Difference between revisions of "Matrix - Analog to Digital Converter"
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* The operating supply voltage is from 2.5V to 6.0V,Among the 2.54 mm spacing pin header the 5V pin is the supply voltage. If you need 0 - 3.3V analog signals and keep the acquisition resolution you can connect it to a 3.3V supply voltage. | * The operating supply voltage is from 2.5V to 6.0V,Among the 2.54 mm spacing pin header the 5V pin is the supply voltage. If you need 0 - 3.3V analog signals and keep the acquisition resolution you can connect it to a 3.3V supply voltage. | ||
− | == | + | ==Features== |
− | * | + | * Wide range supply voltage: 2.5V - 6.0V |
− | * | + | * I2C interface: 3.3V/5V |
− | * 8-bit A/D | + | * 8-bit A/D x 4 |
− | * 8-bit D/A | + | * 8-bit D/A x 1 |
− | * | + | * Small and easy to be used in various situations |
− | * 2. | + | * 2.54 mm spacing pin |
− | * | + | * PCB dimension (mm): 16 x 24 |
[[File:adcpcb.png|frameless|400px|模数PCB]] | [[File:adcpcb.png|frameless|400px|模数PCB]] | ||
− | * | + | * Pin Description: |
{| class="wikitable" | {| class="wikitable" | ||
|- | |- | ||
− | | | + | |Pin || Description |
|- | |- | ||
|SDA || I2C SDA | |SDA || I2C SDA | ||
Line 29: | Line 29: | ||
|SCL || I2C SCL | |SCL || I2C SCL | ||
|- | |- | ||
− | |5V || | + | |5V || Supply Voltage 5V |
|- | |- | ||
− | |GND || | + | |GND || Ground |
|- | |- | ||
− | |AOUT || | + | |AOUT || Analog Output |
|- | |- | ||
− | |A3 || | + | |A3 || Analog Input3 |
|- | |- | ||
− | |A2 || | + | |A2 || Analog Input2 |
|- | |- | ||
− | |A1 || | + | |A1 || Analog Input1 |
|- | |- | ||
− | |A0 || | + | |A0 || Analog Input0 |
|} | |} | ||
Revision as of 06:43, 23 September 2015
Contents
1 Introduction
- The Matrix-Analog_to_Digital_Converter is a single-chip, single-supply low-power 8-bit CMOS data acquisition device.
- It utilizes the PCF8591 chip with four analog inputs, one analog output and a serial I2C-bus interface. Three address pins A0, A1 and A2 are used for programming the hardware address, allowing
the use of up to eight devices connected to the I2C-bus without additional hardware. Address, control and data to and from the device are transferred serially via the two-line bidirectional I2C-bus. The maximum conversion rate is given by the maximum speed of the I2C-bus.
- The I2C hardware address is configured to 1001000x
- The operating supply voltage is from 2.5V to 6.0V,Among the 2.54 mm spacing pin header the 5V pin is the supply voltage. If you need 0 - 3.3V analog signals and keep the acquisition resolution you can connect it to a 3.3V supply voltage.
2 Features
- Wide range supply voltage: 2.5V - 6.0V
- I2C interface: 3.3V/5V
- 8-bit A/D x 4
- 8-bit D/A x 1
- Small and easy to be used in various situations
- 2.54 mm spacing pin
- PCB dimension (mm): 16 x 24
- Pin Description:
Pin | Description |
SDA | I2C SDA |
SCL | I2C SCL |
5V | Supply Voltage 5V |
GND | Ground |
AOUT | Analog Output |
A3 | Analog Input3 |
A2 | Analog Input2 |
A1 | Analog Input1 |
A0 | Analog Input0 |
3 工作原理
芯片PCF8591是用i2c总线进行串行输入/输出,因此模块上的SDA、SCL两个引脚可以接到开发板的I2C的SDA、SCL两个引脚上。模块上还有AINT0-AINT4引脚为外部模拟输入可编程为单端或差分输入,要注意外接的模拟电压输入范围在0—VDD。
1、PCF8591在I2C总线系统通过激活来发送一个有效的地址到设备中,可编程地址必须根据地址引脚A0、A1、A2来设置。I2C协议中信息发送开始后发送的第一个字节是地址信息,地址字节的最后一位是用于设置以后数据传输方向的读/写位。
2、发送到PCF8591 的第二个字节将被存储在控制寄存器,用于控制器件功能。控制寄存器的高半字节用于允许模拟输出,和将模拟输入编程为单端或差分输入。低半字节选择一个由高半字节定义的模拟输入通道。
3、在A/D 转换周期将临时使用片上D/A 转换器和高增益比较器。一个A/D 转换周期总是开始于发送一个有效读模式地址给PCF8591 之后。A/D 转换周期在应答时钟脉冲的后沿被触发,并在传输前一次转换结果时执行A/D转换器采用。
4 下载Matrix源码
Matrix配件相关的代码是完全开源的,统一由一个仓库进行管理:git://github.com/friendlyarm/matrix.git
该仓库里不同的分支代表着Matrix配件所支持的不同开发板。
- nanopi分支包含了Matrix对NanoPi的支持;
- tiny4412分支包含了Matrix对Tiny4412的支持;
- raspberrypi分支包含了Matrix对RaspberryPi的支持;
在主机PC上安装git,以Ubuntu14.04为例
$ sudo apt-get install git
克隆Matrix配件代码仓库
$ git clone git://github.com/friendlyarm/matrix.git
克隆完成后会得到一个matrix目录,里面存放着所有Matrix配件的代码。
5 与NanoPi连接使用
5.1 准备工作
在NanoPi上运行Debian系统,然后在主机PC上安装并使用相应的编译器。参考wiki:NanoPi
注意:必须使用nanopi-v4.1.y-matrix分支编译出来的内核。
下载NanoPi内核源代码并编译
$ git clone https://github.com/friendlyarm/linux-4.x.y.git $ cd linux-4.x.y $ git checkout nanopi-v4.1.y-matrix $ make nanopi_defconfig $ touch .scmversion $ make
5.2 硬件连接
参考下图连接模块Matrix-Analog_to_Digital_Converter和NanoPi
连接说明:
Matrix-Analog_to_Digital_Converter | NanoPi |
SDA | Pin3 |
SCL | Pin5 |
5V | Pin4 |
GND | Pin6 |
5.3 编译测试程序
进入Matrix代码仓库,切换到nanopi分支
$ cd matrix $ git checkout nanopi
编译Matrix配件代码
$ make CROSS_COMPILE=arm-linux- clean $ make CROSS_COMPILE=arm-linux- $ make CROSS_COMPILE=arm-linux- install
注意:请确保你的主机PC当前使用的交叉编译器为NanoPi-Debian配套的arm-linux-gcc-4.4.3。
编译出来的库文件位于install/lib目录下,而测试程序则位于install/usr/bin目录下,模块Matrix-Analog_to_Digital_Converter对应的测试程序为matrix-analog_to_digital_converter。
5.4 运行测试程序
拷贝库文件和测试程序到NanoPi的文件系统上
$ cp install/usr/bin/* nanopi_rootfs/usr/bin/ $ cp install/lib/* nanopi_rootfs/lib/ -d
然后启动NanoPi,在Debian的shell终端中执行如下命令运行模块Matrix-Analog_to_Digital_Converter的测试程序
注意:此模块并不支持热插拔,启动系统前需要确保硬件正常连接。
$ matrix-analog_to_digital_converter
5.5 代码展示
int main(int argc, char ** argv) { int devFD; int data, channel, mode; if ((devFD = pcf8591Init()) == -1) { printf("Fail to init pcf8591\n"); return -1; } if (pcf8591SetCtrl(devFD, PCF8591_INIT_AD_CONTROL) == -1) { printf("Fail to Set pcf8591 control AD\n"); pcf8591DeInit(devFD); return -1; } mode = 0; printf("pcf8591 working as AD in mode%d\n",mode); for (channel = PCF8591_AIN_CHANNEL0; channel <= PCF8591_AIN_CHANNEL3; channel++) { data = pcf8591Read(devFD, mode, channel); printf("Channel%d's value: %d\n",channel,data); } pcf8591DeInit(devFD); return 0; }
6 与Tiny4412连接使用
6.1 准备工作
参考Tiny4412光盘里的《友善之臂Ubuntu使用手册》,在Tiny4412上运行UbuntuCore系统,然后在主机PC上安装并使用相应的编译器。
注意:只能使用Tiny4412SDK-1506的底板。
6.2 硬件连接
参考下图连接模块Matrix-Analog_to_Digital_Converter和Tiny4412
连接说明:
Matrix-Analog_to_Digital_Converter | NanoPi |
SDA | CON18 SDA |
SCL | CON18 SCL |
5V | CON18 5V |
GND | CON18 GND |
6.3 编译测试程序
进入Matrix代码仓库,切换到tiny4412分支
$ cd matrix $ git checkout tiny4412
编译Matrix配件代码
$ make CROSS_COMPILE=arm-linux-gnueabihf- clean $ make CROSS_COMPILE=arm-linux-gnueabihf- $ make CROSS_COMPILE=arm-linux-gnueabihf- install
注意:请确保你的主机PC当前使用的交叉编译器为Tiny4412-UbuntuCore配套的arm-linux-gnueabihf-gcc-4.7.3。
编译出来的库文件位于install/lib目录下,而测试程序则位于install/usr/bin目录下,模块Matrix-Analog_to_Digital_Converter对应的测试程序为matrix-analog_to_digital_converter。
6.4 运行测试程序
拷贝库文件和测试程序到Tiny4412的UbuntuCore的文件系统上
$ cp install/usr/bin/* tiny4412_rootfs/usr/bin/ $ cp install/lib/* tiny4412_rootfs/lib/ -d
然后启动Tiny4412,在UbuntuCore的shell终端中执行如下命令运行模块Matrix-Analog_to_Digital_Converter的测试程序
$ matrix-analog_to_digital_converter
6.5 代码展示
int main(int argc, char ** argv) { int devFD; int data, channel, mode; if ((devFD = pcf8591Init()) == -1) { printf("Fail to init pcf8591\n"); return -1; } if (pcf8591SetCtrl(devFD, PCF8591_INIT_AD_CONTROL) == -1) { printf("Fail to Set pcf8591 control AD\n"); pcf8591DeInit(devFD); return -1; } mode = 0; printf("pcf8591 working as AD in mode%d\n",mode); for (channel = PCF8591_AIN_CHANNEL0; channel <= PCF8591_AIN_CHANNEL3; channel++) { data = pcf8591Read(devFD, mode, channel); printf("Channel%d's value: %d\n",channel,data); } pcf8591DeInit(devFD); return 0; }
7 与RaspberryPi连接使用
8 与Arduino连接使用
9 相关资料