package org.usfirst.frc.team3501.robot.subsystems;
import org.usfirst.frc.team3501.robot.Constants;
-import org.usfirst.frc.team3501.robot.MathLib;
import org.usfirst.frc.team3501.robot.commands.driving.JoystickDrive;
-import org.usfirst.frc.team3501.robot.sensors.GyroLib;
-import org.usfirst.frc.team3501.robot.sensors.Lidar;
import edu.wpi.first.wpilibj.CANTalon;
import edu.wpi.first.wpilibj.CounterBase.EncodingType;
import edu.wpi.first.wpilibj.DoubleSolenoid;
import edu.wpi.first.wpilibj.DoubleSolenoid.Value;
import edu.wpi.first.wpilibj.Encoder;
-import edu.wpi.first.wpilibj.I2C;
import edu.wpi.first.wpilibj.RobotDrive;
import edu.wpi.first.wpilibj.command.PIDSubsystem;
public class DriveTrain extends PIDSubsystem {
- // Current Drive Mode Default Drive Mode is Manual
- private int DRIVE_MODE = 1;
+ // Determines if the "front" of the robot has been reversed
+ private boolean outputFlipped = false;
+
private static double pidOutput = 0;
private Encoder leftEncoder, rightEncoder;
- public static Lidar lidar;
-
private CANTalon frontLeft, frontRight, rearLeft, rearRight;
private RobotDrive robotDrive;
- private GyroLib gyro;
private DoubleSolenoid leftGearPiston, rightGearPiston;
// Drivetrain specific constants that relate to the inches per pulse value for
super(Constants.DriveTrain.kp, Constants.DriveTrain.ki,
Constants.DriveTrain.kd);
- frontLeft = new CANTalon(Constants.DriveTrain.FRONT_LEFT);
- frontRight = new CANTalon(Constants.DriveTrain.FRONT_RIGHT);
- rearLeft = new CANTalon(Constants.DriveTrain.REAR_LEFT);
- rearRight = new CANTalon(Constants.DriveTrain.REAR_RIGHT);
+ frontLeft = new CANTalon(Constants.DriveTrain.DRIVE_FRONT_LEFT);
+ frontRight = new CANTalon(Constants.DriveTrain.DRIVE_FRONT_RIGHT);
+ rearLeft = new CANTalon(Constants.DriveTrain.DRIVE_REAR_LEFT);
+ rearRight = new CANTalon(Constants.DriveTrain.DRIVE_REAR_RIGHT);
robotDrive = new RobotDrive(frontLeft, rearLeft, frontRight, rearRight);
- lidar = new Lidar(I2C.Port.kOnboard);
-
leftEncoder = new Encoder(Constants.DriveTrain.ENCODER_LEFT_A,
Constants.DriveTrain.ENCODER_LEFT_B, false, EncodingType.k4X);
rightEncoder = new Encoder(Constants.DriveTrain.ENCODER_RIGHT_A,
leftEncoder.setDistancePerPulse(Constants.DriveTrain.INCHES_PER_PULSE);
rightEncoder.setDistancePerPulse(Constants.DriveTrain.INCHES_PER_PULSE);
- gyro = new GyroLib(I2C.Port.kOnboard, false);
-
- DRIVE_MODE = Constants.DriveTrain.ENCODER_MODE;
- setEncoderPID();
this.disable();
- gyro.start();
- leftGearPiston = new DoubleSolenoid(Constants.DriveTrain.LEFT_FORWARD,
- Constants.DriveTrain.LEFT_REVERSE);
- rightGearPiston = new DoubleSolenoid(Constants.DriveTrain.RIGHT_FORWARD,
- Constants.DriveTrain.RIGHT_REVERSE);
- Constants.DriveTrain.inverted = false;
+ leftGearPiston = new DoubleSolenoid(Constants.DriveTrain.LEFT_SHIFT_MODULE,
+ Constants.DriveTrain.LEFT_SHIFT_FORWARD,
+ Constants.DriveTrain.LEFT_SHIFT_REVERSE);
+ rightGearPiston = new DoubleSolenoid(
+ Constants.DriveTrain.RIGHT_SHIFT_MODULE,
+ Constants.DriveTrain.RIGHT_SHIFT_FORWARD,
+ Constants.DriveTrain.RIGHT_SHIFT_REVERSE);
}
@Override
}
public void stop() {
- drive(0, 0);
+ setMotorSpeeds(0, 0);
}
public void resetEncoders() {
rightEncoder.reset();
}
- public double getLidarDistance() {
- return lidar.pidGet();
- }
-
public double getRightSpeed() {
return rightEncoder.getRate(); // in inches per second
}
// Get error between the setpoint of PID Controller and the current state of
// the robot
public double getError() {
- if (DRIVE_MODE == Constants.DriveTrain.ENCODER_MODE)
- return Math.abs(this.getSetpoint() - getAvgEncoderDistance());
- else
- return Math.abs(this.getSetpoint() + getGyroAngle());
- }
-
- public double getGyroAngle() {
- return gyro.getRotationZ().getAngle();
- }
-
- public void resetGyro() {
- gyro.reset();
+ return Math.abs(this.getSetpoint() - getAvgEncoderDistance());
}
public void printEncoder(int i, int n) {
}
}
- public void printGyroOutput() {
- System.out.println("Gyro Angle" + -this.getGyroAngle());
- }
-
/*
* returns the PID output that is returned by the PID Controller
*/
// Updates the PID constants based on which control mode is being used
public void updatePID() {
- if (DRIVE_MODE == Constants.DriveTrain.ENCODER_MODE)
- this.getPIDController().setPID(Constants.DriveTrain.kp,
- Constants.DriveTrain.ki, Constants.DriveTrain.kd);
- else
- this.getPIDController().setPID(Constants.DriveTrain.gp,
- Constants.DriveTrain.gd, Constants.DriveTrain.gi);
+ this.getPIDController().setPID(Constants.DriveTrain.kp,
+ Constants.DriveTrain.ki, Constants.DriveTrain.kd);
}
public CANTalon getFrontLeft() {
return rearRight;
}
- public int getMode() {
- return DRIVE_MODE;
- }
-
/*
* Method is a required method that the PID Subsystem uses to return the
* calculated PID value to the driver
- *
+ *
* @param Gives the user the output from the PID algorithm that is calculated
* internally
- *
+ *
* Body: Uses the output, does some filtering and drives the robot
*/
@Override
protected void usePIDOutput(double output) {
double left = 0;
double right = 0;
- if (DRIVE_MODE == Constants.DriveTrain.ENCODER_MODE) {
- double drift = this.getLeftDistance() - this.getRightDistance();
- if (Math.abs(output) > 0 && Math.abs(output) < 0.3)
- output = Math.signum(output) * 0.3;
- left = output;
- right = output + drift * Constants.DriveTrain.kp / 10;
- } else if (DRIVE_MODE == Constants.DriveTrain.GYRO_MODE) {
- left = output;
- right = -output;
- }
- drive(left, right);
+ double drift = this.getLeftDistance() - this.getRightDistance();
+ if (Math.abs(output) > 0 && Math.abs(output) < 0.3)
+ output = Math.signum(output) * 0.3;
+ left = output;
+ right = output + drift * Constants.DriveTrain.kp / 10;
+ setMotorSpeeds(left, right);
pidOutput = output;
}
}
/*
- * Checks the drive mode <<<<<<< 9728080f491e9fb09795494349dba1297f447c0f
- *
- * @return the current state of the robot in each state Average distance from
- * both sides of tank drive for Encoder Mode Angle from the gyro in GYRO_MODE
- * =======
- *
+ * Checks the drive mode
+ *
* @return the current state of the robot in each state Average distance from
* both sides of tank drive for Encoder Mode Angle from the gyro in GYRO_MODE
- * >>>>>>> Move all constants in DeadReckoning to Auton class because it makes
- * more sense
*/
private double sensorFeedback() {
- if (DRIVE_MODE == Constants.DriveTrain.ENCODER_MODE)
- return getAvgEncoderDistance();
- else if (DRIVE_MODE == Constants.DriveTrain.GYRO_MODE)
- return -this.getGyroAngle();
- // counterclockwise is positive on joystick but we want it to be negative
- else
- return 0;
- }
-
- /*
- * @param left and right setpoints to set to the left and right side of tank
- * inverted is for Logan, wants the robot to invert all controls left = right
- * and right = left negative input is required for the regular rotation
- * because RobotDrive tankdrive method drives inverted
- */
- public void drive(double left, double right) {
- robotDrive.tankDrive(-left, -right);
- // dunno why but inverted drive (- values is forward)
- if (!Constants.DriveTrain.inverted)
- robotDrive.tankDrive(-left, -right);
- else
- robotDrive.tankDrive(right, left);
- }
-
- /*
- * constrains the distance to within -100 and 100 since we aren't going to
- * drive more than 100 inches
- *
- * Configure Encoder PID
- *
- * Sets the setpoint to the PID subsystem
- */
- public void driveDistance(double dist, double maxTimeOut) {
- dist = MathLib.constrain(dist, -100, 100);
- setEncoderPID();
- setSetpoint(dist);
- }
-
- /*
- * Sets the encoder mode Updates the PID constants sets the tolerance and sets
- * output/input ranges Enables the PID controllers
- */
- public void setEncoderPID() {
- DRIVE_MODE = Constants.DriveTrain.ENCODER_MODE;
- this.updatePID();
- this.setAbsoluteTolerance(Constants.DriveTrain.encoderTolerance);
- this.setOutputRange(-1.0, 1.0);
- this.setInputRange(-200.0, 200.0);
- this.enable();
- }
-
- /*
- * Sets the Gyro Mode Updates the PID constants, sets the tolerance and sets
- * output/input ranges Enables the PID controllers
- */
- private void setGyroPID() {
- DRIVE_MODE = Constants.DriveTrain.GYRO_MODE;
- this.updatePID();
- this.getPIDController().setPID(Constants.DriveTrain.gp,
- Constants.DriveTrain.gi, Constants.DriveTrain.gd);
-
- this.setAbsoluteTolerance(Constants.DriveTrain.gyroTolerance);
- this.setOutputRange(-1.0, 1.0);
- this.setInputRange(-360.0, 360.0);
- this.enable();
- }
-
- /*
- * Turning method that should be used repeatedly in a command
- *
- * First constrains the angle to within -360 and 360 since that is as much as
- * we need to turn
- *
- * Configures Gyro PID and sets the setpoint as an angle
- */
- public void turnAngle(double angle) {
- angle = MathLib.constrain(angle, -360, 360);
- setGyroPID();
- setSetpoint(angle);
+ return getAvgEncoderDistance();
+ }
+
+ public void joystickDrive(double left, double right) {
+ int type = Constants.DriveTrain.DRIVE_TYPE;
+
+ // Handle flipping of the "front" of the robot
+ double k = (isFlipped() ? -1 : 1);
+
+ if (type == Constants.DriveTrain.TANK) {
+ // TODO Test this for negation and for voltage vs. [-1,1] outputs
+ double leftSpeed = (-frontLeft.get() + -rearLeft.get()) / 2;
+ double rightSpeed = (-frontRight.get() + -rearRight.get()) / 2;
+ left = ((Constants.DriveTrain.kADJUST - 1) * leftSpeed + left)
+ / Constants.DriveTrain.kADJUST;
+ right = ((Constants.DriveTrain.kADJUST - 1) * rightSpeed + right)
+ / Constants.DriveTrain.kADJUST;
+ robotDrive.tankDrive(-left * k, -right * k);
+ } else if (type == Constants.DriveTrain.ARCADE) {
+ double speed = (-frontLeft.get() + -rearLeft.get() + -frontRight.get() + -rearRight
+ .get()) / 2;
+ left = ((Constants.DriveTrain.kADJUST - 1) * speed + left)
+ / Constants.DriveTrain.kADJUST;
+ robotDrive.arcadeDrive(left * k, right);
+ }
}
public void setMotorSpeeds(double left, double right) {
- // positive setpoint to left side makes it go backwards
- // positive setpoint to right side makes it go forwards.
- frontLeft.set(-left);
- rearLeft.set(-left);
- frontRight.set(right);
- rearRight.set(right);
+ double k = (isFlipped() ? -1 : 1);
+ robotDrive.tankDrive(-left * k, -right * k);
}
- /*
- * @return a value that is the current setpoint for the piston kReverse or
- * kForward
+ /**
+ * @return a value that is the current setpoint for the piston (kReverse or
+ * kForward)
*/
- public Value getLeftGearPistonValue() {
- return leftGearPiston.get();
+ public Value getGearPistonValue() {
+ return leftGearPiston.get(); // Pistons should always be in the same state
}
- /*
- * @return a value that is the current setpoint for the piston kReverse or
- * kForward
- */
- public Value getRightGearPistonValue() {
- return rightGearPiston.get();
- }
-
- /*
+ /**
* Changes the ball shift gear assembly to high
*/
public void setHighGear() {
changeGear(Constants.DriveTrain.HIGH_GEAR);
}
- /*
+ /**
* Changes the ball shift gear assembly to low
*/
public void setLowGear() {
changeGear(Constants.DriveTrain.LOW_GEAR);
}
- /*
- * changes the gear to a DoubleSolenoid.Value
+ /**
+ * Changes the gear to a DoubleSolenoid.Value
*/
public void changeGear(DoubleSolenoid.Value gear) {
leftGearPiston.set(gear);
rightGearPiston.set(gear);
}
- public void toggleTimeDeadReckoning() {
- Constants.Auton.isUsingTime = !Constants.Auton.isUsingTime;
+ /**
+ * Switches drivetrain gears from high to low or low to high
+ */
+ public void switchGear() {
+ Value currentValue = getGearPistonValue();
+ Value setValue = (currentValue == Constants.DriveTrain.HIGH_GEAR) ? Constants.DriveTrain.LOW_GEAR
+ : Constants.DriveTrain.HIGH_GEAR;
+ changeGear(setValue);
}
+
+ /**
+ * Toggle whether the motor outputs are flipped, effectively switching which
+ * side of the robot is the front.
+ */
+ public void toggleFlipped() {
+ outputFlipped = !outputFlipped;
+ }
+
+ public boolean isFlipped() {
+ return outputFlipped;
+ }
+
}