Astrid Schut
/
EMG_myo
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Dependencies: MovingAverage mbed HIDScope biquadFilter
main.cpp
- Committer:
- aschut
- Date:
- 2019-03-28
- Revision:
- 23:f01a1bd3b3c4
- Parent:
- 22:2405d2be193d
- Child:
- 24:0db52d2e1d2a
File content as of revision 23:f01a1bd3b3c4:
#include "mbed.h"
#include "HIDScope.h"
#include "BiQuad.h"
#include "BiQuadchains_zelfbeun.h"
DigitalOut led1(LED_GREEN);
DigitalOut led2(LED_RED);
DigitalOut led3(LED_BLUE);
//EMG tickers, these tickers are called in the mainscript with fsample 500Hz, also sends to HIDscope with same fsample
Ticker sample_ticker; //ticker for filtering pref. with 1000Hz, define in tick.attach
Ticker threshold_check_ticker;
Timer t; //timer try out for Astrid
Timer timer_calibration; //timer for EMG calibration
//Input
AnalogIn emg1( A1 );
AnalogIn emg2( A2 );
AnalogIn emg3( A3 );
AnalogIn emg4( A4 );
// GLOBALS EMG
//Filtered EMG signals from the end of the chains
volatile double emg1_filtered, emg2_filtered, emg3_filtered, emg4_filtered;
int i = 0;
//Define doubles for calibration and ticker
double ts = 0.001; //tijdsstap
double calibration_time = 55; //time EMG calibration should take
volatile double temp_highest_emg1 = 0; //highest detected value right biceps
volatile double temp_highest_emg2 = 0;
volatile double temp_highest_emg3 = 0;
volatile double temp_highest_emg4 = 0;
//Doubles for calculation threshold
double biceps_p_t = 0.4; //set threshold at percentage of highest value
double triceps_p_t = 0.5; //set threshold at percentage of highest value
volatile double threshold1;
volatile double threshold2;
volatile double threshold3;
volatile double threshold4;
// thresholdreads bools
int bicepsR;
int tricepsR;
int bicepsL;
int tricepsL;
// EMG OUTPUT
int EMGxplus;
int EMGxmin ;
int EMGyplus;
int EMGymin ;
// ~~~~~~~~~~~~~~~~~~~EMG FUNCTIONS~~~~~~~~~~~~~~~~~~
void emgsample()
{
//All EMG signal through Highpass
double emgread1 = emg1.read();
double emgread2 = emg2.read();
double emgread3 = emg3.read();
double emgread4 = emg4.read();
double emg1_highpassed = highp1.step(emgread1);
double emg2_highpassed = highp2.step(emgread2);
double emg3_highpassed = highp3.step(emgread3);
double emg4_highpassed = highp4.step(emgread4);
//All EMG highpassed through Notch
double emg1_notched = notch1.step(emg1_highpassed);
double emg2_notched = notch2.step(emg2_highpassed);
double emg3_notched = notch3.step(emg3_highpassed);
double emg4_notched = notch4.step(emg4_highpassed);
//All EMG notched rectify
double emg1_abs = abs(emg1_notched);
double emg2_abs = abs(emg2_notched);
double emg3_abs = abs(emg3_notched);
double emg4_abs = abs(emg4_notched);
//All EMG abs into lowpass
emg1_filtered = lowp1.step(emg1_abs);
emg2_filtered = lowp2.step(emg2_abs);
emg3_filtered = lowp3.step(emg3_abs);
emg4_filtered = lowp4.step(emg4_abs);
}
void CalibrationEMG()
{
//static float samples = calibration_time/ts;
while(timer_calibration<55) {
if(timer_calibration>0 && timer_calibration<10) {
led1=!led1;
if(emg1_filtered>temp_highest_emg1) {
temp_highest_emg1= emg1_filtered;
//pc.printf("Temp1 = %f \r\n",temp_highest_emg1);
}
}
if(timer_calibration>10 && timer_calibration<15) {
led1=0;
led2=0;
led3=0;
}
if(timer_calibration>15 && timer_calibration<25) {
led2=!led2;
if(emg2_filtered>temp_highest_emg2) {
temp_highest_emg2= emg2_filtered;
//pc.printf("Temp2 = %f \r\n",temp_highest_emg2);
}
}
if(timer_calibration>25 && timer_calibration<30) {
led1=0;
led2=0;
led3=0;
}
if(timer_calibration>30 && timer_calibration<40) {
led3=!led3;
if(emg3_filtered>temp_highest_emg3) {
temp_highest_emg3= emg3_filtered;
//pc.printf("Temp3 = %f \r\n",temp_highest_emg3);
}
}
if(timer_calibration>40 && timer_calibration<45) {
led1=0;
led2=0;
led3=0;
}
if(timer_calibration>45 && timer_calibration<55) {
led2=!led2;
led3=!led3;
if(emg4_filtered>temp_highest_emg4) {
temp_highest_emg4= emg4_filtered;
//pc.printf("Temp4 = %f \r\n",temp_highest_emg4);
}
}
led1=1;
led2=1;
led3=1;
}
//pc.printf("Highest value right biceps= %f \r\n", temp_highest_emg1);
//pc.printf("Highest value right triceps= %f \r\n", temp_highest_emg2);
//pc.printf("Highest value left biceps= %f \r\n", temp_highest_emg3);
//pc.printf("Highest value left triceps= %f \r\n", temp_highest_emg4);
threshold1 = temp_highest_emg1*biceps_p_t; //Right Biceps
threshold2 = temp_highest_emg2*triceps_p_t; //Right Triceps
threshold3 = temp_highest_emg3*biceps_p_t; //Left Biceps
threshold4 = temp_highest_emg4*triceps_p_t; //Left Triceps
}
//Check if emg_filtered has reached their threshold
void threshold_check()
{
//EMG1 threshold check
if(emg1_filtered>threshold1) {
bicepsR = 1;
} else {
bicepsR= 0;
}
//EMG2 threshold check
if(emg2_filtered>threshold2) {
tricepsR = 1;
} else {
tricepsR= 0;
}
//EMG3 threshold check
if(emg3_filtered>threshold3) {
bicepsL = 1;
} else {
bicepsL= 0;
}
//EMG4 threshold check
if(emg4_filtered>threshold4) {
tricepsL = 1;
} else {
tricepsL= 0;
}
/*
pc.printf("Biceps Right = %i", bicepsR);
pc.printf("Triceps Right = %i",tricepsR);
pc.printf("Biceps Left = %i", bicepsL);
pc.printf("Triceps Left = %i", tricepsL);
*/
}
Ticker sample_timer;
HIDScope scope( 4 );
DigitalOut led(LED1);
void sample()
{
scope.set(0, emg1.read() );
scope.set(1, emg2.read() );
scope.set(2, bicepsR );
scope.set(3, tricepsR);
scope.send();
led = !led;
}
int main()
{
sample_timer.attach(&sample, 0.002);
temp_highest_emg1 = 0; //highest detected value right biceps
temp_highest_emg2 = 0;
temp_highest_emg3 = 0;
temp_highest_emg4 = 0;
timer_calibration.reset();
timer_calibration.start();
sample_ticker.attach(&emgsample, ts);
CalibrationEMG();
sample_ticker.detach();
timer_calibration.stop();
threshold_check_ticker.attach(threshold_check, ts)
/*empty loop, sample() is executed periodically*/
while(1) {}
}