max30100
Dependents: BIOMETRICOS_HUMANOS_BETA
Fork of MAX30100 by
MAX30100_BeatDetector.cpp
- Committer:
- AVELARDEV
- Date:
- 2016-11-25
- Revision:
- 0:010b908e2187
File content as of revision 0:010b908e2187:
/* Arduino-MAX30100 oximetry / heart rate integrated sensor library Copyright (C) 2016 OXullo Intersecans <x@brainrapers.org> This program is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program. If not, see <http://www.gnu.org/licenses/>. */ #include "MAX30100_BeatDetector.h" BeatDetector::BeatDetector() : state(BEATDETECTOR_STATE_INIT), threshold(BEATDETECTOR_MIN_THRESHOLD), beatPeriod(0), lastMaxValue(0), tsLastBeat(0) { t.start(); } bool BeatDetector::addSample(float sample) { return checkForBeat(sample); } float BeatDetector::getRate() { if (beatPeriod != 0) { return 1 / beatPeriod * 1000 * 60; } else { return 0; } } float BeatDetector::getCurrentThreshold() { return threshold; } bool BeatDetector::checkForBeat(float sample) { bool beatDetected = false; switch (state) { case BEATDETECTOR_STATE_INIT: if (t.read_ms() > BEATDETECTOR_INIT_HOLDOFF) { state = BEATDETECTOR_STATE_WAITING; } break; case BEATDETECTOR_STATE_WAITING: if (sample > threshold) { threshold = std::min((uint32_t)sample, (uint32_t)BEATDETECTOR_MAX_THRESHOLD); state = BEATDETECTOR_STATE_FOLLOWING_SLOPE; } // Tracking lost, resetting if (t.read_ms() > BEATDETECTOR_INVALID_READOUT_DELAY) { beatPeriod = 0; lastMaxValue = 0; } decreaseThreshold(); break; case BEATDETECTOR_STATE_FOLLOWING_SLOPE: if (sample < threshold) { state = BEATDETECTOR_STATE_MAYBE_DETECTED; } else { threshold = std::min((uint32_t)sample, (uint32_t)BEATDETECTOR_MAX_THRESHOLD); } break; case BEATDETECTOR_STATE_MAYBE_DETECTED: if (sample + BEATDETECTOR_STEP_RESILIENCY < threshold) { // Found a beat beatDetected = true; lastMaxValue = sample; state = BEATDETECTOR_STATE_MASKING; float delta = t.read_ms(); if (delta) { beatPeriod = BEATDETECTOR_BPFILTER_ALPHA * delta + (1 - BEATDETECTOR_BPFILTER_ALPHA) * beatPeriod; } t.reset(); } else { state = BEATDETECTOR_STATE_FOLLOWING_SLOPE; } break; case BEATDETECTOR_STATE_MASKING: if (t.read_ms() > BEATDETECTOR_MASKING_HOLDOFF) { state = BEATDETECTOR_STATE_WAITING; } decreaseThreshold(); break; } return beatDetected; } void BeatDetector::decreaseThreshold() { // When a valid beat rate readout is present, target the if (lastMaxValue > 0 && beatPeriod > 0) { threshold -= lastMaxValue * (1 - BEATDETECTOR_THRESHOLD_FALLOFF_TARGET) / (beatPeriod / BEATDETECTOR_SAMPLES_PERIOD); } else { // Asymptotic decay threshold *= BEATDETECTOR_THRESHOLD_DECAY_FACTOR; } if (threshold < BEATDETECTOR_MIN_THRESHOLD) { threshold = BEATDETECTOR_MIN_THRESHOLD; } }