春ロボ ロケット団
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Spring_motor_test2
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Dependencies: mbed SpeedController Encoder CruizCore_R1370P
main.cpp
- Committer:
- maxnagazumi
- Date:
- 2020-03-05
- Revision:
- 18:1d89ec4148ec
- Parent:
- 17:bafc6a46b3df
- Child:
- 19:0c1c3b2e009f
File content as of revision 18:1d89ec4148ec:
#include "mbed.h"
#include "EC.h"
#include "SpeedController.h"
#define RESOLUTION 500
#include "math.h"
#include "R1370P.h"
//PwmOut motor_1F(PA_5);//1Forward Right motor Forward
//PwmOut motor_1B(PC_7);//Forward Right motor Back
//PwmOut motor_2F(PC_9);//2Forward Left motor Forward
//PwmOut motor_2B(PA_1);//Forward Left motor Back
//PwmOut motor_3F(PA_10);//3Back Right motor Forward
//PwmOut motor_3B(PB_4);//Back Right motor Back
//PwmOut motor_4F(PA_9);//4Back Left motor Forward
//PwmOut motor_4B(PA_7);//Back Left motor Back
Ec2multi ec[]= {Ec2multi(PC_5,PB_2,RESOLUTION),
Ec2multi(PA_11,PB_1,RESOLUTION),
Ec2multi(PB_12,PB_15,RESOLUTION),
Ec2multi(PC_4,PB_14,RESOLUTION)
}; //1逓倍用class
Ec2multi ecXY[]= {Ec2multi(PC_6,PB_8,RESOLUTION),
Ec2multi(PC_8,PB_9,RESOLUTION)
};
SpeedControl motor[]= {SpeedControl(PA_5,PC_7,50,ec[0]),
SpeedControl(PC_9,PA_1,50,ec[1]),
SpeedControl(PA_10,PB_4,50,ec[2]),
SpeedControl(PA_9,PA_7,50,ec[3])
};
//R1370P gyro(PA_11,PA_12);
DigitalIn button(USER_BUTTON);
Serial pc(USBTX, USBRX); // tx, rx
R1370P gyro(PC_10,PC_11); // tx, rx
Ticker ticker;
void calOmega()
{
for(int i=0; i<4; i++) {
ec[i].calOmega();
}
}
//自己位置取得
double theta=0;
class Location
{
public:
Location():x_(0),y_(0)
{
for(int i =0; i<2; i++) {
old_count[i]=0;
}
}
void calXY()
{
double ec_count[2]= {};
double ax,ay,bx,by;
double atheta,btheta;
atheta = (45+theta)/180*3.14;
btheta = (135+theta)/180*3.14;
ec_count[0]=ecXY[0].getCount();
ec_count[1]=ecXY[1].getCount();
ax = (ec_count[0]-old_count[0])*cos(atheta);
ay = (ec_count[0]-old_count[0])*sin(atheta);
bx = (ec_count[1]-old_count[1])*cos(btheta);
by = (ec_count[1]-old_count[1])*sin(btheta);
x_=x_+ax + bx;
y_=y_+ay + by;
old_count[0]=ec_count[0];
old_count[1]=ec_count[1];
}
double getX()
{
return x_;
}
double getY()
{
return y_;
}
private:
double x_;
double y_;
double old_count[2];
};
//目的地決定
int plot[5][2]= {
{0,0}
,{0,10000}
,{5000,10000}
,{5000,0}
,{2000,5000}
};
//出力を計算
int x,y;
class WheelOmega
{
public:
WheelOmega(): max_(0),vx_(0),vy_(0),theta_(0)
{
for(int i=0; i<4; i++) {
omega[i]=0;
}
}
void setOmega(int max)
{
if(max >= 0) {
max_=max;
} else {
max_ = -1 * max;
}
}
void setVxy(double vx,double vy,double theta)
{
vx_=vx;
vy_=vy;
theta_=theta;
}
void calOmega()
{
omega[0]=max_*vx_/sqrt(2.0)-max_*vy_/sqrt(2.0)-theta*max_*0.005;
omega[1]=-max_*vx_/sqrt(2.0)-max_*vy_/sqrt(2.0)-theta*max_*0.005;
omega[2]=-max_*vx_/sqrt(2.0)+max_*vy_/sqrt(2.0)-theta*max_*0.005;
omega[3]=max_*vx_/sqrt(2.0)+max_*vy_/sqrt(2.0)-theta*max_*0.005;
};
double getOmega(int i)
{
return omega[i];
}
private:
double max_,vx_,vy_,theta_;
double omega[4];
};
WheelOmega omega;
//パラメタ処理
double pControl(int dx_,int dy_,double time_)
{
double distance,z,zMax;
distance = sqrt((double)dx_*dx_+dy_*dy_);
z=0.004*distance;
zMax=10;
if(z>zMax) {
z=zMax;
}
if(time_<1) {
z=z*time_;
}
return z;
}
//出力
int a=0;
void motorOut()
{
for(int i=0; i<4; i++) {
motor[i].Sc(omega.getOmega(i));
}
}
int main()
{
gyro.initialize(); //main関数の最初に一度だけ実行
gyro.acc_offset();
double angle;
angle=gyro.getAngle();
double z;
printf("start\r\n");
motor[0].setEquation(0.008031,-0.022300,-0.008839,-0.016290);
motor[1].setEquation(0.008878,-0.016622,-0.009702,-0.015806);
motor[2].setEquation(0.008637,-0.016537,-0.009397,-0.012159);
motor[3].setEquation(0.008096,-0.014822,-0.008801,-0.016645);
motor[0].setDutyLimit(0.5);
motor[1].setDutyLimit(0.5);
motor[2].setDutyLimit(0.5);
motor[3].setDutyLimit(0.5);
motor[0].setPDparam( 0.02000, 0.0005 );
motor[1].setPDparam( 0.02000, 0.0005 );
motor[2].setPDparam( 0.02000, 0.0005 );
motor[3].setPDparam( 0.02000, 0.0005);
while(1) {
printf("waiting\r\n");
if(button==0) {
wait(1);
ticker.attach(motorOut,0.05);
break;
}
}
int n=1,dx,dy,aimX,aimY;
double vx,vy;
Location location;
Timer time;
time.start();
while(1) {
//自己位置取得
theta=gyro.getAngle()-angle; //角度の値を受け取る
location.calXY();
x=location.getX();
y=location.getY();
printf("X=%d,Y=%d theta=%5.3f z=%5.3f %f \r\n",x,y,theta,z,time.read());
//目的地決定(syuusoku check)
aimX = plot[n][0];
aimY = plot[n][1];
//出力を計算(kitai xy);
dx=aimX-x;
dy=aimY-y;
vx=dx/sqrt((double)dx*dx+dy*dy);
vy=dy/sqrt((double)dx*dx+dy*dy);
//四輪の出力計算
z=pControl(dx,dy,time.read());
omega.setOmega(z);
omega.setVxy(vx,vy,theta);
omega.calOmega();
//ゴール判定
if(dx<500 && dx>-500 && dy<500 && dy>-500) {
n++;
printf("reach%d\r\n",n);
ticker.detach();
/*for(int j=0; j<4; j++) {
motor[j].stop();
}
wait(1);*/
time.reset();
ticker.attach(motorOut,0.05);
}
if(n>=5) {
for(int j=0; j<4; j++) {
motor[j].Sc(0);
}
while(1) {
printf("fin");
ticker.detach();
}
}
}
}