// -----------------------------------------------------------------------------
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// ADE7853 Sensor over I2C
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// Copyright (C) 2017-2019 by Xose Pérez <xose dot perez at gmail dot com>
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// Implemented by Antonio López <tonilopezmr at gmail dot com>
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// -----------------------------------------------------------------------------
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#if SENSOR_SUPPORT && ADE7953_SUPPORT
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#pragma once
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#undef I2C_SUPPORT
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#define I2C_SUPPORT 1 // Explicitly request I2C support.
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#include "Arduino.h"
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#include "I2CSensor.h"
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#include <Wire.h>
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// -----------------------------------------------------------------------------
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// ADE7953 - Energy (Shelly 2.5)
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//
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// Based on datasheet from https://www.analog.com/en/products/ade7953.html
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// Based on Tasmota code https://github.com/arendst/Sonoff-Tasmota/blob/development/sonoff/xnrg_07_ade7953.ino
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//
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// I2C Address: 0x38
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// -----------------------------------------------------------------------------
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#define ADE7953_PREF 1540
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#define ADE7953_UREF 26000
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#define ADE7953_IREF 10000
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#define ADE7953_ALL_RELAYS 0
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#define ADE7953_RELAY_1 1
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#define ADE7953_RELAY_2 2
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#define ADE7953_VOLTAGE 1
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#define ADE7953_TOTAL_DEVICES 3
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class ADE7953Sensor : public I2CSensor {
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protected:
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struct reading_t {
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float current = 0.0;
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float power = 0.0;
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float energy = 0.0;
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};
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public:
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// ---------------------------------------------------------------------
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// Public
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// ---------------------------------------------------------------------
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ADE7953Sensor(): I2CSensor() {
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_sensor_id = SENSOR_ADE7953_ID;
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_readings.resize(ADE7953_TOTAL_DEVICES);
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_energy_offsets.resize(ADE7953_TOTAL_DEVICES);
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_count = _readings.size() * ADE7953_TOTAL_DEVICES + ADE7953_VOLTAGE; //10
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}
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// ---------------------------------------------------------------------
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// Sensors API
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// ---------------------------------------------------------------------
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// Initialization method, must be idempotent
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void begin() {
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if (!_dirty) return;
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_init();
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_dirty = !_ready;
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}
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// Descriptive name of the sensor
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String description() {
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char buffer[25];
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snprintf(buffer, sizeof(buffer), "ADE7953 @ I2C (0x%02X)", _address);
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return String(buffer);
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}
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// Descriptive name of the slot # index
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String slot(unsigned char index) {
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return description();
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};
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// Type for slot # index
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unsigned char type(unsigned char index) {
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if (index == 0) return MAGNITUDE_VOLTAGE;
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index = index % ADE7953_TOTAL_DEVICES;
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if (index == 0) return MAGNITUDE_ENERGY;
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if (index == 1) return MAGNITUDE_CURRENT;
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if (index == 2) return MAGNITUDE_POWER_ACTIVE;
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return MAGNITUDE_NONE;
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}
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// Pre-read hook (usually to populate registers with up-to-date data)
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void pre() {
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uint32_t active_power1 = 0;
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uint32_t active_power2 = 0;
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uint32_t current_rms = 0;
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uint32_t current_rms1 = 0;
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uint32_t current_rms2 = 0;
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uint32_t voltage_rms = 0;
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voltage_rms = read(_address, 0x31C); // Both relays
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current_rms1 = read(_address, 0x31B); // Relay 1
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if (current_rms1 < 2000) { // No load threshold (20mA)
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current_rms1 = 0;
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active_power1 = 0;
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} else {
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active_power1 = (int32_t)read(_address, 0x313) * -1; // Relay 1
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active_power1 = (active_power1 > 0) ? active_power1 : 0;
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}
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current_rms2 = read(_address, 0x31A); // Relay 2
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if (current_rms2 < 2000) { // No load threshold (20mA)
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current_rms2 = 0;
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active_power2 = 0;
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} else {
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active_power2 = (int32_t)read(_address, 0x312); // Relay 2
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active_power2 = (active_power2 > 0) ? active_power2 : 0;
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}
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_voltage = (float) voltage_rms / ADE7953_UREF;
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storeReading(
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ADE7953_ALL_RELAYS,
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(float)(current_rms1 + current_rms2) / (ADE7953_IREF * 10),
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(float)(active_power1 + active_power2) / (ADE7953_PREF / 10)
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);
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storeReading(
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ADE7953_RELAY_1,
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(float) current_rms1 / (ADE7953_IREF * 10),
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(float) active_power1 / (ADE7953_PREF / 10)
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);
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storeReading(
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ADE7953_RELAY_2,
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(float)current_rms2 / (ADE7953_IREF * 10),
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(float)active_power2 / (ADE7953_PREF / 10)
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);
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}
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inline void storeReading(unsigned int relay, float current, float power) {
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auto& reading_ref = _readings.at(relay);
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reading_ref.current = current;
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reading_ref.power = power;
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static unsigned long last = 0;
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if (last > 0) {
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reading_ref.energy += (power * (millis() - last) / 1000);
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}
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last = millis();
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}
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// Current value for slot # index
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double value(unsigned char index) {
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if (index == 0) return _voltage;
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int relay = (index - 1) / ADE7953_TOTAL_DEVICES;
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index = index % ADE7953_TOTAL_DEVICES;
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if (index == 0) return _energy_offsets[relay] + _readings[relay].energy;
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if (index == 1) return _readings[relay].current;
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if (index == 2) return _readings[relay].power;
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return 0;
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}
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unsigned int getTotalDevices() {
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return ADE7953_TOTAL_DEVICES;
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}
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void resetEnergy(int relay, double value = 0) {
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_energy_offsets[relay] = value;
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}
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protected:
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void _init() {
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nice_delay(100); // Need 100mS to init ADE7953
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write(_address, 0x102, 0x0004); // Locking the communication interface (Clear bit COMM_LOCK), Enable HPF
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write(_address, 0x0FE, 0x00AD); // Unlock register 0x120
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write(_address, 0x120, 0x0030); // Configure optimum setting
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_ready = true;
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}
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#if 0
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static int reg_size(uint16_t reg) {
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int size = 0;
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switch ((reg >> 8) & 0x0F) {
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case 0x03:
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size++;
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case 0x02:
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size++;
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case 0x01:
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size++;
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case 0x00:
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case 0x07:
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case 0x08:
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size++;
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}
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return size;
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}
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#else
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// Optimized version of the function above, -80 bytes of code
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// Use the known property of register addresses to calculate their size
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static const int reg_size(const uint16_t reg) {
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const uint8_t mask = ((reg >> 8) & 0b1111);
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if (!mask || (mask & 0b1100)) {
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return 1;
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} else if (mask & 0b0011) {
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return mask + 1;
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}
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return 0;
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}
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#endif
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void write(unsigned char address, uint16_t reg, uint32_t val) {
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int size = reg_size(reg);
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if (size) {
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Wire.beginTransmission(address);
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Wire.write((reg >> 8) & 0xFF);
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Wire.write(reg & 0xFF);
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while (size--) {
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Wire.write((val >> (8 * size)) & 0xFF); // Write data, MSB first
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}
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Wire.endTransmission();
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delayMicroseconds(5); // Bus-free time minimum 4.7us
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}
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}
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static uint32_t read(int address, uint16_t reg) {
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uint32_t response = 0;
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const int size = reg_size(reg);
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if (size) {
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Wire.beginTransmission(address);
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Wire.write((reg >> 8) & 0xFF);
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Wire.write(reg & 0xFF);
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Wire.endTransmission(0);
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Wire.requestFrom(address, size);
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if (size <= Wire.available()) {
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for (int i = 0; i < size; i++) {
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response = response << 8 | Wire.read(); // receive DATA (MSB first)
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}
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}
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}
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return response;
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}
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std::vector<reading_t> _readings;
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float _voltage = 0;
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std::vector<double> _energy_offsets;
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};
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#endif // SENSOR_SUPPORT && ADE7953_SUPPORT
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