Improve EMON sensors

6 years ago · 2d37a53e2a
--- a/code/espurna/config/general.h
+++ b/code/espurna/config/general.h
@ -677,8 +677,8 @@ PROGMEM const char* const custom_reset_string[] = {
 #define I2C_SCL_PIN             SCL         // SCL GPIO (Sonoff => 14)
 #endif

 #define I2C_CLOCK_STRETCH_TIME  50000       // BRZO clock stretch time
 #define I2C_SCL_FREQUENCY       200         // BRZO SCL frequency
 #define I2C_CLOCK_STRETCH_TIME  200         // BRZO clock stretch time
 #define I2C_SCL_FREQUENCY       1000        // BRZO SCL frequency
 #define I2C_CLEAR_BUS           0           // Clear I2C bus at boot

 // -----------------------------------------------------------------------------
@ -773,7 +773,7 @@ PROGMEM const char* const custom_reset_string[] = {
 #define SENSOR_VOLTAGE_DECIMALS         0
 #define SENSOR_POWER_DECIMALS           0
 #define SENSOR_POWER_FACTOR_DECIMALS    0
 #define SENSOR_ENERGY_DECIMALS          3
 #define SENSOR_ENERGY_DECIMALS          0

 #define SENSOR_UNKNOWN_TOPIC            "unknown"
 #define SENSOR_TEMPERATURE_TOPIC        "temperature"
--- a/code/espurna/config/sensors.h
+++ b/code/espurna/config/sensors.h
@ -142,10 +142,9 @@
 // Energy Monitor
 //--------------------------------------------------------------------------------

 #define EMON_FILTER_SPEED        512

 #define EMON_MODE_SAMPLES        1
 #define EMON_MODE_MSECONDS       2
 #define EMON_MAX_SAMPLES            1500        // Max number of samples to get
 #define EMON_MAX_TIME               200         // Max time in ms to sample
 #define EMON_MAINS_VOLTAGE          230         // Mains voltage

 //--------------------------------------------------------------------------------
 // Energy Monitor based on interval analog GPIO
@ -156,20 +155,13 @@
 #define EMON_ANALOG_SUPPORT             0       // Do not build support by default
 #endif

 #define EMON_ANALOG_MAINS_VOLTAGE       230     // Mains voltage
 #define EMON_ANALOG_CURRENT_RATIO       30      // Current ratio in the clamp (30V/1A)
 #define EMON_ANALOG_ADC_BITS            10      // ADC depth
 #define EMON_ANALOG_REFERENCE_VOLTAGE   3.3     // Reference voltage of the ADC

 #define EMON_ANALOG_READ_VALUE          1000
 #define EMON_ANALOG_READ_MODE           EMON_MODE_SAMPLES

 #define EMON_ANALOG_WARMUP_VALUE        1000
 #define EMON_ANALOG_WARMUP_MODE         EMON_MODE_MSECONDS

 #if EMON_ANALOG_SUPPORT
    #undef ADC_VCC_ENABLED
    #define ADC_VCC_ENABLED         0
    #define ADC_VCC_ENABLED             0
 #endif

 //--------------------------------------------------------------------------------
@ -188,12 +180,6 @@
 #define EMON_ADC121_ADC_BITS            12      // ADC depth
 #define EMON_ADC121_REFERENCE_VOLTAGE   3.3     // Reference voltage of the ADC

 #define EMON_ADC121_READ_VALUE          200
 #define EMON_ADC121_READ_MODE           EMON_MODE_MSECONDS

 #define EMON_ADC121_WARMUP_VALUE        1000
 #define EMON_ADC121_WARMUP_MODE         EMON_MODE_MSECONDS

 //--------------------------------------------------------------------------------
 // Internal power montior
 // Enable support by passing ADC_VCC_ENABLED=1 build flag
--- a/code/espurna/power_emon.ino
+++ b/code/espurna/power_emon.ino
@ -53,7 +53,7 @@ unsigned int currentCallback() {

        #if I2C_USE_BRZO
            uint8_t buffer[2];
            i2cStart(ADC121_I2C_ADDRESS);
            brzo_i2c_start_transaction(ADC121_I2C_ADDRESS, I2C_SCL_FREQUENCY);
            buffer[0] = ADC121_REG_RESULT;
            brzo_i2c_write(buffer, 1, false);
            brzo_i2c_read(buffer, 2, false);
--- a/code/espurna/sensor.ino
+++ b/code/espurna/sensor.ino
@ -240,12 +240,12 @@ void sensorInit() {

    #if EMON_ANALOG_SUPPORT
        #include "sensors/EmonAnalogSensor.h"
        sensorRegister(new EmonAnalogSensor(A0, EMON_ANALOG_MAINS_VOLTAGE, EMON_ANALOG_ADC_BITS, EMON_ANALOG_REFERENCE_VOLTAGE, EMON_ANALOG_CURRENT_RATIO));
        sensorRegister(new EmonAnalogSensor(A0, EMON_MAINS_VOLTAGE, EMON_ANALOG_ADC_BITS, EMON_ANALOG_REFERENCE_VOLTAGE, EMON_ANALOG_CURRENT_RATIO));
    #endif

    #if EMON_ADC121_SUPPORT
        #include "sensors/EmonADC121Sensor.h"
        sensorRegister(new EmonADC121Sensor(EMON_ADC121_I2C_ADDRESS, EMON_ANALOG_MAINS_VOLTAGE, EMON_ANALOG_ADC_BITS, EMON_ANALOG_REFERENCE_VOLTAGE, EMON_ANALOG_CURRENT_RATIO));
        sensorRegister(new EmonADC121Sensor(EMON_ADC121_I2C_ADDRESS, EMON_MAINS_VOLTAGE, EMON_ADC121_ADC_BITS, EMON_ADC121_REFERENCE_VOLTAGE, EMON_ADC121_CURRENT_RATIO));
    #endif

    #if COUNTER_SUPPORT
--- a/code/espurna/sensors/EmonADC121Sensor.h
+++ b/code/espurna/sensors/EmonADC121Sensor.h
@ -32,6 +32,7 @@ class EmonADC121Sensor : public EmonSensor {

            // Cache
            _address = address;
            _count = 4;

            // Init sensor
            #if I2C_USE_BRZO
@ -49,7 +50,7 @@ class EmonADC121Sensor : public EmonSensor {
            #endif

            // warmup
            read(EMON_ADC121_WARMUP_VALUE, EMON_ADC121_WARMUP_MODE, _address);
            read(_address);

        }

@ -70,6 +71,8 @@ class EmonADC121Sensor : public EmonSensor {
            _error = SENSOR_ERROR_OK;
            if (index == 0) return MAGNITUDE_CURRENT;
            if (index == 1) return MAGNITUDE_POWER_APPARENT;
            if (index == 2) return MAGNITUDE_ENERGY;
            if (index == 3) return MAGNITUDE_ENERGY_DELTA;
            _error = SENSOR_ERROR_OUT_OF_RANGE;
            return MAGNITUDE_NONE;
        }
@ -82,13 +85,19 @@ class EmonADC121Sensor : public EmonSensor {
            // Cache the value
            static unsigned long last = 0;
            static double current = 0;
            static unsigned long energy_delta = 0;

            if ((last == 0) || (millis() - last > 1000)) {
                current = read(EMON_ADC121_READ_VALUE, EMON_ADC121_READ_MODE, _address);
                current = read(_address);
                energy_delta = current * _voltage * (millis() - last) / 1000;
                _energy += energy_delta;
                last = millis();
            }

            if (index == 0) return current;
            if (index == 1) return current * _voltage;
            if (index == 2) return _energy;
            if (index == 3) return energy_delta;

            _error = SENSOR_ERROR_OUT_OF_RANGE;
            return 0;
@ -124,6 +133,7 @@ class EmonADC121Sensor : public EmonSensor {
        }

        unsigned char _address;
        unsigned long _energy = 0;


 };
--- a/code/espurna/sensors/EmonAnalogSensor.h
+++ b/code/espurna/sensors/EmonAnalogSensor.h
@ -16,12 +16,13 @@ class EmonAnalogSensor : public EmonSensor {

            // Cache
            _gpio = gpio;
            _count = 4;

            // Prepare GPIO
            pinMode(gpio, INPUT);

            // warmup
            read(EMON_ANALOG_WARMUP_VALUE, EMON_ANALOG_WARMUP_MODE, _gpio);
            read(_gpio);

        }

@ -42,6 +43,8 @@ class EmonAnalogSensor : public EmonSensor {
            _error = SENSOR_ERROR_OK;
            if (index == 0) return MAGNITUDE_CURRENT;
            if (index == 1) return MAGNITUDE_POWER_APPARENT;
            if (index == 2) return MAGNITUDE_ENERGY;
            if (index == 3) return MAGNITUDE_ENERGY_DELTA;
            _error = SENSOR_ERROR_OUT_OF_RANGE;
            return MAGNITUDE_NONE;
        }
@ -54,13 +57,19 @@ class EmonAnalogSensor : public EmonSensor {
            // Cache the value
            static unsigned long last = 0;
            static double current = 0;
            static unsigned long energy_delta = 0;

            if ((last == 0) || (millis() - last > 1000)) {
                current = read(EMON_ANALOG_READ_VALUE, EMON_ANALOG_READ_MODE, _gpio);
                current = read(_gpio);
                energy_delta = current * _voltage * (millis() - last) / 1000;
                _energy += energy_delta;
                last = millis();
            }

            if (index == 0) return current;
            if (index == 1) return current * _voltage;
            if (index == 2) return _energy;
            if (index == 3) return energy_delta;

            _error = SENSOR_ERROR_OUT_OF_RANGE;
            return 0;
@ -74,6 +83,7 @@ class EmonAnalogSensor : public EmonSensor {
        }

        unsigned char _gpio;
        unsigned long _energy = 0;


 };
--- a/code/espurna/sensors/EmonSensor.h
+++ b/code/espurna/sensors/EmonSensor.h
@ -7,7 +7,7 @@
 #include "Arduino.h"
 #include "BaseSensor.h"

 #define EMON_DEBUG      1
 #define EMON_DEBUG      0

 class EmonSensor : public BaseSensor {

@ -19,7 +19,6 @@ class EmonSensor : public BaseSensor {
            _voltage = voltage;
            _adc_counts = 1 << bits;
            _pivot = _adc_counts >> 1;
            _count = 2;

            // Calculate factor
            _current_factor = ratio * ref / _adc_counts;
@ -30,7 +29,7 @@ class EmonSensor : public BaseSensor {
            #if EMON_DEBUG
                Serial.print("[EMON] Current ratio: "); Serial.println(ratio);
                Serial.print("[EMON] Ref. Voltage: "); Serial.println(_voltage);
                Serial.print("[EMON] ADC Couns: "); Serial.println(_adc_counts);
                Serial.print("[EMON] ADC Counts: "); Serial.println(_adc_counts);
                Serial.print("[EMON] Current factor: "); Serial.println(_current_factor);
                Serial.print("[EMON] Multiplier: "); Serial.println(_multiplier);
            #endif
@ -53,7 +52,7 @@ class EmonSensor : public BaseSensor {
            }
        }

        double read(unsigned long value, unsigned char mode, unsigned char port) {
        double read(unsigned char port) {

            int sample;
            int max = 0;
@ -61,10 +60,8 @@ class EmonSensor : public BaseSensor {
            double filtered;
            double sum = 0;

            unsigned long start = millis();
            unsigned long samples = 0;

            while (true) {
            unsigned long time_span = millis();
            for (unsigned long i=0; i<_samples; i++) {

                // Read analog value
                sample = readADC(port);
@ -72,38 +69,30 @@ class EmonSensor : public BaseSensor {
                if (sample < min) min = sample;

                // Digital low pass filter extracts the VDC offset
                _pivot = (_pivot + (sample - _pivot) / EMON_FILTER_SPEED);
                _pivot = (_pivot + (sample - _pivot) / _adc_counts);
                filtered = sample - _pivot;

                // Root-mean-square method
                sum += (filtered * filtered);
                ++samples;

                // Exit condition
                if (mode == EMON_MODE_SAMPLES) {
                    if (samples >= value) break;
                } else {
                    if (millis() - start >= value) break;
                }

                yield();

            }
            time_span = millis() - time_span;

            // Quick fix
            if (_pivot < min || max < _pivot) {
                _pivot = (max + min) / 2.0;
            }

            double rms = samples > 0 ? sqrt(sum / samples) : 0;
            // Calculate current
            double rms = _samples > 0 ? sqrt(sum / _samples) : 0;
            double current = _current_factor * rms;
            current = (double) (round(current * _multiplier) - 1) / _multiplier;
            current = (double) (int(current * _multiplier) - 1) / _multiplier;
            if (current < 0) current = 0;

            #if EMON_DEBUG
                Serial.print("[EMON] Total samples: "); Serial.println(samples);
                Serial.print("[EMON] Total time (ms): "); Serial.println(millis() - start);
                Serial.print("[EMON] Sample frequency (1/s): "); Serial.println(1000 * samples / (millis() - start));
                Serial.print("[EMON] Total samples: "); Serial.println(_samples);
                Serial.print("[EMON] Total time (ms): "); Serial.println(time_span);
                Serial.print("[EMON] Sample frequency (Hz): "); Serial.println(1000 * _samples / time_span);
                Serial.print("[EMON] Max value: "); Serial.println(max);
                Serial.print("[EMON] Min value: "); Serial.println(min);
                Serial.print("[EMON] Midpoint value: "); Serial.println(_pivot);
@ -111,6 +100,11 @@ class EmonSensor : public BaseSensor {
                Serial.print("[EMON] Current: "); Serial.println(current);
            #endif

            // Check timing
            if (time_span > EMON_MAX_TIME) {
                _samples = (_samples * EMON_MAX_TIME) / time_span;
            }

            return current;

        }
@ -121,5 +115,7 @@ class EmonSensor : public BaseSensor {
        double _current_factor;
        double _pivot;

        unsigned long _samples = EMON_MAX_SAMPLES;


 };