// // FILE: ACS712.cpp // AUTHOR: Rob Tillaart, Pete Thompson // VERSION: 0.3.8 // DATE: 2020-08-02 // PURPOSE: ACS712 library - current measurement // URL: https://github.com/RobTillaart/ACS712 #include "ACS712.h" // CONSTRUCTOR ACS712::ACS712(uint8_t analogPin, float volts, uint16_t maxADC, float mVperAmpere) { _pin = analogPin; _mVperAmpere = mVperAmpere; _formFactor = ACS712_FF_SINUS; _noisemV = ACS712_DEFAULT_NOISE; // 21mV according to datasheet // set in setADC() // keep it here until after experimental. _maxADC = maxADC; _mVperStep = 1000.0 * volts / maxADC; // 1x 1000 for V -> mV _mAPerStep = 1000.0 * _mVperStep / _mVperAmpere; _midPoint = maxADC / 2; // default ADC is internal. setADC(NULL, volts, maxADC); } // MEASUREMENTS float ACS712::mA_peak2peak(float frequency, uint16_t cycles) { uint16_t period = round(1000000UL / frequency); if (cycles == 0) cycles = 1; float sum = 0; for (uint16_t i = 0; i < cycles; i++) { int minimum, maximum; // Better than using midPoint minimum = maximum = _analogRead(_pin); // find minimum and maximum uint32_t start = micros(); while (micros() - start < period) // UNO ~180 samples... { int value = _analogRead(_pin); if (_suppresNoise) // average 2 samples. { value = (value + _analogRead(_pin))/2; } // determine extremes if (value < minimum) minimum = value; else if (value > maximum) maximum = value; } sum += (maximum - minimum); } float peak2peak = sum * _mAPerStep; if (cycles > 1) peak2peak /= cycles; return peak2peak; } float ACS712::mA_AC(float frequency, uint16_t cycles) { uint16_t period = round(1000000UL / frequency); if (cycles == 0) cycles = 1; float sum = 0; // remove float operation from loop. uint16_t zeroLevel = round(_noisemV/_mVperStep); for (uint16_t i = 0; i < cycles; i++) { uint16_t samples = 0; uint16_t zeros = 0; int _min, _max; _min = _max = _analogRead(_pin); // find minimum and maximum and count the zero-level "percentage" uint32_t start = micros(); while (micros() - start < period) // UNO ~180 samples... { samples++; int value = _analogRead(_pin); if (_suppresNoise) // average 2 samples. { value = (value + _analogRead(_pin))/2; } // determine extremes if (value < _min) _min = value; else if (value > _max) _max = value; // count zeros if (abs(value - _midPoint) <= zeroLevel ) zeros++; } int peak2peak = _max - _min; // automatic determine _formFactor / crest factor float D = 0; float FF = 0; if (zeros > samples * 0.025) // more than 2% zero's { D = 1.0 - (1.0 * zeros) / samples; // % SAMPLES NONE ZERO FF = sqrt(D) * _formFactor; // ASSUME NON ZERO PART ~ SINUS } else // # zeros is small => D --> 1 --> sqrt(D) --> 1 { FF = _formFactor; } // value could be partially pre-calculated: C = 1000.0 * 0.5 * _mVperStep / _mVperAmpere; // return 1000.0 * 0.5 * peak2peak * _mVperStep * _formFactor / _mVperAmpere); sum += peak2peak * FF; } float mA = 0.5 * sum * _mAPerStep; if (cycles > 1) mA /= cycles; return mA; } float ACS712::mA_AC_sampling(float frequency, uint16_t cycles) { uint32_t period = round(1000000UL / frequency); if (cycles == 0) cycles = 1; float sum = 0; // float noiseLevel = _noisemV/_mVperStep; for (uint16_t i = 0; i < cycles; i++) { uint16_t samples = 0; float sumSquared = 0; uint32_t start = micros(); while (micros() - start < period) { samples++; int value = _analogRead(_pin); if (_suppresNoise) // average 2 samples. { value = (value + _analogRead(_pin))/2; } float current = value - _midPoint; sumSquared += (current * current); // not adding noise squared might be more correct for small currents. // if (abs(current) > noiseLevel) // { // sumSquared += (current * current); // } } sum += sqrt(sumSquared / samples); } float mA = sum * _mAPerStep; if (cycles > 1) mA /= cycles; return mA; } float ACS712::mA_DC(uint16_t cycles) { // read at least twice to stabilize the ADC _analogRead(_pin); if (cycles == 0) cycles = 1; float sum = 0; for (uint16_t i = 0; i < cycles; i++) { int value = _analogRead(_pin); if (_suppresNoise) // average 2 samples. { value = (value + _analogRead(_pin))/2; } sum += (value - _midPoint); } float mA = sum * _mAPerStep; if (cycles > 1) mA /= cycles; return mA; } // CALIBRATION MIDPOINT uint16_t ACS712::setMidPoint(uint16_t midPoint) { if (midPoint <= _maxADC) _midPoint = (int) midPoint; return _midPoint; }; uint16_t ACS712::getMidPoint() { return _midPoint; }; uint16_t ACS712::incMidPoint() { if (_midPoint < (int)(_maxADC)) _midPoint += 1; return _midPoint; }; uint16_t ACS712::decMidPoint() { if (_midPoint > 0) _midPoint -= 1; return _midPoint; }; // configure by sampling for 2 cycles of AC // Also works for DC as long as no current flowing // note this is blocking! uint16_t ACS712::autoMidPoint(float frequency, uint16_t cycles) { uint16_t twoPeriods = round(2000000UL / frequency); if (cycles == 0) cycles = 1; uint32_t total = 0; for (uint16_t i = 0; i < cycles; i++) { uint32_t subTotal = 0; uint32_t samples = 0; uint32_t start = micros(); while (micros() - start < twoPeriods) { uint16_t reading = _analogRead(_pin); subTotal += reading; samples++; // Delaying prevents overflow // since we'll perform a maximum of 40,000 reads @ 50 Hz. delayMicroseconds(1); } total += (subTotal / samples); } _midPoint = (total + (cycles/2))/ cycles; // rounding. return _midPoint; } uint16_t ACS712::autoMidPointDC(uint16_t cycles) { if (cycles == 0) cycles = 1; uint32_t total = 0; for (uint16_t i = 0; i < cycles; i++) { total += analogRead(_pin); } _midPoint = (total + (cycles/2))/ cycles; // rounding. return _midPoint; } uint16_t ACS712::resetMidPoint() { _midPoint = _maxADC / 2; return _midPoint; }; // CALIBRATION FORM FACTOR void ACS712::setFormFactor(float formFactor) { _formFactor = formFactor; }; float ACS712::getFormFactor() { return _formFactor; }; // CALIBRATION NOISE // noise defaults 21 datasheet void ACS712::setNoisemV(uint8_t noisemV) { _noisemV = noisemV; }; uint8_t ACS712::getNoisemV() { return _noisemV; }; float ACS712::mVNoiseLevel(float frequency, uint16_t cycles) { float mA = mA_peak2peak(frequency, cycles); // divide by 2 as the level is half of the peak to peak range return mA * _mVperAmpere * 0.001 / 2; } void ACS712::suppressNoise(bool flag) { _suppresNoise = flag; } // CALIBRATION mV PER AMP // Adjusting resolution AC and DC void ACS712::setmVperAmp(float mVperAmpere) { _mVperAmpere = mVperAmpere; _mAPerStep = 1000.0 * _mVperStep / _mVperAmpere; }; float ACS712::getmVperAmp() { return _mVperAmpere; }; float ACS712::getmAPerStep() { return _mAPerStep; }; float ACS712::getAmperePerStep() { return _mAPerStep * 0.001; }; // FREQUENCY DETECTION // uses oversampling and averaging to minimize variation // blocks for substantial amount of time, depending on minimalFrequency float ACS712::detectFrequency(float minimalFrequency) { int maximum = 0; int minimum = 0; maximum = minimum = _analogRead(_pin); // determine maxima uint32_t timeOut = round(1000000.0 / minimalFrequency); uint32_t start = micros(); while (micros() - start < timeOut) { int value = _analogRead(_pin); if (value > maximum) maximum = value; if (value < minimum) minimum = value; } // calculate quarter points // using quarter points is less noise prone than using one single midpoint int Q1 = (3 * minimum + maximum ) / 4; int Q3 = (minimum + 3 * maximum ) / 4; // 10x passing Quantile points // wait for the right moment to start // to prevent endless loop a timeout is checked. timeOut *= 10; start = micros(); // casting to int to keep compiler happy. while ((int(_analogRead(_pin)) > Q1) && ((micros() - start) < timeOut)); while ((int(_analogRead(_pin)) <= Q3) && ((micros() - start) < timeOut)); start = micros(); for (int i = 0; i < 10; i++) { while ((int(_analogRead(_pin)) > Q1) && ((micros() - start) < timeOut)); while ((int(_analogRead(_pin)) <= Q3) && ((micros() - start) < timeOut)); } uint32_t stop = micros(); // calculate frequency float wavelength = stop - start; float frequency = 1e7 / wavelength; if (_microsAdjust != 1.0) frequency *= _microsAdjust; return frequency; } // timing for FREQUENCY DETECTION void ACS712::setMicrosAdjust(float factor) { _microsAdjust = factor; }; float ACS712::getMicrosAdjust() { return _microsAdjust; }; // DEBUG uint16_t ACS712::getMinimum(uint16_t milliSeconds) { uint16_t minimum = _analogRead(_pin); // find minimum uint32_t start = millis(); while (millis() - start < milliSeconds) { uint16_t value = _analogRead(_pin); if (value < minimum) minimum = value; } return minimum; } uint16_t ACS712::getMaximum(uint16_t milliSeconds) { uint16_t maximum = _analogRead(_pin); // find maximum uint32_t start = millis(); while (millis() - start < milliSeconds) { uint16_t value = _analogRead(_pin); if (value > maximum) maximum = value; } return maximum; } void ACS712::setADC(uint16_t (* f)(uint8_t), float volts, uint16_t maxADC) { _readADC = f; _maxADC = maxADC; _mVperStep = 1000.0 * volts / maxADC; // 1x 1000 for V -> mV _mAPerStep = 1000.0 * _mVperStep / _mVperAmpere; _midPoint = maxADC / 2; } ////////////////////////////////////////////////////////////////////// // // PRIVATE // uint16_t ACS712::_analogRead(uint8_t pin) { // if external ADC is defined use it. if (_readADC != NULL) return _readADC(pin); return analogRead(pin); } // -- END OF FILE --