GY-63_MS5611/libraries/MAX6675/MAX6675.h

#pragma once
//
//    FILE: MAX6675.h
//  AUTHOR: Rob Tillaart
// VERSION: 0.1.1
// PURPOSE: Arduino library for MAX6675 chip for K type thermocouple
//    DATE: 2022-01-12
//     URL: https://github.com/RobTillaart/MAX6675


// TODO Breakout board
//
//     +---------+
// Vin | o       |
// 3V3 | o       |
// GND | o     O | Thermocouple
//  D0 | o     O | Thermocouple
//  CS | o       |
// CLK | o       |
//     +---------+

#include "Arduino.h"
#include "SPI.h"


#define MAX6675_LIB_VERSION               (F("0.1.1"))

#define MAX6675_NO_TEMPERATURE            -999

// STATE constants returned by read()
// TODO check
#define STATUS_OK                         0x00
#define STATUS_ERROR                      0x04
#define STATUS_NOREAD                     0x80
#define STATUS_NO_COMMUNICATION           0x81


//  Thermocouples working is based upon Seebeck effect.
//  Different TC have a different Seebeck Coefficient  (µV/°C)
//  See http://www.analog.com/library/analogDialogue/archives/44-10/thermocouple.html
//
//  K_TC == 41.276 µV/°C


class MAX6675
{
public:

  MAX6675();

  //  HW SPI
  void     begin(uint8_t select);
  //  SW SPI
  void     begin(uint8_t clock, uint8_t select, uint8_t miso);

  // returns state - bit field: 0 = STATUS_OK
  uint8_t  read();
  float    getTemperature(void)  { return _temperature + _offset; };

  uint8_t  getStatus(void) const { return _status; };

  // use offset to calibrate the TC.
  void     setOffset(const float  t)   { _offset = t; };
  float    getOffset() const           { return _offset; };

  uint32_t lastRead()    { return _lastTimeRead; };
  uint16_t getRawData()  { return _rawData;};

  //       speed in Hz
  void     setSPIspeed(uint32_t speed);
  uint32_t getSPIspeed() { return _SPIspeed; };
  void     setSWSPIdelay(uint16_t del = 0)  { _swSPIdelay = del; };
  uint16_t getSWSPIdelay() { return _swSPIdelay; };


  //       ESP32 specific
  #if defined(ESP32)
  void     selectHSPI() { _useHSPI = true;  };
  void     selectVSPI() { _useHSPI = false; };
  bool     usesHSPI()   { return _useHSPI;  };
  bool     usesVSPI()   { return !_useHSPI; };

  // to overrule ESP32 default hardware pins
  void     setGPIOpins(uint8_t clock, uint8_t miso, uint8_t mosi, uint8_t select);
  #endif


private:
  uint32_t _read();

  uint8_t  _status;
  float    _temperature;
  float    _offset;
  uint32_t _lastTimeRead;
  uint16_t _rawData;
  bool     _hwSPI;

  uint8_t  _clock;
  uint8_t  _miso;
  uint8_t  _select;

  uint16_t    _swSPIdelay = 0;
  uint32_t    _SPIspeed;
  SPIClass    * mySPI;
  SPISettings _spi_settings;
  #if defined(ESP32)
  bool        _useHSPI = true;
  #endif
};


// -- END OF FILE --
0.1.0 MAX6675 2022-01-12 08:49:49 -05:00			`#pragma once`
			`//`
			`// FILE: MAX6675.h`
			`// AUTHOR: Rob Tillaart`
0.1.1 MAX6675 2022-04-21 03:17:40 -04:00			`// VERSION: 0.1.1`
0.1.0 MAX6675 2022-01-12 08:49:49 -05:00			`// PURPOSE: Arduino library for MAX6675 chip for K type thermocouple`
			`// DATE: 2022-01-12`
			`// URL: https://github.com/RobTillaart/MAX6675`


			`// TODO Breakout board`
			`//`
			`// +---------+`
			`// Vin \| o \|`
			`// 3V3 \| o \|`
			`// GND \| o O \| Thermocouple`
			`// D0 \| o O \| Thermocouple`
			`// CS \| o \|`
			`// CLK \| o \|`
			`// +---------+`

			`#include "Arduino.h"`
			`#include "SPI.h"`


0.1.1 MAX6675 2022-04-21 03:17:40 -04:00			`#define MAX6675_LIB_VERSION (F("0.1.1"))`
0.1.0 MAX6675 2022-01-12 08:49:49 -05:00
			`#define MAX6675_NO_TEMPERATURE -999`

			`// STATE constants returned by read()`
			`// TODO check`
			`#define STATUS_OK 0x00`
			`#define STATUS_ERROR 0x04`
			`#define STATUS_NOREAD 0x80`
			`#define STATUS_NO_COMMUNICATION 0x81`


			`// Thermocouples working is based upon Seebeck effect.`
			`// Different TC have a different Seebeck Coefficient (µV/°C)`
			`// See http://www.analog.com/library/analogDialogue/archives/44-10/thermocouple.html`
			`//`
			`// K_TC == 41.276 µV/°C`


			`class MAX6675`
			`{`
			`public:`

			`MAX6675();`

			`// HW SPI`
			`void begin(uint8_t select);`
			`// SW SPI`
			`void begin(uint8_t clock, uint8_t select, uint8_t miso);`

			`// returns state - bit field: 0 = STATUS_OK`
			`uint8_t read();`
0.1.1 MAX6675 2022-04-21 03:17:40 -04:00			`float getTemperature(void) { return _temperature + _offset; };`
0.1.0 MAX6675 2022-01-12 08:49:49 -05:00
0.1.1 MAX6675 2022-04-21 03:17:40 -04:00			`uint8_t getStatus(void) const { return _status; };`
0.1.0 MAX6675 2022-01-12 08:49:49 -05:00
			`// use offset to calibrate the TC.`
			`void setOffset(const float t) { _offset = t; };`
			`float getOffset() const { return _offset; };`

			`uint32_t lastRead() { return _lastTimeRead; };`
			`uint16_t getRawData() { return _rawData;};`

			`// speed in Hz`
			`void setSPIspeed(uint32_t speed);`
			`uint32_t getSPIspeed() { return _SPIspeed; };`
			`void setSWSPIdelay(uint16_t del = 0) { _swSPIdelay = del; };`
			`uint16_t getSWSPIdelay() { return _swSPIdelay; };`


			`// ESP32 specific`
			`#if defined(ESP32)`
			`void selectHSPI() { _useHSPI = true; };`
			`void selectVSPI() { _useHSPI = false; };`
			`bool usesHSPI() { return _useHSPI; };`
			`bool usesVSPI() { return !_useHSPI; };`

			`// to overrule ESP32 default hardware pins`
			`void setGPIOpins(uint8_t clock, uint8_t miso, uint8_t mosi, uint8_t select);`
			`#endif`


			`private:`
			`uint32_t _read();`

			`uint8_t _status;`
			`float _temperature;`
			`float _offset;`
			`uint32_t _lastTimeRead;`
			`uint16_t _rawData;`
			`bool _hwSPI;`

			`uint8_t _clock;`
			`uint8_t _miso;`
			`uint8_t _select;`

			`uint16_t _swSPIdelay = 0;`
			`uint32_t _SPIspeed;`
			`SPIClass * mySPI;`
			`SPISettings _spi_settings;`
			`#if defined(ESP32)`
			`bool _useHSPI = true;`
			`#endif`
			`};`


			`// -- END OF FILE --`