/** * Simple example with one sensor connected to I2C bus 0. It demonstrates * how to use CCS811 with an external NTC thermistor to determine ambient * temperature. * * Harware configuration: * * +------------------------+ +--------+ * | ESP8266 Bus 0 | | CCS811 | * | GPIO 14 (SCL) >----> SCL | * | GPIO 13 (SDA) <----> SDA | * | GND -----> /WAKE | * +------------------------+ +--------+ */ #include "espressif/esp_common.h" #include "esp/uart.h" #include "i2c/i2c.h" #include "FreeRTOS.h" #include #include // include CCS811 driver #include "ccs811/ccs811.h" // define I2C interfaces at which CCS811 sensors can be connected #define I2C_BUS 0 #define I2C_SCL_PIN 14 #define I2C_SDA_PIN 13 static ccs811_sensor_t* sensor; /* * In this example, user task fetches the sensor values every seconds. */ // parameters of the Adafruit CCS811 Air Quality Sensor Breakout #define CCS811_R_REF 100000 #define CCS811_R_NTC 10000 #define CCS811_R_NTC_TEMP 25 #define CCS811_BCONSTANT 3380 void user_task_periodic(void *pvParameters) { uint16_t tvoc; uint16_t eco2; TickType_t last_wakeup = xTaskGetTickCount(); while (1) { // get environmental data from another sensor and set them // ccs811_set_environmental_data (sensor, 25.3, 47.8); // get the results and do something with them if (ccs811_get_results (sensor, &tvoc, &eco2, 0, 0)) printf("%.3f CCS811 Sensor periodic: TVOC %d ppb, eCO2 %d ppm\n", (double)sdk_system_get_time()*1e-3, tvoc, eco2); // get NTC resistance uint32_t r_ntc = ccs811_get_ntc_resistance (sensor, CCS811_R_REF); // calculation of temperature from application note ams AN000372 double ntc_temp; ntc_temp = log((double)r_ntc / CCS811_R_NTC); // 1 ntc_temp /= CCS811_BCONSTANT; // 2 ntc_temp += 1.0 / (CCS811_R_NTC_TEMP + 273.15); // 3 ntc_temp = 1.0 / ntc_temp; // 4 ntc_temp -= 273.15; // 5 printf("%.3f CCS811 Sensor temperature: R_NTC %u Ohm, T %f °C\n", (double)sdk_system_get_time()*1e-3, r_ntc, ntc_temp); // passive waiting until 1 second is over vTaskDelayUntil(&last_wakeup, 1100 / 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 -- */ // init all I2C bus interfaces at which CCS811 sensors are connected i2c_init(I2C_BUS, I2C_SCL_PIN, I2C_SDA_PIN, I2C_FREQ_100K); // longer clock stretching is required for CCS811 i2c_set_clock_stretch (I2C_BUS, CCS811_I2C_CLOCK_STRETCH); // init the sensor with slave address CCS811_I2C_ADDRESS_1 connected I2C_BUS. sensor = ccs811_init_sensor (I2C_BUS, CCS811_I2C_ADDRESS_1); if (sensor) { #if defined(INT_DATA_RDY_USED) || defined(INT_THRESHOLD_USED) // create a task that is resumed by interrupt handler to use the sensor xTaskCreate(user_task_interrupt, "user_task_interrupt", 256, NULL, 2, &nINT_task); // set the GPIO and interrupt handler for *nINT* interrupt gpio_set_interrupt(INT_GPIO, GPIO_INTTYPE_EDGE_NEG, nINT_handler); #ifdef INT_DATA_RDY_USED // enable the data ready interrupt ccs811_enable_interrupt (sensor, true); #else // set threshold parameters and enable threshold interrupt mode ccs811_set_eco2_thresholds (sensor, 600, 1100, 40); #endif #else // create a periodic task that uses the sensor xTaskCreate(user_task_periodic, "user_task_periodic", 256, NULL, 2, NULL); #endif // start periodic measurement with one measurement per second ccs811_set_mode (sensor, ccs811_mode_1s); } }