/** * Simple example with one sensor connected to I2C bus 0 and a sequence of * heating profiles. The heating profile is changed with each cycle. * * Harware configuration: * * I2C +-------------------------+ +----------+ * | ESP8266 Bus 0 | | BME680 | * | GPIO 14 (SCL) ------> SCL | * | GPIO 13 (SDA) ------- SDA | * +-------------------------+ +----------+ */ #include "espressif/esp_common.h" #include "esp/uart.h" #include "FreeRTOS.h" #include "task.h" // include communication interface driver #include "i2c/i2c.h" // include BME680 driver #include "bme680/bme680.h" // define I2C interface for BME680 sensors #define I2C_BUS 0 #define I2C_SCL_PIN 14 #define I2C_SDA_PIN 13 static bme680_sensor_t* sensor; /* * User task that triggers measurements of sensor every seconds. It uses * function *vTaskDelay* to wait for measurement results and changes the * heating profile in each cycle. */ void user_task(void *pvParameters) { bme680_values_float_t values; TickType_t last_wakeup = xTaskGetTickCount(); uint32_t count = 0; while (1) { if (count++ < 60) // disable gas measurement for cycle counter < 60 bme680_use_heater_profile (sensor, BME680_HEATER_NOT_USED); else // change heating profile in each cycle switch (count % 5) { case 0: bme680_use_heater_profile (sensor, 0); break; case 1: bme680_use_heater_profile (sensor, 1); break; case 2: bme680_use_heater_profile (sensor, 2); break; case 3: bme680_use_heater_profile (sensor, 3); break; case 4: bme680_use_heater_profile (sensor, 4); break; } // measurement duration changes in each cycle uint32_t duration = bme680_get_measurement_duration(sensor); // trigger the sensor to start one TPHG measurement cycle if (bme680_force_measurement (sensor)) { // passive waiting until measurement results are available vTaskDelay (duration); // get the results and do something with them if (bme680_get_results_float (sensor, &values)) printf("%.3f BME680 Sensor: %.2f °C, %.2f %%, %.2f hPa, %.2f Ohm\n", (double)sdk_system_get_time()*1e-3, values.temperature, values.humidity, values.pressure, values.gas_resistance); } // passive waiting until 1 second is over vTaskDelayUntil(&last_wakeup, 1000 / portTICK_PERIOD_MS); } } void user_init(void) { // Set UART Parameter uart_set_baud(0, 115200); // Give the UART some time to settle sdk_os_delay_us(500); /** -- MANDATORY PART -- */ #ifdef SPI_USED // Init the sensor connected to SPI. sensor = bme680_init_sensor (SPI_BUS, 0, SPI_CS_GPIO); #else // Init all I2C bus interfaces at which BME680 sensors are connected i2c_init(I2C_BUS, I2C_SCL_PIN, I2C_SDA_PIN, I2C_FREQ_100K); // Init the sensor connected to I2C. sensor = bme680_init_sensor (I2C_BUS, BME680_I2C_ADDRESS_2, 0); #endif if (sensor) { // Create a task that uses the sensor xTaskCreate(user_task, "user_task", 256, NULL, 2, NULL); /** -- OPTIONAL PART -- */ // Changes the oversampling rates to 4x oversampling for temperature // and 2x oversampling for humidity. Pressure measurement is skipped. bme680_set_oversampling_rates(sensor, osr_4x, osr_none, osr_2x); // Change the IIR filter size for temperature and pressure to 7. bme680_set_filter_size(sensor, iir_size_7); // Define a number of different heating profiles bme680_set_heater_profile (sensor, 0, 200, 100); bme680_set_heater_profile (sensor, 1, 250, 120); bme680_set_heater_profile (sensor, 2, 300, 140); bme680_set_heater_profile (sensor, 3, 350, 160); bme680_set_heater_profile (sensor, 4, 400, 180); } }