''|}
<ol start="32" style="list-style-type: decimal;"><li>Check whether the ADB device is recognizedSelect '''Rootfs and all deb packages''' and press Enter</li></ol>
[[File:zero2w-img275.png]]
</ol>
<ol start="4" style="list-style-type: decimal;">
<li><p>Then select the branch type of the kernel source code. Different versions of the kernel source code maintain different rootfs types.</p><ol style="list-style-type: lower-alpha;"><li><p>In the current branch, you can log in to see three options: debian11, ubuntu20.04, and ubuntu22.04.</p></li><li><p>In the android system through adb shell on Ubuntu PCnext branch, you can see three options: debian11, debian12, and ubuntu22.04.</lip></olli>
<ol stylediv class="list-style-type: decimal;figure"><li><p>Enter first '''Settings'''</p><p>[[File:zero2w-img306.png]]</p></li><li><p>Then select '''Device Preferences'''</p><p>[[File:zero2w-img307.png]]</p></li><li><p>Then select '''Display & Sound'''</p><p>[[File:zero2w-img308.png]]</p></li><li><p>Then select '''Advanced display settings'''</p><p>[[File:zero2w-img309.png]]</p></li><li><p>Then select '''HDMI output mode'''</p><p>[[File:zero2w-img310.png]]</p></li><li><p>Then you can see the list of resolutions supported by the monitor. At this time, clicking the corresponding option will switch to the corresponding resolution. Please note that different monitors may support different resolutions. If you connect it to a TV, you will generally see more resolution options than the picture below.</p><p>[[File:zero2w-img311.png]]</p></li><li><p>The HDMI output of the development board supports 4K display. When connected to a 4K TV, you can see the 4K resolution option.</p><p>[[File:zero2w-img312.png]]</p></li></ol>
</li></ol>
<ol start="7" style="list-style-type: decimal;">
<li>If you are compiling the server version of the image, you can also choose to compile the Standard version or the Minimal version. The Minimal version will have much less pre-installed software than the Standard version ('''please do not choose the Minimal version without special needs, because many things are not pre-installed by default. Some functions may not be available''')</li>
:d) '''25250ec7002de9e81a41de169f1f89721''' is the MD5 hash value generated by the package names of all software packages installed by rootfs. As long as the list of software packages installed by rootfs is not modified, this value will not change. The compilation script will use this MD5 hash value. Determine whether rootfs needs to be recompiled</ol><ol start="42" style="list-style-type: decimallower-alpha;"><li>After turning on WI-FI, you can see the searched signals under '''Available networksbullseye-xfce-arm64.5250ec7002de9e81a41de169f1f89721.tar.lz4.list'''.Lists the package names of all packages installed by rootfs</li><{| class="wikitable" style="width:800px;" |-| test@test:~/orangepi-build$ '''ls external/cache/rootfs/ol>'''
bullseye-xfce-arm64.5250ec7002de9e81a41de169f1f89721.tar.lz4.list|}<div class/ol></li></ol><ol start="figure11"style="list-style-type: decimal;"><li>If the required rootfs already exists under '''external/cache/rootfs''', then compiling the rootfs again will directly skip the compilation process and will not restart the compilation. When compiling the image, it will also go to '''external/cache/rootfs''' to check whether it already exists. There is a cached rootfs available. If it is available, use it directly. This can save a lot of download and compilation time.</li></ol>
</div></ol>
<ol start="3" style="list-style-type: decimal;">
<li>Then select '''Network & Internet'''the model of the development board</li></ol> [[File:zero2w-img314.png]]
[[File:zero2w-img275.png]]
</ol>
<ol start="4" style="list-style-type: decimal;">
<li><p>Then select '''WIFI hotspot'''the branch type of the kernel source code. Different versions of the kernel source code maintain different rootfs types.</p><ol style="list-style-type: lower-alpha;"><li><p>In the current branch, you can see three options: debian11, ubuntu20.04, and ubuntu22.04.</olp></li> [[File<li><p>In the next branch, you can see three options:zero2w-img320debian11, debian12, and ubuntu22.04.png]]</p></li>
[[File:zero2w-img276.png]]
</ol>
</li></ol>
<ol start="5" style="list-style-type: decimal;">
<li>Then open '''Hotspot Enable'''. You can <p>If you select the next branch, you will also see be prompted to select the name memory size, and password of you do not need to select the generated hotspot in the picture belowcurrent branch. Remember them and use them when connecting to </p><ol style="list-style-type: lower-alpha;"><li><p>If the hotspot (if development board you need to modify the name and password purchased has a memory size of 1.5GB, please select the hotspot, you need to close Hotspot Enable firstoption. Then </p></li><li><p>If the development board you can modify it)purchased has 1GB or 2GB or 4GB memory size, please choose the second option.</p><p>[[File:zero2w-img277.png]]</p></li></ol></li><li><p>Then select the type of rootfs</p></li>
[[File:zero2w-img321img286.png]]</ol><ol start="7" style="list-style-type: decimal;"><li><p>Then select the type of image</p><ol style="list-style-type: lower-alpha;"><li><p>'''Image with console interface (server)''' Represents the image of the server version, which is relatively small in size.</p></li><li><p>'''Image with desktop environment'''Represents an image with a desktop, which is relatively large in size.</p></li>
<ol startdiv class="6figure" style="list-style-type: decimal;"><li>At this time, you can take out your mobile phone. If everything is normal, you can find the WIFI hotspot with the same name ('''here AndroidAP_7132''') shown under the '''Hotspot name''' in the picture above in the WI-FI list searched by the mobile phone. Then you can click AndroidAP_7132 to connect to the hotspot. The password can be seen under the '''Hotspot password''' in the picture above.</li></ol>
[[File:zero2w-img322img287.png]]
</div></ol></li></ol><ol start="78" style="list-style-type: decimal;"><li>After If you are compiling the connection is successful, it will be displayed as shown below (server version of the interface will be different on different mobile phones, the specific interface is subject to the one displayed on your mobile phone). At this timeimage, you can open a web page on your mobile phone also choose to see if you can access compile the Standard version or the InternetMinimal version. If the web page can be opened normally, it means that The Minimal version will have much less pre-installed software than the Standard version ('''WIplease do not choose the Minimal version without special needs, because many things are not pre-FI Hotspotinstalled by default. Some functions may not be available''' of the development board can be used normally.)</li></ol>
[[File:zero2w-img107img289.png]]
::o. Finally, write the bin file of u-boot into the image through the dd command.</ol><ol start="11" style="list-style-type: decimal;"><li><p>After compiling the image, the following message will be displayed</p><ol style="list-style-type: lower-alpha;"><li>The storage path of the compiled image</li>{| class="wikitable" style="width:800px;" |-| [ o.k. ] Done building [ '''output/images/orangepizero2w_x.x.x_debian_bullseye_linux6.1.xx_xfce_desktop/orangepizero2w_x.x.x_debian_bullseye_linux6.1.xx_xfce_desktop.img''' ]|}</ol><ol start="2" style="list-style-type: lower-alpha;"><li>Compilation time</li>{| class="wikitable" style="width:800px;" |-| '''[o.k. ] Runtime [File19 min ]'''|}</ol><ol start="3" style="list-style-type:zero2wlower-img333alpha;"><li>Repeat the command to compile the image. Use the following command to start compiling the image directly without selecting it through the graphical interface.</li>{| class="wikitable" style="width:800px;" |-| [ o.k.png]Repeat Build Options [ '''sudo ./build.sh BOARD=orangepizero2w BRANCH=next BUILD_OPT=image RELEASE=bullseye BUILD_MINIMAL=no BUILD_DESKTOP=no KERNEL_CONFIGURE=yes''' ]|}</ol></li></ol><span id="instructions-for-using-the-orange-pi-os-arch-system"></span>
<ol stylespan id="listorange-stylepi-type: loweros-alpha;arch-system-user-guide-instructions"><li>Run the following command to set USB0 to HOST mode:</li></olspan>
<ol start="2" style="list-style-type: lower-alpha;"><li>Run <p>After burning the system, when you start it for the following command to switch back to Device modefirst time and enter the desktop, you will see the user wizard program shown in the figure below.</lip></oldiv class="figure">
<ol start="3" style="list-style-type: lower-alpha;"/div></li><li>The command <p>After selecting the language, the user wizard will immediately switch to view the current mode of USB0 iscorresponding language interface, as shown below in Chinese</lip></oldiv class="figure">
</devdiv></video0li><li><p>Then create a new username and set a password</p><div class="figure">
</div></li>
<li><p>Then make sure there is no problem with the selection, and then click the install '''button'''</p>
<div class="figure">
[[File:zero2w-img336img299.png]]
</div></li><li><p>Then wait for the installation to complete</p>
<div class="figure">
[[File:zero2w-img337img300.png]] </div><ol start="5" style="list-style-type: decimal;"><li>Then use the adb command to install the USB camera test APP into the Android system. Of course, you can also use a USB disk copy to install it.</li></ol> test@test:~$ '''adb install usbcamera.apk''' <ol start="6" style="list-style-type: decimal;"><li>After installation, you can see the startup icon of the USB camera on the Android desktop.</li></ol> [[File:zero2w-img338.png]] <ol start="7" style="list-style-type: decimal;"><li>Then double-click to open the USB camera APP and you can see the output video of the USB camera.</li></ol> <span id="android-system-root-description"></span>== Android system ROOT description == '''The Android system released by Orange Pi has been ROOT and can be tested using the following method.''' # Download from the '''official tool''' on the development board data download page '''rootcheck.apk'''
</div></li>
<li><p>After the installation is complete, you need to click the '''Finish''' button to restart the system.</p>
<div class="figure">
[[File:zero2w-img336img301.png]]
</div></li><li><p>The Orange Pi Hello program will automatically start after restarting. At this time, you need to remove the check '''mark of Start on startup''' in the lower right corner, otherwise you need to manually close the Orange Pi Hello program every time you start it.</p>
<div class="figure">
[[File:zero2w-img339img302.png]]
</div>
::{| class="wikitable" style="width:800px;" |-| [[File:zero2worangepi@orangepi-img341pc ~]$ '''sudo vim /boot/extlinux/extlinux.png]]conf'''|}
<ol start="62" style="list-style-type: decimal;"><li>Then you can click open the corresponding configuration by adding '''FDTOVERLAYS'''CHECK NOW''' to start checking the ROOT status of the Android system/dtbs/allwinner/overlay/xxx. After the check is completed, the display is as follows. You can see that the Android system has obtained ROOT permissionsdtbo''' in '''/boot/extlinux/extlinux.conf'''</li></ol>
'''FDTOVERLAYS <span style="color:#FF0000">/dtbs/allwinner/overlay/sun50i-h616-pi-i2c1.dtbo /dtbs/allwinner/overlay/sun50i-h616-ph-uart5.dtbo</span>'''|}</ol><ol start="6" style="list-style-type: decimal;"><li>After shutting downsetting, press and hold you need to restart the power button or system for the power button on the infrared remote control again configuration to turn it ontake effect.</li>{| class="wikitable" style="width:800px;" |-| [orangepi@orangepi-pc ~]$ '''sudo reboot'''|}</ol><span id="pinhow-interfaceto-gpioinstall-uart-spi-testsoftware"></span>== 40pin interface GPIO, UART, SPI test ==
|-
| '''GPIO序号TF card startup'''| '''GPIO'''| '''功能'''| '''引脚'''|| '''引脚'''| '''功能'''| '''GPIO'''| '''GPIO序号OK'''
|-
| style="text-align: left;"|| style="text-align: left;"|| '''3.3V'''| '''1'''|| '''2WIFI'''| '''5VOK'''| style="text-align: left;"|| style="text-align: left;"|
|-
| '''264Bluetooth'''| '''PI8OK'''| '''TWI1-SDA'''| '''3'''|| '''4'''| '''5V'''| style="text-align: left;"|| style="text-align: left;"|
|-
| '''263USB Camera'''| '''PI7OK'''| '''TWI1-SCL'''| '''5'''|| '''6'''| '''GND'''| style="text-align: left;"|| style="text-align: left;"|
|-
| '''269LED Light'''| '''PI13OK'''| '''PWM3'''| '''7'''|| '''8'''| '''UART0_TX'''-| '''PH040pin GPIO'''| '''224OK'''
|-
|-
| '''22640pin SPI1'''| '''PH2'''| '''UART5_TX'''| '''11'''|| '''12'''| style="text-align: left;"|| '''PI1'''| '''257OK'''
|-
| '''22740pin UART'''| '''PH3OK'''| '''UART5_RX'''| '''13'''|| '''14'''| '''GND'''| style="text-align: left;"|| style="text-align: left;"|
|-
| '''26140pin PWM'''| '''PI5'''| '''UART2_TX'''| '''15'''|| '''16'''| '''PWM4'''| '''PI14'''| '''270OK'''
|-
|-
| '''231Mali GPU'''| '''PH7OK'''| '''SPI1_MOSI'''| '''19'''|| '''20'''| '''GND'''| style="text-align: left;"|| style="text-align: left;"|
|-
| '''232Video codec'''| '''PH8OK'''| '''SPI1_MISO'''}| '''21'''|{| '''22'''| '''UART2_RX'''| '''PI6'''| '''262'''class="wikitable" style="width:800px;text-align: center;"
|-
| '''23024pin Expansion board function'''| '''PH6'''| '''SPI1_CLK'''| '''23'''|| '''24'''| '''SPI1_CS0'''| '''PH5'''| '''229Android12 TV'''
|-
|-
| '''266100M Ethernet port light'''| '''PI10'''| '''TWI2-SDA'''| '''27'''|| '''28'''| '''TWI2-SCL'''| '''PI9'''| '''265OK'''
|-
| '''256USB2.0 HOST x 2'''| '''PI0OK'''| style="text-align: left;"|| '''29'''|| '''30'''| '''GND'''| style="text-align: left;"|| style="text-align: left;"|
|-
| '''271Infrared reception'''| '''PI15'''| style="text-align: left;"|| '''31'''|| '''32'''| '''PWM1'''| '''PI11'''| '''267OK'''
|-
| '''268Headphone audio playback'''| '''PI12OK'''| '''PWM2'''| '''33'''|| '''34'''| '''GND'''| style="text-align: left;"|| style="text-align: left;"|
|-
| '''258On/off button'''| '''PI2'''| style="text-align: left;"|| '''35'''|| '''36'''| style="text-align: left;"|| '''PC12'''| '''76OK'''
|-
| '''272LRADC'''| '''PI16'''| style="text-align: left;"|| '''37'''|| '''38'''| style="text-align: left;"|| '''PI4Custom buttons x 2'''| '''260OK, The default setting is the volume up and down keys.'''
|-
|}
<ol startspan id="2" style="listonboard-led-light-styledisplay-type: decimal;instructions"><li>The device node corresponding to uart2 is '''/dev/ttyAS2''', and the device node corresponding to uart5 is'''/dev/ttyAS5'''</li></olspan>== Onboard LED light display instructions ==
<span id="how-to-return-to-the-previous-interface-in-android"></dev/ttyAS0 /dev/ttyAS1 '''/dev/ttyAS2 /dev/ttyAS5'''span>== How to return to the previous interface in Android ==
<ol startspan id="5" style="listuse-network-connection-styleadb-type: decimal;debugging"><li>The serial port test interface of wiringOP is as shown in the figure below</li></olspan>=== Use network connection adb debugging ===
192.168.1.xxx:5555 device|}</ol><ol start="5" style="list-style-type: decimal;"><li>Then you can log in to the android system through adb shell on Ubuntu PC</li>{| class="wikitable" style="width:800px;"
|-
| test@test:~$ '''GPIO serial numberadb shell''' apollo-p2:/ #| '''GPIO'''}</ol><span id="use-data-cable-to-connect-adb-debugging"></span> === Use data cable to connect adb debugging === | '''Function'# Prepare a USB Type C interface data cable, plug one end of the USB interface into the USB interface of the computer, and plug one end of the USB Type C interface into the USB0 interface of the development board (see the description of the picture on the right below for the location of USB0). In this case, the development board is powered by the computer's USB interface, so please ensure that the computer's USB interface can provide the most sufficient power to drive the development board.| '''pin'''|::[[File:zero2w-img304.png]] [[File:zero2w-img305.png]]| '''pin'''| '''Function'''<ol start="2" style="list-style-type: decimal;">| '''GPIO'''<li>Install adb tool on Ubuntu PC</li>{| '''GPIO serial number'''class="wikitable" style="width:800px;"
|-
|-
| test@test:~$ '''264adb devices'''| '''PI8'''| '''TWI1-SDA'''List of devices attached| '''3'''|4c00146473c28651dd0 device| '''4'''}| '''5V'''</ol>| <ol start="4" style="textlist-alignstyle-type: leftdecimal;"|><li>Then you can log in to the android system through adb shell on Ubuntu PC</li>{| class="wikitable" style="text-alignwidth: left800px;"|
|-
| test@test:~$ '''263adb shell''' apollo-p2:/ $| }</ol><span id="view-how-to-set-hdmi-display-resolution"></span> == View how to set HDMI display resolution == <ol style="list-style-type: decimal;"><li><p>Enter first '''PI7Settings'''</p><p>[[File:zero2w-img306.png]]</p></li>| <li><p>Then select '''TWI1-SCLDevice Preferences'''</p>| <p>[[File:zero2w-img307.png]]</p></li><li><p>Then select '''5Display & Sound'''</p>|<p>[[File:zero2w-img308.png]]</p></li>| <li><p>Then select '''6Advanced display settings'''</p><p>[[File:zero2w-img309.png]]</p></li>| <li><p>Then select '''GNDHDMI output mode'''</p><p>[[File:zero2w-img310.png]]</p></li><li><p>Then you can see the list of resolutions supported by the monitor. At this time, clicking the corresponding option will switch to the corresponding resolution. Please note that different monitors may support different resolutions. If you connect it to a TV, you will generally see more resolution options than the picture below.</p><p>[[File:zero2w-img311.png]]</p></li><li><p>The HDMI output of the development board supports 4K display. When connected to a 4K TV, you can see the 4K resolution option.</p><p>[[File:zero2w-img312.png]]</p></li></ol> <span id="hdmi-to-vga-display-test-1"></span>=== HDMI to VGA display test === | <ol style="textlist-style-aligntype: leftdecimal;"|><li><p>First you need to prepare the following accessories</p>| <ol style="textlist-style-aligntype: leftlower-alpha;"|><li>HDMI to VGA converter</li> [[File:zero2w-img144.png]]</ol><ol start="2" style="list-style-type: lower-alpha;"><li>A VGA cable and a Mini HDMI male to HDMI female adapter</li> [[File:zero2w-img145.png]] [[File:zero2w-img146.png]]</ol>|<ol start="3" style="list-style-type: lower-alpha;">| '''269'''<li>A monitor or TV that supports VGA interface</li></ol>| '''PI13'''</li></ol>| '''PWM3'''| '''7'''<ol start="2" style="list-style-type: decimal;">|<li>HDMI to VGA display test is as follows</li>| '''8'''| '''UART0_TX'''[[File:zero2w-img313.png]]| '''PH0'''{| '''224'''class="wikitable" style="background-color:#ffffdc;width:800px;"
|-
[[File:zero2w-img330.png]]</ol><ol start="26" style="list-style-type: decimal;"><li>The Then click on the Bluetooth device node corresponding you want to connect to SPI1 CS0 is '''/dev/spidev1start pairing.0'''When the following interface pops up, and please use the device node corresponding mouse to SPI1 CS1 is select the '''/dev/spidev1.1Pair'''option</li></ol>
[[File:zero2w-img332.png]]</ol><ol start="8" style="list-style-type: decimal;"><li>After pairing is completed, open '''/dev/spidev1.0 /dev/spidev1.1Paired devices'''and you will see the paired Bluetooth devices.</li>
[[File:zero2w-img333.png]]</ol><ol start="39" style="list-style-type: decimal;"><li>Here is At this time, you can use the Bluetooth of your mobile phone to send a demonstration picture to test the SPI1 development board. After sending, you can see the following confirmation interface through in the Android system of the development board, and then click '''w25qxxAccept''' module. First, connect to start receiving the w25qxx module to pictures sent by the SPI1 interfacemobile phone.</li></ol>
[[File:zero2w-img335.png]]</ol start><span id="4" style="listhow-to-set-usb0-to-host-stylemode-type: decimal;1"><li>Then open wiringOP APP on the desktop</li></olspan>
[[File:zero2w-img365img160.png]]
</divol style="list-style-type: lower-alpha;"></li>Run the following command to set USB0 to HOST mode:</li><p>Then click the {| class="wikitable" style="width:800px;" |-| apollo-p2:/ # '''OPENcat /sys/devices/platform/soc@3000000/soc@3000000\:usbc0@0/usb_host''' button to initialize the SPI</p></li></ol>
apollo-p2:/ #|}</ol><ol start="82" style="list-style-type: decimallower-alpha;"><li>Then fill in Run the bytes that need following command to be sent, such as reading the ID information of the onboard SPIFlash, filling in the address 0x9f in data[0], and then click the switch back to Device mode</li>{| class="wikitable" style="width:800px;" |-| apollo-p2:/ # '''TRANSFERcat /sys/devices/platform/soc@3000000/soc@3000000\:usbc0@0/usb_device''' button</li></ol>
apollo-p2:/ #|}</ol><ol start="93" style="list-style-type: decimallower-alpha;"><li>Finally, The command to view the APP will display the read ID information current mode of the onboard SPI Flash.USB0 is</li><{| class="wikitable" style="width:800px;" |-| apollo-p2:/ # '''cat /sys/devices/platform/soc@3000000/soc@3000000\:usbc0@0/ol>otg_role'''
::{| class="wikitable" style="width:800px;" |-| console:/ # As can be seen from the table below, the Android12 TV system has i2c1 and i2c2 turned on by default.'''ls /dev/video0'''
|-
| test@test:~$ '''adb install usbcamera.apk'''|}</ol><ol start="6" style="textlist-alignstyle-type: leftdecimal;"|><li>After installation, you can see the startup icon of the USB camera on the Android desktop.</li> [[File:zero2w-img338.png]]</ol>| <ol start="7" style="textlist-alignstyle-type: leftdecimal;"|>| '''3<li>Then double-click to open the USB camera APP and you can see the output video of the USB camera.3V'''</li></ol> | '''1'''<span id="android-system-root-description"></span>|| '''2'''== Android system ROOT description ==| '''5V'''{| styleclass="text-align: left;wikitable"|| style="textbackground-aligncolor: left#ffffdc;width:800px;"|
|-
| <big>'''264The Android system released by Orange Pi has been ROOT and can be tested using the following method.'''</big>| } # Download from the '''PI8official tool'''| on the development board data download page '''TWI1-SDArootcheck.apk'''| '''3'''|<div class="figure"> ::[[File:zero2w-img336.png]] </div><div class="figure"> ::[[File:zero2w-img339.png]] </div><ol start="2" style="list-style-type: decimal;"><li><p>Then make sure that the adb connection between the Ubuntu PC and the development board is normal. For how to use adb, please refer to the instructions in the section "[[Orange Pi Zero 2W#How to use ADB| '''4How to use ADB''']]".</p></li>| '''5V'''<li><p>Then use the adb command to install rootcheck.apk into the Android system. Of course, you can also use a USB disk copy to install it.</p></li>{| styleclass="text-align: left;wikitable"|| style="text-alignwidth: left800px;"|
|-
| test@test:~$ '''263adb install rootcheck.apk'''| '''PI7'''}</ol><ol start="4" style="list-style-type: decimal;"><li>After installation, you can see the startup icon of the ROOT test tool on the Android desktop.</li> [[File:zero2w-img340.png]]</ol>| '''TWI1<ol start="5" style="list-style-SCL'''type: decimal;">| <li>The display interface after opening the '''5ROOT test tool'''for the first time is as shown below</li> |[[File:zero2w-img341.png]]</ol>| '''<ol start="6'''" style="list-style-type: decimal;">| <li>Then you can click '''GNDCHECK NOW'''to start checking the ROOT status of the Android system. After the check is completed, the display is as follows. You can see that the Android system has obtained ROOT permissions.</li> | style[[File:zero2w-img342.png]]</ol><span id="texthow-to-use-align: left;miracastreceiver-to-cast-the-mobile-phone-screen-to-the-development-board"|></span> == How to use MiracastReceiver to cast the mobile phone screen to the development board == | <ol style="textlist-alignstyle-type: leftdecimal;"|>|<li><p>First, please make sure that both the development board and the mobile phone are connected to the same WIFI hotspot. For the method of connecting the development board to WIFI, please refer to [[Orange Pi Zero 2W#WI-FI connection method| '''269the instructions in the WI-FI connection method.''']]</p></li>| <li><p>Then open the '''PI13MiracastReceiver'''application in the Android system of the development board</p><p>[[File:zero2w-img343.png]]</p></li>| <li><p>The interface after '''PWM3MiracastReceiver'''is opened is as follows</p>| <div class="figure"> [[File:zero2w-img344.png]] </div></li><li><p>Then find the screen mirroring function in the phone settings. Here we take '''7Xiaomi 12S Pro mobile phone'''as an example. Please research other brands of mobile phones by yourself. As shown in the picture below, click the button in the red box to open the screen mirroring function of the phone.</p><p>[[File:zero2w-img345.png]]</p></li><li><p>After waiting for a period of time, you will be able to see the searched connectable devices on your mobile phone, and then we can select the device corresponding to the development board to connect.</p>|<p>[[File:zero2w-img346.png]]</p></li>| <li><p>Then the selection box shown in the figure below will pop up in the '''8MiracastReceiver'''| application interface of the development board. Here we can select '''UART0_TXAccept'''</p>| '''PH0'''<p>[[File:zero2w-img347.png]]</p></li>| '''224'''<li><p>Then you can see the content of the mobile phone screen on the HDMI screen connected to the development board</p>|<p>[[File:zero2w-img348.png]]</p></li></ol>| style<span id="textmethod-of-align: left;turning-on-and-off-the-machine-through-buttons-or-infrared-remote-control"|></span> | style="text= Method of turning on and off the machine through buttons or infrared remote control == We can turn off or turn on the Android system of the development board through the power on/off button or infrared remote control. However, it should be noted that there is no power on/off button and infrared receiver on the main board of the development board, and it needs to be expanded through a 24pin expansion board. [[File:zero2w-img107.png]] The location of the power button on the 24pin expansion board is as shown in the figure below: [[File:zero2w-alignimg269.png]] The location of the infrared remote control power button is as follows: [[File: left;"|zero2w-img349.png]] | When shutting down, we need to press and hold the power button or the power button on the infrared remote control, and then the Android system will pop up the confirmation dialog box shown in the figure below, and then select '''GNDOK'''to shut down the Android system.| '''9'''|[[File:zero2w-img350.png]] After shutting down, press and hold the power button or the power button on the infrared remote control again to turn it on. | '''10'''<span id="pin-interface-gpio-uart-spi-test"></span>| '''UART0_RX'''== 40pin interface GPIO, UART, SPI test ==| '''PH1'''{| '''225'''class="wikitable" style="background-color:#ffffdc;width:800px;"
|-
| <big>'''226Note: The pin header on the 40pin interface is not soldered by default, and you need to solder it yourself before it can be used.'''</big>| } <span id="pin-gpio-port-test-method"></span>=== 40pin GPIO port test method === # First open wiringOP APP on the desktop ::[[File:zero2w-img351.png]] <ol start="2" style="list-style-type: decimal;"><li>Then click the '''PH2GPIO_TEST'''button to open the GPIO test interface</li> [[File:zero2w-img352.png]]</ol><ol start="3" style="list-style-type: decimal;">| <li>The GPIO test interface is as shown in the figure below. The two rows of '''CheckBox''' buttons on the left have a one-to-one correspondence with the 40pin pins. When the '''CheckBox''' button is checked, the corresponding GPIO pin will be set to '''OUT''' mode and the pin level is set to high level; when unchecked, the GPIO pin level will be set to low level; when the GPIO is clicked When you click the '''GPIO READALL''' button, you can get information such as wPi number, GPIO mode, pin level, etc.; when you click the'''BLINK ALL GPIO''' button, all GPIO ports will cycle through outputting high and low levels. This function can be used to test all the 40pin pins. GPIO port.</li> [[File:zero2w-img353.png]]</ol><ol start="4" style="list-style-type: decimal;"><li>Then click the '''UART5_TXGPIO READALL'''button, and the output information is as shown below:</li> <div class="figure">| [[File:zero2w-img354.png]] </div></ol><ol start="5" style="list-style-type: decimal;"><li>There are a total of 28 GPIO ports available in the 40-pin development board. The following takes pin 12 - corresponding to GPIO PI01 - corresponding to wPi serial number 6 - as an example to demonstrate how to set the high and low levels of the GPIO port. First click the '''CheckBox''' button corresponding to pin 12. When the button is selected, pin 12 will be set to high level. After setting, you can use a multimeter to measure the value of the voltage of the pin. If it is '''113.3v''', it means the setting High level success.</li> |[[File:zero2w-img355.png]]</ol><ol start="6" style="list-style-type: decimal;">| <li>Then click the '''GPIO READALL'''button and you can see that the current pin 12mode is '''OUT''' and the pin level is high level.</li>| [[File:zero2w-img356.png]]</ol><ol start="7" style="textlist-style-aligntype: leftdecimal;"|>| <li>Click the '''CheckBox''' button in the picture below again to uncheck it, and pin 12 will be set to low level. After setting, you can use a multimeter to measure the voltage value of the pin. If it is '''PI10v''', it means the low level setting is successful.</li> [[File:zero2w-img357.png]]| </ol><ol start="8" style="list-style-type: decimal;"><li>Then click the '''257GPIO READALL'''button and you can see that the current pin 12 mode is OUT and the pin level is low level.</li> [[File:zero2w-img358.png]]</ol><span id="pin-uart-test-method"></span> === 40pin UART test method === # As can be seen from the table below, the default uarts available in the Android12 TV system are uart2 and uart5. Please note that uart0 is set as a debugging serial port by default. Please do not use uart0 as a normal serial port. <div style="display: flex;">::{| class="wikitable" style="width:390px;margin-right: 20px;text-align: center;"
|-
| '''227GPIO NO.'''| '''GPIO'''| '''Function'''| '''Pin'''|-| style="text-align: left;"|| style="text-align: left;"|| '''3.3V'''| '''1'''|-| '''264'''| '''PI8'''| '''TWI1-SDA'''| '''3'''|-| '''263'''| '''PH3PI7'''| '''UART5_RXTWI1-SCL'''| '''135'''|-| '''269'''| '''14PI13'''| '''GNDPWM3'''| '''7'''|-| style="text-align: left;"|| style="text-align: left;"|| '''GND'''| '''9'''|-| '''261<span style="color:#FF0000">226</span>'''| '''<span style="color:#FF0000">PH2</span>'''| '''<span style="color:#FF0000">UART5_TX</span>'''| '''<span style="color:#FF0000">11</span>'''|-| '''<span style="color:#FF0000">227</span>'''| '''PI5<span style="color:#FF0000">PH3</span>'''| '''UART2_TX<span style="color:#FF0000">UART5_RX</span>'''| '''15<span style="color:#FF0000">13</span>'''|-| '''16<span style="color:#FF0000">261</span>'''| '''PWM4<span style="color:#FF0000">PI5</span>'''| '''PI14<span style="color:#FF0000">UART2_TX</span>'''| '''270<span style="color:#FF0000">15</span>'''
|-
| style="text-align: left;"|
| '''3.3V'''
| '''17'''
|-
| '''231'''
| '''SPI1_MOSI'''
| '''19'''
|-
| '''232'''
| '''SPI1_MISO'''
| '''21'''
|-
| '''230'''
| '''SPI1_CLK'''
| '''23'''
|-
| style="text-align: left;"|
| '''GND'''
| '''25'''
|-
| '''266'''
| '''TWI2-SDA'''
| '''27'''
|-
| '''256'''
| style="text-align: left;"|
| '''29'''
| '''PI15'''
| style="text-align: left;"|
| '''31'''
|-
| '''268'''
| '''PWM2'''
| '''33'''
|-
| '''258'''
| style="text-align: left;"|
| '''35'''
|-
| '''272'''
| style="text-align: left;"|
| '''37'''
|-
| style="text-align: left;"|
| '''GND'''
| '''39'''
|}{| class="wikitable" style="width:390px;margin-right: 20px;text-align: center;"|-| '''Pin'40''| '''Function'''| '''GPIO'''| '''GPIO NO.'''|-| '''2'''| '''5V'''| style="text-align: left;"|| style="text-align: left;"||-| '''4'''| '''5V'''| style="text-align: left;"|
| style="text-align: left;"|
| '''PI3'''| '''259'''-|} <ol start="2" style="list-style-type: decimal;"><li>The device node corresponding to i2c1 is '''/dev/i2c-1''', and the device node corresponding to i2c2 is '''/dev/i2c-2'''</li></ol> apollo-p2:/ # '''ls /dev/i2c-*''' '''/dev/i2c-1 /dev/i2c-2''' /dev/i2c-5 <ol start="3" style="list-style-type: decimal;"><li>First open wiringOP APP on the desktop</li></ol> [[File:zero2w-img351.png]] <ol start="4" style="list-style-type: decimal;"><li>Then click the '''I2C_TEST''' button to open the i2c test interface</li></ol> [[File:zero2w-img370.png]] <ol start="5" style="list-style-type: decimal;"><li>The i2c test interface of wiringOP is shown in the figure below</li></ol> [[File:zero2w-img371.png]] <ol start="6" style="list-style-type: decimal;"><li>Then click the device node selection box in the upper left corner to select the i2c you want to test</li></ol> [[File:zero2w-img372.png]] <ol start="7" style="list-style-type: decimal;"><li>Then connect an i2c device to the 40pin i2c pin. Here we take the ds1307 rtc module as an example.</li></ol> [[File:zero2w-img178.png]] <ol start="8" style="list-style-type: decimal;"><li><p>The i2c address of the ds1307 rtc module is 0x68. After connecting the lines, we can use the '''i2cdetect -y 1''' or '''i2cdetect -y 2''' command on the serial port command line to check whether the i2c address of the ds1307 rtc module can be scanned. If you can see the address 0x68, it means that the ds1307 rtc module is wired correctly.</p><p>apollo-p2:/ # '''i2cdetect -y 1'''</p><p>'''Or'''</p><p>apollo-p2:/ # '''i2cdetect -y 2'''</p><p>[[File:zero2w-img373.png]]</p></li><li><p>Then set the i2c address to 0x68 in wiringOP, and then click the '''OPEN''' button to open i2c</p><p>[[File:zero2w-img374.png]]</p></li><li><p>After clicking the '''OPEN''' button to open i2c, the display is as follows</p><p>[[File:zero2w-img375.png]]</p></li><li><p>Then we test writing a value to the register of the rtc module, for example, writing 0x55 to the 0x1c address</p><ol style="list-style-type: lower-alpha;"><li><p>We first set the address of the register to be written to 0x1c</p><p>[[File:zero2w-img376.png]]</p></li><li><p>Then set the value to be written to 0x55</p><p>[[File:zero2w-img377.png]]</p></li><li><p>Then click the '''WRITE BYTE''' button to perform the writing action</p><p>[[File:zero2w-img378.png]]</p></li></ol></li><li><p>Then click the '''READ BYTE''' button to read the value of the 0x1c register. If it displays 0x55, it means that the i2c read and write test has passed.</p><p>[[File:zero2w-img379.png]]</p></li></ol> <span id="pin-pwm-test"></span>=== 40pin PWM test === # As can be seen from the table below, the available pwm are pwm1, pwm2, pwm3 and pwm4. {| class="wikitable"|-| '''GPIO serial number'''| '''GPIO'''| '''Function'''| '''pin'''|| '''pin'''| '''Function'''| '''GPIO'''| '''GPIO serial number'''|-| style="text-align: left;"|| style="text-align: left;"|| '''3.3V'''| '''1'''|| '''2'''| '''5VGND'''
| style="text-align: left;"|
| style="text-align: left;"|
|-
| '''2648'''| '''PI8UART0_TX'''| '''TWI1-SDAPH0'''| '''3224'''|| '''4'''| '''5V'''| style="text-align: left;"|| style="text-align: left;"|
|-
| '''10'''
| '''UART0_RX'''
| '''225'''
|-
| '''12'''
| style="text-align: left;"|
| '''257'''
|-
| '''14'''
| '''GND'''
| style="text-align: left;"|
|-
| '''16'''
| '''PWM4'''
| '''270'''
|-
| '''18'''
| style="text-align: left;"|
| '''228'''
|-
| '''20'''
| '''GND'''
| style="text-align: left;"|
|-
| '''232'''| '''PH8'''| '''SPI1_MISO'''| '''21'''|| '''<span style="color:#FF0000">22</span>'''| '''<span style="color:#FF0000">UART2_RX</span>'''| '''<span style="color:#FF0000">PI6</span>'''| '''<span style="color:#FF0000">262</span>'''|-| '''230'''| '''PH6'''| '''SPI1_CLK'''| '''23'''|| '''24'''
| '''SPI1_CS0'''
| '''PH5'''
| '''229'''
|-
| '''26'''
| '''SPI1_CS1'''
| '''233'''
|-
| '''28'''
| '''TWI2-SCL'''
| '''265'''
|-
| '''30'''
| '''GND'''
| style="text-align: left;"|
|-
| '''32'''
| '''PWM1'''
| '''267'''
|-
| '''34'''
| '''GND'''
| style="text-align: left;"|
|-
| '''36'''
| style="text-align: left;"|
| '''76'''
|-
| '''38'''
| style="text-align: left;"|
| '''260'''
|-
| '''40'''
| style="text-align: left;"|
| '''259'''
|}
</div>
<ol start="2" style="list-style-type: decimal;">
<li>First click The device node corresponding to uart2 is '''/dev/ttyAS2''', and the wiringOP icon device node corresponding to open wiringOP APPuart5 is'''/dev/ttyAS5'''</li>{| class="wikitable" style="width:800px;" |-| <p>apollo-p2:/ # ls /dev/ttyAS*</olp><p>/dev/ttyAS0 /dev/ttyAS1 '''<span style="color:#FF0000">/dev/ttyAS2 /dev/ttyAS5</span>'''</p>[[File:zero2w-img351.png]]|}</ol>
<ol start="3" style="list-style-type: decimal;">
<li>Then click the '''PWM_TEST''' button First open wiringOP APP on the main interface of wiringOP to enter the PWM test interfacedesktop</li></ol> [[File:zero2w-img380.png]]
[[File:zero2w-img351.png]]
</ol>
<ol start="4" style="list-style-type: decimal;">
<li>The PWM Then click the '''UART_TEST'''button to open the UART test interface is as follows</li></ol>
<ol start="5" style="list-style-type: decimal;">
<li>Then set which PWM you want to use in the Channel. The default serial port test interface of wiringOP is PWM1. If you want to set it to PWM2, just enter 2 as shown in the Channel. PWM3 and PWM4 and so on.figure below</li></ol> [[File:zero2w-img382.png]]
[[File:zero2w-img360.png]]
</ol>
<ol start="6" style="list-style-type: decimal;">
<li><p>Then you can set select the PWM period. The default configuration is '''50000ns/dev/ttyAS2'''. The converted PWM frequency is or'''20KHz/dev/ttyAS5'''node in the selection box</lip></olp> [[File:zero2w-img383img361.png]] <ol start="7" style="list-style-type: decimal;"/p></li><li>Then <p>Enter the baud rate you want to set in the edit box, and then click the '''EXPORTOPEN'''button to export PWMopen the uart node. After the opening is successful, the '''OPEN''' button becomes unselectable, and the '''CLOSE''' button and '''SEND''' button become selectable.</lip></olli> [[File:zero2w-img384.png]]
[[File:zero2w-img362.png]]
</ol>
<ol start="8" style="list-style-type: decimal;">
<li><p>Then use Dupont wire to short the rx and tx pins of uart</p></li><li><p>Then drag you can enter a paragraph of characters in the progress bar send edit box below to change and click the PWM duty cycle, and then check '''EnableSEND''' button to output the PWM waveformstart sending.</lip></olli>
[[File:zero2w-img385img363.png]]</ol><ol start="10" style="list-style-type: decimal;"><li>If everything is normal, the received string will be displayed in the receiving box</li>
[[File:zero2w-img364.png]]</ol start><span id="9" style="listpin-spi-styletest-type: decimal;method"><li>Then use an oscilloscope to measure the corresponding pins in the 40pin development board and you can see the following waveform.</li></olspan>
<ol start="2" style="list-style-type: decimal;"><li>The device node corresponding to SPI1 CS0 is '''/dev/spidev1.0''', and the device node corresponding to SPI1 CS1 is '''/dev/spidev1.1'''</li>{| class="wikitable" style="width:800px;" |-| apollo-p2:/ # '''ls /dev/spidev1....*'''
<div style="display: flex;">::{| class="wikitable" style="width:390px;margin-right: 20px;text-align: center;"|-| '''GPIO NO.'''| '''GPIO'''| '''Function'''| '''Pin'''|-| style="text-align: left;"|| style="text-align: left;"|| '''3.3V'''| '''1'''|-| '''<span style="color:#FF0000">264</span>'''| '''<span style="color:#FF0000">PI8</span>'''| '''<span style="color:#FF0000">TWI1-SDA</span>'''| '''<span style="color:#FF0000">3</span>'''|-| '''<span style="color:#FF0000">263</span>'''| '''<span style="color:#FF0000">PI7</span>'''| '''<span style="color:#FF0000">TWI1-SCL</span>'''| '''<span style="color:#FF0000">5</span>'''|-| '''269'''| '''PI13'''| '''PWM3'''| '''7'''|-| style="text-align: left;"|| style="text-align: left;"|| '''GND'''| '''9'''|-| '''226'''| '''PH2'''| '''UART5_TX'''| '''11'''|-| '''227'''| '''PH3'''| '''UART5_RX'''| '''13'''|-| '''261'''| '''PI5'''| '''UART2_TX'''| '''15'''|-| style="text-align: left;"|| style="text-align: left;"|| '''3.3V'''| '''17'''|-| '''231'''| '''PH7'''| '''SPI1_MOSI'''| '''19'''|-| '''232'''| '''PH8'''| '''SPI1_MISO'''| '''21'''|-| '''230'''| '''PH6'''| '''SPI1_CLK'''| '''23'''|-| style="text-align: left;"|| style="text-align: left;"|| '''GND'''| '''25'''|-| '''<span style="color:#FF0000">266</span>'''| '''<span style="color:#FF0000">PI10</span>'''| '''<span style="color:#FF0000">TWI2-SDA</span>'''| '''<span style="color:#FF0000">27</span>'''|-| '''256'''| '''PI0'''| style="text-align: left;"|| '''29'''|-| '''271'''| '''PI15'''| style="text-align: left;"|| '''31'''|-| '''268'''| '''PI12'''| '''PWM2'''| '''33'''|-| '''258'''| '''PI2'''| style="text-align: left;"|| '''35'''|-| '''272'''| '''PI16'''| style="text-align: left;"|| '''37'''|-| style="text-align: left;"|| style="text-align: left;"|| '''GND'''| '''39'''|}{| class="wikitable" style="width:390px;margin-right: 20px;text-align: center;"|-| '''Pin'''| '''Function'''| '''GPIO'''| '''GPIO NO.'''|-| '''2'''| '''5V'''| style="text-align: left;"|| style="text-align: left;"||-| '''4'''| '''5V'''| style="text-align: left;"|| style="text-align: left;"||-| '''6'''| '''GND'''| style="text-align: left;"|| style="text-align: left;"||-| '''8'''| '''UART0_TX'''| '''PH0'''| '''224'''|-| '''10'''| '''UART0_RX'''| '''PH1'''| '''225'''|-| '''12'''| style="text-align: left;"|| '''PI1'''| '''257'''|-| '''14'''| '''GND'''| style="text-align: left;"|| style="text-align: left;"||-| '''16'''| '''PWM4'''| '''PI14'''| '''270'''|-| '''18'''| style="text-align: left;"|| '''PH4'''| '''228'''|-| '''20'''| '''GND'''| style="text-align: left;"|| style="text-align: left;"||-| '''22'''| '''UART2_RX'''| '''PI6'''| '''262'''|-| '''24'''| '''SPI1_CS0'''| '''PH5'''| '''229'''|-| '''26'''| '''SPI1_CS1'''| '''PH9'''| '''233'''|-| '''<span style="color:#FF0000">28</span>'''| '''<span style="color:#FF0000">TWI2-SCL</span>'''| '''<span style="color:#FF0000">PI9</span>'''| '''<span style="color:#FF0000">265</span>'''|-| '''30'''| '''GND'''| style="text-align: left;"|| style="text-align: left;"||-| '''32'''| '''PWM1'''| '''PI11'''| '''267'''|-| '''34'''| '''GND'''| style="text-align: left;"|| style="text-align: left;"||-| '''36'''| style="text-align: left;"|| '''PC12'''| '''76'''|-| '''38'''| style="text-align: left;"|| '''PI4'''| '''260'''|-| '''40'''| style="text-align: left;"|| '''PI3'''| '''259'''|}</div> <ol start="2" style="list-style-type: decimal;"><li>The device node corresponding to i2c1 is '''/dev/i2c-1''', and the device node corresponding to i2c2 is '''/dev/i2c-2'''</li>{| class="wikitable" style="width:800px;" |-| apollo-p2:/ # '''ls /dev/i2c-*''' '''<span style="color:#FF0000">/dev/i2c-1 /dev/i2c-2</span>''' /dev/i2c-5|}</ol><ol start="3" style="list-style-type: decimal;"><li>First open wiringOP APP on the desktop</li> [[File:zero2w-img351.png]]</ol><ol start="4" style="list-style-type: decimal;"><li>Then click the '''I2C_TEST''' button to open the i2c test interface</li> [[File:zero2w-img370.png]]</ol><ol start="5" style="list-style-type: decimal;"><li>The i2c test interface of wiringOP is shown in the figure below</li> [[File:zero2w-img371.png]]</ol><ol start="6" style="list-style-type: decimal;"><li>Then click the device node selection box in the upper left corner to select the i2c you want to test</li> [[File:zero2w-img372.png]]</ol><ol start="7" style="list-style-type: decimal;"><li>Then connect an i2c device to the 40pin i2c pin. Here we take the ds1307 rtc module as an example.</li> [[File:zero2w-img178.png]]</ol><ol start="8" style="list-style-type: decimal;"><li><p>The i2c address of the ds1307 rtc module is 0x68. After connecting the lines, we can use the '''i2cdetect -y 1''' or '''i2cdetect -y 2''' command on the serial port command line to check whether the i2c address of the ds1307 rtc module can be scanned. If you can see the address 0x68, it means that the ds1307 rtc module is wired correctly.</p>{| class="wikitable" style="width:800px;" |-| <p>apollo-p2:/ # '''i2cdetect -y 1'''</p><p>'''Or'''</p><p>apollo-p2:/ # '''i2cdetect -y 2'''</p>|}<p>[[File:zero2w-img373.png]]</p></li><li><p>Then set the i2c address to 0x68 in wiringOP, and then click the '''OPEN''' button to open i2c</p><p>[[File:zero2w-img374.png]]</p></li><li><p>After clicking the '''OPEN''' button to open i2c, the display is as follows</p><p>[[File:zero2w-img375.png]]</p></li><li><p>Then we test writing a value to the register of the rtc module, for example, writing 0x55 to the 0x1c address</p><ol style="list-style-type: lower-alpha;"><li><p>We first set the address of the register to be written to 0x1c</p><p>[[File:zero2w-img376.png]]</p></li><li><p>Then set the value to be written to 0x55</p><p>[[File:zero2w-img377.png]]</p></li><li><p>Then click the '''WRITE BYTE''' button to perform the writing action</p><p>[[File:zero2w-img378.png]]</p></li></ol></li><li><p>Then click the '''READ BYTE''' button to read the value of the 0x1c register. If it displays 0x55, it means that the i2c read and write test has passed.</p><p>[[File:zero2w-img379.png]]</p></li></ol> <span id="pin-pwm-test"></span> === 40pin PWM test === # As can be seen from the table below, the available pwm are pwm1, pwm2, pwm3 and pwm4. <div style="display: flex;">::{| class="wikitable" style="width:390px;margin-right: 20px;text-align: center;"|-| '''GPIO NO.'''| '''GPIO'''| '''Function'''| '''Pin'''|-| style="text-align: left;"|| style="text-align: left;"|| '''3.3V'''| '''1'''|-| '''264'''| '''PI8'''| '''TWI1-SDA'''| '''3'''|-| '''263'''| '''PI7'''| '''TWI1-SCL'''| '''5'''|-| '''<span style="color:#FF0000">269</span>'''| '''<span style="color:#FF0000">PI13</span>'''| '''<span style="color:#FF0000">PWM3</span>'''| '''<span style="color:#FF0000">7</span>'''|-| style="text-align: left;"|| style="text-align: left;"|| '''GND'''| '''9'''|-| '''226'''| '''PH2'''| '''UART5_TX'''| '''11'''|-| '''227'''| '''PH3'''| '''UART5_RX'''| '''13'''|-| '''261'''| '''PI5'''| '''UART2_TX'''| '''15'''|-| style="text-align: left;"|| style="text-align: left;"|| '''3.3V'''| '''17'''|-| '''231'''| '''PH7'''| '''SPI1_MOSI'''| '''19'''|-| '''232'''| '''PH8'''| '''SPI1_MISO'''| '''21'''|-| '''230'''| '''PH6'''| '''SPI1_CLK'''| '''23'''|-| style="text-align: left;"|| style="text-align: left;"|| '''GND'''| '''25'''|-| '''266'''| '''PI10'''| '''TWI2-SDA'''| '''27'''|-| '''256'''| '''PI0'''| style="text-align: left;"|| '''29'''|-| '''271'''| '''PI15'''| style="text-align: left;"|| '''31'''|-| '''<span style="color:#FF0000">268</span>'''| '''<span style="color:#FF0000">PI12</span>'''| '''<span style="color:#FF0000">PWM2</span>'''| '''<span style="color:#FF0000">33</span>'''|-| '''258'''| '''PI2'''| style="text-align: left;"|| '''35'''|-| '''272'''| '''PI16'''| style="text-align: left;"|| '''37'''|-| style="text-align: left;"|| style="text-align: left;"|| '''GND'''| '''39'''|}{| class="wikitable" style="width:390px;margin-right: 20px;text-align: center;"|-| '''Pin'''| '''Function'''| '''GPIO'''| '''GPIO NO.'''|-| '''2'''| '''5V'''| style="text-align: left;"|| style="text-align: left;"||-| '''4'''| '''5V'''| style="text-align: left;"|| style="text-align: left;"||-| '''6'''| '''GND'''| style="text-align: left;"|| style="text-align: left;"||-| '''8'''| '''UART0_TX'''| '''PH0'''| '''224'''|-| '''10'''| '''UART0_RX'''| '''PH1'''| '''225'''|-| '''12'''| style="text-align: left;"|| '''PI1'''| '''257'''|-| '''14'''| '''GND'''| style="text-align: left;"|| style="text-align: left;"||-| '''<span style="color:#FF0000">16</span>'''| '''<span style="color:#FF0000">PWM4</span>'''| '''<span style="color:#FF0000">PI14</span>'''| '''<span style="color:#FF0000">270</span>'''|-| '''18'''| style="text-align: left;"|| '''PH4'''| '''228'''|-| '''20'''| '''GND'''| style="text-align: left;"|| style="text-align: left;"||-| '''22'''| '''UART2_RX'''| '''PI6'''| '''262'''|-| '''24'''| '''SPI1_CS0'''| '''PH5'''| '''229'''|-| '''26'''| '''SPI1_CS1'''| '''PH9'''| '''233'''|-| '''28'''| '''TWI2-SCL'''| '''PI9'''| '''265'''|-| '''30'''| '''GND'''| style="text-align: left;"|| style="text-align: left;"||-| '''<span style="color:#FF0000">32</span>'''| '''<span style="color:#FF0000">PWM1</span>'''| '''<span style="color:#FF0000">PI11</span>'''| '''<span style="color:#FF0000">267</span>'''|-| '''34'''| '''GND'''| style="text-align: left;"|| style="text-align: left;"||-| '''36'''| style="text-align: left;"|| '''PC12'''| '''76'''|-| '''38'''| style="text-align: left;"|| '''PI4'''| '''260'''|-| '''40'''| style="text-align: left;"|| '''PI3'''| '''259'''|}</div> <ol start="2" style="list-style-type: decimal;"><li>First click the wiringOP icon to open wiringOP APP</li> [[File:zero2w-img351.png]]</ol><ol start="3" style="list-style-type: decimal;"><li>Then click the '''PWM_TEST''' button on the main interface of wiringOP to enter the PWM test interface</li> [[File:zero2w-img380.png]]</ol><ol start="4" style="list-style-type: decimal;"><li>The PWM test interface is as follows</li> <div class="figure"> [[File:zero2w-img381.png]] </div></ol><ol start="5" style="list-style-type: decimal;"><li>Then set which PWM you want to use in the Channel. The default is PWM1. If you want to set it to PWM2, just enter 2 in the Channel. PWM3 and PWM4 and so on.</li> [[File:zero2w-img382.png]]</ol><ol start="6" style="list-style-type: decimal;"><li>Then you can set the PWM period. The default configuration is '''50000ns'''. The converted PWM frequency is '''20KHz'''</li> [[File:zero2w-img383.png]]</ol><ol start="7" style="list-style-type: decimal;"><li>Then click the '''EXPORT'''button to export PWM</li> [[File:zero2w-img384.png]]</ol><ol start="8" style="list-style-type: decimal;"><li>Then drag the progress bar below to change the PWM duty cycle, and then check '''Enable''' to output the PWM waveform.</li> [[File:zero2w-img385.png]]</ol><ol start="9" style="list-style-type: decimal;"><li>Then use an oscilloscope to measure the corresponding pins in the 40pin development board and you can see the following command waveform.</li> [[File:zero2w-img386.png]]</ol><span id="how-to-compile-android-12-source-code"></span> = '''How to compile Android 12 source code''' = <span id="download-the -source-code-of-android-12"></span>== Download the source code of Android 12 == <ol style="list-style-type: decimal;"><li><p>First download the compressed package of the Android 12 source code and generate the final compressed package of the files modified by Orange Pi Zero2w from Google Cloud Drive</p><ol style="list-style-type: lower-alpha;"><li>Google Cloud Drive</li> [[File:zero2w-img387.png]]</ol></li></ol><ol start="2" style="list-style-type: decimal;"><li>After downloading the compressed package of Android 12 source code, please check whether the MD5 checksum is correct. If it is incorrect, please download the source code again. Here's how to check the MD5 checksum:</li>{| class="wikitable" style="width:800px;" |-| test@test:~$ '''md5sum -c H618-Android12-Src.tar.gz.md5sum''' H618-Android12-Src.tar.gzaa: '''<span style="color:#FF0000">OK</span>''' H618-Android12-Src.tar.gzab: '''<span style="color:#FF0000">OK</span>''' ......|}</ol><ol start="3" style="list-style-type: decimal;"><li>Then you need to merge multiple compressed files into one, and then extract the Android source code. The command looks like this:</li>{| class="wikitable" style="width:800px;" |-| test@test:~$ '''cat H618-Android12-Src.tar.gz<span style="color:#FF0000">a</span>* > H618-Android12-Src.tar.gz''' test@test:~$ '''tar -xvf H618-Android12-Src.tar.gz'''|}</ol><ol start="4" style="list-style-type: decimal;"><li>Then unzip the compressed package of the files modified by Orange Pi Zero2w</li>{| class="wikitable" style="width:800px;" |-| test@test:~$ '''tar zxf opizero2w_android12_patches.tar.gz''' test@test:~$ '''ls''' '''opizero2w_android12_patches''' opizero2w_android12_patches.tar.gz|}</ol><ol start="5" style="list-style-type: decimal;"><li>Then copy the files modified by Orange Pi Zero2w to the Android source code</li>{| class="wikitable" style="width:800px;" |-| test@test:~$ '''cp -rf opizero2w_android12_patches/* H618-Android12-Src/'''|}</ol><span id="compile-the-source-code-of-android-12"></span> == Compile the source code of Android 12 == {| class="wikitable" style="background-color:#ffffdc;width:800px;" |-| <big>'''Android12 is compiled on an x86_64 computer with <span style="color:#FF0000">Ubuntu 22.04</span> installed. Other versions of Ubuntu system package dependencies may have some differences. The imagedownload address of the Ubuntu 22.04 <span style="color:#FF0000">amd64</span> version is as follows:''' [https://repo.huaweicloud.com/ubuntu-releases/22.04/ubuntu-22.04.2-desktop-amd64.iso '''https://repo.huaweicloud.com/ubuntu-releases/22.04/ubuntu-22.04.2-desktop-amd64.iso'''] '''The x86_64 computer hardware configuration for compiling Android12 source code recommends a memory of 16GB or more, and a hard disk space of 200GB or more is recommended. The more CPU cores, the better.'''</big>|} # First install the software packages needed to compile Android12 source code ::{| class="wikitable" style="width:800px;" |-| test@test:~$ '''sudo apt-get update''' test@test:~$ '''sudo apt-get install -y git gnupg flex bison gperf build-essential \''' '''zip curl zlib1g-dev gcc-multilib g++-multilib libc6-dev-i386 \''' '''lib32ncurses5-dev x11proto-core-dev libx11-dev lib32z1-dev ccache \''' '''libgl1-mesa-dev libxml2-utils xsltproc unzip u-boot-tools python-is-python3 \''' '''libssl-dev libncurses5 clang gawk'''|} <ol start="2" style="list-style-type: decimal;"><li><p>Then compile the code in the longan folder, which mainly contains u-boot and linux kernel</p><ol style="list-style-type: lower-alpha;"><li>First run '''./build.sh config''' to set compilation options</li>{| class="wikitable" style="width:800px;" |-| <p>test@test:~$ '''cd H618-Android12-Src/longan'''</p><p>test@test:~/H618-Android12-Src/longan$ '''./build.sh config'''</p> <p>Welcome to mkscript setup progress</p><p>All available platform:</p>:<p>0. android</p>:<p>1. linux</p><p>Choice [android]: '''<span style="color:#FF0000">0</span>'''</p><p>All available ic:</p>:<p>0. h618</p><p>Choice [h618]: '''<span style="color:#FF0000">0</span>'''</p><p>All available board:</p>:<p>0. ft</p>:<p>1. p1</p>:<p>2. p2</p>:<p>3. p7</p>:<p>4. p7l</p>:<p>5. perf1</p>:<p>6. perf2</p>:<p>7. perf3</p>:<p>8. qa</p><p>Choice [p2]: '''<span style="color:#FF0000">2</span>'''</p><p>All available flash:</p>:<p>0. default</p>:<p>1. nor</p><p>Choice [default]: '''<span style="color:#FF0000">0</span>'''</p><p>All available kern_ver:</p>:<p>0. linux-5.4</p><p>Choice [linux-5.4]: '''<span style="color:#FF0000">0</span>'''</p><p>All available arch:</p>:<p>0. arm</p>:<p>1. arm64</p><p>Choice [arm64]: '''<span style="color:#FF0000">1</span>'''</p><p>'''......'''</p><p>*** Default configuration is based on 'sun50iw9p1smp_h618_android_defconfig'</p><p>#</p><p># configuration written to .config</p><p>#</p><p>make[1]: Leaving directory '/home/test/H618-Android12-Src/longan/out/kernel/build'</p><p>make: Leaving directory '/home/test/H618-Android12-Src/longan/kernel/linux-5.4'</p><p>INFO: clean buildserver</p><p>INFO: prepare_buildserver</p>|}</ol><ol start="2" style="list-style-type: lower-alpha;"><li>Then run the '''./build.sh''' script to start compilation.</li>{| class="wikitable" style="width:800px;" |-| test@test:~/H618-Android12-Src/longan$ '''./build.sh'''|}</ol><ol start="3" style="list-style-type: lower-alpha;"><li>After compilation is completed, you will see the following output</li>{| class="wikitable" style="width:800px;" |-| sun50iw9p1 compile Kernel successful INFO: Prepare toolchain ... '''......''' INFO: build kernel OK. INFO: build rootfs ... INFO: skip make rootfs for android INFO: ---------------------------------------- INFO: build lichee OK. INFO: ----------------------------------------|}</ol></li></ol><ol start="3" style="list-style-type: decimal;"><li>Then use the following command to compile the Android source code and generate the final Android image</li>{| class="wikitable" style="width:800px;" |-| test@test:~$ '''cd H618-Android12-Src''' test@test:~/H618-Android12-Src$ '''source build/envsetup.sh''' test@test:~/H618-Android12-Src$ '''lunch apollo_p2-userdebug''' test@test:~/H618-Android12-Src$ '''make -j8''' test@test:~/H618-Android12-Src$ '''pack'''|}</ol><ol start="4" style="list-style-type: decimal;"><li><p>The storage path of the Android image generated by compilation is:</p>{| class="wikitable" style="width:800px;" |-| <p>'''longan/out/h618_android12_p2_uart0.img'''</p>|}</li></ol> <span id="appendix"></span> = '''Appendix''' = <span id="user-manual-update-history"></span>== User manual update history == {| class="wikitable" style="width:800px;text-align: center;"|-| '''Version'''| '''Date'''| '''Release Notes'''|-| v1.0| 2023-09-14| initial version|} <span id="image-update-history"></span>== Image update history == {| class="wikitable" style="width:800px;"|-| style="text-align: center;"| '''Date''' | style="text-align: center;"| '''Release Notes'''|-| style="text-align: center;"| 2023-09-14| orangepizero2w_1.0.0_debian_bullseye_server_linux5.4.125.7z orangepizero2w_1.0.0_ubuntu_focal_server_linux5.4.125.7z orangepizero2w_1.0.0_ubuntu_focal_desktop_xfce_linux5.4.125.7z orangepizero2w_1.0.0_debian_bullseye_desktop_xfce_linux5.4.125.7z orangepizero2w_1.0.0_ubuntu_jammy_server_linux6.1.31.7z orangepizero2w_1.0.0_debian_bookworm_server_linux6.1.31.7z orangepizero2w_1.0.0_debian_bullseye_server_linux6.1.31.7z orangepizero2w_1.0.0_ubuntu_jammy_desktop_xfce_linux6.1.31.7z orangepizero2w_1.0.0_debian_bookworm_desktop_xfce_linux6.1.31.7z orangepizero2w_1.0.0_debian_bullseye_desktop_xfce_linux6.1.31.7z OrangePi_Zero2w_Android12_v1.0.tar.gz
Opios-arch-aarch64-xfce-opizero2w-23.09-linux6.1.31.img.xz