mirror of https://github.com/esphome/esphome.git
128 lines
5.7 KiB
C++
128 lines
5.7 KiB
C++
#pragma once
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#include "esphome/core/component.h"
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#include "esphome/components/sensor/sensor.h"
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#include "esphome/components/spi/spi.h"
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#include "atm90e32_reg.h"
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namespace esphome {
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namespace atm90e32 {
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class ATM90E32Component : public PollingComponent,
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public spi::SPIDevice<spi::BIT_ORDER_MSB_FIRST, spi::CLOCK_POLARITY_HIGH,
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spi::CLOCK_PHASE_TRAILING, spi::DATA_RATE_1MHZ> {
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public:
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static const uint8_t PHASEA = 0;
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static const uint8_t PHASEB = 1;
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static const uint8_t PHASEC = 2;
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void loop() override;
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void setup() override;
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void dump_config() override;
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float get_setup_priority() const override;
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void update() override;
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void set_voltage_sensor(int phase, sensor::Sensor *obj) { this->phase_[phase].voltage_sensor_ = obj; }
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void set_current_sensor(int phase, sensor::Sensor *obj) { this->phase_[phase].current_sensor_ = obj; }
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void set_power_sensor(int phase, sensor::Sensor *obj) { this->phase_[phase].power_sensor_ = obj; }
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void set_reactive_power_sensor(int phase, sensor::Sensor *obj) { this->phase_[phase].reactive_power_sensor_ = obj; }
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void set_apparent_power_sensor(int phase, sensor::Sensor *obj) { this->phase_[phase].apparent_power_sensor_ = obj; }
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void set_forward_active_energy_sensor(int phase, sensor::Sensor *obj) {
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this->phase_[phase].forward_active_energy_sensor_ = obj;
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}
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void set_reverse_active_energy_sensor(int phase, sensor::Sensor *obj) {
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this->phase_[phase].reverse_active_energy_sensor_ = obj;
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}
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void set_power_factor_sensor(int phase, sensor::Sensor *obj) { this->phase_[phase].power_factor_sensor_ = obj; }
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void set_phase_angle_sensor(int phase, sensor::Sensor *obj) { this->phase_[phase].phase_angle_sensor_ = obj; }
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void set_harmonic_active_power_sensor(int phase, sensor::Sensor *obj) {
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this->phase_[phase].harmonic_active_power_sensor_ = obj;
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}
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void set_peak_current_sensor(int phase, sensor::Sensor *obj) { this->phase_[phase].peak_current_sensor_ = obj; }
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void set_volt_gain(int phase, uint16_t gain) { this->phase_[phase].voltage_gain_ = gain; }
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void set_ct_gain(int phase, uint16_t gain) { this->phase_[phase].ct_gain_ = gain; }
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void set_freq_sensor(sensor::Sensor *freq_sensor) { freq_sensor_ = freq_sensor; }
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void set_peak_current_signed(bool flag) { peak_current_signed_ = flag; }
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void set_chip_temperature_sensor(sensor::Sensor *chip_temperature_sensor) {
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chip_temperature_sensor_ = chip_temperature_sensor;
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}
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void set_line_freq(int freq) { line_freq_ = freq; }
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void set_current_phases(int phases) { current_phases_ = phases; }
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void set_pga_gain(uint16_t gain) { pga_gain_ = gain; }
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uint16_t calibrate_voltage_offset_phase(uint8_t /*phase*/);
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uint16_t calibrate_current_offset_phase(uint8_t /*phase*/);
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int32_t last_periodic_millis = millis();
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protected:
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uint16_t read16_(uint16_t a_register);
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int read32_(uint16_t addr_h, uint16_t addr_l);
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void write16_(uint16_t a_register, uint16_t val);
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float get_local_phase_voltage_(uint8_t /*phase*/);
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float get_local_phase_current_(uint8_t /*phase*/);
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float get_local_phase_active_power_(uint8_t /*phase*/);
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float get_local_phase_reactive_power_(uint8_t /*phase*/);
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float get_local_phase_power_factor_(uint8_t /*phase*/);
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float get_local_phase_forward_active_energy_(uint8_t /*phase*/);
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float get_local_phase_reverse_active_energy_(uint8_t /*phase*/);
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float get_local_phase_angle_(uint8_t /*phase*/);
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float get_local_phase_harmonic_active_power_(uint8_t /*phase*/);
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float get_local_phase_peak_current_(uint8_t /*phase*/);
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float get_phase_voltage_(uint8_t /*phase*/);
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float get_phase_voltage_avg_(uint8_t /*phase*/);
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float get_phase_current_(uint8_t /*phase*/);
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float get_phase_current_avg_(uint8_t /*phase*/);
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float get_phase_active_power_(uint8_t /*phase*/);
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float get_phase_reactive_power_(uint8_t /*phase*/);
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float get_phase_power_factor_(uint8_t /*phase*/);
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float get_phase_forward_active_energy_(uint8_t /*phase*/);
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float get_phase_reverse_active_energy_(uint8_t /*phase*/);
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float get_phase_angle_(uint8_t /*phase*/);
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float get_phase_harmonic_active_power_(uint8_t /*phase*/);
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float get_phase_peak_current_(uint8_t /*phase*/);
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float get_frequency_();
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float get_chip_temperature_();
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bool get_publish_interval_flag_() { return publish_interval_flag_; };
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void set_publish_interval_flag_(bool flag) { publish_interval_flag_ = flag; };
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struct ATM90E32Phase {
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uint16_t voltage_gain_{7305};
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uint16_t ct_gain_{27961};
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uint16_t voltage_offset_{0};
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uint16_t current_offset_{0};
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float voltage_{0};
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float current_{0};
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float active_power_{0};
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float reactive_power_{0};
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float power_factor_{0};
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float forward_active_energy_{0};
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float reverse_active_energy_{0};
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float phase_angle_{0};
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float harmonic_active_power_{0};
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float peak_current_{0};
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sensor::Sensor *voltage_sensor_{nullptr};
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sensor::Sensor *current_sensor_{nullptr};
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sensor::Sensor *power_sensor_{nullptr};
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sensor::Sensor *reactive_power_sensor_{nullptr};
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sensor::Sensor *apparent_power_sensor_{nullptr};
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sensor::Sensor *power_factor_sensor_{nullptr};
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sensor::Sensor *forward_active_energy_sensor_{nullptr};
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sensor::Sensor *reverse_active_energy_sensor_{nullptr};
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sensor::Sensor *phase_angle_sensor_{nullptr};
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sensor::Sensor *harmonic_active_power_sensor_{nullptr};
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sensor::Sensor *peak_current_sensor_{nullptr};
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uint32_t cumulative_forward_active_energy_{0};
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uint32_t cumulative_reverse_active_energy_{0};
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} phase_[3];
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sensor::Sensor *freq_sensor_{nullptr};
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sensor::Sensor *chip_temperature_sensor_{nullptr};
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uint16_t pga_gain_{0x15};
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int line_freq_{60};
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int current_phases_{3};
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bool publish_interval_flag_{true};
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bool peak_current_signed_{false};
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};
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} // namespace atm90e32
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} // namespace esphome
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