ENSMM
Test program for a Max30102 heartrate sensor on a STM32L476RG specific board ENSMM
Dependencies: mbed
These two pictures show how to connect the Mheuve Sensor to the ST-Link debugger (don't forget to disable ST-link jumpers and JP5 on the board! ):
These two pictures show how to connect the Mheuve Sensor TX RX to the ST-Link debugger (don't forget to cross TX and RX, it means Mheuve sensor TX on ST-Link RX and ST-Link TX on Mheuve sensor RX ):
The Mheuve sensor board needs to be powered by an external battery.
The result appears on the terminal, speed config is 115200 bds.
algorithm/algorithm.cpp
- Committer:
- MaximGordon
- Date:
- 2016-04-21
- Revision:
- 2:560e76e77544
- Parent:
- 1:e88f22c6c1b0
- Child:
- 3:7c0fb55eb3ff
File content as of revision 2:560e76e77544:
/** \file algorithm.cpp ******************************************************
*
* Project: MAXREFDES117#
* Filename: algorithm.cpp
* Description: This module calculates the heart rate/SpO2 level
*
* Revision History:
*\n 1-18-2016 Rev 01.00 SK Initial release.
*\n
*
* --------------------------------------------------------------------
*
* This code follows the following naming conventions:
*
*\n char ch_pmod_value
*\n char (array) s_pmod_s_string[16]
*\n float f_pmod_value
*\n int32_t n_pmod_value
*\n int32_t (array) an_pmod_value[16]
*\n int16_t w_pmod_value
*\n int16_t (array) aw_pmod_value[16]
*\n uint16_t uw_pmod_value
*\n uint16_t (array) auw_pmod_value[16]
*\n uint8_t uch_pmod_value
*\n uint8_t (array) auch_pmod_buffer[16]
*\n uint32_t un_pmod_value
*\n int32_t * pn_pmod_value
*
* ------------------------------------------------------------------------- */
/*******************************************************************************
* Copyright (C) 2015 Maxim Integrated Products, Inc., All Rights Reserved.
*
* 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 MAXIM INTEGRATED 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.
*
* Except as contained in this notice, the name of Maxim Integrated
* Products, Inc. shall not be used except as stated in the Maxim Integrated
* Products, Inc. Branding Policy.
*
* The mere transfer of this software does not imply any licenses
* of trade secrets, proprietary technology, copyrights, patents,
* trademarks, maskwork rights, or any other form of intellectual
* property whatsoever. Maxim Integrated Products, Inc. retains all
* ownership rights.
*******************************************************************************
*/
#include "algorithm.h"
#include "mbed.h"
void maxim_heart_rate_and_oxygen_saturation(uint32_t *un_ir_buffer , int32_t n_ir_buffer_length, uint32_t *un_red_buffer , int32_t *n_spo2, int8_t *ch_spo2_valid ,
int32_t *n_heart_rate , int8_t *ch_hr_valid)
/**
* \brief Calculate the heart rate and SpO2 level
* \par Details
* By detecting peaks of PPG cycle and corresponding AC/DC of red/infra-red signal, the ratio for the SPO2 is computed.
* Since this algorithm is aiming for Arm M0/M3. formaula for SPO2 did not achieve the accuracy due to register overflow.
* Thus, accurate SPO2 is precalculated and save longo uch_spo2_table[] per each ratio.
*
* \param[in] *un_ir_buffer - IR sensor data buffer
* \param[in] n_ir_buffer_length - IR sensor data buffer length
* \param[in] *un_red_buffer - Red sensor data buffer
* \param[out] *n_spo2 - Calculated SpO2 value
* \param[out] *ch_spo2_valid - 1 if the calculated SpO2 value is valid
* \param[out] *n_heart_rate - Calculated heart rate value
* \param[out] *ch_hr_valid - 1 if the calculated heart rate value is valid
*
* \retval None
*/
{
uint32_t un_ir_mean ,un_only_once ;
int32_t k ,n_i_ratio_count;
int32_t i,s ,m, n_exact_ir_valley_locs_count ,n_middle_idx;
int32_t n_th1, n_npks,n_c_min;
int32_t n_ir_valley_locs[15] ;
int32_t n_exact_ir_valley_locs[15] ;
int32_t n_dx_peak_locs[15] ;
int32_t n_peak_interval_sum;
int32_t n_y_ac, n_x_ac;
int32_t n_spo2_calc;
int32_t n_y_dc_max, n_x_dc_max;
int32_t n_y_dc_max_idx, n_x_dc_max_idx;
int32_t n_ratio[5],n_ratio_average;
int32_t n_nume, n_denom ;
// remove DC of ir signal
un_ir_mean =0;
for (k=0 ; k<n_ir_buffer_length ; k++ ) un_ir_mean += un_ir_buffer[k] ;
un_ir_mean =un_ir_mean/n_ir_buffer_length ;
for (k=0 ; k<n_ir_buffer_length ; k++ ) n_x[k] = un_ir_buffer[k] - un_ir_mean ;
// 4 pt Moving Average
for(k=0; k< BUFFER_SIZE-MA4_SIZE; k++){
n_denom= ( n_x[k]+n_x[k+1]+ n_x[k+2]+ n_x[k+3]);
n_x[k]= n_denom/(int32_t)4;
}
// get difference of smoothed IR signal
for( k=0; k<BUFFER_SIZE-MA4_SIZE-1; k++)
n_dx[k]= (n_x[k+1]- n_x[k]);
// 2-pt Moving Average to n_dx
for(k=0; k< BUFFER_SIZE-MA4_SIZE-2; k++){
n_dx[k] = ( n_dx[k]+n_dx[k+1])/2 ;
}
// hamming window
// flip wave form so that we can detect valley with peak detector
for ( i=0 ; i<BUFFER_SIZE-HAMMING_SIZE-MA4_SIZE-2 ;i++){
s= 0;
for( k=i; k<i+ HAMMING_SIZE ;k++){
s -= n_dx[k] *uw_hamm[k-i] ;
}
n_dx[i]= s/ (int32_t)1146; // divide by sum of uw_hamm
}
n_th1=0; // threshold calculation
for ( k=0 ; k<BUFFER_SIZE-HAMMING_SIZE ;k++){
n_th1 += ((n_dx[k]>0)? n_dx[k] : ((int32_t)0-n_dx[k])) ;
}
n_th1= n_th1/ ( BUFFER_SIZE-HAMMING_SIZE);
// peak location is acutally index for sharpest location of raw signal since we flipped the signal
maxim_find_peaks( n_dx_peak_locs, &n_npks, n_dx, BUFFER_SIZE-HAMMING_SIZE, n_th1, 8, 5 );//peak_height, peak_distance, max_num_peaks
n_peak_interval_sum =0;
if (n_npks>=2){
for (k=1; k<n_npks; k++)
n_peak_interval_sum += (n_dx_peak_locs[k] -n_dx_peak_locs[k -1] ) ;
n_peak_interval_sum =n_peak_interval_sum/(n_npks-1);
*n_heart_rate =(int32_t)( 6000/ n_peak_interval_sum );// beats per minutes
//prlongf(">>> *n_heart_rate= %d \n", *n_heart_rate) ;
*ch_hr_valid = 1;
}
else {
*n_heart_rate = -999;
*ch_hr_valid = 0;
}
for ( k=0 ; k<n_npks ;k++)
n_ir_valley_locs[k]= n_dx_peak_locs[k] +HAMMING_SIZE /2;
// raw value : RED(=y) and IR(=X)
// we need to assess DC and AC value of ir and red PPG.
for (k=0 ; k<n_ir_buffer_length ; k++ ) {
n_x[k] = un_ir_buffer[k] ;
n_y[k] = un_red_buffer[k] ;
}
// find precise min near n_ir_valley_locs
n_exact_ir_valley_locs_count =0;
for ( k=0 ; k<n_npks ;k++){
un_only_once =1;
m=n_ir_valley_locs[k];
n_c_min= 16777216;//2^24;
if (m+5 < BUFFER_SIZE-HAMMING_SIZE && m-5 >0){
for(i= m-5;i<m+5; i++)
if (n_x[i]<n_c_min){
if (un_only_once >0){
un_only_once =0;
}
n_c_min= n_x[i] ;
n_exact_ir_valley_locs[k]=i;
}
if (un_only_once ==0) n_exact_ir_valley_locs_count ++ ;
}
}
if (n_exact_ir_valley_locs_count <2 ){
*n_spo2 = -999 ; // do not use SPO2 since signal ratio is out of range
*ch_spo2_valid = 0;
return;
}
// 4 pt MA
for(k=0; k< BUFFER_SIZE-MA4_SIZE; k++){
n_x[k]=( n_x[k]+n_x[k+1]+ n_x[k+2]+ n_x[k+3])/(int32_t)4;
n_y[k]=( n_y[k]+n_y[k+1]+ n_y[k+2]+ n_y[k+3])/(int32_t)4;
}
//using n_exact_ir_valley_locs , find ir-red DC andir-red AC for SPO2 calibration ratio
//finding AC/DC maximum of raw ir * red between two valley locations
n_ratio_average =0;
n_i_ratio_count = 0;
for(k=0; k< 5; k++) n_ratio[k]=0;
for (k=0; k< n_exact_ir_valley_locs_count; k++){
if (n_exact_ir_valley_locs[k] > BUFFER_SIZE ){
*n_spo2 = -999 ; // do not use SPO2 since valley loc is out of range
*ch_spo2_valid = 0;
return;
}
}
// find max between two valley locations
// and use ratio betwen AC compoent of Ir & Red and DC compoent of Ir & Red for SPO2
for (k=0; k< n_exact_ir_valley_locs_count-1; k++){
n_y_dc_max= -16777216 ;
n_x_dc_max= - 16777216;
// printf("range=%d: %d\n ", n_exact_ir_valley_locs[k], n_exact_ir_valley_locs[k+1]);
if (n_exact_ir_valley_locs[k+1]-n_exact_ir_valley_locs[k] >10){
for (i=n_exact_ir_valley_locs[k]; i< n_exact_ir_valley_locs[k+1]; i++){
if (n_x[i]> n_x_dc_max) {n_x_dc_max =n_x[i];n_x_dc_max_idx =i; }
if (n_y[i]> n_y_dc_max) {n_y_dc_max =n_y[i];n_y_dc_max_idx=i;}
}
n_y_ac= (n_y[n_exact_ir_valley_locs[k+1]] - n_y[n_exact_ir_valley_locs[k] ] )*(n_y_dc_max_idx -n_exact_ir_valley_locs[k]); //red
n_y_ac= n_y[n_exact_ir_valley_locs[k]] + n_y_ac/ (n_exact_ir_valley_locs[k+1] - n_exact_ir_valley_locs[k]) ;
n_y_ac= n_y[n_y_dc_max_idx] - n_y_ac; // subracting linear DC compoenents from raw
n_x_ac= (n_x[n_exact_ir_valley_locs[k+1]] - n_x[n_exact_ir_valley_locs[k] ] )*(n_x_dc_max_idx -n_exact_ir_valley_locs[k]); // ir
n_x_ac= n_x[n_exact_ir_valley_locs[k]] + n_x_ac/ (n_exact_ir_valley_locs[k+1] - n_exact_ir_valley_locs[k]);
n_x_ac= n_x[n_y_dc_max_idx] - n_x_ac; // subracting linear DC compoenents from raw
n_nume=( n_y_ac *n_x_dc_max)>>7 ; //prepare X100 to preserve floating value
n_denom= ( n_x_ac *n_y_dc_max)>>7;
if (n_denom>0 && n_i_ratio_count <5 && n_nume != 0)
{
n_ratio[n_i_ratio_count]= (n_nume*100)/n_denom ; //formular is ( n_y_ac *n_x_dc_max) / ( n_x_ac *n_y_dc_max) ;
n_i_ratio_count++;
}
}
// prlongf("n_ratio[%d]= %d n_exact_ir_valley_locs[k] =%d , n_exact_ir_valley_locs[%d] =%d \n",k, n_ratio[k] ,n_exact_ir_valley_locs[k] ,k+1, n_exact_ir_valley_locs[k+1] ) ;
// prlongf("n_nume= %d ,n_denom= %d n_y_ac = %d, n_x_dc_max = %d, n_x_ac= %d, n_y_dc_max = %d\n",n_nume, n_denom, n_y_ac ,n_x_dc_max ,n_x_ac ,n_y_dc_max );
}
maxim_sort_ascend(n_ratio, n_i_ratio_count);
n_middle_idx= n_i_ratio_count/2;
if (n_middle_idx >1)
n_ratio_average =( n_ratio[n_middle_idx-1] +n_ratio[n_middle_idx])/2; // use median
else
n_ratio_average = n_ratio[n_middle_idx ];
if( n_ratio_average>2 && n_ratio_average <184){
n_spo2_calc= uch_spo2_table[n_ratio_average] ;
*n_spo2 = n_spo2_calc ;
*ch_spo2_valid = 1;// float_SPO2 = -45.060*n_ratio_average* n_ratio_average/10000 + 30.354 *n_ratio_average/100 + 94.845 ; // for comparison with table
}
else{
*n_spo2 = -999 ; // do not use SPO2 since signal ratio is out of range
*ch_spo2_valid = 0;
}
}
void maxim_find_peaks( int32_t *n_locs, int32_t *n_npks, int32_t *n_x, int32_t n_size, int32_t n_min_height, int32_t n_min_distance, int32_t n_max_num )
/**
* \brief Find peaks
* \par Details
* Find at most MAX_NUM peaks above MIN_HEIGHT separated by at least MIN_DISTANCE
*
* \retval None
*/
{
maxim_peaks_above_min_height( n_locs, n_npks, n_x, n_size, n_min_height );
maxim_remove_close_peaks( n_locs, n_npks, n_x, n_min_distance );
*n_npks = min( *n_npks, n_max_num );
}
void maxim_peaks_above_min_height( int32_t *n_locs, int32_t *n_npks, int32_t *n_x, int32_t n_size, int32_t n_min_height )
/**
* \brief Find peaks above n_min_height
* \par Details
* Find all peaks above MIN_HEIGHT
*
* \retval None
*/
{
int32_t i = 1, n_width;
*n_npks = 0;
while (i < n_size-1){
if (n_x[i] > n_min_height && n_x[i] > n_x[i-1]){ // find left edge of potential peaks
n_width = 1;
while (i+n_width < n_size && n_x[i] == n_x[i+n_width]) // find flat peaks
n_width++;
if (n_x[i] > n_x[i+n_width] && (*n_npks) < 15 ){ // find right edge of peaks
n_locs[(*n_npks)++] = i;
// for flat peaks, peak location is left edge
i += n_width+1;
}
else
i += n_width;
}
else
i++;
}
}
void maxim_remove_close_peaks( int32_t *n_locs, int32_t *n_npks, int32_t *n_x, int32_t n_min_distance )
/**
* \brief Remove peaks
* \par Details
* Remove peaks separated by less than MIN_DISTANCE
*
* \retval None
*/
{
int32_t i, j, n_old_npks, n_dist;
/* Order peaks from large to small */
maxim_sort_indices_descend( n_x, n_locs, *n_npks );
for ( i = -1; i < *n_npks; i++ ){
n_old_npks = *n_npks;
*n_npks = i+1;
for ( j = i+1; j < n_old_npks; j++ ){
n_dist = n_locs[j] - ( i == -1 ? -1 : n_locs[i] ); // lag-zero peak of autocorr is at index -1
if ( n_dist > n_min_distance || n_dist < -n_min_distance )
n_locs[(*n_npks)++] = n_locs[j];
}
}
// Resort indices longo ascending order
maxim_sort_ascend( n_locs, *n_npks );
}
void maxim_sort_ascend(int32_t *n_x, int32_t n_size)
/**
* \brief Sort array
* \par Details
* Sort array in ascending order (insertion sort algorithm)
*
* \retval None
*/
{
int32_t i, j, n_temp;
for (i = 1; i < n_size; i++) {
n_temp = n_x[i];
for (j = i; j > 0 && n_temp < n_x[j-1]; j--)
n_x[j] = n_x[j-1];
n_x[j] = n_temp;
}
}
void maxim_sort_indices_descend( int32_t *n_x, int32_t *n_indx, int32_t n_size)
/**
* \brief Sort indices
* \par Details
* Sort indices according to descending order (insertion sort algorithm)
*
* \retval None
*/
{
int32_t i, j, n_temp;
for (i = 1; i < n_size; i++) {
n_temp = n_indx[i];
for (j = i; j > 0 && n_x[n_temp] > n_x[n_indx[j-1]]; j--)
n_indx[j] = n_indx[j-1];
n_indx[j] = n_temp;
}
}