示例#1
0
class MyRobot(TimedRobot):
    leftMotor: TalonSRX
    rightMotor: TalonSRX

    mySolenoid = Solenoid(0)

    navx = AHRS.create_i2c()

    def robotInit(self):
        self.leftMotor = VictorSPX(0)
        self.rightMotor = TalonSRX("pizza")
    
    def teleopInit(self):
        self.leftMotor.setSpeed(0.3)
        self.rightMotor.setSpeed(0.3)

        self.mySolenoid.set(True)

        angle = self.navx.getAngle()
示例#2
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    def __init__(self):
        self.timer = Timer()
        self.driver_station = DriverStation(controller=XboxController(0))

        # self.gyroscope = AHRS.create_i2c()

        # self.left_encoder = Encoder()
        # self.right_encoder = Encoder()

        self.drivetrain = TankDrivetrain(timer=self.timer, left_motors=[TalonSRX(10), TalonSRX(6)],
                                         right_motors=[TalonSRX(12), TalonSRX(18)])

        self.pneumatics = Pneumatics(compressor=Compressor(0), start_compressor=True, timer=self.timer)

        self.beak = BeakMechanism(beak_solenoid=DoubleSolenoid(0, 4, 5), diag_solenoid=DoubleSolenoid(0, 0, 1),
                                  driver_station=self.driver_station, timer=self.timer, cooldown=0.5)

        # self.odometry = EncoderOdometry(left_encoder=self.left_encoder, right_encoder=self.right_encoder, gyro=self.gyroscope)

        '''
示例#3
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    def init(self):
        self.logger.info("DeepSpaceLift::init()")
        self.timer = wpilib.Timer()
        self.timer.start()

        self.robot_mode = RobotMode.TEST

        self.last_lift_adjust_time = 0
        self.lift_adjust_timer = wpilib.Timer()
        self.lift_adjust_timer.start()

        self.state_timer = wpilib.Timer()
        self.current_state = LiftState.LIFT_START_CONFIGURATION
        self.current_lift_preset = LiftPreset.LIFT_PRESET_STOW
        self.current_lift_preset_val = self.lift_stow_position

        self.lift_setpoint = self.min_lift_position
        self.lift_adjust_val = 0

        self.lift_talon = TalonSRX(robotmap.LIFT_CAN_ID)
        '''Select and zero sensor in init() function.  That way the zero position doesn't get reset every time we enable/disable robot'''
        self.lift_talon.configSelectedFeedbackSensor(FeedbackDevice.Analog, 0,
                                                     robotmap.CAN_TIMEOUT_MS)
        self.lift_talon.setSelectedSensorPosition(0, 0,
                                                  robotmap.CAN_TIMEOUT_MS)

        self.lift_pneumatic_extend = Solenoid(robotmap.PCM1_CANID,
                                              robotmap.LIFT_RAISE_SOLENOID)
        self.lift_pneumatic_retract = Solenoid(robotmap.PCM1_CANID,
                                               robotmap.LIFT_LOWER_SOLENOID)

        self.lift_pneumatic_extend.set(False)
        self.lift_pneumatic_retract.set(True)

        self.test_lift_pneumatic = sendablechooser.SendableChooser()
        self.test_lift_pneumatic.setDefaultOption("Retract", 1)
        self.test_lift_pneumatic.addOption("Extend", 2)

        SmartDashboard.putData("TestLiftPneumatic", self.test_lift_pneumatic)
    def __init__(self):

        super().__init__("Elevator")

        # Initializes the elevator Talon, put it as one for now
        self.elevatorleader = TalonSRX(CAN_ELEVATOR_LEADER)
        set_motor(self.elevatorleader, TalonSRX.NeutralMode.Brake, False)
        self.elevatorleader.configSelectedFeedbackSensor(
            FeedbackDevice.QuadEncoder, 0, 0)
        self.elevatorleader.setSelectedSensorPosition(0, 0, 0)
        self.elevatorleader.setSensorPhase(False)

        self.elevatorfollower = VictorSPX(CAN_ELEVATOR_FOLLOWER)
        set_motor(self.elevatorfollower, TalonSRX.NeutralMode.Brake, False)
        self.elevatorfollower.follow(self.elevatorleader)

        # The preference table is used to get values to the code while the
        # robot is running, useful
        self.prefs = Preferences.getInstance()
        # for tuning the PIDs and stuff

        self.elevator_zero = False

        self.set_values()
    def __init__(self):
        super().__init__("Payload")
        # TODO Two limit switches on the leader
        self.prefs = Preferences.getInstance()

        self.elbowleader = TalonSRX(CAN_ELBOW_LEADER)
        set_motor(self.elbowleader, TalonSRX.NeutralMode.Brake, False)
        self.elbowleader.configSelectedFeedbackSensor(
            FeedbackDevice.QuadEncoder, 0, 0)
        self.elbowleader.setSelectedSensorPosition(0, 0, 0)
        self.elbowleader.selectProfileSlot(0, 0)
        self.elbowleader.setSensorPhase(True)

        self.elbowfollower = VictorSPX(CAN_ELBOW_FOLLOWER)
        set_motor(self.elbowfollower, VictorSPX.NeutralMode.Brake, False)
        self.elbowfollower.follow(self.elbowleader)

        self.baller = TalonSRX(CAN_BALL_INTAKE)
        set_motor(self.baller, TalonSRX.NeutralMode.Brake, False)

        self.elbow_zero = False

        self.DS = DoubleSolenoid(2, 3)
        self.set_values()
示例#6
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    def __init__(
        self,
        name: str,
        steer_talon: ctre.TalonSRX,
        drive_talon: ctre.TalonSRX,
        x_pos: float,
        y_pos: float,
        reverse_steer_direction: bool = False,
        reverse_steer_encoder: bool = True,
        reverse_drive_direction: bool = False,
        reverse_drive_encoder: bool = False,
    ):
        if hal.isSimulation():
            # we aren't using the PID simulation here
            steer_talon._use_notifier = False
            drive_talon._use_notifier = False

        self.name = name

        self.steer_motor = steer_talon
        self.drive_motor = drive_talon
        self.x_pos = x_pos
        self.y_pos = y_pos
        self.dist = math.hypot(self.x_pos, self.y_pos)
        self.angle = math.atan2(self.y_pos, self.x_pos)
        self.reverse_steer_direction = reverse_steer_direction
        self.reverse_steer_encoder = reverse_steer_encoder
        self.reverse_drive_direction = reverse_drive_direction
        self.reverse_drive_encoder = reverse_drive_encoder

        self.steer_enc_offset = self.steer_motor.configGetCustomParam(
            0, timoutMs=10)

        self.nt = NetworkTables.getTable("SwerveDrive").getSubTable(name)
        self.steer_enc_offset_entry = self.nt.getEntry("steer_enc_offset")
        self.steer_enc_offset_entry.setDouble(self.steer_enc_offset)
        self.steer_enc_offset_entry.addListener(
            self.nt_offset_changed, NetworkTables.NotifyFlags.UPDATE)

        self.last_speed = 0.0

        self.update_odometry()

        # NOTE: In all the following config* calls to the drive and steer
        # motors, the last argument is the timeout in milliseconds. See
        # robotpy-ctre documentation for details.

        self.steer_motor.configSelectedFeedbackSensor(
            ctre.FeedbackDevice.CTRE_MagEncoder_Absolute, 0, 10)
        # changes direction of motor encoder
        self.steer_motor.setSensorPhase(self.reverse_steer_encoder)
        # changes sign of motor throttle vilues
        self.steer_motor.setInverted(self.reverse_steer_direction)
        # self.steer_motor.setSelectedSensorPosition(0)

        self.steer_motor.config_kP(0, 1, 10)
        self.steer_motor.config_kI(0, 0.0, 10)
        self.steer_motor.config_kD(0, 0.02, 10)
        self.steer_motor.selectProfileSlot(0, 0)
        self.steer_motor.config_kF(0, 0, 10)

        self.steer_motor.setNeutralMode(ctre.NeutralMode.Coast)

        self.drive_motor.configSelectedFeedbackSensor(
            ctre.FeedbackDevice.QuadEncoder, 0, 10)
        # changes direction of motor encoder
        self.drive_motor.setSensorPhase(self.reverse_drive_encoder)
        # changes sign of motor throttle values
        self.drive_motor.setInverted(self.reverse_drive_direction)
        # Reset drive encoder to 0
        self.drive_motor.setSelectedSensorPosition(0)
        # TODO: change back to original constants once we get on to real robot
        self.drive_motor.config_kP(0, 0.005, 10)
        self.drive_motor.config_kI(0, 0, 10)
        self.drive_motor.config_kD(0, 0, 10)
        self.drive_motor.config_kF(0, 1024.0 / self.DRIVE_FREE_SPEED, 10)
        self.drive_motor.configClosedLoopRamp(0.3, 10)
        self.drive_motor.selectProfileSlot(0, 0)

        self.drive_motor.setNeutralMode(ctre.NeutralMode.Brake)

        self.reset_encoder_delta()

        # self.steer_motor.configPeakCurrentLimit(50, timeoutMs=10)
        # self.steer_motor.configContinuousCurrentLimit(40, timeoutMs=10)
        # self.steer_motor.enableCurrentLimit(True)

        self.drive_motor.configVoltageCompSaturation(9, timeoutMs=10)
        self.drive_motor.configPeakCurrentLimit(50, timeoutMs=10)
        self.drive_motor.configContinuousCurrentLimit(40, timeoutMs=10)
        self.drive_motor.enableCurrentLimit(True)
        self.drive_motor.enableVoltageCompensation(True)
    def createMotor(self, MotorSpec):
        motr = None
        if MotorSpec['ContType'] == 'CAN':
            if MotorSpec['Type'] == 'TalonSRX':
                if MotorSpec['jobType'] == 'master':
                    motr = TalonSRX(MotorSpec['port'])
                elif MotorSpec['jobType'] == 'slave':
                    motr = TalonSRX(MotorSpec['port'])
                    motr.setInverted(MotorSpec['inverted'])
                    motr.set(ctre.ControlMode.Follower, MotorSpec['masterPort'])
            if MotorSpec['Type'] == 'TalonFX':
                if MotorSpec['jobType'] == 'master':
                    motr = TalonFX(MotorSpec['port'])
                elif MotorSpec['jobType'] == 'slave':
                    motr = TalonFX(MotorSpec['port'])
                    motr.setInverted(MotorSpec['inverted'])
                    motr.set(ctre.ControlMode.Follower, MotorSpec['masterPort'])
            if MotorSpec['Type'] == 'VictorSPX':
                if MotorSpec['jobType'] == 'master':
                    motr = VictorSPX(MotorSpec['port'])
                elif MotorSpec['jobType'] == 'slave':
                    motr = VictorSPX(MotorSpec['port'])
                    motr.setInverted(MotorSpec['inverted'])
                    motr.set(ctre.ControlMode.Follower, MotorSpec['masterPort'])
            if MotorSpec['Type'] == 'SparkMax':
                motr = SparkMax(MotorSpec['port'])
        else:
            print("IDK your motor")

        return motr
示例#8
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 def robotInit(self):
     self.leftMotor = VictorSPX(0)
     self.rightMotor = TalonSRX("pizza")
class Elevator(Subsystem):
    """
    For both Hatches and Balls
    """
    def __init__(self):

        super().__init__("Elevator")

        # Initializes the elevator Talon, put it as one for now
        self.elevatorleader = TalonSRX(CAN_ELEVATOR_LEADER)
        set_motor(self.elevatorleader, TalonSRX.NeutralMode.Brake, False)
        self.elevatorleader.configSelectedFeedbackSensor(
            FeedbackDevice.QuadEncoder, 0, 0)
        self.elevatorleader.setSelectedSensorPosition(0, 0, 0)
        self.elevatorleader.setSensorPhase(False)

        self.elevatorfollower = VictorSPX(CAN_ELEVATOR_FOLLOWER)
        set_motor(self.elevatorfollower, TalonSRX.NeutralMode.Brake, False)
        self.elevatorfollower.follow(self.elevatorleader)

        # The preference table is used to get values to the code while the
        # robot is running, useful
        self.prefs = Preferences.getInstance()
        # for tuning the PIDs and stuff

        self.elevator_zero = False

        self.set_values()

    def set_position(self, position):
        if self.elevator_zero:
            self.elevatorleader.set(ControlMode.MotionMagic, position)
        else:
            print("Position Not Set")

    def elevator_speed(self, speed):
        self.elevatorleader.set(ControlMode.PercentOutput, speed)

    def set_values(self):
        # This will set the PIDs, velocity, and acceleration, values from the
        # preference table so we can tune them easily
        #self.elevatorleader.config_kP(0, self.prefs.getFloat("Elevator P", 0.1), 0)
        #self.elevatorleader.config_kI(0, self.prefs.getFloat("Elevator I", 0.0), 0)
        #self.elevatorleader.config_kD(0, self.prefs.getFloat("Elevator D", 0.0), 0)
        #self.elevatorleader.configMotionCruiseVelocity(
        #   int(self.prefs.getInt("Elevator Velocity", 1024)), 0)
        #self.elevatorleader.configMotionAcceleration(
        #   int(self.prefs.getInt("Elevator Acceleration", 1024)), 0)
        self.elevatorleader.config_kP(0, 3.2, 0)
        self.elevatorleader.config_kI(0, 0.0, 0)
        self.elevatorleader.config_kD(0, 0.0, 0)
        self.elevatorleader.configMotionCruiseVelocity(int(1000), 0)
        self.elevatorleader.configMotionAcceleration(int(1000), 0)

    def publish_data(self):
        # This will print the position and velocity to the smartDashboard
        SmartDashboard.putNumber(
            "Elevator Position",
            self.elevatorleader.getSelectedSensorPosition(0))
        #SmartDashboard.putNumber("Elevator Velocity", self.elevatorleader.getSelectedSensorVelocity(0))
        #SmartDashboard.putNumber("Elevator Current", self.elevatorleader.getOutputCurrent())
        #SmartDashboard.putNumber("Elevator Output", self.elevatorleader.getMotorOutputPercent())

    def check_for_zero(self):
        if not self.elevator_zero:
            if self.elevatorleader.isFwdLimitSwitchClosed():
                self.elevatorleader.setSelectedSensorPosition(0, 0, 0)
                self.elevator_zero = True

    def initDefaultCommand(self):
        self.setDefaultCommand(elv_zero())

    def get_position(self):
        return self.elevatorleader.getSelectedSensorPosition(0)
class Payload(Subsystem):
    """
    For both Hatches and Balls
    """
    def __init__(self):
        super().__init__("Payload")
        # TODO Two limit switches on the leader
        self.prefs = Preferences.getInstance()

        self.elbowleader = TalonSRX(CAN_ELBOW_LEADER)
        set_motor(self.elbowleader, TalonSRX.NeutralMode.Brake, False)
        self.elbowleader.configSelectedFeedbackSensor(
            FeedbackDevice.QuadEncoder, 0, 0)
        self.elbowleader.setSelectedSensorPosition(0, 0, 0)
        self.elbowleader.selectProfileSlot(0, 0)
        self.elbowleader.setSensorPhase(True)

        self.elbowfollower = VictorSPX(CAN_ELBOW_FOLLOWER)
        set_motor(self.elbowfollower, VictorSPX.NeutralMode.Brake, False)
        self.elbowfollower.follow(self.elbowleader)

        self.baller = TalonSRX(CAN_BALL_INTAKE)
        set_motor(self.baller, TalonSRX.NeutralMode.Brake, False)

        self.elbow_zero = False

        self.DS = DoubleSolenoid(2, 3)
        self.set_values()

    def initDefaultCommand(self):
        self.setDefaultCommand(BallZ())

    def set_wheels_speed(self, speed):
        self.baller.set(ControlMode.PercentOutput, speed)
        #print(speed)

    def hatch_punch_out(self):
        subsystems.SERIAL.fire_event('Punch It')
        self.DS.set(DoubleSolenoid.Value.kForward)

    def hatch_punch_in(self):
        self.DS.set(DoubleSolenoid.Value.kReverse)

    def set_position(self, pos):
        if self.elbow_zero:
            self.elbowleader.set(mode=ControlMode.MotionMagic, demand0=pos)
        else:
            print("Elbow Not Set")

    def set_speed(self, speed):
        self.elbowleader.set(mode=ControlMode.PercentOutput, demand0=speed)

    def set_values(self):
        self.elbowleader.config_kP(0, 0.8, 0)
        self.elbowleader.config_kI(0, 0.0, 0)
        self.elbowleader.config_kD(0, 0.0, 0)
        self.elbowleader.configMotionCruiseVelocity(int(200), 0)
        self.elbowleader.configMotionAcceleration(int(200), 0)

    def get_position(self):
        return self.elbowleader.getSelectedSensorPosition(0)

    def check_for_zero(self):
        if not self.elbow_zero:
            if self.elbowleader.isRevLimitSwitchClosed():
                self.elbowleader.setSelectedSensorPosition(0, 0, 0)
                self.elbow_zero = True

    def publish_data(self):
        #print(self.elbowleader.getSelectedSensorPosition(0))
        SmartDashboard.putNumber("elbowPosition",
                                 self.elbowleader.getSelectedSensorPosition(0))
示例#11
0
class DeepSpaceLift():
    min_lift_position = ntproperty("/LiftSettings/MinLiftPosition",
                                   75,
                                   persistent=True)
    max_lift_position = ntproperty("/LiftSettings/MaxLiftPosition",
                                   225,
                                   persistent=True)
    max_lift_adjust_rate = ntproperty("/LiftSettings/MaxLiftAdjustRate",
                                      10,
                                      persistent=True)
    max_lift_adjust_value = ntproperty("/LiftSettings/MaxLiftAdjustValue",
                                       15,
                                       persistent=True)

    lift_stow_position = ntproperty("/LiftSettings/LiftStowPosition",
                                    90,
                                    persistent=True)

    lift_front_port_low = ntproperty("/LiftSettings/LiftFrontPortLow",
                                     150,
                                     persistent=True)
    lift_front_port_middle = ntproperty("/LiftSettings/LiftFrontPortMiddle",
                                        175,
                                        persistent=True)
    lift_front_port_high = ntproperty("/LiftSettings/LiftFrontPortHigh",
                                      200,
                                      persistent=True)

    lift_side_hatch_low = ntproperty("/LiftSettings/LiftSideHatchLow",
                                     135,
                                     persistent=True)
    lift_side_hatch_middle = ntproperty("/LiftSettings/LiftSideHatchMiddle",
                                        160,
                                        persistent=True)
    lift_side_hatch_high = ntproperty("/LiftSettings/LiftSideHatchHigh",
                                      185,
                                      persistent=True)

    on_target = False

    def __init__(self, logger):
        self.logger = logger

    def init(self):
        self.logger.info("DeepSpaceLift::init()")
        self.timer = wpilib.Timer()
        self.timer.start()

        self.robot_mode = RobotMode.TEST

        self.last_lift_adjust_time = 0
        self.lift_adjust_timer = wpilib.Timer()
        self.lift_adjust_timer.start()

        self.state_timer = wpilib.Timer()
        self.current_state = LiftState.LIFT_START_CONFIGURATION
        self.current_lift_preset = LiftPreset.LIFT_PRESET_STOW
        self.current_lift_preset_val = self.lift_stow_position

        self.lift_setpoint = self.min_lift_position
        self.lift_adjust_val = 0

        self.lift_talon = TalonSRX(robotmap.LIFT_CAN_ID)
        '''Select and zero sensor in init() function.  That way the zero position doesn't get reset every time we enable/disable robot'''
        self.lift_talon.configSelectedFeedbackSensor(FeedbackDevice.Analog, 0,
                                                     robotmap.CAN_TIMEOUT_MS)
        self.lift_talon.setSelectedSensorPosition(0, 0,
                                                  robotmap.CAN_TIMEOUT_MS)

        self.lift_pneumatic_extend = Solenoid(robotmap.PCM1_CANID,
                                              robotmap.LIFT_RAISE_SOLENOID)
        self.lift_pneumatic_retract = Solenoid(robotmap.PCM1_CANID,
                                               robotmap.LIFT_LOWER_SOLENOID)

        self.lift_pneumatic_extend.set(False)
        self.lift_pneumatic_retract.set(True)

        self.test_lift_pneumatic = sendablechooser.SendableChooser()
        self.test_lift_pneumatic.setDefaultOption("Retract", 1)
        self.test_lift_pneumatic.addOption("Extend", 2)

        SmartDashboard.putData("TestLiftPneumatic", self.test_lift_pneumatic)

    def config(self, simulation):
        self.logger.info("DeepSpaceLift::config()")
        '''Generic config'''
        self.lift_talon.configNominalOutputForward(0.0,
                                                   robotmap.CAN_TIMEOUT_MS)
        self.lift_talon.configNominalOutputReverse(0.0,
                                                   robotmap.CAN_TIMEOUT_MS)
        self.lift_talon.configPeakOutputForward(1.0, robotmap.CAN_TIMEOUT_MS)
        self.lift_talon.configPeakOutputReverse(-1.0, robotmap.CAN_TIMEOUT_MS)
        self.lift_talon.enableVoltageCompensation(True)
        self.lift_talon.configVoltageCompSaturation(11.5,
                                                    robotmap.CAN_TIMEOUT_MS)
        self.lift_talon.configOpenLoopRamp(0.125, robotmap.CAN_TIMEOUT_MS)
        self.lift_talon.setInverted(True)
        '''sensor config'''
        self.lift_talon.configSelectedFeedbackCoefficient(
            1.0, 0, robotmap.CAN_TIMEOUT_MS)
        self.lift_talon.setSensorPhase(False)
        self.lift_talon.setStatusFramePeriod(StatusFrame.Status_2_Feedback0,
                                             10, robotmap.CAN_TIMEOUT_MS)

    def deploy_lift(self):
        self.current_state = LiftState.LIFT_DEPLOY_BEGIN

    def go_to_preset(self, preset):
        self.lift_adjust_val = 0

        if preset == LiftPreset.LIFT_PRESET_PORT_LOW:
            self.current_lift_preset = LiftPreset.LIFT_PRESET_PORT_LOW
            self.current_lift_preset_val = self.lift_front_port_low
            self.lift_pneumatic_extend.set(False)
            self.lift_pneumatic_retract.set(True)
            self.state_timer.stop()
            self.state_timer.reset()

        elif preset == LiftPreset.LIFT_PRESET_PORT_MIDDLE:
            self.current_lift_preset = LiftPreset.LIFT_PRESET_PORT_MIDDLE
            self.current_lift_preset_val = self.lift_front_port_middle
            self.lift_pneumatic_extend.set(False)
            self.lift_pneumatic_retract.set(True)
            self.state_timer.stop()
            self.state_timer.reset()

        elif preset == LiftPreset.LIFT_PRESET_PORT_HIGH:
            self.current_lift_preset = LiftPreset.LIFT_PRESET_PORT_HIGH
            self.current_lift_preset_val = self.lift_front_port_high
            self.lift_pneumatic_extend.set(True)
            self.lift_pneumatic_retract.set(False)
            self.state_timer.stop()
            self.state_timer.reset()

        elif preset == LiftPreset.LIFT_PRESET_HATCH_LOW:
            self.current_lift_preset = LiftPreset.LIFT_PRESET_HATCH_LOW
            self.current_lift_preset_val = self.lift_side_hatch_low
            self.lift_pneumatic_extend.set(False)
            self.lift_pneumatic_retract.set(True)
            self.state_timer.stop()
            self.state_timer.reset()

        elif preset == LiftPreset.LIFT_PRESET_HATCH_MIDDLE:
            self.current_lift_preset = LiftPreset.LIFT_PRESET_HATCH_MIDDLE
            self.current_lift_preset_val = self.lift_side_hatch_middle
            self.lift_pneumatic_extend.set(False)
            self.lift_pneumatic_retract.set(True)
            self.state_timer.stop()
            self.state_timer.reset()

        elif preset == LiftPreset.LIFT_PRESET_HATCH_HIGH:
            self.current_lift_preset = LiftPreset.LIFT_PRESET_HATCH_HIGH
            self.current_lift_preset_val = self.lift_side_hatch_high
            self.lift_pneumatic_extend.set(True)
            self.lift_pneumatic_retract.set(False)
            self.state_timer.stop()
            self.state_timer.reset()

        elif preset == LiftPreset.LIFT_PRESET_STOW:
            self.current_lift_preset = LiftPreset.LIFT_PRESET_STOW
            self.current_lift_preset_val = self.lift_stow_position
            self.state_timer.reset()
            self.state_timer.start()

    def iterate(self, robot_mode, simulation, pilot_stick, copilot_stick):
        self.robot_mode = robot_mode
        lift_position = self.lift_talon.getAnalogInRaw()

        if lift_position > self.lift_stow_position + 5:
            SmartDashboard.putBoolean("Creep", True)
        else:
            SmartDashboard.putBoolean("Creep", False)

        if robot_mode == RobotMode.TEST:

            if self.test_lift_pneumatic.getSelected() == 1:
                self.lift_pneumatic_extend.set(False)
                self.lift_pneumatic_retract.set(True)
            else:
                self.lift_pneumatic_extend.set(True)
                self.lift_pneumatic_retract.set(False)

            #need to check these separately so we don't disable the mechanism completely if we end up one tick outside our allowable range
            if lift_position > self.min_lift_position or lift_position < self.max_lift_position:
                self.lift_talon.set(
                    ControlMode.PercentOutput,
                    -1.0 * pilot_stick.getRawAxis(robotmap.XBOX_RIGHT_Y_AXIS))
            elif lift_position < self.min_lift_position:
                #allow upward motion
                self.lift_talon.set(
                    ControlMode.PercentOutput,
                    max(
                        -1.0 *
                        pilot_stick.getRawAxis(robotmap.XBOX_RIGHT_Y_AXIS), 0))
            elif lift_position > self.max_lift_position:
                #allow downward motion
                self.lift_talon.set(
                    ControlMode.PercentOutput,
                    min(
                        -1.0 *
                        pilot_stick.getRawAxis(robotmap.XBOX_RIGHT_Y_AXIS), 0))
            else:
                self.lift_talon.set(ControlMode.PercentOutput, 0.0)
        else:
            self.iterate_state_machine(pilot_stick, copilot_stick)

        SmartDashboard.putString("Lift State", self.current_state.name)
        SmartDashboard.putString("Lift Preset", self.current_lift_preset.name)
        SmartDashboard.putNumber("Lift Setpoint", self.lift_setpoint)
        SmartDashboard.putNumber("Lift Position", lift_position)

    def iterate_state_machine(self, pilot_stick, copilot_stick):
        #****************DEPLOY SEQUENCE**************************
        if self.current_state == LiftState.LIFT_DEPLOY_EXTEND_PNEUMATIC:
            self.lift_pneumatic_extend.set(True)
            self.lift_pneumatic_retract.set(False)
            self.state_timer.reset()
            self.state_timer.start()
            self.current_state = LiftState.LIFT_DEPLOY_WAIT1

        elif self.current_state == LiftState.LIFT_DEPLOY_WAIT1:
            if self.state_timer.hasPeriodPassed(0.5):
                self.current_state = LiftState.LIFT_DEPLOY_MOVE_TO_STOW

        elif self.current_state == LiftState.LIFT_DEPLOY_MOVE_TO_STOW:
            self.go_to_preset(LiftPreset.LIFT_PRESET_STOW)
            if self.bang_bang_to_setpoint():
                self.current_state = LiftState.LIFT_DEPLOY_RETRACT_PNEUMATIC

        if self.current_state == LiftState.LIFT_DEPLOY_RETRACT_PNEUMATIC:
            self.lift_pneumatic_extend.set(False)
            self.lift_pneumatic_retract.set(True)
            self.state_timer.reset()
            self.state_timer.start()
            self.current_state = LiftState.LIFT_DEPLOY_WAIT2

        elif self.current_state == LiftState.LIFT_DEPLOY_WAIT2:
            if self.state_timer.hasPeriodPassed(0.25):
                self.current_state = LiftState.LIFT_DEPLOYED

        #****************DEPLOY SEQUENCE**************************

        #****************DEPLOYED*********************************
        elif self.current_state == LiftState.LIFT_DEPLOYED:
            if self.robot_mode == RobotMode.TELE:
                if copilot_stick.LeftBumper().get() and copilot_stick.X().get(
                ):
                    if not self.current_lift_preset == LiftPreset.LIFT_PRESET_PORT_LOW:
                        self.go_to_preset(LiftPreset.LIFT_PRESET_PORT_LOW)
                elif copilot_stick.LeftBumper().get() and copilot_stick.Y(
                ).get():
                    if not self.current_lift_preset == LiftPreset.LIFT_PRESET_PORT_MIDDLE:
                        self.go_to_preset(LiftPreset.LIFT_PRESET_PORT_MIDDLE)
                elif copilot_stick.LeftBumper().get() and copilot_stick.B(
                ).get():
                    if not self.current_lift_preset == LiftPreset.LIFT_PRESET_PORT_HIGH:
                        self.go_to_preset(LiftPreset.LIFT_PRESET_PORT_HIGH)
                elif copilot_stick.RightBumper().get() and copilot_stick.X(
                ).get():
                    if not self.current_lift_preset == LiftPreset.LIFT_PRESET_HATCH_LOW:
                        self.go_to_preset(LiftPreset.LIFT_PRESET_HATCH_LOW)
                elif copilot_stick.RightBumper().get() and copilot_stick.Y(
                ).get():
                    if not self.current_lift_preset == LiftPreset.LIFT_PRESET_HATCH_MIDDLE:
                        self.go_to_preset(LiftPreset.LIFT_PRESET_HATCH_MIDDLE)
                elif copilot_stick.RightBumper().get() and copilot_stick.B(
                ).get():
                    if not self.current_lift_preset == LiftPreset.LIFT_PRESET_HATCH_HIGH:
                        self.go_to_preset(LiftPreset.LIFT_PRESET_HATCH_HIGH)
                else:
                    if not self.current_lift_preset == LiftPreset.LIFT_PRESET_STOW:
                        self.go_to_preset(LiftPreset.LIFT_PRESET_STOW)

            current_lift_adjust_time = self.lift_adjust_timer.get()
            dt = current_lift_adjust_time - self.last_lift_adjust_time
            self.last_lift_adjust_time = current_lift_adjust_time

            if self.bang_bang_to_setpoint():
                max_down_adjust = float(
                    abs(self.current_lift_preset_val -
                        self.lift_stow_position))
                max_up_adjust = float(
                    abs(self.current_lift_preset_val - self.max_lift_position))
                self.lift_adjust_val += dt * self.max_lift_adjust_rate * pilot_stick.RightStickY(
                )
                if self.lift_adjust_val > 0:
                    self.lift_adjust_val = min(self.lift_adjust_val,
                                               self.max_lift_adjust_value)
                else:
                    self.lift_adjust_val = max(self.lift_adjust_val,
                                               -self.max_lift_adjust_value)
                self.lift_adjust_val = max(
                    min(self.lift_adjust_val, max_up_adjust), -max_down_adjust)

        #****************DEPLOYED*********************************

    def bang_bang_to_setpoint(self):
        if self.current_lift_preset == LiftPreset.LIFT_PRESET_STOW and (
                self.state_timer.get() > 1.0
                or self.robot_mode == RobotMode.AUTO):
            self.lift_pneumatic_extend.set(False)
            self.lift_pneumatic_retract.set(True)
            self.set_lift_setpoint(self.current_lift_preset_val +
                                   int(self.lift_adjust_val))

        if not self.current_lift_preset == LiftPreset.LIFT_PRESET_STOW:
            self.set_lift_setpoint(self.current_lift_preset_val +
                                   int(self.lift_adjust_val))

        lift_position = self.lift_talon.getSelectedSensorPosition(0)
        err = abs(lift_position - self.lift_setpoint)
        if err > 1:
            self.on_target = False
            if lift_position < self.lift_setpoint:
                self.lift_talon.set(ControlMode.PercentOutput, 1.0)
            elif lift_position > self.lift_setpoint:
                self.lift_talon.set(ControlMode.PercentOutput, -1.0)
        else:
            self.lift_talon.set(ControlMode.PercentOutput, 0.0)
            self.on_target = True

        return self.on_target

    def disable(self):
        self.logger.info("DeepSpaceLift::disable()")
        self.lift_talon.set(ControlMode.PercentOutput, 0)

    def set_lift_setpoint(self, ticks):
        self.lift_setpoint = max(min(ticks, self.max_lift_position),
                                 self.min_lift_position)