/* * Author: Andrei Vasiliu * Author: Yevgeniy Kiveisha * Copyright (c) 2015 Intel Corporation. * * Permission is hereby granted, free of charge, to any person obtaining * a copy of this software and associated documentation files (the * "Software"), to deal in the Software without restriction, including * without limitation the rights to use, copy, modify, merge, publish, * distribute, sublicense, and/or sell copies of the Software, and to * permit persons to whom the Software is furnished to do so, subject to * the following conditions: * * The above copyright notice and this permission notice shall be * included in all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, * EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND * NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE * LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION * OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION * WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. */ #include #include #include #include #include "pulsensor.h" #if defined(JAVACALLBACK) Pulsensor::Pulsensor (Callback *obj_call) : pin_ctx(0) { obj_callback = obj_call; sample_counter = 0; last_beat_time = 0; threshold = 512; ibi = 600; trough = 512; peak = 512; is_pulse = FALSE; ret = FALSE; bpm = 0; qs = FALSE; apmlitude = 100; } #else Pulsensor::Pulsensor (callback_handler handler) : pin_ctx(0) { callback = handler; sample_counter = 0; last_beat_time = 0; threshold = 512; ibi = 600; trough = 512; peak = 512; is_pulse = FALSE; ret = FALSE; bpm = 0; qs = FALSE; apmlitude = 100; } #endif void Pulsensor::start_sampler () { int error; ctx_counter++; usleep (100000); error = pthread_create (&(sample_thread), NULL, &Pulsensor::do_sample, this); if (error != 0) { printf ("ERROR : Cannot created sampler thread.\n"); } } void Pulsensor::stop_sampler () { ctx_counter--; } void *Pulsensor::do_sample (void *arg) { int data_from_sensor; clbk_data callback_data; Pulsensor *pulsensor = static_cast(arg); while (pulsensor->ctx_counter) { data_from_sensor = pulsensor->pin_ctx.read (); pulsensor->ret = FALSE; pulsensor->sample_counter += 2; int N = pulsensor->sample_counter - pulsensor->last_beat_time; if (data_from_sensor < pulsensor->threshold && N > ( pulsensor->ibi / 5)* 3) { if (data_from_sensor < pulsensor->trough) { pulsensor->trough = data_from_sensor; } } if (data_from_sensor > pulsensor->threshold && data_from_sensor > pulsensor->peak) { pulsensor->peak = data_from_sensor; } if (N > 250) { // printf ("(NO_GDB) DEBUG\n"); if ( (data_from_sensor > pulsensor->threshold) && (pulsensor->is_pulse == FALSE) && (N > (pulsensor->ibi / 5)* 3) ) { pulsensor->is_pulse = callback_data.is_heart_beat = TRUE; #if defined(JAVACALLBACK) pulsensor->obj_callback->run(callback_data); #else pulsensor->callback(callback_data); #endif pulsensor->ibi = pulsensor->sample_counter - pulsensor->last_beat_time; pulsensor->last_beat_time = pulsensor->sample_counter; // second beat if (pulsensor->second_beat) { pulsensor->second_beat = FALSE; for (int i = 0; i <= 9; i++) { pulsensor->ibi_rate[i] = pulsensor->ibi; } } // first beat if (pulsensor->first_beat) { pulsensor->first_beat = FALSE; pulsensor->second_beat = TRUE; pulsensor->ret = TRUE; } else { uint32_t running_total = 0; for(int i = 0; i <= 8; i++){ pulsensor->ibi_rate[i] = pulsensor->ibi_rate[i+1]; running_total += pulsensor->ibi_rate[i]; } pulsensor->ibi_rate[9] = pulsensor->ibi; running_total += pulsensor->ibi_rate[9]; running_total /= 10; pulsensor->bpm = 60000 / running_total; pulsensor->qs = TRUE; } } } if (pulsensor->ret == FALSE) { if (data_from_sensor < pulsensor->threshold && pulsensor->is_pulse == TRUE) { pulsensor->is_pulse = callback_data.is_heart_beat = FALSE; #if defined(JAVACALLBACK) pulsensor->obj_callback->run(callback_data); #else pulsensor->callback(callback_data); #endif pulsensor->is_pulse = FALSE; pulsensor->apmlitude = pulsensor->peak - pulsensor->trough; pulsensor->threshold = pulsensor->apmlitude / 2 + pulsensor->trough; pulsensor->peak = pulsensor->threshold; pulsensor->trough = pulsensor->threshold; } if (N > 2500) { pulsensor->threshold = 512; pulsensor->peak = 512; pulsensor->trough = 512; pulsensor->last_beat_time = pulsensor->sample_counter; pulsensor->first_beat = TRUE; pulsensor->second_beat = FALSE; } } usleep (2000); } return NULL; }