E=MC
Code for the car to drive in a figure eight motion
Dependencies: mbed-rtos mbed MODSERIAL mbed-dsp telemetry
encoder.cpp
- Committer:
- cheryl_he
- Date:
- 2015-03-20
- Revision:
- 23:d8cacd996cce
- Parent:
- 13:97708869a4ba
File content as of revision 23:d8cacd996cce:
#include <encoder.h>
//Observed average speeds for each duty cycle
const float TUNING_CONSTANT_20 = 3.00;
const float TUNING_CONSTANT_30 = 4.30;
const float TUNING_CONSTANT_50 = 6.880;
const float PI = 3.14159;
const float WHEEL_CIRCUMFERENCE = .05*PI;
//Velocity Control Tuning Constants
const float TUNE_THRESH = 0.5f;
const float TUNE_AMT = 0.1f;
Encoder::Encoder(Timer t1){
//set timer
t = t1;
//Initialize Intervals used during encoder data collection to measure velocity
interval1=0;
interval2=0;
interval3=0;
avg_interval=0;
lastchange1 = 0;
lastchange2 = 0;
lastchange3 = 0;
lastchange4 = 0;
//Initialize Variables used to for velocity control
avg_speed = 0;
stall_check = 0;
tuning_val = 1;
// Servo parameters
lastTurnTime = 0.0f;
servoLeft = true;
//Parameters specifying sample sizes and delays for small and large average speed samples
num_samples_small = 10.0f;
delay_small = 0.05f;
num_samples_large = 100.0f;
delay_large = 0.1f;
}
float Encoder::get_speed(){
float revPerSec = (1.0f/((float)avg_interval*.000001))*.25f;
float linearSpeed = revPerSec * WHEEL_CIRCUMFERENCE;
return linearSpeed;
}
float Encoder::get_avg_speed(float num_samples, float delay) {
float avg_avg_speed = 0;
for (int c = 0; c < num_samples; c++) {
if (num_samples == num_samples_small){
small_avg_speed_list[c] = get_speed();
} else if (num_samples == num_samples_large){
large_avg_speed_list[c] = get_speed();
//pc.printf("\n\rworking: %f", large_avg_speed_list[c]);
}
wait(delay);
}
for (int c = 1; c < num_samples; c++) {
if (num_samples == num_samples_small){
avg_avg_speed += small_avg_speed_list[c];
} else if (num_samples == num_samples_large){
avg_avg_speed += large_avg_speed_list[c];
//pc.printf("\n\rworking: %f", large_avg_speed_list[c]);
}
}
return avg_avg_speed/num_samples;
}
float Encoder::velocity_control(float duty_cyc, float tuning_const) {
avg_speed = get_avg_speed(num_samples_small, delay_small);
if (avg_speed == stall_check) {
avg_speed = 0;
tuning_val += TUNE_AMT;
} else if((avg_speed - tuning_const) > TUNE_THRESH){
tuning_val -= TUNE_AMT;
stall_check = avg_speed;
} else if (avg_speed - tuning_const < -1*TUNE_THRESH){
tuning_val += TUNE_AMT;
stall_check = avg_speed;
} else {
tuning_val = 1;
stall_check = avg_speed;
}
return .0025 * duty_cyc * tuning_val;
}
void Encoder::fallInterrupt(){
int time = t.read_us();
interval1 = time - lastchange2;
interval2 = lastchange1-lastchange3;
interval3 = lastchange2 - lastchange4;
avg_interval = (interval1 + interval2 + interval3)/3;
lastchange4 = lastchange3;
lastchange3 = lastchange2;
lastchange2 = lastchange1;
lastchange1 = time;
//pc.printf("dark to light time : %d\n\r", interval);
//pc.printf("fall");
}
void Encoder::riseInterrupt(){
int time = t.read_us();
interval1 = time - lastchange2;
interval2 = lastchange1-lastchange3;
interval3 = lastchange2 - lastchange4;
avg_interval = (interval1 + interval2 + interval3)/3;
lastchange4 = lastchange3;
lastchange3 = lastchange2;
lastchange2 = lastchange1;
lastchange1 = time;
//pc.printf("light to dark time : %d\n\r", interval);
//pc.printf("rise");
}