/* Code to detect pulses from the PulseSensor, using an interrupt service routine. Here is a link to the tutorial\ https://pulsesensor.com/pages/getting-advanced Copyright World Famous Electronics LLC - see LICENSE Contributors: Joel Murphy, https://pulsesensor.com Yury Gitman, https://pulsesensor.com Bradford Needham, @bneedhamia, https://bluepapertech.com Licensed under the MIT License, a copy of which should have been included with this software. This software is not intended for medical use. */ /* Every Sketch that uses the PulseSensor Playground must define USE_ARDUINO_INTERRUPTS before including PulseSensorPlayground.h. Here, #define USE_ARDUINO_INTERRUPTS true tells the library to use interrupts to automatically read and process PulseSensor data. See ProcessEverySample.ino for an example of not using interrupts. */ #define USE_ARDUINO_INTERRUPTS true #include /* The format of our output. Set this to PROCESSING_VISUALIZER if you're going to run the Processing Visualizer Sketch. See https://github.com/WorldFamousElectronics/PulseSensor_Amped_Processing_Visualizer Set this to SERIAL_PLOTTER if you're going to run the Arduino IDE's Serial Plotter. */ const int OUTPUT_TYPE = PROCESSING_VISUALIZER; /* Pinout: PULSE_INPUT = Analog Input. Connected to the pulse sensor purple (signal) wire. PULSE_BLINK = digital Output. Connected to an LED (and 220 ohm resistor) that will flash on each detected pulse. PULSE_FADE = digital Output. PWM pin onnected to an LED (and resistor) that will smoothly fade with each pulse. NOTE: PULSE_FADE must be a pin that supports PWM. Do not use pin 9 or 10, because those pins' PWM interferes with the sample timer. */ const int PULSE_INPUT = A0; const int PULSE_BLINK = 9; // Pin 9 is the on-board LED const int THRESHOLD = 550; // Adjust this number to avoid noise when idle /* All the PulseSensor Playground functions. */ PulseSensorPlayground pulseSensor; void setup() { /* Use 115200 baud because that's what the Processing Sketch expects to read, and because that speed provides about 11 bytes per millisecond. If we used a slower baud rate, we'd likely write bytes faster than they can be transmitted, which would mess up the timing of readSensor() calls, which would make the pulse measurement not work properly. */ Serial.begin(115200); // Configure the PulseSensor manager. pulseSensor.analogInput(PULSE_INPUT); pulseSensor.blinkOnPulse(PULSE_BLINK); pulseSensor.setSerial(Serial); pulseSensor.setOutputType(OUTPUT_TYPE); pulseSensor.setThreshold(THRESHOLD); // Now that everything is ready, start reading the PulseSensor signal. if (!pulseSensor.begin()) { /* PulseSensor initialization failed, likely because our particular Arduino platform interrupts aren't supported yet. If your Sketch hangs here, try PulseSensor_BPM_Alternative.ino, which doesn't use interrupts. */ for(;;) { // Flash the led to show things didn't work. digitalWrite(PULSE_BLINK, LOW); delay(50); digitalWrite(PULSE_BLINK, HIGH); delay(50); } } } void loop() { /* Wait a bit. We don't output every sample, because our baud rate won't support that much I/O. */ delay(20); // write the latest sample to Serial. pulseSensor.outputSample(); /* If a beat has happened since we last checked, write the per-beat information to Serial. */ if (pulseSensor.sawStartOfBeat()) { pulseSensor.outputBeat(); } }