esphome/esphome/components/pmsx003/pmsx003.cpp
R Huish 3d4c0e6667
Added missing PM_1_0 and PM_10_0 for PMS5003T and PMS5003ST (#4560)
* Added missing PM_1_0 and PM_10_0 for PMS5003T

Added missing PM_1_0 and PM_10_0 for PMS5003T

* Revert "Added missing PM_1_0 and PM_10_0 for PMS5003T"

This reverts commit 86084f7c61.

* Added tests for PMS5003T

* Added missing PM_1_0 and PM_10_0 for PMS5003T PMS5003ST

* Added missing PM_1_0 and PM_10_0 for PMS5003T

* lint: Trailing whitespace fixed

* tab character removed

* Clang format suggested edit
2023-03-15 22:21:10 +00:00

357 lines
14 KiB
C++

#include "pmsx003.h"
#include "esphome/core/log.h"
namespace esphome {
namespace pmsx003 {
static const char *const TAG = "pmsx003";
void PMSX003Component::set_pm_1_0_std_sensor(sensor::Sensor *pm_1_0_std_sensor) {
pm_1_0_std_sensor_ = pm_1_0_std_sensor;
}
void PMSX003Component::set_pm_2_5_std_sensor(sensor::Sensor *pm_2_5_std_sensor) {
pm_2_5_std_sensor_ = pm_2_5_std_sensor;
}
void PMSX003Component::set_pm_10_0_std_sensor(sensor::Sensor *pm_10_0_std_sensor) {
pm_10_0_std_sensor_ = pm_10_0_std_sensor;
}
void PMSX003Component::set_pm_1_0_sensor(sensor::Sensor *pm_1_0_sensor) { pm_1_0_sensor_ = pm_1_0_sensor; }
void PMSX003Component::set_pm_2_5_sensor(sensor::Sensor *pm_2_5_sensor) { pm_2_5_sensor_ = pm_2_5_sensor; }
void PMSX003Component::set_pm_10_0_sensor(sensor::Sensor *pm_10_0_sensor) { pm_10_0_sensor_ = pm_10_0_sensor; }
void PMSX003Component::set_pm_particles_03um_sensor(sensor::Sensor *pm_particles_03um_sensor) {
pm_particles_03um_sensor_ = pm_particles_03um_sensor;
}
void PMSX003Component::set_pm_particles_05um_sensor(sensor::Sensor *pm_particles_05um_sensor) {
pm_particles_05um_sensor_ = pm_particles_05um_sensor;
}
void PMSX003Component::set_pm_particles_10um_sensor(sensor::Sensor *pm_particles_10um_sensor) {
pm_particles_10um_sensor_ = pm_particles_10um_sensor;
}
void PMSX003Component::set_pm_particles_25um_sensor(sensor::Sensor *pm_particles_25um_sensor) {
pm_particles_25um_sensor_ = pm_particles_25um_sensor;
}
void PMSX003Component::set_pm_particles_50um_sensor(sensor::Sensor *pm_particles_50um_sensor) {
pm_particles_50um_sensor_ = pm_particles_50um_sensor;
}
void PMSX003Component::set_pm_particles_100um_sensor(sensor::Sensor *pm_particles_100um_sensor) {
pm_particles_100um_sensor_ = pm_particles_100um_sensor;
}
void PMSX003Component::set_temperature_sensor(sensor::Sensor *temperature_sensor) {
temperature_sensor_ = temperature_sensor;
}
void PMSX003Component::set_humidity_sensor(sensor::Sensor *humidity_sensor) { humidity_sensor_ = humidity_sensor; }
void PMSX003Component::set_formaldehyde_sensor(sensor::Sensor *formaldehyde_sensor) {
formaldehyde_sensor_ = formaldehyde_sensor;
}
void PMSX003Component::loop() {
const uint32_t now = millis();
// If we update less often than it takes the device to stabilise, spin the fan down
// rather than running it constantly. It does take some time to stabilise, so we
// need to keep track of what state we're in.
if (this->update_interval_ > PMS_STABILISING_MS) {
if (this->initialised_ == 0) {
this->send_command_(PMS_CMD_AUTO_MANUAL, 0);
this->send_command_(PMS_CMD_ON_STANDBY, 1);
this->initialised_ = 1;
}
switch (this->state_) {
case PMSX003_STATE_IDLE:
// Power on the sensor now so it'll be ready when we hit the update time
if (now - this->last_update_ < (this->update_interval_ - PMS_STABILISING_MS))
return;
this->state_ = PMSX003_STATE_STABILISING;
this->send_command_(PMS_CMD_ON_STANDBY, 1);
this->fan_on_time_ = now;
return;
case PMSX003_STATE_STABILISING:
// wait for the sensor to be stable
if (now - this->fan_on_time_ < PMS_STABILISING_MS)
return;
// consume any command responses that are in the serial buffer
while (this->available())
this->read_byte(&this->data_[0]);
// Trigger a new read
this->send_command_(PMS_CMD_TRIG_MANUAL, 0);
this->state_ = PMSX003_STATE_WAITING;
break;
case PMSX003_STATE_WAITING:
// Just go ahead and read stuff
break;
}
} else if (now - this->last_update_ < this->update_interval_) {
// Otherwise just leave the sensor powered up and come back when we hit the update
// time
return;
}
if (now - this->last_transmission_ >= 500) {
// last transmission too long ago. Reset RX index.
this->data_index_ = 0;
}
if (this->available() == 0)
return;
this->last_transmission_ = now;
while (this->available() != 0) {
this->read_byte(&this->data_[this->data_index_]);
auto check = this->check_byte_();
if (!check.has_value()) {
// finished
this->parse_data_();
this->data_index_ = 0;
this->last_update_ = now;
} else if (!*check) {
// wrong data
this->data_index_ = 0;
} else {
// next byte
this->data_index_++;
}
}
}
float PMSX003Component::get_setup_priority() const { return setup_priority::DATA; }
optional<bool> PMSX003Component::check_byte_() {
uint8_t index = this->data_index_;
uint8_t byte = this->data_[index];
if (index == 0)
return byte == 0x42;
if (index == 1)
return byte == 0x4D;
if (index == 2)
return true;
uint16_t payload_length = this->get_16_bit_uint_(2);
if (index == 3) {
bool length_matches = false;
switch (this->type_) {
case PMSX003_TYPE_X003:
length_matches = payload_length == 28 || payload_length == 20;
break;
case PMSX003_TYPE_5003T:
case PMSX003_TYPE_5003S:
length_matches = payload_length == 28;
break;
case PMSX003_TYPE_5003ST:
length_matches = payload_length == 36;
break;
}
if (!length_matches) {
ESP_LOGW(TAG, "PMSX003 length %u doesn't match. Are you using the correct PMSX003 type?", payload_length);
return false;
}
return true;
}
// start (16bit) + length (16bit) + DATA (payload_length-2 bytes) + checksum (16bit)
uint8_t total_size = 4 + payload_length;
if (index < total_size - 1)
return true;
// checksum is without checksum bytes
uint16_t checksum = 0;
for (uint8_t i = 0; i < total_size - 2; i++)
checksum += this->data_[i];
uint16_t check = this->get_16_bit_uint_(total_size - 2);
if (checksum != check) {
ESP_LOGW(TAG, "PMSX003 checksum mismatch! 0x%02X!=0x%02X", checksum, check);
return false;
}
return {};
}
void PMSX003Component::send_command_(uint8_t cmd, uint16_t data) {
this->data_index_ = 0;
this->data_[data_index_++] = 0x42;
this->data_[data_index_++] = 0x4D;
this->data_[data_index_++] = cmd;
this->data_[data_index_++] = (data >> 8) & 0xFF;
this->data_[data_index_++] = (data >> 0) & 0xFF;
int sum = 0;
for (int i = 0; i < data_index_; i++) {
sum += this->data_[i];
}
this->data_[data_index_++] = (sum >> 8) & 0xFF;
this->data_[data_index_++] = (sum >> 0) & 0xFF;
for (int i = 0; i < data_index_; i++) {
this->write_byte(this->data_[i]);
}
this->data_index_ = 0;
}
void PMSX003Component::parse_data_() {
switch (this->type_) {
case PMSX003_TYPE_5003ST: {
float temperature = this->get_16_bit_uint_(30) / 10.0f;
float humidity = this->get_16_bit_uint_(32) / 10.0f;
ESP_LOGD(TAG, "Got Temperature: %.1f°C, Humidity: %.1f%%", temperature, humidity);
if (this->temperature_sensor_ != nullptr)
this->temperature_sensor_->publish_state(temperature);
if (this->humidity_sensor_ != nullptr)
this->humidity_sensor_->publish_state(humidity);
// The rest of the PMS5003ST matches the PMS5003S, continue on
}
case PMSX003_TYPE_5003S: {
uint16_t formaldehyde = this->get_16_bit_uint_(28);
ESP_LOGD(TAG, "Got Formaldehyde: %u µg/m^3", formaldehyde);
if (this->formaldehyde_sensor_ != nullptr)
this->formaldehyde_sensor_->publish_state(formaldehyde);
// The rest of the PMS5003S matches the PMS5003, continue on
}
case PMSX003_TYPE_X003: {
uint16_t pm_1_0_std_concentration = this->get_16_bit_uint_(4);
uint16_t pm_2_5_std_concentration = this->get_16_bit_uint_(6);
uint16_t pm_10_0_std_concentration = this->get_16_bit_uint_(8);
uint16_t pm_1_0_concentration = this->get_16_bit_uint_(10);
uint16_t pm_2_5_concentration = this->get_16_bit_uint_(12);
uint16_t pm_10_0_concentration = this->get_16_bit_uint_(14);
uint16_t pm_particles_03um = this->get_16_bit_uint_(16);
uint16_t pm_particles_05um = this->get_16_bit_uint_(18);
uint16_t pm_particles_10um = this->get_16_bit_uint_(20);
uint16_t pm_particles_25um = this->get_16_bit_uint_(22);
uint16_t pm_particles_50um = this->get_16_bit_uint_(24);
uint16_t pm_particles_100um = this->get_16_bit_uint_(26);
ESP_LOGD(TAG,
"Got PM1.0 Concentration: %u µg/m^3, PM2.5 Concentration %u µg/m^3, PM10.0 Concentration: %u µg/m^3",
pm_1_0_concentration, pm_2_5_concentration, pm_10_0_concentration);
if (this->pm_1_0_std_sensor_ != nullptr)
this->pm_1_0_std_sensor_->publish_state(pm_1_0_std_concentration);
if (this->pm_2_5_std_sensor_ != nullptr)
this->pm_2_5_std_sensor_->publish_state(pm_2_5_std_concentration);
if (this->pm_10_0_std_sensor_ != nullptr)
this->pm_10_0_std_sensor_->publish_state(pm_10_0_std_concentration);
if (this->pm_1_0_sensor_ != nullptr)
this->pm_1_0_sensor_->publish_state(pm_1_0_concentration);
if (this->pm_2_5_sensor_ != nullptr)
this->pm_2_5_sensor_->publish_state(pm_2_5_concentration);
if (this->pm_10_0_sensor_ != nullptr)
this->pm_10_0_sensor_->publish_state(pm_10_0_concentration);
if (this->pm_particles_03um_sensor_ != nullptr)
this->pm_particles_03um_sensor_->publish_state(pm_particles_03um);
if (this->pm_particles_05um_sensor_ != nullptr)
this->pm_particles_05um_sensor_->publish_state(pm_particles_05um);
if (this->pm_particles_10um_sensor_ != nullptr)
this->pm_particles_10um_sensor_->publish_state(pm_particles_10um);
if (this->pm_particles_25um_sensor_ != nullptr)
this->pm_particles_25um_sensor_->publish_state(pm_particles_25um);
if (this->pm_particles_50um_sensor_ != nullptr)
this->pm_particles_50um_sensor_->publish_state(pm_particles_50um);
if (this->pm_particles_100um_sensor_ != nullptr)
this->pm_particles_100um_sensor_->publish_state(pm_particles_100um);
break;
}
case PMSX003_TYPE_5003T: {
uint16_t pm_1_0_std_concentration = this->get_16_bit_uint_(4);
uint16_t pm_2_5_std_concentration = this->get_16_bit_uint_(6);
uint16_t pm_10_0_std_concentration = this->get_16_bit_uint_(8);
uint16_t pm_1_0_concentration = this->get_16_bit_uint_(10);
uint16_t pm_2_5_concentration = this->get_16_bit_uint_(12);
uint16_t pm_10_0_concentration = this->get_16_bit_uint_(14);
uint16_t pm_particles_03um = this->get_16_bit_uint_(16);
uint16_t pm_particles_05um = this->get_16_bit_uint_(18);
uint16_t pm_particles_10um = this->get_16_bit_uint_(20);
uint16_t pm_particles_25um = this->get_16_bit_uint_(22);
// Note the pm particles 50um & 100um are not returned,
// as PMS5003T uses those data values for temperature and humidity.
float temperature = this->get_16_bit_uint_(24) / 10.0f;
float humidity = this->get_16_bit_uint_(26) / 10.0f;
ESP_LOGD(TAG,
"Got PM1.0 Concentration: %u µg/m^3, PM2.5 Concentration %u µg/m^3, PM10.0 Concentration: %u µg/m^3, "
"Temperature: %.1f°C, Humidity: %.1f%%",
pm_1_0_concentration, pm_2_5_concentration, pm_10_0_concentration, temperature, humidity);
if (this->pm_1_0_std_sensor_ != nullptr)
this->pm_1_0_std_sensor_->publish_state(pm_1_0_std_concentration);
if (this->pm_2_5_std_sensor_ != nullptr)
this->pm_2_5_std_sensor_->publish_state(pm_2_5_std_concentration);
if (this->pm_10_0_std_sensor_ != nullptr)
this->pm_10_0_std_sensor_->publish_state(pm_10_0_std_concentration);
if (this->pm_1_0_sensor_ != nullptr)
this->pm_1_0_sensor_->publish_state(pm_1_0_concentration);
if (this->pm_2_5_sensor_ != nullptr)
this->pm_2_5_sensor_->publish_state(pm_2_5_concentration);
if (this->pm_10_0_sensor_ != nullptr)
this->pm_10_0_sensor_->publish_state(pm_10_0_concentration);
if (this->pm_particles_03um_sensor_ != nullptr)
this->pm_particles_03um_sensor_->publish_state(pm_particles_03um);
if (this->pm_particles_05um_sensor_ != nullptr)
this->pm_particles_05um_sensor_->publish_state(pm_particles_05um);
if (this->pm_particles_10um_sensor_ != nullptr)
this->pm_particles_10um_sensor_->publish_state(pm_particles_10um);
if (this->pm_particles_25um_sensor_ != nullptr)
this->pm_particles_25um_sensor_->publish_state(pm_particles_25um);
if (this->temperature_sensor_ != nullptr)
this->temperature_sensor_->publish_state(temperature);
if (this->humidity_sensor_ != nullptr)
this->humidity_sensor_->publish_state(humidity);
break;
}
}
// Spin down the sensor again if we aren't going to need it until more time has
// passed than it takes to stabilise
if (this->update_interval_ > PMS_STABILISING_MS) {
this->send_command_(PMS_CMD_ON_STANDBY, 0);
this->state_ = PMSX003_STATE_IDLE;
}
this->status_clear_warning();
}
uint16_t PMSX003Component::get_16_bit_uint_(uint8_t start_index) {
return (uint16_t(this->data_[start_index]) << 8) | uint16_t(this->data_[start_index + 1]);
}
void PMSX003Component::dump_config() {
ESP_LOGCONFIG(TAG, "PMSX003:");
LOG_SENSOR(" ", "PM1.0STD", this->pm_1_0_std_sensor_);
LOG_SENSOR(" ", "PM2.5STD", this->pm_2_5_std_sensor_);
LOG_SENSOR(" ", "PM10.0STD", this->pm_10_0_std_sensor_);
LOG_SENSOR(" ", "PM1.0", this->pm_1_0_sensor_);
LOG_SENSOR(" ", "PM2.5", this->pm_2_5_sensor_);
LOG_SENSOR(" ", "PM10.0", this->pm_10_0_sensor_);
LOG_SENSOR(" ", "PM0.3um", this->pm_particles_03um_sensor_);
LOG_SENSOR(" ", "PM0.5um", this->pm_particles_05um_sensor_);
LOG_SENSOR(" ", "PM1.0um", this->pm_particles_10um_sensor_);
LOG_SENSOR(" ", "PM2.5um", this->pm_particles_25um_sensor_);
LOG_SENSOR(" ", "PM5.0um", this->pm_particles_50um_sensor_);
LOG_SENSOR(" ", "PM10.0um", this->pm_particles_100um_sensor_);
LOG_SENSOR(" ", "Temperature", this->temperature_sensor_);
LOG_SENSOR(" ", "Humidity", this->humidity_sensor_);
LOG_SENSOR(" ", "Formaldehyde", this->formaldehyde_sensor_);
this->check_uart_settings(9600);
}
} // namespace pmsx003
} // namespace esphome