#pragma once // // FILE: MAX31855.h // AUTHOR: Rob Tillaart // VERSION: 0.4.2 // PURPOSE: Arduino library for MAX31855 chip for K type thermocouple // DATE: 2014-01-01 // URL: https://github.com/RobTillaart/MAX31855_RT // http://forum.arduino.cc/index.php?topic=208061 // 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 MAX31855_VERSION (F("0.4.2")) #define MAX31855_NO_TEMPERATURE -999 // STATE constants returned by read() #define STATUS_OK 0x00 #define STATUS_OPEN_CIRCUIT 0x01 #define STATUS_SHORT_TO_GND 0x02 #define STATUS_SHORT_TO_VCC 0x04 #define STATUS_ERROR 0x07 #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 // // As the MAX31855 is designed for K type sensors, one can calculate // the factor needed to convert other sensors measurements. // NOTE: this is only a linear approximation. // // Seebeck Coefficients (sensitivity) from the MAX31855 datasheet page 8 // to be used in setSeebeckCoefficient() // // TYPE COEFFICIENT #define E_TC 76.373 #define J_TC 57.953 #define K_TC 41.276 #define N_TC 36.256 #define R_TC 10.506 #define S_TC 9.587 #define T_TC 52.18 class MAX31855 { public: MAX31855(); // 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 getInternal(void) const { return _internal; } float getTemperature(void); uint8_t getStatus(void) const { return _status; }; inline bool openCircuit() { return _status == STATUS_OPEN_CIRCUIT; }; inline bool shortToGND() { return _status == STATUS_SHORT_TO_GND; }; inline bool shortToVCC() { return _status == STATUS_SHORT_TO_VCC; }; inline bool genericError() { return _status == STATUS_ERROR; }; inline bool noRead() { return _status == STATUS_NOREAD; }; inline bool noCommunication() { return _status == STATUS_NO_COMMUNICATION; }; // use offset to calibrate the TC. void setOffset(const float t) { _offset = t; }; float getOffset() const { return _offset; }; // set the above E_TC or other Seebeck Coefficients // one can also set your own optimized values. void setSeebeckCoefficient(const float SC) { _SeebeckC = SC; }; float getSeebeckCoefficient() const { return _SeebeckC; }; uint32_t lastRead() { return _lastTimeRead; }; uint32_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 _internal; float _temperature; float _offset; float _SeebeckC; uint32_t _lastTimeRead; uint32_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 --