Difference between revisions of "NanoPi M1 Plus"

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(连接有线网络)
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===连接有线网络===
+
===Ethernet Connection===
M1+在加电开机前如果已正确的连接网线,则系统启动时会自动获取IP地址,如果没有连接网线、没有DHCP服务或是其它网络问题,则会导致获取IP地址失败,同时系统启动会因此等待约15~60秒的时间。
+
If the NanoPi M1 Plus is connected to a network via Ethernet before it is powered on it will automatically obtain an IP after it is powered up. If it is not connected via Ethernet or its DHCP is not activated obtaining an IP will fail and system will hang on for about 15 to 60 seconds
* 配置MAC地址
+
* Setup MAC Address
板子没有提供有效的Ethernet的MAC地址,系统在连接网络时会自动生成一个随机的MAC地址,您可以修改 /etc/network/interfaces.d/eth0 ,配置一个固定的MAC地址:
+
The NanoPi M1 Plus by default doesn't have a valid MAC address. If the board connects a network successfully it will automatically generate a random MAC in "/etc/network/interfaces.d/eth0". Users can change it to a self-defined valid one:
 
<syntaxhighlight lang="bash">
 
<syntaxhighlight lang="bash">
 
vi /etc/network/interfaces.d/eth0
 
vi /etc/network/interfaces.d/eth0
 
</syntaxhighlight>
 
</syntaxhighlight>
以下是配置文件的具体内容:
+
Here is the content of a sample configuration file:
 
<syntaxhighlight lang="bash">
 
<syntaxhighlight lang="bash">
 
auto eth0
 
auto eth0
Line 252: Line 252:
 
hwaddress 76:92:d4:85:f3:0f
 
hwaddress 76:92:d4:85:f3:0f
 
</syntaxhighlight>
 
</syntaxhighlight>
其中"hwaddress" 就是用来指定MAC地址,"76:92:d4:85:f3:0f"是一个随机生成的地址,为防止冲突导致网络问题,请修改为一个不同的且有效的地址。<br />
+
The "hwaddress" specifies the MAC address. Here the "76:92:d4:85:f3:0f" is a random MAC. We suggest users change it to a valid one.<br/>
需要注意的一点是,MAC地址必须符合IEEE的规则,请不要随意指定,否则会出现无法获取IP地址、无法上网等问题。
+
Note: when you reset the MAC please make sure your MAC meets IEEE's definition otherwise it will cause unexpected issues.
修改完配置文件并保存后,可重启板子或直接下列命令重启网络服务:
+
After you make your change, save, exit and reboot your board or run the following commands to restart the network:
 
<syntaxhighlight lang="bash">
 
<syntaxhighlight lang="bash">
 
systemctl restart networking
 
systemctl restart networking

Revision as of 15:01, 28 February 2017

查看中文

1 Introduction

Overview
Front
Back
  • The NanoPi M1 Plus is designed and developed by FriendlyElec for professionals, enterprise users, makers and hobbyists. It is only two thirds the size of a Raspberry Pi. FriendlyElec has made a Debian, Ubuntu-MATE, Ubuntu-Core and Android images ready for it.
  • The NanoPi M1 Plus uses the Allwinner H3 Soc. It integrates Gbps Ethernet, IR receiver, video/audio output, WiFi & Bluetooth, onboard microphone and supports DVP/Camera/HDMI and CVBS. It has a serial debug port. Its GPIO pins are compatible with those of a Raspberry Pi.

2 Hardware Spec

  • CPU: Allwinner H3, Quad-core Cortex-A7@1.2GHz
  • GPU: Mali400MP2@600MHz,Supports OpenGL ES2.0
  • DDR3 RAM: 1GB
  • eMMC: 8GB
  • Wireless: 802.11 b/g/n
  • Bluetooth: 4.0 dual mode
  • Antenna Interface: Shared by WiFi and Bluetooth, IPX interface
  • Connectivity: 10/100/1000M Ethernet
  • Audio: 3.5mm jack/Via HDMI
  • Microphone: onboard microphone
  • IR: onboard IR receiver
  • USB Host: USB 2.0 x 3, 2 x USB Type A and 1 x 2.54mm pitch pin-header
  • MicroSD Slot: x1
  • MicroUSB: power input and data transmission, OTG
  • Audio Output: HDMI 1.4 1080P, CVBS
  • DVP Camera Interface: 24pin, 0.5mm pitch FPC seat
  • Serial Debug Port: 4Pin, 2.54mm pitch pin-header
  • GPIO: 40pin, 2.54mm pitch pin-header, compatible with RasberryPi 2's GPIO. It contains UART, SPI, I2C, I2S/PCM, SPDIF-OUT and IO
  • User Button: 1 x Power Button and 1 x Reset Button
  • LED: 1 x Power LED and 1 x System Status LED
  • PCB Dimension: 64 x 60 mm, ENIG
  • Power Supply: DC 5V/2A
  • OS/Software: u-boot, Debian, Ubuntu-MATE, Ubuntu-Core

3 Diagram, Layout and Dimension

3.1 Layout

File:-1602-if01.png
NanoPi M1 Plus Layout
  • GPIO Pin Description
Pin# Name Linux gpio Pin# Name Linux gpio
1 SYS_3.3V 2 VDD_5V
3 I2C0_SDA 4 VDD_5V
5 I2C0_SCL 6 GND
7 GPIOG11 203 8 UART1_TX/GPIOG6 198
9 GND 10 UART1_RX/GPIOG7 199
11 UART2_TX/GPIOA0 0 12 PWM1/GPIOA6 6
13 UART2_RTS/GPIOA2 2 14 GND
15 UART2_CTS/GPIOA3 3 16 UART1_RTS/GPIOG8 200
17 SYS_3.3V 18 UART1_CTS/GPIOG9 201
19 SPI0_MOSI/GPIOC0 64 20 GND
21 SPI0_MISO/GPIOC1 65 22 UART2_RX/GPIOA1 1
23 SPI0_CLK/GPIOC2 66 24 SPI0_CS/GPIOC3 67
25 GND 26 SPDIF-OUT/GPIOA17 17
27 I2C1_SDA/GPIOA19/PCM0_CLK/I2S0_BCK 19 28 I2C1_SCL/GPIOA18/PCM0_SYNC/I2S0_LRCK 18
29 GPIOA20/PCM0_DOUT/I2S0_SDOUT 20 30 GND
31 GPIOA21/PCM0_DIN/I2S0_SDIN 21 32 NC
33 NC 34 GND
35 NC 36 NC
37 GPIOA9 9 38 NC
39 GND 40 NC
  • Debug Port(UART0)
Pin# Name
1 GND
2 VDD_5V
3 UART_TXD0
4 UART_RXD0
  • USB Pin Header
Pin# Name
1 5V
2 DM
3 DP
4 GND
  • DVP Camera Interface Pin Description
Pin# Name Description
1, 2 SYS_3.3V 3.3V Output, it can be used to power camera modules
7,9,13,15,24 GND Ground, 0V
3 I2C2_SCL I2C clock signal
4 I2C2_SDA I2C data signal
5 GPIOE15 regular GPIO, used to control connected camera modules
6 GPIOE14 regular GPIO, used to control connected camera modules
8 MCLK Clock signals output to camera modules
10 NC Not connected
11 VSYNC vertical synchronization
12 HREF/HSYNC horizontal synchronization
14 PCLK peripheral clock
16-23 Data bit7-0 data bits
Notes
  1. SYS_3.3V: 3.3V power output
  2. VDD_5V: 5V power output5V. When the external device’s power is greater than the MicroUSB’s the external device is charging the board otherwise the board powers the external device.The input range is 4.7V ~ 5.6V
  3. All pins are 3.3V, output current is 5mA
  4. For more details refer to the document:NanoPi-M1-Plus-1702-Schematic.pdf

3.2 Board Dimension

NanoPi-M1-Plus-1702-Drawing.jpg

For more details please refer to the document:pcb in dxf format

4 Get Started

4.1 Essentials You Need

Before starting to use your NanoPi M1 Plus get the following items ready

  • NanoPi M1 Plus
  • MicroSD Card/TF Card: Class 10 or Above, minimum 8GB SDHC
  • A DC 5V/2A power is a must
  • HDMI monitor
  • USB keyboard, mouse and possible a USB hub(or a TTL to serial board)
  • A host computer running Ubuntu 14.04 64 bit system

4.2 TF Cards We Tested

To make your NanoPi M1 Plus boot and run fast we highly recommend you use a Class10 8GB SDHC TF card or a better one. The following cards are what we used in all our test cases presented here:

  • SanDisk TF 8G Class10 Micro/SD TF card:

SanDisk MicroSD 8G

  • SanDisk TF128G MicroSDXC TF 128G Class10 48MB/S:

SanDisk MicroSD 128G

  • 川宇 8G C10 High Speed class10 micro SD card:

chuanyu MicroSD 8G

4.3 Make an Installation TF Card

4.3.1 Download Image Files

Get the following files from here download link to download image files (under the "officail-ROMs" diirectory) and the flashing utility (under the "tools" diirectory):

Image Files
nanopi-m1-plus-debian-sd4g.img.zip Debian Image File
nanopi-m1-plus-ubuntu-core-qte-sd4g.img.zip Ubuntu core with Qt Embedded
nanopi-m1-eflasher-sd8g.img.zip eflasher which can be used to Flash image files to eMMC
nanopi-m1-plus-android.img.zip Android Image File
Flash Utility
win32diskimager.rar Windows utility. Under Linux users can use "dd"
PhoenixCard_V310.rar Windows utility for flashing Android image. Attention: the "dd" command under Linux doesn't work for flashing Android image
HDDLLF.4.40.exe Windows utility for formatting a TF card

4.3.2 TF Card Systems

4.3.2.1 Make Debian Image Card
  • Extract the nanopi-m1-plus-debian-sd4g.img.zip and win32diskimager.rar files. Insert a TF card(at least 8G) into a Windows PC and run the win32diskimager utility as administrator. On the utility's main window select your TF card's drive, the wanted image file and click on "write" to start flashing the TF card.
  • Insert this card into your NanoPi M1 Plus' BOOT slot and power on (with a 5V/2A power source). If the green LED is on and the blue LED is blinking this indicates your NanoPi M1 Plus has successfully booted.

Note:you can make a Ubuntu image card in this way too.

4.3.2.2 Make Android Image Card
  • On a Windows PC run the HDDLLF.4.40 utility as administrator. Insert a TF card(at least 8G) into this PC and format it. After formatting is done take out the TF card, insert it into the PC again and format it with Windows internal format utility to format it to FAT32. After this formatting is done take out the card.
  • Extract the nanopi-m1-plus-android.img.zip and PhoenixCard_V310.rar files. Insert the TF card you made in the previous step into a Windows PC and run the PhoenixCard_V310 utility as administrator. On the utility's main window select your TF card's drive, the wanted image file and click on "write" to start flashing the TF card.
  • Insert this card into your NanoPi M1 Plus' BOOT slot and power on (with a 5V/2A power source). If the green LED is on and the blue LED is blinking this indicates your NanoPi M1 Plus has successfully booted.

Note: you must format your TF card before you start making it an Android image card.

4.3.3 Flash image to eMMC with eflasher

  • Extract the nanopi-m1-eflasher-sd8g.img.zip and win32diskimager.rar files. Insert a TF card(at least 4G) into a Windows PC and run the win32diskimager utility as administrator. On the utility's main window select your TF card's drive, the wanted image file and click on "write" to start flashing the TF card.
  • Insert this card into your NanoPi M1 Plus' BOOT slot and power on (with a 5V/2A power source). If the green LED is on and the blue LED is blinking this indicates your NanoPi M1 Plus has successfully booted.
  • Connect the board to an HDMI monitor or an LCD and a USB mouse, and select an OS to start installation.

eflasher
If no monitor is connected you can select an OS by running the following command:

eflasher

Type a number and enter to select an OS, then type "yes" and enter to start installation. After installation is done shutdown the system, take out the TF card, power on your board again and it will boot from eMMC.

5 Work with Debian

5.1 Run Debian

  • Insert a TF card with Debian image into your NanoPi M1 Plus, connect the it to an HDMI monitor and a 5V/2A power it will be automatically powered on. If you can see the blue LED flashing it means your board is working and you will see Debain being loaded on the HDMI monitor.

1) If you connect your NanoPi M1 Plus to an HDMI monitor you need to use a USB mouse and a USB keyboard to operate.
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.

  • Here is a setup where we connect a NanoPi M1 Plus to a PC via the PSU-ONECOM and you can power on your M1 Plus from either the PSU-ONECOM or its MicroUSB:

PSU-ONECOM-NanoPI-M1-Plus

  • The password for both "root" and "fa" is "fa" under Debian.
  • Update packages
sudo apt-get update

5.2 Extend TF Card's rootfs Section

When you boot Debian for the first time with your image card your OS will automatically resize the file system and this process takes a relatively long time.After your OS is fully loaded you can check the file system's size by using the following command:

df -h

5.3 Ethernet Connection

If the NanoPi M1 Plus is connected to a network via Ethernet before it is powered on it will automatically obtain an IP after it is powered up. If it is not connected via Ethernet or its DHCP is not activated obtaining an IP will fail and system will hang on for about 15 to 60 seconds

  • Setup MAC Address

The NanoPi M1 Plus by default doesn't have a valid MAC address. If the board connects a network successfully it will automatically generate a random MAC in "/etc/network/interfaces.d/eth0". Users can change it to a self-defined valid one:

vi /etc/network/interfaces.d/eth0

Here is the content of a sample configuration file:

auto eth0
allow-hotplug eth0
iface eth0 inet dhcp
hwaddress 76:92:d4:85:f3:0f

The "hwaddress" specifies the MAC address. Here the "76:92:d4:85:f3:0f" is a random MAC. We suggest users change it to a valid one.
Note: when you reset the MAC please make sure your MAC meets IEEE's definition otherwise it will cause unexpected issues. After you make your change, save, exit and reboot your board or run the following commands to restart the network:

systemctl restart networking

5.4 连接无线网络

用vi或在图形界面下用gedit编辑文件 /etc/wpa_supplicant/wpa_supplicant.conf, 在文件末尾填入路由器信息如下所示:

network={
        ssid="YourWiFiESSID"
        psk="YourWiFiPassword"
}

其中,YourWiFiESSID和YourWiFiPassword请替换成你要连接的无线AP名称和密码。
保存退出后,执行以下命令即可连接WiFi:

ifdown wlan0
ifup wlan0

如果你的WiFi密码中有特殊字符,或者你不希望明文存放密码,你可以使用wpa_passphrase命令为WiFi密码生成一个密钥(psk),用密钥来代替密码 ,在命令行下,可输入以下命令生成密钥:

wpa_passphrase YourWiFiESSID

在提示输入密码时,输入你的WiFi密码,再打开 /etc/wpa_supplicant/wpa_supplicant.conf 文件你会发现密钥已经被更新,你可以删除明文的密码了。

5.5 通过VNC和ssh登录Debian

如果你不想连接HDMI,可以使用手机或电脑到这里下载并安装一个名为VNC Viewer的软件,用VNC连接到M1+,默认的端口号为1,密码为:fa123456 。
以下是在iPhone上用VNC登录M1+的画面:
VNC to NanoPi2
你也可以通过 ssh -l root 192.168.8.1 命令在终端上登录,默认的root用户密码是 fa 。请将192.168.8.1替换为实际IP地址。

5.6 HDMI输出声音

Debian系统默认从3.5mm耳机座输出声音,想从HDMI输出需要修改文件系统上的配置文件/etc/asound.conf如下:

pcm.!default {
    type hw
    card 1
    device 0
}
 
ctl.!default {
    type hw
    card 1
}

card 0代表3.5mm耳机孔,card 1代表HDMI音频。设置完成后需要重启系统才能生效。

5.7 测试GPU

启动Debian系统,在HDMI界面下登录Debian,打开终端并运行命令:

glmark2-es2

测试效果如下:
m1-gpu-glmark2

5.8 测试VPU

访问此处下载地址的test-video目录下载视频文件,启动Debian系统,在HDMI界面下登录Debian,打开终端并运行命令:

sudo apt-get install mpv
video_play mpv ./big_buck_bunny_1080p_H264_AAC_25fps_7200K.MP4

经测试,可流畅硬解播放1080p视频。

5.9 连接USB WiFi

Debian系统已经支持市面上众多常见的USB WiFi,想知道你的USB WiFi是否可用只需将其接在M1+上即可,已测试过的USB WiFi型号如下:

序号 型号
1 RTL8188CUS/8188EU 802.11n WLAN Adapter
2 RT2070 Wireless Adapter
3 RT2870/RT3070 Wireless Adapter
4 RTL8192CU Wireless Adapter
5 小米WiFi mt7601

M1+ 上电启动连接上USB WiFi后,通过串口登录到系统,敲入以下命令可以查看到系统是否识别到USB WiFi,如果出现“wlan0”,则证明USB WiFi已被识别到:

ifconfig -a

用vi或在图形界面下用gedit编辑文件 /etc/wpa_supplicant/wpa_supplicant.conf, 在文件末尾填入路由器信息如下所示:

network={
        ssid="YourWiFiESSID"
        psk="YourWiFiPassword"
}

其中,YourWiFiESSID和YourWiFiPassword请替换成你要连接的无线AP名称和密码。
保存退出后,执行以下命令即可连接WiFi:

ifdown wlan0
ifup wlan0

如果你的WiFi密码中有特殊字符,或者你不希望明文存放密码,你可以使用wpa_passphrase命令为WiFi密码生成一个密钥(psk),用密钥来代替密码 ,在命令行下,可输入以下命令生成密钥:

wpa_passphrase YourWiFiESSID

在提示输入密码时,输入你的WiFi密码,再打开 /etc/wpa_supplicant/wpa_supplicant.conf 文件你会发现密钥已经被更新,你可以删除明文的密码了。

5.10 连接DVP摄像头模块(CAM500B)

CAM500B是一款500万像素摄像头模块,以DVP并行信号输出,详细信息请参考Matirx-CAM500B
NanoPi-M1-Plus-cam500a
根据上图连接M1+和CAM500B,然后上电启动Debian系统,连接网络,以root用户登录终端并编译运行mjpg-streamer:

cd /root/mjpg-streamer
make
./start.sh

mjpg-streamer是一个开源的网络视频流服务器,在板子上成功运行mjpg-streamer后会打印下列信息:

 
 i: Using V4L2 device.: /dev/video0
 i: Desired Resolution: 1280 x 720
 i: Frames Per Second.: 30
 i: Format............: YUV
 i: JPEG Quality......: 90
 o: www-folder-path...: ./www/
 o: HTTP TCP port.....: 8080
 o: username:password.: disabled
 o: commands..........: enabled

假设M1+的IP地址为192.168.1.230,在PC的浏览器中输入 192.168.1.230:8080 就能浏览摄像头采集的画面了,效果如下:
mjpg-streamer-cam500a
mjpg-streamer是用libjpeg对摄像头数据进行软编码,你可以使用ffmpeg对摄像头数据进行硬编码,这样能大大降低CPU的占用率并提高编码速度:

ffmpeg -t 30 -f v4l2 -channel 0 -video_size 1280x720 -i /dev/video0 -pix_fmt nv12 -r 30 -b:v 64k -c:v cedrus264 test.mp4

默认会录制30秒的视频,输入q能终止录制。录制完成后会在当前目录生成一个名为test.mp4的视频文件,可将其拷贝到PC上进行播放验证。

5.11 连接USB摄像头模块(FA-CAM202)

FA-CAM202是一款200万像素的USB摄像头模块。
启动Debian系统,在HDMI界面下登录Debian,打开终端并运行命令:

xawtv 0

可以在HDMI界面下正常看到摄像头的预览内容。 注:这里的"0"指的是接进板子的摄像头为/dev/video0设备,请根据实际情况填写video索引号。

5.12 连接摄像头测试OpenCV

OpenCV的全称是Open Source Computer Vision Library,是一个跨平台的计算机视觉库。
执行以下步骤测试OpenCV:

  • 连接网线,然后启动Debian系统,在HDMI界面下登录Debian。
  • 安装opencv库,执行命令:
apt-get update
apt-get install libcv-dev libopencv-dev
  • 参考前面章节,确保摄像头工作正常:
  • 运行OpenCV官方C++示例代码,执行下列命令编译运行:
cd /home/fa/Documents/opencv-demo
make
./demo

可以看到效果如下:
OpenCV-M1+

5.13 命令行查看CPU工作温度

在串口终端执行如下命令,可以快速地获取CPU的当前温度和运行频率等信息:

cpu_freq

5.14 通过Rpi-Monitor查看系统状态

Debian系统里已经集成了Rpi-Monitor,该服务允许用户在通过浏览器查看开发板系统状态。
假设M1+的IP地址为192.168.1.230,在PC的浏览器中输入下述地址:

192.168.1.230:8888

可以进入如下页面:
rpi-monitor
用户可以非常方便地查看到系统负载、CPU的频率和温度、可用内存、SD卡容量等信息。

6 如何编译Debian系统

6.1 准备工作

访问此处下载地址的sources/nanopi-h3-bsp目录,下载所有压缩文件,使用7-Zip工具解压后得到lichee目录和android目录,请务必保证这2个目录位于同一个目录中,如下:

ls ./
android lichee

也可以从github上克隆lichee源码:

git clone https://github.com/friendlyarm/h3_lichee.git lichee

注:lichee是全志为其CPU的板级支持包所起的项目名称,里面包含了U-boot,Linux等源码和众多的编译脚本。

6.2 安装交叉编译器

访问此处下载地址的toolchain目录,下载交叉编译器gcc-linaro-arm.tar.xz,将该压缩包放置在lichee/brandy/toochain/目录下即可,无需解压。

6.3 编译lichee源码

编译全志 H3 的BSP源码包必须使用64bit的Linux PC系统,并安装下列软件包,下列操作均基于Ubuntu-14.04 LTS-64bit:

sudo apt-get install gawk git gnupg flex bison gperf build-essential \
zip curl libc6-dev libncurses5-dev:i386 x11proto-core-dev \
libx11-dev:i386 libreadline6-dev:i386 libgl1-mesa-glx:i386 \
libgl1-mesa-dev g++-multilib mingw32 tofrodos \
python-markdown libxml2-utils xsltproc zlib1g-dev:i386

为Debian系统编译lichee源码包,进入lichee目录,执行命令:

cd lichee
./build.sh -p sun8iw7p1 -b nanopi-h3

该命令会为Debian系统一次性编译好U-boot、Linux内核和模块。
lichee目录里内置了交叉编译器,当使用build.sh脚本进行源码编译时,会自动使用该内置的编译器,所以无需手动安装编译器。

6.4 打包系统组件

./gen_script.sh -b nanopi-m1-plus

该命令会为U-boot打上全志系列CPU的硬件板级配置补丁,然后所有编译生成的可执行文件(包括U-boot、Linux内核)拷贝到lichee/tools/pack/out/目录以便进行统一管理。

下列命令可以更新TF卡上的U-boot:

./fuse_uboot.sh /dev/sdx

/dev/sdx请替换为实际的TF卡设备文件名。
内核boot.img和驱动模块均位于linux-3.4/output目录下,将boot.img拷贝到TF卡的boot分区的根目录即可更新内核。

6.5 编译U-boot

如果你想单独编译U-boot,可以执行命令:

./build.sh -p sun8iw7p1 -b nanopi-h3 -m uboot
./gen_script.sh -b nanopi-m1-plus

gen_script.sh脚本会为U-boot打上全志系列CPU的硬件板级配置补丁,只有打过补丁文件的U-boot才能烧写到TF卡中正常运行。 执行下列命令更新TF卡上的U-boot:

./fuse_uboot.sh /dev/sdx

/dev/sdx请替换为实际的TF卡设备文件名。

6.6 编译Linux内核

如果你想单独编译Linux内核,可以执行命令:

./build.sh -p sun8iw7p1 -b nanopi-h3 -m kernel

编译完成后内核boot.img和驱动模块均位于linux-3.4/output目录下,将boot.img拷贝到TF卡的boot分区的根目录即可。

6.7 清理lichee源码

./build.sh -p sun8iw7p1_linux -b nanopi-h3 -m clean

7 Android系统的使用

7.1 连接USB WiFi

Android系统目前仅支持型号为rtl8188etv/rtl8188eu的USB WiFi,即插即用。

7.2 使用红外遥控器(RC-100)

启动Android系统后,可用红外遥控器(型号为RC-100)进行远程操控。
RC-100上的按键功能如下:

按键名称 按键功能
POWER 开机/关机
F1 搜索
F2 打开浏览器
F3 进入/退出鼠标模式
UP 向上移动
DOWN 向下移动
LEFT 向左移动
RIGHT 向右移动
OK 确认
音量- 减小音量
音量静音 静音
音量+ 增大音量
SETTING 打开设置
HOME 回到主界面
BACK 返回上一个界面

Android系统第一次启动时,需要点击屏幕上的按钮完成教学示范,用户可以按下 F3 进入鼠标模式,然后配合上下左右和OK按键完成教学操作。

7.3 播放4K视频

访问此处下载地址的test-video目录,下载4K视频文件4K-Chimei-inn-60mbps.mp4,将其拷贝到SD卡或者U盘上。
在M1+上启动并运行Android系统,将带有视频文件的SD卡或者U盘接到M1+上,通过文件浏览器ESFileExplorer找到视频文件,点击视频文件并选择使用系统自带应用Gallery播放视频,即可观看影片。
经测试,将视频文件拷贝到U盘播放效果会更佳。

8 如何编译Android系统

8.1 准备工作

访问此处下载地址的sources/nanopi-h3-bsp目录,下载所有压缩文件,使用7-Zip工具解压后得到lichee目录和android目录,请务必保证这2个目录位于同一个目录中,如下:

ls ./
android lichee

也可以从github上克隆lichee源码:

git clone https://github.com/friendlyarm/h3_lichee.git lichee

注:lichee是全志为其CPU的板级支持包所起的项目名称,里面包含了U-boot,Linux等源码和众多的编译脚本。

编译全志 H3 的BSP源码包必须使用 64bit 的Linux系统,并安装下列软件包,下列操作均基于Ubuntu-14.04 LTS-64bit:

sudo apt-get install gawk git gnupg flex bison gperf build-essential \
zip curl libc6-dev libncurses5-dev:i386 x11proto-core-dev \
libx11-dev:i386 libreadline6-dev:i386 libgl1-mesa-glx:i386 \
libgl1-mesa-dev g++-multilib mingw32 tofrodos \
python-markdown libxml2-utils xsltproc zlib1g-dev:i386

8.2 安装交叉编译器

访问此处下载地址的toolchain目录,下载交叉编译器压缩包gcc-linaro-arm.tar.xz,然后将该压缩包放置在lichee/brandy/toochain/目录下即可,无需解压。

8.3 编译Android

  • 搭建编译环境

搭建编译Android的环境建议使用64位的Ubuntu-14.04 LTS-64bit,安装需要的包即可。

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

更多说明可查看:android_initializing

  • 安装JDK

使用JDK1.6.0_45版本,下载和安装说明请查看Oracle官方网址:Oracle JDK ,这里假设JDK已经成功安装到路径/usr/lib/jvm/下。

  • 编译系统
cd lichee
export PATH=/usr/lib/jvm/jdk1.6.0_45/bin:$PATH
./gen_android_img.sh -b nanopi-m1-plus -t android

上述命令会编译lichee目录和android目录,编译完成后会在lichee/tools/pack/目录下生成Android系统固件sun8iw7p1_android_nanopi-h3_uart0.img。

8.4 清理lichee源码

./build.sh -p sun8iw7p1_android -b nanopi-h3 -m clean

9 更多OS

10 3D打印文件下载

  • NanoPi M1 Plus 3D打印外壳:[1]

3D打印M1+

11 NanoPi M1 Plus初学者入门开发教程

12 资源链接

13 更新日志

13.1 2017-02-04

  • 修复Debian系统和Ubuntu-Core系统USB WiFi无法使用的问题;
  • 将Ubuntu-Core系统的版本号从15.10升级到16.04;