ec
Fork of EC by
SpeedController.cpp
- Committer:
- jack0325suzu
- Date:
- 2017-04-10
- Revision:
- 14:28b6628fe90f
- Parent:
- 13:caa6db604077
File content as of revision 14:28b6628fe90f:
#include "mbed.h" #include "EC.h" /***EC classの方を先に読んでおくこと***/ SpeedControl::SpeedControl(PinName signalA , PinName signalB , PinName signalZ , int s , double t , PinName pwm_F , PinName pwm_B) : Ec(signalA,signalB,signalZ,s,t) , pwm_F_(pwm_F),pwm_B_(pwm_B) { Kv_p=0;Kv_d=0;Kv_i=0;diff=0;diff_old=0;integral=0;now_time_=0;old_time_=0; out_duty=0;out=0;duty=0; pwm_F_.period_us(100); pwm_B_.period_us(100); C=45.0; } void SpeedControl::Sc(double target_omega){ //スカンジウムじゃないよ now_omega=omega; now_time_=timer.read(); diff= target_omega-now_omega; integral+=diff; out_duty=Kv_p*diff+Kv_d*(diff-diff_old)/(now_time_-old_time_)+Kv_i*integral*(now_time_-old_time_); diff_old=diff; if(out_duty>0.1)out_duty=0.1; if(out_duty<-0.1)out_duty=-0.1; out+=out_duty; duty=0.0001*out+target_omega/C; if(duty<-0.95)duty=-0.95; else if(duty>0.95)duty=0.95; old_time_=now_time_; if(duty>=0){ pwm_F_=duty; pwm_B_=0; } else { pwm_F_=0; pwm_B_=-duty; } } void SpeedControl::turnF(double duty){ if(duty>0.95) { pwm_F_=0.95; pwm_B_=0; duty=0.95; } else { pwm_F_=duty; pwm_B_=0; } } void SpeedControl::turnB(double duty){ if(duty>0.95) { pwm_F_=0; pwm_B_=0.95; } else { pwm_F_=0; pwm_B_=duty; } } void SpeedControl::Accelarate(double target_duty){ double now_speed,old_speed; double duty; int start_point; int max_point=int(target_duty/0.05); int now_point=int((double)pwm_F_/0.05); if(now_point<3) start_point=3; else start_point=now_point; if(max_point>19) max_point=19; else if(max_point<0) max_point=0; if(max_point>now_point){ for(int i=start_point;i<=max_point;i++){ duty=(double)i*5.0/100.0; printf("duty = %f RPM = %f\r\n",(double)i*5.0/100.0,getRPM()); turnF(duty); int count=0; while(1){ old_speed=now_speed; wait(0.01); now_speed=getRPM(); if(now_speed<old_speed) { if(count>1) break; else count++; } } } } else if(max_point<now_point){ for(int i=now_point;i>=max_point;i--){ duty=(double)i*5.0/100.0; printf("duty = %f RPM = %f\r\n",(double)i*5.0/100.0,getRPM()); turnF(duty); int count=0; while(1){ old_speed=now_speed; wait(0.01); now_speed=getRPM(); if(now_speed>old_speed) { if(count>1) break; else count++; } } } } } void SpeedControl::ScZ(double target_RPM){ now_RPM=getRPM(); //if(fabs(now_RPM-target_RPM)>300) Accelarate(target_RPM/C); diff=target_RPM-now_RPM; integral+=diff; out_duty=0.01*(Kv_p*diff+Kv_d*(diff-diff_old)+Kv_i*integral); diff_old=diff; if(out_duty>0.01)out_duty=0.01; if(out_duty<-0.01)out_duty=-0.01; out+=out_duty; duty=0.0001*out/*+target_RPM/C*/; turnF(duty); } void SpeedControl::ScZ2(double target_RPM){ now_time_=timer.read(); now_RPM=getRPM(); diff=target_RPM-now_RPM; integral+=diff; out_duty=(now_time_-old_time_)*Kv_p*diff+Kv_d*(diff-diff_old)/(now_time_-old_time_)+Kv_i*integral; old_time_=now_time_; diff_old=diff; if(out_duty>0.001)out_duty=0.001; if(out_duty<-0.001)out_duty=-0.001; out+=out_duty; duty=0.001*out; turnF(duty); } void SpeedControl::setPIDparam(double p,double i,double d){ Kv_p=p; Kv_d=d; Kv_i=i; } void SpeedControl::setDOconstant(double c){ C=c; } void SpeedControl::reset(){ S=0;stateA=0;stateB=0;count=0;pre_count=0.0,omega=0; rev=0;now_time=0;old_time=0;RPM=0;RPM_old=0; diff=0;diff_old=0;integral=0;now_time_=0;old_time_=0; out=0;out_duty=0; } void SpeedControl::stop(){ pwm_F_=0; pwm_B_=0; }