// // FILE: DAC8552.cpp // AUTHOR: Rob Tillaart // PURPOSE: Arduino library for DAC8552 SPI Digital Analog Convertor // VERSION: 0.2.4 // URL: https://github.com/RobTillaart/DAC8552 // // HISTORY: see changelog.md #include "DAC8552.h" #define MAXVOLTAGE 5.0 #define MAXVALUE 0xFFFF DAC8552::DAC8552(uint8_t slaveSelect) { _hwSPI = true; _select = slaveSelect; } DAC8552::DAC8552(uint8_t spiData, uint8_t spiClock, uint8_t slaveSelect) { _hwSPI = false; _dataOut = spiData; _clock = spiClock; _select = slaveSelect; } // initializes the SPI // and sets internal state void DAC8552::begin() { pinMode(_select, OUTPUT); digitalWrite(_select, HIGH); _spi_settings = SPISettings(_SPIspeed, MSBFIRST, SPI_MODE1); if(_hwSPI) { #if defined(ESP32) if (_useHSPI) // HSPI { mySPI = new SPIClass(HSPI); mySPI->end(); mySPI->begin(14, 12, 13, _select); // CLK=14 MISO=12 MOSI=13 } else // VSPI { mySPI = new SPIClass(VSPI); mySPI->end(); mySPI->begin(18, 19, 23, _select); // CLK=18 MISO=19 MOSI=23 } #else // generic hardware SPI mySPI = &SPI; mySPI->end(); mySPI->begin(); #endif delay(1); } else // software SPI { pinMode(_dataOut, OUTPUT); pinMode(_clock, OUTPUT); digitalWrite(_dataOut, LOW); digitalWrite(_clock, LOW); } _value[0] = 0; _value[1] = 0; _register[0] = 0x00; _register[1] = 0x40; } #if defined(ESP32) void DAC8552::setGPIOpins(uint8_t clk, uint8_t miso, uint8_t mosi, uint8_t select) { _clock = clk; _dataOut = mosi; _select = select; pinMode(_select, OUTPUT); digitalWrite(_select, HIGH); mySPI->end(); // disable SPI mySPI->begin(clk, miso, mosi, select); } #endif // channel = 0, 1, 2, 3 depending on type // value = 0..65535 void DAC8552::bufferValue(uint8_t channel, uint16_t value) { _value[channel] = value; updateDevice(channel, false); } // channel = 0, 1, 2, 3 depending on type // value = 0..65535 void DAC8552::setValue(uint8_t channel, uint16_t value) { _value[channel] = value; updateDevice(channel, true); } // channel = 0, 1, 2, 3 depending on type // returns 0..65535 uint16_t DAC8552::getValue(uint8_t channel) { return _value[channel]; } void DAC8552::bufferPowerDown(uint8_t channel, uint8_t powerDownMode) { _register[channel] &= 0xFC; _register[channel] |= (powerDownMode & 0x03); updateDevice(channel, false); } void DAC8552::setPowerDown(uint8_t channel, uint8_t powerDownMode) { _register[channel] &= 0xFC; _register[channel] |= (powerDownMode & 0x03); updateDevice(channel, true); } uint8_t DAC8552::getPowerDownMode(uint8_t channel) { return _register[channel] & 0x03; } void DAC8552::setSPIspeed(uint32_t speed) { _SPIspeed = speed; _spi_settings = SPISettings(_SPIspeed, MSBFIRST, SPI_MODE1); }; ////////////////////////////////////////////////////////////////// // // PRIVATE // // channel = 0, 1, 2, 3 depending on type // direct = true ==> write buffers to both channel A and channel B // direct = false ==> buffer value void DAC8552::updateDevice(uint8_t channel, bool directWrite) { uint8_t configRegister = _register[channel]; if (directWrite) configRegister |= 0x30; digitalWrite(_select, LOW); if (_hwSPI) { mySPI->beginTransaction(_spi_settings); mySPI->transfer(configRegister); mySPI->transfer(_value[channel] >> 8); mySPI->transfer(_value[channel] & 0xFF); mySPI->endTransaction(); } else // Software SPI { swSPI_transfer(configRegister); swSPI_transfer(_value[channel] >> 8); swSPI_transfer(_value[channel] & 0xFF); } digitalWrite(_select, HIGH); } // simple one mode version void DAC8552::swSPI_transfer(uint8_t value) { uint8_t clk = _clock; uint8_t dao = _dataOut; for (uint8_t mask = 0x80; mask; mask >>= 1) { digitalWrite(dao,(value & mask)); digitalWrite(clk, HIGH); digitalWrite(clk, LOW); } } // -- END OF FILE --