GDP 4
car using PID from centre line
Dependencies: FRDM-TFC mbed CBuffer XBEE mbed_angular_speed motor2 MMA8451Q
Fork of
KL25Z_Camera_Test
by 
GDP 4
main.cpp
- Committer:
- lh14g13
- Date:
- 2017-01-12
- Revision:
- 33:0fc789c09694
- Parent:
- 32:6829684f8c4d
- Child:
- 36:7f482c048387
File content as of revision 33:0fc789c09694:
//Autonomous Car GDP controller
//Written by various group members
//Commented & cleaned up by Max/Adam
//To-do
// -Change xbee transmission to non-blocking
// -Improve start/stop detection and resultant action (setting PID values?)
#include <stdarg.h>
#include <stdio.h>
#include "mbed.h"
#include "TFC.h"
#include "XBEE.h"
#include "angular_speed.h"
#include "main.h"
#include "motor.h"
// Serial
#if USE_COMMS
Serial pc(PTD3,PTD2);
XBEE xb(&pc);
#endif
// PID Timer
Timer t;
//Speed Sensors interupts and timers
InterruptIn leftHallSensor(D0);
InterruptIn rightHallSensor(D2);
Timer t1;
Timer t2;
//testing timer for laptimes
Timer lapTimer;
int main() {
//Set up TFC driver stuff
TFC_Init();
ALIGN_SERVO;
#if USE_COMMS
//Setup baud rate for serial link, do not change!
pc.baud(BAUD_RATE);
#endif
//Initialise/reset PID variables
initVariables();
initSpeedSensors();
while(1) {
#if USE_COMMS
handleComms();
#endif
//If we have an image ready
if(TFC_LineScanImageReady>0) {
/* Find the bounds of the track and calculate how close we are to
* the centre */
servo_pid.measured_value = findCentreValue(CLOSE_CAMERA, left, right);
// Check if car is at the stop line
handleStartStop();
#if USE_COMMS
// Send the line scan image over serial
sendImage();
#endif
//Reset image ready flag
TFC_LineScanImageReady=0;
// Slow down, adjust PID values and enable differential before corners.
//handleCornering();
// Run the PID controllers and adjust steering/motor accordingly
PIDController();
#if USE_COMMS
// Send the wheel speeds over serial
sendSpeeds();
#endif
}
}
}
void initVariables() {
// Initialise three PID controllers for the servo and each wheel.
initPID(&servo_pid, 2.2f, 0.6f, 0.f);
initPID(&left_motor_pid, 0.01f, 0.f, 0.f);
initPID(&right_motor_pid, 0.01f, 0.f, 0.f);
right_motor_pid.desired_value=0;
left_motor_pid.desired_value=0;
// intialise the maximum speed interms of the angular speed.
valBufferIndex = 0;
speed = 50;
//Start stop
startstop = 0;
seen = false;
// Turning
turning = 0;
keepTurning = 0;
slow = false;
wL = 0;
wR = 0;
prevL = 0;
prevR = 0;
}
void initPID(pid_instance* pid, float Kp, float Ki, float Kd) {
pid->Kp = Kp;
pid->Ki = Ki;
pid->Kd = Kd;
pid->dt = 0;
pid->p_error = 0;
pid->pid_error = 0;
pid->integral = 0;
pid->measured_value = 0;
pid->desired_value = 0;
pid->derivative = 0;
}
bool leftSeen;
bool rightSeen;
//Function which calcuates how far to the left/right of the centre of the track the car is
//Takes data from either camera, and passes some variables by reference, which will hold
//the indices holding the locations of the left and right edges of the track
inline float findCentreValue(volatile uint16_t * cam_data, uint8_t &l, uint8_t &r) {
diff = 0; //Holds difference in intensity between consecutive pixels
prev = -1; //Holds index of last inspected pixel
//Used for crossroads navigation, holds info on which edges of the track are observed
leftSeen = false;
rightSeen = false;
//Starting in the middle index, step left, inspecting the the edge of the track
for(i = 63; i > 0; i--) {
curr_left = (uint8_t)(cam_data[i] >> 4) & 0xFF;
diff = prev - curr_left;
//Check incorporates a combination of looking at the difference in intensities
//and whether the pixels intensity is less than a threshold, corresponding to the black edge
if(abs(diff) >= CAM_DIFF && curr_left <= CAM_THRESHOLD && prev != -1) {
l = i; //Record the index where the edge is observed
leftSeen = true;
break;
}
prev = curr_left; //Update previous value for the loop
}
prev = -1;
//As before, start in the middle but this time step rightwards in the image
for(i = 64; i < 128; i++) {
curr_right = (uint8_t)(cam_data[i] >> 4) & 0xFF;
int diff = prev - curr_right;
if(abs(diff) >= CAM_DIFF && curr_right <= CAM_THRESHOLD && prev != -1) {
r = i;
rightSeen = true;
break;
}
prev = curr_right;
}
//If both edges are not visible, we are likely in a crossroads
if(!rightSeen && !leftSeen) {
sendString("lost edges");
ALIGN_SERVO; //Straighten wheels so we go straight through the crossroads
servo_pid.integral = 0;
}
//Calculate how left/right from the centre line we are
return (64 - ((l+r)/2))/64.f;
}
//Unused function currently
//Was used to establish whether we are in a corner, by inspecting a buffer of
//centre line values
inline void handleCornering() {
//Get current value of how left/right of centre line we are on the track
float lookaheadMeasuredValue = findCentreValue(LOOKAHEAD_CAMERA, farLeft, farRight);
measuredValBuffer[frame_counter % 64] = servo_pid.measured_value;
int count = 0;
for(i = 0; i < 10; i++) {
//Step through the buffer, using modulus operator
float val = abs(measuredValBuffer[(frame_counter - i) % 64]);
if(val > 0.09) { //If the value exceeds a certain value (obtained experimentally), we are in a corner
count++;
}
}
/*if(!turning && abs(lookaheadMeasuredValue) > 0.11f){
TFC_SetMotorPWM(0.4,0.4);
}
*/
if(false) {
//default
//TFC_SetMotorPWM(0.4,0.4);
//dutyCycleCorner(speed,servo_pid.output);
//dutyCycleCorner(float cornerspeed, servo_pid.output);
//dutyCycleCorner(speed, servo_pid.output);
// This activates the electronic differential so that it runs whilst cornering.
// this changes the desired desired speed of each of the wheels according to the angle of the servo.
sensorCorner(left_motor_pid.desired_value, right_motor_pid.desired_value , servo_pid.output, speed);
}
/*
if(abs(servo_pid.measured_value) > 0.11f){
if(!turning) {
turning = 1;
} else {
turning++;
}
} else {
if(turning) {
if(keepTurning == 0 || count > 6) {
keepTurning++;
} else {
//sendString("stop turning turned=%d",turning);
keepTurning = 0;
turning = 0;
left_motor_pid.desired_value=speed;
right_motot_pid.desired_value=speed;
TFC_SetMotorPWM(speed,speed);
}
}
}
*/
}
//Unused function currently
//Was used to estimate whether the stop marker was seen
inline float getLineEntropy() {
float entropy = 0;
float last = (int8_t)(CLOSE_CAMERA[0] >> 4) & 0xFF;
for(int i = 1; i < 128; i++) {
entropy += abs(last - ((int8_t)(CLOSE_CAMERA[i] >> 4) & 0xFF));
}
return entropy;
}
void handlePID(pid_instance *pid) {
pid->dt = t.read();
pid->pid_error = pid->desired_value - pid->measured_value;
pid->integral = pid->integral + pid->pid_error * pid->dt;
pid->derivative = (pid->pid_error - pid->p_error) / pid->dt;
pid->output = pid->Kp * pid->pid_error + pid->Ki * pid->integral + pid->Kd * pid->derivative;
pid->p_error = pid->pid_error;
if(pid->integral > 1.0f) {
pid->integral = 1.0f;
}
if(pid->integral < -1.0f ) {
pid->integral = -1.0f;
}
}
inline void PIDController() {
// update motor measurements
// Read the angular velocity of both wheels
prevL = wL;
prevR = wR;
wL=Get_Speed(Time_L);
wR=Get_Speed(Time_R);
// Check if left wheel is slipping/giving an abnormal reading and ignore reading
if(wL - prevL < 1.2/0.025) { //<3 magic numbers: 48....?
left_motor_pid.measured_value = wL;
}
if(wR - prevR < 1.2/0.025) {
right_motor_pid.measured_value = wR;
}
//PID Stuff!
t.start();
handlePID(&servo_pid);
handlePID(&left_motor_pid);
handlePID(&right_motor_pid);
if((-1.0 <= servo_pid.output) && (servo_pid.output <= 1.0))
{
TFC_SetServo(0, servo_pid.output);
}
else //Unhappy PID state
{
//sendString("out = %f p_err = %f", servo_pid.output, servo_pid.p_error);
//ALIGN_SERVO;
//Could cause the car to be travelling along one side of the track rather than in the middle
if(servo_pid.output >= 1.0f) {
TFC_SetServo(0, 0.9f);
servo_pid.output = 1.0f;
} else {
TFC_SetServo(0, -0.9f);
servo_pid.output = -1.0f;
}
}
if(left_motor_pid.output > 1.0f) {
left_motor_pid.output = 1.0f;
}
if(left_motor_pid.output < 0.0f) {
left_motor_pid.output = 0.0f;
}
if(right_motor_pid.output > 1.0f) {
right_motor_pid.output = 1.0f;
}
if(right_motor_pid.output < 0.0f) {
right_motor_pid.output = 0.0f;
}
TFC_SetMotorPWM(left_motor_pid.output,right_motor_pid.output);
t.stop();
t.reset();
t.start();
}
inline void handleStartStop() {
//Function to detect the NXP cup stop marker
int slower = 0; //Only send a string every few frames
int difference = 0; //Holds the difference between intensities of consecutive pixels
int lastPixel, currentPixel, transitionsSeen;
lastPixel = -1;
transitionsSeen = 0;
//Starting near the left edge, step right, counting transitions.
//If there are several (exact value varies, best established experimentally), it is the marker
for(int i = 30; i < 98; i++) {
currentPixel = (int)(CLOSE_CAMERA[i] >> 4) & 0xFF;
difference = lastPixel - currentPixel;
if(abs(difference) > 10 && lastPixel != -1){ //transition seen, increment counter
transitionsSeen++;
i+=5;
}
lastPixel = currentPixel;
}
//Was used to send an indication that the marker was seen, useful for debugging
//if (slower % 1000 == 0) {
//sendString("Transitions seen: %d", transitionsSeen);
//}
//slower++;
if(transitionsSeen >= 5) {
//Stop the car!
sendString("Start/stop seen");
TFC_SetMotorPWM(0.f,0.f);
TFC_HBRIDGE_DISABLE;
lapTime();
}
}
inline void initSpeedSensors() {
t1.start();
t2.start();
//Left and Right are defined looking at the rear of the car, in the direction the camera points at.
leftHallSensor.rise(&GetTime_L);
rightHallSensor.rise(&GetTime_R);
}
void GetTime_L(){
Time_L=t1.read_us();
t1.reset();
}
void GetTime_R(){
Time_R=t2.read_us();
t2.reset();
}
#if USE_COMMS
void sendBattery() {
if(frame_counter % 256 == 0) {
float level = TFC_ReadBatteryVoltage() * 6.25;
pc.putc('J');
byte_float_union._float = level;
pc.putc(byte_float_union.bytes[0]);
pc.putc(byte_float_union.bytes[1]);
pc.putc(byte_float_union.bytes[2]);
pc.putc(byte_float_union.bytes[3]);
}
}
void sendString(const char *format, ...) {
va_list arg;
pc.putc('E');
va_start (arg, format);
pc.vprintf(format,arg);
va_end (arg);
pc.putc(0);
}
inline void sendImage() {
//Only send 1/3 of camera frames to GUI program
if((frame_counter % 3) == 0) {
pc.putc('H');
if(sendCam == 0) {
for(i = 0; i < 128; i++) {
pc.putc((int8_t)(CLOSE_CAMERA[i] >> 4) & 0xFF);
}
} else {
for(i = 0; i < 128; i++) {
pc.putc((int8_t)(LOOKAHEAD_CAMERA[i] >> 4) & 0xFF);
}
}
sendBattery();
}
frame_counter++;
}
inline void sendSpeeds() {
/*float en = getLineEntropy();
if(onTrack) {
if(en <= 14000) {
onTrack = false;
sendString("offfffffffffffff");
TFC_SetMotorPWM(0.0,0.0);
TFC_HBRIDGE_DISABLE;
}
} else {
if(en > 14000) {
onTrack = true;
sendString("ON TRACK");
}
}*/
pc.putc('B');
byte_float_union._float = wL * WHEEL_RADIUS;//left_motor_pid.output; //
pc.putc(byte_float_union.bytes[0]);
pc.putc(byte_float_union.bytes[1]);
pc.putc(byte_float_union.bytes[2]);
pc.putc(byte_float_union.bytes[3]);
byte_float_union._float = wR * WHEEL_RADIUS; // right_motor_pid.output; //
pc.putc(byte_float_union.bytes[0]);
pc.putc(byte_float_union.bytes[1]);
pc.putc(byte_float_union.bytes[2]);
pc.putc(byte_float_union.bytes[3]);
}
inline void handleComms() {
if(curr_cmd != 0) {
switch(curr_cmd) {
case 'A':
if(xb.cBuffer->available() >= 12) {
byte_float_union.bytes[0] = xb.cBuffer->read();
byte_float_union.bytes[1] = xb.cBuffer->read();
byte_float_union.bytes[2] = xb.cBuffer->read();
byte_float_union.bytes[3] = xb.cBuffer->read();
servo_pid.Kp = byte_float_union._float;
byte_float_union.bytes[0] = xb.cBuffer->read();
byte_float_union.bytes[1] = xb.cBuffer->read();
byte_float_union.bytes[2] = xb.cBuffer->read();
byte_float_union.bytes[3] = xb.cBuffer->read();
servo_pid.Ki = byte_float_union._float;
byte_float_union.bytes[0] = xb.cBuffer->read();
byte_float_union.bytes[1] = xb.cBuffer->read();
byte_float_union.bytes[2] = xb.cBuffer->read();
byte_float_union.bytes[3] = xb.cBuffer->read();
servo_pid.Kd = byte_float_union._float;
sendString("pid= Kp: %f, Ki: %f, Kd: %f", servo_pid.Kp, servo_pid.Ki, servo_pid.Kd);
curr_cmd = 0;
}
break;
case 'F':
if(xb.cBuffer->available() >= 1) {
char a = xb.cBuffer->read();
speed = a;
sendString("s = %u %f",a, speed);
curr_cmd = 0;
right_motor_pid.desired_value=speed;
left_motor_pid.desired_value=speed;
}
break;
default:
// Unrecognised command
curr_cmd = 0;
break;
}
}
if(xb.cBuffer->available() > 0 && curr_cmd == 0) {
//Start car
char cmd = xb.cBuffer->read();
if(cmd == 'D') {
ALIGN_SERVO;
right_motor_pid.desired_value=speed;
left_motor_pid.desired_value=speed;
TFC_HBRIDGE_ENABLE;
servo_pid.integral = 0;
lapTimer.start();
lapNo =0;
} else if (cmd == 'C') {
TFC_SetMotorPWM(0.0,0.0);
right_motor_pid.desired_value=0;
right_motor_pid.measured_value = 0;
wR = 0;
prevR = 0;
left_motor_pid.desired_value=0;
left_motor_pid.measured_value = 0;
wL = 0;
prevL = 0;
TFC_HBRIDGE_DISABLE;
endTest();
} else if(cmd == 'A') {
curr_cmd = 'A';
} else if(cmd == 'F') {
curr_cmd = 'F';
} else if(cmd == 'K') {
sendCam = ~sendCam;
}
}
}
float testSpeed(float speed)
{
// search: Speed Increase
// every time the car sees the stop start the speed of the car will increase
// this can occur on stop start trigger.
// may need to send the speed back to the telemetry.
if (speed>0.4)
{
speed+=0.05;
}
else
{
speed+=0.1;
}
sendString("s = %f", speed);
return speed;
}
int lapTime()
{
// function which sends the lap time back to the telemetry.
//reads the timer
float newTime= lapTimer.read();
lapNo += 1;
float lapTime= newTime-oldTime;
float avgTime= newTime/lapNo;
// this calulates the average lap time and the lap time.
//then sends the information back to the UI.
sendString("For lap number: %d Lap Time: %f Avergae time: %f \n\r", lapNo,lapTime,avgTime);
return 0;
}
void endTest()
{// This runs when the car has stopped, this should give the final elapsed time and othere things. this also stops the timer
float time= lapTimer.read();
sendString("Laps done: %d Time elapsed: %f Average time: %f \n\r",lapNo, time,float (time/lapNo));
lapTimer.stop();
}
//motor controll specific(newfunction)
#endif