FORARKADI
Dependencies: mbed mypidror1 Motor Map
recive.cpp
- Committer:
- noamnahum
- Date:
- 2020-03-06
- Revision:
- 4:d40399d8ae44
- Parent:
- 3:94eac3bdfbf5
- Child:
- 5:8ef69c6f3718
File content as of revision 4:d40399d8ae44:
//////////////////////////////////////// // Controlling Thorttle // // // //////////////////////////////////////// /* Pingout: Nucleo-L432KC PA_0 ---> Analogin ---> Read Potentiometer 1 PA_1 ---> Analogin ---> Read Potentiometer 2 PA_3 ----> DigitalOut ---> to Led MOSFET LED1 ----> DigitalOut ----> Error Indication CANBUS: PA_11 ---> CANBUS TX PA_12 ----> CANBUS RX Motor: PA_8 (D9) --- PWMOUT PA_5 ---> Digitalout ---> Motor FWD direction PA_6 ---> Digitalout ---> Motor RWD direction */ /////////////// // Libraries // /////////////// #include "PID.h" #include "Motor.h" #include <Map.hpp> #include "mbed.h" /////////////// // #defines // /////////////// ///////////// // Objects // ///////////// //thorttle potentiometer AnalogIn analog_value1(PA_0); AnalogIn analog_value2(PA_1); int pid_event = 0; //led indicator DigitalOut myled(LED1); // brake signalout DigitalOut mybrake(PA_3); // can bus CAN can1(PA_11, PA_12); //Motor Control Motor myMotor(PA_8, PA_5, PA_6); //Brake signal //Serial Serial pc(USBTX,USBRX); //Timer Timer t; Timer can; Timer tpid; /////////////// // variables // /////////////// int startup = 0; int counter = 0; int errorcounter = 0; int recievecounter = 0; // PID // pid output limits const float output_lower_limit = -255; const float output_upper_limit = 255; //pid constants const float kp = 1.5; const float ki = 2; const float kd = 0; //Time sample const float Ts = 0.001; //Tickers Ticker main_ticker; Ticker motor; Ticker syserror; //Flags for indication if something happend - error handling int pidflag = 0; int canflag = 0; int cantimeoutflag = 0; // if can message is not recived more then 100ms int rsflag = 0; int terrorflag = 0; int perrorflag = 0; //Thorttle and pedal intital values float thorttle1, thorttle2, sumThorttle, subThorttle; float mdagree, pdagree = 0; float mythorttle,sumthorttle = 0; //Motor speed pwm -1<speed<1 float speed = 0; // Define PID object // PID pid(&pdagree, &mdagree, &speed, output_lower_limit, output_upper_limit,kp, ki, kd, Ts); ////////////////// //define Mapping// ////////////////// Map mapvaltovolt = Map(0, 1, 0, 3300); // Maping Volt value from 0-1 to 0-3300 Map mtodagree = Map(230, 3070, 0, 255); // Maping Volt value from 490-3150 to 0 - 255 Map nspeed = Map(-255, 255, -1, 1); // Maping out put speed from -255-255 to -1-1 //////////////////// //define functions/// //////////////////// // After pid calculate and Sensor data recieve this function command the output to the motor void BrakeOn() { mybrake = 1; } void BrakeOff() { mybrake = 0; } void commandMotor(){ float Motorcommand = nspeed.Calculate(speed); myMotor.speed(Motorcommand); } // if there is Error this function Turn the Motor speed to 0 // Close the Thorttle and then The engine is off void sendError() { if (errorcounter == 1){ main_ticker.detach(); pid.stop(); syserror.attach(sendError, 0.0005); } myMotor.speed(0); } /*while (1) { BrakeOn(); //pc.printf("Error is: %.4f\n\r", 1); wait(1); BrakeOff(); wait(1); } }*/ // get Data overcanbus void getData() { //pc.printf("%d", 1); CANMessage msg; if(can1.read(msg)) { recievecounter ++; //pc.printf("Pedal sensor worng values\n"); //pc.printf("my data: %d", msg.data[2]); if (can.read() > 0) { can.stop(); can.reset(); } if (msg.data[2]==1){ errorcounter = 1; perrorflag = 1; sendError(); } if (msg.data[2]==0){ perrorflag = 0; } if (msg.data[3]==1){ BrakeOn(); } if (msg.data[3]==0){ BrakeOff(); } pdagree = msg.data[0]; } if (!can1.read(msg)) { can.start(); } if (can.read() > 0.1) { // if message not recieved more then 0.1 sec send error can.stop(); //can.reset(); errorcounter = 1; cantimeoutflag = 1; sendError(); } } //reading Thorttle sensors void readSensors() { thorttle1 = analog_value1.read(); // Converts and read the analog input value (value from 0.0 to 1.0) thorttle2 = analog_value2.read(); // Converts and read the analog input value (value from 0.0 to 1.0) thorttle1 = mapvaltovolt.Calculate(thorttle1); thorttle2 = mapvaltovolt.Calculate(thorttle2); sumThorttle = thorttle1+thorttle2; subThorttle = abs(3300-sumThorttle); getData(); pid.sample(); commandMotor(); //pc.printf("matzeret1 is: %.4f, matzeret2 is:%.4f\n\r", thorttle1, thorttle2); //pc.printf("Subthorttle is: %.4f\n\r", subThorttle); if (subThorttle<330) { //checking error mythorttle = mtodagree.Calculate(thorttle1); sumthorttle = sumthorttle + mythorttle; counter++; if (t.read()>0) { errorcounter = 0; t.stop(); t.reset(); } if (counter == 10) { mdagree = sumthorttle/10; counter = 0; sumthorttle = 0; } } if (subThorttle>330) { if (errorcounter == 0) { t.start(); errorcounter = 1; } if (t.read() > 0.1) { t.stop(); t.reset(); terrorflag = 1; errorcounter = 1; sendError(); } } } int main() { pc.baud(9600); pid.start(); main_ticker.attach(readSensors, 0.0005); while(1){ pc.printf("Pedal: %.4f\n\n\r, Thorttle: %.4f\n\n\r, subthorttle: %.4f\n\n\r, recievecounter: %d\n\n\r, ThorttleErrorFlag: %d\n\n\r, PedalErrorFlag: %d\n\n\r, CanTimeoutFlag: %d\n\n\r", pdagree, mdagree, subThorttle, recievecounter, terrorflag, perrorflag, cantimeoutflag); } }