diff --git a/CODEOWNERS b/CODEOWNERS index 2d6df3ebd9..9adb3034a0 100644 --- a/CODEOWNERS +++ b/CODEOWNERS @@ -18,6 +18,7 @@ esphome/components/ac_dimmer/* @glmnet esphome/components/adc/* @esphome/core esphome/components/adc128s102/* @DeerMaximum esphome/components/addressable_light/* @justfalter +esphome/components/ade7880/* @kpfleming esphome/components/ade7953/* @angelnu esphome/components/ade7953_i2c/* @angelnu esphome/components/ade7953_spi/* @angelnu diff --git a/esphome/components/ade7880/__init__.py b/esphome/components/ade7880/__init__.py new file mode 100644 index 0000000000..aed63c7dfa --- /dev/null +++ b/esphome/components/ade7880/__init__.py @@ -0,0 +1 @@ +CODEOWNERS = ["@kpfleming"] diff --git a/esphome/components/ade7880/ade7880.cpp b/esphome/components/ade7880/ade7880.cpp new file mode 100644 index 0000000000..31b72d51a6 --- /dev/null +++ b/esphome/components/ade7880/ade7880.cpp @@ -0,0 +1,302 @@ +// This component was developed using knowledge gathered by a number +// of people who reverse-engineered the Shelly 3EM: +// +// @AndreKR on GitHub +// Axel (@Axel830 on GitHub) +// Marko (@goodkiller on GitHub) +// Michaël Piron (@michaelpiron on GitHub) +// Theo Arends (@arendst on GitHub) + +#include "ade7880.h" +#include "ade7880_registers.h" +#include "esphome/core/log.h" + +namespace esphome { +namespace ade7880 { + +static const char *const TAG = "ade7880"; + +void IRAM_ATTR ADE7880Store::gpio_intr(ADE7880Store *arg) { arg->reset_done = true; } + +void ADE7880::setup() { + if (this->irq0_pin_ != nullptr) { + this->irq0_pin_->setup(); + } + this->irq1_pin_->setup(); + if (this->reset_pin_ != nullptr) { + this->reset_pin_->setup(); + } + this->store_.irq1_pin = this->irq1_pin_->to_isr(); + this->irq1_pin_->attach_interrupt(ADE7880Store::gpio_intr, &this->store_, gpio::INTERRUPT_FALLING_EDGE); + + // if IRQ1 is already asserted, the cause must be determined + if (this->irq1_pin_->digital_read() == 0) { + ESP_LOGD(TAG, "IRQ1 found asserted during setup()"); + auto status1 = read_u32_register16_(STATUS1); + if ((status1 & ~STATUS1_RSTDONE) != 0) { + // not safe to proceed, must initiate reset + ESP_LOGD(TAG, "IRQ1 asserted for !RSTDONE, resetting device"); + this->reset_device_(); + return; + } + if ((status1 & STATUS1_RSTDONE) == STATUS1_RSTDONE) { + // safe to proceed, device has just completed reset cycle + ESP_LOGD(TAG, "Acknowledging RSTDONE"); + this->write_u32_register16_(STATUS0, 0xFFFF); + this->write_u32_register16_(STATUS1, 0xFFFF); + this->init_device_(); + return; + } + } + + this->reset_device_(); +} + +void ADE7880::loop() { + // check for completion of a reset cycle + if (!this->store_.reset_done) { + return; + } + + ESP_LOGD(TAG, "Acknowledging RSTDONE"); + this->write_u32_register16_(STATUS0, 0xFFFF); + this->write_u32_register16_(STATUS1, 0xFFFF); + this->init_device_(); + this->store_.reset_done = false; + this->store_.reset_pending = false; +} + +template +void ADE7880::update_sensor_from_s24zp_register16_(sensor::Sensor *sensor, uint16_t a_register, F &&f) { + if (sensor == nullptr) { + return; + } + + float val = this->read_s24zp_register16_(a_register); + sensor->publish_state(f(val)); +} + +template +void ADE7880::update_sensor_from_s16_register16_(sensor::Sensor *sensor, uint16_t a_register, F &&f) { + if (sensor == nullptr) { + return; + } + + float val = this->read_s16_register16_(a_register); + sensor->publish_state(f(val)); +} + +template +void ADE7880::update_sensor_from_s32_register16_(sensor::Sensor *sensor, uint16_t a_register, F &&f) { + if (sensor == nullptr) { + return; + } + + float val = this->read_s32_register16_(a_register); + sensor->publish_state(f(val)); +} + +void ADE7880::update() { + if (this->store_.reset_pending) { + return; + } + + auto start = millis(); + + if (this->channel_n_ != nullptr) { + auto *chan = this->channel_n_; + this->update_sensor_from_s24zp_register16_(chan->current, NIRMS, [](float val) { return val / 100000.0f; }); + } + + if (this->channel_a_ != nullptr) { + auto *chan = this->channel_a_; + this->update_sensor_from_s24zp_register16_(chan->current, AIRMS, [](float val) { return val / 100000.0f; }); + this->update_sensor_from_s24zp_register16_(chan->voltage, BVRMS, [](float val) { return val / 10000.0f; }); + this->update_sensor_from_s24zp_register16_(chan->active_power, AWATT, [](float val) { return val / 100.0f; }); + this->update_sensor_from_s24zp_register16_(chan->apparent_power, AVA, [](float val) { return val / 100.0f; }); + this->update_sensor_from_s16_register16_(chan->power_factor, APF, + [](float val) { return std::abs(val / -327.68f); }); + this->update_sensor_from_s32_register16_(chan->forward_active_energy, AFWATTHR, [&chan](float val) { + return chan->forward_active_energy_total += val / 14400.0f; + }); + this->update_sensor_from_s32_register16_(chan->reverse_active_energy, AFWATTHR, [&chan](float val) { + return chan->reverse_active_energy_total += val / 14400.0f; + }); + } + + if (this->channel_b_ != nullptr) { + auto *chan = this->channel_b_; + this->update_sensor_from_s24zp_register16_(chan->current, BIRMS, [](float val) { return val / 100000.0f; }); + this->update_sensor_from_s24zp_register16_(chan->voltage, BVRMS, [](float val) { return val / 10000.0f; }); + this->update_sensor_from_s24zp_register16_(chan->active_power, BWATT, [](float val) { return val / 100.0f; }); + this->update_sensor_from_s24zp_register16_(chan->apparent_power, BVA, [](float val) { return val / 100.0f; }); + this->update_sensor_from_s16_register16_(chan->power_factor, BPF, + [](float val) { return std::abs(val / -327.68f); }); + this->update_sensor_from_s32_register16_(chan->forward_active_energy, BFWATTHR, [&chan](float val) { + return chan->forward_active_energy_total += val / 14400.0f; + }); + this->update_sensor_from_s32_register16_(chan->reverse_active_energy, BFWATTHR, [&chan](float val) { + return chan->reverse_active_energy_total += val / 14400.0f; + }); + } + + if (this->channel_c_ != nullptr) { + auto *chan = this->channel_c_; + this->update_sensor_from_s24zp_register16_(chan->current, CIRMS, [](float val) { return val / 100000.0f; }); + this->update_sensor_from_s24zp_register16_(chan->voltage, CVRMS, [](float val) { return val / 10000.0f; }); + this->update_sensor_from_s24zp_register16_(chan->active_power, CWATT, [](float val) { return val / 100.0f; }); + this->update_sensor_from_s24zp_register16_(chan->apparent_power, CVA, [](float val) { return val / 100.0f; }); + this->update_sensor_from_s16_register16_(chan->power_factor, CPF, + [](float val) { return std::abs(val / -327.68f); }); + this->update_sensor_from_s32_register16_(chan->forward_active_energy, CFWATTHR, [&chan](float val) { + return chan->forward_active_energy_total += val / 14400.0f; + }); + this->update_sensor_from_s32_register16_(chan->reverse_active_energy, CFWATTHR, [&chan](float val) { + return chan->reverse_active_energy_total += val / 14400.0f; + }); + } + + ESP_LOGD(TAG, "update took %u ms", millis() - start); +} + +void ADE7880::dump_config() { + ESP_LOGCONFIG(TAG, "ADE7880:"); + LOG_PIN(" IRQ0 Pin: ", this->irq0_pin_); + LOG_PIN(" IRQ1 Pin: ", this->irq1_pin_); + LOG_PIN(" RESET Pin: ", this->reset_pin_); + ESP_LOGCONFIG(TAG, " Frequency: %.0f Hz", this->frequency_); + + if (this->channel_a_ != nullptr) { + ESP_LOGCONFIG(TAG, " Phase A:"); + LOG_SENSOR(" ", "Current", this->channel_a_->current); + LOG_SENSOR(" ", "Voltage", this->channel_a_->voltage); + LOG_SENSOR(" ", "Active Power", this->channel_a_->active_power); + LOG_SENSOR(" ", "Apparent Power", this->channel_a_->apparent_power); + LOG_SENSOR(" ", "Power Factor", this->channel_a_->power_factor); + LOG_SENSOR(" ", "Forward Active Energy", this->channel_a_->forward_active_energy); + LOG_SENSOR(" ", "Reverse Active Energy", this->channel_a_->reverse_active_energy); + ESP_LOGCONFIG(TAG, " Calibration:"); + ESP_LOGCONFIG(TAG, " Current: %u", this->channel_a_->current_gain_calibration); + ESP_LOGCONFIG(TAG, " Voltage: %d", this->channel_a_->voltage_gain_calibration); + ESP_LOGCONFIG(TAG, " Power: %d", this->channel_a_->power_gain_calibration); + ESP_LOGCONFIG(TAG, " Phase Angle: %u", this->channel_a_->phase_angle_calibration); + } + + if (this->channel_b_ != nullptr) { + ESP_LOGCONFIG(TAG, " Phase B:"); + LOG_SENSOR(" ", "Current", this->channel_b_->current); + LOG_SENSOR(" ", "Voltage", this->channel_b_->voltage); + LOG_SENSOR(" ", "Active Power", this->channel_b_->active_power); + LOG_SENSOR(" ", "Apparent Power", this->channel_b_->apparent_power); + LOG_SENSOR(" ", "Power Factor", this->channel_b_->power_factor); + LOG_SENSOR(" ", "Forward Active Energy", this->channel_b_->forward_active_energy); + LOG_SENSOR(" ", "Reverse Active Energy", this->channel_b_->reverse_active_energy); + ESP_LOGCONFIG(TAG, " Calibration:"); + ESP_LOGCONFIG(TAG, " Current: %u", this->channel_b_->current_gain_calibration); + ESP_LOGCONFIG(TAG, " Voltage: %d", this->channel_b_->voltage_gain_calibration); + ESP_LOGCONFIG(TAG, " Power: %d", this->channel_b_->power_gain_calibration); + ESP_LOGCONFIG(TAG, " Phase Angle: %u", this->channel_b_->phase_angle_calibration); + } + + if (this->channel_c_ != nullptr) { + ESP_LOGCONFIG(TAG, " Phase C:"); + LOG_SENSOR(" ", "Current", this->channel_c_->current); + LOG_SENSOR(" ", "Voltage", this->channel_c_->voltage); + LOG_SENSOR(" ", "Active Power", this->channel_c_->active_power); + LOG_SENSOR(" ", "Apparent Power", this->channel_c_->apparent_power); + LOG_SENSOR(" ", "Power Factor", this->channel_c_->power_factor); + LOG_SENSOR(" ", "Forward Active Energy", this->channel_c_->forward_active_energy); + LOG_SENSOR(" ", "Reverse Active Energy", this->channel_c_->reverse_active_energy); + ESP_LOGCONFIG(TAG, " Calibration:"); + ESP_LOGCONFIG(TAG, " Current: %u", this->channel_c_->current_gain_calibration); + ESP_LOGCONFIG(TAG, " Voltage: %d", this->channel_c_->voltage_gain_calibration); + ESP_LOGCONFIG(TAG, " Power: %d", this->channel_c_->power_gain_calibration); + ESP_LOGCONFIG(TAG, " Phase Angle: %u", this->channel_c_->phase_angle_calibration); + } + + if (this->channel_n_ != nullptr) { + ESP_LOGCONFIG(TAG, " Neutral:"); + LOG_SENSOR(" ", "Current", this->channel_n_->current); + ESP_LOGCONFIG(TAG, " Calibration:"); + ESP_LOGCONFIG(TAG, " Current: %u", this->channel_n_->current_gain_calibration); + } + + LOG_I2C_DEVICE(this); + LOG_UPDATE_INTERVAL(this); +} + +void ADE7880::calibrate_s10zp_reading_(uint16_t a_register, int16_t calibration) { + if (calibration == 0) { + return; + } + + this->write_s10zp_register16_(a_register, calibration); +} + +void ADE7880::calibrate_s24zpse_reading_(uint16_t a_register, int32_t calibration) { + if (calibration == 0) { + return; + } + + this->write_s24zpse_register16_(a_register, calibration); +} + +void ADE7880::init_device_() { + this->write_u8_register16_(CONFIG2, CONFIG2_I2C_LOCK); + + this->write_u16_register16_(GAIN, 0); + + if (this->frequency_ > 55) { + this->write_u16_register16_(COMPMODE, COMPMODE_DEFAULT | COMPMODE_SELFREQ); + } + + if (this->channel_n_ != nullptr) { + this->calibrate_s24zpse_reading_(NIGAIN, this->channel_n_->current_gain_calibration); + } + + if (this->channel_a_ != nullptr) { + this->calibrate_s24zpse_reading_(AIGAIN, this->channel_a_->current_gain_calibration); + this->calibrate_s24zpse_reading_(AVGAIN, this->channel_a_->voltage_gain_calibration); + this->calibrate_s24zpse_reading_(APGAIN, this->channel_a_->power_gain_calibration); + this->calibrate_s10zp_reading_(APHCAL, this->channel_a_->phase_angle_calibration); + } + + if (this->channel_b_ != nullptr) { + this->calibrate_s24zpse_reading_(BIGAIN, this->channel_b_->current_gain_calibration); + this->calibrate_s24zpse_reading_(BVGAIN, this->channel_b_->voltage_gain_calibration); + this->calibrate_s24zpse_reading_(BPGAIN, this->channel_b_->power_gain_calibration); + this->calibrate_s10zp_reading_(BPHCAL, this->channel_b_->phase_angle_calibration); + } + + if (this->channel_c_ != nullptr) { + this->calibrate_s24zpse_reading_(CIGAIN, this->channel_c_->current_gain_calibration); + this->calibrate_s24zpse_reading_(CVGAIN, this->channel_c_->voltage_gain_calibration); + this->calibrate_s24zpse_reading_(CPGAIN, this->channel_c_->power_gain_calibration); + this->calibrate_s10zp_reading_(CPHCAL, this->channel_c_->phase_angle_calibration); + } + + // write three default values to data memory RAM to flush the I2C write queue + this->write_s32_register16_(VLEVEL, 0); + this->write_s32_register16_(VLEVEL, 0); + this->write_s32_register16_(VLEVEL, 0); + + this->write_u8_register16_(DSPWP_SEL, DSPWP_SEL_SET); + this->write_u8_register16_(DSPWP_SET, DSPWP_SET_RO); + this->write_u16_register16_(RUN, RUN_ENABLE); +} + +void ADE7880::reset_device_() { + if (this->reset_pin_ != nullptr) { + ESP_LOGD(TAG, "Reset device using RESET pin"); + this->reset_pin_->digital_write(false); + delay(1); + this->reset_pin_->digital_write(true); + } else { + ESP_LOGD(TAG, "Reset device using SWRST command"); + this->write_u16_register16_(CONFIG, CONFIG_SWRST); + } + this->store_.reset_pending = true; +} + +} // namespace ade7880 +} // namespace esphome diff --git a/esphome/components/ade7880/ade7880.h b/esphome/components/ade7880/ade7880.h new file mode 100644 index 0000000000..a565357dc5 --- /dev/null +++ b/esphome/components/ade7880/ade7880.h @@ -0,0 +1,131 @@ +#pragma once + +// This component was developed using knowledge gathered by a number +// of people who reverse-engineered the Shelly 3EM: +// +// @AndreKR on GitHub +// Axel (@Axel830 on GitHub) +// Marko (@goodkiller on GitHub) +// Michaël Piron (@michaelpiron on GitHub) +// Theo Arends (@arendst on GitHub) + +#include "esphome/core/component.h" +#include "esphome/core/hal.h" +#include "esphome/components/i2c/i2c.h" +#include "esphome/components/sensor/sensor.h" + +#include "ade7880_registers.h" + +namespace esphome { +namespace ade7880 { + +struct NeutralChannel { + void set_current(sensor::Sensor *sens) { this->current = sens; } + + void set_current_gain_calibration(int32_t val) { this->current_gain_calibration = val; } + + sensor::Sensor *current{nullptr}; + int32_t current_gain_calibration{0}; +}; + +struct PowerChannel { + void set_current(sensor::Sensor *sens) { this->current = sens; } + void set_voltage(sensor::Sensor *sens) { this->voltage = sens; } + void set_active_power(sensor::Sensor *sens) { this->active_power = sens; } + void set_apparent_power(sensor::Sensor *sens) { this->apparent_power = sens; } + void set_power_factor(sensor::Sensor *sens) { this->power_factor = sens; } + void set_forward_active_energy(sensor::Sensor *sens) { this->forward_active_energy = sens; } + void set_reverse_active_energy(sensor::Sensor *sens) { this->reverse_active_energy = sens; } + + void set_current_gain_calibration(int32_t val) { this->current_gain_calibration = val; } + void set_voltage_gain_calibration(int32_t val) { this->voltage_gain_calibration = val; } + void set_power_gain_calibration(int32_t val) { this->power_gain_calibration = val; } + void set_phase_angle_calibration(int32_t val) { this->phase_angle_calibration = val; } + + sensor::Sensor *current{nullptr}; + sensor::Sensor *voltage{nullptr}; + sensor::Sensor *active_power{nullptr}; + sensor::Sensor *apparent_power{nullptr}; + sensor::Sensor *power_factor{nullptr}; + sensor::Sensor *forward_active_energy{nullptr}; + sensor::Sensor *reverse_active_energy{nullptr}; + int32_t current_gain_calibration{0}; + int32_t voltage_gain_calibration{0}; + int32_t power_gain_calibration{0}; + uint16_t phase_angle_calibration{0}; + float forward_active_energy_total{0}; + float reverse_active_energy_total{0}; +}; + +// Store data in a class that doesn't use multiple-inheritance (no vtables in flash!) +struct ADE7880Store { + volatile bool reset_done{false}; + bool reset_pending{false}; + ISRInternalGPIOPin irq1_pin; + + static void gpio_intr(ADE7880Store *arg); +}; + +class ADE7880 : public i2c::I2CDevice, public PollingComponent { + public: + void set_irq0_pin(InternalGPIOPin *pin) { this->irq0_pin_ = pin; } + void set_irq1_pin(InternalGPIOPin *pin) { this->irq1_pin_ = pin; } + void set_reset_pin(InternalGPIOPin *pin) { this->reset_pin_ = pin; } + void set_frequency(float frequency) { this->frequency_ = frequency; } + void set_channel_n(NeutralChannel *channel) { this->channel_n_ = channel; } + void set_channel_a(PowerChannel *channel) { this->channel_a_ = channel; } + void set_channel_b(PowerChannel *channel) { this->channel_b_ = channel; } + void set_channel_c(PowerChannel *channel) { this->channel_c_ = channel; } + + void setup() override; + + void loop() override; + + void update() override; + + void dump_config() override; + + float get_setup_priority() const override { return setup_priority::DATA; } + + protected: + ADE7880Store store_{}; + InternalGPIOPin *irq0_pin_{nullptr}; + InternalGPIOPin *irq1_pin_{nullptr}; + InternalGPIOPin *reset_pin_{nullptr}; + float frequency_; + NeutralChannel *channel_n_{nullptr}; + PowerChannel *channel_a_{nullptr}; + PowerChannel *channel_b_{nullptr}; + PowerChannel *channel_c_{nullptr}; + + void calibrate_s10zp_reading_(uint16_t a_register, int16_t calibration); + void calibrate_s24zpse_reading_(uint16_t a_register, int32_t calibration); + + void init_device_(); + + // each of these functions allow the caller to pass in a lambda (or any other callable) + // which modifies the value read from the register before it is passed to the sensor + // the callable will be passed a 'float' value and is expected to return a 'float' + template void update_sensor_from_s24zp_register16_(sensor::Sensor *sensor, uint16_t a_register, F &&f); + template void update_sensor_from_s16_register16_(sensor::Sensor *sensor, uint16_t a_register, F &&f); + template void update_sensor_from_s32_register16_(sensor::Sensor *sensor, uint16_t a_register, F &&f); + + void reset_device_(); + + uint8_t read_u8_register16_(uint16_t a_register); + int16_t read_s16_register16_(uint16_t a_register); + uint16_t read_u16_register16_(uint16_t a_register); + int32_t read_s24zp_register16_(uint16_t a_register); + int32_t read_s32_register16_(uint16_t a_register); + uint32_t read_u32_register16_(uint16_t a_register); + + void write_u8_register16_(uint16_t a_register, uint8_t value); + void write_s10zp_register16_(uint16_t a_register, int16_t value); + void write_u16_register16_(uint16_t a_register, uint16_t value); + void write_s24zpse_register16_(uint16_t a_register, int32_t value); + void write_s32_register16_(uint16_t a_register, int32_t value); + void write_u32_register16_(uint16_t a_register, uint32_t value); +}; + +} // namespace ade7880 +} // namespace esphome diff --git a/esphome/components/ade7880/ade7880_i2c.cpp b/esphome/components/ade7880/ade7880_i2c.cpp new file mode 100644 index 0000000000..fae20f175d --- /dev/null +++ b/esphome/components/ade7880/ade7880_i2c.cpp @@ -0,0 +1,101 @@ +// This component was developed using knowledge gathered by a number +// of people who reverse-engineered the Shelly 3EM: +// +// @AndreKR on GitHub +// Axel (@Axel830 on GitHub) +// Marko (@goodkiller on GitHub) +// Michaël Piron (@michaelpiron on GitHub) +// Theo Arends (@arendst on GitHub) + +#include "ade7880.h" + +namespace esphome { +namespace ade7880 { + +// adapted from https://stackoverflow.com/a/55912127/1886371 +template inline T sign_extend(const T &v) noexcept { + using S = struct { signed Val : Bits; }; + return reinterpret_cast(&v)->Val; +} + +// Register types +// unsigned 8-bit (uint8_t) +// signed 10-bit - 16-bit ZP on wire (int16_t, needs sign extension) +// unsigned 16-bit (uint16_t) +// unsigned 20-bit - 32-bit ZP on wire (uint32_t) +// signed 24-bit - 32-bit ZPSE on wire (int32_t, needs sign extension) +// signed 24-bit - 32-bit ZP on wire (int32_t, needs sign extension) +// signed 24-bit - 32-bit SE on wire (int32_t) +// signed 28-bit - 32-bit ZP on wire (int32_t, needs sign extension) +// unsigned 32-bit (uint32_t) +// signed 32-bit (int32_t) + +uint8_t ADE7880::read_u8_register16_(uint16_t a_register) { + uint8_t in; + this->read_register16(a_register, &in, sizeof(in)); + return in; +} + +int16_t ADE7880::read_s16_register16_(uint16_t a_register) { + int16_t in; + this->read_register16(a_register, reinterpret_cast(&in), sizeof(in)); + return convert_big_endian(in); +} + +uint16_t ADE7880::read_u16_register16_(uint16_t a_register) { + uint16_t in; + this->read_register16(a_register, reinterpret_cast(&in), sizeof(in)); + return convert_big_endian(in); +} + +int32_t ADE7880::read_s24zp_register16_(uint16_t a_register) { + // s24zp means 24 bit signed value in the lower 24 bits of a 32-bit register + int32_t in; + this->read_register16(a_register, reinterpret_cast(&in), sizeof(in)); + return sign_extend<24>(convert_big_endian(in)); +} + +int32_t ADE7880::read_s32_register16_(uint16_t a_register) { + int32_t in; + this->read_register16(a_register, reinterpret_cast(&in), sizeof(in)); + return convert_big_endian(in); +} + +uint32_t ADE7880::read_u32_register16_(uint16_t a_register) { + uint32_t in; + this->read_register16(a_register, reinterpret_cast(&in), sizeof(in)); + return convert_big_endian(in); +} + +void ADE7880::write_u8_register16_(uint16_t a_register, uint8_t value) { + this->write_register16(a_register, &value, sizeof(value)); +} + +void ADE7880::write_s10zp_register16_(uint16_t a_register, int16_t value) { + int16_t out = convert_big_endian(value & 0x03FF); + this->write_register16(a_register, reinterpret_cast(&out), sizeof(out)); +} + +void ADE7880::write_u16_register16_(uint16_t a_register, uint16_t value) { + uint16_t out = convert_big_endian(value); + this->write_register16(a_register, reinterpret_cast(&out), sizeof(out)); +} + +void ADE7880::write_s24zpse_register16_(uint16_t a_register, int32_t value) { + // s24zpse means a 24-bit signed value, sign-extended to 28 bits, in the lower 28 bits of a 32-bit register + int32_t out = convert_big_endian(value & 0x0FFFFFFF); + this->write_register16(a_register, reinterpret_cast(&out), sizeof(out)); +} + +void ADE7880::write_s32_register16_(uint16_t a_register, int32_t value) { + int32_t out = convert_big_endian(value); + this->write_register16(a_register, reinterpret_cast(&out), sizeof(out)); +} + +void ADE7880::write_u32_register16_(uint16_t a_register, uint32_t value) { + uint32_t out = convert_big_endian(value); + this->write_register16(a_register, reinterpret_cast(&out), sizeof(out)); +} + +} // namespace ade7880 +} // namespace esphome diff --git a/esphome/components/ade7880/ade7880_registers.h b/esphome/components/ade7880/ade7880_registers.h new file mode 100644 index 0000000000..8b5b68abb0 --- /dev/null +++ b/esphome/components/ade7880/ade7880_registers.h @@ -0,0 +1,243 @@ +#pragma once + +// This file is a modified version of the one created by Michaël Piron (@michaelpiron on GitHub) + +// Source: https://www.analog.com/media/en/technical-documentation/application-notes/AN-1127.pdf + +namespace esphome { +namespace ade7880 { + +// DSP Data Memory RAM registers +constexpr uint16_t AIGAIN = 0x4380; +constexpr uint16_t AVGAIN = 0x4381; +constexpr uint16_t BIGAIN = 0x4382; +constexpr uint16_t BVGAIN = 0x4383; +constexpr uint16_t CIGAIN = 0x4384; +constexpr uint16_t CVGAIN = 0x4385; +constexpr uint16_t NIGAIN = 0x4386; + +constexpr uint16_t DICOEFF = 0x4388; + +constexpr uint16_t APGAIN = 0x4389; +constexpr uint16_t AWATTOS = 0x438A; +constexpr uint16_t BPGAIN = 0x438B; +constexpr uint16_t BWATTOS = 0x438C; +constexpr uint16_t CPGAIN = 0x438D; +constexpr uint16_t CWATTOS = 0x438E; +constexpr uint16_t AIRMSOS = 0x438F; +constexpr uint16_t AVRMSOS = 0x4390; +constexpr uint16_t BIRMSOS = 0x4391; +constexpr uint16_t BVRMSOS = 0x4392; +constexpr uint16_t CIRMSOS = 0x4393; +constexpr uint16_t CVRMSOS = 0x4394; +constexpr uint16_t NIRMSOS = 0x4395; +constexpr uint16_t HPGAIN = 0x4398; +constexpr uint16_t ISUMLVL = 0x4399; + +constexpr uint16_t VLEVEL = 0x439F; + +constexpr uint16_t AFWATTOS = 0x43A2; +constexpr uint16_t BFWATTOS = 0x43A3; +constexpr uint16_t CFWATTOS = 0x43A4; + +constexpr uint16_t AFVAROS = 0x43A5; +constexpr uint16_t BFVAROS = 0x43A6; +constexpr uint16_t CFVAROS = 0x43A7; + +constexpr uint16_t AFIRMSOS = 0x43A8; +constexpr uint16_t BFIRMSOS = 0x43A9; +constexpr uint16_t CFIRMSOS = 0x43AA; + +constexpr uint16_t AFVRMSOS = 0x43AB; +constexpr uint16_t BFVRMSOS = 0x43AC; +constexpr uint16_t CFVRMSOS = 0x43AD; + +constexpr uint16_t HXWATTOS = 0x43AE; +constexpr uint16_t HYWATTOS = 0x43AF; +constexpr uint16_t HZWATTOS = 0x43B0; +constexpr uint16_t HXVAROS = 0x43B1; +constexpr uint16_t HYVAROS = 0x43B2; +constexpr uint16_t HZVAROS = 0x43B3; + +constexpr uint16_t HXIRMSOS = 0x43B4; +constexpr uint16_t HYIRMSOS = 0x43B5; +constexpr uint16_t HZIRMSOS = 0x43B6; +constexpr uint16_t HXVRMSOS = 0x43B7; +constexpr uint16_t HYVRMSOS = 0x43B8; +constexpr uint16_t HZVRMSOS = 0x43B9; + +constexpr uint16_t AIRMS = 0x43C0; +constexpr uint16_t AVRMS = 0x43C1; +constexpr uint16_t BIRMS = 0x43C2; +constexpr uint16_t BVRMS = 0x43C3; +constexpr uint16_t CIRMS = 0x43C4; +constexpr uint16_t CVRMS = 0x43C5; +constexpr uint16_t NIRMS = 0x43C6; + +constexpr uint16_t ISUM = 0x43C7; + +// Internal DSP Memory RAM registers +constexpr uint16_t RUN = 0xE228; + +constexpr uint16_t AWATTHR = 0xE400; +constexpr uint16_t BWATTHR = 0xE401; +constexpr uint16_t CWATTHR = 0xE402; +constexpr uint16_t AFWATTHR = 0xE403; +constexpr uint16_t BFWATTHR = 0xE404; +constexpr uint16_t CFWATTHR = 0xE405; +constexpr uint16_t AFVARHR = 0xE409; +constexpr uint16_t BFVARHR = 0xE40A; +constexpr uint16_t CFVARHR = 0xE40B; + +constexpr uint16_t AVAHR = 0xE40C; +constexpr uint16_t BVAHR = 0xE40D; +constexpr uint16_t CVAHR = 0xE40E; + +constexpr uint16_t IPEAK = 0xE500; +constexpr uint16_t VPEAK = 0xE501; + +constexpr uint16_t STATUS0 = 0xE502; +constexpr uint16_t STATUS1 = 0xE503; + +constexpr uint16_t AIMAV = 0xE504; +constexpr uint16_t BIMAV = 0xE505; +constexpr uint16_t CIMAV = 0xE506; + +constexpr uint16_t OILVL = 0xE507; +constexpr uint16_t OVLVL = 0xE508; +constexpr uint16_t SAGLVL = 0xE509; +constexpr uint16_t MASK0 = 0xE50A; +constexpr uint16_t MASK1 = 0xE50B; + +constexpr uint16_t IAWV = 0xE50C; +constexpr uint16_t IBWV = 0xE50D; +constexpr uint16_t ICWV = 0xE50E; +constexpr uint16_t INWV = 0xE50F; +constexpr uint16_t VAWV = 0xE510; +constexpr uint16_t VBWV = 0xE511; +constexpr uint16_t VCWV = 0xE512; + +constexpr uint16_t AWATT = 0xE513; +constexpr uint16_t BWATT = 0xE514; +constexpr uint16_t CWATT = 0xE515; + +constexpr uint16_t AFVAR = 0xE516; +constexpr uint16_t BFVAR = 0xE517; +constexpr uint16_t CFVAR = 0xE518; + +constexpr uint16_t AVA = 0xE519; +constexpr uint16_t BVA = 0xE51A; +constexpr uint16_t CVA = 0xE51B; + +constexpr uint16_t CHECKSUM = 0xE51F; +constexpr uint16_t VNOM = 0xE520; +constexpr uint16_t LAST_RWDATA_24BIT = 0xE5FF; +constexpr uint16_t PHSTATUS = 0xE600; +constexpr uint16_t ANGLE0 = 0xE601; +constexpr uint16_t ANGLE1 = 0xE602; +constexpr uint16_t ANGLE2 = 0xE603; +constexpr uint16_t PHNOLOAD = 0xE608; +constexpr uint16_t LINECYC = 0xE60C; +constexpr uint16_t ZXTOUT = 0xE60D; +constexpr uint16_t COMPMODE = 0xE60E; +constexpr uint16_t GAIN = 0xE60F; +constexpr uint16_t CFMODE = 0xE610; +constexpr uint16_t CF1DEN = 0xE611; +constexpr uint16_t CF2DEN = 0xE612; +constexpr uint16_t CF3DEN = 0xE613; +constexpr uint16_t APHCAL = 0xE614; +constexpr uint16_t BPHCAL = 0xE615; +constexpr uint16_t CPHCAL = 0xE616; +constexpr uint16_t PHSIGN = 0xE617; +constexpr uint16_t CONFIG = 0xE618; +constexpr uint16_t MMODE = 0xE700; +constexpr uint16_t ACCMODE = 0xE701; +constexpr uint16_t LCYCMODE = 0xE702; +constexpr uint16_t PEAKCYC = 0xE703; +constexpr uint16_t SAGCYC = 0xE704; +constexpr uint16_t CFCYC = 0xE705; +constexpr uint16_t HSDC_CFG = 0xE706; +constexpr uint16_t VERSION = 0xE707; +constexpr uint16_t DSPWP_SET = 0xE7E3; +constexpr uint16_t LAST_RWDATA_8BIT = 0xE7FD; +constexpr uint16_t DSPWP_SEL = 0xE7FE; +constexpr uint16_t FVRMS = 0xE880; +constexpr uint16_t FIRMS = 0xE881; +constexpr uint16_t FWATT = 0xE882; +constexpr uint16_t FVAR = 0xE883; +constexpr uint16_t FVA = 0xE884; +constexpr uint16_t FPF = 0xE885; +constexpr uint16_t VTHDN = 0xE886; +constexpr uint16_t ITHDN = 0xE887; +constexpr uint16_t HXVRMS = 0xE888; +constexpr uint16_t HXIRMS = 0xE889; +constexpr uint16_t HXWATT = 0xE88A; +constexpr uint16_t HXVAR = 0xE88B; +constexpr uint16_t HXVA = 0xE88C; +constexpr uint16_t HXPF = 0xE88D; +constexpr uint16_t HXVHD = 0xE88E; +constexpr uint16_t HXIHD = 0xE88F; +constexpr uint16_t HYVRMS = 0xE890; +constexpr uint16_t HYIRMS = 0xE891; +constexpr uint16_t HYWATT = 0xE892; +constexpr uint16_t HYVAR = 0xE893; +constexpr uint16_t HYVA = 0xE894; +constexpr uint16_t HYPF = 0xE895; +constexpr uint16_t HYVHD = 0xE896; +constexpr uint16_t HYIHD = 0xE897; +constexpr uint16_t HZVRMS = 0xE898; +constexpr uint16_t HZIRMS = 0xE899; +constexpr uint16_t HZWATT = 0xE89A; +constexpr uint16_t HZVAR = 0xE89B; +constexpr uint16_t HZVA = 0xE89C; +constexpr uint16_t HZPF = 0xE89D; +constexpr uint16_t HZVHD = 0xE89E; +constexpr uint16_t HZIHD = 0xE89F; +constexpr uint16_t HCONFIG = 0xE900; +constexpr uint16_t APF = 0xE902; +constexpr uint16_t BPF = 0xE903; +constexpr uint16_t CPF = 0xE904; +constexpr uint16_t APERIOD = 0xE905; +constexpr uint16_t BPERIOD = 0xE906; +constexpr uint16_t CPERIOD = 0xE907; +constexpr uint16_t APNOLOAD = 0xE908; +constexpr uint16_t VARNOLOAD = 0xE909; +constexpr uint16_t VANOLOAD = 0xE90A; +constexpr uint16_t LAST_ADD = 0xE9FE; +constexpr uint16_t LAST_RWDATA_16BIT = 0xE9FF; +constexpr uint16_t CONFIG3 = 0xEA00; +constexpr uint16_t LAST_OP = 0xEA01; +constexpr uint16_t WTHR = 0xEA02; +constexpr uint16_t VARTHR = 0xEA03; +constexpr uint16_t VATHR = 0xEA04; + +constexpr uint16_t HX_REG = 0xEA08; +constexpr uint16_t HY_REG = 0xEA09; +constexpr uint16_t HZ_REG = 0xEA0A; +constexpr uint16_t LPOILVL = 0xEC00; +constexpr uint16_t CONFIG2 = 0xEC01; + +// STATUS1 Register Bits +constexpr uint32_t STATUS1_RSTDONE = (1 << 15); + +// CONFIG Register Bits +constexpr uint16_t CONFIG_SWRST = (1 << 7); + +// CONFIG2 Register Bits +constexpr uint8_t CONFIG2_I2C_LOCK = (1 << 1); + +// COMPMODE Register Bits +constexpr uint16_t COMPMODE_DEFAULT = 0x01FF; +constexpr uint16_t COMPMODE_SELFREQ = (1 << 14); + +// RUN Register Bits +constexpr uint16_t RUN_ENABLE = (1 << 0); + +// DSPWP_SET Register Bits +constexpr uint8_t DSPWP_SET_RO = (1 << 7); + +// DSPWP_SEL Register Bits +constexpr uint8_t DSPWP_SEL_SET = 0xAD; + +} // namespace ade7880 +} // namespace esphome diff --git a/esphome/components/ade7880/sensor.py b/esphome/components/ade7880/sensor.py new file mode 100644 index 0000000000..42a2b0d3fc --- /dev/null +++ b/esphome/components/ade7880/sensor.py @@ -0,0 +1,290 @@ +import esphome.codegen as cg +import esphome.config_validation as cv +from esphome.components import sensor, i2c +from esphome import pins +from esphome.const import ( + CONF_ACTIVE_POWER, + CONF_APPARENT_POWER, + CONF_CALIBRATION, + CONF_CURRENT, + CONF_FORWARD_ACTIVE_ENERGY, + CONF_FREQUENCY, + CONF_ID, + CONF_NAME, + CONF_PHASE_A, + CONF_PHASE_ANGLE, + CONF_PHASE_B, + CONF_PHASE_C, + CONF_POWER_FACTOR, + CONF_RESET_PIN, + CONF_REVERSE_ACTIVE_ENERGY, + CONF_VOLTAGE, + DEVICE_CLASS_APPARENT_POWER, + DEVICE_CLASS_CURRENT, + DEVICE_CLASS_ENERGY, + DEVICE_CLASS_POWER, + DEVICE_CLASS_POWER_FACTOR, + DEVICE_CLASS_VOLTAGE, + STATE_CLASS_MEASUREMENT, + STATE_CLASS_TOTAL_INCREASING, + UNIT_AMPERE, + UNIT_PERCENT, + UNIT_VOLT, + UNIT_VOLT_AMPS, + UNIT_VOLT_AMPS_REACTIVE_HOURS, + UNIT_WATT, + UNIT_WATT_HOURS, +) + +DEPENDENCIES = ["i2c"] + +ade7880_ns = cg.esphome_ns.namespace("ade7880") +ADE7880 = ade7880_ns.class_("ADE7880", cg.PollingComponent, i2c.I2CDevice) +NeutralChannel = ade7880_ns.struct("NeutralChannel") +PowerChannel = ade7880_ns.struct("PowerChannel") + +CONF_CURRENT_GAIN = "current_gain" +CONF_IRQ0_PIN = "irq0_pin" +CONF_IRQ1_PIN = "irq1_pin" +CONF_POWER_GAIN = "power_gain" +CONF_VOLTAGE_GAIN = "voltage_gain" + +CONF_NEUTRAL = "neutral" + +NEUTRAL_CHANNEL_SCHEMA = cv.Schema( + { + cv.GenerateID(): cv.declare_id(NeutralChannel), + cv.Optional(CONF_NAME): cv.string_strict, + cv.Required(CONF_CURRENT): cv.maybe_simple_value( + sensor.sensor_schema( + unit_of_measurement=UNIT_AMPERE, + accuracy_decimals=2, + device_class=DEVICE_CLASS_CURRENT, + state_class=STATE_CLASS_MEASUREMENT, + ), + key=CONF_NAME, + ), + cv.Required(CONF_CALIBRATION): cv.Schema( + { + cv.Required(CONF_CURRENT_GAIN): cv.int_, + }, + ), + } +) + +POWER_CHANNEL_SCHEMA = cv.Schema( + { + cv.GenerateID(): cv.declare_id(PowerChannel), + cv.Optional(CONF_NAME): cv.string_strict, + cv.Optional(CONF_VOLTAGE): cv.maybe_simple_value( + sensor.sensor_schema( + unit_of_measurement=UNIT_VOLT, + accuracy_decimals=1, + device_class=DEVICE_CLASS_VOLTAGE, + state_class=STATE_CLASS_MEASUREMENT, + ), + key=CONF_NAME, + ), + cv.Optional(CONF_CURRENT): cv.maybe_simple_value( + sensor.sensor_schema( + unit_of_measurement=UNIT_AMPERE, + accuracy_decimals=2, + device_class=DEVICE_CLASS_CURRENT, + state_class=STATE_CLASS_MEASUREMENT, + ), + key=CONF_NAME, + ), + cv.Optional(CONF_ACTIVE_POWER): cv.maybe_simple_value( + sensor.sensor_schema( + unit_of_measurement=UNIT_WATT, + accuracy_decimals=1, + device_class=DEVICE_CLASS_POWER, + state_class=STATE_CLASS_MEASUREMENT, + ), + key=CONF_NAME, + ), + cv.Optional(CONF_APPARENT_POWER): cv.maybe_simple_value( + sensor.sensor_schema( + unit_of_measurement=UNIT_VOLT_AMPS, + accuracy_decimals=1, + device_class=DEVICE_CLASS_APPARENT_POWER, + state_class=STATE_CLASS_MEASUREMENT, + ), + key=CONF_NAME, + ), + cv.Optional(CONF_POWER_FACTOR): cv.maybe_simple_value( + sensor.sensor_schema( + unit_of_measurement=UNIT_PERCENT, + accuracy_decimals=0, + device_class=DEVICE_CLASS_POWER_FACTOR, + state_class=STATE_CLASS_MEASUREMENT, + ), + key=CONF_NAME, + ), + cv.Optional(CONF_FORWARD_ACTIVE_ENERGY): cv.maybe_simple_value( + sensor.sensor_schema( + unit_of_measurement=UNIT_WATT_HOURS, + accuracy_decimals=2, + device_class=DEVICE_CLASS_ENERGY, + state_class=STATE_CLASS_TOTAL_INCREASING, + ), + key=CONF_NAME, + ), + cv.Optional(CONF_REVERSE_ACTIVE_ENERGY): cv.maybe_simple_value( + sensor.sensor_schema( + unit_of_measurement=UNIT_VOLT_AMPS_REACTIVE_HOURS, + accuracy_decimals=2, + device_class=DEVICE_CLASS_ENERGY, + state_class=STATE_CLASS_TOTAL_INCREASING, + ), + key=CONF_NAME, + ), + cv.Required(CONF_CALIBRATION): cv.Schema( + { + cv.Required(CONF_CURRENT_GAIN): cv.int_, + cv.Required(CONF_VOLTAGE_GAIN): cv.int_, + cv.Required(CONF_POWER_GAIN): cv.int_, + cv.Required(CONF_PHASE_ANGLE): cv.int_, + }, + ), + } +) + +CONFIG_SCHEMA = ( + cv.Schema( + { + cv.GenerateID(): cv.declare_id(ADE7880), + cv.Optional(CONF_FREQUENCY, default="50Hz"): cv.All( + cv.frequency, cv.Range(min=45.0, max=66.0) + ), + cv.Optional(CONF_IRQ0_PIN): pins.internal_gpio_input_pin_schema, + cv.Required(CONF_IRQ1_PIN): pins.internal_gpio_input_pin_schema, + cv.Optional(CONF_RESET_PIN): pins.internal_gpio_output_pin_schema, + cv.Optional(CONF_PHASE_A): POWER_CHANNEL_SCHEMA, + cv.Optional(CONF_PHASE_B): POWER_CHANNEL_SCHEMA, + cv.Optional(CONF_PHASE_C): POWER_CHANNEL_SCHEMA, + cv.Optional(CONF_NEUTRAL): NEUTRAL_CHANNEL_SCHEMA, + } + ) + .extend(cv.polling_component_schema("60s")) + .extend(i2c.i2c_device_schema(0x38)) +) + + +async def neutral_channel(config): + var = cg.new_Pvariable(config[CONF_ID]) + + current = config[CONF_CURRENT] + sens = await sensor.new_sensor(current) + cg.add(var.set_current(sens)) + + cg.add( + var.set_current_gain_calibration(config[CONF_CALIBRATION][CONF_CURRENT_GAIN]) + ) + + return var + + +async def power_channel(config): + var = cg.new_Pvariable(config[CONF_ID]) + + for sensor_type in [ + CONF_CURRENT, + CONF_VOLTAGE, + CONF_ACTIVE_POWER, + CONF_APPARENT_POWER, + CONF_POWER_FACTOR, + CONF_FORWARD_ACTIVE_ENERGY, + CONF_REVERSE_ACTIVE_ENERGY, + ]: + if conf := config.get(sensor_type): + sens = await sensor.new_sensor(conf) + cg.add(getattr(var, f"set_{sensor_type}")(sens)) + + for calib_type in [ + CONF_CURRENT_GAIN, + CONF_VOLTAGE_GAIN, + CONF_POWER_GAIN, + CONF_PHASE_ANGLE, + ]: + cg.add( + getattr(var, f"set_{calib_type}_calibration")( + config[CONF_CALIBRATION][calib_type] + ) + ) + + return var + + +def final_validate(config): + for channel in [CONF_PHASE_A, CONF_PHASE_B, CONF_PHASE_C]: + if channel := config.get(channel): + channel_name = channel.get(CONF_NAME) + + for sensor_type in [ + CONF_CURRENT, + CONF_VOLTAGE, + CONF_ACTIVE_POWER, + CONF_APPARENT_POWER, + CONF_POWER_FACTOR, + CONF_FORWARD_ACTIVE_ENERGY, + CONF_REVERSE_ACTIVE_ENERGY, + ]: + if conf := channel.get(sensor_type): + sensor_name = conf.get(CONF_NAME) + if ( + sensor_name + and channel_name + and not sensor_name.startswith(channel_name) + ): + conf[CONF_NAME] = f"{channel_name} {sensor_name}" + + if channel := config.get(CONF_NEUTRAL): + channel_name = channel.get(CONF_NAME) + if conf := channel.get(CONF_CURRENT): + sensor_name = conf.get(CONF_NAME) + if ( + sensor_name + and channel_name + and not sensor_name.startswith(channel_name) + ): + conf[CONF_NAME] = f"{channel_name} {sensor_name}" + + +FINAL_VALIDATE_SCHEMA = final_validate + + +async def to_code(config): + var = cg.new_Pvariable(config[CONF_ID]) + await cg.register_component(var, config) + await i2c.register_i2c_device(var, config) + + if irq0_pin := config.get(CONF_IRQ0_PIN): + pin = await cg.gpio_pin_expression(irq0_pin) + cg.add(var.set_irq0_pin(pin)) + + pin = await cg.gpio_pin_expression(config[CONF_IRQ1_PIN]) + cg.add(var.set_irq1_pin(pin)) + + if reset_pin := config.get(CONF_RESET_PIN): + pin = await cg.gpio_pin_expression(reset_pin) + cg.add(var.set_reset_pin(pin)) + + if frequency := config.get(CONF_FREQUENCY): + cg.add(var.set_frequency(frequency)) + + if channel := config.get(CONF_PHASE_A): + chan = await power_channel(channel) + cg.add(var.set_channel_a(chan)) + + if channel := config.get(CONF_PHASE_B): + chan = await power_channel(channel) + cg.add(var.set_channel_b(chan)) + + if channel := config.get(CONF_PHASE_C): + chan = await power_channel(channel) + cg.add(var.set_channel_c(chan)) + + if channel := config.get(CONF_NEUTRAL): + chan = await neutral_channel(channel) + cg.add(var.set_channel_n(chan)) diff --git a/tests/components/ade7880/common.yaml b/tests/components/ade7880/common.yaml new file mode 100644 index 0000000000..0aa388a325 --- /dev/null +++ b/tests/components/ade7880/common.yaml @@ -0,0 +1,56 @@ +i2c: + - id: i2c_ade7880 + scl: ${scl_pin} + sda: ${sda_pin} + +sensor: + - platform: ade7880 + i2c_id: i2c_ade7880 + irq0_pin: ${irq0_pin} + irq1_pin: ${irq1_pin} + reset_pin: ${reset_pin} + frequency: 60Hz + phase_a: + name: Channel A + voltage: Voltage + current: Current + active_power: Active Power + power_factor: Power Factor + forward_active_energy: Forward Active Energy + reverse_active_energy: Reverse Active Energy + calibration: + current_gain: 3116628 + voltage_gain: -757178 + power_gain: -1344457 + phase_angle: 188 + phase_b: + name: Channel B + voltage: Voltage + current: Current + active_power: Active Power + power_factor: Power Factor + forward_active_energy: Forward Active Energy + reverse_active_energy: Reverse Active Energy + calibration: + current_gain: 3133655 + voltage_gain: -755235 + power_gain: -1345638 + phase_angle: 188 + phase_c: + name: Channel C + voltage: Voltage + current: Current + active_power: Active Power + power_factor: Power Factor + forward_active_energy: Forward Active Energy + reverse_active_energy: Reverse Active Energy + calibration: + current_gain: 3111158 + voltage_gain: -743813 + power_gain: -1351437 + phase_angle: 180 + neutral: + name: Neutral + current: Current + calibration: + current_gain: 3189 diff --git a/tests/components/ade7880/test.esp32-c3-idf.yaml b/tests/components/ade7880/test.esp32-c3-idf.yaml new file mode 100644 index 0000000000..87db3e9427 --- /dev/null +++ b/tests/components/ade7880/test.esp32-c3-idf.yaml @@ -0,0 +1,8 @@ +substitutions: + scl_pin: GPIO5 + sda_pin: GPIO4 + irq0_pin: GPIO6 + irq1_pin: GPIO7 + reset_pin: GPIO10 + +<<: !include common.yaml diff --git a/tests/components/ade7880/test.esp32-c3.yaml b/tests/components/ade7880/test.esp32-c3.yaml new file mode 100644 index 0000000000..87db3e9427 --- /dev/null +++ b/tests/components/ade7880/test.esp32-c3.yaml @@ -0,0 +1,8 @@ +substitutions: + scl_pin: GPIO5 + sda_pin: GPIO4 + irq0_pin: GPIO6 + irq1_pin: GPIO7 + reset_pin: GPIO10 + +<<: !include common.yaml diff --git a/tests/components/ade7880/test.esp32-idf.yaml b/tests/components/ade7880/test.esp32-idf.yaml new file mode 100644 index 0000000000..685b49ff32 --- /dev/null +++ b/tests/components/ade7880/test.esp32-idf.yaml @@ -0,0 +1,8 @@ +substitutions: + scl_pin: GPIO5 + sda_pin: GPIO4 + irq0_pin: GPIO13 + irq1_pin: GPIO15 + reset_pin: GPIO16 + +<<: !include common.yaml diff --git a/tests/components/ade7880/test.esp32.yaml b/tests/components/ade7880/test.esp32.yaml new file mode 100644 index 0000000000..685b49ff32 --- /dev/null +++ b/tests/components/ade7880/test.esp32.yaml @@ -0,0 +1,8 @@ +substitutions: + scl_pin: GPIO5 + sda_pin: GPIO4 + irq0_pin: GPIO13 + irq1_pin: GPIO15 + reset_pin: GPIO16 + +<<: !include common.yaml diff --git a/tests/components/ade7880/test.esp8266.yaml b/tests/components/ade7880/test.esp8266.yaml new file mode 100644 index 0000000000..685b49ff32 --- /dev/null +++ b/tests/components/ade7880/test.esp8266.yaml @@ -0,0 +1,8 @@ +substitutions: + scl_pin: GPIO5 + sda_pin: GPIO4 + irq0_pin: GPIO13 + irq1_pin: GPIO15 + reset_pin: GPIO16 + +<<: !include common.yaml diff --git a/tests/components/ade7880/test.rp2040.yaml b/tests/components/ade7880/test.rp2040.yaml new file mode 100644 index 0000000000..685b49ff32 --- /dev/null +++ b/tests/components/ade7880/test.rp2040.yaml @@ -0,0 +1,8 @@ +substitutions: + scl_pin: GPIO5 + sda_pin: GPIO4 + irq0_pin: GPIO13 + irq1_pin: GPIO15 + reset_pin: GPIO16 + +<<: !include common.yaml diff --git a/tests/test1.yaml b/tests/test1.yaml index 14e3c40a67..e2d6a5f3d7 100644 --- a/tests/test1.yaml +++ b/tests/test1.yaml @@ -1771,6 +1771,62 @@ sensor: memory_location: 0x20 memory_address: 0x7d name: Adres sensor + - platform: ade7880 + i2c_id: i2c_bus + irq0_pin: + number: GPIO13 + allow_other_uses: true + irq1_pin: + number: GPIO5 + allow_other_uses: true + reset_pin: + number: GPIO16 + allow_other_uses: true + frequency: 60Hz + phase_a: + name: Channel A + voltage: Voltage + current: Current + active_power: Active Power + power_factor: Power Factor + forward_active_energy: Forward Active Energy + reverse_active_energy: Reverse Active Energy + calibration: + current_gain: 3116628 + voltage_gain: -757178 + power_gain: -1344457 + phase_angle: 188 + phase_b: + name: Channel B + voltage: Voltage + current: Current + active_power: Active Power + power_factor: Power Factor + forward_active_energy: Forward Active Energy + reverse_active_energy: Reverse Active Energy + calibration: + current_gain: 3133655 + voltage_gain: -755235 + power_gain: -1345638 + phase_angle: 188 + phase_c: + name: Channel C + voltage: Voltage + current: Current + active_power: Active Power + power_factor: Power Factor + forward_active_energy: Forward Active Energy + reverse_active_energy: Reverse Active Energy + calibration: + current_gain: 3111158 + voltage_gain: -743813 + power_gain: -1351437 + phase_angle: 180 + neutral: + name: Neutral + current: Current + calibration: + current_gain: 3189 psram: diff --git a/tests/test3.1.yaml b/tests/test3.1.yaml index 5cbdca91c1..fca37054a7 100644 --- a/tests/test3.1.yaml +++ b/tests/test3.1.yaml @@ -290,6 +290,62 @@ sensor: id: adc128s102_channel_0 channel: 0 + - platform: ade7880 + irq0_pin: + number: GPIO13 + allow_other_uses: true + irq1_pin: + number: GPIO5 + allow_other_uses: true + reset_pin: + number: GPIO16 + allow_other_uses: true + frequency: 60Hz + phase_a: + name: Channel A + voltage: Voltage + current: Current + active_power: Active Power + power_factor: Power Factor + forward_active_energy: Forward Active Energy + reverse_active_energy: Reverse Active Energy + calibration: + current_gain: 3116628 + voltage_gain: -757178 + power_gain: -1344457 + phase_angle: 188 + phase_b: + name: Channel B + voltage: Voltage + current: Current + active_power: Active Power + power_factor: Power Factor + forward_active_energy: Forward Active Energy + reverse_active_energy: Reverse Active Energy + calibration: + current_gain: 3133655 + voltage_gain: -755235 + power_gain: -1345638 + phase_angle: 188 + phase_c: + name: Channel C + voltage: Voltage + current: Current + active_power: Active Power + power_factor: Power Factor + forward_active_energy: Forward Active Energy + reverse_active_energy: Reverse Active Energy + calibration: + current_gain: 3111158 + voltage_gain: -743813 + power_gain: -1351437 + phase_angle: 180 + neutral: + name: Neutral + current: Current + calibration: + current_gain: 3189 + apds9960: address: 0x20 update_interval: 60s