Robert Hill
/
FRDM_HR_
This is the Heart Rate demo program, testing and verifying the functionality of the HR sensor.
HeartRate.cpp
- Committer:
- roberthill04
- Date:
- 2016-02-24
- Revision:
- 0:92d3ea9d3e67
File content as of revision 0:92d3ea9d3e67:
#include "PulseSensor.h" #include "mbed.h" //#include "AnalogIn.h" DigitalOut led_red(LED_RED); DigitalOut led_green(LED_GREEN); DigitalOut led_blue(LED_BLUE); DigitalIn sw2(SW2); DigitalIn sw3(SW3); Serial pc(USBTX, USBRX); AnalogIn Pulse_Signal(A0); //Initialize analog input for pulse signal bool Button_Pressed = true; //Initialize flag for output on terminal PulseSensor::PulseSensor(PinName analogPin, void (*printDataCallback)(char,int), int callbackRateMs) { _started = false; _pAin = new AnalogIn(analogPin); _callbackRateMs = callbackRateMs; _printDataCallback = printDataCallback; } PulseSensor::~PulseSensor() { delete _pAin; } void PulseSensor::process_data_ticker_callback(void) { _printDataCallback('S', Signal); // send Processing the raw Pulse Sensor data if (QS == true) { // Quantified Self flag is true when a heartbeat is found //fadeRate = 255; // Set 'fadeRate' Variable to 255 to fade LED with pulse _printDataCallback('B',BPM); // send heart rate with a 'B' prefix _printDataCallback('Q',IBI); // send time between beats with a 'Q' prefix QS = false; // reset the Quantified Self flag for next time } } void PulseSensor::sensor_ticker_callback(void) { Signal = 1023 * _pAin->read(); // read the Pulse Sensor sampleCounter += 2; // keep track of the time in mS with this variable int N = sampleCounter - lastBeatTime; // monitor the time since the last beat to avoid noise // find the peak and trough of the pulse wave if(Signal < thresh && N > (IBI/5)*3) { // avoid dichrotic noise by waiting 3/5 of last IBI if (Signal < T) { // T is the trough T = Signal; // keep track of lowest point in pulse wave } } if(Signal > thresh && Signal > P) { // thresh condition helps avoid noise P = Signal; // P is the peak } // keep track of highest point in pulse wave // NOW IT'S TIME TO LOOK FOR THE HEART BEAT // signal surges up in value every time there is a pulse if (N > 250) { // avoid high frequency noise by waiting //this also sets limit to HR sensor to max =240 BPMs if ( (Signal > thresh) && (Pulse == false) && (N > (IBI/5)*3) ) { Pulse = true; // set the Pulse flag when we think there is a pulse //digitalWrite(blinkPin,HIGH); // turn on pin 13 LED IBI = sampleCounter - lastBeatTime; // measure time between beats in mS lastBeatTime = sampleCounter; // keep track of time for next pulse if(firstBeat) { // if it's the first time we found a beat, if firstBeat == TRUE firstBeat = false; // clear firstBeat flag return; // IBI value is unreliable so discard it } if(secondBeat) { // if this is the second beat, if secondBeat == TRUE secondBeat = false; // clear secondBeat flag for(int i=0; i<=9; i++) { // seed the running total to get a realisitic BPM at startup rate[i] = IBI; } } // keep a running total of the last 10 IBI values long runningTotal = 0; // clear the runningTotal variable for(int i=0; i<=8; i++) { // shift data in the rate array rate[i] = rate[i+1]; // and drop the oldest IBI value runningTotal += rate[i]; // add up the 9 oldest IBI values } rate[9] = IBI; // add the latest IBI to the rate array runningTotal += rate[9]; // add the latest IBI to runningTotal runningTotal /= 10; // average the last 10 IBI values BPM = 60000/runningTotal; // how many beats can fit into a minute? that's BPM! QS = true; // set Quantified Self flag // QS FLAG IS NOT CLEARED INSIDE THIS ISR } } if (Signal < thresh && Pulse == true) { // when the values are going down, the beat is over Pulse = false; // reset the Pulse flag so we can do it again amp = P - T; // get amplitude of the pulse wave thresh = amp/2 + T; // set thresh at 50% of the amplitude P = thresh; // reset these for next time T = thresh; } if (N > 2500) { // if 2.5 seconds go by without a beat thresh = 512; // set thresh default P = 512; // set P default T = 512; // set T default lastBeatTime = sampleCounter; // bring the lastBeatTime up to date firstBeat = true; // set these to avoid noise secondBeat = true; // when we get the heartbeat back } } void sendDataToProcessing(char symbol, int data) { pc.printf("%c%d\r\n", symbol, data); } int main() { pc.baud(9600); pc.printf("Hello World from FRDM-K64F board. This is the Heart Rate Demo Program. "); pc.printf("Press SW2 (Button Near FRDM Logo) to see current Heart Rate.\n "); led_blue = 1; //LED is off led_green = 1; led_red = 1; PulseSensor Pulse_Signal(A0, sendDataToProcessing); Pulse_Signal.start(); while(1) { if (sw2 == 0 && Button_Pressed == true) { Pulse_Signal.stop(); //stops the continuous signal pc.printf("Current Heart Rate is: %d BPM \t", Pulse_Signal.BPM); Button_Pressed= false; wait(1); } else if (sw3 == 0 && Button_Pressed == true) { Pulse_Signal.start(); //restarts the pulse signal // Button_Pressed= false; } Button_Pressed = true; } } bool PulseSensor::start() { if (_started == false) { sampleCounter = 0; lastBeatTime = 0; P =512; T = 512; thresh = 512; amp = 100; firstBeat = true; secondBeat = true; BPM=0; Signal=0; IBI = 600; Pulse = false; QS = false; _pulseSensorTicker.attach(this, &PulseSensor::sensor_ticker_callback, ((float)_sensorTickRateMs/1000)); _processDataTicker.attach(this, &PulseSensor::process_data_ticker_callback, ((float)_callbackRateMs/1000)); _started = true; return true; } else { return false; } } bool PulseSensor::stop() { if(_started == true) { _pulseSensorTicker.detach(); _processDataTicker.detach(); _started = false; return true; } else { return false; } }