Chris Elsholz
/
Quadrocopter
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Fork of
Quadrocopter
by 
Marco Friedmann
main.cpp
- Committer:
- chriselsholz
- Date:
- 2017-09-14
- Revision:
- 23:c99a4bd60609
- Parent:
- 21:f09823a13ac6
- Child:
- 24:aaa5b4703555
File content as of revision 23:c99a4bd60609:
#include <Timer.h>
#include <math.h>
#include "mbed.h"
#include "stdio.h"
#include "deklaration.h"
#include "messen.h"
#include "filter/Kalman.h"
#define RAD 57.29577951
double dt;
uint32_t zeit2;
uint8_t k;
int main()
{
gain_g = 0;
z_off = 0;
dt = 0;
k = 0;
drift_z = 0;
Motor1.period_ms(2);
Motor2.period_ms(2);
Motor3.period_ms(2);
Motor4.period_ms(2);
initialisierung_gyro();
initialisierung_acc();
Kalman(&Q_angle, &Q_bias, &R_measure, &bias, P);
if (taster1)
{
uint16_t flanke1,hilfe1=0,flanke2,hilfe2=0,flanke3,hilfe3=0,flanke4,hilfe4=0;
pc.printf("Taster-Modus aktiv\n\r");
n1=n2=n3=n4=625;
while(1)
{
flanke2 = taster2;
if ((flanke2 != 0) && (hilfe2 == 0))
{
n1+=50;
n2+=50;
n3+=50;
n4+=50;
}
hilfe2=flanke2;
flanke3 = taster3;
if ((flanke3 != 0) && (hilfe3 == 0))
{
n1-=50;
n2-=50;
n3-=50;
n4-=50;
}
hilfe3=flanke3;
flanke4 = taster4;
if ((flanke4 != 0) && (hilfe4 == 0))
{
n1=n2=n3=n4=625;
}
hilfe4=flanke4;
Motor1.pulsewidth_us(n1);
Motor2.pulsewidth_us(n2);
Motor3.pulsewidth_us(n3);
Motor4.pulsewidth_us(n4);
pc.printf("Drehzahl= %d\r= %d",n1);
}
}
if (taster2)
{
viberationen(&rauschen, &Motor1, &Motor2, &Motor3, &Motor4, &taster4);
}
if (taster3)
{
anlernen(&Motor1, &Motor2, &Motor3, &Motor4, &taster1, &taster2, &taster4);
}
pc.printf("Druecke Taster1 fuer den Start\n\r");
n1=n2=n3=n4=700;
Motor1.pulsewidth_us(n1);
Motor2.pulsewidth_us(n2);
Motor3.pulsewidth_us(n3);
Motor4.pulsewidth_us(n4);
while(1)
{
if (taster1)
{
while(1)//(!taster4)
{
pc.printf("\n\rOffset und Driftberechnung wird durchgefuehrt, halte die Drohne still");
offset_gyro(&z_off, &x_off, &y_off);
drift_gyro(&drift_z, &drift_x, &drift_y, &timer, &timer2, &gain_g, &roll_g, &pitch_g, &z_off, &x_off, &y_off);
pc.printf("\n\rOffgesamt:\n\rZ = %3.5f\tY = %3.5f\tZ = %3.5f\t\n\r", z_off, x_off, y_off);
pc.printf("\n\rDrift:Z: %3.10f\tX: %3.10f\tY: %3.10f\n\r", drift_z, drift_x, drift_y);
/********//******/
/*Messen*//*Gyro*/
/********//******/
timer.stop();
timer2.stop();
timer.reset();
timer2.reset();
gain_g = 0;
pitch_g = 0;
roll_g = 0;
timer.start();
timer2.start();
int i = 0;
while(1)
{
i++;
dt = timer.read_us()*0.000001;
timer.reset();
aktuell_roh(&z_g, &x_g, &y_g, &z_a, &x_a, &y_a);
gain_g = ((z_g - z_off) * 1/16.4);
pitch_g = ((y_g - y_off) * 1/16.4);
roll_g = ((x_g - x_off) * 1/16.4);
y = y_a / 16384.00;
x = x_a / 16384.00;
z = z_a / 16384.00;
roll_a = atan2(y, sqrt(x * x + z * z)) * RAD;
pitch_a = atan2(-x, z) * RAD;
newAngle = roll_a;
newRate = roll_g;
if (timer2.read_ms() >= 2000)
{
gain_g -= drift_z;
pitch_g -= drift_y;
roll_g -= drift_x;
timer2.reset();
}
//gain = gain_g;
//pitch = pitch_g * 0.9 + pitch_a * 0.1;
roll = getAngle(&newAngle, &newRate, &dt, &Q_angle, &Q_bias, &R_measure, &bias);
if (i == 2000)
{
pc.printf("gain: %2.5f\tpitch: %2.5f\troll: %2.5f\t\n\r",roll);
i = 0;
}
n1=n2=n3=n4=800;
Motor1.pulsewidth_us(n1);
Motor2.pulsewidth_us(n2);
Motor3.pulsewidth_us(n3);
Motor4.pulsewidth_us(n4);
if(taster4){
n1=n2=n3=n4=700;
Motor1.pulsewidth_us(n1);
Motor2.pulsewidth_us(n2);
Motor3.pulsewidth_us(n3);
Motor4.pulsewidth_us(n4); while(1);}
}
}
}
}
}