class heart_rate
pixart_heart_rate.cpp
- Committer:
- bell_huang
- Date:
- 2017-10-27
- Revision:
- 8:70ed6c78681c
- Parent:
- 7:95cb4b23a31f
File content as of revision 8:70ed6c78681c:
#include "pixart_heart_rate.h" #include "pah8series_api_c.h" #include <limits> #include <string.h> #include <stdlib.h> #define debug_printf(...) \ do { \ if (m_debug_print_handler) \ m_debug_print_handler(__VA_ARGS__); \ } while (0) #define log_printf(...) debug_printf(__VA_ARGS__) namespace pixart { class pah_hr_data : public pah8series_data_t {}; const float heart_rate::GRAVITY_OF_EARTH = 9.80665f; const size_t heart_rate::PPG_SYNC_COUNT = 20; const size_t heart_rate::ACCEL_AXIS_NUM = 3; heart_rate::heart_rate(TIME_TO_MILLISEC_HANDLE time_to_millisec_handler, size_t ppg_max_sample_num, size_t accel_max_sample_num) : PPG_MAX_SAMPLE_NUM(ppg_max_sample_num) , PPG_CH_NUM(2) , ACCEL_MAX_SAMPLE_NUM(accel_max_sample_num) , m_debug_print_handler(NULL) , m_time_to_millisec_handler(time_to_millisec_handler) , m_alg_buffer(NULL) , m_gravity_mode(gravity_4g) , m_last_report_timestamp(0) , m_frame_count(0) { } heart_rate::~heart_rate() { pah8series_close(); if (m_alg_buffer) free(m_alg_buffer); } void heart_rate::enable_debug_print(DEBUG_PRINT_HANDLE handler) { m_debug_print_handler = handler; } bool heart_rate::init(gravity_mode gravity) { if (!m_alg_buffer) m_alg_buffer = malloc(pah8series_query_open_size()); if (!m_alg_buffer) return false; uint8_t ret = pah8series_open(m_alg_buffer); if (ret != MSG_SUCCESS) return false; pah8series_set_param(PAH8SERIES_PARAM_IDX_PPG_CH_NUM, (float)PPG_CH_NUM); pah8series_set_param(PAH8SERIES_PARAM_IDX_HAS_IR_CH, 0.0f); float gsensor_mode = (float)gravity_to_hr_alg_gsensor_mode(gravity); pah8series_set_param(PAH8SERIES_PARAM_IDX_GSENSOR_MODE, gsensor_mode); log_pah8series_data_header(PPG_CH_NUM, 0, gsensor_mode); m_gravity_mode = gravity; return true; } void heart_rate::reset() { m_ppg_sample_queue.clear(); m_accel_sample_queue.clear(); m_last_report_timestamp = 0; m_frame_count = 0; memset(&m_result, 0, sizeof(m_result)); } bool heart_rate::set_ppg_sample(const ppg_sample &ppg_sample) { // overflow if (m_ppg_sample_queue.size() + 1 > PPG_MAX_SAMPLE_NUM) return false; m_ppg_sample_queue.push_back(ppg_sample); flush(); return true; } bool heart_rate::set_accel_sample(const accel_sample &accel_sample) { // overflow if (m_accel_sample_queue.size() + 1 > ACCEL_MAX_SAMPLE_NUM) return false; m_accel_sample_queue.push_back(accel_sample); return true; } const heart_rate::result& heart_rate::get_result() const { return m_result; } int heart_rate::gravity_to_hr_alg_gsensor_mode(gravity_mode gravity) { int gsensor_mode = 0; switch (gravity) { case gravity_2g: gsensor_mode = 0; break; case gravity_4g: gsensor_mode = 1; break; case gravity_8g: gsensor_mode = 2; break; case gravity_16g: default: gsensor_mode = 3; break; } return gsensor_mode; } int16_t heart_rate::gravity_to_int16(gravity_mode gravity, float value) { typedef int16_t result_type; static const result_type MAX = std::numeric_limits<result_type>::max(); static const result_type MIN = std::numeric_limits<result_type>::min(); float result = (value * MAX) / ((float)gravity * GRAVITY_OF_EARTH); if (result > MAX) return MAX; else if (result < MIN) return MIN; return (result_type)result; } void heart_rate::flush() { // Get sync timestamp if (m_ppg_sample_queue.size() < PPG_SYNC_COUNT) return; uint64_t sync_timestamp = m_ppg_sample_queue[PPG_SYNC_COUNT - 1].timestamp; // Ensure accel sensor has data timestamp later than sync_timestamp if (m_ppg_sample_queue.size() < PPG_MAX_SAMPLE_NUM) { if (m_accel_sample_queue.empty() || (m_accel_sample_queue.back().timestamp < sync_timestamp)) return; } // Flush PPG size_t flush_ppg_sample_count = PPG_SYNC_COUNT; std::vector<int32_t> hr_ppg_data(flush_ppg_sample_count * PPG_CH_NUM); for (size_t i = 0; i < flush_ppg_sample_count; ++i) { hr_ppg_data[i * PPG_CH_NUM + 0] = m_ppg_sample_queue[i].ch1; hr_ppg_data[i * PPG_CH_NUM + 1] = m_ppg_sample_queue[i].ch2; } uint8_t touch_flag = m_ppg_sample_queue[flush_ppg_sample_count - 1].is_touched; uint64_t ppg_timestamp = m_ppg_sample_queue[flush_ppg_sample_count - 1].timestamp; if (m_last_report_timestamp == 0) m_last_report_timestamp = m_ppg_sample_queue.front().timestamp; std::deque<ppg_sample>::iterator flush_ppg_end_iter(m_ppg_sample_queue.begin()); std::advance(flush_ppg_end_iter, flush_ppg_sample_count); m_ppg_sample_queue.erase(m_ppg_sample_queue.begin(), flush_ppg_end_iter); // Flush ACCEL size_t flush_accel_sample_count = 0; for (size_t i = 0; i < m_accel_sample_queue.size(); ++i) { if (m_accel_sample_queue[i].timestamp <= sync_timestamp) ++flush_accel_sample_count; else break; } std::vector<int16_t> hr_accel_data(flush_accel_sample_count * ACCEL_AXIS_NUM); for (size_t i = 0; i < flush_accel_sample_count; ++i) { hr_accel_data[i * ACCEL_AXIS_NUM + 0] = (int16_t)gravity_to_int16(m_gravity_mode, m_accel_sample_queue[i].x); hr_accel_data[i * ACCEL_AXIS_NUM + 1] = (int16_t)gravity_to_int16(m_gravity_mode, m_accel_sample_queue[i].y); hr_accel_data[i * ACCEL_AXIS_NUM + 2] = (int16_t)gravity_to_int16(m_gravity_mode, m_accel_sample_queue[i].z); } std::deque<accel_sample>::iterator flush_accel_end_iter(m_accel_sample_queue.begin()); std::advance(flush_accel_end_iter, flush_accel_sample_count); m_accel_sample_queue.erase(m_accel_sample_queue.begin(), flush_accel_end_iter); // Duration uint32_t time_ms = (uint32_t)m_time_to_millisec_handler(ppg_timestamp - m_last_report_timestamp); m_last_report_timestamp = ppg_timestamp; pah_hr_data pah8series_data; pah8series_data.frame_count = m_frame_count; pah8series_data.time = time_ms; pah8series_data.touch_flag = touch_flag; pah8series_data.nf_ppg_channel = PPG_CH_NUM; pah8series_data.nf_ppg_per_channel = flush_ppg_sample_count; pah8series_data.ppg_data = &hr_ppg_data[0]; pah8series_data.nf_mems = flush_accel_sample_count; pah8series_data.mems_data = &hr_accel_data[0]; ++m_frame_count; if (m_debug_print_handler) log_pah8series_data(&pah8series_data); uint8_t ret = pah8series_entrance(&pah8series_data); float hr = 123.0f; pah8series_get_hr(&hr); int hr_trust_level = 456; pah8series_get_hr_trust_level(&hr_trust_level); //debug_printf("ret = %d, hr = %d, hr_trust_level = %d\n", ret, (int)hr, hr_trust_level); if (ret == MSG_SUCCESS || ret == MSG_HR_READY) m_result.ret = ret_success; else if (ret == MSG_NO_TOUCH) m_result.ret = ret_no_touch; else if (ret == MSG_SIGNAL_POOR) m_result.ret = ret_signal_poor; else m_result.ret = ret_fail; m_result.hr = hr; m_result.hr_trust_level = hr_trust_level; } void heart_rate::log_pah8series_data_header(uint32_t ch_num, uint32_t ir_ch_num, uint32_t g_sensor_mode) { //log pah8series data header // (1)Using total channel numbers; // (2)reserved; // (3)reserved; // (4)IR channel number; // (5)MEMS mode 0:2G, 1:4G, 2:8G log_printf("PPG CH#, %d, %d, %d, %d, %d\n", ch_num, 0, 0, ir_ch_num, g_sensor_mode); } void heart_rate::log_pah8series_data(const pah_hr_data *pxialg_data) { int i = 0; uint32_t *ppg_data = (uint32_t *)pxialg_data->ppg_data; int16_t *mems_data = pxialg_data->mems_data; int data_num = pxialg_data->nf_ppg_channel * pxialg_data->nf_ppg_per_channel; log_printf("Frame Count, %d \n", pxialg_data->frame_count); log_printf("Time, %d \n", pxialg_data->time); log_printf("PPG, %d, %d, ", pxialg_data->touch_flag, data_num); for (i = 0; i < data_num; ++i) { log_printf("%d, ", *ppg_data); ppg_data++; } log_printf("\n"); log_printf("MEMS, %d, ", pxialg_data->nf_mems); for (i = 0; i < pxialg_data->nf_mems * 3; ++i) { log_printf("%d, ", *mems_data); mems_data++; } log_printf("\n"); } }