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Add spi support for ade7953 (#5439) 

Co-authored-by: Jesse Hills <3060199+jesserockz@users.noreply.github.com>
This commit is contained in:
Angel Nunez Mencias 2023-11-07 01:17:29 +01:00 committed by GitHub
parent 7ac9caa169
commit defe8ac97b
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GPG Key ID: 4AEE18F83AFDEB23
18 changed files with 834 additions and 241 deletions
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3
CODEOWNERS
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@ -17,6 +17,9 @@ esphome/components/ac_dimmer/* @glmnet
esphome/components/adc/* @esphome/core
esphome/components/adc128s102/* @DeerMaximum
esphome/components/addressable_light/* @justfalter
esphome/components/ade7953/* @angelnu
esphome/components/ade7953_i2c/* @angelnu
esphome/components/ade7953_spi/* @angelnu
esphome/components/airthings_ble/* @jeromelaban
esphome/components/airthings_wave_base/* @jeromelaban @kpfleming @ncareau
esphome/components/airthings_wave_mini/* @ncareau

1
esphome/components/ade7953/__init__.py
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@ -0,0 +1 @@
CODEOWNERS = ["@angelnu"]

53
esphome/components/ade7953/ade7953.cpp
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@ -1,53 +0,0 @@
#include "ade7953.h"
#include "esphome/core/log.h"
namespace esphome {
namespace ade7953 {
static const char *const TAG = "ade7953";
void ADE7953::dump_config() {
ESP_LOGCONFIG(TAG, "ADE7953:");
LOG_PIN(" IRQ Pin: ", irq_pin_);
LOG_I2C_DEVICE(this);
LOG_UPDATE_INTERVAL(this);
LOG_SENSOR(" ", "Voltage Sensor", this->voltage_sensor_);
LOG_SENSOR(" ", "Current A Sensor", this->current_a_sensor_);
LOG_SENSOR(" ", "Current B Sensor", this->current_b_sensor_);
LOG_SENSOR(" ", "Active Power A Sensor", this->active_power_a_sensor_);
LOG_SENSOR(" ", "Active Power B Sensor", this->active_power_b_sensor_);
}
#define ADE_PUBLISH_(name, val, factor) \
if (err == i2c::ERROR_OK && this->name##_sensor_) { \
float value = (val) / (factor); \
this->name##_sensor_->publish_state(value); \
}
#define ADE_PUBLISH(name, val, factor) ADE_PUBLISH_(name, val, factor)
void ADE7953::update() {
if (!this->is_setup_)
return;
uint32_t val;
i2c::ErrorCode err = ade_read_32_(0x0312, &val);
ADE_PUBLISH(active_power_a, (int32_t) val, 154.0f);
err = ade_read_32_(0x0313, &val);
ADE_PUBLISH(active_power_b, (int32_t) val, 154.0f);
err = ade_read_32_(0x031A, &val);
ADE_PUBLISH(current_a, (uint32_t) val, 100000.0f);
err = ade_read_32_(0x031B, &val);
ADE_PUBLISH(current_b, (uint32_t) val, 100000.0f);
err = ade_read_32_(0x031C, &val);
ADE_PUBLISH(voltage, (uint32_t) val, 26000.0f);
// auto apparent_power_a = this->ade_read_<int32_t>(0x0310);
// auto apparent_power_b = this->ade_read_<int32_t>(0x0311);
// auto reactive_power_a = this->ade_read_<int32_t>(0x0314);
// auto reactive_power_b = this->ade_read_<int32_t>(0x0315);
// auto power_factor_a = this->ade_read_<int16_t>(0x010A);
// auto power_factor_b = this->ade_read_<int16_t>(0x010B);
}
} // namespace ade7953
} // namespace esphome

97
esphome/components/ade7953/ade7953.h
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@ -1,97 +0,0 @@
#pragma once
#include "esphome/core/component.h"
#include "esphome/core/hal.h"
#include "esphome/components/i2c/i2c.h"
#include "esphome/components/sensor/sensor.h"
#include <vector>
namespace esphome {
namespace ade7953 {
class ADE7953 : public i2c::I2CDevice, public PollingComponent {
public:
void set_irq_pin(InternalGPIOPin *irq_pin) { irq_pin_ = irq_pin; }
void set_voltage_sensor(sensor::Sensor *voltage_sensor) { voltage_sensor_ = voltage_sensor; }
void set_current_a_sensor(sensor::Sensor *current_a_sensor) { current_a_sensor_ = current_a_sensor; }
void set_current_b_sensor(sensor::Sensor *current_b_sensor) { current_b_sensor_ = current_b_sensor; }
void set_active_power_a_sensor(sensor::Sensor *active_power_a_sensor) {
active_power_a_sensor_ = active_power_a_sensor;
}
void set_active_power_b_sensor(sensor::Sensor *active_power_b_sensor) {
active_power_b_sensor_ = active_power_b_sensor;
}
void setup() override {
if (this->irq_pin_ != nullptr) {
this->irq_pin_->setup();
}
this->set_timeout(100, [this]() {
this->ade_write_8_(0x0010, 0x04);
this->ade_write_8_(0x00FE, 0xAD);
this->ade_write_16_(0x0120, 0x0030);
this->is_setup_ = true;
});
}
void dump_config() override;
void update() override;
protected:
i2c::ErrorCode ade_write_8_(uint16_t reg, uint8_t value) {
std::vector<uint8_t> data;
data.push_back(reg >> 8);
data.push_back(reg >> 0);
data.push_back(value);
return write(data.data(), data.size());
}
i2c::ErrorCode ade_write_16_(uint16_t reg, uint16_t value) {
std::vector<uint8_t> data;
data.push_back(reg >> 8);
data.push_back(reg >> 0);
data.push_back(value >> 8);
data.push_back(value >> 0);
return write(data.data(), data.size());
}
i2c::ErrorCode ade_write_32_(uint16_t reg, uint32_t value) {
std::vector<uint8_t> data;
data.push_back(reg >> 8);
data.push_back(reg >> 0);
data.push_back(value >> 24);
data.push_back(value >> 16);
data.push_back(value >> 8);
data.push_back(value >> 0);
return write(data.data(), data.size());
}
i2c::ErrorCode ade_read_32_(uint16_t reg, uint32_t *value) {
uint8_t reg_data[2];
reg_data[0] = reg >> 8;
reg_data[1] = reg >> 0;
i2c::ErrorCode err = write(reg_data, 2);
if (err != i2c::ERROR_OK)
return err;
uint8_t recv[4];
err = read(recv, 4);
if (err != i2c::ERROR_OK)
return err;
*value = 0;
*value |= ((uint32_t) recv[0]) << 24;
*value |= ((uint32_t) recv[1]) << 16;
*value |= ((uint32_t) recv[2]) << 8;
*value |= ((uint32_t) recv[3]);
return i2c::ERROR_OK;
}
InternalGPIOPin *irq_pin_{nullptr};
bool is_setup_{false};
sensor::Sensor *voltage_sensor_{nullptr};
sensor::Sensor *current_a_sensor_{nullptr};
sensor::Sensor *current_b_sensor_{nullptr};
sensor::Sensor *active_power_a_sensor_{nullptr};
sensor::Sensor *active_power_b_sensor_{nullptr};
};
} // namespace ade7953
} // namespace esphome

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esphome/components/ade7953/sensor.py
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@ -1,90 +1,5 @@
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_ID,
CONF_IRQ_PIN,
CONF_VOLTAGE,
DEVICE_CLASS_CURRENT,
DEVICE_CLASS_POWER,
DEVICE_CLASS_VOLTAGE,
STATE_CLASS_MEASUREMENT,
UNIT_AMPERE,
UNIT_VOLT,
UNIT_WATT,
CONFIG_SCHEMA = CONFIG_SCHEMA = cv.invalid(
"The ade7953 sensor component has been renamed to ade7953_i2c."
)
DEPENDENCIES = ["i2c"]
ade7953_ns = cg.esphome_ns.namespace("ade7953")
ADE7953 = ade7953_ns.class_("ADE7953", cg.PollingComponent, i2c.I2CDevice)
CONF_CURRENT_A = "current_a"
CONF_CURRENT_B = "current_b"
CONF_ACTIVE_POWER_A = "active_power_a"
CONF_ACTIVE_POWER_B = "active_power_b"
CONFIG_SCHEMA = (
cv.Schema(
{
cv.GenerateID(): cv.declare_id(ADE7953),
cv.Optional(CONF_IRQ_PIN): pins.internal_gpio_input_pin_schema,
cv.Optional(CONF_VOLTAGE): sensor.sensor_schema(
unit_of_measurement=UNIT_VOLT,
accuracy_decimals=1,
device_class=DEVICE_CLASS_VOLTAGE,
state_class=STATE_CLASS_MEASUREMENT,
),
cv.Optional(CONF_CURRENT_A): sensor.sensor_schema(
unit_of_measurement=UNIT_AMPERE,
accuracy_decimals=2,
device_class=DEVICE_CLASS_CURRENT,
state_class=STATE_CLASS_MEASUREMENT,
),
cv.Optional(CONF_CURRENT_B): sensor.sensor_schema(
unit_of_measurement=UNIT_AMPERE,
accuracy_decimals=2,
device_class=DEVICE_CLASS_CURRENT,
state_class=STATE_CLASS_MEASUREMENT,
),
cv.Optional(CONF_ACTIVE_POWER_A): sensor.sensor_schema(
unit_of_measurement=UNIT_WATT,
accuracy_decimals=1,
device_class=DEVICE_CLASS_POWER,
state_class=STATE_CLASS_MEASUREMENT,
),
cv.Optional(CONF_ACTIVE_POWER_B): sensor.sensor_schema(
unit_of_measurement=UNIT_WATT,
accuracy_decimals=1,
device_class=DEVICE_CLASS_POWER,
state_class=STATE_CLASS_MEASUREMENT,
),
}
)
.extend(cv.polling_component_schema("60s"))
.extend(i2c.i2c_device_schema(0x38))
)
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 irq_pin_config := config.get(CONF_IRQ_PIN):
irq_pin = await cg.gpio_pin_expression(irq_pin_config)
cg.add(var.set_irq_pin(irq_pin))
for key in [
CONF_VOLTAGE,
CONF_CURRENT_A,
CONF_CURRENT_B,
CONF_ACTIVE_POWER_A,
CONF_ACTIVE_POWER_B,
]:
if key not in config:
continue
conf = config[key]
sens = await sensor.new_sensor(conf)
cg.add(getattr(var, f"set_{key}_sensor")(sens))

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esphome/components/ade7953_base/__init__.py Normal file
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import esphome.codegen as cg
import esphome.config_validation as cv
from esphome.components import sensor
from esphome import pins
from esphome.const import (
CONF_IRQ_PIN,
CONF_VOLTAGE,
CONF_FREQUENCY,
DEVICE_CLASS_CURRENT,
DEVICE_CLASS_APPARENT_POWER,
DEVICE_CLASS_POWER,
DEVICE_CLASS_REACTIVE_POWER,
DEVICE_CLASS_POWER_FACTOR,
DEVICE_CLASS_VOLTAGE,
DEVICE_CLASS_FREQUENCY,
STATE_CLASS_MEASUREMENT,
UNIT_VOLT,
UNIT_HERTZ,
UNIT_AMPERE,
UNIT_VOLT_AMPS,
UNIT_WATT,
UNIT_VOLT_AMPS_REACTIVE,
UNIT_PERCENT,
)
CONF_CURRENT_A = "current_a"
CONF_CURRENT_B = "current_b"
CONF_ACTIVE_POWER_A = "active_power_a"
CONF_ACTIVE_POWER_B = "active_power_b"
CONF_APPARENT_POWER_A = "apparent_power_a"
CONF_APPARENT_POWER_B = "apparent_power_b"
CONF_REACTIVE_POWER_A = "reactive_power_a"
CONF_REACTIVE_POWER_B = "reactive_power_b"
CONF_POWER_FACTOR_A = "power_factor_a"
CONF_POWER_FACTOR_B = "power_factor_b"
CONF_VOLTAGE_PGA_GAIN = "voltage_pga_gain"
CONF_CURRENT_PGA_GAIN_A = "current_pga_gain_a"
CONF_CURRENT_PGA_GAIN_B = "current_pga_gain_b"
CONF_VOLTAGE_GAIN = "voltage_gain"
CONF_CURRENT_GAIN_A = "current_gain_a"
CONF_CURRENT_GAIN_B = "current_gain_b"
CONF_ACTIVE_POWER_GAIN_A = "active_power_gain_a"
CONF_ACTIVE_POWER_GAIN_B = "active_power_gain_b"
PGA_GAINS = {
"1x": 0b000,
"2x": 0b001,
"4x": 0b010,
"8x": 0b011,
"16x": 0b100,
"22x": 0b101,
}
ade7953_base_ns = cg.esphome_ns.namespace("ade7953_base")
ADE7953 = ade7953_base_ns.class_("ADE7953", cg.PollingComponent)
ADE7953_CONFIG_SCHEMA = cv.Schema(
{
cv.Optional(CONF_IRQ_PIN): pins.internal_gpio_input_pin_schema,
cv.Optional(CONF_VOLTAGE): sensor.sensor_schema(
unit_of_measurement=UNIT_VOLT,
accuracy_decimals=1,
device_class=DEVICE_CLASS_VOLTAGE,
state_class=STATE_CLASS_MEASUREMENT,
),
cv.Optional(CONF_FREQUENCY): sensor.sensor_schema(
unit_of_measurement=UNIT_HERTZ,
accuracy_decimals=2,
device_class=DEVICE_CLASS_FREQUENCY,
state_class=STATE_CLASS_MEASUREMENT,
),
cv.Optional(CONF_CURRENT_A): sensor.sensor_schema(
unit_of_measurement=UNIT_AMPERE,
accuracy_decimals=2,
device_class=DEVICE_CLASS_CURRENT,
state_class=STATE_CLASS_MEASUREMENT,
),
cv.Optional(CONF_CURRENT_B): sensor.sensor_schema(
unit_of_measurement=UNIT_AMPERE,
accuracy_decimals=2,
device_class=DEVICE_CLASS_CURRENT,
state_class=STATE_CLASS_MEASUREMENT,
),
cv.Optional(CONF_ACTIVE_POWER_A): sensor.sensor_schema(
unit_of_measurement=UNIT_WATT,
accuracy_decimals=1,
device_class=DEVICE_CLASS_POWER,
state_class=STATE_CLASS_MEASUREMENT,
),
cv.Optional(CONF_ACTIVE_POWER_B): sensor.sensor_schema(
unit_of_measurement=UNIT_WATT,
accuracy_decimals=1,
device_class=DEVICE_CLASS_POWER,
state_class=STATE_CLASS_MEASUREMENT,
),
cv.Optional(CONF_APPARENT_POWER_A): sensor.sensor_schema(
unit_of_measurement=UNIT_VOLT_AMPS,
accuracy_decimals=1,
device_class=DEVICE_CLASS_APPARENT_POWER,
state_class=STATE_CLASS_MEASUREMENT,
),
cv.Optional(CONF_APPARENT_POWER_B): sensor.sensor_schema(
unit_of_measurement=UNIT_VOLT_AMPS,
accuracy_decimals=1,
device_class=DEVICE_CLASS_APPARENT_POWER,
state_class=STATE_CLASS_MEASUREMENT,
),
cv.Optional(CONF_REACTIVE_POWER_A): sensor.sensor_schema(
unit_of_measurement=UNIT_VOLT_AMPS_REACTIVE,
accuracy_decimals=1,
device_class=DEVICE_CLASS_REACTIVE_POWER,
state_class=STATE_CLASS_MEASUREMENT,
),
cv.Optional(CONF_REACTIVE_POWER_B): sensor.sensor_schema(
unit_of_measurement=UNIT_VOLT_AMPS_REACTIVE,
accuracy_decimals=1,
device_class=DEVICE_CLASS_REACTIVE_POWER,
state_class=STATE_CLASS_MEASUREMENT,
),
cv.Optional(CONF_POWER_FACTOR_A): sensor.sensor_schema(
unit_of_measurement=UNIT_PERCENT,
accuracy_decimals=2,
device_class=DEVICE_CLASS_POWER_FACTOR,
state_class=STATE_CLASS_MEASUREMENT,
),
cv.Optional(CONF_POWER_FACTOR_B): sensor.sensor_schema(
unit_of_measurement=UNIT_PERCENT,
accuracy_decimals=2,
device_class=DEVICE_CLASS_POWER_FACTOR,
state_class=STATE_CLASS_MEASUREMENT,
),
cv.Optional(
CONF_VOLTAGE_PGA_GAIN,
default="1x",
): cv.one_of(*PGA_GAINS, lower=True),
cv.Optional(
CONF_CURRENT_PGA_GAIN_A,
default="1x",
): cv.one_of(*PGA_GAINS, lower=True),
cv.Optional(
CONF_CURRENT_PGA_GAIN_B,
default="1x",
): cv.one_of(*PGA_GAINS, lower=True),
cv.Optional(CONF_VOLTAGE_GAIN, default=0x400000): cv.hex_int_range(
min=0x100000, max=0x800000
),
cv.Optional(CONF_CURRENT_GAIN_A, default=0x400000): cv.hex_int_range(
min=0x100000, max=0x800000
),
cv.Optional(CONF_CURRENT_GAIN_B, default=0x400000): cv.hex_int_range(
min=0x100000, max=0x800000
),
cv.Optional(CONF_ACTIVE_POWER_GAIN_A, default=0x400000): cv.hex_int_range(
min=0x100000, max=0x800000
),
cv.Optional(CONF_ACTIVE_POWER_GAIN_B, default=0x400000): cv.hex_int_range(
min=0x100000, max=0x800000
),
}
).extend(cv.polling_component_schema("60s"))
async def register_ade7953(var, config):
await cg.register_component(var, config)
if irq_pin_config := config.get(CONF_IRQ_PIN):
irq_pin = await cg.gpio_pin_expression(irq_pin_config)
cg.add(var.set_irq_pin(irq_pin))
cg.add(var.set_pga_v(PGA_GAINS[config.get(CONF_VOLTAGE_PGA_GAIN)]))
cg.add(var.set_pga_ia(PGA_GAINS[config.get(CONF_CURRENT_PGA_GAIN_A)]))
cg.add(var.set_pga_ib(PGA_GAINS[config.get(CONF_CURRENT_PGA_GAIN_B)]))
cg.add(var.set_vgain(config.get(CONF_VOLTAGE_GAIN)))
cg.add(var.set_aigain(config.get(CONF_CURRENT_GAIN_A)))
cg.add(var.set_bigain(config.get(CONF_CURRENT_GAIN_B)))
cg.add(var.set_awgain(config.get(CONF_ACTIVE_POWER_GAIN_A)))
cg.add(var.set_bwgain(config.get(CONF_ACTIVE_POWER_GAIN_B)))
for key in [
CONF_VOLTAGE,
CONF_FREQUENCY,
CONF_CURRENT_A,
CONF_CURRENT_B,
CONF_POWER_FACTOR_A,
CONF_POWER_FACTOR_B,
CONF_APPARENT_POWER_A,
CONF_APPARENT_POWER_B,
CONF_ACTIVE_POWER_A,
CONF_ACTIVE_POWER_B,
CONF_REACTIVE_POWER_A,
CONF_REACTIVE_POWER_B,
]:
if key not in config:
continue
conf = config[key]
sens = await sensor.new_sensor(conf)
cg.add(getattr(var, f"set_{key}_sensor")(sens))

129
esphome/components/ade7953_base/ade7953_base.cpp Normal file
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#include "ade7953_base.h"
#include "esphome/core/log.h"
namespace esphome {
namespace ade7953_base {
static const char *const TAG = "ade7953";
void ADE7953::setup() {
if (this->irq_pin_ != nullptr) {
this->irq_pin_->setup();
}
// The chip might take up to 100ms to initialise
this->set_timeout(100, [this]() {
// this->ade_write_8(0x0010, 0x04);
this->ade_write_8(0x00FE, 0xAD);
this->ade_write_16(0x0120, 0x0030);
// Set gains
this->ade_write_8(PGA_V_8, pga_v_);
this->ade_write_8(PGA_IA_8, pga_ia_);
this->ade_write_8(PGA_IB_8, pga_ib_);
this->ade_write_32(AVGAIN_32, vgain_);
this->ade_write_32(AIGAIN_32, aigain_);
this->ade_write_32(BIGAIN_32, bigain_);
this->ade_write_32(AWGAIN_32, awgain_);
this->ade_write_32(BWGAIN_32, bwgain_);
// Read back gains for debugging
this->ade_read_8(PGA_V_8, &pga_v_);
this->ade_read_8(PGA_IA_8, &pga_ia_);
this->ade_read_8(PGA_IB_8, &pga_ib_);
this->ade_read_32(AVGAIN_32, &vgain_);
this->ade_read_32(AIGAIN_32, &aigain_);
this->ade_read_32(BIGAIN_32, &bigain_);
this->ade_read_32(AWGAIN_32, &awgain_);
this->ade_read_32(BWGAIN_32, &bwgain_);
this->is_setup_ = true;
});
}
void ADE7953::dump_config() {
LOG_PIN(" IRQ Pin: ", irq_pin_);
LOG_UPDATE_INTERVAL(this);
LOG_SENSOR(" ", "Voltage Sensor", this->voltage_sensor_);
LOG_SENSOR(" ", "Current A Sensor", this->current_a_sensor_);
LOG_SENSOR(" ", "Current B Sensor", this->current_b_sensor_);
LOG_SENSOR(" ", "Power Factor A Sensor", this->power_factor_a_sensor_);
LOG_SENSOR(" ", "Power Factor B Sensor", this->power_factor_b_sensor_);
LOG_SENSOR(" ", "Apparent Power A Sensor", this->apparent_power_a_sensor_);
LOG_SENSOR(" ", "Apparent Power B Sensor", this->apparent_power_b_sensor_);
LOG_SENSOR(" ", "Active Power A Sensor", this->active_power_a_sensor_);
LOG_SENSOR(" ", "Active Power B Sensor", this->active_power_b_sensor_);
LOG_SENSOR(" ", "Rective Power A Sensor", this->reactive_power_a_sensor_);
LOG_SENSOR(" ", "Reactive Power B Sensor", this->reactive_power_b_sensor_);
ESP_LOGCONFIG(TAG, " PGA_V_8: 0x%X", pga_v_);
ESP_LOGCONFIG(TAG, " PGA_IA_8: 0x%X", pga_ia_);
ESP_LOGCONFIG(TAG, " PGA_IB_8: 0x%X", pga_ib_);
ESP_LOGCONFIG(TAG, " VGAIN_32: 0x%08jX", (uintmax_t) vgain_);
ESP_LOGCONFIG(TAG, " AIGAIN_32: 0x%08jX", (uintmax_t) aigain_);
ESP_LOGCONFIG(TAG, " BIGAIN_32: 0x%08jX", (uintmax_t) bigain_);
ESP_LOGCONFIG(TAG, " AWGAIN_32: 0x%08jX", (uintmax_t) awgain_);
ESP_LOGCONFIG(TAG, " BWGAIN_32: 0x%08jX", (uintmax_t) bwgain_);
}
#define ADE_PUBLISH_(name, val, factor) \
if (err == 0 && this->name##_sensor_) { \
float value = (val) / (factor); \
this->name##_sensor_->publish_state(value); \
}
#define ADE_PUBLISH(name, val, factor) ADE_PUBLISH_(name, val, factor)
void ADE7953::update() {
if (!this->is_setup_)
return;
bool err;
uint32_t interrupts_a = 0;
uint32_t interrupts_b = 0;
if (this->irq_pin_ != nullptr) {
// Read and reset interrupts
this->ade_read_32(0x032E, &interrupts_a);
this->ade_read_32(0x0331, &interrupts_b);
}
uint32_t val;
uint16_t val_16;
// Power factor
err = this->ade_read_16(0x010A, &val_16);
ADE_PUBLISH(power_factor_a, (int16_t) val_16, (0x7FFF / 100.0f));
err = this->ade_read_16(0x010B, &val_16);
ADE_PUBLISH(power_factor_b, (int16_t) val_16, (0x7FFF / 100.0f));
// Apparent power
err = this->ade_read_32(0x0310, &val);
ADE_PUBLISH(apparent_power_a, (int32_t) val, 154.0f);
err = this->ade_read_32(0x0311, &val);
ADE_PUBLISH(apparent_power_b, (int32_t) val, 154.0f);
// Active power
err = this->ade_read_32(0x0312, &val);
ADE_PUBLISH(active_power_a, (int32_t) val, 154.0f);
err = this->ade_read_32(0x0313, &val);
ADE_PUBLISH(active_power_b, (int32_t) val, 154.0f);
// Reactive power
err = this->ade_read_32(0x0314, &val);
ADE_PUBLISH(reactive_power_a, (int32_t) val, 154.0f);
err = this->ade_read_32(0x0315, &val);
ADE_PUBLISH(reactive_power_b, (int32_t) val, 154.0f);
// Current
err = this->ade_read_32(0x031A, &val);
ADE_PUBLISH(current_a, (uint32_t) val, 100000.0f);
err = this->ade_read_32(0x031B, &val);
ADE_PUBLISH(current_b, (uint32_t) val, 100000.0f);
// Voltage
err = this->ade_read_32(0x031C, &val);
ADE_PUBLISH(voltage, (uint32_t) val, 26000.0f);
// Frequency
err = this->ade_read_16(0x010E, &val_16);
ADE_PUBLISH(frequency, 223750.0f, 1 + val_16);
}
} // namespace ade7953_base
} // namespace esphome

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esphome/components/ade7953_base/ade7953_base.h Normal file
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#pragma once
#include "esphome/core/component.h"
#include "esphome/core/hal.h"
#include "esphome/components/sensor/sensor.h"
#include <vector>
namespace esphome {
namespace ade7953_base {
static const uint8_t PGA_V_8 =
0x007; // PGA_V, (R/W) Default: 0x00, Unsigned, Voltage channel gain configuration (Bits[2:0])
static const uint8_t PGA_IA_8 =
0x008; // PGA_IA, (R/W) Default: 0x00, Unsigned, Current Channel A gain configuration (Bits[2:0])
static const uint8_t PGA_IB_8 =
0x009; // PGA_IB, (R/W) Default: 0x00, Unsigned, Current Channel B gain configuration (Bits[2:0])
static const uint32_t AIGAIN_32 =
0x380; // AIGAIN, (R/W) Default: 0x400000, Unsigned,Current channel gain (Current Channel A)(32 bit)
static const uint32_t AVGAIN_32 = 0x381; // AVGAIN, (R/W) Default: 0x400000, Unsigned,Voltage channel gain(32 bit)
static const uint32_t AWGAIN_32 =
0x382; // AWGAIN, (R/W) Default: 0x400000, Unsigned,Active power gain (Current Channel A)(32 bit)
static const uint32_t AVARGAIN_32 =
0x383; // AVARGAIN, (R/W) Default: 0x400000, Unsigned, Reactive power gain (Current Channel A)(32 bit)
static const uint32_t AVAGAIN_32 =
0x384; // AVAGAIN, (R/W) Default: 0x400000, Unsigned,Apparent power gain (Current Channel A)(32 bit)
static const uint32_t BIGAIN_32 =
0x38C; // BIGAIN, (R/W) Default: 0x400000, Unsigned,Current channel gain (Current Channel B)(32 bit)
static const uint32_t BVGAIN_32 = 0x38D; // BVGAIN, (R/W) Default: 0x400000, Unsigned,Voltage channel gain(32 bit)
static const uint32_t BWGAIN_32 =
0x38E; // BWGAIN, (R/W) Default: 0x400000, Unsigned,Active power gain (Current Channel B)(32 bit)
static const uint32_t BVARGAIN_32 =
0x38F; // BVARGAIN, (R/W) Default: 0x400000, Unsigned, Reactive power gain (Current Channel B)(32 bit)
static const uint32_t BVAGAIN_32 =
0x390; // BVAGAIN, (R/W) Default: 0x400000, Unsigned,Apparent power gain (Current Channel B)(32 bit)
class ADE7953 : public PollingComponent, public sensor::Sensor {
public:
void set_irq_pin(InternalGPIOPin *irq_pin) { irq_pin_ = irq_pin; }
// Set PGA input gains: 0 1x, 1 2x, 0b10 4x
void set_pga_v(uint8_t pga_v) { pga_v_ = pga_v; }
void set_pga_ia(uint8_t pga_ia) { pga_ia_ = pga_ia; }
void set_pga_ib(uint8_t pga_ib) { pga_ib_ = pga_ib; }
// Set input gains
void set_vgain(uint32_t vgain) { vgain_ = vgain; }
void set_aigain(uint32_t aigain) { aigain_ = aigain; }
void set_bigain(uint32_t bigain) { bigain_ = bigain; }
void set_awgain(uint32_t awgain) { awgain_ = awgain; }
void set_bwgain(uint32_t bwgain) { bwgain_ = bwgain; }
void set_voltage_sensor(sensor::Sensor *voltage_sensor) { voltage_sensor_ = voltage_sensor; }
void set_frequency_sensor(sensor::Sensor *frequency_sensor) { frequency_sensor_ = frequency_sensor; }
void set_power_factor_a_sensor(sensor::Sensor *power_factor_a) { power_factor_a_sensor_ = power_factor_a; }
void set_power_factor_b_sensor(sensor::Sensor *power_factor_b) { power_factor_b_sensor_ = power_factor_b; }
void set_current_a_sensor(sensor::Sensor *current_a_sensor) { current_a_sensor_ = current_a_sensor; }
void set_current_b_sensor(sensor::Sensor *current_b_sensor) { current_b_sensor_ = current_b_sensor; }
void set_apparent_power_a_sensor(sensor::Sensor *apparent_power_a) { apparent_power_a_sensor_ = apparent_power_a; }
void set_apparent_power_b_sensor(sensor::Sensor *apparent_power_b) { apparent_power_b_sensor_ = apparent_power_b; }
void set_active_power_a_sensor(sensor::Sensor *active_power_a_sensor) {
active_power_a_sensor_ = active_power_a_sensor;
}
void set_active_power_b_sensor(sensor::Sensor *active_power_b_sensor) {
active_power_b_sensor_ = active_power_b_sensor;
}
void set_reactive_power_a_sensor(sensor::Sensor *reactive_power_a) { reactive_power_a_sensor_ = reactive_power_a; }
void set_reactive_power_b_sensor(sensor::Sensor *reactive_power_b) { reactive_power_b_sensor_ = reactive_power_b; }
void setup() override;
void dump_config() override;
void update() override;
protected:
InternalGPIOPin *irq_pin_{nullptr};
bool is_setup_{false};
sensor::Sensor *voltage_sensor_{nullptr};
sensor::Sensor *frequency_sensor_{nullptr};
sensor::Sensor *current_a_sensor_{nullptr};
sensor::Sensor *current_b_sensor_{nullptr};
sensor::Sensor *apparent_power_a_sensor_{nullptr};
sensor::Sensor *apparent_power_b_sensor_{nullptr};
sensor::Sensor *active_power_a_sensor_{nullptr};
sensor::Sensor *active_power_b_sensor_{nullptr};
sensor::Sensor *reactive_power_a_sensor_{nullptr};
sensor::Sensor *reactive_power_b_sensor_{nullptr};
sensor::Sensor *power_factor_a_sensor_{nullptr};
sensor::Sensor *power_factor_b_sensor_{nullptr};
uint8_t pga_v_;
uint8_t pga_ia_;
uint8_t pga_ib_;
uint32_t vgain_;
uint32_t aigain_;
uint32_t bigain_;
uint32_t awgain_;
uint32_t bwgain_;
virtual bool ade_write_8(uint16_t reg, uint8_t value) = 0;
virtual bool ade_write_16(uint16_t reg, uint16_t value) = 0;
virtual bool ade_write_32(uint16_t reg, uint32_t value) = 0;
virtual bool ade_read_8(uint16_t reg, uint8_t *value) = 0;
virtual bool ade_read_16(uint16_t reg, uint16_t *value) = 0;
virtual bool ade_read_32(uint16_t reg, uint32_t *value) = 0;
};
} // namespace ade7953_base
} // namespace esphome

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esphome/components/ade7953_i2c/__init__.py Normal file
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CODEOWNERS = ["@angelnu"]

80
esphome/components/ade7953_i2c/ade7953_i2c.cpp Normal file
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#include "ade7953_i2c.h"
#include "esphome/core/log.h"
#include "esphome/core/helpers.h"
namespace esphome {
namespace ade7953_i2c {
static const char *const TAG = "ade7953";
void AdE7953I2c::dump_config() {
ESP_LOGCONFIG(TAG, "ADE7953_i2c:");
LOG_I2C_DEVICE(this);
ade7953_base::ADE7953::dump_config();
}
bool AdE7953I2c::ade_write_8(uint16_t reg, uint8_t value) {
std::vector<uint8_t> data(3);
data.push_back(reg >> 8);
data.push_back(reg >> 0);
data.push_back(value);
return this->write(data.data(), data.size()) != i2c::ERROR_OK;
}
bool AdE7953I2c::ade_write_16(uint16_t reg, uint16_t value) {
std::vector<uint8_t> data(4);
data.push_back(reg >> 8);
data.push_back(reg >> 0);
data.push_back(value >> 8);
data.push_back(value >> 0);
return this->write(data.data(), data.size()) != i2c::ERROR_OK;
}
bool AdE7953I2c::ade_write_32(uint16_t reg, uint32_t value) {
std::vector<uint8_t> data(6);
data.push_back(reg >> 8);
data.push_back(reg >> 0);
data.push_back(value >> 24);
data.push_back(value >> 16);
data.push_back(value >> 8);
data.push_back(value >> 0);
return this->write(data.data(), data.size()) != i2c::ERROR_OK;
}
bool AdE7953I2c::ade_read_8(uint16_t reg, uint8_t *value) {
uint8_t reg_data[2];
reg_data[0] = reg >> 8;
reg_data[1] = reg >> 0;
i2c::ErrorCode err = this->write(reg_data, 2);
if (err != i2c::ERROR_OK)
return true;
err = this->read(value, 1);
return (err != i2c::ERROR_OK);
}
bool AdE7953I2c::ade_read_16(uint16_t reg, uint16_t *value) {
uint8_t reg_data[2];
reg_data[0] = reg >> 8;
reg_data[1] = reg >> 0;
i2c::ErrorCode err = this->write(reg_data, 2);
if (err != i2c::ERROR_OK)
return true;
uint8_t recv[2];
err = this->read(recv, 2);
if (err != i2c::ERROR_OK)
return true;
*value = encode_uint16(recv[0], recv[1]);
return false;
}
bool AdE7953I2c::ade_read_32(uint16_t reg, uint32_t *value) {
uint8_t reg_data[2];
reg_data[0] = reg >> 8;
reg_data[1] = reg >> 0;
i2c::ErrorCode err = this->write(reg_data, 2);
if (err != i2c::ERROR_OK)
return true;
uint8_t recv[4];
err = this->read(recv, 4);
if (err != i2c::ERROR_OK)
return true;
*value = encode_uint32(recv[0], recv[1], recv[2], recv[3]);
return false;
}
} // namespace ade7953_i2c
} // namespace esphome

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esphome/components/ade7953_i2c/ade7953_i2c.h Normal file
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#pragma once
#include "esphome/core/component.h"
#include "esphome/core/hal.h"
#include "esphome/components/i2c/i2c.h"
#include "esphome/components/sensor/sensor.h"
#include "esphome/components/ade7953_base/ade7953_base.h"
#include <vector>
namespace esphome {
namespace ade7953_i2c {
class AdE7953I2c : public ade7953_base::ADE7953, public i2c::I2CDevice {
public:
void dump_config() override;
protected:
bool ade_write_8(uint16_t reg, uint8_t value) override;
bool ade_write_16(uint16_t reg, uint16_t value) override;
bool ade_write_32(uint16_t reg, uint32_t value) override;
bool ade_read_8(uint16_t reg, uint8_t *value) override;
bool ade_read_16(uint16_t reg, uint16_t *value) override;
bool ade_read_32(uint16_t reg, uint32_t *value) override;
};
} // namespace ade7953_i2c
} // namespace esphome

27
esphome/components/ade7953_i2c/sensor.py Normal file
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import esphome.codegen as cg
import esphome.config_validation as cv
from esphome.components import i2c, ade7953_base
from esphome.const import CONF_ID
DEPENDENCIES = ["i2c"]
AUTO_LOAD = ["ade7953_base"]
ade7953_ns = cg.esphome_ns.namespace("ade7953_i2c")
ADE7953 = ade7953_ns.class_("AdE7953I2c", ade7953_base.ADE7953, i2c.I2CDevice)
CONFIG_SCHEMA = (
cv.Schema(
{
cv.GenerateID(): cv.declare_id(ADE7953),
}
)
.extend(ade7953_base.ADE7953_CONFIG_SCHEMA)
.extend(i2c.i2c_device_schema(0x38))
)
async def to_code(config):
var = cg.new_Pvariable(config[CONF_ID])
await i2c.register_i2c_device(var, config)
await ade7953_base.register_ade7953(var, config)

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esphome/components/ade7953_spi/__init__.py Normal file
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CODEOWNERS = ["@angelnu"]

81
esphome/components/ade7953_spi/ade7953_spi.cpp Normal file
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#include "ade7953_spi.h"
#include "esphome/core/log.h"
#include "esphome/core/helpers.h"
namespace esphome {
namespace ade7953_spi {
static const char *const TAG = "ade7953";
void AdE7953Spi::setup() {
this->spi_setup();
ade7953_base::ADE7953::setup();
}
void AdE7953Spi::dump_config() {
ESP_LOGCONFIG(TAG, "ADE7953_spi:");
LOG_PIN(" CS Pin: ", this->cs_);
ade7953_base::ADE7953::dump_config();
}
bool AdE7953Spi::ade_write_8(uint16_t reg, uint8_t value) {
this->enable();
this->write_byte16(reg);
this->transfer_byte(0);
this->transfer_byte(value);
this->disable();
return false;
}
bool AdE7953Spi::ade_write_16(uint16_t reg, uint16_t value) {
this->enable();
this->write_byte16(reg);
this->transfer_byte(0);
this->write_byte16(value);
this->disable();
return false;
}
bool AdE7953Spi::ade_write_32(uint16_t reg, uint32_t value) {
this->enable();
this->write_byte16(reg);
this->transfer_byte(0);
this->write_byte16(value >> 16);
this->write_byte16(value & 0xFFFF);
this->disable();
return false;
}
bool AdE7953Spi::ade_read_8(uint16_t reg, uint8_t *value) {
this->enable();
this->write_byte16(reg);
this->transfer_byte(0x80);
*value = this->read_byte();
this->disable();
return false;
}
bool AdE7953Spi::ade_read_16(uint16_t reg, uint16_t *value) {
this->enable();
this->write_byte16(reg);
this->transfer_byte(0x80);
uint8_t recv[2];
this->read_array(recv, 4);
*value = encode_uint16(recv[0], recv[1]);
this->disable();
return false;
}
bool AdE7953Spi::ade_read_32(uint16_t reg, uint32_t *value) {
this->enable();
this->write_byte16(reg);
this->transfer_byte(0x80);
uint8_t recv[4];
this->read_array(recv, 4);
*value = encode_uint32(recv[0], recv[1], recv[2], recv[3]);
this->disable();
return false;
}
} // namespace ade7953_spi
} // namespace esphome

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esphome/components/ade7953_spi/ade7953_spi.h Normal file
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#pragma once
#include "esphome/core/component.h"
#include "esphome/core/hal.h"
#include "esphome/components/spi/spi.h"
#include "esphome/components/sensor/sensor.h"
#include "esphome/components/ade7953_base/ade7953_base.h"
#include <vector>
namespace esphome {
namespace ade7953_spi {
class AdE7953Spi : public ade7953_base::ADE7953,
public spi::SPIDevice<spi::BIT_ORDER_MSB_FIRST, spi::CLOCK_POLARITY_HIGH, spi::CLOCK_PHASE_LEADING,
spi::DATA_RATE_1MHZ> {
public:
void setup() override;
void dump_config() override;
protected:
bool ade_write_8(uint16_t reg, uint8_t value) override;
bool ade_write_16(uint16_t reg, uint16_t value) override;
bool ade_write_32(uint16_t reg, uint32_t value) override;
bool ade_read_8(uint16_t reg, uint8_t *value) override;
bool ade_read_16(uint16_t reg, uint16_t *value) override;
bool ade_read_32(uint16_t reg, uint32_t *value) override;
};
} // namespace ade7953_spi
} // namespace esphome

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esphome/components/ade7953_spi/sensor.py Normal file
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import esphome.codegen as cg
import esphome.config_validation as cv
from esphome.components import spi, ade7953_base
from esphome.const import CONF_ID
DEPENDENCIES = ["spi"]
AUTO_LOAD = ["ade7953_base"]
ade7953_ns = cg.esphome_ns.namespace("ade7953_spi")
ADE7953 = ade7953_ns.class_("AdE7953Spi", ade7953_base.ADE7953, spi.SPIDevice)
CONFIG_SCHEMA = (
cv.Schema(
{
cv.GenerateID(): cv.declare_id(ADE7953),
}
)
.extend(ade7953_base.ADE7953_CONFIG_SCHEMA)
.extend(spi.spi_device_schema())
)
async def to_code(config):
var = cg.new_Pvariable(config[CONF_ID])
await spi.register_spi_device(var, config)
await ade7953_base.register_ade7953(var, config)

63
tests/test11.5.yaml
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@ -51,6 +51,15 @@ uart:
i2c:
frequency: 100khz
spi:
- id: spi_1
clk_pin: 12
mosi_pin: 13
miso_pin: 14
- id: spi_2
clk_pin: 32
mosi_pin: 33
modbus:
uart_id: uart_1
flow_control_pin: 5
@ -574,6 +583,60 @@ sensor:
temperature:
name: Kuntze temperature
- platform: ade7953_i2c
irq_pin: 16
voltage:
name: ADE7953 Voltage
current_a:
name: ADE7953 Current A
current_b:
name: ADE7953 Current B
power_factor_a:
name: "ADE7953 Power Factor A"
power_factor_b:
name: "ADE7953 Power Factor B"
apparent_power_a:
name: "ADE7953 Apparent Power A"
apparent_power_b:
name: "ADE7953 Apparent Power B"
active_power_a:
name: ADE7953 Active Power A
active_power_b:
name: ADE7953 Active Power B
reactive_power_a:
name: "ADE7953 Reactive Power A"
reactive_power_b:
name: "ADE7953 Reactive Power B"
update_interval: 1s
- platform: ade7953_spi
spi_id: spi_1
cs_pin: 04
irq_pin: 16
voltage:
name: ADE7953 Voltage
current_a:
name: ADE7953 Current A
current_b:
name: ADE7953 Current B
power_factor_a:
name: "ADE7953 Power Factor A"
power_factor_b:
name: "ADE7953 Power Factor B"
apparent_power_a:
name: "ADE7953 Apparent Power A"
apparent_power_b:
name: "ADE7953 Apparent Power B"
active_power_a:
name: ADE7953 Active Power A
active_power_b:
name: ADE7953 Active Power B
reactive_power_a:
name: "ADE7953 Reactive Power A"
reactive_power_b:
name: "ADE7953 Reactive Power B"
update_interval: 1s
script:
- id: automation_test
then:

44
tests/test3.1.yaml
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@ -169,7 +169,7 @@ sensor:
- id: custom_sensor
name: Custom Sensor
- platform: ade7953
- platform: ade7953_i2c
irq_pin: GPIO16
voltage:
name: ADE7953 Voltage
@ -180,12 +180,50 @@ sensor:
current_b:
name: ADE7953 Current B
id: ade7953_current_b
power_factor_a:
name: "ADE7953 Power Factor A"
power_factor_b:
name: "ADE7953 Power Factor B"
apparent_power_a:
name: "ADE7953 Apparent Power A"
apparent_power_b:
name: "ADE7953 Apparent Power B"
active_power_a:
name: ADE7953 Active Power A
id: ade7953_active_power_a
active_power_b:
name: ADE7953 Active Power B
id: ade7953_active_power_b
reactive_power_a:
name: "ADE7953 Reactive Power A"
reactive_power_b:
name: "ADE7953 Reactive Power B"
update_interval: 1s
- platform: ade7953_spi
cs_pin: GPIO04
irq_pin: GPIO16
voltage:
name: ADE7953 Voltage
current_a:
name: ADE7953 Current A
current_b:
name: ADE7953 Current B
power_factor_a:
name: "ADE7953 Power Factor A"
power_factor_b:
name: "ADE7953 Power Factor B"
apparent_power_a:
name: "ADE7953 Apparent Power A"
apparent_power_b:
name: "ADE7953 Apparent Power B"
active_power_a:
name: ADE7953 Active Power A
active_power_b:
name: ADE7953 Active Power B
reactive_power_a:
name: "ADE7953 Reactive Power A"
reactive_power_b:
name: "ADE7953 Reactive Power B"
update_interval: 1s
- platform: tmp102
name: TMP102 Temperature