st-anything/lib/EmonLib/EmonLib.cpp

/*
  Emon.cpp - Library for openenergymonitor
  Created by Trystan Lea, April 27 2010
  GNU GPL
  modified to use up to 12 bits ADC resolution (ex. Arduino Due)
  by boredman@boredomprojects.net 26.12.2013
  Low Pass filter for offset removal replaces HP filter 1/1/2015 - RW
*/

// Proboscide99 10/08/2016 - Added ADMUX settings for ATmega1284 e 1284P (644 / 644P also, but not tested) in readVcc function

//#include "WProgram.h" un-comment for use on older versions of Arduino IDE
#include "EmonLib.h"

#if defined(ARDUINO) && ARDUINO >= 100
#include "Arduino.h"
#else
#include "WProgram.h"
#endif


//--------------------------------------------------------------------------------------
// Sets the pins to be used for voltage and current sensors
//--------------------------------------------------------------------------------------
void EnergyMonitor::voltage(unsigned int _inPinV, double _VCAL, double _PHASECAL)
{
  inPinV = _inPinV;
  VCAL = _VCAL;
  PHASECAL = _PHASECAL;
  offsetV = ADC_COUNTS>>1;
}

void EnergyMonitor::current(unsigned int _inPinI, double _ICAL)
{
  inPinI = _inPinI;
  ICAL = _ICAL;
  offsetI = ADC_COUNTS>>1;
}

//--------------------------------------------------------------------------------------
// Sets the pins to be used for voltage and current sensors based on emontx pin map
//--------------------------------------------------------------------------------------
void EnergyMonitor::voltageTX(double _VCAL, double _PHASECAL)
{
  inPinV = 2;
  VCAL = _VCAL;
  PHASECAL = _PHASECAL;
  offsetV = ADC_COUNTS>>1;
}

void EnergyMonitor::currentTX(unsigned int _channel, double _ICAL)
{
  if (_channel == 1) inPinI = 3;
  if (_channel == 2) inPinI = 0;
  if (_channel == 3) inPinI = 1;
  ICAL = _ICAL;
  offsetI = ADC_COUNTS>>1;
}

//--------------------------------------------------------------------------------------
// emon_calc procedure
// Calculates realPower,apparentPower,powerFactor,Vrms,Irms,kWh increment
// From a sample window of the mains AC voltage and current.
// The Sample window length is defined by the number of half wavelengths or crossings we choose to measure.
//--------------------------------------------------------------------------------------
void EnergyMonitor::calcVI(unsigned int crossings, unsigned int timeout)
{
  #if defined emonTxV3
  int SupplyVoltage=3300;
  #else
  int SupplyVoltage = readVcc();
  #endif

  unsigned int crossCount = 0;                             //Used to measure number of times threshold is crossed.
  unsigned int numberOfSamples = 0;                        //This is now incremented

  //-------------------------------------------------------------------------------------------------------------------------
  // 1) Waits for the waveform to be close to 'zero' (mid-scale adc) part in sin curve.
  //-------------------------------------------------------------------------------------------------------------------------
  unsigned long start = millis();    //millis()-start makes sure it doesnt get stuck in the loop if there is an error.

  while(1)                                   //the while loop...
  {
    startV = analogRead(inPinV);                    //using the voltage waveform
    if ((startV < (ADC_COUNTS*0.55)) && (startV > (ADC_COUNTS*0.45))) break;  //check its within range
    if ((millis()-start)>timeout) break;
  }

  //-------------------------------------------------------------------------------------------------------------------------
  // 2) Main measurement loop
  //-------------------------------------------------------------------------------------------------------------------------
  start = millis();

  while ((crossCount < crossings) && ((millis()-start)<timeout))
  {
    numberOfSamples++;                       //Count number of times looped.
    lastFilteredV = filteredV;               //Used for delay/phase compensation

    //-----------------------------------------------------------------------------
    // A) Read in raw voltage and current samples
    //-----------------------------------------------------------------------------
    sampleV = analogRead(inPinV);                 //Read in raw voltage signal
    sampleI = analogRead(inPinI);                 //Read in raw current signal

    //-----------------------------------------------------------------------------
    // B) Apply digital low pass filters to extract the 2.5 V or 1.65 V dc offset,
    //     then subtract this - signal is now centred on 0 counts.
    //-----------------------------------------------------------------------------
    offsetV = offsetV + ((sampleV-offsetV)/1024);
    filteredV = sampleV - offsetV;
    offsetI = offsetI + ((sampleI-offsetI)/1024);
    filteredI = sampleI - offsetI;

    //-----------------------------------------------------------------------------
    // C) Root-mean-square method voltage
    //-----------------------------------------------------------------------------
    sqV= filteredV * filteredV;                 //1) square voltage values
    sumV += sqV;                                //2) sum

    //-----------------------------------------------------------------------------
    // D) Root-mean-square method current
    //-----------------------------------------------------------------------------
    sqI = filteredI * filteredI;                //1) square current values
    sumI += sqI;                                //2) sum

    //-----------------------------------------------------------------------------
    // E) Phase calibration
    //-----------------------------------------------------------------------------
    phaseShiftedV = lastFilteredV + PHASECAL * (filteredV - lastFilteredV);

    //-----------------------------------------------------------------------------
    // F) Instantaneous power calc
    //-----------------------------------------------------------------------------
    instP = phaseShiftedV * filteredI;          //Instantaneous Power
    sumP +=instP;                               //Sum

    //-----------------------------------------------------------------------------
    // G) Find the number of times the voltage has crossed the initial voltage
    //    - every 2 crosses we will have sampled 1 wavelength
    //    - so this method allows us to sample an integer number of half wavelengths which increases accuracy
    //-----------------------------------------------------------------------------
    lastVCross = checkVCross;
    if (sampleV > startV) checkVCross = true;
                     else checkVCross = false;
    if (numberOfSamples==1) lastVCross = checkVCross;

    if (lastVCross != checkVCross) crossCount++;
  }

  //-------------------------------------------------------------------------------------------------------------------------
  // 3) Post loop calculations
  //-------------------------------------------------------------------------------------------------------------------------
  //Calculation of the root of the mean of the voltage and current squared (rms)
  //Calibration coefficients applied.

  double V_RATIO = VCAL *((SupplyVoltage/1000.0) / (ADC_COUNTS));
  Vrms = V_RATIO * sqrt(sumV / numberOfSamples);

  double I_RATIO = ICAL *((SupplyVoltage/1000.0) / (ADC_COUNTS));
  Irms = I_RATIO * sqrt(sumI / numberOfSamples);

  //Calculation power values
  realPower = V_RATIO * I_RATIO * sumP / numberOfSamples;
  apparentPower = Vrms * Irms;
  powerFactor=realPower / apparentPower;

  //Reset accumulators
  sumV = 0;
  sumI = 0;
  sumP = 0;
//--------------------------------------------------------------------------------------
}

//--------------------------------------------------------------------------------------
double EnergyMonitor::calcIrms(unsigned int Number_of_Samples)
{

  #if defined emonTxV3
    int SupplyVoltage=3300;
  #else
    int SupplyVoltage = readVcc();
  #endif


  for (unsigned int n = 0; n < Number_of_Samples; n++)
  {
    sampleI = analogRead(inPinI);

    // Digital low pass filter extracts the 2.5 V or 1.65 V dc offset,
    //  then subtract this - signal is now centered on 0 counts.
    offsetI = (offsetI + (sampleI-offsetI)/1024);
    filteredI = sampleI - offsetI;

    // Root-mean-square method current
    // 1) square current values
    sqI = filteredI * filteredI;
    // 2) sum
    sumI += sqI;
  }

  double I_RATIO = ICAL *((SupplyVoltage/1000.0) / (ADC_COUNTS));
  Irms = I_RATIO * sqrt(sumI / Number_of_Samples);

  //Reset accumulators
  sumI = 0;
  //--------------------------------------------------------------------------------------

  return Irms;
}

void EnergyMonitor::serialprint()
{
  Serial.print(realPower);
  Serial.print(' ');
  Serial.print(apparentPower);
  Serial.print(' ');
  Serial.print(Vrms);
  Serial.print(' ');
  Serial.print(Irms);
  Serial.print(' ');
  Serial.print(powerFactor);
  Serial.println(' ');
  delay(100);
}

//thanks to http://hacking.majenko.co.uk/making-accurate-adc-readings-on-arduino
//and Jérôme who alerted us to http://provideyourown.com/2012/secret-arduino-voltmeter-measure-battery-voltage/

long EnergyMonitor::readVcc() {
  long result;

  //not used on emonTx V3 - as Vcc is always 3.3V - eliminates bandgap error and need for calibration http://harizanov.com/2013/09/thoughts-on-avr-adc-accuracy/

  #if defined(__AVR_ATmega168__) || defined(__AVR_ATmega328__) || defined (__AVR_ATmega328P__)
  ADMUX = _BV(REFS0) | _BV(MUX3) | _BV(MUX2) | _BV(MUX1);
  #elif defined(__AVR_ATmega644__) || defined(__AVR_ATmega644P__) || defined(__AVR_ATmega1284__) || defined(__AVR_ATmega1284P__)
  ADMUX = _BV(REFS0) | _BV(MUX4) | _BV(MUX3) | _BV(MUX2) | _BV(MUX1);
  #elif defined(__AVR_ATmega32U4__) || defined(__AVR_ATmega1280__) || defined(__AVR_ATmega2560__) || defined(__AVR_AT90USB1286__)
  ADMUX = _BV(REFS0) | _BV(MUX4) | _BV(MUX3) | _BV(MUX2) | _BV(MUX1);
  ADCSRB &= ~_BV(MUX5);   // Without this the function always returns -1 on the ATmega2560 http://openenergymonitor.org/emon/node/2253#comment-11432
  #elif defined (__AVR_ATtiny24__) || defined(__AVR_ATtiny44__) || defined(__AVR_ATtiny84__)
  ADMUX = _BV(MUX5) | _BV(MUX0);
  #elif defined (__AVR_ATtiny25__) || defined(__AVR_ATtiny45__) || defined(__AVR_ATtiny85__)
  ADMUX = _BV(MUX3) | _BV(MUX2);

  #endif


  #if defined(__AVR__)
  delay(2);                                        // Wait for Vref to settle
  ADCSRA |= _BV(ADSC);                             // Convert
  while (bit_is_set(ADCSRA,ADSC));
  result = ADCL;
  result |= ADCH<<8;
  result = READVCC_CALIBRATION_CONST / result;  //1100mV*1024 ADC steps http://openenergymonitor.org/emon/node/1186
  return result;
  #elif defined(__arm__)
  return (3300);                                  //Arduino Due
  #else
  return (3300);                                  //Guess that other un-supported architectures will be running a 3.3V!
  #endif
}
IP Configuration 2023-03-11 14:11:03 +00:00			`/*`
			`Emon.cpp - Library for openenergymonitor`
			`Created by Trystan Lea, April 27 2010`
			`GNU GPL`
			`modified to use up to 12 bits ADC resolution (ex. Arduino Due)`
			`by boredman@boredomprojects.net 26.12.2013`
			`Low Pass filter for offset removal replaces HP filter 1/1/2015 - RW`
			`*/`

			`// Proboscide99 10/08/2016 - Added ADMUX settings for ATmega1284 e 1284P (644 / 644P also, but not tested) in readVcc function`

			`//#include "WProgram.h" un-comment for use on older versions of Arduino IDE`
			`#include "EmonLib.h"`

			`#if defined(ARDUINO) && ARDUINO >= 100`
			`#include "Arduino.h"`
			`#else`
			`#include "WProgram.h"`
			`#endif`


			`//--------------------------------------------------------------------------------------`
			`// Sets the pins to be used for voltage and current sensors`
			`//--------------------------------------------------------------------------------------`
			`void EnergyMonitor::voltage(unsigned int _inPinV, double _VCAL, double _PHASECAL)`
			`{`
			`inPinV = _inPinV;`
			`VCAL = _VCAL;`
			`PHASECAL = _PHASECAL;`
			`offsetV = ADC_COUNTS>>1;`
			`}`

			`void EnergyMonitor::current(unsigned int _inPinI, double _ICAL)`
			`{`
			`inPinI = _inPinI;`
			`ICAL = _ICAL;`
			`offsetI = ADC_COUNTS>>1;`
			`}`

			`//--------------------------------------------------------------------------------------`
			`// Sets the pins to be used for voltage and current sensors based on emontx pin map`
			`//--------------------------------------------------------------------------------------`
			`void EnergyMonitor::voltageTX(double _VCAL, double _PHASECAL)`
			`{`
			`inPinV = 2;`
			`VCAL = _VCAL;`
			`PHASECAL = _PHASECAL;`
			`offsetV = ADC_COUNTS>>1;`
			`}`

			`void EnergyMonitor::currentTX(unsigned int _channel, double _ICAL)`
			`{`
			`if (_channel == 1) inPinI = 3;`
			`if (_channel == 2) inPinI = 0;`
			`if (_channel == 3) inPinI = 1;`
			`ICAL = _ICAL;`
			`offsetI = ADC_COUNTS>>1;`
			`}`

			`//--------------------------------------------------------------------------------------`
			`// emon_calc procedure`
			`// Calculates realPower,apparentPower,powerFactor,Vrms,Irms,kWh increment`
			`// From a sample window of the mains AC voltage and current.`
			`// The Sample window length is defined by the number of half wavelengths or crossings we choose to measure.`
			`//--------------------------------------------------------------------------------------`
			`void EnergyMonitor::calcVI(unsigned int crossings, unsigned int timeout)`
			`{`
			`#if defined emonTxV3`
			`int SupplyVoltage=3300;`
			`#else`
			`int SupplyVoltage = readVcc();`
			`#endif`

			`unsigned int crossCount = 0; //Used to measure number of times threshold is crossed.`
			`unsigned int numberOfSamples = 0; //This is now incremented`

			`//-------------------------------------------------------------------------------------------------------------------------`
			`// 1) Waits for the waveform to be close to 'zero' (mid-scale adc) part in sin curve.`
			`//-------------------------------------------------------------------------------------------------------------------------`
			`unsigned long start = millis(); //millis()-start makes sure it doesnt get stuck in the loop if there is an error.`

			`while(1) //the while loop...`
			`{`
			`startV = analogRead(inPinV); //using the voltage waveform`
			`if ((startV < (ADC_COUNTS0.55)) && (startV > (ADC_COUNTS0.45))) break; //check its within range`
			`if ((millis()-start)>timeout) break;`
			`}`

			`//-------------------------------------------------------------------------------------------------------------------------`
			`// 2) Main measurement loop`
			`//-------------------------------------------------------------------------------------------------------------------------`
			`start = millis();`

			`while ((crossCount < crossings) && ((millis()-start)<timeout))`
			`{`
			`numberOfSamples++; //Count number of times looped.`
			`lastFilteredV = filteredV; //Used for delay/phase compensation`

			`//-----------------------------------------------------------------------------`
			`// A) Read in raw voltage and current samples`
			`//-----------------------------------------------------------------------------`
			`sampleV = analogRead(inPinV); //Read in raw voltage signal`
			`sampleI = analogRead(inPinI); //Read in raw current signal`

			`//-----------------------------------------------------------------------------`
			`// B) Apply digital low pass filters to extract the 2.5 V or 1.65 V dc offset,`
			`// then subtract this - signal is now centred on 0 counts.`
			`//-----------------------------------------------------------------------------`
			`offsetV = offsetV + ((sampleV-offsetV)/1024);`
			`filteredV = sampleV - offsetV;`
			`offsetI = offsetI + ((sampleI-offsetI)/1024);`
			`filteredI = sampleI - offsetI;`

			`//-----------------------------------------------------------------------------`
			`// C) Root-mean-square method voltage`
			`//-----------------------------------------------------------------------------`
			`sqV= filteredV * filteredV; //1) square voltage values`
			`sumV += sqV; //2) sum`

			`//-----------------------------------------------------------------------------`
			`// D) Root-mean-square method current`
			`//-----------------------------------------------------------------------------`
			`sqI = filteredI * filteredI; //1) square current values`
			`sumI += sqI; //2) sum`

			`//-----------------------------------------------------------------------------`
			`// E) Phase calibration`
			`//-----------------------------------------------------------------------------`
			`phaseShiftedV = lastFilteredV + PHASECAL * (filteredV - lastFilteredV);`

			`//-----------------------------------------------------------------------------`
			`// F) Instantaneous power calc`
			`//-----------------------------------------------------------------------------`
			`instP = phaseShiftedV * filteredI; //Instantaneous Power`
			`sumP +=instP; //Sum`

			`//-----------------------------------------------------------------------------`
			`// G) Find the number of times the voltage has crossed the initial voltage`
			`// - every 2 crosses we will have sampled 1 wavelength`
			`// - so this method allows us to sample an integer number of half wavelengths which increases accuracy`
			`//-----------------------------------------------------------------------------`
			`lastVCross = checkVCross;`
			`if (sampleV > startV) checkVCross = true;`
			`else checkVCross = false;`
			`if (numberOfSamples==1) lastVCross = checkVCross;`

			`if (lastVCross != checkVCross) crossCount++;`
			`}`

			`//-------------------------------------------------------------------------------------------------------------------------`
			`// 3) Post loop calculations`
			`//-------------------------------------------------------------------------------------------------------------------------`
			`//Calculation of the root of the mean of the voltage and current squared (rms)`
			`//Calibration coefficients applied.`

			`double V_RATIO = VCAL *((SupplyVoltage/1000.0) / (ADC_COUNTS));`
			`Vrms = V_RATIO * sqrt(sumV / numberOfSamples);`

			`double I_RATIO = ICAL *((SupplyVoltage/1000.0) / (ADC_COUNTS));`
			`Irms = I_RATIO * sqrt(sumI / numberOfSamples);`

			`//Calculation power values`
			`realPower = V_RATIO * I_RATIO * sumP / numberOfSamples;`
			`apparentPower = Vrms * Irms;`
			`powerFactor=realPower / apparentPower;`

			`//Reset accumulators`
			`sumV = 0;`
			`sumI = 0;`
			`sumP = 0;`
			`//--------------------------------------------------------------------------------------`
			`}`

			`//--------------------------------------------------------------------------------------`
			`double EnergyMonitor::calcIrms(unsigned int Number_of_Samples)`
			`{`

			`#if defined emonTxV3`
			`int SupplyVoltage=3300;`
			`#else`
			`int SupplyVoltage = readVcc();`
			`#endif`


			`for (unsigned int n = 0; n < Number_of_Samples; n++)`
			`{`
			`sampleI = analogRead(inPinI);`

			`// Digital low pass filter extracts the 2.5 V or 1.65 V dc offset,`
			`// then subtract this - signal is now centered on 0 counts.`
			`offsetI = (offsetI + (sampleI-offsetI)/1024);`
			`filteredI = sampleI - offsetI;`

			`// Root-mean-square method current`
			`// 1) square current values`
			`sqI = filteredI * filteredI;`
			`// 2) sum`
			`sumI += sqI;`
			`}`

			`double I_RATIO = ICAL *((SupplyVoltage/1000.0) / (ADC_COUNTS));`
			`Irms = I_RATIO * sqrt(sumI / Number_of_Samples);`

			`//Reset accumulators`
			`sumI = 0;`
			`//--------------------------------------------------------------------------------------`

			`return Irms;`
			`}`

			`void EnergyMonitor::serialprint()`
			`{`
			`Serial.print(realPower);`
			`Serial.print(' ');`
			`Serial.print(apparentPower);`
			`Serial.print(' ');`
			`Serial.print(Vrms);`
			`Serial.print(' ');`
			`Serial.print(Irms);`
			`Serial.print(' ');`
			`Serial.print(powerFactor);`
			`Serial.println(' ');`
			`delay(100);`
			`}`

			`//thanks to http://hacking.majenko.co.uk/making-accurate-adc-readings-on-arduino`
			`//and Jérôme who alerted us to http://provideyourown.com/2012/secret-arduino-voltmeter-measure-battery-voltage/`

			`long EnergyMonitor::readVcc() {`
			`long result;`

			`//not used on emonTx V3 - as Vcc is always 3.3V - eliminates bandgap error and need for calibration http://harizanov.com/2013/09/thoughts-on-avr-adc-accuracy/`

			`#if defined(__AVR_ATmega168__) \|\| defined(__AVR_ATmega328__) \|\| defined (__AVR_ATmega328P__)`
			`ADMUX = _BV(REFS0) \| _BV(MUX3) \| _BV(MUX2) \| _BV(MUX1);`
			`#elif defined(__AVR_ATmega644__) \|\| defined(__AVR_ATmega644P__) \|\| defined(__AVR_ATmega1284__) \|\| defined(__AVR_ATmega1284P__)`
			`ADMUX = _BV(REFS0) \| _BV(MUX4) \| _BV(MUX3) \| _BV(MUX2) \| _BV(MUX1);`
			`#elif defined(__AVR_ATmega32U4__) \|\| defined(__AVR_ATmega1280__) \|\| defined(__AVR_ATmega2560__) \|\| defined(__AVR_AT90USB1286__)`
			`ADMUX = _BV(REFS0) \| _BV(MUX4) \| _BV(MUX3) \| _BV(MUX2) \| _BV(MUX1);`
			`ADCSRB &= ~_BV(MUX5); // Without this the function always returns -1 on the ATmega2560 http://openenergymonitor.org/emon/node/2253#comment-11432`
			`#elif defined (__AVR_ATtiny24__) \|\| defined(__AVR_ATtiny44__) \|\| defined(__AVR_ATtiny84__)`
			`ADMUX = _BV(MUX5) \| _BV(MUX0);`
			`#elif defined (__AVR_ATtiny25__) \|\| defined(__AVR_ATtiny45__) \|\| defined(__AVR_ATtiny85__)`
			`ADMUX = _BV(MUX3) \| _BV(MUX2);`

			`#endif`


			`#if defined(__AVR__)`
			`delay(2); // Wait for Vref to settle`
			`ADCSRA \|= _BV(ADSC); // Convert`
			`while (bit_is_set(ADCSRA,ADSC));`
			`result = ADCL;`
			`result \|= ADCH<<8;`
			`result = READVCC_CALIBRATION_CONST / result; //1100mV*1024 ADC steps http://openenergymonitor.org/emon/node/1186`
			`return result;`
			`#elif defined(__arm__)`
			`return (3300); //Arduino Due`
			`#else`
			`return (3300); //Guess that other un-supported architectures will be running a 3.3V!`
			`#endif`
			`}`