Dependencies: mbed
main.cpp
- Committer:
- jsobiecki
- Date:
- 2019-03-28
- Revision:
- 5:1649f59c37de
- Parent:
- 4:5a892f5ab5a8
- Child:
- 6:2cd6ae395c0f
File content as of revision 5:1649f59c37de:
#include "mbed.h"
#include "Robot.h"
#include "math.h"
#include "ActiveCell.h"
#include "HistogramCell.h"
#define M_PI 3.14159265358979323846
//EXERCICIO 1
//Luis Cruz N2011164454
//Jacek Sobecki N2018319609
Serial pc(SERIAL_TX, SERIAL_RX, 115200);
DigitalIn button(PC_13);
void poseEst(float p[], float radius, float enc_res, float b);
void SpeedLim(float w[]);
void initializeArrays();
void calcForce();
void updateActive(double xR, double yR);
//int ReadSensors();
//const int m = 200, n = 200, activeSize = 11;
//histogram size
const int hSize = 60;
//active region size
const int aSize = 11;
ActiveCell activeReg[aSize][aSize];
HistogramCell histogram[hSize][hSize];
//Repulsive force sums
double fX, fY;
float p[3], p_obj[3];
int main(){
button.mode(PullUp);
getCountsAndReset();
setSpeeds(0, 0);
initializeArrays();
while(button==1);
//w[0] = Omega | w[1] = X | w[2] = Y
//p[0] = X | p[1] = Y | p[2] = Theta
//p_obj[0] = X | p_obj[1] = Y | p_obj[2] = Theta
//b = Distance between wheels, enc_res = Encoder Resolution, v = Calculated speed
//k_v = Speed gain, k_s = Curvature gain, wratio = Angular speed ratio control command
//Cells dim: 5x5cm |
float w[3], v, theta, theta_error, err, integral = 0.0;
const float radius = 3.5, b = 13.3, enc_res = 1440, k_v = 7,
k_s = 60, k_i = 1, sample_time = 0.05, Fcr = 1.0, d_stalker = 5.0;
// ===============================================================================
// =================================== COORDS ====================================
// ===============================================================================
//Target coordinates
p_obj[0] = 400, p_obj[1] = 400, p_obj[2] = 0;
//Initial coordinates:
p[0] = 100, p[1] = 100, p[2] = 0;
// ===============================================================================
// =================================== EXECUTION =================================
// ===============================================================================
while(1){
getCountsAndReset();
pc.printf("Speeds: Left=%lf Right=%lf\n", w[1], w[2]);
pc.printf("Odometer: X=%lf Y=%lf Theta=%lf\n", p[0], p[1], p[2]);
pc.printf("Position: X=%lf Y=%lf Theta=%lf\n", p[0], p[1], p[2]);
//Path calculation
poseEst(p, radius, enc_res, b); //Pose estimation
//Control Law
err = sqrt(pow((p_obj[0]-p[0]),2)+pow((p_obj[1]-p[1]),2)) - d_stalker; //distance to the point
theta = atan2(p_obj[1]-p[1],p_obj[0]-p[0]);
theta = atan2(sin(theta),cos(theta));
p[2] = atan2(sin(p[2]),cos(p[2]));
theta_error = theta-p[2];
w[0] = k_s*(theta_error); //direction gain
integral += err;
v = k_v*err+k_i*integral; //Speed gain
w[1] = (v-(b/2)*w[0])/radius;
w[2] = (v+(b/2)*w[0])/radius;
SpeedLim(w);
if((fabs(p[0]-p_obj[0])+fabs(p[1]-p_obj[1])) < 1){
setSpeeds(0,0);
}
else{
setSpeeds(w[1], w[2]);
}
wait(sample_time);
}
}
// ===============================================================================
// =================================== FUNCTIONS =================================
// ===============================================================================
//Pose Estimation function
void poseEst(float p[], float radius, float enc_res, float b){
float deltaDl, deltaDr, deltaD, deltaT;
deltaDl = ((float)countsLeft)*(2.0*M_PI*radius/enc_res);
deltaDr = ((float)countsRight)*(2.0*M_PI*radius/enc_res);
deltaD = (deltaDr + deltaDl)/2;
deltaT = (deltaDr - deltaDl)/b;
if(fabs(deltaT) == 0){
p[0] = p[0] + deltaD*cos(p[2]) + deltaT/2;
p[1] = p[1] + deltaD*sin(p[2]) + deltaT/2;
return;
}
p[0] = p[0] + deltaD*(sin(deltaT/2.0f)/(deltaT/2.0f))*cos(p[2]+deltaT/2.0f);
p[1] = p[1] + deltaD*(sin(deltaT/2.0f)/(deltaT/2.0f))*sin(p[2]+deltaT/2.0f);
p[2] = p[2] + deltaT;
}
//Speed limiter function
void SpeedLim(float w[]){
float wratio;
wratio = w[2]/w[1];
if(w[2] > 150 || w[1] > 150){
if(wratio < 1){
w[1] = 150;
w[2] = w[1]*wratio;
}
else if(wratio > 1){
w[2] = 150;
w[1] = w[2]/wratio;
}
else{
w[2] = 150;
w[1] = 150;
}
}
if(w[2] < 50 || w[1] < 50){
if(wratio < 1){
w[1] = 50;
w[2] = w[1]*wratio;
}
else if(wratio > 1){
w[2] = 50;
w[1] = w[2]/wratio;
}
else{
w[2] = 50;
w[1] = 50;
}
}
}
void initializeArrays() {
for (int i = 0; i < hSize; i++) {
for (int j = 0; j < hSize; j++) {
histogram[i][j].calculate(i, j);
}
}
for (int i = 0; i < aSize; i++) {
for (int j = 0; j < aSize; j++) {
activeReg[i][j].calDist(i, j);
}
}
}
void calcForce(){
for (int i = 0; i < aSize; i++) {
for (int j = 0; j < aSize; j++) {
activeReg[i][j].calForce();
}
}
activeReg[5][5].forceX=0;
activeReg[5][5].forceY=0;
}
//every time robot changes position we need to call this function to update active region and calculate forces
//xR, yR - robots position in coordinates system
void updateActive(double xR, double yR) {
int idXr = 0;
int idYr = 0;
for (int i = 0; i < hSize; i++) {
for (int j = 0; j < hSize; j++) {
if (xR > histogram[i][j].x - 2.5 && xR < histogram[i][j].x + 2.5 && yR > histogram[i][j].y - 2.5 &&
yR < histogram[i][j].y + 2.5) {
idXr = i;
idYr = j;
break;
}
}
}
int m = idXr - aSize / 2;
for (int k = 0; k < aSize; k++) {
int n = idYr - aSize / 2;
for (int l = 0; l < aSize; l++) {
if (m > 0 && n > 0 && m < hSize && n < hSize) {
activeReg[k][l].cellVal = histogram[m][n].cellVal;
}
n++;
}
m++;
}
calcForce();
}
void sumForces(){
//attractive force
int Fca=10;
double distance = sqrt(pow((double)abs(p_obj[0] - p[0]), 2) + pow((double)abs(p_obj[1] - p[1]), 2));
double aFx = Fca*(p_obj[0]-p[0])/distance;
double aFy = Fca*(p_obj[1]-p[1])/distance;
//repulsive force
double rFx=0;
double rFy=0;
for(int i=0;i<aSize;i++){
for(int j=0;j<aSize;j++){
rFx+=activeReg[i][j].forceX;
rFy+=activeReg[i][j].forceY;
}
}
//sum
fX=aFx-rFx;
fY=aFy-rFy;
}