Momo Medical / Momo_Pilot_1

Pilot 1 working code (excluding new patient after calculation). %d changed in %f sensordata serial log.

Dependencies:   ADS1015 MPU6050 PixelArray mbed

Fork of Momo_New by Momo Medical

Sensorplate/main.cpp

Committer:
DEldering
Date:
2017-09-14
Revision:
6:9c1944f3ebe5
Parent:
5:fa879b059fd1
Child:
7:dba5091c8b7d

File content as of revision 6:9c1944f3ebe5:

#include "mbed.h"
#include "Adafruit_ADS1015.h"
#include "USBSerial.h"
#include "MPU6050.h"

I2C i2c(p28, p27);                  // I2C
MPU6050 agu(p28,p27);               // Accelerometer/Gyroscope Unit
Adafruit_ADS1115 pr1(&i2c, 0x48);   // first PiëzoResistive ADC
Adafruit_ADS1115 pr2(&i2c, 0x49);   // second PiëzoResistive ADC
Adafruit_ADS1115 pel(&i2c, 0x4B);   // PiëzoElectric ADC
Serial pc(USBTX, USBRX); // tx, rx  // Serial USB connection
Timer t;                            // Timer for equally time-spaced samples
Ticker sample_cycle;                // Polling cycle
int cycle_time = 100000;            // Cycle time in us
int i2c_freq = 400000;              // I2C Frequency
int usb_baud = 115200;              // USB Baud rate
short res[8] = {0,0,0,0,0,0,0,0};   // 8 PR sensors 1 time per cycle
short elec[5] = {0,0,0,0,0};        // 1 PE sensor 5 times per cycle
int angle = 0;                      // Accelerometer Z-axis
int k = 0;
float acce[3];                      // Raw accelerometer data
float gyro[3];                      // Raw gyroscope data

void read_adc()
{
    t.reset();
    t.start();

    elec[0] = pel.readADC_SingleEnded(0);       //First PE readout

    for (k = 0; k < 4; k = k + 1) {
        res[k] =    pr1.readADC_SingleEnded(k); //First 4 PR readout
    }
    while(t.read_us()<(1*(cycle_time/5))) {}    //Wait untill 20% of cycle

    elec[1] = pel.readADC_SingleEnded(0);       //Second PE readout

    for (k = 0; k < 4; k = k + 1) {
        res[k+4] =  pr2.readADC_SingleEnded(k); //Last 4 PR readout
    }
    while(t.read_us()<(2*(cycle_time/5))) {}    //Wait untill 40% of cycle 

    elec[2] = pel.readADC_SingleEnded(0);       //Third PE readout

    agu.getAccelero(acce);                      //Get accelerometer data
    angle = acce[2]*10;
    
    while(t.read_us()<(3*(cycle_time/5))) {}    //Wait untill 60% of cycle

    elec[3] = pel.readADC_SingleEnded(0);       //Fourth PE readout

    agu.getGyro(gyro);                          //Get gyroscope data
    
    while(t.read_us()<(4*(cycle_time/5))) {}    //Wait untill 80% of cycle

    elec[4] = pel.readADC_SingleEnded(0);       //Fifth PE readout

    while(t.read_us()<(4.5*(cycle_time/5))) {}  //Wait untill 90% of cycle
    pc.printf(",%d,%d,%d,%d,%d,%d,%d,%d,%d,%d,%d,%d,%d,%d,%d,%d,%d,%d,%d,\r\n", res[4], res[7], res[6], res[5], res[1], res[0], res[2], res[3], elec[0], elec[1], elec[2], elec[3], elec[4], acce[0]*100, acce[1]*100, acce[2]*100, gyro[0]*100, gyro[1]*100, gyro[2]*100); // print all to serial port
    //receiving order: 8 resistive sensors, 5 electric readings, 3 accelerometer axes, 3 gyroscope axes
}

int main()
{
    i2c.frequency(i2c_freq);
    pc.baud(usb_baud);
    pr1.setGain(GAIN_TWOTHIRDS); // set range to +/-6.144V
    pr2.setGain(GAIN_TWOTHIRDS); // set range to +/-6.144V
    pel.setGain(GAIN_TWOTHIRDS); // set range to +/-6.144V
    sample_cycle.attach_us(&read_adc, cycle_time);
    while (1) {
        wait_us(cycle_time+1); // wait indefinitely because the ticker restarts every 50 ms
    }
}