#include <Wire.h> #include "MAX30105.h" #include "spo2_algorithm.h" MAX30105 particleSensor; #define MAX_BRIGHTNESS 255 #if defined(__AVR_ATmega328P__) || defined(__AVR_ATmega168__) //Arduino Uno doesn't have enough SRAM to store 100 samples of IR led data and red led data in 32-bit format //To solve this problem, 16-bit MSB of the sampled data will be truncated. Samples become 16-bit data. uint16_t irBuffer[100]; //infrared LED sensor data uint16_t redBuffer[100]; //red LED sensor data #else uint32_t irBuffer[100]; //infrared LED sensor data uint32_t redBuffer[100]; //red LED sensor data #endif int32_t bufferLength; //data length int32_t spo2; //SPO2 value int8_t validSPO2; //indicator to show if the SPO2 calculation is valid int32_t heartRate; //heart rate value int8_t validHeartRate; //indicator to show if the heart rate calculation is valid byte pulseLED = 11; //Must be on PWM pin byte readLED = 13; //Blinks with each data read void setup() { Serial.begin(115200); // initialize serial communication at 115200 bits per second: pinMode(pulseLED, OUTPUT); pinMode(readLED, OUTPUT); // Initialize sensor if (!particleSensor.begin(Wire, I2C_SPEED_FAST)) //Use default I2C port, 400kHz speed { Serial.println(F("MAX30105 was not found. Please check wiring/power.")); while (1); } Serial.println(F("Attach sensor to finger with rubber band. Press any key to start conversion")); while (Serial.available() == 0) ; //wait until user presses a key Serial.read(); byte ledBrightness = 60; //Options: 0=Off to 255=50mA byte sampleAverage = 4; //Options: 1, 2, 4, 8, 16, 32 byte ledMode = 2; //Options: 1 = Red only, 2 = Red + IR, 3 = Red + IR + Green byte sampleRate = 100; //Options: 50, 100, 200, 400, 800, 1000, 1600, 3200 int pulseWidth = 411; //Options: 69, 118, 215, 411 int adcRange = 4096; //Options: 2048, 4096, 8192, 16384 particleSensor.setup(ledBrightness, sampleAverage, ledMode, sampleRate, pulseWidth, adcRange); //Configure sensor with these settings } void loop() { bufferLength = 100; //buffer length of 100 stores 4 seconds of samples running at 25sps //read the first 100 samples, and determine the signal range for (byte i = 0 ; i < bufferLength ; i++) { while (particleSensor.available() == false) //do we have new data? particleSensor.check(); //Check the sensor for new data redBuffer[i] = particleSensor.getRed(); irBuffer[i] = particleSensor.getIR(); particleSensor.nextSample(); //We're finished with this sample so move to next sample Serial.print(F("red=")); Serial.print(redBuffer[i], DEC); Serial.print(F(", ir=")); Serial.println(irBuffer[i], DEC); } //calculate heart rate and SpO2 after first 100 samples (first 4 seconds of samples) maxim_heart_rate_and_oxygen_saturation(irBuffer, bufferLength, redBuffer, & spo2, & validSPO2, & heartRate, & validHeartRate); //Continuously taking samples from MAX30102. Heart rate and SpO2 are calculated every 1 second while (1) { //dumping the first 25 sets of samples in the memory and shift the last 75 sets of samples to the top for (byte i = 25; i < 100; i++) { redBuffer[i - 25] = redBuffer[i]; irBuffer[i - 25] = irBuffer[i]; } //take 25 sets of samples before calculating the heart rate. for (byte i = 75; i < 100; i++) { while (particleSensor.available() == false) //do we have new data? particleSensor.check(); //Check the sensor for new data digitalWrite(readLED, !digitalRead(readLED)); //Blink onboard LED with every data read redBuffer[i] = particleSensor.getRed(); irBuffer[i] = particleSensor.getIR(); particleSensor.nextSample(); //We're finished with this sample so move to next sample Serial.print(F(", HR=")); Serial.print(heartRate, DEC); Serial.print(F(", HRvalid=")); Serial.print(validHeartRate, DEC); Serial.print(F(", SPO2=")); Serial.print(spo2, DEC); Serial.print(F(", SPO2Valid=")); Serial.println(validSPO2, DEC); } //After gathering 25 new samples recalculate HR and SP02 maxim_heart_rate_and_oxygen_saturation(irBuffer, bufferLength, redBuffer, spo2, & validSPO2, & heartRate, & validHeartRate); } }