RFIDRC522ラズベリーパイ2Windows IOT
WindowsIOTのRaspberryPi2.0でRFID「RC522」を使用する方法を探しています。
もちろん、公式の互換性はありません...
公式のもの(OM5577デモボード)はフランスで高価な方法です(私は多くの送料なしでそれを販売した再販業者を見つけませんでした(総費用は約80ドルです))。
RC522は安い(<10 $)。これは、ArduinoおよびLinux上のRaspberry Pi2.0でうまく機能します。しかし、残念ながらまだWindowsIOTにはありません。
私は実際にarduinoをブリッジとして使用しています...これは最適なソリューションではありません。しかし、うまく機能し、常にOM5577の半分の価格です。
this プロジェクトを見つけ、Windows IOT SIPおよびIO ...を使用してVS(Visual C++)プロジェクトに変換しようとしています...私は惨めに失敗します。 。
私の夢では、このデバイスをC#で標準のWindowsIOT「ProximityDevice」クラスを使用して使用できるようになります。
私に何か考えはありますか?
前もって感謝します。
私はついに解決策を見つけました。
私はarudinoの移植性に成功していません。だから私は this プロジェクトを開始点として使用しました。
プロジェクトはC#で記述されています。コードをWindowsIOTGPIOとSPIに適合させました。それは働いています!
メイン
var mfrc = new Mfrc522();
await mfrc.InitIO();
while (true)
{
if (mfrc.IsTagPresent())
{
var uid = mfrc.ReadUid();
mfrc.HaltTag();
}
}
ライブラリMfrc522Lib.cs(オールインワン)
using System;
using System.Collections.Generic;
using System.Threading;
using System.Threading.Tasks;
using Windows.Devices.Enumeration;
using Windows.Devices.Gpio;
using Windows.Devices.Spi;
namespace Mfrc522Lib
{
public static class Registers
{
private const byte bitFraming = 0x0D;
private const byte comIrq = 0x04;
private const byte comIrqEnable = 0x02;
private const byte command = 0x01;
private const byte control = 0x0C;
private const byte error = 0x06;
private const byte fifoData = 0x09;
private const byte fifoLevel = 0x0A;
private const byte mode = 0x11;
private const byte rxMode = 0x13;
private const byte timerMode = 0x2A;
private const byte timerPrescaler = 0x2B;
private const byte timerReloadHigh = 0x2C;
private const byte timerReloadLow = 0x2D;
private const byte txAsk = 0x15;
private const byte txControl = 0x14;
private const byte txMode = 0x12;
private const byte version = 0x37;
public static byte BitFraming
{
get
{
return bitFraming;
}
}
public static byte ComIrq
{
get
{
return comIrq;
}
}
public static byte ComIrqEnable
{
get
{
return comIrqEnable;
}
}
public static byte Command
{
get
{
return command;
}
}
public static byte Control
{
get
{
return control;
}
}
public static byte Error
{
get
{
return error;
}
}
public static byte FifoData
{
get
{
return fifoData;
}
}
public static byte FifoLevel
{
get
{
return fifoLevel;
}
}
public static byte Mode
{
get
{
return mode;
}
}
public static byte RxMode
{
get
{
return rxMode;
}
}
public static byte TimerMode
{
get
{
return timerMode;
}
}
public static byte TimerPrescaler
{
get
{
return timerPrescaler;
}
}
public static byte TimerReloadHigh
{
get
{
return timerReloadHigh;
}
}
public static byte TimerReloadLow
{
get
{
return timerReloadLow;
}
}
public static byte TxAsk
{
get
{
return txAsk;
}
}
public static byte TxControl
{
get
{
return txControl;
}
}
public static byte TxMode
{
get
{
return txMode;
}
}
public static byte Version
{
get
{
return version;
}
}
}
public static class PiccResponses
{
private const ushort answerToRequest = 0x0004;
private const byte selectAcknowledge = 0x08;
private const byte acknowledge = 0x0A;
public static byte Acknowledge
{
get
{
return acknowledge;
}
}
public static byte SelectAcknowledge
{
get
{
return selectAcknowledge;
}
}
public static ushort AnswerToRequest
{
get
{
return answerToRequest;
}
}
}
public static class PiccCommands
{
private const byte anticollision_1 = 0x93;
private const byte anticollision_2 = 0x20;
private const byte authenticateKeyA = 0x60;
private const byte authenticateKeyB = 0x61;
private const byte halt_1 = 0x50;
private const byte halt_2 = 0x00;
private const byte read = 0x30;
private const byte request = 0x26;
private const byte select_1 = 0x93;
private const byte select_2 = 0x70;
private const byte write = 0xA0;
public static byte AuthenticateKeyA
{
get
{
return authenticateKeyA;
}
}
public static byte AuthenticateKeyB
{
get
{
return authenticateKeyB;
}
}
public static byte Halt_1
{
get
{
return halt_1;
}
}
public static byte Halt_2
{
get
{
return halt_2;
}
}
public static byte Read
{
get
{
return read;
}
}
public static byte Request
{
get
{
return request;
}
}
public static byte Select_1
{
get
{
return select_1;
}
}
public static byte Select_2
{
get
{
return select_2;
}
}
public static byte Write
{
get
{
return write;
}
}
public static byte Anticollision_1
{
get
{
return anticollision_1;
}
}
public static byte Anticollision_2
{
get
{
return anticollision_2;
}
}
}
public static class PcdCommands
{
private const byte idle = 0x00;
private const byte mifareAuthenticate = 0x0E;
private const byte transceive = 0x0C;
public static byte Idle
{
get
{
return idle;
}
}
public static byte MifareAuthenticate
{
get
{
return mifareAuthenticate;
}
}
public static byte Transceive
{
get
{
return transceive;
}
}
}
public class Uid
{
public byte Bcc { get; private set; }
public byte[] Bytes { get; private set; }
public byte[] FullUid { get; private set; }
public bool IsValid { get; private set; }
internal Uid(byte[] uid)
{
FullUid = uid;
Bcc = uid[4];
Bytes = new byte[4];
System.Array.Copy(FullUid, 0, Bytes, 0, 4);
foreach (var b in Bytes)
{
if (b != 0x00)
IsValid = true;
}
}
public sealed override bool Equals(object obj)
{
if (!(obj is Uid))
return false;
var uidWrapper = (Uid)obj;
for (int i = 0; i < 5; i++)
{
if (FullUid[i] != uidWrapper.FullUid[i])
return false;
}
return true;
}
public sealed override int GetHashCode()
{
int uid = 0;
for (int i = 0; i < 4; i++)
uid |= Bytes[i] << (i * 8);
return uid;
}
public sealed override string ToString()
{
var formatString = "x" + (Bytes.Length * 2);
return GetHashCode().ToString(formatString);
}
}
public sealed class Mfrc522
{
public SpiDevice _spi { get; private set; }
public GpioController IoController { get; private set; }
public GpioPin _resetPowerDown { get; private set; }
/* Uncomment for Raspberry Pi 2 */
private const string SPI_CONTROLLER_NAME = "SPI0";
private const Int32 SPI_CHIP_SELECT_LINE = 0;
private const Int32 RESET_PIN = 25;
internal async Task InitIO()
{
try
{
IoController = GpioController.GetDefault();
_resetPowerDown = IoController.OpenPin(RESET_PIN);
_resetPowerDown.Write(GpioPinValue.High);
_resetPowerDown.SetDriveMode(GpioPinDriveMode.Output);
}
/* If initialization fails, throw an exception */
catch (Exception ex)
{
throw new Exception("GPIO initialization failed", ex);
}
try
{
var settings = new SpiConnectionSettings(SPI_CHIP_SELECT_LINE);
settings.ClockFrequency = 1000000;
settings.Mode = SpiMode.Mode0;
String spiDeviceSelector = SpiDevice.GetDeviceSelector();
IReadOnlyList<DeviceInformation> devices = await DeviceInformation.FindAllAsync(spiDeviceSelector);
_spi = await SpiDevice.FromIdAsync(devices[0].Id, settings);
}
/* If initialization fails, display the exception and stop running */
catch (Exception ex)
{
throw new Exception("SPI Initialization Failed", ex);
}
Reset();
}
public void Reset()
{
_resetPowerDown.Write(GpioPinValue.Low);
System.Threading.Tasks.Task.Delay(50).Wait();
_resetPowerDown.Write(GpioPinValue.High);
System.Threading.Tasks.Task.Delay(50).Wait();
// Force 100% ASK modulation
WriteRegister(Registers.TxAsk, 0x40);
// Set CRC to 0x6363
WriteRegister(Registers.Mode, 0x3D);
// Enable antenna
SetRegisterBits(Registers.TxControl, 0x03);
}
public bool IsTagPresent()
{
// Enable short frames
WriteRegister(Registers.BitFraming, 0x07);
// Transceive the Request command to the tag
Transceive(false, PiccCommands.Request);
// Disable short frames
WriteRegister(Registers.BitFraming, 0x00);
// Check if we found a card
return GetFifoLevel() == 2 && ReadFromFifoShort() == PiccResponses.AnswerToRequest;
}
public Uid ReadUid()
{
// Run the anti-collision loop on the card
Transceive(false, PiccCommands.Anticollision_1, PiccCommands.Anticollision_2);
// Return tag UID from FIFO
return new Uid(ReadFromFifo(5));
}
public void HaltTag()
{
// Transceive the Halt command to the tag
Transceive(false, PiccCommands.Halt_1, PiccCommands.Halt_2);
}
public bool SelectTag(Uid uid)
{
// Send Select command to tag
var data = new byte[7];
data[0] = PiccCommands.Select_1;
data[1] = PiccCommands.Select_2;
uid.FullUid.CopyTo(data, 2);
Transceive(true, data);
return GetFifoLevel() == 1 && ReadFromFifo() == PiccResponses.SelectAcknowledge;
}
internal byte[] ReadBlock(byte blockNumber, Uid uid, byte[] keyA = null, byte[] keyB = null)
{
if (keyA != null)
MifareAuthenticate(PiccCommands.AuthenticateKeyA, blockNumber, uid, keyA);
else if (keyB != null)
MifareAuthenticate(PiccCommands.AuthenticateKeyB, blockNumber, uid, keyB);
else
return null;
// Read block
Transceive(true, PiccCommands.Read, blockNumber);
return ReadFromFifo(16);
}
internal bool WriteBlock(byte blockNumber, Uid uid, byte[] data, byte[] keyA = null, byte[] keyB = null)
{
if (keyA != null)
MifareAuthenticate(PiccCommands.AuthenticateKeyA, blockNumber, uid, keyA);
else if (keyB != null)
MifareAuthenticate(PiccCommands.AuthenticateKeyB, blockNumber, uid, keyB);
else
return false;
// Write block
Transceive(true, PiccCommands.Write, blockNumber);
if (ReadFromFifo() != PiccResponses.Acknowledge)
return false;
// Make sure we write only 16 bytes
var buffer = new byte[16];
data.CopyTo(buffer, 0);
Transceive(true, buffer);
return ReadFromFifo() == PiccResponses.Acknowledge;
}
protected void MifareAuthenticate(byte command, byte blockNumber, Uid uid, byte[] key)
{
// Put reader in Idle mode
WriteRegister(Registers.Command, PcdCommands.Idle);
// Clear the FIFO
SetRegisterBits(Registers.FifoLevel, 0x80);
// Create Authentication packet
var data = new byte[12];
data[0] = command;
data[1] = (byte)(blockNumber & 0xFF);
key.CopyTo(data, 2);
uid.Bytes.CopyTo(data, 8);
WriteToFifo(data);
// Put reader in MfAuthent mode
WriteRegister(Registers.Command, PcdCommands.MifareAuthenticate);
// Wait for (a generous) 25 ms
System.Threading.Tasks.Task.Delay(25).Wait();
}
protected void Transceive(bool enableCrc, params byte[] data)
{
if (enableCrc)
{
// Enable CRC
SetRegisterBits(Registers.TxMode, 0x80);
SetRegisterBits(Registers.RxMode, 0x80);
}
// Put reader in Idle mode
WriteRegister(Registers.Command, PcdCommands.Idle);
// Clear the FIFO
SetRegisterBits(Registers.FifoLevel, 0x80);
// Write the data to the FIFO
WriteToFifo(data);
// Put reader in Transceive mode and start sending
WriteRegister(Registers.Command, PcdCommands.Transceive);
SetRegisterBits(Registers.BitFraming, 0x80);
// Wait for (a generous) 25 ms
System.Threading.Tasks.Task.Delay(25).Wait();
// Stop sending
ClearRegisterBits(Registers.BitFraming, 0x80);
if (enableCrc)
{
// Disable CRC
ClearRegisterBits(Registers.TxMode, 0x80);
ClearRegisterBits(Registers.RxMode, 0x80);
}
}
protected byte[] ReadFromFifo(int length)
{
var buffer = new byte[length];
for (int i = 0; i < length; i++)
buffer[i] = ReadRegister(Registers.FifoData);
return buffer;
}
protected byte ReadFromFifo()
{
return ReadFromFifo(1)[0];
}
protected void WriteToFifo(params byte[] values)
{
foreach (var b in values)
WriteRegister(Registers.FifoData, b);
}
protected int GetFifoLevel()
{
return ReadRegister(Registers.FifoLevel);
}
protected byte ReadRegister(byte register)
{
register <<= 1;
register |= 0x80;
var writeBuffer = new byte[] { register, 0x00 };
return TransferSpi(writeBuffer)[1];
}
protected ushort ReadFromFifoShort()
{
var low = ReadRegister(Registers.FifoData);
var high = (ushort)(ReadRegister(Registers.FifoData) << 8);
return (ushort)(high | low);
}
protected void WriteRegister(byte register, byte value)
{
register <<= 1;
var writeBuffer = new byte[] { register, value };
TransferSpi(writeBuffer);
}
protected void SetRegisterBits(byte register, byte bits)
{
var currentValue = ReadRegister(register);
WriteRegister(register, (byte)(currentValue | bits));
}
protected void ClearRegisterBits(byte register, byte bits)
{
var currentValue = ReadRegister(register);
WriteRegister(register, (byte)(currentValue & ~bits));
}
private byte[] TransferSpi(byte[] writeBuffer)
{
var readBuffer = new byte[writeBuffer.Length];
_spi.TransferFullDuplex(writeBuffer, readBuffer);
return readBuffer;
}
}
}
スキーマ
SPIを使用しているため、ハードウェアの互換性の問題は発生しないはずです。既存のArduinoコードを翻訳したくない場合、Microsoftには、既存のArduinoスケッチとライブラリを使用できるようにする技術がいくつかあります。詳細については、こちらをご覧ください: http://ms-iot.github.io/content/en-US/win10/ArduinoWiringProjectGuide.htm
追加:UIDを16進文字を表す文字列として表示する場合は、TagIsPresent部分内で次を使用できます。
var uid = mfrc.ReadUid();
string txt_Result = "";
foreach (byte byt in uid.FullUid)
{
txt_Result = txt_Result + byt.ToString("x2");
}
mfrc.HaltTag();