001// Copyright (c) FIRST and other WPILib contributors. 002// Open Source Software; you can modify and/or share it under the terms of 003// the WPILib BSD license file in the root directory of this project. 004 005package edu.wpi.first.wpilibj.drive; 006 007import static edu.wpi.first.util.ErrorMessages.requireNonNullParam; 008 009import edu.wpi.first.hal.FRCNetComm.tInstances; 010import edu.wpi.first.hal.FRCNetComm.tResourceType; 011import edu.wpi.first.hal.HAL; 012import edu.wpi.first.math.MathUtil; 013import edu.wpi.first.util.sendable.Sendable; 014import edu.wpi.first.util.sendable.SendableBuilder; 015import edu.wpi.first.util.sendable.SendableRegistry; 016import edu.wpi.first.wpilibj.motorcontrol.MotorController; 017 018/** 019 * A class for driving differential drive/skid-steer drive platforms such as the Kit of Parts drive 020 * base, "tank drive", or West Coast Drive. 021 * 022 * <p>These drive bases typically have drop-center / skid-steer with two or more wheels per side 023 * (e.g., 6WD or 8WD). This class takes a MotorController per side. For four and six motor 024 * drivetrains, construct and pass in {@link 025 * edu.wpi.first.wpilibj.motorcontrol.MotorControllerGroup} instances as follows. 026 * 027 * <p>Four motor drivetrain: 028 * 029 * <pre><code> 030 * public class Robot { 031 * MotorController m_frontLeft = new PWMVictorSPX(1); 032 * MotorController m_rearLeft = new PWMVictorSPX(2); 033 * MotorControllerGroup m_left = new MotorControllerGroup(m_frontLeft, m_rearLeft); 034 * 035 * MotorController m_frontRight = new PWMVictorSPX(3); 036 * MotorController m_rearRight = new PWMVictorSPX(4); 037 * MotorControllerGroup m_right = new MotorControllerGroup(m_frontRight, m_rearRight); 038 * 039 * DifferentialDrive m_drive = new DifferentialDrive(m_left, m_right); 040 * } 041 * </code></pre> 042 * 043 * <p>Six motor drivetrain: 044 * 045 * <pre><code> 046 * public class Robot { 047 * MotorController m_frontLeft = new PWMVictorSPX(1); 048 * MotorController m_midLeft = new PWMVictorSPX(2); 049 * MotorController m_rearLeft = new PWMVictorSPX(3); 050 * MotorControllerGroup m_left = new MotorControllerGroup(m_frontLeft, m_midLeft, m_rearLeft); 051 * 052 * MotorController m_frontRight = new PWMVictorSPX(4); 053 * MotorController m_midRight = new PWMVictorSPX(5); 054 * MotorController m_rearRight = new PWMVictorSPX(6); 055 * MotorControllerGroup m_right = new MotorControllerGroup(m_frontRight, m_midRight, m_rearRight); 056 * 057 * DifferentialDrive m_drive = new DifferentialDrive(m_left, m_right); 058 * } 059 * </code></pre> 060 * 061 * <p>A differential drive robot has left and right wheels separated by an arbitrary width. 062 * 063 * <p>Drive base diagram: 064 * 065 * <pre> 066 * |_______| 067 * | | | | 068 * | | 069 * |_|___|_| 070 * | | 071 * </pre> 072 * 073 * <p>Each drive function provides different inverse kinematic relations for a differential drive 074 * robot. 075 * 076 * <p>This library uses the NWU axes convention (North-West-Up as external reference in the world 077 * frame). The positive X axis points ahead, the positive Y axis points to the left, and the 078 * positive Z axis points up. Rotations follow the right-hand rule, so counterclockwise rotation 079 * around the Z axis is positive. 080 * 081 * <p>Inputs smaller then {@value edu.wpi.first.wpilibj.drive.RobotDriveBase#kDefaultDeadband} will 082 * be set to 0, and larger values will be scaled so that the full range is still used. This deadband 083 * value can be changed with {@link #setDeadband}. 084 * 085 * <p>{@link edu.wpi.first.wpilibj.MotorSafety} is enabled by default. The tankDrive, arcadeDrive, 086 * or curvatureDrive methods should be called periodically to avoid Motor Safety timeouts. 087 */ 088public class DifferentialDrive extends RobotDriveBase implements Sendable, AutoCloseable { 089 private static int instances; 090 091 private final MotorController m_leftMotor; 092 private final MotorController m_rightMotor; 093 094 private boolean m_reported; 095 096 /** 097 * Wheel speeds for a differential drive. 098 * 099 * <p>Uses normalized voltage [-1.0..1.0]. 100 */ 101 @SuppressWarnings("MemberName") 102 public static class WheelSpeeds { 103 public double left; 104 public double right; 105 106 /** Constructs a WheelSpeeds with zeroes for left and right speeds. */ 107 public WheelSpeeds() {} 108 109 /** 110 * Constructs a WheelSpeeds. 111 * 112 * @param left The left speed [-1.0..1.0]. 113 * @param right The right speed [-1.0..1.0]. 114 */ 115 public WheelSpeeds(double left, double right) { 116 this.left = left; 117 this.right = right; 118 } 119 } 120 121 /** 122 * Construct a DifferentialDrive. 123 * 124 * <p>To pass multiple motors per side, use a {@link 125 * edu.wpi.first.wpilibj.motorcontrol.MotorControllerGroup}. If a motor needs to be inverted, do 126 * so before passing it in. 127 * 128 * @param leftMotor Left motor. 129 * @param rightMotor Right motor. 130 */ 131 public DifferentialDrive(MotorController leftMotor, MotorController rightMotor) { 132 requireNonNullParam(leftMotor, "leftMotor", "DifferentialDrive"); 133 requireNonNullParam(rightMotor, "rightMotor", "DifferentialDrive"); 134 135 m_leftMotor = leftMotor; 136 m_rightMotor = rightMotor; 137 SendableRegistry.addChild(this, m_leftMotor); 138 SendableRegistry.addChild(this, m_rightMotor); 139 instances++; 140 SendableRegistry.addLW(this, "DifferentialDrive", instances); 141 } 142 143 @Override 144 public void close() { 145 SendableRegistry.remove(this); 146 } 147 148 /** 149 * Arcade drive method for differential drive platform. The calculated values will be squared to 150 * decrease sensitivity at low speeds. 151 * 152 * @param xSpeed The robot's speed along the X axis [-1.0..1.0]. Forward is positive. 153 * @param zRotation The robot's rotation rate around the Z axis [-1.0..1.0]. Counterclockwise is 154 * positive. 155 */ 156 public void arcadeDrive(double xSpeed, double zRotation) { 157 arcadeDrive(xSpeed, zRotation, true); 158 } 159 160 /** 161 * Arcade drive method for differential drive platform. 162 * 163 * @param xSpeed The robot's speed along the X axis [-1.0..1.0]. Forward is positive. 164 * @param zRotation The robot's rotation rate around the Z axis [-1.0..1.0]. Counterclockwise is 165 * positive. 166 * @param squareInputs If set, decreases the input sensitivity at low speeds. 167 */ 168 public void arcadeDrive(double xSpeed, double zRotation, boolean squareInputs) { 169 if (!m_reported) { 170 HAL.report( 171 tResourceType.kResourceType_RobotDrive, tInstances.kRobotDrive2_DifferentialArcade, 2); 172 m_reported = true; 173 } 174 175 xSpeed = MathUtil.applyDeadband(xSpeed, m_deadband); 176 zRotation = MathUtil.applyDeadband(zRotation, m_deadband); 177 178 var speeds = arcadeDriveIK(xSpeed, zRotation, squareInputs); 179 180 m_leftMotor.set(speeds.left * m_maxOutput); 181 m_rightMotor.set(speeds.right * m_maxOutput); 182 183 feed(); 184 } 185 186 /** 187 * Curvature drive method for differential drive platform. 188 * 189 * <p>The rotation argument controls the curvature of the robot's path rather than its rate of 190 * heading change. This makes the robot more controllable at high speeds. 191 * 192 * @param xSpeed The robot's speed along the X axis [-1.0..1.0]. Forward is positive. 193 * @param zRotation The normalized curvature [-1.0..1.0]. Counterclockwise is positive. 194 * @param allowTurnInPlace If set, overrides constant-curvature turning for turn-in-place 195 * maneuvers. zRotation will control turning rate instead of curvature. 196 */ 197 public void curvatureDrive(double xSpeed, double zRotation, boolean allowTurnInPlace) { 198 if (!m_reported) { 199 HAL.report( 200 tResourceType.kResourceType_RobotDrive, tInstances.kRobotDrive2_DifferentialCurvature, 2); 201 m_reported = true; 202 } 203 204 xSpeed = MathUtil.applyDeadband(xSpeed, m_deadband); 205 zRotation = MathUtil.applyDeadband(zRotation, m_deadband); 206 207 var speeds = curvatureDriveIK(xSpeed, zRotation, allowTurnInPlace); 208 209 m_leftMotor.set(speeds.left * m_maxOutput); 210 m_rightMotor.set(speeds.right * m_maxOutput); 211 212 feed(); 213 } 214 215 /** 216 * Tank drive method for differential drive platform. The calculated values will be squared to 217 * decrease sensitivity at low speeds. 218 * 219 * @param leftSpeed The robot's left side speed along the X axis [-1.0..1.0]. Forward is positive. 220 * @param rightSpeed The robot's right side speed along the X axis [-1.0..1.0]. Forward is 221 * positive. 222 */ 223 public void tankDrive(double leftSpeed, double rightSpeed) { 224 tankDrive(leftSpeed, rightSpeed, true); 225 } 226 227 /** 228 * Tank drive method for differential drive platform. 229 * 230 * @param leftSpeed The robot left side's speed along the X axis [-1.0..1.0]. Forward is positive. 231 * @param rightSpeed The robot right side's speed along the X axis [-1.0..1.0]. Forward is 232 * positive. 233 * @param squareInputs If set, decreases the input sensitivity at low speeds. 234 */ 235 public void tankDrive(double leftSpeed, double rightSpeed, boolean squareInputs) { 236 if (!m_reported) { 237 HAL.report( 238 tResourceType.kResourceType_RobotDrive, tInstances.kRobotDrive2_DifferentialTank, 2); 239 m_reported = true; 240 } 241 242 leftSpeed = MathUtil.applyDeadband(leftSpeed, m_deadband); 243 rightSpeed = MathUtil.applyDeadband(rightSpeed, m_deadband); 244 245 var speeds = tankDriveIK(leftSpeed, rightSpeed, squareInputs); 246 247 m_leftMotor.set(speeds.left * m_maxOutput); 248 m_rightMotor.set(speeds.right * m_maxOutput); 249 250 feed(); 251 } 252 253 /** 254 * Arcade drive inverse kinematics for differential drive platform. 255 * 256 * @param xSpeed The robot's speed along the X axis [-1.0..1.0]. Forward is positive. 257 * @param zRotation The robot's rotation rate around the Z axis [-1.0..1.0]. Counterclockwise is 258 * positive. 259 * @param squareInputs If set, decreases the input sensitivity at low speeds. 260 * @return Wheel speeds [-1.0..1.0]. 261 */ 262 public static WheelSpeeds arcadeDriveIK(double xSpeed, double zRotation, boolean squareInputs) { 263 xSpeed = MathUtil.clamp(xSpeed, -1.0, 1.0); 264 zRotation = MathUtil.clamp(zRotation, -1.0, 1.0); 265 266 // Square the inputs (while preserving the sign) to increase fine control 267 // while permitting full power. 268 if (squareInputs) { 269 xSpeed = Math.copySign(xSpeed * xSpeed, xSpeed); 270 zRotation = Math.copySign(zRotation * zRotation, zRotation); 271 } 272 273 double leftSpeed = xSpeed - zRotation; 274 double rightSpeed = xSpeed + zRotation; 275 276 // Find the maximum possible value of (throttle + turn) along the vector 277 // that the joystick is pointing, then desaturate the wheel speeds 278 double greaterInput = Math.max(Math.abs(xSpeed), Math.abs(zRotation)); 279 double lesserInput = Math.min(Math.abs(xSpeed), Math.abs(zRotation)); 280 if (greaterInput == 0.0) { 281 return new WheelSpeeds(0.0, 0.0); 282 } 283 double saturatedInput = (greaterInput + lesserInput) / greaterInput; 284 leftSpeed /= saturatedInput; 285 rightSpeed /= saturatedInput; 286 287 return new WheelSpeeds(leftSpeed, rightSpeed); 288 } 289 290 /** 291 * Curvature drive inverse kinematics for differential drive platform. 292 * 293 * <p>The rotation argument controls the curvature of the robot's path rather than its rate of 294 * heading change. This makes the robot more controllable at high speeds. 295 * 296 * @param xSpeed The robot's speed along the X axis [-1.0..1.0]. Forward is positive. 297 * @param zRotation The normalized curvature [-1.0..1.0]. Counterclockwise is positive. 298 * @param allowTurnInPlace If set, overrides constant-curvature turning for turn-in-place 299 * maneuvers. zRotation will control rotation rate around the Z axis instead of curvature. 300 * @return Wheel speeds [-1.0..1.0]. 301 */ 302 public static WheelSpeeds curvatureDriveIK( 303 double xSpeed, double zRotation, boolean allowTurnInPlace) { 304 xSpeed = MathUtil.clamp(xSpeed, -1.0, 1.0); 305 zRotation = MathUtil.clamp(zRotation, -1.0, 1.0); 306 307 double leftSpeed; 308 double rightSpeed; 309 310 if (allowTurnInPlace) { 311 leftSpeed = xSpeed - zRotation; 312 rightSpeed = xSpeed + zRotation; 313 } else { 314 leftSpeed = xSpeed - Math.abs(xSpeed) * zRotation; 315 rightSpeed = xSpeed + Math.abs(xSpeed) * zRotation; 316 } 317 318 // Desaturate wheel speeds 319 double maxMagnitude = Math.max(Math.abs(leftSpeed), Math.abs(rightSpeed)); 320 if (maxMagnitude > 1.0) { 321 leftSpeed /= maxMagnitude; 322 rightSpeed /= maxMagnitude; 323 } 324 325 return new WheelSpeeds(leftSpeed, rightSpeed); 326 } 327 328 /** 329 * Tank drive inverse kinematics for differential drive platform. 330 * 331 * @param leftSpeed The robot left side's speed along the X axis [-1.0..1.0]. Forward is positive. 332 * @param rightSpeed The robot right side's speed along the X axis [-1.0..1.0]. Forward is 333 * positive. 334 * @param squareInputs If set, decreases the input sensitivity at low speeds. 335 * @return Wheel speeds [-1.0..1.0]. 336 */ 337 public static WheelSpeeds tankDriveIK(double leftSpeed, double rightSpeed, boolean squareInputs) { 338 leftSpeed = MathUtil.clamp(leftSpeed, -1.0, 1.0); 339 rightSpeed = MathUtil.clamp(rightSpeed, -1.0, 1.0); 340 341 // Square the inputs (while preserving the sign) to increase fine control 342 // while permitting full power. 343 if (squareInputs) { 344 leftSpeed = Math.copySign(leftSpeed * leftSpeed, leftSpeed); 345 rightSpeed = Math.copySign(rightSpeed * rightSpeed, rightSpeed); 346 } 347 348 return new WheelSpeeds(leftSpeed, rightSpeed); 349 } 350 351 @Override 352 public void stopMotor() { 353 m_leftMotor.stopMotor(); 354 m_rightMotor.stopMotor(); 355 feed(); 356 } 357 358 @Override 359 public String getDescription() { 360 return "DifferentialDrive"; 361 } 362 363 @Override 364 public void initSendable(SendableBuilder builder) { 365 builder.setSmartDashboardType("DifferentialDrive"); 366 builder.setActuator(true); 367 builder.setSafeState(this::stopMotor); 368 builder.addDoubleProperty("Left Motor Speed", m_leftMotor::get, m_leftMotor::set); 369 builder.addDoubleProperty("Right Motor Speed", m_rightMotor::get, m_rightMotor::set); 370 } 371}