| 1 | package org.usfirst.frc.team3501.robot.subsystems; |
| 2 | |
| 3 | import org.usfirst.frc.team3501.robot.Constants; |
| 4 | import org.usfirst.frc.team3501.robot.MathLib; |
| 5 | import org.usfirst.frc.team3501.robot.commands.driving.JoystickDrive; |
| 6 | import org.usfirst.frc.team3501.robot.sensors.GyroLib; |
| 7 | import org.usfirst.frc.team3501.robot.sensors.Lidar; |
| 8 | |
| 9 | import edu.wpi.first.wpilibj.CANTalon; |
| 10 | import edu.wpi.first.wpilibj.Compressor; |
| 11 | import edu.wpi.first.wpilibj.CounterBase.EncodingType; |
| 12 | import edu.wpi.first.wpilibj.DoubleSolenoid; |
| 13 | import edu.wpi.first.wpilibj.DoubleSolenoid.Value; |
| 14 | import edu.wpi.first.wpilibj.Encoder; |
| 15 | import edu.wpi.first.wpilibj.I2C; |
| 16 | import edu.wpi.first.wpilibj.RobotDrive; |
| 17 | import edu.wpi.first.wpilibj.command.PIDSubsystem; |
| 18 | |
| 19 | public class DriveTrain extends PIDSubsystem { |
| 20 | // Current Drive Mode Default Drive Mode is Manual |
| 21 | private int DRIVE_MODE = 1; |
| 22 | private static double pidOutput = 0; |
| 23 | |
| 24 | private Encoder leftEncoder, rightEncoder; |
| 25 | |
| 26 | public static Lidar lidar; |
| 27 | |
| 28 | private CANTalon frontLeft, frontRight, rearLeft, rearRight; |
| 29 | private RobotDrive robotDrive; |
| 30 | |
| 31 | private GyroLib gyro; |
| 32 | private DoubleSolenoid leftGearPiston, rightGearPiston; |
| 33 | private Compressor compressor; |
| 34 | |
| 35 | // Drivetrain specific constants that relate to the inches per pulse value for |
| 36 | // the encoders |
| 37 | |
| 38 | public DriveTrain() { |
| 39 | super(Constants.DriveTrain.kp, Constants.DriveTrain.ki, |
| 40 | Constants.DriveTrain.kd); |
| 41 | |
| 42 | frontLeft = new CANTalon(Constants.DriveTrain.FRONT_LEFT); |
| 43 | frontRight = new CANTalon(Constants.DriveTrain.FRONT_RIGHT); |
| 44 | rearLeft = new CANTalon(Constants.DriveTrain.REAR_LEFT); |
| 45 | rearRight = new CANTalon(Constants.DriveTrain.REAR_RIGHT); |
| 46 | |
| 47 | robotDrive = new RobotDrive(frontLeft, rearLeft, frontRight, rearRight); |
| 48 | |
| 49 | lidar = new Lidar(I2C.Port.kMXP); |
| 50 | leftEncoder = new Encoder(Constants.DriveTrain.ENCODER_LEFT_A, |
| 51 | Constants.DriveTrain.ENCODER_LEFT_B, false, EncodingType.k4X); |
| 52 | rightEncoder = new Encoder(Constants.DriveTrain.ENCODER_RIGHT_A, |
| 53 | Constants.DriveTrain.ENCODER_RIGHT_B, false, EncodingType.k4X); |
| 54 | leftEncoder.setDistancePerPulse(Constants.DriveTrain.INCHES_PER_PULSE); |
| 55 | rightEncoder.setDistancePerPulse(Constants.DriveTrain.INCHES_PER_PULSE); |
| 56 | |
| 57 | leftEncoder.setDistancePerPulse(Constants.DriveTrain.INCHES_PER_PULSE); |
| 58 | rightEncoder.setDistancePerPulse(Constants.DriveTrain.INCHES_PER_PULSE); |
| 59 | |
| 60 | gyro = new GyroLib(I2C.Port.kOnboard, false); |
| 61 | |
| 62 | DRIVE_MODE = Constants.DriveTrain.ENCODER_MODE; |
| 63 | setEncoderPID(); |
| 64 | this.disable(); |
| 65 | gyro.start(); |
| 66 | |
| 67 | leftGearPiston = new DoubleSolenoid(Constants.DriveTrain.MODULE_B_ID, |
| 68 | Constants.DriveTrain.LEFT_FORWARD, Constants.DriveTrain.LEFT_REVERSE); |
| 69 | rightGearPiston = new DoubleSolenoid(Constants.DriveTrain.MODULE_B_ID, |
| 70 | Constants.DriveTrain.RIGHT_FORWARD, Constants.DriveTrain.RIGHT_REVERSE); |
| 71 | |
| 72 | compressor = new Compressor(Constants.DriveTrain.COMPRESSOR_ID); |
| 73 | |
| 74 | Constants.DriveTrain.inverted = false; |
| 75 | } |
| 76 | |
| 77 | @Override |
| 78 | protected void initDefaultCommand() { |
| 79 | setDefaultCommand(new JoystickDrive()); |
| 80 | } |
| 81 | |
| 82 | // Print tne PID Output |
| 83 | public void printOutput() { |
| 84 | System.out.println("PIDOutput: " + pidOutput); |
| 85 | } |
| 86 | |
| 87 | private double getAvgEncoderDistance() { |
| 88 | return (leftEncoder.getDistance() + rightEncoder.getDistance()) / 2; |
| 89 | } |
| 90 | |
| 91 | // Whether or not the PID Controller thinks we have reached the target |
| 92 | // setpoint |
| 93 | public boolean reachedTarget() { |
| 94 | if (this.onTarget()) { |
| 95 | this.disable(); |
| 96 | return true; |
| 97 | } else { |
| 98 | return false; |
| 99 | } |
| 100 | } |
| 101 | |
| 102 | public void stop() { |
| 103 | drive(0, 0); |
| 104 | } |
| 105 | |
| 106 | public void resetEncoders() { |
| 107 | leftEncoder.reset(); |
| 108 | rightEncoder.reset(); |
| 109 | } |
| 110 | |
| 111 | public double getLidarDistance() { |
| 112 | return lidar.pidGet(); |
| 113 | } |
| 114 | |
| 115 | public double getRightSpeed() { |
| 116 | return rightEncoder.getRate(); // in inches per second |
| 117 | } |
| 118 | |
| 119 | public double getLeftSpeed() { |
| 120 | return leftEncoder.getRate(); // in inches per second |
| 121 | } |
| 122 | |
| 123 | public double getSpeed() { |
| 124 | return (getLeftSpeed() + getRightSpeed()) / 2.0; // in inches per second |
| 125 | } |
| 126 | |
| 127 | public double getRightDistance() { |
| 128 | return rightEncoder.getDistance(); // in inches |
| 129 | } |
| 130 | |
| 131 | public double getLeftDistance() { |
| 132 | return leftEncoder.getDistance(); // in inches |
| 133 | } |
| 134 | |
| 135 | // Get error between the setpoint of PID Controller and the current state of |
| 136 | // the robot |
| 137 | public double getError() { |
| 138 | if (DRIVE_MODE == Constants.DriveTrain.ENCODER_MODE) |
| 139 | return Math.abs(this.getSetpoint() - getAvgEncoderDistance()); |
| 140 | else |
| 141 | return Math.abs(this.getSetpoint() + getGyroAngle()); |
| 142 | } |
| 143 | |
| 144 | public double getGyroAngle() { |
| 145 | return gyro.getRotationZ().getAngle(); |
| 146 | } |
| 147 | |
| 148 | public void resetGyro() { |
| 149 | gyro.reset(); |
| 150 | } |
| 151 | |
| 152 | public void printEncoder(int i, int n) { |
| 153 | if (i % n == 0) { |
| 154 | System.out.println("Left: " + this.getLeftDistance()); |
| 155 | System.out.println("Right: " + this.getRightDistance()); |
| 156 | |
| 157 | } |
| 158 | } |
| 159 | |
| 160 | public void printGyroOutput() { |
| 161 | System.out.println("Gyro Angle" + -this.getGyroAngle()); |
| 162 | } |
| 163 | |
| 164 | /* |
| 165 | * returns the PID output that is returned by the PID Controller |
| 166 | */ |
| 167 | public double getOutput() { |
| 168 | return pidOutput; |
| 169 | } |
| 170 | |
| 171 | // Updates the PID constants based on which control mode is being used |
| 172 | public void updatePID() { |
| 173 | if (DRIVE_MODE == Constants.DriveTrain.ENCODER_MODE) |
| 174 | this.getPIDController().setPID(Constants.DriveTrain.kp, |
| 175 | Constants.DriveTrain.ki, Constants.DriveTrain.kd); |
| 176 | else |
| 177 | this.getPIDController().setPID(Constants.DriveTrain.gp, |
| 178 | Constants.DriveTrain.gd, Constants.DriveTrain.gi); |
| 179 | } |
| 180 | |
| 181 | public CANTalon getFrontLeft() { |
| 182 | return frontLeft; |
| 183 | } |
| 184 | |
| 185 | public CANTalon getFrontRight() { |
| 186 | return frontRight; |
| 187 | } |
| 188 | |
| 189 | public CANTalon getRearLeft() { |
| 190 | return rearLeft; |
| 191 | } |
| 192 | |
| 193 | public CANTalon getRearRight() { |
| 194 | return rearRight; |
| 195 | } |
| 196 | |
| 197 | public int getMode() { |
| 198 | return DRIVE_MODE; |
| 199 | } |
| 200 | |
| 201 | /* |
| 202 | * Method is a required method that the PID Subsystem uses to return the |
| 203 | * calculated PID value to the driver |
| 204 | * |
| 205 | * @param Gives the user the output from the PID algorithm that is calculated |
| 206 | * internally |
| 207 | * |
| 208 | * Body: Uses the output, does some filtering and drives the robot |
| 209 | */ |
| 210 | @Override |
| 211 | protected void usePIDOutput(double output) { |
| 212 | double left = 0; |
| 213 | double right = 0; |
| 214 | if (DRIVE_MODE == Constants.DriveTrain.ENCODER_MODE) { |
| 215 | double drift = this.getLeftDistance() - this.getRightDistance(); |
| 216 | if (Math.abs(output) > 0 && Math.abs(output) < 0.3) |
| 217 | output = Math.signum(output) * 0.3; |
| 218 | left = output; |
| 219 | right = output + drift * Constants.DriveTrain.kp / 10; |
| 220 | } else if (DRIVE_MODE == Constants.DriveTrain.GYRO_MODE) { |
| 221 | left = output; |
| 222 | right = -output; |
| 223 | } |
| 224 | drive(left, right); |
| 225 | pidOutput = output; |
| 226 | } |
| 227 | |
| 228 | @Override |
| 229 | protected double returnPIDInput() { |
| 230 | return sensorFeedback(); |
| 231 | } |
| 232 | |
| 233 | /* |
| 234 | * Checks the drive mode |
| 235 | * |
| 236 | * @return the current state of the robot in each state Average distance from |
| 237 | * both sides of tank drive for Encoder Mode Angle from the gyro in GYRO_MODE |
| 238 | */ |
| 239 | private double sensorFeedback() { |
| 240 | if (DRIVE_MODE == Constants.DriveTrain.ENCODER_MODE) |
| 241 | return getAvgEncoderDistance(); |
| 242 | else if (DRIVE_MODE == Constants.DriveTrain.GYRO_MODE) |
| 243 | return -this.getGyroAngle(); |
| 244 | // counterclockwise is positive on joystick but we want it to be negative |
| 245 | else |
| 246 | return 0; |
| 247 | } |
| 248 | |
| 249 | /* |
| 250 | * @param left and right setpoints to set to the left and right side of tank |
| 251 | * inverted is for Logan, wants the robot to invert all controls left = right |
| 252 | * and right = left negative input is required for the regular rotation |
| 253 | * because RobotDrive tankdrive method drives inverted |
| 254 | */ |
| 255 | public void drive(double left, double right) { |
| 256 | // robotDrive.tankDrive(-left, -right); |
| 257 | // dunno why but inverted drive (- values is forward) |
| 258 | if (!Constants.DriveTrain.inverted) |
| 259 | robotDrive.tankDrive(-left, -right); |
| 260 | else |
| 261 | robotDrive.tankDrive(right, left); |
| 262 | } |
| 263 | |
| 264 | public void arcadeDrive(double y, double twist) { |
| 265 | robotDrive.arcadeDrive(y, twist); |
| 266 | } |
| 267 | |
| 268 | /* |
| 269 | * constrains the distance to within -100 and 100 since we aren't going to |
| 270 | * drive more than 100 inches |
| 271 | * |
| 272 | * Configure Encoder PID |
| 273 | * |
| 274 | * Sets the setpoint to the PID subsystem |
| 275 | */ |
| 276 | public void driveDistance(double dist, double maxTimeOut) { |
| 277 | dist = MathLib.constrain(dist, -100, 100); |
| 278 | setEncoderPID(); |
| 279 | setSetpoint(dist); |
| 280 | } |
| 281 | |
| 282 | /* |
| 283 | * Sets the encoder mode Updates the PID constants sets the tolerance and sets |
| 284 | * output/input ranges Enables the PID controllers |
| 285 | */ |
| 286 | public void setEncoderPID() { |
| 287 | DRIVE_MODE = Constants.DriveTrain.ENCODER_MODE; |
| 288 | this.updatePID(); |
| 289 | this.setAbsoluteTolerance(Constants.DriveTrain.encoderTolerance); |
| 290 | this.setOutputRange(-1.0, 1.0); |
| 291 | this.setInputRange(-200.0, 200.0); |
| 292 | this.enable(); |
| 293 | } |
| 294 | |
| 295 | /* |
| 296 | * Sets the Gyro Mode Updates the PID constants, sets the tolerance and sets |
| 297 | * output/input ranges Enables the PID controllers |
| 298 | */ |
| 299 | private void setGyroPID() { |
| 300 | DRIVE_MODE = Constants.DriveTrain.GYRO_MODE; |
| 301 | this.updatePID(); |
| 302 | this.getPIDController().setPID(Constants.DriveTrain.gp, |
| 303 | Constants.DriveTrain.gi, Constants.DriveTrain.gd); |
| 304 | |
| 305 | this.setAbsoluteTolerance(Constants.DriveTrain.gyroTolerance); |
| 306 | this.setOutputRange(-1.0, 1.0); |
| 307 | this.setInputRange(-360.0, 360.0); |
| 308 | this.enable(); |
| 309 | } |
| 310 | |
| 311 | /* |
| 312 | * Turning method that should be used repeatedly in a command |
| 313 | * |
| 314 | * First constrains the angle to within -360 and 360 since that is as much as |
| 315 | * we need to turn |
| 316 | * |
| 317 | * Configures Gyro PID and sets the setpoint as an angle |
| 318 | */ |
| 319 | public void turnAngle(double angle) { |
| 320 | angle = MathLib.constrain(angle, -360, 360); |
| 321 | setGyroPID(); |
| 322 | setSetpoint(angle); |
| 323 | } |
| 324 | |
| 325 | public void setMotorSpeeds(double left, double right) { |
| 326 | // positive setpoint to left side makes it go backwards |
| 327 | // positive setpoint to right side makes it go forwards. |
| 328 | frontLeft.set(-left); |
| 329 | rearLeft.set(-left); |
| 330 | frontRight.set(right); |
| 331 | rearRight.set(right); |
| 332 | } |
| 333 | |
| 334 | /* |
| 335 | * @return a value that is the current setpoint for the piston kReverse or |
| 336 | * kForward |
| 337 | */ |
| 338 | public Value getLeftGearPistonValue() { |
| 339 | return leftGearPiston.get(); |
| 340 | } |
| 341 | |
| 342 | /* |
| 343 | * @return a value that is the current setpoint for the piston kReverse or |
| 344 | * kForward |
| 345 | */ |
| 346 | public Value getRightGearPistonValue() { |
| 347 | return rightGearPiston.get(); |
| 348 | } |
| 349 | |
| 350 | /* |
| 351 | * Changes the ball shift gear assembly to high |
| 352 | */ |
| 353 | public void setHighGear() { |
| 354 | changeGear(Constants.DriveTrain.HIGH_GEAR); |
| 355 | } |
| 356 | |
| 357 | /* |
| 358 | * Changes the ball shift gear assembly to low |
| 359 | */ |
| 360 | public void setLowGear() { |
| 361 | changeGear(Constants.DriveTrain.LOW_GEAR); |
| 362 | } |
| 363 | |
| 364 | /* |
| 365 | * changes the gear to a DoubleSolenoid.Value |
| 366 | */ |
| 367 | public void changeGear(DoubleSolenoid.Value gear) { |
| 368 | leftGearPiston.set(gear); |
| 369 | rightGearPiston.set(gear); |
| 370 | } |
| 371 | |
| 372 | public void startCompressor() { |
| 373 | compressor.start(); |
| 374 | } |
| 375 | |
| 376 | public void stopCompressor() { |
| 377 | compressor.stop(); |
| 378 | } |
| 379 | |
| 380 | public void toggleCompressor() { |
| 381 | if (compressor.enabled()) |
| 382 | compressor.stop(); |
| 383 | else |
| 384 | compressor.start(); |
| 385 | } |
| 386 | |
| 387 | } |