Difference between revisions of "NanoPC-T3"

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(Working with Debian)
(updated by API)
 
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Line 40: Line 40:
 
* Working Temperature: -40℃ to 80℃
 
* Working Temperature: -40℃ to 80℃
 
* OS/Software: uboot, Android and Debian
 
* OS/Software: uboot, Android and Debian
 +
 +
==Software Features==
 +
===UbuntuCore===
 +
<!---
 +
* mainline kernel: Linux-4.11.2
 +
* rpi-monitor: check system status and information
 +
--->
 +
* npi-config: system configuration utility for setting passwords, language, timezone, hostname, SSH and auto-login,and enabling/disabling i2c, spi, serial and PWM
 +
<!---
 +
* software utility: wiringNP to access GPIO pins
 +
* software utility: RPi.GPIO_NP to access GPIO pins
 +
--->
 +
* networkmanager: manage network
 +
* system log output from serial port
 +
<!---
 +
* nano editor
 +
--->
 +
* welcome window with basic system information and status
 +
* auto-login with user account "pi" with access to npi-config
 +
* UART2 enabled
 +
* supports CAM500B
 +
<!---
 +
* sudoers include "fa"
 +
* on first system boot file system will be automatically extended.
 +
* supports file system auto check and repair on system boot.
 +
* supports FriendlyElec's [http://wiki.friendlyelec.com/wiki/index.php/NanoHat_PCM5102A NanoHat-PCM5102A] 
 +
* supports USB WiFi module: refer to [[#Connect USB WiFi to NEO]]
 +
* supports audio recording and playing with 3.5mm audio jack
 +
* supports USB Host and 100M Ethernet
 +
* supports FriendlyElec BakeBit modules
 +
* supports dynamic frequency scaling and voltage regulation
 +
* relieves overheat compared to kernel Linux-3.4
 +
* fixed MAC address
 +
 +
===Ubuntu OLED===
 +
* mainline kernel: Linux-4.11.2
 +
* supports FriendlyElec's OLED module
 +
--->
 +
 +
===Debian===
 +
* supports CAM500B
 +
 +
<!---
 +
===Debian for NAS Dock===
 +
* mainline kernel: Linux-4.11.2
 +
* supports FriendlyElec's NAS Dock
 +
* optimized OpenMediaVault configuration options
 +
* allocated swap section
 +
--->
 +
===Android===
 +
* supports setting up static IP
 +
* supports accessing hardware with FriendlyElec's libfriendlyarm-things.so
 +
* integrated iTest utility for testing hardware
  
 
==Diagram, Layout and Dimension==
 
==Diagram, Layout and Dimension==
Line 297: Line 350:
 
::#SYS_3.3V: 3.3V power output
 
::#SYS_3.3V: 3.3V power output
 
::#VDD_5V: 5V power output
 
::#VDD_5V: 5V power output
::#For more details refer to the document: [http://wiki.friendlyarm.com/wiki/images/d/d5/NanoPC-T2-T3-1603-Schematic.pdf NanoPC-T3 Schematic]
+
::#For more details refer to the document: [http://wiki.friendlyelec.com/wiki/images/b/b4/NanoPC-T2-T3-1711-Schematic.pdf NanoPC-T2-T3-1711-Schematic.pdf]
  
 
===Board Dimension===
 
===Board Dimension===
 
[[File:NanoPC-T2-T3-1603-Dimensions.png|frameless|800px|NanoPC-T3 Dimensions]]
 
[[File:NanoPC-T2-T3-1603-Dimensions.png|frameless|800px|NanoPC-T3 Dimensions]]
  
::For more details refer to the document: [http://wiki.friendlyarm.com/wiki/images/2/24/NanoPC-T2-T3-1603-Dimensions%28dxf%29.zip NanoPC-T3-Dimensions(dxf)]
+
::For more details refer to the document: [http://wiki.friendlyelec.com/wiki/images/2/24/NanoPC-T2-T3-1603-Dimensions%28dxf%29.zip NanoPC-T3-Dimensions(dxf)]
  
 
*'''Power Jack'''
 
*'''Power Jack'''
Line 318: Line 371:
 
Before starting to use your NanoPC-T3 get the following items ready
 
Before starting to use your NanoPC-T3 get the following items ready
 
* NanoPC-T3
 
* NanoPC-T3
* SD Card: Class 10 or Above, minimum 8GB SDHC
+
* SD Card: Class 10 or Above
 
* A DC 5V/2A power is a must
 
* A DC 5V/2A power is a must
 
* HDMI monitor or LCD
 
* HDMI monitor or LCD
 
* USB keyboard, mouse and possible a USB hub(or a TTL to serial board)
 
* USB keyboard, mouse and possible a USB hub(or a TTL to serial board)
* A host computer running Ubuntu 14.04 64 bit system
+
* A host computer running Ubuntu 18.04 64 bit system
 
+
{{S5P6818BootFromSDCard|NanoPC-T3}}
 
+
{{BurnOSToEMMC|NanoPC-T3|s5p6818-eflasher}}
===Make an Installation SD Card===
+
{{S5PXX18MakeSDCardViaSDFusing|NanoPC-T3|sd-fuse_s5p6818}}
====Boot NanoPC-T3 from SD Card====
+
{{ResizeTFCardFS|NanoPC-T3}}
Get the following files from [https://www.mediafire.com/folder/gg764iwvfm0mf/S5P6818_Board here] to download necessary files:<br />
+
{{S5Pxx18HDMI|NanoPC-T3|arch/arm/plat-s5p6818/nanopi3/lcds.c}}
* Get a 4G SDHC card and backup its data if necessary <br />
+
{{S5Pxx18MofidyKernelCommandLineOnHostPC|NanoPC-T3|sd-fuse_s5p6818}}
::{| class="wikitable"
+
{{FriendlyCoreGeneral|NanoPC-T3}}
|-
+
{{FriendlyCoreRunX11Application|NanoPC-T3}}
|colspan=2|Image Files:
+
{{FriendlyCoreS5Pxx18|NanoPC-T3}}
|-
+
{{UbuntuXenial-Arm64-Install-Docker|NanoPC-T3}}
|s5p6818-debian-sd4g-YYYYMMDD.img  || Debian image files                 
+
{{S5Pxx18Android|NanoPC-T3}}
|-
+
{{S5P6818BuildFromSource|NanoPC-T3}}
|s5p6818-android-sd4g-YYYYMMDD.img  || Android image files 
+
{{S5P6818-KernelHeaderFile|NanoPC-T3}}
|-
+
{{S5Pxx18ExternalModules|NanoPC-T3}}
|s5p6818-ubuntu-core-qte-sd4g-YYYYMMDD.img || Ubuntu Core + QT image files
+
{{S5Pxx18AccessHWUnderAndroid|NanoPC-T3}}
 
+
{{S5Pxx18ConnectToLCDModules|NanoPC-T3}}
|-
+
{{S5Pxx18HWfiles|NanoPC-T3}}
|colspan=2|Flash Utility: 
+
{{DownloadUrl|NanoPC-T3}}
|-
+
{{TechSupport|NanoPC-T3}}
|win32diskimager.rar || Windows utility. Under Linux users can use "dd"
+
{{MoreOS}}
|-
+
{{S5P6818ChangeLog}}
|}
+
 
+
* Uncompress these files. Insert an SD card(at least 4G) into a Windows PC and run the win32diskimager utility as administrator. On the utility's main window select your SD card's drive, the wanted image file and click on "write" to start flashing the SD card.
+
* Insert this card into your NanoPC-T3's boot slot, press and hold the boot key and power on (with a 5V/2A power source). If the PWR LED is on and LED1 is blinking this indicates your NanoPC-T3 has successfully booted.<br />
+
 
+
====Flash image to eMMC with eflasher====
+
* Download eflasher <br />
+
Get the eflasher utility s5p6818-eflasher-sd8g-xxx-full.img.7z<br />
+
This package includes a Ubuntu Core, Debian, Android 5 image files;<br />
+
Get the Windows utility: win32diskimager.rar;<br/>
+
* Flash eflasher Image <br />
+
Extract the .7z package and you will get .img files.Insert an SD card(at least 4G) into a Windows PC and run the win32diskimager utility as administrator. On the utility's main window select your SD card's drive, the wanted image file and click on "write" to start flashing the SD card.<br/>
+
If your PC runs Linux you can use the dd command to flash a .img file to the SD card;<br />
+
* Flash image to eMMC
+
Insert this card into your NanoPC-T3, connect the board to an HDMI monitor or an LCD, press and hold the boot key and power on (with a 5V/2A power source) the board. After your board is powered on you will see multiple OS options and you can select an OS to start installation.
+
<!---
+
* Download RAW Image<br />
+
Get the image file: s5p6818-eflasher-sd4g.img.zip and the Windows utility: win32diskimager.rar;
+
* Flash RAW Image to SD Card<br />
+
Insert an SD card(at least 4G) into a Windows PC and run the win32diskimager utility as administrator. On the utility's main window select your SD card's drive, the wanted image file and click on "write" to start flashing the SD card
+
* Prepare RAW image
+
Go to this link [https://www.mediafire.com/folder/gg764iwvfm0mf/NanoPC-T3_Board] to download Android and Debian image files(System-image-files-for-eMMC). After download untar the ".tgz" ball and copy the files to your SD card.
+
::{| class="wikitable"
+
|-
+
|OS || Image  || Files || Copy to...
+
|-
+
|Android 5.1  || android-lollipop-images.tgz <br /> android-lollipop-images.tgz.hash.md5
+
|| boot.img <br /> system.img <br /> userdata.img <br /> cache.img <br /> partmap.txt <br />
+
|| images\android
+
|-
+
|Debian (Jessie) || debian-jessie-images.tgz <br />debian-jessie-images.tgz.hash.md5
+
|| boot.img <br />rootfs.img <br />partmap.txt <br />
+
|| images\debian
+
|-
+
|Ubuntu Core + QT || core-qte-images.tgz <br />core-qte-images.tgz.hash.md5
+
|| boot.img <br />rootfs.img <br />partmap.txt <br />
+
|| images\core-qte
+
 
+
|-
+
|}
+
 
+
* Specify OS
+
By default the SD card's configuration file "images\FriendlyARM.ini" specifies Android to be flashed to eMMC. If you want to install Debian make the following change:
+
<syntaxhighlight lang="bash">
+
OS = Debian
+
</syntaxhighlight>
+
"#" is a comment
+
 
+
* Flash Image to NanoPC-T3's eMMC
+
Insert this card into your NanoPC-T3, connect the board to an HDMI monitor or an LCD, press and hold the boot key and power on (with a 5V/2A power source) the board to start installation. You can watch the whole installation process from the HDMI monitor or LCD. If the following messages pop up it means the installation has succeeded.
+
<syntaxhighlight lang="bash">
+
Android is fused successfully.
+
All done.
+
</syntaxhighlight>
+
After installation is done do "reset" or power off and on the board to boot the board from eMMC.
+
+
You can check the LED's status to monitor the installation process too:
+
::{| class="wikitable"
+
|-
+
|LED Status || Installation Status
+
|-
+
|LED1 blinks twice continuously <br /> LED2 off  || Power on normal.<br /> If installation doesn't proceed LED1 will keep behaving this way and LED2 will be off
+
|-
+
|LED1 and LED2 blink alternatively with each blink for 0.3s || Installation proceeding
+
|-
+
|LED1 and LED2 blink alternatively with each blink for 1.2s || Installation succeeded
+
|-
+
|LED1 and LED2 blink simultaneously || Installation failed
+
|-
+
|}
+
---><br/ >
+
[[File:NanoPC-T3-eMMC.png|frameless|500px|NanoPC-T3-eMMC]]
+
 
+
====Make Installation Card under Linux Desktop====
+
*1) Insert your SD card into a host computer running Ubuntu and check your SD card's device name
+
<syntaxhighlight lang="bash">
+
dmesg | tail
+
</syntaxhighlight>
+
Search the messages output by "dmesg" for similar words like "sdc: sdc1 sdc2". If you can find them it means your SD card has been recognized as "/dev/sdc". Or you can check that by commanding "cat /proc/partitions"
+
 
+
*2) Downlaod Linux script
+
<syntaxhighlight lang="bash">
+
git clone https://github.com/friendlyarm/sd-fuse_s5p6818.git
+
cd sd-fuse_s5p6818
+
</syntaxhighlight>
+
 
+
*3) Make Android SD Card
+
<syntaxhighlight lang="bash">
+
su
+
./fusing.sh /dev/sdx
+
</syntaxhighlight>
+
(Note: you need to replace "/dev/sdx" with the device name in your system) <br />
+
When you run the script for the first time it will prompt you to download an image you have to hit “Y” within 10 seconds otherwise you will miss the download
+
 
+
*4) Here is how to make a Debian SD card
+
<syntaxhighlight lang="bash">
+
./fusing.sh /dev/sdx debian
+
</syntaxhighlight>
+
 
+
====Extend NanoPC-T3's SD Card Section====
+
* When Debian/Ubuntu is loaded the SD card's section will be automatically extended.
+
* When Android is loaded you need to run the following commands on your host PC to extend your SD card's section:
+
<syntaxhighlight lang="bash">
+
sudo umount /dev/sdx?
+
sudo parted /dev/sdx unit % resizepart 4 100 resizepart 7 100 unit MB print
+
sudo resize2fs -f /dev/sdx7
+
</syntaxhighlight>
+
(Note: you need to replace "/dev/sdx" with the device name in your system)
+
 
+
====LCD/HDMI Resolution====
+
When the system boots our uboot will check whether it is connected to an LCD or to an HDMI monitor. If it recognizes an LCD it will configure its resolution. Our uboot defaults to the HDMI 720P configuration.<br/>
+
If you want to modify the LCD resolution you can modify file "arch/arm/plat-s5p6818/nanopi3/lcds.c" in the kernel and recompile it.<br/>
+
If your NanoPC-T3 is connected to an HDMI monitor and it runs Android it will automatically set the resolution to an appropriate HDMI mode by checking the "EDID". If your NanoPC-T3 is connected to an HDMI monitor and it runs Debian by default it will set the resolution to the HDMI 720P configuration. If you want to modify the HDMI resolution to 1080P modify your kernel's configuration as explained above.
+
 
+
===Update Image Files in SD Card From PC Host===
+
If you want to make some changes to the image files in your SD card follow the steps below otherwise you can skip this section.<br/>
+
Insert your SD card into a host PC running Linux, mount the boot and rootfs sections of the SD card and follow the steps below:<br/>
+
1) If you want to change your kernel command line parameters you can do it via the fw_setevn utility under "sd-fuse_s5p6818/tools".
+
Check the current Command Line:
+
<syntaxhighlight lang="bash">
+
cd sd-fuse_s5p6818/tools
+
./fw_printenv /dev/sdc | grep bootargs
+
</syntaxhighlight>
+
Android 5.1.1_r6 starts SELinux. By default it is enforcing. You can change it this way:
+
<syntaxhighlight lang="bash">
+
./fw_setenv /dev/sdc bootargs XXX androidboot.selinux=permissive
+
</syntaxhighlight>
+
This sets it to "permissive". The "XXX" stands for the original bootargs' value.<br/>
+
 
+
2) Update Kernel<br/>
+
Our customized uboot will check the LCD type when it boots.<br/>
+
For Android it doesn't make any difference which display device is detected. You can use your generated uImage to replace the existing one under "boot".<br/>
+
For Debian if your generated kernel is for an LCD you need to replace the existing uImage or if your kernel is for an HDMI monitor you need to replace the existing uImage.hdmi.<br/>
+
 
+
===Run Android or Debian===
+
* Insert an SD card with Android/Debian image file into your NanoPC-T3, connect the board to an HDMI monitor, press and hold the boot key, power on the board the NanoPC-T3 will boot from the SD card. If you can see the PWR LED on and the LED1 flashing it means your board is working and you will see Android/Debain being loaded on the HDMI monitor.<br/>
+
1) If you connect the NanoPC-T3 to an HDMI monitor you need to use a USB mouse and a USB keyboard to operate. If you connect it to an LCD with capacitive touch you can operate directly on the LCD.<br/>
+
2)If you want to do kernel development you need to use a serial communication board, ie a PSU-ONECOM board, which will allow you to operate the board via a serial terminal<br/>
+
* Here is a setup where we connect a NanoPC-T3 to a PC running Ubuntu and Minicom via a serial cable you will see system messages output to the PC’s minicom terminal:
+
[[File:PSU-ONECOM02.png|frameless|400px|PSU-ONECOM02]]
+
* Under Debian the password for "root" is "fa"
+
 
+
==Working with Debian==
+
===Ethernet Connection===
+
* If the NanoPC-T3 is connected to a network via Ethernet before it is powered on, it will automatically obtain an IP after it is powered up.
+
 
+
===Wireless Connection===
+
Under Debian you can manage your network with [[Use NetworkManager to configure network settings|NetworkManager]].<br />
+
After Debian boots click on the network icon on the bottom right of the task bar a NetworkManger menu will pop up and all the available networks will be listed. If there is an active wireless network you will see something similar to the following screenshot:<br />
+
[[File:NetworkManagerIcon.png|frameless|400px|NetworkManagerIcon]]<br />
+
You can click on a WiFI AP and connect your board to it.<br />
+
For more details refer to:[[Use NetworkManager to configure network settings|NetworkManager]].<br />
+
 
+
===Setup Wi-Fi AP===
+
Follow the steps below. Since our OS image by default already has the NetworkManager utility you will be prompted to uninstall it first:<br />
+
<syntaxhighlight lang="bash">
+
sudo turn-wifi-into-apmode yes
+
</syntaxhighlight>
+
After you uninstall the NetworkManager reboot your board.<br />
+
After your board is rebooted run the above commands again and you will be prompted to type in a WIFI's name and password. Type in your wanted name and password<br />
+
<br />
+
If this is successful you will be able to find and connect your board to a WIFI. Login to your board at 192.168.8.1:
+
<syntaxhighlight lang="bash">
+
ssh root@192.168.8.1
+
</syntaxhighlight>
+
Type in a password. In our system the password is "fa".<br />
+
<br />
+
To login smoothly via SSH we recommend you turning off WIFI's power save mode by running the following commands:
+
<syntaxhighlight lang="bash">
+
sudo iwconfig wlan0 power off
+
</syntaxhighlight>
+
You can check your WiFi's mode by running the following command:<br />
+
<syntaxhighlight lang="bash">
+
sudo cat /sys/module/bcmdhd/parameters/op_mode
+
</syntaxhighlight>
+
Number 2 means your WiFi is in AP mode. You can switch to the Station mode by running the following command:<br />
+
<syntaxhighlight lang="bash">
+
sudo turn-wifi-into-apmode no
+
</syntaxhighlight>
+
 
+
===Bluetooth===
+
Here are the steps to transfer a file from T2 to a mobile phone. Run the following command to search a surrounding Bluetooth device:<br />
+
<syntaxhighlight lang="bash">
+
hcitool scan
+
</syntaxhighlight>
+
<br />
+
In our example a mobile phone was detected and the following messages were listed:<br />
+
Scanning ...<br />
+
38:BC:1A:B1:7E:DD      MEIZU MX4<br />
+
<br />
+
These messages indicated that a MEIZU MX4 mobile phone was detected. We then checked the Bluetooth services this phone supported with its MAC address presented in front of its device name<br />
+
<syntaxhighlight lang="bash">
+
sdptool browse 38:BC:1A:B1:7E:DD
+
</syntaxhighlight>
+
Note: you need to use your device's name and its MAC address when you run these commands.<br /><br />
+
The command listed all the services the phone supported. We needed the "OBEX Object Push" service which is for file transfers.<br />
+
Service Name: OBEX Object Push<br />
+
Service RecHandle: 0x1000b<br />
+
Service Class ID List:<br />
+
"OBEX Object Push" (0x1105)<br />
+
Protocol Descriptor List:<br />
+
"L2CAP" (0x0100)<br />
+
"RFCOMM" (0x0003)<br />
+
Channel: 25<br />
+
"OBEX" (0x0008)<br />
+
Profile Descriptor List:<br />
+
"OBEX Object Push" (0x1105)<br />
+
Version: 0x0100<br />
+
<br />
+
From the above messages we could get the channel number 25 for the "OBEX Object Push" service. We input this number to the "ussp-push" by running the following command:
+
<syntaxhighlight lang="bash">
+
ussp-push 38:BC:1A:B1:7E:DD@25 example.jpg example.jpg
+
</syntaxhighlight>
+
Note: you need to use your device's name, its MAC address and channel number when you run these commands.<br /><br />
+
Usually after the above commands are run a popup window will show on the phone that communicates with T2 and you can start file transfers.<br />
+
<br />
+
Common Issues:<br />
+
1) If T2 cannot find a Bluetooth device you can try this command to restart its Bluetooth:<br />
+
<syntaxhighlight lang="bash">
+
rfkill unblock 0
+
</syntaxhighlight>
+
2) If any of these commands is not installed you can try this command to install it:<br />
+
<syntaxhighlight lang="bash">
+
apt-get install bluetooth bluez obexftp openobex-apps python-gobject ussp-push
+
</syntaxhighlight>
+
 
+
===Install Debian Packages===
+
We provide a Debian Jessie image. You can install Jessie's packages by commanding "apt-get". If this is your first installation you need to update the package list by running the following command
+
<syntaxhighlight lang="bash">
+
apt-get update
+
</syntaxhighlight>
+
You can install your preferred packages. For example if you want to install an FTP server you can do this:
+
<syntaxhighlight lang="bash">
+
apt-get install vsftpd
+
</syntaxhighlight>
+
Note: you can change your download server by editting "/etc/apt/sources.list". You can get a complete server list from [http://www.debian.org/mirror/list]. You need to select the one with "armhf".
+
 
+
===Audio Output from HDMI or 3.5mm Jack under Debian===
+
Our default Debian image for the NanoPC-T3 doesn't support audio output. If you want to enable this function you need to install the alsa package.
+
* Make sure your Debian OS is our latest version and your board has access to the internet;
+
* Power up your board and run the following commands on your board's commandline utility to install the alsa package:
+
<syntaxhighlight lang="bash">
+
apt-get update
+
apt-get install libasound2
+
apt-get install alsa-base
+
apt-get install alsa-utils
+
</syntaxhighlight>
+
* After the installation is done copy a ".wav" audio file to your NanoPC-T3, connect your T3 to a earphone or speaker and try playing this audio file(By default Debian's audio output is from the 3.5mm audio jack):
+
<syntaxhighlight lang="bash">
+
aplay music.wav
+
</syntaxhighlight>
+
* By default Debian's audio output is from the 3.5mm audio jack. If you want audio output from the HDMI you need to change the setting by editing the "/etc/asound.conf" file:
+
<syntaxhighlight lang="bash">
+
pcm.!default {
+
    type hw
+
    card 1
+
    device 0}
+
+
ctl.!default {
+
    type hw
+
    card 1}
+
</syntaxhighlight>
+
card 0 stands for the 3.5mm audio jack and card 1 stands for the HDMI audio. After you make your change reboot your board to make it effective.
+
 
+
==Make Your Own OS Image==
+
 
+
===Install Cross Compiler===
+
Download the compiler package:
+
<syntaxhighlight lang="bash">
+
git clone https://github.com/friendlyarm/prebuilts.git
+
sudo mkdir -p /opt/FriendlyARM/toolchain
+
sudo tar xf prebuilts/gcc-x64/arm-cortexa9-linux-gnueabihf-4.9.3.tar.xz -C /opt/FriendlyARM/toolchain/
+
</syntaxhighlight>
+
 
+
Then add the compiler's directory to "PATH" by appending the following lines in "~/.bashrc":
+
<syntaxhighlight lang="bash">
+
export PATH=/opt/FriendlyARM/toolchain/4.9.3/bin:$PATH
+
export GCC_COLORS=auto
+
</syntaxhighlight>
+
 
+
Execute "~/.bashrc" to make the changes take effect. Note that there is a space after the first ".":
+
<syntaxhighlight lang="bash">
+
. ~/.bashrc
+
</syntaxhighlight>
+
 
+
This compiler is a 64-bit one therefore it cannot be run on a 32-bit Linux machine. After the compiler is installed you can verify it by running the following commands:
+
<syntaxhighlight lang="bash">
+
arm-linux-gcc -v
+
Using built-in specs.
+
COLLECT_GCC=arm-linux-gcc
+
COLLECT_LTO_WRAPPER=/opt/FriendlyARM/toolchain/4.9.3/libexec/gcc/arm-cortexa9-linux-gnueabihf/4.9.3/lto-wrapper
+
Target: arm-cortexa9-linux-gnueabihf
+
Configured with: /work/toolchain/build/src/gcc-4.9.3/configure --build=x86_64-build_pc-linux-gnu
+
--host=x86_64-build_pc-linux-gnu --target=arm-cortexa9-linux-gnueabihf --prefix=/opt/FriendlyARM/toolchain/4.9.3
+
--with-sysroot=/opt/FriendlyARM/toolchain/4.9.3/arm-cortexa9-linux-gnueabihf/sys-root --enable-languages=c,c++
+
--with-arch=armv7-a --with-tune=cortex-a9 --with-fpu=vfpv3 --with-float=hard
+
...
+
Thread model: posix
+
gcc version 4.9.3 (ctng-1.21.0-229g-FA)
+
</syntaxhighlight>
+
 
+
===Compile U-Boot===
+
Download the U-Boot source code and compile it. Note that the github's branch is nanopi2-lollipop-mr1:
+
<syntaxhighlight lang="bash">
+
git clone https://github.com/friendlyarm/uboot_nanopi2.git
+
cd uboot_nanopi2
+
git checkout nanopi2-lollipop-mr1
+
make s5p6818_nanopi3_config
+
make CROSS_COMPILE=arm-linux-
+
</syntaxhighlight>
+
 
+
After your compilation succeeds a u-boot.bin will be generated. If you want to test it flash it to your installation SD card via fastboot. Here is how you can do it:<br/>
+
1) On your host PC run "sudo apt-get install android-tools-fastboot" to install the fastboot utility;<br/>
+
2) Connect your NanoPC-T3 to your host PC via a serial cable (e.g. PSU-ONECOME). Press the enter key within two seconds right after you power on your NanoPC-T3 and you will enter uboot's command line mode;<br/>
+
3) After type in "fastboot" and press "enter" you will enter the fastboot mode;<br/>
+
4) Connect your NanoPC-T3 to this host PC via a microUSB cable and type in the following command to flash u-boot.bin:<br/>
+
<syntaxhighlight lang="bash">
+
fastboot flash bootloader u-boot.bin
+
</syntaxhighlight>
+
<br />
+
Warning: you cannot update this SD card by commanding "dd". This command will cause trouble when booting the NanoPC-T3.<br/>
+
 
+
===Prepare mkimage===
+
You need the mkimage utility to compile a U-Boot source code package. Make sure this utility works well on your host before you start compiling a uImage.<br/>
+
You can install this utility by either commanding "sudo apt-get install u-boot-tools" or following the commands below:
+
<syntaxhighlight lang="bash">
+
cd uboot_nanopi2
+
make CROSS_COMPILE=arm-linux- tools
+
sudo mkdir -p /usr/local/sbin && sudo cp -v tools/mkimage /usr/local/sbin
+
</syntaxhighlight>
+
 
+
===Compile Linux Kernel===
+
====Compile Kernel====
+
* Download Kernel Source Code
+
<syntaxhighlight lang="bash">
+
git clone https://github.com/friendlyarm/linux-3.4.y.git
+
cd linux-3.4.y
+
git checkout nanopi2-lollipop-mr1
+
</syntaxhighlight>
+
The NanoPC-T3's kernel source code lies in the "nanopi2-lollipop-mr1" branch.
+
* Compile Android Kernel
+
<syntaxhighlight lang="bash">
+
make nanopi3_android_defconfig
+
touch .scmversion
+
make uImage
+
</syntaxhighlight>
+
* Compile Debian Kernel
+
<syntaxhighlight lang="bash">
+
make nanopi3_linux_defconfig
+
touch .scmversion
+
make uImage
+
</syntaxhighlight>
+
After your compilation succeeds a uImage will be generated in the "arch/arm/boot/uImage" directory. This kernel is for HDMI 720P. You can use it to replace the existing uImage.hdmi.<br/>
+
If you want to generate a kernel for HDMI 1080P you can do it this way:
+
<syntaxhighlight lang="bash">
+
touch .scmversion
+
make nanopi3_linux_defconfig
+
make menuconfig
+
  Device Drivers -->
+
    Graphics support -->
+
      Nexell Graphics -->
+
        [ ] LCD
+
        [*] HDMI
+
        (0)  Display In  [0=Display 0, 1=Display 1]
+
              Resolution (1920 * 1080p)  --->
+
make uImage
+
</syntaxhighlight>
+
After your compilation succeeds a uImage will be generated for HDMI 1080P. You can use it to replace the existing uImage.
+
 
+
====User Your Generated Kernel====
+
* Update the kernel file in SD card
+
If you use an SD card to boot Android you can copy your generated uImage file to your SD card's boot section(e.g. section 1 /dev/sdX1).<br/>
+
If you use an SD card to Debian and you generated a uImage for an HDMI monitor you can use that uImage to replace the uImage.hdmi file in the SD card's boot section. If you use an SD card to Debian and you generated a uImage for an LCD you can use that uImage to replace the uImage file in the SD card's boot section.
+
 
+
* Update Android kernel file in eMMC
+
If you want to update the kernel file in eMMC you need firstly boot your board, then mount eMMC's boot section, replace the boot section's kernel file with your generated one and reboot your board to make your new kernel run.<br/>
+
If you boot your board from eMMC you can update your kernel file by following the steps below:<br/>
+
1) After Android is loaded mount eMMC's boot section (in our example eMMC's device name was /dev/mmcblk0p1) by using the following commands:<br/>
+
<syntaxhighlight lang="bash">
+
su
+
mount -t ext4 /dev/block/mmcblk0p1 /mnt/media_rw/sdcard1/
+
</syntaxhighlight>
+
2) Connect your board to a host PC running Ubuntu and copy the uImage file to eMMC's boot section by running the following commands;<br/>
+
<syntaxhighlight lang="bash">
+
adb push uImage /mnt/media_rw/sdcard1/
+
</syntaxhighlight>
+
3) Or you can copy your generated kernel file to an external storage card(e.g. an SD card or a USB drive), connect the storage card to your board the move the file from the card to eMMC's boot section;<br/>
+
4) After update is done type in "reboot" to reload Android. Note don't directly power off and on the board or press the reset button to reboot the board. These two actions will damage your kernel file.<br/>
+
 
+
* Update Debian kernel file in eMMC
+
If you boot your board from eMMC you can update your kernel file by following the steps below:<br/>
+
1) When Debian is being loaded eMMC's boot section will be automatically mounted(in our example eMMC's device name was /dev/mmcblk0p1). You can use "mount" to verify that;<br/>
+
2) Connect your board to a host PC via Ethernet and copy your generated uImage file via scp/ftp to eMMC's boot section and replace the existing file. If your file is for an LCD use your uImage file to replace the existing uImage. If your file is for an HDMI monitor use your uImage.hdmi file to replace the existing uImage.hdmi file;<br/>
+
3) Or you can copy your generated kernel file to an external storage card(e.g. an SD card or a USB drive), connect the storage card to your board the move the file from the card to eMMC's boot section;<br/>
+
4) After update is done type in "reboot" to reload Debian. Note don't directly power off and on the board or press the reset button to reboot the board. These two actions will damage your kernel file<br/>
+
 
+
* Generate Your boot.img
+
 
+
If you want to generate an image file that can be flashed to eMMC you need to generate a boot.img file and copy it to your installation SD card.<br/>
+
For Android copy the uImage file to Android source code's "device/friendly-arm/nanopi3/boot/" directory and compile this whole Android source code. After your compilation is successful you will get a boot.img file.<br/>
+
For Debian follow the steps below to generate a boot.img file:<br/>
+
1) Download debian_nanopi2
+
<syntaxhighlight lang="bash">
+
git clone https://github.com/friendlyarm/debian_nanopi2.git
+
</syntaxhighlight>
+
2) Copy the image file for an HDMI monitor and use it to replace the "debian_nanopi2/boot/uImage.hdmi" file and copy the image file for an LCD and use it to replace the "debian_nanopi2/boot/uImage" file;<br/>
+
3) Generate Debian's boot.img
+
<syntaxhighlight lang="bash">
+
cd debian_nanopi2
+
mkdir rootfs
+
./build.sh
+
</syntaxhighlight>
+
A newly generated boot.img will be under the "debian_nanopi2/sd-fuse_nanopi2/debian" directory.<br/>
+
The "mkdir rootfs" command creates a working directory for the build.sh script to run. It also creates some files such as "rootfs.img" but these files are useless.
+
 
+
====Compile Kernel Modules====
+
Android contains kernel modules which are in the "/lib/modules" directory in the system section. If you want to add your own modules to the kernel or you changed your kernel configurations you need to recompile these new modules.<br/>
+
Compile Original Kernel Modules:
+
<syntaxhighlight lang="bash">
+
cd linux-3.4.y
+
make CROSS_COMPILE=arm-linux- modules
+
</syntaxhighlight>
+
Here we have two new modules and we can compile them by following the commands below:
+
<syntaxhighlight lang="bash">
+
cd /opt/FriendlyARM/s5p6818/android
+
./vendor/friendly-arm/build/common/build-modules.sh
+
</syntaxhighlight>
+
The "/opt/FriendlyARM/s5p6818/android" directory points to the top directory of Android source code. You can get more details by specifying option "-h".<br/>
+
After your compilation succeeds new modules will be generated
+
 
+
===Compile Android===
+
 
+
* Install Cross Compiler
+
Install 64 bit Ubuntu 14.04 on your host PC.
+
<syntaxhighlight lang="bash">
+
sudo apt-get install bison g++-multilib git gperf libxml2-utils make python-networkx zip
+
sudo apt-get install flex libncurses5-dev zlib1g-dev gawk minicom
+
</syntaxhighlight>
+
For more details refer to https://source.android.com/source/initializing.html 。
+
 
+
* Download Source Code
+
You need to use repo to get the Android source code. Refer to https://source.android.com/source/downloading.html 。
+
<syntaxhighlight lang="bash">
+
mkdir android && cd android
+
repo init -u https://github.com/friendlyarm/android_manifest.git -b nanopi3-lollipop-mr1
+
repo sync
+
</syntaxhighlight>
+
The "android" directory is the working directory.
+
 
+
* Compile System Package
+
<syntaxhighlight lang="bash">
+
source build/envsetup.sh
+
lunch aosp_nanopi3-userdebug
+
make -j8
+
</syntaxhighlight>
+
After your compilation succeeds an image will be generated in the "out/target/product/nanopi3/" directory.
+
::{| class="wikitable"
+
|-
+
|filename    || partition || Description 
+
|-
+
|boot.img    || boot      || -
+
|-
+
|cache.img    || cache    || -
+
|-
+
|userdata.img || userdata  || -
+
|-
+
|system.img  || system    || -
+
|-
+
|partmap.txt  || -        || partition file
+
|-
+
|}
+
 
+
* Flash Image to SD Card
+
If you want to boot your board from an SD card you need to copy your generated image file to the "sd-fuse_s5p6818
+
/android/" directory and flash it to your SD card with our script. For more details refer to [[# Make an Installation SD Card under Linux Desktop]]。
+
 
+
* Flash Image to eMMC
+
After compiling Android successfully you can flash it to eMMC with either of the following methods:<br/>
+
1) fastboot: right after the NanoPC-T2 is booted from eMMC press any key to enter the uboot commandline mode and type in "fastboot"<br/>
+
Connect your board to a host PC running Ubuntu with a USB cable and run the following commands in the PC's terminal:<br />
+
<syntaxhighlight lang="bash">
+
cd out/target/product/nanopi3
+
sudo fastboot flash boot boot.img
+
sudo fastboot flash cache cache.img
+
sudo fastboot flash userdata userdata.img
+
sudo fastboot flash system system.img
+
sudo fastboot reboot
+
</syntaxhighlight>
+
2) Use an SD Card<br/>
+
Copy these files: boot.img, cache.img, userdata.img, system.img, partmap.txt from the out/target/product/nanopi3 directory to your installation SD card's images/android directory and you can use this SD card to flash Android to eMMC.<br/>
+
 
+
==Connect NanoPC-T3 to External Modules==
+
===Connect NanoPC-T3 to USB Camera(FA-CAM202)===
+
* In this use case the NanoPC-T3 runs Debian. If you connect your NanoPC-T3 to our LCD or an HDMI monitor after Debain is fully loaded click on "other"-->"xawtv" on the left bottom of the GUI and the USB Camera application will be started. After enter "welcome to xawtv!" click on "OK" to start exploring.
+
[[File:USB-camera-nanopi2.png|frameless|500px|USB camera]]
+
[[File:USB-camera-nanopC-T2-01.png|frameless|500px|USB camera-01]]
+
 
+
===Connect NanoPC-T3 to CMOS 5M-Pixel Camera===
+
<!---
+
* In this use case the NanoPC-T3 runs Android5.1. If you connect your NanoPC-T3 to our LCD or an HDMI monitor after Android is fully loaded click on the "Camera" icon and the application will be started.
+
[[File:CMOS-camera-nanopc-t2.png|frameless|500px|CMOS camera]]
+
--->
+
For more details about the CAM500A camera refer to [http://wiki.friendlyarm.com/wiki/index.php/Matrix_-_CAM500A]<br/>
+
*If your NanoPC-T3 runs Android5.1 and it is connected to our LCD or an HDMI monitor after Android is fully loaded click on the "Camera" icon and the application will be started. You can take pictures or record videos
+
[[File:CMOS-camera-nanopc-t2.png|frameless|500px|CMOS camera]]
+
 
+
*Under Debian/Ubuntu a camera utility "nanocams" is available for previewing 40 frames and picture taking. You can try it by following the commands below
+
<syntaxhighlight lang="bash">
+
sudo nanocams -p 1 -n 40 -c 4 -o IMG001.jpg
+
</syntaxhighlight>
+
For more details about the usage of the nanocams run "nanocams -h".
+
You can get its source code from our git hub:
+
<syntaxhighlight lang="bash">
+
git clone https://github.com/friendlyarm/nexell_linux_platform.git
+
</syntaxhighlight>
+
 
+
===Use OpenCV to Access USB Camera===
+
* The full name of "OpenCV" is Open Source Computer Vision Library and it is a cross platform vision library.
+
* When the NanoPC-T3 runs Debian users can use OpenCV APIs to access a USB Camera device.<br>
+
1. Here is a guideline on how to use OpenCV with C++ on the NanoPC-T3:
+
* Firstly you need to make sure your NanoPC-T3 is connected to the internet.Login to your NanoPC-T3 via a serial terminal or SSH. After login type in your username(root) and password(fa):
+
* Run the following commands:
+
<br>
+
<syntaxhighlight lang="bash">
+
apt-get update
+
apt-get install libcv-dev libopencv-dev
+
</syntaxhighlight>
+
 
+
2. Make sure your USB camera works with the NanoPC-T3. You can test your camera with NanoPC-T3's camera utility.<br>
+
 
+
3. Check your camera device:
+
<syntaxhighlight lang="bash">
+
ls /dev/video*
+
</syntaxhighlight>
+
* Note:in our test case video0 was the device name.
+
 
+
4. OpenCV's code sample(official code in C++) is under /home/fa/Documents/opencv-demo. Compile the code sample with the following commands:
+
<syntaxhighlight lang="bash">
+
cd /home/fa/Documents/opencv-demo
+
make
+
</syntaxhighlight>
+
After it is compiled successfully a "demo" executable will be generated<br />
+
 
+
5. Connect NanoPC-T3 to USB Keyboard & Run the Following Command:
+
<syntaxhighlight lang="bash">
+
./demo
+
</syntaxhighlight>
+
opencv is successfully started
+
 
+
===Connect NanoPC-T3 to Matrix GPS Module===
+
* The Matrix-GPS module is a small GPS module with high performance. It can be used in navigation devices, four-axle drones and etc.
+
* The Matrix-GPS module uses serial communication. When the NanoPC-T3 is connected to the Matrix GPS module, after the NanoPC-T3 is powered up type in the following command in a terminal or click on the xgps icon it will be started.
+
<syntaxhighlight lang="bash">
+
$su - fa -c "DISPLAY=:0 xgps 127.0.0.1:9999"
+
</syntaxhighlight>
+
* Or on the Debian GUI start the LXTerminal, type in "xgps" and enter it will be started too.
+
For more details about this GPS module refer to [http://wiki.friendlyarm.com/wiki/index.php/Matrix_-_GPS Click to check]<br />
+
Refer to the following diagram to connect the NanoPC-T3 to the Matrix-GPS:<br />
+
[[File:GPS_NanoPC-T2.png|frameless|600px|GPS_NanoPC-T2]]
+
 
+
Connection Details:
+
{| class="wikitable"
+
|-
+
|Matrix-GPS || NanoPC-T3    
+
|-
+
|RXD    || Pin11
+
|-
+
|TXD    || Pin12
+
|-
+
|5V    || Pin29
+
|-
+
|GND    || Pin30
+
|}
+
 
+
==Android Hardware Access==
+
FriendlyElec developed a library called “libfriendlyarm-hardware.so”, for android developer to access the hardware resources on the development board in their android apps, the library is based on Android NDK.<br />
+
Accessible Modules:
+
* Serial Port
+
* PWM
+
* EEPROM
+
* ADC
+
* LED
+
* LCD 1602 (I2C)
+
* OLED (SPI)
+
 
+
Accessible Ports:
+
* GPIO
+
* Serial Port
+
* I2C
+
* SPI
+
 
+
Please refer to the following url for details:<br />
+
* Homepage: http://wiki.friendlyarm.com/wiki/index.php/Android_Hardware_Access
+
* Examples: https://github.com/friendlyarm/AndroidHardwareAccess
+
* Guide to API in Chinese: https://github.com/friendlyarm/AndroidHardwareAccess/blob/master/友善电子Android硬件开发指南.pdf
+
 
+
==Source Code and Image Files Download Links==
+
* Image File:[https://www.mediafire.com/folder/gg764iwvfm0mf/S5P6818]
+
* Source Code:[https://github.com/friendlyarm]
+
 
+
==Resources==
+
*SOC Datasheet: [http://wiki.friendlyarm.com/wiki/images/8/8b/SEC_S5P6818X_Users_Manual_preliminary_Ver_0.00.pdf S5P6818 Datasheet]
+
* AXP228_Users_Manual [http://wiki.friendlyarm.com/wiki/index.php/File:116.AXP228_V1.1_20130106.pdf AXP228_V1.1_20130106]
+
* eMMC [http://wiki.friendlyarm.com/wiki/index.php/File:KLMxGxxEMx-B031(eMMC5.0_1xnm_based_e_MMC)1.0.pdf eMMC5.0_1xnm_based_e_MMC]
+
*Schematic: [http://wiki.friendlyarm.com/wiki/images/d/d5/NanoPC-T2-T3-1603-Schematic.pdf NanoPC-T3 Schematic]
+
*PCB Dimension: [http://wiki.friendlyarm.com/wiki/images/2/24/NanoPC-T2-T3-1603-Dimensions%28dxf%29.zip NanoPC-T3-Dimensions(dxf)]
+
 
+
==Update Log==
+
===April-28-2016===
+
* Released English version
+
 
+
===June-30-2016===
+
* Added sections 5.2.4 and 8
+
 
+
===Sep-27-2016===
+
* Added section 9
+
* Updated sections 5.2.2 and 8.2
+
 
+
===Nov-2-2016===
+
* Updated sections 6.4 and 11
+

Latest revision as of 08:14, 3 July 2024

查看中文

Contents

1 Introduction

Overview
Front
Back
  • The NanoPC-T3 octa-core single board computer is designed and developed by FriendlyARM for professional and enterprise users. It uses the Samsung Octa-Core Cortex-A53 S5P6818 SoC. Compared to the FriendlyARM NanoPC-T2 the NanoPC-T3 not only has all the T2’s interfaces and ports but also has a more powerful SoC. Its dynamic frequency scales from 400M up to 1.4GHz. The NanoPC-T3 has 8G eMMC onboard, audio jack, video input/output interfaces, built-in WiFi, Bluetooth and Gbps Ethernet port. In addition the NanoPC-T3 has power management, on board porcelain antenna and serial debug port. To avoid overheat issues the NanoPC-T3 has a heat sink with mounting holes.
  • The NanoPC-T3 has two camera interfaces: a DVP camera interface and a MIPI-CSI interface, and four video interfaces: HDMI 1.4A, LVDS, parallel RGB-LCD interface and MIPI-DSI interface. It supports RTC and has RTC interface pins. It has four USB ports with two being type A ports and two being 2.54mm pitch pin-headers.
  • The NanoPC-T3 supports muitple OS systems e.g. Android5.1, Debian and UbuntoCore+Qt. It is an open source project with rich interfaces and ports. It is born a choice for professional and enterprise users.

2 Hardware Spec

  • SoC: Samsung S5P6818 Octa-Core Cortex-A53, 400M Hz - 1.4G Hz
  • Power Management Unit: AXP228 PMU, it supports software power-off and wake-up.
  • System Memory: 1GB/2GB 32bit DDR3 RAM
  • Storage: 1 x SD Card Socket
  • Ethernet: Gbit Ethernet(RTL8211E)
  • WiFi: 802.11b/g/n
  • Bluetooth: 4.0 dual mode
  • Antenna: Porcelain Antenna IPX Interface
  • eMMC: 8GB
  • Video Input: DVP Camera/MIPI-CSI (two camera interfaces)
  • Video Output: HDMI Type-A / LVDS / Parallel RGB-LCD / MIPI-DSI (four video output interfaces)
  • Audio: 3.5 mm audio jack / via HDMI
  • Microphone: onboard Microphone
  • USB Host: 4 x USB 2.0 Host, two type A ports and two 2.54 mm pitch pin-headers
  • MicroUSB: 1 x MicroUSB 2.0 Client, Type A
  • LCD Interface: 0.5mm pitch 45 pin FPC seat, full color RGB 8-8-8
  • HDMI: 1.4A Type A, 1080P
  • DVP Camera: 0.5mm pitch 24 pin FPC seat
  • GPIO: 2.54 mm pitch 30 pin-header
  • Serial Debug Port: 2.54mm pitch 4-pin-header
  • User Key: K1 (power), Reset
  • LED: 1 x power LED and 2 x GPIO LED
  • Other Resources: CPU’s internal TMU
  • RTC Battery: RTC Battery Seat
  • Heat Sink: 1 x Heat Sink with mounting holes
  • Power: DC 5V/2A
  • PCB: Six Layer
  • Dimension: 100 mm x 60 mm
  • Working Temperature: -40℃ to 80℃
  • OS/Software: uboot, Android and Debian

3 Software Features

3.1 UbuntuCore

  • npi-config: system configuration utility for setting passwords, language, timezone, hostname, SSH and auto-login,and enabling/disabling i2c, spi, serial and PWM
  • networkmanager: manage network
  • system log output from serial port
  • welcome window with basic system information and status
  • auto-login with user account "pi" with access to npi-config
  • UART2 enabled
  • supports CAM500B

3.2 Debian

  • supports CAM500B

3.3 Android

  • supports setting up static IP
  • supports accessing hardware with FriendlyElec's libfriendlyarm-things.so
  • integrated iTest utility for testing hardware

4 Diagram, Layout and Dimension

4.1 Layout

NanoPC-T3 Layout
  • 30Pin GPIO Pin Spec
Pin# Name Pin# Name
1 SYS_3.3V 2 DGND
3 UART2_TX/GPIOD20 4 UART2_RX/GPIOD16
5 I2C0_SCL 6 I2C0_SDA
7 SPI0_MOSI/GPIOC31 8 SPI0_MISO/GPIOD0
9 SPI0_CLK/GPIOC29 10 SPI0_CS/GPIOC30
11 UART3_TX/GPIOD21 12 UART3_RX/GPIOD17
13 UART4_TX/GPIOB29 14 UART4_RX/GPIOB28
15 UART5_TX/GPIOB31 16 UART5_RX/GPIOB30
17 GPIOC4 18 GPIOC7
19 GPIOC8 20 GPIOC24
21 GPIOC28 22 GPIOB26
23 GPIOD1/PWM0 24 GPIOD8/PPM
25 GPIOC13/PWM1 26 AliveGPIO3
27 GPIOC14/PWM2 28 AliveGPIO5
29 VDD_5V 30 DGND
  • 20Pin LVDS Interface Pin Spec
Pin# Name Pin# Name
1 SYS_3.3V 2 SYS_3.3V
3 GPIOC16 4 GPIOB18
5 DGND 6 DGND
7 LVDS_D0- 8 LVDS_D0+
9 LVDS_D1- 10 LVDS_D1+
11 LVDS_D2- 12 LVDS_D2+
13 DGND 14 DGND
15 LVDS_CLK- 16 LVDS_CLK+
17 LVDS_D3- 18 LVDS_D3+
19 I2C2_SCL 20 I2C2_SDA
  • DVP Camera Interface Pin Spec
Pin# Name
1, 2 SYS_3.3V
7,9,13,15,24 DGND
3 I2C0_SCL
4 I2C0_SDA
5 GPIOB14
6 GPIOB16
8,10 NC
11 VSYNC
12 HREF
14 PCLK
16-23 Data bit7-0
  • RGB LCD Interface Pin Spec
Pin# Name Description
1, 2 VDD_5V 5V Output, it can be used to power LCD modules
11,20,29, 37,38,39,40, 45 DGND Ground
3-10 Blue LSB to MSB RGB blue
12-19 Green LSB to MSB RGB green
21-28 Red LSB to MSB RGB red
30 GPIOB25 available for users
31 GPIOC15 occupied by FriendlyARM one wire technology to recognize LCD models and control backlight and implement resistive touch, not applicable for users
32 XnRSTOUT Form CPU low when system is reset
33 VDEN signal the external LCD that data is valid on the data bus
34 VSYNC vertical synchronization
35 HSYNC horizontal synchronization
36 LCDCLK LCD clock, Pixel frequency
41 I2C2_SCL I2C2 clock signal, for capacitive touch data transmission
42 I2C2_SDA I2C2 data signal, for capacitive touch data transmission
43 GPIOC16 interrupt pin for capacitive touch, used with I2C2
44 NC Not connected
  • MIPI-DSI Interface Pin Spec
Pin# Name
1, 2, 3 VDD_5V
4 DGND
5 I2C2_SDA
6 I2C2_SCL
7 DGND
8 GPIOC0
9 DGND
10 GPIOC1
11 DGND
12 GPIOA28
13 nRESETOUT
14, 15 DGND
16 MIPIDSI_DN3
17 MIPIDSI_DP3
18 DGND
19 MIPIDSI_DN2
20 MIPIDSI_DP2
21 DGND
22 MIPIDSI_DN1
23 MIPIDSI_DP1
24 DGND
25 MIPIDSI_DN0
26 MIPIDSI_DP0
27 DGND
28 MIPIDSI_DNCLK
29 MIPIDSI_DPCLK
30 DGND
  • MIPI-CSI Interface Pin Spec
Pin# Name
1, 2 SYS_3.3V
3 DGND
4 I2C0_SDA
5 I2C0_SCL
6 DGND
7 SPI2_MOSI/GPIOC12
8 SPI2_MISO/GPIOC11
9 SPI2_CS/GPIOC10
10 SPI2_CLK/GPIOC9
11 DGND
12 GPIOB9
13 GPIOC2
14, 15 DGND
16 MIPICSI_DN3
17 MIPICSI_DP3
18 DGND
19 MIPICSI_DN2
20 MIPICSI_DP2
21 DGND
22 MIPICSI_DN1
23 MIPICSI_DP1
24 DGND
25 MIPICSI_DN0
26 MIPICSI_DP0
27 DGND
28 MIPICSI_DNCLK
29 MIPICSI_DPCLK
30 DGND
Notes
  1. SYS_3.3V: 3.3V power output
  2. VDD_5V: 5V power output
  3. For more details refer to the document: NanoPC-T2-T3-1711-Schematic.pdf

4.2 Board Dimension

NanoPC-T3 Dimensions

For more details refer to the document: NanoPC-T3-Dimensions(dxf)
  • Power Jack
  • DC 4.7~5.6V IN, 4.0*1.7mm Power Jack
DC-023.png

5 Notes in Hardware Design

5.1 EEPROM

  • The board has an EEPROM(model: 24AA025E48T-I/OT) with a unique MAC. This EEPROM is connected to I2C0 and its address is 0x51 therefore some EEPROM chips cannot be connected to I2C0 which will cause conflicts of addresses.
  • In our tests these EEPROM chips cannot be connected to I2C0: 24C04, 24C08 and 24C16. There chips which we tested can be connected to I2C0: 24C01, 24C02 and 24C256
  • For more details about EEPROM address issues refer to http://www.onsemi.com/pub_link/Collateral/CAT24C01-D.PDF

6 Get Started

6.1 Essentials You Need

Before starting to use your NanoPC-T3 get the following items ready

  • NanoPC-T3
  • SD Card: Class 10 or Above
  • A DC 5V/2A power is a must
  • HDMI monitor or LCD
  • USB keyboard, mouse and possible a USB hub(or a TTL to serial board)
  • A host computer running Ubuntu 18.04 64 bit system

6.2 Boot from SD Card

Get the following files from here download link:

  • Get a 8G SDHC card and backup its data if necessary.
Image Files
s5p6818-sd-friendlycore-xenial-4.4-armhf-YYYYMMDD.img.zip FriendlyCore(32bit) with Qt 5.10.0 (base on Ubuntu core) image file
s5p6818-sd-friendlycore-xenial-4.4-arm64-YYYYMMDD.img.zip FriendlyCore(64bit) with Qt 5.10.0 (base on Ubuntu core) image file
s5p6818-sd-lubuntu-desktop-xenial-4.4-armhf-YYYYMMDD.img.zip LUbuntu Desktop image file with X Window
s5p6818-sd-friendlywrt-4.4-YYYYMMDD.img.zip FriendlyWrt image file (base on OpenWrt)
s5p6818-sd-android7-YYYYMMDD.img.zip Android7 image file
s5p6818-sd-android-lollipop-YYYYMMDD.img.zip Android5.1 image file
s5p6818-eflasher-lubuntu-desktop-xenial-4.4-armhf-YYYYMMDD.img.zip SD card image, which is used to install a lubuntu desktop to eMMC
s5p6818-eflasher-friendlywrt-4.4-YYYYMMDD.img.zip SD card image, which is used to install a FriendlyWrt to eMMC
s5p6818-eflasher-android7-YYYYMMDD.img.zip SD card image, which is used to install a android7 to eMMC
s5p6818-eflasher-android-lollipop-YYYYMMDD.img.zip SD card image, which is used to install an Android to eMMC
s5p6818-eflasher-friendlycore-xenial-4.4-arm64-YYYYMMDD.img.zip SD card image, which is used to install a FriendlyCore-arm64 to eMMC
s5p6818-eflasher-friendlycore-xenial-4.4-armhf-YYYYMMDD.img.zip SD card image, which is used to install a FriendlyCore-armhf to eMMC
Flash Utility:
win32diskimager.rar Windows utility. Under Linux users can use "dd"
  • Uncompress these files. Insert an SD card(at least 4G) into a Windows PC and run the win32diskimager utility as administrator. On the utility's main window select your SD card's drive, the wanted image file and click on "write" to start flashing the SD card.
  • Insert this card into your board's boot slot, press and hold the boot key (only applies to a board with onboard eMMC) and power on (with a 5V/2A power source). If the PWR LED is on and LED1 is blinking this indicates your board has successfully booted.

6.3 Flash image to eMMC with eflasher

  • Download eflasher image file

An image file's name is as : s5p6818-eflasher-OSNAME-YYYYMMDD.img.zip
The "OSNAME" is the name of an OS e.g. android, friendlycore and etc;
This image file is used for making an installation SD card and it contains a Ubuntu core system and a utility EFlasher;
Download s5p6818-eflasher-OSNAME-YYYYMMDD.img.zip to a host PC and get a windows utility win32diskimager.rar as well;

  • Make Installation SD Card with eflasher

Extract the package with a 7z utility and you will get a file with an extension ".img". Insert an SDHC card(minimum 8G or above) to a PC running Windows, run the Win32DiskImager utility as administrator, click on "Image File" to select your wanted file, select your SD card and click on "Write" to start flashing the Image to your SD card;
If your PC runs Linux you can command "dd" to extract the package and get an ".img" file and write it to your SD card;

  • Operate in GUI Window: Flash OS to eMMC

Insert your SD card to NanoPC-T3, connect an HDMI monitor or LCD to your board, press and hold the "boot" key beside the Ethernet port, power on the board you will see a pop-up window asking you to select an OS for installation. Select your wanted OS and start installation.

  • Operate in Commandline Utility: Flash OS to eMMC

Insert an installation SD card to NanoPC-T3, log into or SSH to your board and run the following command to start EFlasher:

sudo eflasher

6.3.1 Make Installation Card under Linux Desktop

  • 1) Insert your SD card into a host computer running Ubuntu and check your SD card's device name
dmesg | tail

Search the messages output by "dmesg" for similar words like "sdc: sdc1 sdc2". If you can find them it means your SD card has been recognized as "/dev/sdc". Or you can check that by commanding "cat /proc/partitions"

  • 2) Downlaod Linux script

git clone https://github.com/friendlyarm/sd-fuse_s5p6818.git
cd sd-fuse_s5p6818

  • 3) Here is how to make a Lubuntu desktop SD card
sudo ./fusing.sh /dev/sdx lubuntu

(Note: you need to replace "/dev/sdx" with the device name in your system)
When you run the script for the first time it will prompt you to download an image you have to hit “Y” within 10 seconds otherwise you will miss the download

  • 4) Run this command to make a complete image file:
sudo ./mkimage.sh lubuntu

More content please refre: Assembling the SD card image yourself

6.4 Extend SD Card Section

  • When Debian/Ubuntu is loaded the SD card's section will be automatically extended.
  • When Android is loaded you need to run the following commands on your host PC to extend your SD card's section:
sudo umount /dev/sdx?
sudo parted /dev/sdx unit % resizepart 4 100 resizepart 7 100 unit MB print
sudo resize2fs -f /dev/sdx7

(Note: you need to replace "/dev/sdx" with the device name in your system)

6.5 LCD/HDMI Resolution

When the system boots our uboot will check whether it is connected to an LCD or to an HDMI monitor. If it recognizes an LCD it will configure its resolution. Our uboot defaults to the HDMI 720P configuration.
If you want to modify the LCD resolution you can modify file "arch/arm/plat-s5p6818/nanopi3/lcds.c" in the kernel and recompile it.
If your NanoPC-T3 is connected to an HDMI monitor and it runs Android it will automatically set the resolution to an appropriate HDMI mode by checking the "EDID". If your NanoPC-T3 is connected to an HDMI monitor and it runs Debian by default it will set the resolution to the HDMI 720P configuration. If you want to modify the HDMI resolution to 1080P modify your kernel's configuration as explained above.

6.6 Update SD Card's boot parameters From PC Host

Insert your SD card into a host PC running Linux, if you want to change your kernel command line parameters you can do it via the fw_setevn utility.
Check the current Command Line:

git clone https://github.com/friendlyarm/sd-fuse_s5p6818.git
cd sd-fuse_s5p6818/tools
./fw_printenv /dev/sdx | grep bootargs

For example, to disable android SELinux, You can change it this way:

./fw_setenv /dev/sdc bootargs XXX androidboot.selinux=permissive

The "XXX" stands for the original bootargs' value.

7 Work with FriendlyCore

7.1 Introduction

FriendlyCore is a light Linux system without X-windows, based on ubuntu core, It uses the Qt-Embedded's GUI and is popular in industrial and enterprise applications.

Besides the regular Ubuntu core's features our FriendlyCore has the following additional features:

  • it supports our LCDs with both capacitive touch and resistive touch(S700, X710, HD702, S430, HD101 and S70)
  • it supports WiFi
  • it supports Ethernet
  • it supports Bluetooth and has been installed with bluez utilities
  • it supports audio playing
  • it supports Qt 5.10.0 EGLES and OpenGL ES1.1/2.0 (Only for S5P4418/S5P6818)

7.2 System Login

  • If your board is connected to an HDMI monitor you need to use a USB mouse and keyboard.
  • If you want to do kernel development you need to use a serial communication board, ie a PSU-ONECOM board, which will

For example, NanoPi-M1:
PSU-ONECOM-M1.jpg
You can use a USB to Serial conversion board too.
Make sure you use a 5V/2A power to power your board from its MicroUSB port:
For example, NanoPi-NEO2:
USB2UART-NEO2.jpg

  • FriendlyCore User Accounts:

Non-root User:

   User Name: pi
   Password: pi

Root:

   User Name: root
   Password: fa

The system is automatically logged in as "pi". You can do "sudo npi-config" to disable auto login.

  • Update packages
$ sudo apt-get update

7.3 Configure System with npi-config

The npi-config is a commandline utility which can be used to initialize system configurations such as user password, system language, time zone, Hostname, SSH switch , Auto login and etc. Type the following command to run this utility.

$ sudo npi-config

Here is how npi-config's GUI looks like:
npi-config

7.4 Develop Qt Application

Please refer to: How to Build and Install Qt Application for FriendlyELEC Boards

7.5 Setup Program to AutoRun

You can setup a program to autorun on system boot with npi-config:

sudo npi-config

Go to Boot Options -> Autologin -> Qt/Embedded, select Enable and reboot.

7.6 Extend TF Card's Section

When FriendlyCore is loaded the TF card's section will be automatically extended.You can check the section's size by running the following command:

$ df -h

7.7 Transfer files using Bluetooth

Take the example of transferring files to the mobile phone. First, set your mobile phone Bluetooth to detectable status, then execute the following command to start Bluetooth search.:

hcitool scan


Search results look like:

Scanning ...
    2C:8A:72:1D:46:02   HTC6525LVW

This means that a mobile phone named HTC6525LVW is searched. We write down the MAC address in front of the phone name, and then use the sdptool command to view the Bluetooth service supported by the phone:

sdptool browser 2C:8A:72:1D:46:02

Note: Please replace the MAC address in the above command with the actual Bluetooth MAC address of the mobile phone.
This command will detail the protocols supported by Bluetooth for mobile phones. What we need to care about is a file transfer service called OBEX Object Push. Take the HTC6525LVW mobile phone as an example. The results are as follows:

Service Name: OBEX Object Push
Service RecHandle: 0x1000b
Service Class ID List:
  "OBEX Object Push" (0x1105)
Protocol Descriptor List:
  "L2CAP" (0x0100)
  "RFCOMM" (0x0003)
    Channel: 12
  "OBEX" (0x0008)
Profile Descriptor List:
  "OBEX Object Push" (0x1105)
    Version: 0x0100

As can be seen from the above information, the channel used by the OBEX Object Push service of this mobile phone is 12, we need to pass it to the obexftp command, and finally the command to initiate the file transfer request is as follows:

obexftp --nopath --noconn --uuid none --bluetooth -b 2C:8A:72:1D:46:02 -B 12 -put example.jpg

Note: Please replace the MAC address, channel and file name in the above command with the actual one.

After executing the above commands, please pay attention to the screen of the mobile phone. The mobile phone will pop up a prompt for pairing and receiving files. After confirming, the file transfer will start.

Bluetooth FAQ:
1) Bluetooth device not found on the development board, try to open Bluetooth with the following command:

rfkill unblock 0

2) Prompt can not find the relevant command, you can try to install related software with the following command:

apt-get install bluetooth bluez obexftp openobex-apps python-gobject ussp-push

7.8 WiFi

For either an SD WiFi or a USB WiFi you can connect it to your board in the same way. The APXX series WiFi chips are SD WiFi chips. By default FriendlyElec's system supports most popular USB WiFi modules. Here is a list of the USB WiFi modules we tested:

Index Model
1 RTL8188CUS/8188EU 802.11n WLAN Adapter
2 RT2070 Wireless Adapter
3 RT2870/RT3070 Wireless Adapter
4 RTL8192CU Wireless Adapter
5 mi WiFi mt7601
6 5G USB WiFi RTL8821CU
7 5G USB WiFi RTL8812AU

You can use the NetworkManager utility to manage network. You can run "nmcli" in the commandline utility to start it. Here are the commands to start a WiFi connection:

  • Change to root
$ su root
  • Check device list
$ nmcli dev

Note: if the status of a device is "unmanaged" it means that device cannot be accessed by NetworkManager. To make it accessed you need to clear the settings under "/etc/network/interfaces" and reboot your system.

  • Start WiFi
$ nmcli r wifi on
  • Scan Surrounding WiFi Sources
$ nmcli dev wifi
  • Connect to a WiFi Source
$ nmcli dev wifi connect "SSID" password "PASSWORD" ifname wlan0

The "SSID" and "PASSWORD" need to be replaced with your actual SSID and password.If you have multiple WiFi devices you need to specify the one you want to connect to a WiFi source with iface
If a connection succeeds it will be automatically setup on next system reboot.

For more details about NetworkManager refer to this link: Use NetworkManager to configure network settings

If your USB WiFi module doesn't work most likely your system doesn't have its driver. For a Debian system you can get a driver from Debian-WiFi and install it on your system. For a Ubuntu system you can install a driver by running the following commands:

$ apt-get install linux-firmware

In general all WiFi drivers are located at the "/lib/firmware" directory.

7.9 Setup Wi-Fi AP

Follow the steps below. Since our OS image by default already has the NetworkManager utility you will be prompted to uninstall it first:

sudo turn-wifi-into-apmode yes

After you uninstall the NetworkManager reboot your board.
After your board is rebooted run the above commands again and you will be prompted to type in a WIFI's name and password. Type in your wanted name and password

If this is successful you will be able to find and connect your board to a WIFI. Login to your board at 192.168.8.1:

ssh root@192.168.8.1

Type in a password. In our system the password is "fa".

To login smoothly via SSH we recommend you turning off WIFI's power save mode by running the following commands:

sudo iwconfig wlan0 power off

You can check your WiFi's mode by running the following command:

sudo cat /sys/module/bcmdhd/parameters/op_mode

Number 2 means your WiFi is in AP mode. You can switch to the Station mode by running the following command:

sudo turn-wifi-into-apmode no

7.10 Bluetooth

Search for surrounding bluetooth devices by running the following command:

$ su root
$ hciconfig hci0 up
$ hcitool scan

You can run "hciconfig" to check bluetooth's status.

7.11 Ethernet Connection

If a board is connected to a network via Ethernet before it is powered on it will automatically obtain an IP with DHCP activated after it is powered up. If you want to set up a static IP refer to: Use NetworkManager to configure network settings


7.12 Custom welcome message

The welcome message is printed from the script in this directory:

/etc/update-motd.d/

For example, to change the FriendlyELEC LOGO, you can change the file /etc/update-motd.d/10-header. For example, to change the LOGO to HELLO, you can change the following line:

TERM=linux toilet -f standard -F metal $BOARD_VENDOR

To:

TERM=linux toilet -f standard -F metal HELLO

7.13 Modify timezone

For exampe, change to Shanghai timezone:

sudo rm /etc/localtime
sudo ln -ls /usr/share/zoneinfo/Asia/Shanghai /etc/localtime

7.14 Select the system default audio device

You can set the system default audio device by following the steps below.
Use the following command to view all the sound card devices in the system (Note: different development boards will have different results):

pi@NanoPi:~$ aplay -l
**** List of PLAYBACK Hardware Devices ****
card 0: nanopi2audio [nanopi2-audio], device 0: c0055000.i2s-ES8316 HiFi ES8316 HiFi-0 []
  Subdevices: 1/1
  Subdevice #0: subdevice #0
card 0: nanopi2audio [nanopi2-audio], device 1: c0059000.spdiftx-dit-hifi dit-hifi-1 []
  Subdevices: 1/1
  Subdevice #0: subdevice #0

As you can see, the following sound card devices are available on the hardware:

Sound card device Sound card number Description
nanopi2audio device 0 3.5mm jack interface
nanopi2audio device 1 HDMI

To configure the audio output to the 3.5mm jack, create or modify the configuration file /etc/asound.conf and modify it to the following:

pcm.!default {
    type hw
    card 0
    device 0
}
 
ctl.!default {
    type hw
    card 0
}

To configure to output audio to HDMI, change the device 0 above to device 1.


7.15 Run the X11 application

FriendlyCore system built-in lightweight Xorg,although there is no window manager, you can still run a single X-Windows application,For example, the program to run is ~/YourX11App,use the following command:

. /usr/bin/setqt5env-xcb
startx ~/YourX11App -geometry 1280x800

Note that there is a space between "." and /usr/bin/setqt5env-xcb. In addition, the resolution after -geometry should be changed to the actual resolution of your screen.

7.16 Run Qt 5.10.0 Demo with GPU acceleration

Run the following command

$ sudo qt5demo

S5pxx18-QtE

7.17 Run Qt 5.10.0 Demo with OpenGL

Run the following command

. setqt5env
cd $QTDIR
cd /examples/opengl/qopenglwidget
./qopenglwidget

For more Qt 5.10.0 examples, please go to:
cd $QTDIR/examples/

7.18 Play HD Video with Hardware-decoding

gst-player is console player, it base on GStreamer, support VPU with Hardware-decoding:

sudo gst-player /home/pi/demo.mp4

The equivalent gsteamer command is as follows:

sudo gst-launch-1.0 filesrc location=/home/pi/demo.mp4 ! qtdemux name=demux demux. ! queue ! faad ! audioconvert ! audioresample ! alsasink device="hw:0,DEV=1" demux. ! queue ! h264parse ! nxvideodec ! nxvideosink dst-x=0 dst-y=93 dst-w=1280 dst-h=533

7.19 Connect to DVP Camera CAM500B

The CAM500B camera module is a 5M-pixel camera with DVP interface. For more tech details about it you can refer to Matrix - CAM500B.
Enter the following command to preview the video:

gst-launch-1.0 -e v4l2src device=/dev/video6 ! video/x-raw,format=I420,framerate=30/1,width=1280,height=720 ! nxvideosink

Enter the following command to start recording (VPU hardware encoding):

gst-launch-1.0 -e v4l2src device=/dev/video6 ! video/x-raw,format=I420,framerate=30/1,width=1280,height=720 ! tee name=t t. \
 ! queue ! nxvideosink t. ! queue ! nxvideoenc bitrate=12000000 ! mp4mux ! \
 filesink location=result_720.mp4

7.20 Power Off and Schedule Power On

“PMU Power Management” feature helps us to auto power on the board at a specific time, it is implemented by an MCU, support software power-off, and RTC alarm power-up functions.

Here’s a simple guide:
Turn on automatically after 100 seconds. (Time must be greater than 60 seconds.):

$ sudo echo 100 > /sys/class/i2c-dev/i2c-3/device/3-002d/wakealarm

After setting up the automatic boot, turn off board with the 'poweroff’ command:

$ sudo poweroff

Cancel automatic boot:

$ sudo echo 0 > /sys/class/i2c-dev/i2c-3/device/3-002d/wakealarm

Query the current settings, in the front is current time, followed by the time of automatic booting: If no automatic boot is set, it will display "disabled”.

$ sudo cat /sys/class/i2c-dev/i2c-3/device/3-002d/wakealarm


Note that some older versions of hardware may not support this feature, if you don't see this file node in your system:
/sys/class/i2c-dev/i2c-3/device/3-002d/wakealarm
your board may be it does not support this feature.

7.21 Installing and Using OpenCV 4.1.2

OpenCV has been pre-installed in FriendlyCore (Version after 20191126) and does not require manual installation.
Please refre this link: https://github.com/friendlyarm/install-opencv-on-friendlycore/blob/s5pxx18/README.md
Quick test:

. /usr/bin/cv-env.sh
. /usr/bin/setqt5env-eglfs
cd /usr/local/share/opencv4/samples/python
python3 turing.py

7.22 Installing and Using Caffe

git clone https://github.com/friendlyarm/install-caffe-on-friendlycore
cd install-caffe-on-friendlycore
sudo ./install-caffe.sh

7.23 How to install and use docker (for aarch64 system)

7.23.1 How to Install Docker

Run the following commands:

wget https://download.docker.com/linux/ubuntu/dists/xenial/pool/stable/arm64/containerd.io_1.2.6-3_arm64.deb
wget https://download.docker.com/linux/ubuntu/dists/xenial/pool/stable/arm64/docker-ce-cli_19.03.2~3-0~ubuntu-xenial_arm64.deb
wget https://download.docker.com/linux/ubuntu/dists/xenial/pool/stable/arm64/docker-ce_19.03.2~3-0~ubuntu-xenial_arm64.deb
sudo dpkg -i containerd.io_1.2.6-3_arm64.deb
sudo dpkg -i docker-ce-cli_19.03.2~3-0~ubuntu-xenial_arm64.deb
sudo dpkg -i docker-ce_19.03.2~3-0~ubuntu-xenial_arm64.deb

7.23.2 Test Docker installation

Test that your installation works by running the simple docker image:

git clone https://github.com/friendlyarm/debian-jessie-arm-docker
cd debian-jessie-arm-docker
./rebuild-image.sh
./run.sh

8 Work with Android

8.1 Work with 4G Module EC20 under Android5

8.1.1 Hardware Setup

Connect an EC20 module to a USB to miniPCIe board and connect the board to an ARM board's USB Host. Here is a hardware setup:
T2-4G-EC20.jpg
Power on the board and you will be able to surf the internet with the 4G module like using an Android phone.


Replace the logo.bmp:

/opt/FriendlyARM/smart4418/android/device/friendly-arm/nanopi3/boot/logo.bmp
/opt/FriendlyARM/smart4418/android/device/friendly-arm/nanopi2/boot/logo.bmp

Replace the bootanimation.zip:

/opt/FriendlyARM/smart4418/android/device/friendly-arm/nanopi3/bootanimation.zip
/opt/FriendlyARM/smart4418/android/device/friendly-arm/nanopi2/bootanimation.zip

Re-compile android.

8.3 Use fastboot command to flash android firmware

Enter the uboot command line mode on the serial terminal when powering on, and then enter the following command:

fastboot 0

For S5P4418:

fastboot flash partmap partmap.txt
fastboot flash 2ndboot bl1-mmcboot.bin
fastboot flash fip-loader loader-mmc.img
fastboot flash fip-secure bl_mon.img
fastboot flash fip-nonsecure bootloader.img
fastboot flash boot boot.img
fastboot flash system system.img
fastboot flash cache cache.img
fastboot flash userdata userdata.img

For S5P6818:

fastboot flash partmap partmap.txt
fastboot flash 2ndboot bl1-mmcboot.bin
fastboot flash fip-loader fip-loader.img 
fastboot flash fip-secure fip-secure.img 
fastboot flash fip-nonsecure fip-nonsecure.img
fastboot flash boot boot.img
fastboot flash system system.img
fastboot flash cache cache.img
fastboot flash userdata userdata.img

8.4 Android Keys

Android 5:

  vendor/friendly-arm/nanopi3/security/

Android 7:

  build/target/product/security/

8.5 Optimizing HDMI Performance on Android 7

8.5.1 Note

By default, the driver initializes two framebuffers, one for the primary LCD display and the other for HDMI. If your project specifically requires the use of HDMI and not the LCD, you can follow the steps outlined in this chapter to make modifications. After making these changes, HDMI will be configured as the primary display, resulting in the initialization of only one framebuffer. This optimization conserves resources and leads to corresponding improvements in UI performance and boot speed.
The content of this chapter is applicable exclusively to S5P6818 running Android 7. For S5P4418, the modification process is similar, with adjustments needed in the corresponding files.

8.5.2 Modify the kernel

You need to modify the kernel Device Tree Source (DTS) to disable the dp_drm_lvds node, as shown below:

--- a/arch/arm64/boot/dts/nexell/s5p6818-nanopi3-common.dtsi
+++ b/arch/arm64/boot/dts/nexell/s5p6818-nanopi3-common.dtsi
@@ -810,6 +810,7 @@
                        plane-names = "video", "rgb", "primary";
                };
                port@1 {
+                       status = "disabled";
                        reg = <1>;
                        back_color = < 0x0 >;
                        color_key = < 0x0 >;
@@ -820,7 +821,7 @@
 
 &dp_drm_lvds {
        remote-endpoint = <&lcd_panel>;
-       status = "ok";
+       status = "disabled";
 
        display-timing {
                clock-frequency = <50000000>;

After compilation, you will obtain a new arch/arm64/boot/dts/nexell/s5p6818-nanopi3-rev*.dtb file.
During the testing phase, you can directly update it to the board using adb with the following command:

adb root; adb wait-for-device; adb shell mkdir /storage/sdcard1/; adb
shell mount -t ext4 /dev/block/mmcblk0p1 /storage/sdcard1/
adb push arch/arm64/boot/dts/nexell/s5p6818-nanopi3-rev*.dtb /storage/sdcard1/

For a complete firmware update, you will need to replace the files in the device/friendlyelec/nanopi3/boot directory of the Android 7 source code.

8.5.3 Modify env.conf

To modify the device/friendlyelec/nanopi3/boot/env.conf file and add a line

lcdtype     HDMI1080P60

This mode needs to match the mode detected by Android 7 after startup; otherwise, it may result in a prolonged black screen state or even no display output. In such cases, you may need to manually set it in the U-Boot command-line environment:

setenv lcdtype HDMI1080P60; saveenv; reset

8.5.4 Modify system.prop

To modify the device/friendlyelec/nanopi3/system.prop file in Android 7

ro.sf.lcd_density=240

Alternatively, you can adjust the system property or experiment with different values that you deem more appropriate. You can also use the following command to change the display density under the serial or adb environment and observe if the effect is suitable:

adb shell wm density 240

8.5.5 Compiling Android

Follow the instructions in the wiki to compile Android 7 and conduct testing. If you encounter any exceptions, please carefully review the preceding steps.

9 Make Your Own OS Image

9.1 Install Cross Compiler

9.1.1 Install aarch64-linux-gcc 6.4

Download the compiler package:

git clone https://github.com/friendlyarm/prebuilts.git -b master --depth 1
cd prebuilts/gcc-x64
cat toolchain-4.9.3-armhf.tar.gz* | sudo tar xz -C /

Then add the compiler's directory to "PATH" by appending the following lines in "~/.bashrc":

export PATH=/opt/FriendlyARM/toolchain/4.9.3/bin:$PATH
export GCC_COLORS=auto

Execute "~/.bashrc" to make the changes take effect. Note that there is a space after the first ".":

. ~/.bashrc

This compiler is a 64-bit one therefore it cannot be run on a 32-bit Linux machine. After the compiler is installed you can verify it by running the following commands:

arm-linux-gcc -v
Using built-in specs.
COLLECT_GCC=arm-linux-gcc
COLLECT_LTO_WRAPPER=/opt/FriendlyARM/toolchain/4.9.3/libexec/gcc/arm-cortexa9-linux-gnueabihf/4.9.3/lto-wrapper
Target: arm-cortexa9-linux-gnueabihf
Configured with: /work/toolchain/build/src/gcc-4.9.3/configure --build=x86_64-build_pc-linux-gnu
--host=x86_64-build_pc-linux-gnu --target=arm-cortexa9-linux-gnueabihf --prefix=/opt/FriendlyARM/toolchain/4.9.3
--with-sysroot=/opt/FriendlyARM/toolchain/4.9.3/arm-cortexa9-linux-gnueabihf/sys-root --enable-languages=c,c++
--with-arch=armv7-a --with-tune=cortex-a9 --with-fpu=vfpv3 --with-float=hard
...
Thread model: posix
gcc version 4.9.3 (ctng-1.21.0-229g-FA)

9.2 Compile Linux kernel for FriendlyCore/Lubuntu/EFlasher

9.2.1 Compile Kernel

  • Download Kernel Source Code
git clone https://github.com/friendlyarm/linux.git -b nanopi2-v4.4.y --depth 1
cd linux

The kernel source for S5P6818 is in the "nanopi2-v4.4.y" branch. Before you start compiling it you need to switch to this branch.

  • Compile Ubuntu Kernel
touch .scmversion
make ARCH=arm64 nanopi3_linux_defconfig
make ARCH=arm64

After your compilation succeeds an "arch/arm/boot/Image" will be generated and a DTB file(s5p6818-nanopi3-rev*.dtb) will be generated in the "arch/arm/boot/dts/nexell" directory. You can use them to replace the existing Image and DTB files in the boot partition of your bootable SD card.

9.2.2 Use Your Generated Kernel

  • Update kernel in SD card

If you use an SD card to boot Ubuntu you can copy your generated Image and DTB files to your SD card's boot partition(e.g. partition 1 /dev/sdX1).

  • Update kernel in eMMC

If you boot your board from eMMC you can update your kernel file by following the steps below:
1) Usually after OS is loaded eMMC's boot partition (in our example eMMC's device name was /dev/mmcblk0p1) will be automatically mounted and you can verify that by running "mount"
2) Connect your board to a host PC running Ubuntu and copy the Image and DTB files to eMMC's boot partition
3) Or you can copy your generated kernel file to an external storage card(e.g. an SD card or a USB drive), connect the storage card to your board the move the file from the card to eMMC's boot partition
4) After update is done type "reboot" to reboot your board. Note: don't just directly disconnect your board from its power source or press the reset button to reboot the board. These actions will damage your kernel file

  • Generate Your boot.img

Refer to this repo: https://github.com/friendlyarm/sd-fuse_s5p6818

9.3 Compile Linux kernel for Android7

The Android 7.1.2 source code already contains the pre-compiled kernel. If you need to customize it, you can compile the kernel according to the following guide.

git clone https://github.com/friendlyarm/linux.git -b nanopi2-v4.4.y --depth 1
cd linux
touch .scmversion
make ARCH=arm64 nanopi3_nougat_defconfig
make ARCH=arm64

The newly generated kernel is arch/arm64/boot/Image,The new DTB file is also included under the directory arch/arm64/boot/dts/nexell/.(s5p6818-nanopi3-rev*.dtb).
If you only want to debug the kernel, you can quickly update it with adb:

adb root; adb shell mkdir /storage/sdcard1/; adb shell mount -t ext4 /dev/block/mmcblk0p1 /storage/sdcard1/;
adb push arch/arm64/boot/Image arch/arm64/boot/dts/nexell/s5p6818-nanopi3-rev*.dtb /storage/sdcard1/

If you want to generate boot.img for burning, you can copy the kernel Image and DTB files to the Android7 source code directory: device/friendlyelec/nanopi3/boot, then recompile Android7.

9.4 Compile U-Boot for Android7/FriendlyCore/Lubuntu/EFlasher

Download the U-Boot v2016.01 source code and compile it. Note that the github's branch is nanopi2-v2016.01:

git clone https://github.com/friendlyarm/u-boot.git 
cd u-boot
git checkout nanopi2-v2016.01
make s5p6818_nanopi3_config
make CROSS_COMPILE=aarch64-linux-

After your compilation succeeds a fip-nonsecure.img will be generated. If you want to test it flash it to your installation SD card to replace an existing U-Boot v2016.01 file via fastboot, sd-fuse_s5p6818 or eflasher ROM.
For Android7: You can copy fip-nonsecure.img to the Android7 source directory device/friendlyelec/nanopi3/boot and recompile Android7.
Note: you cannot use mixed U-Boot files. For example you cannot use fastboot to update an existing U-Boot V2014.07 and you cannot use bootloader.img to replace an existing u-boot.bin.

9.5 Compile Android 7.1.2

9.5.1 Install Cross Compiler

Install 64 bit Ubuntu 16.04 on your host PC.

sudo apt-get install bison g++-multilib git gperf libxml2-utils make python-networkx zip
sudo apt-get install flex curl libncurses5-dev libssl-dev zlib1g-dev gawk minicom
sudo apt-get install openjdk-8-jdk
sudo apt-get install exfat-fuse exfat-utils device-tree-compiler liblz4-tool

For more details refer to https://source.android.com/source/initializing.html

9.5.2 Download Android7 Source Code

There are two ways to download the source code:

  • repo archive file on netdisk

Netdisk URL: Click here
File location on netdisk:sources/s5pxx18-android-7.git-YYYYMMDD.tgz (YYYYMMDD means the date of packaging)
After extracting the repo package from the network disk, you need to execute the sync.sh script, which will pull the latest code from gitlab:

tar xvzf /path/to/netdisk/sources/s5pxx18-android-7.git-YYYYMMDD.tgz
cd s5pxx18-android-7
./sync.sh
  • git clone from gitlab

NanoPC-T3 source code is maintained in gitlab, You can download it by running the following command:

git clone https://gitlab.com/friendlyelec/s5pxx18-android-7.git -b master


9.5.3 Compile Android7

cd s5pxx18-android-7
source build/envsetup.sh
lunch aosp_nanopi3-userdebug
make -j8

After your compilation succeeds the following files will be generated in the "out/target/product/nanopi3/" directory.

filename partition Description
bl1-mmcboot.bin raw boot firmware
fip-loader.img raw boot firmware
fip-secure.img raw boot firmware
fip-nonsecure.img raw uboot-v2016.01
env.conf - Uboot environment variable containing Android kernel command line parameters
boot.img boot kernel Image, DTBs; logo; Android ramdisk
cache.img cache -
userdata.img userdata -
system.img system -
partmap.txt - Partition description file

10 Build Kernel Headers Package

The following commands need to be executed on the development board:

10.1 Software Version

The OS image file name: s5p6818-sd-friendlycore-xenial-4.4-arm64-YYYYMMDD.img, s5p6818-eflasher-friendlycore-xenial-4.4-arm64-YYYYMMDD.img

pi@NanoPC-T3:~$ lsb_release -a
No LSB modules are available.
Distributor ID: Ubuntu
Description:    Ubuntu 16.04.6 LTS
Release:        16.04
Codename:       xenial
pi@NanoPC-T3:~$ cat /proc/version
Linux version 4.4.172-s5p6818 (root@jensen) (gcc version 6.4.0 (ctng-1.23.0-150g-FA) ) #1 SMP PREEMPT Thu Jan 21 18:51:13 CST 2021

10.2 Install the required packages

sudo apt-get update
sudo apt-get install -y dpkg-dev bsdtar

10.3 Build Kernel Headers Package

git clone https://github.com/friendlyarm/linux -b nanopi2-v4.4.y --depth 1 kernel-s5pxx18-arm64
cd kernel-s5pxx18-arm64
rm -rf .git
make distclean
touch .scmversion
sed -i '/^CONFIG_CROSS_COMPILE/d' ./arch/arm64/configs/nanopi3_linux_defconfig
make CROSS_COMPILE= ARCH=arm64 nanopi3_linux_defconfig
alias tar=bsdtar
make CROSS_COMPILE= ARCH=arm64 bindeb-pkg -j4

The following message is displayed to indicate completion:

dpkg-deb: building package 'linux-firmware-image-4.4.172-s5p6818' in '../linux-firmware-image-4.4.172-s5p6818_4.4.172-s5p6818-1_arm64.deb'.
dpkg-deb: building package 'linux-headers-4.4.172-s5p6818' in '../linux-headers-4.4.172-s5p6818_4.4.172-s5p6818-1_arm64.deb'.
dpkg-deb: building package 'linux-libc-dev' in '../linux-libc-dev_4.4.172-s5p6818-1_arm64.deb'.
dpkg-deb: building package 'linux-image-4.4.172-s5p6818' in '../linux-image-4.4.172-s5p6818_4.4.172-s5p6818-1_arm64.deb'.
dpkg-genchanges: binary-only upload (no source code included)

10.4 Installation

sudo rm -f /lib/modules/4.4.172-s5p6818/build
sudo rm -f /lib/modules/4.4.172-s5p6818/source
sudo dpkg -i ../linux-headers-4.4.172-s5p6818_4.4.172-s5p6818-1_arm64.deb

10.5 Testing

To compile the pf_ring module as an example, refer to the documentation: https://www.ntop.org/guides/pf_ring/get_started/git_installation.html.

git clone https://github.com/ntop/PF_RING.git
cd PF_RING/kernel/
make CROSS_COMPILE=

After compiling, use insmod to try to load the module:

sudo insmod ./pf_ring.ko

11 Connect NanoPC-T3 to External Modules

11.1 Connect NanoPC-T3 to USB Camera(FA-CAM202)

  • In this use case the NanoPC-T3 runs Debian. If you connect your NanoPC-T3 to our LCD or an HDMI monitor after Debain is fully loaded click on "other"-->"xawtv" on the left bottom of the GUI and the USB Camera application will be started. After enter "welcome to xawtv!" click on "OK" to start exploring.

USB camera USB camera-01

11.2 Connect NanoPC-T3 to CMOS 5M-Pixel Camera

For more details about the CAM500A camera refer to [1]

  • If your NanoPC-T3 runs Android5.1 and it is connected to our LCD or an HDMI monitor after Android is fully loaded click on the "Camera" icon and the application will be started. You can take pictures or record videos

CMOS camera

  • Under Debian a camera utility "nanocams" is available for previewing 40 frames and picture taking. You can try it by following the commands below
sudo nanocams -p 1 -n 40 -c 4 -o IMG001.jpg

For more details about the usage of the nanocams run "nanocams -h". You can get its source code from our git hub:

git clone https://github.com/friendlyarm/nexell_linux_platform.git
  • Under FriendlyCore (kernel 4.4), You can try it by following the commands below:

Enter the following command to preview the video:

gst-launch-1.0 -e v4l2src device=/dev/video6 ! video/x-raw,format=I420,framerate=30/1,width=1280,height=720 ! nxvideosink

Enter the following command to start recording (VPU hardware encoding):

gst-launch-1.0 -e v4l2src device=/dev/video6 ! video/x-raw,format=I420,framerate=30/1,width=1280,height=720 ! tee name=t t. \
 ! queue ! nxvideosink t. ! queue ! nxvideoenc bitrate=12000000 ! mp4mux ! \
 filesink location=result_720.mp4

11.3 Use OpenCV to Access USB Camera

  • The full name of "OpenCV" is Open Source Computer Vision Library and it is a cross platform vision library.
  • When the NanoPC-T3 runs Debian users can use OpenCV APIs to access a USB Camera device.

1. Here is a guideline on how to use OpenCV with C++ on the NanoPC-T3:

  • Firstly you need to make sure your NanoPC-T3 is connected to the internet.Login to your NanoPC-T3 via a serial terminal or SSH. After login type in your username(root) and password(fa):
  • Run the following commands:


apt-get update
apt-get install libcv-dev libopencv-dev

2. Make sure your USB camera works with the NanoPC-T3. You can test your camera with NanoPC-T3's camera utility.

3. Check your camera device:

ls /dev/video*
  • Note:in our test case video0 was the device name.

4. OpenCV's code sample(official code in C++) is under /home/fa/Documents/opencv-demo. Compile the code sample with the following commands:

cd /home/fa/Documents/opencv-demo
make

After it is compiled successfully a "demo" executable will be generated

5. Connect NanoPC-T3 to USB Keyboard & Run the Following Command:

./demo

opencv is successfully started

11.4 Connect NanoPC-T3 to Matrix GPS Module

  • The Matrix-GPS module is a small GPS module with high performance. It can be used in navigation devices, four-axle drones and etc.
  • The Matrix-GPS module uses serial communication. When the NanoPC-T3 is connected to the Matrix GPS module, after the NanoPC-T3 is powered up type in the following command in a terminal or click on the xgps icon it will be started.
$su - fa -c "DISPLAY=:0 xgps 127.0.0.1:9999"
  • Or on the Debian GUI start the LXTerminal, type in "xgps" and enter it will be started too.

For more details about this GPS module refer to Click to check
Refer to the following diagram to connect the NanoPC-T3 to the Matrix-GPS:
GPS_NanoPC-T2

Connection Details:

Matrix-GPS NanoPC-T3
RXD Pin11
TXD Pin12
5V Pin29
GND Pin30

12 Access Hardware under Android

FriendlyElec developed a library called “libfriendlyarm-things.so”, for android developer to access the hardware resources on the development board in their android apps, the library is based on Android NDK.
Accessible Modules:

  • Serial Port
  • PWM
  • EEPROM
  • ADC
  • LED
  • LCD 1602 (I2C)
  • OLED (SPI)


Interfaces & Ports:

  • GPIO
  • Serial Port
  • I2C
  • SPI


Refer to the following url for details:

13 Connect NanoPC-T3 to FriendlyARM LCD Modules

  • Android

Here are the LCDs that are supported under Android:S430, S700/S701, S702, HD700, HD702, HD101 and X710 all of which are LCDs with capacitive touch.

  • FriendlyCore & Lubuntu Desktop

Here are the LCDs that are supported under FriendlyCore and Lubuntu Desktop:S430, S700/S701, S702, HD700, HD702, HD101 and X710 all of which are LCDs with capacitive touch;
W35B, H43, P43, S70D and Matrix 2.8" SPI Key TFT LCD all of which are LCDs with resistive touch
All these LCD's tech details can be obtained on our wiki site:LCDModules

14 Schematics & Mechanical drawing

15 Source Code and Image Files Download Links

  • Image File: [2]
  • Source Code: [3]

16 Tech Support

If you have any further questions please visit our forum http://www.friendlyarm.com/Forum/ and post a message or email us at techsupport@friendlyarm.com. We will endeavor to get back to you as soon as possible.

17 More OS Support

17.1 DietPi

Dietpi-logo.png
DietPi is a highly optimised & minimal Debian-based Linux distribution. DietPi is extremely lightweight at its core, and also extremely easy to install and use.
Setting up a single board computer (SBC) or even a computer, for both regular or server use, takes time and skill. DietPi provides an easy way to install and run favourite software you choose.
For more information, please visit this link https://dietpi.com/docs/.

DietPi supports many of the NanoPi board series, you may download the image file from here:

18 Update Log

18.1 2023-01-09

18.1.1 FriendlyCore:

  • optimized the systemd service

18.2 2020-10-26

  • FriendlyCore, Lubuntu:

Fix Bluetooth stability issue

18.3 2019-12-27

  • FriendlyWrt:

Upgrade to OpenWrt r19-snapshot 64bit, support Docker CE

  • eflasher:

1) Supports flashing only some files, such as updating only the kernel and uboot in emmc
2) Added gui option to disable overlay filesystem
3) Add command line parameters to achieve one-click installation without interaction
4) Fix the issue that the same mac address will appear on different devices after backup and restore image
5) UI interface can now be configured with title, hide interface menus and buttons

18.4 2019-11-26

  • FriendlyCore:

Pre-installed OpenCV 4.1.2

18.5 2019-11-14

  • Introducing a new system FriendlyWrt:

FriendlyWrt is a customized OpenWrt system developed by FriendlyElec. It is open source and suitable for applications in IoT, NAS etc.
Please refre: http://wiki.friendlyelec.com/wiki/index.php/How_to_Build_FriendlyWrt

  • FriendlyCore, Lubuntu updated as follows:

1) Added support for new 4.3-inch screen YZ43
2) Compile bcmdhd as a module.

  • Android7 update is as follows:

1) Added support for new 4.3-inch screen YZ43
2) Optimize the touch experience when using HD900 screen under Android 7 system

18.6 2019-10-18

  • Android7, FriendlyCore, Lubuntu:

Fixed audio playback issue.

18.7 2019-09-30

  • Android7 updated as follows:

1)Added support for Android hardware access library (named FriendlyThing), support access to hardware resources such as GPIO, PWM, RTC, serial port and watchdog, providing open source demo
2) Added support for camera CAM500B (OV5640)
3) Added support for LCD W500 (800x480)
4) Fixed LCD-S430 compatibility issues

  • FriendlyCore, FriendlyDesktop updated as follows:

1) Kernel version updated to v4.4.172, same as Android 7
2) Added Docker support, support 32bit and 64bit file systems
3) Kernel configuration items are optimized to enable more features and device drivers

18.8 2019-07-18

  • Introducing a new system Android 7.1.2

1) Features similar to the old version of Android 5, support 4G, WiFi, Ethernet, Bluetooth, etc.
2) Kernel version: 4.4.172
3) Known issue: The camera is not working yet

  • Android/FriendlyCore/Lubuntu updated as follows:

1) Fix an issue where HD101B can't be touched in some cases
2) Fix GPIO configuration of Power key
3) Solve the problem of too small volume: the volume of the DAC is changed from -20dB to -6dB during playback.
4) Add more models of USB Wi-Fi support, built-in driver rtl8821CU.ko, rtl88XXau.ko

  • Updates for Lubuntu only:

1) Modify Lubuntu's Power key behavior to (without pop-ups) shut down directly
2) Add script xrotate.sh to simplify screen rotation settings (Note: screen rotation will lose performance)

  • The following updates are only available for NanoPC T3/T3+, Smart6818:

Support for reading Ethernet Mac addresses from the onboard EEPROM, only supports the following systems: FriendlyCore, Lubuntu, Android7

18.9 2019-06-25

Linux(Ubuntu 16.04/18.04) uses OverlayFS to enhance filesystem stability.

18.10 2019-06-03

1) Configure LED1 to be in heartbeat mode
2) Fix HDMI 1080P may have no display problem in some cases
3) Fix the issue that mysql cannot be installed under Linux
4) Fix the issue that the 1-wire touch resistance screen cannot be used under lubuntu

18.11 2019-01-24

1) Update uboot-v2014.07, uboot-v2016.01 for HD702V LCD
2) Adjust Qt5 font path

18.12 2018-12-17

  • Android5 updated as follows:

1) Add support for 4G network, support module: Quectel EC20
2) Add audio setting UI, you can set the default output to headphones or HDMI
3) Synchronously turn off the backlight of the one-line touch screen when the system Shutdown

  • FriendlyCore updated as follows:

1) Add OV5640 camera support
2) Update BL1 to improve system startup stability

  • Lubuntu updated as follows:

1) Add Chrome-browser browser, support web page 1080P hardware decoding, support WebGL
2) Set the audio output channel to HDMI by default (can be changed via /etc/asound.conf)
3) Update BL1 to improve system startup stability
4) Fixed some issues regarding the package error in the previous version
5) Adjust DPMS settings, turn off automatic sleep by default

18.13 April-28-2016

  • Released English version

18.14 June-30-2016

  • Added sections 5.2.4 and 8

18.15 Sep-27-2016

  • Added section 9
  • Updated sections 5.2.2 and 8.2

18.16 Nov-2-2016

  • Updated sections 6.4 and 11

18.17 June-20-2017

  • Updated sections 6.2 and 6.3: wireless connection and setting up WIFI AP
  • Updated section 8.4.1: added compiling kernel for UbuntuCore
  • Added section 3: software features
  • Added section 7: UbuntuCore
  • Added section 9.5: LCD support

18.18 March-28-2018

  • Updated sections 6.10