GY-63_MS5611/libraries/AD985X/AD985X.cpp
2021-10-16 22:10:27 +02:00

368 lines
7.7 KiB
C++
Raw Blame History

This file contains ambiguous Unicode characters

This file contains Unicode characters that might be confused with other characters. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

//
// FILE: AD985X.cpp
// AUTHOR: Rob Tillaart
// VERSION: 0.3.2
// DATE: 2019-02-08
// PURPOSE: Class for AD9850 and AD9851 function generator
//
// HISTORY:
// 0.1.0 2019-03-19 initial version
// 0.1.1 2020-12-09 add arduino-ci
// 0.1.2 2020-12-27 add setAutoMode() + offset
// 0.2.0 2020-12-28 major refactor class hierarchy + float frequency
// 0.2.1 2021-01-10 add get- and setARCCutOffFreq()
// 0.2.2 2021-01-24 add manual updating frequency
// get- setManualFQ_UD(), update()
// inverted SELECT line as preparation for multidevice.
// 0.3.0 2021-06-06 fix factory bit mask + new examples + some refactor
// added multi device document
// 0.3.1 2021-08-25 VSPI / HSPI support for ESP32
// faster software SPI
// minor optimizations / refactor
// 0.3.2 2021-10-16 update build-ci
#include "AD985X.h"
// UNO HARDWARE SPI PINS
#define SPI_CLOCK 13
#define SPI_MISO 12
#define SPI_MOSI 11
#define AD985X_POWERDOWN 0x04
////////////////////////////////////////////////////////
//
// AD9850
//
AD9850::AD9850()
{
}
void AD9850::begin(uint8_t select, uint8_t resetPin, uint8_t FQUDPin, uint8_t dataOut , uint8_t clock)
{
_select = select;
_reset = resetPin;
_fqud = FQUDPin;
_dataOut = dataOut;
_clock = clock;
// following 3 are always set.
pinMode(_select, OUTPUT);
pinMode(_reset, OUTPUT);
pinMode(_fqud, OUTPUT);
// device select = HIGH See - https://github.com/RobTillaart/AD985X/issues/13
digitalWrite(_select, LOW);
digitalWrite(_reset, LOW);
digitalWrite(_fqud, LOW);
_hwSPI = ((dataOut == 0) || (clock == 0));
_spi_settings = SPISettings(2000000, LSBFIRST, SPI_MODE0);
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
}
else // software SPI
{
pinMode(_dataOut, OUTPUT);
pinMode(_clock, OUTPUT);
digitalWrite(_dataOut, LOW);
digitalWrite(_clock, LOW);
}
reset();
}
#if defined(ESP32)
void AD9850::setGPIOpins(uint8_t clk, uint8_t miso, uint8_t mosi, uint8_t select)
{
_clock = clk;
_dataOut = mosi;
_select = select;
pinMode(_select, OUTPUT);
digitalWrite(_select, LOW);
mySPI->end(); // disable SPI
mySPI->begin(clk, miso, mosi, select);
}
#endif
void AD9850::reset()
{
// be sure to select the correct device
digitalWrite(_select, HIGH);
pulsePin(_reset);
if (_hwSPI) pulsePin(SPI_CLOCK);
else pulsePin(_clock);
digitalWrite(_select, LOW);
_config = 0; // 0 phase no power down
_freq = 0;
_factor = 0;
_offset = 0;
_autoUpdate = true;
writeData();
}
void AD9850::powerDown()
{
_config |= AD985X_POWERDOWN; // keep phase and REFCLK as is.
writeData();
}
void AD9850::powerUp()
{
_config &= ~AD985X_POWERDOWN;
writeData();
}
void AD9850::setPhase(uint8_t phase)
{
if (phase > 31) return;
_config &= 0x07;
_config |= (phase << 3);
writeData();
}
void AD9850::pulsePin(uint8_t pin)
{
digitalWrite(pin, HIGH);
digitalWrite(pin, LOW);
}
void AD9850::setSPIspeed(uint32_t speed)
{
_SPIspeed = speed;
_spi_settings = SPISettings(_SPIspeed, LSBFIRST, SPI_MODE0);
};
void AD9850::writeData()
{
// Serial.println(_factor, HEX);
// Serial.println(_config, HEX);
uint32_t data = _factor;
// used for multidevice config only - https://github.com/RobTillaart/AD985X/issues/13
digitalWrite(_select, HIGH);
if (_hwSPI)
{
mySPI->beginTransaction(_spi_settings);
mySPI->transfer(data & 0xFF);
data >>= 8;
mySPI->transfer(data & 0xFF);
data >>= 8;
mySPI->transfer(data & 0xFF);
mySPI->transfer(data >> 8);
mySPI->transfer(_config & 0xFC); // mask factory test bit
mySPI->endTransaction();
}
else
{
swSPI_transfer(data & 0xFF);
data >>= 8;
swSPI_transfer(data & 0xFF);
data >>= 8;
swSPI_transfer(data & 0xFF);
swSPI_transfer(data >> 8);
swSPI_transfer(_config & 0xFC); // mask factory test bit
}
digitalWrite(_select, LOW);
// update frequency + phase + control bits.
// should at least be 4 ns delay - P14 datasheet
if (_autoUpdate) update();
}
// simple one mode version
void AD9850::swSPI_transfer(uint8_t val)
{
uint8_t clk = _clock;
uint8_t dao = _dataOut;
// for (uint8_t mask = 0x80; mask; mask >>= 1) // MSBFIRST
for (uint8_t mask = 0x01; mask; mask <<= 1) // LSBFIRST
{
digitalWrite(dao, (val & mask));
digitalWrite(clk, HIGH);
digitalWrite(clk, LOW);
}
}
void AD9850::setFrequency(uint32_t freq)
{
// freq OUT = (Δ Phase × CLKIN)/2^32
// 64 bit math to keep precision to the max
if (freq > AD9850_MAX_FREQ) freq = AD9850_MAX_FREQ;
// _factor = round(freq * 34.359738368); // 4294967296 / 125000000
_factor = (147573952589ULL * freq) >> 32;
_freq = freq;
_factor += _offset;
writeData();
}
// especially for lower frequencies (with decimals)
void AD9850::setFrequencyF(float freq)
{
// freq OUT = (Δ Phase × CLKIN)/2^32
// 64 bit math to keep precision to the max
if (freq > AD9850_MAX_FREQ) freq = AD9850_MAX_FREQ;
_factor = round(freq * 34.359738368); // 4294967296 / 125000000
_freq = freq;
_factor += _offset;
writeData();
}
void AD9850::update()
{
digitalWrite(_select, HIGH);
pulsePin(_fqud);
digitalWrite(_select, LOW);
}
////////////////////////////////////////////////////////
//
// AD9851
//
#define AD9851_REFCLK 0x01 // bit is a 6x multiplier bit P.14 datasheet
void AD9851::setFrequency(uint32_t freq)
{
// PREVENT OVERFLOW
if (freq > AD9851_MAX_FREQ) freq = AD9851_MAX_FREQ;
// AUTO SWITCH REFERENCE FREQUENCY
if (_autoRefClock)
{
if (freq > _ARCCutOffFreq)
{
_config |= AD9851_REFCLK;
}
else
{
_config &= ~AD9851_REFCLK;
}
}
if (_config & AD9851_REFCLK) // 6x 30 = 180 MHz
{
_factor = (102481911520ULL * freq) >> 32; // (1 << 64) / 180000000
}
else // 1x 30 = 30 MHz
{
_factor = (614891469123ULL * freq) >> 32; // (1 << 64) / 30000000
}
_freq = freq;
_factor += _offset;
writeData();
}
// especially for lower frequencies (with decimals)
void AD9851::setFrequencyF(float freq)
{
// PREVENT OVERFLOW
if (freq > AD9851_MAX_FREQ) freq = AD9851_MAX_FREQ;
// AUTO SWITCH REFERENCE FREQUENCY
if (_autoRefClock)
{
if (freq > _ARCCutOffFreq)
{
_config |= AD9851_REFCLK;
}
else
{
_config &= ~AD9851_REFCLK;
}
}
if (_config & AD9851_REFCLK) // 6x 30 = 180 MHz
{
_factor = uint64_t(102481911520ULL * freq) >> 32; // (1 << 64) / 180000000
}
else // 1x 30 = 30 MHz
{
_factor = (6148914691ULL * uint64_t (100 * freq)) >> 32;
}
_freq = freq;
_factor += _offset;
writeData();
}
////////////////////////////////////////////////////////
//
// AD9851 - AUTO REFERENCE CLOCK
//
void AD9851::setAutoRefClock(bool arc)
{
_autoRefClock = arc;
setFrequency(_freq);
};
void AD9851::setRefClockHigh()
{
_config |= AD9851_REFCLK;
setFrequency(_freq);
}
void AD9851::setRefClockLow()
{
_config &= ~AD9851_REFCLK;
setFrequency(_freq);
}
uint8_t AD9851::getRefClock()
{
return (_config & AD9851_REFCLK) ? 180 : 30;
}
void AD9851::setARCCutOffFreq(uint32_t Hz)
{
if (Hz > 30000000UL) Hz = 30000000;
_ARCCutOffFreq = Hz;
};
// -- END OF FILE --