This example shows how to use WisBlock IO RAK1921 which is an OLED SSD1306(128*64, I2C) board.
The following hardware are required.
- WisBlock Base RAK5005-O * 1pcs
- WisBlock Core RAK4631 * 1pcs
- WisBlock Sensor RAK1906 * 1pcs (Optional)
- WisBlock IO RAK1921 * 1pcs
Hardware is shown as follows:
Assembled as follows:
For stable connection, please use screws to tighten.
To use the environment WisBlock Sensor RAK1906, The following software is required.
- ArduinoIDE
- RAK4630 BSP
- U8g2 library
- Adafruit BME680 Library
Connect the assembled hardware to the PC with a USB cable, open the Arduino, and select the development board and port in the tool menu.
The Demo is designed to display BME680 sensor data on SSD1306.
/*
This sketch demonstrate how to use SSD1306 to display sensor data of BME680.
*/
/**
@file RAK1920_QWIIC_AirQuality_SGP30.ino
@author rakwireless.com
@brief This sketch demonstrate how to use SSD1306 to display sensor data of BME680.
@version 0.1
@date 2020-07-28
@copyright Copyright (c) 2020
@note RAK5005-O GPIO mapping to RAK4631 GPIO ports
RAK5005-O <-> nRF52840
IO1 <-> P0.17 (Arduino GPIO number 17)
IO2 <-> P1.02 (Arduino GPIO number 34)
IO3 <-> P0.21 (Arduino GPIO number 21)
IO4 <-> P0.04 (Arduino GPIO number 4)
IO5 <-> P0.09 (Arduino GPIO number 9)
IO6 <-> P0.10 (Arduino GPIO number 10)
SW1 <-> P0.01 (Arduino GPIO number 1)
A0 <-> P0.04/AIN2 (Arduino Analog A2
A1 <-> P0.31/AIN7 (Arduino Analog A7
SPI_CS <-> P0.26 (Arduino GPIO number 26)
*/
#include <Wire.h>
#include <Adafruit_Sensor.h>
#include <Adafruit_BME680.h> // Click to install library: http://librarymanager/All#Adafruit_BME680
#include <U8g2lib.h> // Click to install library: http://librarymanager/All#u8g2
U8G2_SSD1306_128X64_NONAME_F_HW_I2C u8g2(U8G2_R0);
Adafruit_BME680 bme;
void bme680_init()
{
Wire.begin();
if (!bme.begin(0x76)) {
Serial.println("Could not find a valid BME680 sensor, check wiring!");
return;
}
// Set up oversampling and filter initialization
bme.setTemperatureOversampling(BME680_OS_8X);
bme.setHumidityOversampling(BME680_OS_2X);
bme.setPressureOversampling(BME680_OS_4X);
bme.setIIRFilterSize(BME680_FILTER_SIZE_3);
bme.setGasHeater(320, 150); // 320*C for 150 ms
}
void bme680_get()
{
char data[32] = {0};
double temp = bme.temperature;
double pres = bme.pressure / 100.0;
double hum = bme.humidity;
Serial.print("T=");
Serial.print(temp);
Serial.print("C, RH=");
Serial.print(hum);
Serial.print("%, P=");
Serial.print(pres);
Serial.print("hPa");
float gas = bme.gas_resistance / 1000.0;
Serial.printf(", G= %.3f kOhms\n", gas);
// display bme680 sensor data on OLED
u8g2.clearBuffer(); // clear the internal memory
u8g2.setFont(u8g2_font_ncenB10_tr); // choose a suitable font
memset(data, 0, sizeof(data));
sprintf(data, "T=%.2fC", temp);
u8g2.drawStr(3, 15, data);
memset(data, 0, sizeof(data));
snprintf(data, 64, "RH=%.2f%%", hum);
u8g2.drawStr(3, 30, data);
memset(data, 0, sizeof(data));
sprintf(data, "P=%.2fhPa", pres);
u8g2.drawStr(3, 45, data);
memset(data, 0, sizeof(data));
sprintf(data, "G=%.3f kOhms", gas);
u8g2.drawStr(3, 60, data);
u8g2.sendBuffer(); // transfer internal memory to the display
}
void setup()
{
// Initialize the built in LED
pinMode(LED_BUILTIN, OUTPUT);
digitalWrite(LED_BUILTIN, LOW);
// Initialize Serial for debug output
Serial.begin(115200);
time_t serial_timeout = millis();
// On nRF52840 the USB serial is not available immediately
while (!Serial)
{
if ((millis() - serial_timeout) < 5000)
{
delay(100);
digitalWrite(LED_BUILTIN, !digitalRead(LED_BUILTIN));
}
else
{
break;
}
}
bme680_init();
u8g2.begin();
}
void loop()
{
if (! bme.performReading()) {
Serial.println("Failed to perform reading :(");
return;
}
bme680_get();
delay(5000);
}
The test results are as follows:
