ECE 4781 Project

Dependencies:   LSM9DS0 SDFileSystem mbed

main.cpp

Committer:
mburtt3
Date:
2015-11-15
Revision:
0:ea323e2fa56c

File content as of revision 0:ea323e2fa56c:

// skeleton code for ECE 2036 thermostat lab
// code must be added by students
#include "mbed.h"
//#include "TMP36.h"
#include "SDFileSystem.h"
//#include "TextLCD.h"
//#include "PinDetect.h"
//#include "Speaker.h"
// must add your new class code to the project file Shiftbrite.h
//#include "Shiftbrite.h"
#include "LSM9DS0.h"
#include <cmath>

// use class to setup temperature sensor pins
//TMP36 myTMP36(p15);  //Analog in

// use class to setup microSD card filesystem
SDFileSystem sd(p5, p6, p7, p8, "sd");

// use class to setup the LCD
//TextLCD myLCD(p22, p23, p24, p25, p26, p27); // rs, e, d4-d7

// use class to setup Mbed's four on-board LEDs
DigitalOut myLED1(LED1);
DigitalOut myLED2(LED2);
DigitalOut myLED3(LED3);
DigitalOut myLED4(LED4);

//also setting any unused analog input pins to digital outputs reduces A/D noise a bit
//see http://mbed.org/users/chris/notebook/Getting-best-ADC-performance/
DigitalOut P16(p16);
DigitalOut P17(p17);
DigitalOut P18(p18);
DigitalOut P19(p19);
DigitalOut P20(p20);

//Copied straight from the SDFileSystem_HelloWorld Code
int main() {
    printf("Hello World!\n");   
 
    mkdir("/sd/mydir", 0777);
    
    FILE *fp = fopen("/sd/mydir/sdtest.txt", "w");
    if(fp == NULL) {
        error("Could not open file for write\n");
    }
    fprintf(fp, "Hello fun SD Card TEST1");
    fclose(fp); 
 
    printf("Goodbye World!\n");
}

// This code is for the IMU and is taken straight from https://developer.mbed.org/users/randrews33/notebook/lsm9ds0-inertial-measurement-unit/
// For testing purposes
// SDO_XM and SDO_G are both grounded, so our addresses are:
#define LSM9DS0_XM  0x1E // Would be 0x1E if SDO_XM is LOW
#define LSM9DS0_G   0x6A // Would be 0x6A if SDO_G is LOW
 
// Create an instance of the LSM9DS0 library called `dof` the
// parameters for this constructor are:
// pins,[gyro I2C address],[xm I2C add.]
LSM9DS0 dof(p28, p27, LSM9DS0_G, LSM9DS0_XM);
DigitalIn DReady(p23);
 
Serial pc(USBTX, USBRX); // tx, rx
 
bool printMag = true;
bool printAccel = true;
bool printGyro = true;
 
void setup()
{
    pc.baud(115200); // Start serial at 115200 bps
    // Use the begin() function to initialize the LSM9DS0 library.
    // You can either call it with no parameters (the easy way):
    uint16_t status = dof.begin();
    
    // Or call it with declarations for sensor scales and data rates:
    //uint16_t status = dof.begin(dof.G_SCALE_2000DPS,
    //                            dof.A_SCALE_6G, dof.M_SCALE_2GS);
    
    // begin() returns a 16-bit value which includes both the gyro
    // and accelerometers WHO_AM_I response. You can check this to
    // make sure communication was successful.
    pc.printf("LSM9DS0 WHO_AM_I's returned: 0x");
    pc.printf("%x\n",status);
    pc.printf("Should be 0x49D4\n");
    pc.printf("\n");
}
 
void printGyro() {
    dof.readGyro();
    
    pc.printf("G: ");
    
    pc.printf("%2f",dof.calcGyro(dof.gx));
    pc.printf(", ");
    pc.printf("%2f",dof.calcGyro(dof.gy));
    pc.printf(", ");
    pc.printf("%2f\n",dof.calcGyro(dof.gz));
}
 
void printAccel() {
    dof.readAccel();
    
    pc.printf("A: ");
    
    pc.printf("%2f",dof.calcAccel(dof.ax));
    pc.printf(", ");
    pc.printf("%2f",dof.calcAccel(dof.ay));
    pc.printf(", ");
    pc.printf("%2f\n",dof.calcAccel(dof.az));
    
}
 
void printMag() {
    dof.readMag();
    
    pc.printf("M: ");
    
    pc.printf("%2f",dof.calcMag(dof.mx));
    pc.printf(", ");
    pc.printf("%2f",dof.calcMag(dof.my));
    pc.printf(", ");
    pc.printf("%2f\n",dof.calcMag(dof.mz));
}
 
// Here's a fun function to calculate your heading, using Earth's
// magnetic field.
// It only works if the sensor is flat (z-axis normal to Earth).
// Additionally, you may need to add or subtract a declination
// angle to get the heading normalized to your location.
// See: http://www.ngdc.noaa.gov/geomag/declination.shtml
void printHeading(float hx, float hy)
{
    float heading;
    
    if (hy > 0) heading = 90 - (atan(hx / hy) * (180 / 3.14));
    else if (hy < 0) heading = - (atan(hx / hy) * (180 / 3.14));
    else // hy = 0
    {
        if (hx < 0) heading = 180;
        else heading = 0;
    }
    
    pc.printf("Heading: ");
    pc.printf("%2f\n",heading);
}
 
// Another fun function that does calculations based on the
// acclerometer data. This function will print your LSM9DS0's
// orientation -- it's roll and pitch angles.
void printOrientation(float x, float y, float z)
{
    float pitch, roll;
    
    pitch = atan2(x, sqrt(y * y) + (z * z));
    roll = atan2(y, sqrt(x * x) + (z * z));
    pitch *= 180.0 / 3.14;
    roll *= 180.0 / 3.14;
    
    pc.printf("Pitch, Roll: ");
    pc.printf("%2f",pitch);
    pc.printf(", ");
    pc.printf("%2f\n",roll);
}
 
void readData() {
    // To read from the device, you must first call the
    // readMag(), readAccel(), and readGyro() functions.
    // When this exits, it'll update the appropriate
    // variables ([mx, my, mz], [ax, ay, az], [gx, gy, gz])
    // with the most current data.
 
    dof.readMag();
    dof.readAccel();
    dof.readGyro();
}
 
void loop() {
    // Loop until the Data Ready signal goes high
    while (!Dready) {}
    
    readData();
    
    if (printGyro) printGyro();  // Print "G: gx, gy, gz"
    if (printAccel) printAccel(); // Print "A: ax, ay, az"
    if (printMag) printMag();   // Print "M: mx, my, mz"
    
    // Print the heading and orientation for fun!
    printHeading((float) dof.mx, (float) dof.my);
    printOrientation(dof.calcAccel(dof.ax), dof.calcAccel(dof.ay),
                     dof.calcAccel(dof.az));
    pc.printf("\n");
    
    wait(2);
}
 
 
int main()
{
    setup();
    while (true)
    {
      loop();
    }
}