class DriveTrain(Subsystem):
'''
'Tank Drive' system set up with 2 motors per side, one a "master"
with a mag encoder attached and the other "slave" controller set
to follow the "master".
'''
def __init__(self):
# Initialize all controllers
self.driveLeftMaster = Talon(kDriveTrain.lmId)
self.driveLeftSlave = Talon(kDriveTrain.lsId)
self.driveRightMaster = Talon(kDriveTrain.rmId)
self.driveRightSlave = Talon(kDriveTrain.rsId)
# Connect the slaves to the masters on each side
self.driveLeftSlave.follow(self.driveLeftMaster)
self.driveRightSlave.follow(self.driveRightMaster)
# Makes sure both sides' controllers show green and use positive
# values to move the bot forward.
# CURRENTLY DISABLED WHEN USING WITH DifferentialDrive
# self.driveLeftSlave.setInverted(False)
# self.driveLeftMaster.setInverted(False)
self.driveRightSlave.setInverted(True)
self.driveRightMaster.setInverted(True)
# Configures each master to use the attached Mag Encoders
self.driveLeftMaster.configSelectedFeedbackSensor(
ctre.FeedbackDevice.CTRE_MagEncoder_Relative, 0, 0)
self.driveRightMaster.configSelectedFeedbackSensor(
ctre.FeedbackDevice.CTRE_MagEncoder_Relative, 0, 0)
# Reverses the encoder direction so forward movement always
# results in a positive increase in the encoder ticks.
self.driveLeftMaster.setSensorPhase(True)
self.driveRightMaster.setSensorPhase(True)
# Throw data on the SmartDashboard so we can work with it.
SD.putNumber('Left Quad Pos.',
self.driveLeftMaster.getQuadraturePosition())
SD.putNumber('Right Quad Pos.',
self.driveRightMaster.getQuadraturePosition())
# these may give the derivitive an integral of the PID once
# they are set. For now, they just show 0
SD.putNumber('Left Derivative',
self.driveLeftMaster.getErrorDerivative(0))
SD.putNumber('Left Integral',
self.driveLeftMaster.getIntegralAccumulator(0))
self.leftVel = None
self.leftPos = None
self.rightVel = None
self.rightPos = None
# self.driveLeftMaster.config_kP(0, .3, 10)
# kP = self.driveLeftMaster.configGetParameter(
# self.driveLeftMaster.ParamEnum.eProfileParamSlot_P, 0, 10)
# SmartDashboard.putNumber('Left Proportional', kP)
self.driveControllerLeft = SpeedControllerGroup(self.driveLeftMaster)
self.driveControllerRight = SpeedControllerGroup(self.driveRightMaster)
self.driveControllerRight.setInverted(True)
self.drive = DifferentialDrive(self.driveControllerLeft,
self.driveControllerRight)
def moveToPosition(self, position, side='left'):
if side == 'left':
self.driveLeftMaster.setSafetyEnabled(False)
self.driveLeftMaster.set(Talon.ControlMode.Position, position)
else:
self.driveRightMaster.set(Talon.ControlMode.Position, position)
def stop(self):
# self.driveLeftMaster.set(0)
# self.driveRightMaster.set(0)
self.drive.stopMotor()
def arcade(self, speed, rotation):
self.updateSD()
self.drive.arcadeDrive(speed, rotation, True)
def updateSD(self):
leftVel = self.driveLeftMaster.getSelectedSensorVelocity(0)
leftPos = self.driveLeftMaster.getSelectedSensorPosition(0)
rightVel = self.driveRightMaster.getSelectedSensorVelocity(0)
rightPos = self.driveRightMaster.getSelectedSensorPosition(0)
# calculate side deltas
if self.leftVel:
leftVelDelta = leftVel - self.leftVel
else:
leftVelDelta = 0
if self.leftPos:
leftPosDelta = leftPos - self.leftPos
else:
leftPosDelta = 0
if self.rightVel:
rightVelDelta = rightVel - self.rightVel
else:
rightVelDelta = 0
if self.rightPos:
rightPosDelta = rightPos - self.rightPos
else:
rightPosDelta = 0
# calculate delta of delta
differenceVel = leftVelDelta - rightVelDelta
differencePos = leftPosDelta - rightPosDelta
SD.putNumber("LeftSensorVel", leftVel)
SD.putNumber("LeftSensorPos", leftPos)
SD.putNumber("RightSensorVel", rightVel)
SD.putNumber("RightSensorPos", rightPos)
SD.putNumber('LeftVelDelta', leftVelDelta)
SD.putNumber('LeftPosDelta', leftPosDelta)
SD.putNumber('RightVelDelta', rightVelDelta)
SD.putNumber('RightPosDelta', rightPosDelta)
SD.putNumber('DifferenceVel', differenceVel)
SD.putNumber('DifferencePos', differencePos)
self.leftVel = leftVel
self.leftPos = leftPos
self.rightVel = rightVel
self.rightPos = rightPos
class DriveTrain(Subsystem):
'''
'Tank Drive' system set up with 2 motors per side, one a "master"
with a mag encoder attached and the other "slave" controller set
to follow the "master".
'''
def __init__(self, robot):
self.robot = robot
# Initialize all controllers
self.driveLeftMaster = Talon(self.robot.kDriveTrain['left_master'])
self.driveLeftSlave = Talon(self.robot.kDriveTrain['left_slave'])
self.driveRightMaster = Talon(self.robot.kDriveTrain['right_master'])
self.driveRightSlave = Talon(self.robot.kDriveTrain['right_slave'])
wpilib.LiveWindow.addActuator("DriveTrain", "LeftMaster",
self.driveLeftMaster)
wpilib.LiveWindow.addActuator("DriveTrain", "RightMaster",
self.driveRightMaster)
# Connect the slaves to the masters on each side
self.driveLeftSlave.follow(self.driveLeftMaster)
self.driveRightSlave.follow(self.driveRightMaster)
# Makes sure both sides' controllers show green and use positive
# values to move the bot forward.
self.driveLeftSlave.setInverted(False)
self.driveLeftMaster.setInverted(False)
self.driveRightSlave.setInverted(True)
self.driveRightMaster.setInverted(True)
# Configures each master to use the attached Mag Encoders
self.driveLeftMaster.configSelectedFeedbackSensor(
ctre.talonsrx.TalonSRX.FeedbackDevice.CTRE_MagEncoder_Relative, 0,
0)
self.driveRightMaster.configSelectedFeedbackSensor(
ctre.talonsrx.TalonSRX.FeedbackDevice.CTRE_MagEncoder_Relative, 0,
0)
# Reverses the encoder direction so forward movement always
# results in a positive increase in the encoder ticks.
self.driveLeftMaster.setSensorPhase(True)
self.driveRightMaster.setSensorPhase(True)
self.driveLeftMaster.setQuadraturePosition(0, 0)
self.driveRightMaster.setQuadraturePosition(0, 0)
# Throw data on the SmartDashboard so we can work with it.
# SD.putNumber(
# 'Left Quad Pos.',
# self.driveLeftMaster.getQuadraturePosition())
# SD.putNumber(
# 'Right Quad Pos.',
# self.driveRightMaster.getQuadraturePosition())
self.leftVel = None
self.leftPos = None
self.rightVel = None
self.rightPos = None
self.leftMaxVel = 0
self.rightMaxVel = 0
# self.driveLeftMaster.config_kP(0, .3, 10)
self.driveControllerLeft = SpeedControllerGroup(self.driveLeftMaster)
self.driveControllerRight = SpeedControllerGroup(self.driveRightMaster)
self.driveControllerRight.setInverted(True)
self.drive = DifferentialDrive(self.driveControllerLeft,
self.driveControllerRight)
# self.drive = DifferentialDrive(self.driveLeftMaster,
# self.driveRightMaster)
wpilib.LiveWindow.addActuator("DriveTrain", "Left Master",
self.driveLeftMaster)
wpilib.LiveWindow.addActuator("DriveTrain", "Right Master",
self.driveRightMaster)
#wpilib.LiveWindow.add(self.driveLeftSlave)
#wpilib.LiveWindow.add(self.driveRightSlave)
#wpilib.Sendable.setName(self.drive, 'Drive')
#wpilib.LiveWindow.add(self.drive)
#wpilib.Sendable.setName(self.driveLeftMaster, 'driveLeftMaster')
#wpilib.LiveWindow.add(self.driveRightMaster)
super().__init__()
def moveToPosition(self, position, side='left'):
if side == 'left':
self.driveLeftMaster.setSafetyEnabled(False)
self.driveLeftMaster.set(
ctre.talonsrx.TalonSRX.ControlMode.Position, position)
else:
self.driveRightMaster.set(
ctre.talonsrx.TalonSRX.ControlMode.Position, position)
def stop(self):
self.drive.stopMotor()
def arcade(self, speed, rotation):
self.updateSD()
self.drive.arcadeDrive(speed, rotation, True)
def updateSD(self):
leftVel = self.driveLeftMaster.getSelectedSensorVelocity(0)
leftPos = self.driveLeftMaster.getSelectedSensorPosition(0)
rightVel = self.driveRightMaster.getSelectedSensorVelocity(0)
rightPos = self.driveRightMaster.getSelectedSensorPosition(0)
# keep the biggest velocity values
if self.leftMaxVel < leftVel:
self.leftMaxVel = leftVel
if self.rightMaxVel < rightVel:
self.rightMaxVel = rightVel
# calculate side deltas
if self.leftVel:
leftVelDelta = leftVel - self.leftVel
else:
leftVelDelta = 0
if self.leftPos:
leftPosDelta = leftPos - self.leftPos
else:
leftPosDelta = 0
if self.rightVel:
rightVelDelta = rightVel - self.rightVel
else:
rightVelDelta = 0
if self.rightPos:
rightPosDelta = rightPos - self.rightPos
else:
rightPosDelta = 0
# calculate delta of delta
differenceVel = leftVelDelta - rightVelDelta
differencePos = leftPosDelta - rightPosDelta
SD.putNumber("LeftSensorVel", leftVel)
SD.putNumber("LeftSensorPos", leftPos)
SD.putNumber("RightSensorVel", rightVel)
SD.putNumber("RightSensorPos", rightPos)
SD.putNumber('LeftVelDelta', leftVelDelta)
SD.putNumber('LeftPosDelta', leftPosDelta)
SD.putNumber('RightVelDelta', rightVelDelta)
SD.putNumber('RightPosDelta', rightPosDelta)
SD.putNumber('DifferenceVel', differenceVel)
SD.putNumber('DifferencePos', differencePos)
SD.putNumber('Left Max Vel', self.leftMaxVel)
SD.putNumber('Right Max Vel', self.rightMaxVel)
self.leftVel = leftVel
self.leftPos = leftPos
self.rightVel = rightVel
self.rightPos = rightPos
class DriveTrain(Subsystem):
'''
'Tank Drive' system set up with 2 motors per side, one a "master"
with a mag encoder attached and the other "slave" controller set
to follow the "master".
'''
def __init__(self, robot):
self.robot = robot
# Initialize all controllers
self.driveLeftMaster = Talon(self.robot.kDriveTrain['left_master'])
self.driveLeftSlave = Talon(self.robot.kDriveTrain['left_slave'])
self.driveRightMaster = Talon(self.robot.kDriveTrain['right_master'])
self.driveRightSlave = Talon(self.robot.kDriveTrain['right_slave'])
wpilib.LiveWindow.addActuator("DriveTrain", "LeftMaster",
self.driveLeftMaster)
wpilib.LiveWindow.addActuator("DriveTrain", "RightMaster",
self.driveRightMaster)
# Connect the slaves to the masters on each side
self.driveLeftSlave.follow(self.driveLeftMaster)
self.driveRightSlave.follow(self.driveRightMaster)
# Makes sure both sides' controllers show green and use positive
# values to move the bot forward.
self.driveLeftSlave.setInverted(False)
self.driveLeftMaster.setInverted(False)
self.driveRightSlave.setInverted(True)
self.driveRightMaster.setInverted(True)
"""
Initializes the count for toggling which side of the
robot will be considered the front when driving.
"""
self.robotFrontToggleCount = 2
# Configures each master to use the attached Mag Encoders
self.driveLeftMaster.configSelectedFeedbackSensor(
ctre.talonsrx.TalonSRX.FeedbackDevice.CTRE_MagEncoder_Relative, 0,
0)
self.driveRightMaster.configSelectedFeedbackSensor(
ctre.talonsrx.TalonSRX.FeedbackDevice.CTRE_MagEncoder_Relative, 0,
0)
# Reverses the encoder direction so forward movement always
# results in a positive increase in the encoder ticks.
self.driveLeftMaster.setSensorPhase(True)
self.driveRightMaster.setSensorPhase(True)
# these supposedly aren't part of the WPI_TalonSRX class
# self.driveLeftMaster.setSelectedSensorPostion(0, 0, 10)
# self.driveRightMaster.setSelectedSensorPosition(0, 0, 10)
# Throw data on the SmartDashboard so we can work with it.
# SD.putNumber(
# 'Left Quad Pos.',
# self.driveLeftMaster.getQuadraturePosition())
# SD.putNumber(
# 'Right Quad Pos.',
# self.driveRightMaster.getQuadraturePosition())
self.leftVel = None
self.leftPos = None
self.rightVel = None
self.rightPos = None
self.leftMaxVel = 0
self.rightMaxVel = 0
self.leftMinVel = 0
self.rightMinVel = 0
# self.driveLeftMaster.config_kP(0, .3, 10)
self.driveControllerLeft = SpeedControllerGroup(self.driveLeftMaster)
self.driveControllerRight = SpeedControllerGroup(self.driveRightMaster)
self.driveControllerRight.setInverted(True)
self.drive = DifferentialDrive(self.driveControllerLeft,
self.driveControllerRight)
super().__init__()
def moveToPosition(self, position, side='left'):
if side == 'left':
self.driveLeftMaster.setSafetyEnabled(False)
self.driveLeftMaster.set(
ctre.talonsrx.TalonSRX.ControlMode.Position, position)
else:
self.driveRightMaster.set(
ctre.talonsrx.TalonSRX.ControlMode.Position, position)
def stop(self):
self.drive.stopMotor()
def arcade(self, speed, rotation):
self.updateSD()
if self.robot.dStick.getRawButtonReleased(3):
self.robotFrontToggleCount += 1
"""
This if statement acts as a toggle to change which motors are
inverted, completely changing the "front" of the robot. This is
useful for when we are about to climb.
"""
if self.robotFrontToggleCount % 2 == 0:
self.drive.arcadeDrive(speed, rotation, True)
else:
self.drive.arcadeDrive(-speed, rotation, True)
def arcadeWithRPM(self, speed, rotation, maxRPM):
if self.robot.dStick.getRawButtonReleased(3):
self.robotFrontToggleCount += 1
self.driveLeftMaster.setSafetyEnabled(False)
XSpeed = wpilib.RobotDrive.limit(speed)
XSpeed = self.applyDeadband(XSpeed, .02)
ZRotation = wpilib.RobotDrive.limit(rotation)
ZRotation = self.applyDeadband(ZRotation, .02)
if self.robotFrontToggleCount % 2 == 1:
XSpeed = -XSpeed
XSpeed = math.copysign(XSpeed * XSpeed, XSpeed)
ZRotation = math.copysign(ZRotation * ZRotation, ZRotation)
maxInput = math.copysign(max(abs(XSpeed), abs(ZRotation)), XSpeed)
if XSpeed >= 0.0:
if ZRotation >= 0.0:
leftMotorSpeed = maxInput
rightMotorSpeed = XSpeed - ZRotation
else:
leftMotorSpeed = XSpeed + ZRotation
rightMotorSpeed = maxInput
else:
if ZRotation >= 0.0:
leftMotorSpeed = XSpeed + ZRotation
rightMotorSpeed = maxInput
else:
leftMotorSpeed = maxInput
rightMotorSpeed = XSpeed - ZRotation
leftMotorSpeed = wpilib.RobotDrive.limit(leftMotorSpeed)
rightMotorSpeed = wpilib.RobotDrive.limit(rightMotorSpeed)
leftMotorRPM = leftMotorSpeed * maxRPM
rightMotorRPM = rightMotorSpeed * maxRPM
self.driveLeftMaster.set(ctre.talonsrx.TalonSRX.ControlMode.Velocity,
leftMotorRPM)
self.driveRightMaster.set(ctre.talonsrx.TalonSRX.ControlMode.Velocity,
rightMotorRPM)
def updateSD(self):
leftVel = self.driveLeftMaster.getSelectedSensorVelocity(0)
leftPos = self.driveLeftMaster.getSelectedSensorPosition(0)
rightVel = self.driveRightMaster.getSelectedSensorVelocity(0)
rightPos = self.driveRightMaster.getSelectedSensorPosition(0)
# keep the biggest velocity values
if self.leftMaxVel < leftVel:
self.leftMaxVel = leftVel
if self.rightMaxVel < rightVel:
self.rightMaxVel = rightVel
# keep the smallest velocity values
if self.leftMinVel > leftVel:
self.leftMinVel = leftVel
if self.rightMinVel > rightVel:
self.rightMinVel = rightVel
# calculate side deltas
if self.leftVel:
leftVelDelta = leftVel - self.leftVel
else:
leftVelDelta = 0
if self.leftPos:
leftPosDelta = leftPos - self.leftPos
else:
leftPosDelta = 0
if self.rightVel:
rightVelDelta = rightVel - self.rightVel
else:
rightVelDelta = 0
if self.rightPos:
rightPosDelta = rightPos - self.rightPos
else:
rightPosDelta = 0
# calculate delta of delta
differenceVel = leftVelDelta - rightVelDelta
differencePos = leftPosDelta - rightPosDelta
SD.putNumber("LeftSensorVel", leftVel)
SD.putNumber("LeftSensorPos", leftPos)
SD.putNumber("RightSensorVel", rightVel)
SD.putNumber("RightSensorPos", rightPos)
SD.putNumber('LeftVelDelta', leftVelDelta)
SD.putNumber('LeftPosDelta', leftPosDelta)
SD.putNumber('RightVelDelta', rightVelDelta)
SD.putNumber('RightPosDelta', rightPosDelta)
SD.putNumber('DifferenceVel', differenceVel)
SD.putNumber('DifferencePos', differencePos)
SD.putNumber('Left Max Vel', self.leftMaxVel)
SD.putNumber('Right Max Vel', self.rightMaxVel)
SD.putNumber('Left Min Vel', self.leftMinVel)
SD.putNumber('Right Min Vel', self.rightMinVel)
self.leftVel = leftVel
self.leftPos = leftPos
self.rightVel = rightVel
self.rightPos = rightPos
# kP = self.driveLeftMaster.configGetParameter(
# self.driveLeftMaster.ParamEnum.eProfileParamSlot_P, 0, 10)
# SmartDashboard.putNumber('Left Proportional', kP)
# these may give the derivitive an integral of the PID once
# they are set. For now, they just show 0
#SD.putNumber(
# 'Left Derivative',
# self.driveLeftMaster.getErrorDerivative(0))
#SD.putNumber(
# 'Left Integral',
# self.driveLeftMaster.getIntegralAccumulator(0))
def applyDeadband(self, value, deadband):
"""Returns 0.0 if the given value is within the specified range around zero. The remaining range
between the deadband and 1.0 is scaled from 0.0 to 1.0.
:param value: value to clip
:param deadband: range around zero
"""
if abs(value) > deadband:
if value < 0.0:
return (value - deadband) / (1.0 - deadband)
else:
return (value + deadband) / (1.0 - deadband)
return 0.0
class DriveTrain(Subsystem):
'''
'Tank Drive' system set up with 2 motors per side, one a "master"
with a mag encoder attached and the other "slave" controller set
to follow the "master".
'''
def __init__(self, robot):
self.robot = robot
self.ahrs = AHRS.create_spi()
self.ahrs.reset()
# self.angleAdjustment = self.ahrs.getAngle()
# self.ahrs.setAngleAdjustment(self.angleAdjustment)
# Initialize all controllers
self.driveLeftMaster = Talon(self.robot.kDriveTrain['left_master'])
self.driveLeftSlave = Talon(self.robot.kDriveTrain['left_slave'])
self.driveRightMaster = Talon(self.robot.kDriveTrain['right_master'])
self.driveRightSlave = Talon(self.robot.kDriveTrain['right_slave'])
wpilib.LiveWindow.addActuator("DriveTrain", "LeftMaster",
self.driveLeftMaster)
wpilib.LiveWindow.addActuator("DriveTrain", "RightMaster",
self.driveRightMaster)
# Connect the slaves to the masters on each side
self.driveLeftSlave.follow(self.driveLeftMaster)
self.driveRightSlave.follow(self.driveRightMaster)
self.driveLeftMaster.configNominalOutputForward(0, 0)
self.driveLeftMaster.configNominalOutputReverse(0, 0)
self.driveRightMaster.configNominalOutputForward(0, 0)
self.driveRightMaster.configNominalOutputReverse(0, 0)
self.speed = .4
self.driveLeftMaster.configPeakOutputForward(self.speed, 0)
self.driveLeftMaster.configPeakOutputReverse(-self.speed, 0)
self.driveRightMaster.configPeakOutputForward(self.speed, 0)
self.driveRightMaster.configPeakOutputReverse(-self.speed, 0)
self.driveLeftMaster.configClosedLoopRamp(.2, 0)
self.driveRightMaster.configClosedLoopRamp(.2, 0)
self.driveLeftMaster.setSafetyEnabled(False)
self.driveRightMaster.setSafetyEnabled(False)
# Makes sure both sides' controllers show green and use positive
# values to move the bot forward.
self.driveLeftSlave.setInverted(False)
self.driveLeftMaster.setInverted(False)
self.driveRightSlave.setInverted(True)
self.driveRightMaster.setInverted(True)
self.PID()
"""
Initializes the count for toggling which side of the
robot will be considered the front when driving.
"""
self.robotFrontToggleCount = 2
# Configures each master to use the attached Mag Encoders
self.driveLeftMaster.configSelectedFeedbackSensor(
ctre.talonsrx.TalonSRX.FeedbackDevice.CTRE_MagEncoder_Relative, 0,
0)
self.driveRightMaster.configSelectedFeedbackSensor(
ctre.talonsrx.TalonSRX.FeedbackDevice.CTRE_MagEncoder_Relative, 0,
0)
# Reverses the encoder direction so forward movement always
# results in a positive increase in the encoder ticks.
self.driveLeftMaster.setSensorPhase(True)
self.driveRightMaster.setSensorPhase(True)
self.driveLeftMaster.setSelectedSensorPosition(0, 0, 0)
self.driveRightMaster.setSelectedSensorPosition(0, 0, 0)
# these supposedly aren't part of the WPI_TalonSRX class
# self.driveLeftMaster.setSelectedSensorPostion(0, 0, 10)
# self.driveRightMaster.setSelectedSensorPosition(0, 0, 10)
# Throw data on the SmartDashboard so we can work with it.
# SD.putNumber(
# 'Left Quad Pos.',
# self.driveLeftMaster.getQuadraturePosition())
# SD.putNumber(
# 'Right Quad Pos.',
# self.driveRightMaster.getQuadraturePosition())
self.leftVel = None
self.leftPos = None
self.rightVel = None
self.rightPos = None
# self.driveLeftMaster.config_kP(0, .3, 10)
self.driveControllerLeft = SpeedControllerGroup(self.driveLeftMaster)
self.driveControllerRight = SpeedControllerGroup(self.driveRightMaster)
self.driveControllerRight.setInverted(True)
self.drive = DifferentialDrive(self.driveControllerLeft,
self.driveControllerRight)
self.drive.setSafetyEnabled(False)
self.previousError = 0
super().__init__()
def autoInit(self):
self.speed = .5
self.driveLeftMaster.configPeakOutputForward(self.speed, 0)
self.driveLeftMaster.configPeakOutputReverse(-self.speed, 0)
self.driveRightMaster.configPeakOutputForward(self.speed, 0)
self.driveRightMaster.configPeakOutputReverse(-self.speed, 0)
self.driveLeftMaster.config_kP(0, .115, 0)
self.driveRightMaster.config_kP(0, .115, 0)
# self.driveLeftMaster.config_kP(0, .185, 0)
# self.driveRightMaster.config_kP(0, .185, 0)
# self.driveLeftMaster.config_kP(0, 20, 0)
# self.driveRightMaster.config_kP(0, 20, 0)
self.driveLeftMaster.config_kF(0, 0.0, 0)
self.driveRightMaster.config_kF(0, 0.0, 0)
def teleInit(self):
self.speed = .55
self.driveLeftMaster.configPeakOutputForward(self.speed, 0)
self.driveLeftMaster.configPeakOutputReverse(-self.speed, 0)
self.driveRightMaster.configPeakOutputForward(self.speed, 0)
self.driveRightMaster.configPeakOutputReverse(-self.speed, 0)
self.driveLeftMaster.config_kP(0, 0.0, 0)
self.driveRightMaster.config_kP(0, 0.0, 0)
self.driveLeftMaster.config_kF(0, 0.313, 0)
self.driveRightMaster.config_kF(0, 0.313, 0)
def moveToPosition(self, position):
self.driveLeftMaster.set(ctre.talonsrx.TalonSRX.ControlMode.Position,
position)
self.driveRightMaster.set(ctre.talonsrx.TalonSRX.ControlMode.Position,
position)
def stop(self):
self.drive.stopMotor()
def arcade(self, speed, rotation):
# self.updateSD()
if self.robot.dStick.getRawButtonReleased(3):
self.robotFrontToggleCount += 1
"""
This if statement acts as a toggle to change which motors are
inverted, completely changing the "front" of the robot. This is
useful for when we are about to climb.
"""
if self.robotFrontToggleCount % 2 == 0:
self.drive.arcadeDrive(speed, rotation, True)
else:
self.drive.arcadeDrive(-speed, rotation, True)
def arcadeWithRPM(self, speed, rotation, maxRPM):
# self.updateSD()
self.driveLeftMaster.setSafetyEnabled(False)
if self.robot.dStick.getRawButtonReleased(3):
self.robotFrontToggleCount += 1
if self.robotFrontToggleCount % 2 == 0:
XSpeed = wpilib.RobotDrive.limit(speed)
else:
XSpeed = wpilib.RobotDrive.limit(-speed)
XSpeed = self.applyDeadband(XSpeed, .02)
ZRotation = wpilib.RobotDrive.limit(rotation)
ZRotation = self.applyDeadband(ZRotation, .02)
XSpeed = math.copysign(XSpeed * XSpeed, XSpeed)
ZRotation = math.copysign(ZRotation * ZRotation, ZRotation)
maxInput = math.copysign(max(abs(XSpeed), abs(ZRotation)), XSpeed)
if XSpeed >= 0.0:
if ZRotation >= 0.0:
leftMotorSpeed = maxInput
rightMotorSpeed = XSpeed - ZRotation
else:
leftMotorSpeed = XSpeed + ZRotation
rightMotorSpeed = maxInput
else:
if ZRotation >= 0.0:
leftMotorSpeed = XSpeed + ZRotation
rightMotorSpeed = maxInput
else:
leftMotorSpeed = maxInput
rightMotorSpeed = XSpeed - ZRotation
leftMotorSpeed = wpilib.RobotDrive.limit(leftMotorSpeed)
rightMotorSpeed = wpilib.RobotDrive.limit(rightMotorSpeed)
leftMotorRPM = leftMotorSpeed * maxRPM
rightMotorRPM = rightMotorSpeed * maxRPM
self.driveLeftMaster.set(ctre.talonsrx.TalonSRX.ControlMode.Velocity,
leftMotorRPM)
self.driveRightMaster.set(ctre.talonsrx.TalonSRX.ControlMode.Velocity,
rightMotorRPM)
def updateSD(self):
leftVel = self.driveLeftMaster.getSelectedSensorVelocity(0)
leftPos = self.driveLeftMaster.getSelectedSensorPosition(0)
rightVel = self.driveRightMaster.getSelectedSensorVelocity(0)
rightPos = self.driveRightMaster.getSelectedSensorPosition(0)
# calculate side deltas
if self.leftVel:
leftVelDelta = leftVel - self.leftVel
else:
leftVelDelta = 0
if self.leftPos:
leftPosDelta = leftPos - self.leftPos
else:
leftPosDelta = 0
if self.rightVel:
rightVelDelta = rightVel - self.rightVel
else:
rightVelDelta = 0
if self.rightPos:
rightPosDelta = rightPos - self.rightPos
else:
rightPosDelta = 0
# calculate delta of delta
differenceVel = leftVelDelta - rightVelDelta
differencePos = leftPosDelta - rightPosDelta
SD.putNumber("LeftSensorVel", leftVel)
SD.putNumber("LeftSensorPos", leftPos)
SD.putNumber("RightSensorVel", rightVel)
SD.putNumber("RightSensorPos", rightPos)
SD.putNumber('LeftVelDelta', leftVelDelta)
SD.putNumber('LeftPosDelta', leftPosDelta)
SD.putNumber('RightVelDelta', rightVelDelta)
SD.putNumber('RightPosDelta', rightPosDelta)
SD.putNumber('DifferenceVel', differenceVel)
SD.putNumber('DifferencePos', differencePos)
SD.putNumber('Angle', self.ahrs.getAngle())
SD.putNumber('Angle Adjustment', self.ahrs.getAngleAdjustment())
self.leftVel = leftVel
self.leftPos = leftPos
self.rightVel = rightVel
self.rightPos = rightPos
# kP = self.driveLeftMaster.configGetParameter(
# self.driveLeftMaster.ParamEnum.eProfileParamSlot_P, 0, 10)
# SmartDashboard.putNumber('Left Proportional', kP)
# these may give the derivitive an integral of the PID once
# they are set. For now, they just show 0
#SD.putNumber(
# 'Left Derivative',
# self.driveLeftMaster.getErrorDerivative(0))
#SD.putNumber(
# 'Left Integral',
# self.driveLeftMaster.getIntegralAccumulator(0))
def applyDeadband(self, value, deadband):
"""Returns 0.0 if the given value is within the specified range around zero. The remaining range
between the deadband and 1.0 is scaled from 0.0 to 1.0.
:param value: value to clip
:param deadband: range around zero
"""
if abs(value) > deadband:
if value < 0.0:
return (value - deadband) / (1.0 - deadband)
else:
return (value + deadband) / (1.0 - deadband)
return 0.0
def setAngle(self, angle, tolerance):
#self.tolerance = tolerance
#self.calculateAdjustedSetpoint(angle)
self.turnController.setSetpoint(angle)
if ((self.ahrs.getYaw() <= (angle + tolerance))
and (self.ahrs.getYaw() >= (angle - tolerance))):
self.turnController.disable()
self.driveLeftMaster.set(0)
self.driveRightMaster.set(0)
else:
self.turnController.enable()
self.drive.arcadeDrive(0, self.output)
#self.leftTurnController.setSetpoint(angle)
def isInGyroPosition(self):
SD.putNumber('Is in gyro position',
((self.ahrs.getYaw() <=
(self.turnController.getSetpoint() +
self.robot.autonomous.ANGLE_TOLERANCE)) and
(self.ahrs.getYaw() >=
(self.turnController.getSetpoint() -
self.robot.autonomous.ANGLE_TOLERANCE))))
return ((self.ahrs.getYaw() <= (self.turnController.getSetpoint() +
self.robot.autonomous.ANGLE_TOLERANCE))
and (self.ahrs.getYaw() >=
(self.turnController.getSetpoint() -
self.robot.autonomous.ANGLE_TOLERANCE)))
def calculateAdjustedSetpoint(self, angle):
self.startingYaw = self.robot.autonomous.startingYaw
adjustedAngle = angle + self.startingYaw
if adjustedAngle < -180:
undershot = adjustedAngle + 180
adjustedAngle = 180 + undershot
elif adjustedAngle > 180:
overshot = adjustedAngle - 180
adjustedAngle = -180 + overshot
self.adjustedSetpoint = adjustedAngle
def PID(self):
self.kP = .045
self.kI = 0.00
self.kD = 0.00
self.kF = 0.00
self.turnController = wpilib.PIDController(self.kP,
self.kI,
self.kD,
self.kF,
self.ahrs,
output=self)
self.turnController.setInputRange(-180, 180)
self.turnController.setOutputRange(-0.55, 0.55)
self.turnController.disable()
def pidWrite(self, output):
self.output = output