mirror of
https://github.com/esphome/esphome.git
synced 2024-12-02 19:54:14 +01:00
bf5f846fc6
Co-authored-by: Otto winter <otto@otto-winter.com>
358 lines
13 KiB
C++
358 lines
13 KiB
C++
#include "sgp30.h"
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#include "esphome/core/log.h"
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#include "esphome/core/application.h"
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namespace esphome {
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namespace sgp30 {
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static const char *const TAG = "sgp30";
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static const uint16_t SGP30_CMD_GET_SERIAL_ID = 0x3682;
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static const uint16_t SGP30_CMD_GET_FEATURESET = 0x202f;
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static const uint16_t SGP30_CMD_IAQ_INIT = 0x2003;
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static const uint16_t SGP30_CMD_MEASURE_IAQ = 0x2008;
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static const uint16_t SGP30_CMD_SET_ABSOLUTE_HUMIDITY = 0x2061;
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static const uint16_t SGP30_CMD_GET_IAQ_BASELINE = 0x2015;
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static const uint16_t SGP30_CMD_SET_IAQ_BASELINE = 0x201E;
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// Sensor baseline should first be relied on after 1H of operation,
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// if the sensor starts with a baseline value provided
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const uint32_t IAQ_BASELINE_WARM_UP_SECONDS_WITH_BASELINE_PROVIDED = 3600;
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// Sensor baseline could first be relied on after 12H of operation,
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// if the sensor starts without any prior baseline value provided
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const uint32_t IAQ_BASELINE_WARM_UP_SECONDS_WITHOUT_BASELINE = 43200;
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// Shortest time interval of 1H for storing baseline values.
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// Prevents wear of the flash because of too many write operations
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const uint32_t SHORTEST_BASELINE_STORE_INTERVAL = 3600;
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// Store anyway if the baseline difference exceeds the max storage diff value
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const uint32_t MAXIMUM_STORAGE_DIFF = 50;
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void SGP30Component::setup() {
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ESP_LOGCONFIG(TAG, "Setting up SGP30...");
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// Serial Number identification
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if (!this->write_command_(SGP30_CMD_GET_SERIAL_ID)) {
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this->error_code_ = COMMUNICATION_FAILED;
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this->mark_failed();
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return;
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}
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uint16_t raw_serial_number[3];
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if (!this->read_data_(raw_serial_number, 3)) {
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this->mark_failed();
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return;
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}
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this->serial_number_ = (uint64_t(raw_serial_number[0]) << 24) | (uint64_t(raw_serial_number[1]) << 16) |
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(uint64_t(raw_serial_number[2]));
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ESP_LOGD(TAG, "Serial Number: %" PRIu64, this->serial_number_);
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// Featureset identification for future use
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if (!this->write_command_(SGP30_CMD_GET_FEATURESET)) {
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this->mark_failed();
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return;
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}
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uint16_t raw_featureset[1];
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if (!this->read_data_(raw_featureset, 1)) {
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this->mark_failed();
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return;
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}
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this->featureset_ = raw_featureset[0];
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if (uint16_t(this->featureset_ >> 12) != 0x0) {
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if (uint16_t(this->featureset_ >> 12) == 0x1) {
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// ID matching a different sensor: SGPC3
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this->error_code_ = UNSUPPORTED_ID;
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} else {
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// Unknown ID
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this->error_code_ = INVALID_ID;
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}
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this->mark_failed();
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return;
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}
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ESP_LOGD(TAG, "Product version: 0x%0X", uint16_t(this->featureset_ & 0x1FF));
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// Sensor initialization
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if (!this->write_command_(SGP30_CMD_IAQ_INIT)) {
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ESP_LOGE(TAG, "Sensor sgp30_iaq_init failed.");
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this->error_code_ = MEASUREMENT_INIT_FAILED;
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this->mark_failed();
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return;
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}
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// Hash with compilation time
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// This ensures the baseline storage is cleared after OTA
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uint32_t hash = fnv1_hash(App.get_compilation_time());
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this->pref_ = global_preferences.make_preference<SGP30Baselines>(hash, true);
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if (this->pref_.load(&this->baselines_storage_)) {
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ESP_LOGI(TAG, "Loaded eCO2 baseline: 0x%04X, TVOC baseline: 0x%04X", this->baselines_storage_.eco2,
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baselines_storage_.tvoc);
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this->eco2_baseline_ = this->baselines_storage_.eco2;
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this->tvoc_baseline_ = this->baselines_storage_.tvoc;
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}
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// Initialize storage timestamp
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this->seconds_since_last_store_ = 0;
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// Sensor baseline reliability timer
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if (this->eco2_baseline_ > 0 && this->tvoc_baseline_ > 0) {
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this->required_warm_up_time_ = IAQ_BASELINE_WARM_UP_SECONDS_WITH_BASELINE_PROVIDED;
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this->write_iaq_baseline_(this->eco2_baseline_, this->tvoc_baseline_);
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} else {
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this->required_warm_up_time_ = IAQ_BASELINE_WARM_UP_SECONDS_WITHOUT_BASELINE;
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}
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}
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bool SGP30Component::is_sensor_baseline_reliable_() {
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if ((this->required_warm_up_time_ == 0) || (std::floor(millis() / 1000) >= this->required_warm_up_time_)) {
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// requirement for warm up is removed once the millis uptime surpasses the required warm_up_time
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// this avoids the repetitive warm up when the millis uptime is rolled over every ~40 days
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this->required_warm_up_time_ = 0;
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return true;
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}
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return false;
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}
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void SGP30Component::read_iaq_baseline_() {
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if (this->is_sensor_baseline_reliable_()) {
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if (!this->write_command_(SGP30_CMD_GET_IAQ_BASELINE)) {
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ESP_LOGD(TAG, "Error getting baseline");
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this->status_set_warning();
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return;
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}
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this->set_timeout(50, [this]() {
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uint16_t raw_data[2];
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if (!this->read_data_(raw_data, 2)) {
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this->status_set_warning();
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return;
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}
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uint16_t eco2baseline = (raw_data[0]);
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uint16_t tvocbaseline = (raw_data[1]);
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ESP_LOGI(TAG, "Current eCO2 baseline: 0x%04X, TVOC baseline: 0x%04X", eco2baseline, tvocbaseline);
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if (eco2baseline != this->eco2_baseline_ || tvocbaseline != this->tvoc_baseline_) {
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this->eco2_baseline_ = eco2baseline;
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this->tvoc_baseline_ = tvocbaseline;
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if (this->eco2_sensor_baseline_ != nullptr)
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this->eco2_sensor_baseline_->publish_state(this->eco2_baseline_);
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if (this->tvoc_sensor_baseline_ != nullptr)
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this->tvoc_sensor_baseline_->publish_state(this->tvoc_baseline_);
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// Store baselines after defined interval or if the difference between current and stored baseline becomes too
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// much
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if (this->store_baseline_ &&
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(this->seconds_since_last_store_ > SHORTEST_BASELINE_STORE_INTERVAL ||
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abs(this->baselines_storage_.eco2 - this->eco2_baseline_) > MAXIMUM_STORAGE_DIFF ||
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abs(this->baselines_storage_.tvoc - this->tvoc_baseline_) > MAXIMUM_STORAGE_DIFF)) {
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this->seconds_since_last_store_ = 0;
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this->baselines_storage_.eco2 = this->eco2_baseline_;
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this->baselines_storage_.tvoc = this->tvoc_baseline_;
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if (this->pref_.save(&this->baselines_storage_)) {
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ESP_LOGI(TAG, "Store eCO2 baseline: 0x%04X, TVOC baseline: 0x%04X", this->baselines_storage_.eco2,
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this->baselines_storage_.tvoc);
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} else {
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ESP_LOGW(TAG, "Could not store eCO2 and TVOC baselines");
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}
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}
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}
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this->status_clear_warning();
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});
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} else {
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ESP_LOGD(TAG, "Baseline reading not available for: %.0fs",
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(this->required_warm_up_time_ - std::floor(millis() / 1000)));
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}
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}
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void SGP30Component::send_env_data_() {
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if (this->humidity_sensor_ == nullptr && this->temperature_sensor_ == nullptr)
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return;
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float humidity = NAN;
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if (this->humidity_sensor_ != nullptr)
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humidity = this->humidity_sensor_->state;
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if (isnan(humidity) || humidity < 0.0f || humidity > 100.0f) {
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ESP_LOGW(TAG, "Compensation not possible yet: bad humidity data.");
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return;
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} else {
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ESP_LOGD(TAG, "External compensation data received: Humidity %0.2f%%", humidity);
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}
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float temperature = NAN;
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if (this->temperature_sensor_ != nullptr) {
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temperature = float(this->temperature_sensor_->state);
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}
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if (isnan(temperature) || temperature < -40.0f || temperature > 85.0f) {
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ESP_LOGW(TAG, "Compensation not possible yet: bad temperature value data.");
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return;
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} else {
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ESP_LOGD(TAG, "External compensation data received: Temperature %0.2f°C", temperature);
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}
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float absolute_humidity =
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216.7f * (((humidity / 100) * 6.112f * std::exp((17.62f * temperature) / (243.12f + temperature))) /
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(273.15f + temperature));
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uint8_t humidity_full = uint8_t(std::floor(absolute_humidity));
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uint8_t humidity_dec = uint8_t(std::floor((absolute_humidity - std::floor(absolute_humidity)) * 256));
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ESP_LOGD(TAG, "Calculated Absolute humidity: %0.3f g/m³ (0x%04X)", absolute_humidity,
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uint16_t(uint16_t(humidity_full) << 8 | uint16_t(humidity_dec)));
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uint8_t crc = sht_crc_(humidity_full, humidity_dec);
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uint8_t data[4];
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data[0] = SGP30_CMD_SET_ABSOLUTE_HUMIDITY & 0xFF;
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data[1] = humidity_full;
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data[2] = humidity_dec;
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data[3] = crc;
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if (!this->write_bytes(SGP30_CMD_SET_ABSOLUTE_HUMIDITY >> 8, data, 4)) {
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ESP_LOGE(TAG, "Error sending compensation data.");
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}
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}
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void SGP30Component::write_iaq_baseline_(uint16_t eco2_baseline, uint16_t tvoc_baseline) {
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uint8_t data[7];
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data[0] = SGP30_CMD_SET_IAQ_BASELINE & 0xFF;
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data[1] = tvoc_baseline >> 8;
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data[2] = tvoc_baseline & 0xFF;
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data[3] = sht_crc_(data[1], data[2]);
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data[4] = eco2_baseline >> 8;
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data[5] = eco2_baseline & 0xFF;
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data[6] = sht_crc_(data[4], data[5]);
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if (!this->write_bytes(SGP30_CMD_SET_IAQ_BASELINE >> 8, data, 7)) {
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ESP_LOGE(TAG, "Error applying eCO2 baseline: 0x%04X, TVOC baseline: 0x%04X", eco2_baseline, tvoc_baseline);
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} else
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ESP_LOGI(TAG, "Initial baselines applied successfully! eCO2 baseline: 0x%04X, TVOC baseline: 0x%04X", eco2_baseline,
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tvoc_baseline);
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}
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void SGP30Component::dump_config() {
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ESP_LOGCONFIG(TAG, "SGP30:");
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LOG_I2C_DEVICE(this);
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if (this->is_failed()) {
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switch (this->error_code_) {
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case COMMUNICATION_FAILED:
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ESP_LOGW(TAG, "Communication failed! Is the sensor connected?");
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break;
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case MEASUREMENT_INIT_FAILED:
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ESP_LOGW(TAG, "Measurement Initialization failed!");
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break;
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case INVALID_ID:
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ESP_LOGW(TAG, "Sensor reported an invalid ID. Is this an SGP30?");
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break;
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case UNSUPPORTED_ID:
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ESP_LOGW(TAG, "Sensor reported an unsupported ID (SGPC3).");
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break;
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default:
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ESP_LOGW(TAG, "Unknown setup error!");
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break;
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}
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} else {
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ESP_LOGCONFIG(TAG, " Serial number: %" PRIu64, this->serial_number_);
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if (this->eco2_baseline_ != 0x0000 && this->tvoc_baseline_ != 0x0000) {
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ESP_LOGCONFIG(TAG, " Baseline:");
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ESP_LOGCONFIG(TAG, " eCO2 Baseline: 0x%04X", this->eco2_baseline_);
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ESP_LOGCONFIG(TAG, " TVOC Baseline: 0x%04X", this->tvoc_baseline_);
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} else {
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ESP_LOGCONFIG(TAG, " Baseline: No baseline configured");
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}
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ESP_LOGCONFIG(TAG, " Warm up time: %us", this->required_warm_up_time_);
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}
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LOG_UPDATE_INTERVAL(this);
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LOG_SENSOR(" ", "eCO2 sensor", this->eco2_sensor_);
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LOG_SENSOR(" ", "TVOC sensor", this->tvoc_sensor_);
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LOG_SENSOR(" ", "eCO2 baseline sensor", this->eco2_sensor_baseline_);
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LOG_SENSOR(" ", "TVOC baseline sensor", this->tvoc_sensor_baseline_);
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ESP_LOGCONFIG(TAG, "Store baseline: %s", YESNO(this->store_baseline_));
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if (this->humidity_sensor_ != nullptr && this->temperature_sensor_ != nullptr) {
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ESP_LOGCONFIG(TAG, " Compensation:");
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LOG_SENSOR(" ", "Temperature Source:", this->temperature_sensor_);
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LOG_SENSOR(" ", "Humidity Source:", this->humidity_sensor_);
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} else {
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ESP_LOGCONFIG(TAG, " Compensation: No source configured");
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}
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}
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void SGP30Component::update() {
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if (!this->write_command_(SGP30_CMD_MEASURE_IAQ)) {
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this->status_set_warning();
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return;
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}
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this->seconds_since_last_store_ += this->update_interval_ / 1000;
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this->set_timeout(50, [this]() {
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uint16_t raw_data[2];
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if (!this->read_data_(raw_data, 2)) {
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this->status_set_warning();
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return;
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}
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float eco2 = (raw_data[0]);
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float tvoc = (raw_data[1]);
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ESP_LOGD(TAG, "Got eCO2=%.1fppm TVOC=%.1fppb", eco2, tvoc);
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if (this->eco2_sensor_ != nullptr)
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this->eco2_sensor_->publish_state(eco2);
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if (this->tvoc_sensor_ != nullptr)
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this->tvoc_sensor_->publish_state(tvoc);
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if (this->get_update_interval() != 1000) {
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ESP_LOGW(TAG, "Update interval for SGP30 sensor must be set to 1s for optimized readout");
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}
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this->status_clear_warning();
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this->send_env_data_();
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this->read_iaq_baseline_();
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});
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}
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bool SGP30Component::write_command_(uint16_t command) {
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// Warning ugly, trick the I2Ccomponent base by setting register to the first 8 bit.
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return this->write_byte(command >> 8, command & 0xFF);
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}
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uint8_t SGP30Component::sht_crc_(uint8_t data1, uint8_t data2) {
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uint8_t bit;
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uint8_t crc = 0xFF;
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crc ^= data1;
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for (bit = 8; bit > 0; --bit) {
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if (crc & 0x80)
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crc = (crc << 1) ^ 0x131;
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else
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crc = (crc << 1);
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}
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crc ^= data2;
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for (bit = 8; bit > 0; --bit) {
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if (crc & 0x80)
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crc = (crc << 1) ^ 0x131;
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else
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crc = (crc << 1);
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}
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return crc;
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}
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bool SGP30Component::read_data_(uint16_t *data, uint8_t len) {
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const uint8_t num_bytes = len * 3;
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auto *buf = new uint8_t[num_bytes];
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if (!this->parent_->raw_receive(this->address_, buf, num_bytes)) {
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delete[](buf);
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return false;
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}
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for (uint8_t i = 0; i < len; i++) {
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const uint8_t j = 3 * i;
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uint8_t crc = sht_crc_(buf[j], buf[j + 1]);
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if (crc != buf[j + 2]) {
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ESP_LOGE(TAG, "CRC8 Checksum invalid! 0x%02X != 0x%02X", buf[j + 2], crc);
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delete[](buf);
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return false;
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}
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data[i] = (buf[j] << 8) | buf[j + 1];
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}
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delete[](buf);
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return true;
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}
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} // namespace sgp30
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} // namespace esphome
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