BroBot Code for ESE350 Lab6 part 3 (Skeleton)
Dependencies: MPU6050_V3 mbed-rtos mbed
Fork of BroBot_RTOS_ESE350 by
Revision 20:a7cba632d0b1, committed 2017-03-22
- Comitter:
- csharer
- Date:
- Wed Mar 22 21:59:10 2017 +0000
- Parent:
- 19:19d72dc64b43
- Commit message:
- Final Skeleton code for ESE350
Changed in this revision
main.cpp | Show annotated file Show diff for this revision Revisions of this file |
--- a/main.cpp Wed Mar 22 21:41:07 2017 +0000 +++ b/main.cpp Wed Mar 22 21:59:10 2017 +0000 @@ -200,6 +200,7 @@ float throttle = 0; float steering = 0; float control_output = 0; + float pos_control_output = 0; int robot_pos = 0; //int loop_counter = 0; int velocitySamplesCounter = 0; @@ -277,6 +278,13 @@ velocitySum = velocitySum - runningSumReplaceVal + newVelocity; velocity = velocitySum/VELOCITY_SAMPLES; + /*################################################################## + ########## ALL CODING FOR THIS LAB WILL BE COMPLETED BELOW ######### + ######### THERE ARE 2 PARTS, PART 1 MUST BE COMPLETED FIRST ######## + ####### IT IS NOT RECOMENDED TO MODIFY CODE OUTSIDE THIS LOOP ###### + ##################################################################*/ + + //PART 2 // ***************** Position Controller ********************* //Inputs: robot_position, target_pos //Error: distance from target position @@ -285,19 +293,22 @@ float Kp1P = Kp2/1000; float Kd1P = Kd2/100; - //Calculate the Position Error using robot_pos and target_pos - pos_error = robot_pos - target_pos; //robot_pos - target_pos; + //(2.0) Calculate the Position Error using robot_pos and target_pos + pos_error = 0; - //Calculate the Proportional Term (P Term) Using The Error - kp_pos_term = Kp1P * pos_error; + //(2.1) Calculate the Proportional Term (P Term) Using The Error + kp_pos_term = 0; - //Calculate the Derivative Term (D Term) Using The Error - change_in_target_pos = target_pos - target_pos_old; - kd_pos_term = ((Kd1P * change_in_target_pos) + (Kd1P*velocity)); - target_velocity = kp_pos_term + -kd_pos_term; - target_velocity = CAP(target_velocity, 100); - target_angle = -target_velocity; + //(2.2) Calculate the Derivative Term (D Term) Using The Error + change_in_target_pos = 0; + kd_pos_term = 0; //Use change_in_target_pos and velocity + pos_control_output = 0; //Add the two terms together (P + D) + pos_control_output = CAP(pos_control_output, 100); //Cap the values + + //This Control Output Will Feed Into The Stability Controller + target_angle = -pos_control_output; + //PART 1 (Do this before the Position Controller) //************ PD Stability CONTROLLER HERE **************** //Inputs: angle, target_angle //Error: distance from target_angle @@ -307,20 +318,19 @@ float Kp1S = Kp1/100; float Kd1S = Kd1*100; - //Calculate the Angle Error Using target_angle and angle - error = target_angle - angle; + //(1.0) Calculate the Angle Error Using target_angle and angle + error = 0; - //Calculate the Proportional Term (P term) Using the Error - kp_term = Kp1S * error; + //(1.1) Calculate the Proportional Term (P term) Using the Error + kp_term = 0; - //Calculate the Derivatve Term (D term) - change_in_target_angle = target_angle - target_angle_old; //add - change_in_angle = angle - angle_old2; //add - kd_term = ((Kd1S * change_in_target_angle) - (Kd1S*change_in_angle)) / dt; - //kd_term = ((Kd1 * change_in_target_angle) - (Kd1*velocity)); + //(1.2) Calculate the Derivatve Term (D term) + change_in_target_angle = 0; + change_in_angle = 0; //Look 2 samples back (use angle_old2) + kd_term = 0; - //Calculate the Control Output - control_output += kp_term + kd_term; //-100 to 100 + //(1.3) Calculate the Control Output + control_output += 0; //Add the P and D terms together here control_output = CAP(control_output, MAX_CONTROL_OUTPUT); // Limit max output from control //*************** Set Motor Speed *************************