/*
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POWER V9261F MODULE
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Copyright (C) 2016-2017 by Xose Pérez <xose dot perez at gmail dot com>
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*/
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#if POWER_PROVIDER == POWER_PROVIDER_V9261F
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// -----------------------------------------------------------------------------
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// MODULE GLOBALS AND CACHE
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// -----------------------------------------------------------------------------
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#include <SoftwareSerial.h>
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SoftwareSerial * _v9261f_uart;
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double _v9261f_active = 0;
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double _v9261f_reactive = 0;
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double _v9261f_voltage = 0;
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double _v9261f_current = 0;
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double _v9261f_ratioP = V9261F_POWER_FACTOR;
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double _v9261f_ratioC = V9261F_CURRENT_FACTOR;
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double _v9261f_ratioV = V9261F_VOLTAGE_FACTOR;
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double _v9261f_ratioR = V9261F_RPOWER_FACTOR;
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unsigned char _v9261f_data[24];
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// -----------------------------------------------------------------------------
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// HAL
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// -----------------------------------------------------------------------------
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void _v9261fRead() {
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static unsigned char state = 0;
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static unsigned long last = 0;
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static bool found = false;
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static unsigned char index = 0;
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if (state == 0) {
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while (_v9261f_uart->available()) {
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_v9261f_uart->flush();
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found = true;
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last = millis();
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}
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if (found && (millis() - last > V9261F_SYNC_INTERVAL)) {
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_v9261f_uart->flush();
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index = 0;
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state = 1;
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}
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} else if (state == 1) {
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while (_v9261f_uart->available()) {
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_v9261f_uart->read();
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if (index++ >= 7) {
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_v9261f_uart->flush();
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index = 0;
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state = 2;
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}
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}
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} else if (state == 2) {
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while (_v9261f_uart->available()) {
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_v9261f_data[index] = _v9261f_uart->read();
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if (index++ >= 19) {
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_v9261f_uart->flush();
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last = millis();
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state = 3;
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}
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}
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} else if (state == 3) {
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if (_v9261fChecksum()) {
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_v9261f_active = (double) (
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(_v9261f_data[3]) +
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(_v9261f_data[4] << 8) +
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(_v9261f_data[5] << 16) +
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(_v9261f_data[6] << 24)
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) / _v9261f_ratioP;
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_v9261f_reactive = (double) (
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(_v9261f_data[7]) +
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(_v9261f_data[8] << 8) +
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(_v9261f_data[9] << 16) +
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(_v9261f_data[10] << 24)
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) / _v9261f_ratioR;
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_v9261f_voltage = (double) (
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(_v9261f_data[11]) +
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(_v9261f_data[12] << 8) +
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(_v9261f_data[13] << 16) +
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(_v9261f_data[14] << 24)
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) / _v9261f_ratioV;
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_v9261f_current = (double) (
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(_v9261f_data[15]) +
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(_v9261f_data[16] << 8) +
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(_v9261f_data[17] << 16) +
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(_v9261f_data[18] << 24)
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) / _v9261f_ratioC;
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if (_v9261f_active < 0) _v9261f_active = 0;
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if (_v9261f_reactive < 0) _v9261f_reactive = 0;
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if (_v9261f_voltage < 0) _v9261f_voltage = 0;
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if (_v9261f_current < 0) _v9261f_current = 0;
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_power_newdata = true;
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}
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last = millis();
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index = 0;
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state = 4;
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} else if (state == 4) {
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while (_v9261f_uart->available()) {
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_v9261f_uart->flush();
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last = millis();
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}
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if (millis() - last > V9261F_SYNC_INTERVAL) {
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state = 1;
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}
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}
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}
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bool _v9261fChecksum() {
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unsigned char checksum = 0;
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for (unsigned char i = 0; i < 19; i++) {
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checksum = checksum + _v9261f_data[i];
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}
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checksum = ~checksum + 0x33;
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return checksum == _v9261f_data[19];
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}
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// -----------------------------------------------------------------------------
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// POWER API
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// -----------------------------------------------------------------------------
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double _powerCurrent() {
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return _v9261f_current;
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}
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double _powerVoltage() {
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return _v9261f_voltage;
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}
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double _powerActivePower() {
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return _v9261f_active;
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}
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double _powerApparentPower() {
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return sqrt(_v9261f_reactive * _v9261f_reactive + _v9261f_active * _v9261f_active);
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}
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double _powerReactivePower() {
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return _v9261f_reactive;
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}
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double _powerPowerFactor() {
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double apparent = _powerApparentPower();
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if (apparent > 0) return _powerActivePower() / apparent;
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return 1;
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}
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void _powerEnabledProvider() {
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// Nothing to do
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}
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void _powerConfigureProvider() {
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_v9261f_ratioP = getSetting("pwrRatioP", V9261F_POWER_FACTOR).toFloat();
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_v9261f_ratioV = getSetting("pwrRatioV", V9261F_VOLTAGE_FACTOR).toFloat();
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_v9261f_ratioC = getSetting("pwrRatioC", V9261F_CURRENT_FACTOR).toFloat();
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_v9261f_ratioR = getSetting("pwrRatioR", V9261F_RPOWER_FACTOR).toFloat();
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}
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void _powerCalibrateProvider(unsigned char magnitude, double value) {
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if (value <= 0) return;
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if (magnitude == POWER_MAGNITUDE_ACTIVE) {
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_v9261f_ratioP = _v9261f_ratioP * (_v9261f_active / value);
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setSetting("pwrRatioP", _v9261f_ratioP);
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}
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if (magnitude == POWER_MAGNITUDE_CURRENT) {
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_v9261f_ratioC = _v9261f_ratioC * (_v9261f_current / value);
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setSetting("pwrRatioC", _v9261f_ratioC);
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}
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if (magnitude == POWER_MAGNITUDE_VOLTAGE) {
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_v9261f_ratioV = _v9261f_ratioV * (_v9261f_voltage / value);
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setSetting("pwrRatioV", _v9261f_ratioV);
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}
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if (magnitude == POWER_MAGNITUDE_POWER_FACTOR) {
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if (value < 100) {
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double apparent = _v9261f_ratioP / (value / 100);
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value = sqrt(apparent * apparent - _v9261f_ratioP * _v9261f_ratioP);
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_v9261f_ratioR = _v9261f_ratioR * (_v9261f_reactive / value);
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setSetting("pwrRatioR", _v9261f_ratioR);
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}
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}
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saveSettings();
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}
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void _powerResetCalibrationProvider() {
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delSetting("pwrRatioP");
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delSetting("pwrRatioC");
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delSetting("pwrRatioV");
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delSetting("pwrRatioR");
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_powerConfigureProvider();
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saveSettings();
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}
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void _powerSetupProvider() {
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_v9261f_uart = new SoftwareSerial(V9261F_PIN, SW_SERIAL_UNUSED_PIN, V9261F_PIN_INVERSE, 256);
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_v9261f_uart->begin(V9261F_BAUDRATE);
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}
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void _powerLoopProvider(bool before) {
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if (before) {
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_v9261fRead();
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}
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}
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#endif // POWER_PROVIDER & POWER_PROVIDER_EMON
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