Beispiel #1
0
	RobotSystem(void):
		robotInted(false)
		,stick(1)		// as they are declared above.
		,stick2(2)
		,line1(10)
		,line2(11)
		,line3(12)
		//,camera(AxisCamera::GetInstance())
		,updateCAN("CANUpdate",(FUNCPTR)UpdateCAN)
		,cameraTask("CAMERA", (FUNCPTR)CameraTask)
		,compressor(14,1)
		,EncArm(2,3)
		,EncClaw(5,6)
		,PIDArm(.04,0,0) // .002, .033
		,PIDClaw(.014,.0000014,0)
		,LowArm(.1)
		/*
		,MiniBot1(4)
		,MiniBot2(2)
		,ClawGrip(3)
		*/
		,MiniBot1a(8,1)
		,MiniBot1b(8,2)
		,MiniBot2a(8,3)
		,MiniBot2b(8,4)
		,ClawOpen(8, 8)
		,ClawClose(8,7)
		,LimitClaw(7)
		,LimitArm(13)
	{
	//	myRobot.SetExpiration(0.1);
		GetWatchdog().SetEnabled(false);
		GetWatchdog().SetExpiration(1);
		compressor.Start();
		debug("Waiting to init CAN");
		Wait(2);
		
		Dlf = new CANJaguar(6,CANJaguar::kSpeed);
		Dlb = new CANJaguar(3,CANJaguar::kSpeed);
		Drf = new CANJaguar(7,CANJaguar::kSpeed);
		Drb = new CANJaguar(2,CANJaguar::kSpeed);
		arm1 = new CANJaguar(5);
		arm1_sec = new CANJaguar(8);
		arm2 = new CANJaguar(4);
		
		
		EncArm.SetDistancePerPulse(.00025);
		EncClaw.SetDistancePerPulse(.00025);
		EncClaw.SetReverseDirection(false);
		EncArm.SetReverseDirection(true);
		EncArm.Reset();
		EncClaw.Reset();
		
		
		updateCAN.Start((int)this);
		//cameraTask.Start((int)this);
		EncArm.Start();
		EncClaw.Start();
		debug("done initing");
	}
Beispiel #2
0
	/**
	 * This autonomous (along with the chooser code above) shows how to select between different autonomous modes
	 * using the dashboard. The sendable chooser code works with the Java SmartDashboard. If you prefer the LabVIEW
	 * Dashboard, remove all of the chooser code and uncomment the GetString line to get the auto name from the text box
	 * below the Gyro
	 *
	 * You can add additional auto modes by adding additional comparisons to the if-else structure below with additional strings.
	 * If using the SendableChooser make sure to add them to the chooser code above as well.
	 */
	void AutonomousInit()
	{
		autoSelected = *((std::string*)chooser->GetSelected());
		//std::string autoSelected = SmartDashboard::GetString("Auto Selector", autoNameDefault);
		std::cout << "Auto selected: " << autoSelected << std::endl;

		rotation = 0.0;
				//*((double*)posChooser->GetSelected());

		//goal = *((std::string*)goalChooser->GetSelected());
		shoot = "No";
		//*((std::string*)shootChooser->GetSelected());

		defenseCrossed = false;
		done = false;


		std::cout << "Here" << std::endl;
		drive->SetMaxOutput(1.0);
		std::cout << "there" << std::endl;
		//Make sure to reset the encoder!
		leftEnc->Reset();
		rightEnc->Reset();
		gyro->Reset();
		autoCounter = 0;
		timer->Reset();
	}
Beispiel #3
0
	void RawControl::resetEncoders()
	{
		wheelEncoderFR->Reset();
		wheelEncoderFL->Reset();
		wheelEncoderBR->Reset();
		wheelEncoderBL->Reset();
		
	}
// Starts at the beginning of the autonomous period
void Robot::AutonomousInit() {
	autoLoopCounter = 0;

	encoder1.Reset();
	encoder2.Reset();
	lifterEncoder.Reset();
	ballManipulatorEncoder.Reset();
}
Beispiel #5
0
	void TeleopInit()
	{
		leftEnc->Reset();
		rightEnc->Reset();
		gyro->Reset();

		powerCounter = 0;
	}
  void RobotInit ()
  {
  lw = LiveWindow::GetInstance();
  CameraServer::GetInstance()->SetQuality(50);
   //the camera name (ex "cam0") can be found through the roborio web interface
  CameraServer::GetInstance()->StartAutomaticCapture("cam1");
  AutonState = 0;
  ballarm.Reset();
  ballarm.SetMaxPeriod(.01);
  ballarm.SetMinRate(.02);
  ballarm.SetDistancePerPulse(.9);
  gyroOne.Calibrate();
  UpdateActuatorCmnds(0,0,false,false,false,false,false,false,false,0,0,0,0,0);

  UpdateSmartDashboad(false,
                      false,
                      false,
                      false,
                      false,
                      0,
                      0,
                      0,
                      0,
                      0,
                      0,
                      0,
                      0,
                      0);
  }
	void Drive (float speed, int dist)
	{
		leftDriveEncoder.Reset();
		leftDriveEncoder.Start();
		
		int reading = 0;
		dist = abs(dist);
		
		// The encoder.Reset() method seems not to set Get() values back to zero,
		// so we use a variable to capture the initial value.
		dsLCD->PrintfLine(DriverStationLCD::kUser_Line2, "initial=%d\n", leftDriveEncoder.Get());
		dsLCD->UpdateLCD();

		// Start moving the robot
		robotDrive.Drive(speed, 0.0);
		
		while ((IsAutonomous()) && (reading <= dist))
		{
			reading = abs(leftDriveEncoder.Get());				
			dsLCD->PrintfLine(DriverStationLCD::kUser_Line3, "reading=%d\n", reading);
			dsLCD->UpdateLCD();
		}

		robotDrive.Drive(0.0, 0.0);
		
		leftDriveEncoder.Stop();
	}	
	// Runs during test mode
	// Test
	// * 
	void Test()
	{
		shifters.Set(DoubleSolenoid::kForward);

		leftDriveEncoder.Start();
		leftDriveEncoder.Reset();

		int start = leftDriveEncoder.Get();

		while (IsTest()) {
			if (rightStick.GetRawButton(7)) {
				robotDrive.ArcadeDrive(rightStick.GetY(), -rightStick.GetX());
			}
			else {
				robotDrive.ArcadeDrive(rightStick.GetY()/2, -rightStick.GetX()/2);
			}

			if (gamepad.GetEvent(4) == kEventClosed) {
				start = leftDriveEncoder.Get();
			}

			dsLCD->PrintfLine(DriverStationLCD::kUser_Line3, "lde: %d", leftDriveEncoder.Get() - start);
			dsLCD->UpdateLCD();

			gamepad.Update();
		}
	}
Beispiel #9
0
    // WHen robot is enabled
    void init() {
        log->info("initializing");
        log->print();
        climber = NULL;
        leftDriveEncoder->Reset();
        leftDriveEncoder->SetDistancePerPulse(DriveDistancePerPulse);
        leftDriveEncoder->Start();
		rightDriveEncoder->Reset();
        rightDriveEncoder->SetDistancePerPulse(DriveDistancePerPulse);
        rightDriveEncoder->Start();
        //leftClimber->motorController->Disable();
		leftClimber->encoder->Reset();
        leftClimber->encoder->Start();
        //rightClimber->motorController->Disable();
        rightClimber->encoder->Reset();
        rightClimber->encoder->Start();
        bcdValue = bcd->value();
        loadSwitchOldState = loaderSwitch->Get();
        #if 0
		bool leftDone = false;
		bool rightDone = false;
        // Only do this for some BCD values?
        while (!leftDone || !rightDone){
			if (!leftDone)
				leftDone = leftClimber->UpdateState(-1.0, -30);
			if (!rightDone)
				rightDone = rightClimber->UpdateState(-1.0, -30);
	        log->info("Wait: Ll Rl: %d %d",
	        		leftClimber->lowerLimitSwitch->Get(),
	        		rightClimber->lowerLimitSwitch->Get());
	        log->print();
		}
#endif
        climbState = NotInitialized;
        cameraElevateAngle =
        		(cameraElevateMotor->GetMaxAngle()-cameraElevateMotor->GetMinAngle()) * 2/3;
        cameraPivotAngle = 0;
        cameraPivotMotor->SetAngle(cameraPivotAngle);
        cameraElevateMotor->SetAngle(cameraElevateAngle);
        loading = false;
        loaderDisengageDetected = false;
        //This is a rough guess of motor power it should be based on voltage
        shooterMotorVolts = 8.0; // volts as a fraction of 12V
    	loadCount = 0;
    }
Beispiel #10
0
	void initRobot () {
			cerr << "running init\n";
			Dlf->EnableControl(0);
			Dlb->EnableControl(0);
			Drf->EnableControl(0);
			Drb->EnableControl(0);
			arm1->EnableControl();
			arm1_sec->EnableControl();
			arm2->EnableControl();
			
			
			
			Dlf->ConfigEncoderCodesPerRev(250);
			Dlf->SetPID(1,0,0);
			Dlb->ConfigEncoderCodesPerRev(250);
			Dlb->SetPID(1,0,0);
			Drf->ConfigEncoderCodesPerRev(250);
			Drf->SetPID(1,0,0);
			Drb->ConfigEncoderCodesPerRev(250);
			Drb->SetPID(1,0,0);
			Wait(.1);
			if(robotInted==false) {
				int count=220;
				arm2->Set(-.3);
				while(count-->0 && LimitClaw.Get() == 1) Wait(.005);
				arm2->Set(.15);
				while(count-->0 && LimitClaw.Get() == 0) Wait(.005);
				arm2->Set(0);
				if(count>0)
					EncClaw.Reset();
				arm1->Set(-.3);
				arm1_sec->Set(-.3);
				while(count-->0 && LimitArm.Get() == 1) Wait(.005);
				arm1->Set(.5);
				arm1_sec->Set(.5);
				while(count-->0 && LimitArm.Get() == 0) Wait(.005);
				if(count>0)
					EncArm.Reset();
				arm1->Set(0);
				arm1_sec->Set(0);
				
				robotInted = true;
			}
		}
Beispiel #11
0
	void Test() {
		robotDrive.SetSafetyEnabled(false);
		uint8_t toSend[10];//array of bytes to send over I2C
		uint8_t toReceive[10];//array of bytes to receive over I2C
		uint8_t numToSend = 1;//number of bytes to send
		uint8_t numToReceive = 0;//number of bytes to receive
		toSend[0] = 7; //send 0 to arduino
		i2c.Transaction(toSend, numToSend, toReceive, numToReceive);

		bool isSettingUp = true;

		pickup.setGrabber(-1);
		pickup.setLifter(1);
		while (isSettingUp) {
			isSettingUp = false;
			if (grabOuterLimit.Get() == false) {
				pickup.setGrabber(0);
			}
			else {
				isSettingUp = true;
			}

			if (liftLowerLimit.Get()) {
				pickup.setLifter(0);
			}
			else {
				isSettingUp = true;
			}
		}
		gyro.Reset();
		liftEncoder.Reset();
		grabEncoder.Reset();

		toSend[0] = 8;
		i2c.Transaction(toSend, numToSend, toReceive, numToReceive);

		while(IsTest() && IsEnabled());

		toSend[0] = 0;
		i2c.Transaction(toSend, numToSend, toReceive, numToReceive);
	}
Beispiel #12
0
	void OperatorControl(void) {
		char count=0;
		double target = 0, speed = 0;
		while(!IsDisabled()) {
			double tmpStick = -1*stick.GetRawAxis(2);
			if(tmpStick < .2 && tmpStick > -.2) tmpStick=0;
			target += tmpStick*1.5;
			int location = enc.GetRaw();
			if(stick.GetRawButton(5)) {
				up.Set(true);
				down.Set(false);
			}else if(stick.GetRawButton(7) && location > 0) {
				down.Set(true);
				up.Set(false);
			}else if(stick.GetRawButton(8)) {
				down.Set(true);
				up.Set(false);
			}else if(stick.GetRawButton(9)){
			
				speed = pid(target, location);
				if(speed > 1) {
					up.Set(true);
					down.Set(false);
				}else if(speed < -1) {
					up.Set(false);
					down.Set(true);
				}else{
					up.Set(false);
					down.Set(false);
				}
			}else if(stick.GetRawButton(10)) {
				enc.Reset();
			}else{
				up.Set(false);
				down.Set(false);
			}
			if(stick.GetRawButton(1))
				target = 2;
			if(stick.GetRawButton(4))
				target = 400;
			if(stick.GetRawButton(3))
				target = 200;
			if(stick.GetRawButton(2))
				target = 70;
				
			Wait(.02);
			while(count++%30==0) cerr << location << '\t' << target << '\t' << speed << endl;
		}
	}
Beispiel #13
0
	/**
	 * Runs during test mode	```````
	 */
	void Test() {
		TestMode tester(m_ds);
		driveDistanceRight.Reset();
		driveDistanceRight.Start();
		ballGrabber.resetSetPoint();
		shooter.motorShutOff();
		while (IsTest() && IsEnabled()){
			lcd->Clear();
			tester.PerformTesting(&gamePad, &driveDistanceRight, lcd, &rightJoyStick, &leftJoyStick,
								  &testSwitch, &testTalons, &frontUltrasonic, &backUltrasonic,
								  &ballGrabber.ballDetector, &analogTestSwitch,
								  &shooter, &ballGrabber
								  );
			lcd->UpdateLCD();
			Wait(0.1);
			
		}
		driveDistanceRight.Stop();
		}
Beispiel #14
0
	void DoAutonomousMoveStep(const step_speed *speeds, char * message)
	{
		leftDriveEncoder.Reset();
		double dist = speeds[0].distance;
		double reading;
		
		// Start moving the robot
		leftDriveMotor.Set(speeds->speed_left);
		rightDriveMotor.Set(speeds->speed_right);

		reading = absolute(leftDriveEncoder.GetDistance());
		
		while (dist > reading)
		{
			Wait(0.02);
			reading = absolute(leftDriveEncoder.GetDistance());
			dsLCD->PrintfLine(DriverStationLCD::kUser_Line3, "D: %5.0f R : %5.0f", dist, reading);
			dsLCD->UpdateLCD();
		}
		
		leftDriveMotor.Set(0.0);
		rightDriveMotor.Set(0.0);
	}
Beispiel #15
0
	void Autonomous()
	{
		Timer timer;
		float power = 0;
		bool isLifting = false;
		bool isGrabbing = false;
		double liftHeight = Constants::liftBoxHeight-Constants::liftBoxLip;
		double grabPower = Constants::grabAutoCurrent;
		bool backOut;

		uint8_t toSend[1];//array of bytes to send over I2C
		uint8_t toReceive[0];//array of bytes to receive over I2C
		uint8_t numToSend = 1;//number of bytes to send
		uint8_t numToReceive = 0;//number of bytes to receive
		toSend[0] = 2;//set the byte to send to 1
		i2c.Transaction(toSend, numToSend, toReceive, numToReceive);//send over I2C

		bool isSettingUp = true;

		//pickup.setGrabber(-1); //open grabber all the way
		pickup.setLifter(0.8);

		while (isSettingUp && IsEnabled() && IsAutonomous()) {
			isSettingUp = false;
			/*if (grabOuterLimit.Get() == false) {
				pickup.setGrabber(0); //open until limit
			}
			else {
				isSettingUp = true;
			}*/

			if (liftLowerLimit.Get()) {
				pickup.setLifter(0); //down till bottom
			}
			else {
				isSettingUp = true;
			}
		}

		gyro.Reset();
		liftEncoder.Reset();
		grabEncoder.Reset();

		if (grabStick.GetZ() > .8) {
			timer.Reset();
			timer.Start();
			while (timer.Get() < 1) {
				robotDrive.MecanumDrive_Cartesian(0, power, 0, gyro.GetAngle());	// drive back
				if(power>-.4){
					power-=0.005;
					Wait(.005);
				}
			}
			robotDrive.MecanumDrive_Cartesian(0, 0, 0, gyro.GetAngle());	// STOP!!!
			timer.Stop();
			timer.Reset();
			Wait(1);
		}
		power = 0;

		while (isLifting && IsEnabled() && IsAutonomous()) {
			Wait(.005);
		}

		backOut = Constants::autoBackOut;
		pickup.grabberGrab(isGrabbing, grabPower, backOut, grabStick);
		Wait(.005);

		while (isGrabbing && IsEnabled() && IsAutonomous()) {
			Wait(.005);
		}

		liftHeight = 3*Constants::liftBoxHeight;
		Wait(.005);
		pickup.lifterPosition(liftHeight, isLifting, grabStick);
		Wait(.005);
		while (isLifting && IsEnabled() && IsAutonomous()) {
			Wait(.005);
		}

		while(prox.GetVoltage() * Constants::ultrasonicVoltageToInches / 12 < 2 && IsEnabled() && IsAutonomous());	// while the nearest object is closer than 2 feet

		timer.Start();

		while(prox.GetVoltage() * Constants::ultrasonicVoltageToInches  < Constants::autoBackupDistance && timer.Get() < Constants::autoMaxDriveTime && IsEnabled() && IsAutonomous()) {	// while the nearest object is further than 12 feet
			if (power < .45) { //ramp up the power slowly
				power += .00375;
			}
			robotDrive.MecanumDrive_Cartesian(0, power, 0, gyro.GetAngle());	// drive back
			float distance = prox.GetVoltage() * Constants::ultrasonicVoltageToInches / 12;	// distance from ultrasonic sensor
			SmartDashboard::PutNumber("Distance", distance);	// write stuff to smart dash
			SmartDashboard::PutNumber("Drive Front Left Current", pdp.GetCurrent(Constants::driveFrontLeftPin));
			SmartDashboard::PutNumber("Drive Front Right Current", pdp.GetCurrent(Constants::driveFrontRightPin));
			SmartDashboard::PutNumber("Drive Rear Left Current", pdp.GetCurrent(Constants::driveRearLeftPin));
			SmartDashboard::PutNumber("Drive Rear Right Current", pdp.GetCurrent(Constants::driveRearRightPin));
			SmartDashboard::PutNumber("Gyro Angle", gyro.GetAngle());
			SmartDashboard::PutNumber("Distance (in)", prox.GetVoltage() * Constants:: ultrasonicVoltageToInches);

			Wait(.005);
		}

		timer.Reset();

		while(timer.Get() < Constants::autoBrakeTime && IsEnabled() && IsAutonomous()) {	// while the nearest object is further than 12 feet
			robotDrive.MecanumDrive_Cartesian(0,Constants::autoBrakePower,0); ///Brake
		}

		float turn = 0;

		while (fabs(turn) < 85 && IsEnabled() && IsAutonomous())  { //turn 90(ish) degrees
			robotDrive.MecanumDrive_Cartesian(0,0,.1);
			turn = gyro.GetAngle();
			if (turn > 180) {
				turn -= 360;
			}
		}


		robotDrive.MecanumDrive_Cartesian(0,0,0); ///STOP!!!

		timer.Stop();
		toSend[0] = 8;
		i2c.Transaction(toSend, numToSend, toReceive, numToReceive);

		while(IsAutonomous() && IsEnabled());

		toSend[0] = 0;
		i2c.Transaction(toSend, numToSend, toReceive, numToReceive);
	}
/******************************************************************************
 * Function:     TeleopPeriodic
 *
 * Description:  This is the function that is called during the periodic period
 *               for teleop.
 ******************************************************************************/
  void TeleopPeriodic()
    {
      float DrvRY, DrvLY;
      float BallRollerSpd;
      float FishTapeSpd;
      float WenchSpd;
      float LgtY, LgtZ;
      double LgtPOV;
      int LgtP1;
      bool LgtT0;
      bool LgtB1,LgtB3,LgtB4,LgtB5,LgtB6,LgtB7,LgtB8,LgtB9,LgtB11,LgtB10,LgtB12;
      bool XbxB4, XbxB5, XbxB2, XbxB1;
      bool BallSw;
      int XbxPOV;
      double ArmP;
      double ArmError;
      double desiredPos;
      double LoArmCurve;


    while (IsOperatorControl() && IsEnabled())
      {

      /* Read sensor values here: */
      ArmP = ballarm.GetDistance();

      BallSw = BlSw.Get();

      /* Read Xbox controller commands here: */
      DrvLY = -xboxDrive.GetRawAxis(1);
      DrvRY = -xboxDrive.GetRawAxis(5);

      XbxB1 = xboxDrive.GetRawButton(1);
      XbxB2 = xboxDrive.GetRawButton(2);
      XbxB4 = xboxDrive.GetRawButton(4);
      XbxB5 = xboxDrive.GetRawButton(5);

      XbxPOV = xboxDrive.GetPOV(0);

      /* Read Logictec joystick commands here: */
      LgtY = Logitech.GetRawAxis(1);
      LgtZ = Logitech.GetRawAxis(2);

      LgtP1  = Logitech.GetPOV(0);
      LgtT0  = Logitech.GetRawButton(1);
      LgtB1  = Logitech.GetRawButton(2);
      LgtB3  = Logitech.GetRawButton(3);
      LgtB4  = Logitech.GetRawButton(4);
      LgtB5  = Logitech.GetRawButton(5);
      LgtB6  = Logitech.GetRawButton(6);
      LgtB7  = Logitech.GetRawButton(7);
      LgtB8  = Logitech.GetRawButton(8);
      LgtB9  = Logitech.GetRawButton(9);
      LgtB10 = Logitech.GetRawButton(10);
      LgtB11 = Logitech.GetRawButton(11);
      LgtB12 = Logitech.GetRawButton(12);

      LgtPOV = (double)LgtP1;

     // DriverStation::
	 //double GetMatchTime();
	 // SmartDashboard::PutNumber("MatchTime", GetMatchTime());


      if(LgtB12 && LgtB10)
        {
        ballarm.Reset();
        }


      /* Set the desired position of the ball arm. */
      if (LgtB7)
        {
        /* This is the middle position of the arm:  */
         desiredPos = 120;
        }
      else if (LgtB8)
        {
        /* This is the upper position of the arm: */
          desiredPos = 210;
        }
      else if((LgtB3) || (LgtB5) ||(LgtB6) || (LgtB9) || (LgtB11))
        {
        /* Default */
          desiredPos = 0;
        }

      /* Set the ball roller state: */
      if (LgtT0 == true &&
          BallSw == true)
        {
          BallRollerSpd = 1;
        }
      else if (LgtB1 == true)
        {
          BallRollerSpd = -1;
        }
      else
        {
          BallRollerSpd = 0.0;
        }


      /* Set the output to the fish tape: */
      if (LgtP1 == 180)
        {
          FishTapeSpd = -1.0;
        }
      else if(LgtP1 == 0)
        {
          FishTapeSpd = 1.0;
        }
      else
        {
          FishTapeSpd = 0.0;
        }

      /* Set the output to the lower arm: */
      LoArmCurve = LgtY*LowArmGx;

//      SmartDashboard::


      /* Determine the wench state */
      if (LgtB4 == true)
        {
        WenchSpd = 1;
        }
      else if (XbxB4)
      {
    	  WenchSpd = -.5;
      }
      else
        {
        WenchSpd = 0.0;
        }

   /*   if(GetMatchTime() < 30)
      {
    	  Light1.Set(0);
    	  Light2.Set(0);
      }*/

      /* Output data to the smart dashboard: */
      ReadAutonSwitch();

      UpdateSmartDashboad(Sw1.Get(),
                          Sw2.Get(),
                          Sw3.Get(),
                          Sw4.Get(),
                          BlSw.Get(),
                          AutonState,
                          0,
                          ballarm.GetDistance(),
                          gyroOne.GetAngle(),
                          accel.GetX(),
                          accel.GetY(),
                          accel.GetZ(),
                          (double)DrvLY,
                          (double)DrvRY);

      UpdateActuatorCmnds(BallRollerSpd,
    		              desiredPos,
                          LgtB3,
                          LgtB5,
                          LgtB6,
                          LgtB7,
                          LgtB8,
                          LgtB9,
                          LgtB11,
                          DrvLY,
                          DrvRY,
                          FishTapeSpd,
                          LoArmCurve,
                          WenchSpd);

      /* Force the program  to wait a period of time in order to conserve power: */
      Wait(kUpdatePeriod); // Wait 5ms for the next update.

      Scheduler::GetInstance()->Run();
      }
  }
Beispiel #17
0
	void TeleopPeriodic()
	{
		char myString [STAT_STR_LEN];

		if (running)
		{
			enterHoldCommand = joystick->GetRawButton(BUT_JS_ENT_POS_HOLD);
			exitHoldCommand = joystick->GetRawButton(BUT_JS_EXIT_POS_HOLD);

			switch (liftState)
			{
				case raising:
					if (GetLiftLimitSwitchMax())
					{
						SetLiftMotor(MOTOR_SPEED_STOP);
						if(!liftEncFullRanged)
						{
							maxLiftEncDist = liftEncoder->GetDistance();
							liftEncFullRanged = true;
						}
						motorSpeed = -MOTOR_SPEED_DOWN;
						liftState = lowering;
						SetLiftMotor(motorSpeed);
					}

					if (enterHoldCommand && liftEncZeroed && liftEncFullRanged)
					{
						liftState = holding;
					}

					break;

				case lowering:
					if (GetLiftLimitSwitchMin())
					{
						SetLiftMotor(MOTOR_SPEED_STOP);
						if(!liftEncZeroed)
						{
							liftEncoder->Reset();
							liftEncZeroed = true;
						}
						motorSpeed=MOTOR_SPEED_UP;
						liftState = raising;
						SetLiftMotor(motorSpeed);
					}

					if (enterHoldCommand && liftEncZeroed && liftEncFullRanged)
					{
						liftState = holding;
					}
					break;

				case holding:
					if(!(controlLift->IsEnabled()))
					{
						pidPosSetPoint = SP_RANGE_FRACTION*maxLiftEncDist; //go to the midpoint of the range
						controlLift->SetSetpoint(pidPosSetPoint);
#if BUILD_VERSION == COMPETITION
						controlLift2->SetSetpoint(pidPosSetPoint);
#endif
						controlLift->Enable();
#if BUILD_VERSION == COMPETITION
						controlLift2->Enable();
#endif
					}

					if(exitHoldCommand)
					{
						controlLift->Disable();
#if BUILD_VERSION == COMPETITION
						controlLift2->Disable();
#endif
						motorSpeed = -MOTOR_SPEED_DOWN;
						liftState = lowering;
						SetLiftMotor(motorSpeed);
					}
				break;
			}
		}

		//status
		sprintf(myString, "running: %d\n", running);
		SmartDashboard::PutString("DB/String 0", myString);
		sprintf(myString, "State: %d\n", liftState);
		SmartDashboard::PutString("DB/String 1", myString);
		sprintf(myString, "motorSpeed: %f\n", motorSpeed);
		SmartDashboard::PutString("DB/String 2", myString);
		sprintf(myString, "lift encoder zeroed: %d\n", liftEncZeroed);
		SmartDashboard::PutString("DB/String 3", myString);
		sprintf(myString, "max enc set: %d\n", liftEncFullRanged);
		SmartDashboard::PutString("DB/String 4", myString);
		sprintf(myString, "maxLiftEncDist: %f\n", maxLiftEncDist);
		SmartDashboard::PutString("DB/String 5", myString);
		sprintf(myString, "enc dist: %f\n", liftEncoder->GetDistance());
		SmartDashboard::PutString("DB/String 6", myString);
		sprintf(myString, "pid: %d\n", controlLift->IsEnabled());
		SmartDashboard::PutString("DB/String 7", myString);
		sprintf(myString, "dist to sp : %f\n", DistToSetpoint());
		SmartDashboard::PutString("DB/String 8", myString);
		sprintf(myString, "at sp : %d\n", AtSetpoint());
		SmartDashboard::PutString("DB/String 9", myString);
	}
Beispiel #18
0
 void Reset() {
   m_speedController->Set(0.0f);
   m_encoder->Reset();
 }
	void OperatorControl(void)
	{
		autonomous = false;
		//myRobot.SetSafetyEnabled(false);
		//myRobot.SetInvertedMotor(kFrontLeftMotor, true);
		//	myRobot.SetInvertedMotor(3, true);
		//variables for great pid
		double rightSpeed,leftSpeed;
		float rightSP, leftSP, liftSP, lastLiftSP, gripSP, tempLeftSP, tempRightSP;
		float stickY[2];
		float stickYAbs[2];
		bool lightOn = false;
		AxisCamera &camera = AxisCamera::GetInstance();
		camera.WriteResolution(AxisCameraParams::kResolution_160x120);
		camera.WriteMaxFPS(5);
		camera.WriteBrightness(50);
		camera.WriteRotation(AxisCameraParams::kRotation_0);
		rightEncoder->Start();
		leftEncoder->Start();
		liftEncoder->Start();
		rightEncoder->Reset();
		leftEncoder->Reset();
		liftEncoder->Reset();
		bool fastest = false; //transmission mode
		float reduction = 1; //gear reduction from 
		bool bDrivePID = false;
		//float maxSpeed = 500;
		float liftPower = 0;
		float liftPos = -10;
		bool disengageBrake = false;
		int count = 0;
		//int popCount = 0;
		double popStart = 0;
		double popTime = 0;
		int popStage = 0;
		int liftCount = 0;
		int liftCount2 = 0;
		const float LOG17 = log(17.61093344);
		float liftPowerAbs = 0;
		float gripError = 0;
		float gripErrorAbs = 0;
		float gripPropMod = 0;
		float gripIntMod = 0;
		bool shiftHigh = false;
		leftEncoder->SetDistancePerPulse((6 * PI / 1000)/reduction); //6-inch wheels, 1000 raw counts per revolution,
		rightEncoder->SetDistancePerPulse((6 * PI / 1000)/reduction); //about 1:1 gear ratio
		DriverStationEnhancedIO &myEIO = driverStation->GetEnhancedIO();
		GetWatchdog().SetEnabled(true);
		GetWatchdog().SetExpiration(0.3);

		PIDDriveLeft->SetOutputRange(-1, 1);
		PIDDriveRight->SetOutputRange(-1, 1);
		//PIDDriveLeft->SetInputRange(-244,244);
		//PIDDriveRight->SetInputRange(-244,244);
		PIDDriveLeft->SetTolerance(5);
		PIDDriveRight->SetTolerance(5);
		PIDDriveLeft->SetContinuous(false);
		PIDDriveRight->SetContinuous(false);
		//PIDDriveLeft->Enable();
		//PIDDriveRight->Enable();
		PIDDriveRight->SetPID(DRIVEPROPGAIN, DRIVEINTGAIN, DRIVEDERIVGAIN);
		PIDDriveLeft->SetPID(DRIVEPROPGAIN, DRIVEINTGAIN, DRIVEDERIVGAIN);
		
		liftSP = 0;
		PIDLift->SetTolerance(10);
		PIDLift->SetContinuous(false);
		PIDLift->SetOutputRange(-0.75, 1.); //BUGBUG
		PIDLift->Enable();
		
		gripSP = 0;
		float goalGripSP = 0;
		bool useGoalSP = true;
		bool gripPIDOn = true;
		float gripP[10];
		float gripI[10];
		float gripD[10];
		PIDGrip->SetOutputRange(-0.5, 0.28); //Negative goes up
		PIDGrip->SetTolerance(5);
		PIDGrip->SetSetpoint(0);
		PIDGrip->Enable();
		miniDep->Set(miniDep->kForward);
		int i = 0;
		while(i < 10)
		{
			gripP[i] = GRIPPROPGAIN;
			i++;
		}
		i = 0;
		while(i < 10)
		{
			gripI[i] = GRIPINTGAIN;
			i++;
		}
		i = 0;
		while(i < 10)
		{
			gripD[i] = GRIPDERIVGAIN;
			i++;
		}

		while (IsOperatorControl())
		{
			GetWatchdog().Feed();
			count++;
#if !(SKELETON)
			sendVisionData();
#endif
			/*
			if(LIFTLOW1BUTTON && !(counts%10)) printf("LIFTLOW1BUTTON\n");
			if(LIFTLOW2BUTTON && !(counts%10)) printf("LIFTLOW2BUTTON\n");
			if(LIFTMID1BUTTON && !(counts%10)) printf("LIFTMID1BUTTON\n");
			if(LIFTMID2BUTTON && !(counts%10)) printf("LIFTMID2BUTTON\n");
			if(LIFTHIGH1BUTTON && !(counts%10)) printf("LIFTHIGH1BUTTON\n");
			if(LIFTHIGH2BUTTON && !(counts%10)) printf("LIFTHIGH2BUTTON\n");
			*/
			/*
			if(lsLeft->Get()) printf("LSLEFT\n");
			if(lsMiddle->Get()) printf("LSMIDDLE\n");
			if(lsRight->Get()) printf("LSRIGHT\n");
			*/
			stickY[0] = stickL.GetY();
			stickY[1] = stickR.GetY();
			stickYAbs[0] = fabs(stickY[0]);
			stickYAbs[1] = fabs(stickY[1]);
			if(bDrivePID)
			{
	#if 0
				frontLeftMotor->Set(stickY[0]);
				rearLeftMotor->Set(stickY[0]);
				frontRightMotor->Set(stickY[1]);
				rearRightMotor->Set(stickY[1]);
				
				if(!(count%5)) printf("Speeds: %4.2f %4.2f Outputs: %f %f \n", leftEncoder->GetRate(),
						rightEncoder->GetRate(), frontLeftMotor->Get(), frontRightMotor->Get());
	#endif		
				if(stickYAbs[0] <= 0.05 )
				{
					leftSP = 0;
					if(!(count%3) && !BACKWARDBUTTON)
					{
						PIDDriveLeft->Reset();
						PIDDriveLeft->Enable();
					}
				}
				else leftSP = stickY[0] * stickY[0] * (stickY[0]/stickYAbs[0]); //set points for pid control
				if(stickYAbs[1] <= 0.05)
				{
					rightSP = 0;
					if(!(count%3) && !BACKWARDBUTTON)
					{
						PIDDriveRight->Reset();
						PIDDriveRight->Enable();
					}
				}
				else rightSP = stickY[1] * stickY[1] * (stickY[1]/stickYAbs[1]);
				
				if (BACKWARDBUTTON)
				{
					tempRightSP = rightSP;
					tempLeftSP = leftSP;
					rightSP = -tempLeftSP;
					leftSP = -tempRightSP; //This line and above line sets opposite values for the controller. ...Theoretically.
				}
				
				PIDDriveLeft->SetSetpoint(leftSP);
				PIDDriveRight->SetSetpoint(rightSP);
					
				
				leftSpeed = leftEncoder->GetRate();
				rightSpeed = rightEncoder->GetRate();
				if(!(count++ % 5))
				{
				printf("rate L: %2.2f R: %2.2f SP %2.4f %2.4f ERR %2.2f %2.2f Pow: %1.2f %1.2f\n", 
						leftPIDSource->PIDGet(), rightPIDSource->PIDGet(), leftSP, rightSP,
						PIDDriveLeft->GetError(), PIDDriveRight->GetError(), frontLeftMotor->Get(),
						frontRightMotor->Get());
						
				
				//printf("Throttle value: %f", stickR.GetThrottle());
				if(PIDDriveRight->OnTarget()) printf("Right on \n");
				if(PIDDriveLeft->OnTarget()) printf("Left on \n");
				}
					
				if(PIDRESETBUTTON)
				{
					//PIDDriveRight->SetPID(stickR.GetThrottle()+1,DRIVEINTGAIN, DRIVEDERIVGAIN); 
					//PIDDriveLeft->SetPID(stickR.GetThrottle()+1,DRIVEINTGAIN, DRIVEDERIVGAIN);
					PIDDriveLeft->Reset();
					PIDDriveRight->Reset();
					PIDDriveLeft->Enable();
					PIDDriveRight->Enable();
				}
			}
			else
			{
				if(PIDDriveLeft->IsEnabled()) PIDDriveLeft->Reset();
				if(PIDDriveRight->IsEnabled()) PIDDriveRight->Reset();
				if(DEMOSWITCH)
				{
					stickY[0] = stickY[0]*(1 - lift->getPosition()); //reduces power based on lift height
					stickY[1] = stickY[0]*(1 - lift->getPosition());
				}
				if(stickYAbs[0] > 0.05)
				{
					frontLeftMotor->Set(stickY[0]);
					rearLeftMotor->Set(stickY[0]);
				}
				else
				{
					frontLeftMotor->Set(0);
					rearLeftMotor->Set(0);
				}
				if(stickYAbs[1] > 0.05)
				{
					frontRightMotor->Set(-stickY[1]);
					rearRightMotor->Set(-stickY[1]);
				}
				else
				{
					frontRightMotor->Set(0);
					rearRightMotor->Set(0);
				}
			}
			
			if(stickL.GetRawButton(2) && stickL.GetRawButton(3) && stickR.GetRawButton(2) &&
					stickR.GetRawButton(3) && BACKWARDBUTTON && !(count%5)) bDrivePID = !bDrivePID;
			
			if((SHIFTBUTTON && shiftHigh) || DEMOSWITCH)
			{
				shifter->Set(shifter->kReverse);
				shiftHigh = false;
				maxSpeed = 12;
			}
			else if(!SHIFTBUTTON && !shiftHigh && !DEMOSWITCH)
			{
				shifter->Set(shifter->kForward);
				shiftHigh = true;
				maxSpeed = 25; //last value 35
			}

			sendIOPortData();
#if !(SKELETON)
			/*
			if(LIGHTBUTTON) lightOn = true;
			else lightOn = false;
			if(!lightOn) light->Set(light->kOff);
			if(lightOn) light->Set(light->kOn);
			*/
			if(!MODESWITCH)
			{
				lastLiftSP = liftSP;
				if(!PIDLift->IsEnabled()) PIDLift->Enable();
				if(LIFTLOW1BUTTON) liftSP = LIFTLOW1;
				if(LIFTLOW2BUTTON) liftSP = LIFTLOW2;
				if(LIFTMID1BUTTON) liftSP = LIFTMID1;
				if(LIFTMID2BUTTON) liftSP = LIFTMID2;
				if(LIFTHIGH1BUTTON) liftSP = LIFTHIGH1;
				if(LIFTHIGH2BUTTON && !(DEMOSWITCH && (stickYAbs[0] > 0.05 || stickYAbs[1] > 0.05))) liftSP = LIFTHIGH2;
				
				if(!lift->isBraking() && !disengageBrake)
				{
					PIDLift->SetSetpoint(liftSP);
					if(liftSP == 0 && liftPIDSource->PIDGet() < 0.1) //BUGBUG
					{
						//PIDLift->SetPID(LIFTPROPGAIN, LIFTINTGAIN, 3*LIFTDERIVGAIN);
						PIDLift->SetOutputRange(-liftPIDSource->PIDGet() - 0.1, 1.); //BUGBUG
					}
					else PIDLift->SetOutputRange(-0.75, 1.); //BUGBUG
				}
				if(lift->isBraking() && lastLiftSP != liftSP)
				{
					PIDLift->SetSetpoint(lastLiftSP + 0.06);
					PIDLift->SetPID(12.5 + 1.5*lift->getPosition(), LIFTINTGAIN + 0.6 + 3*lift->getPosition()/10, 0);
					lift->brakeOff();
					disengageBrake = true;
					if(!liftCount) liftCount = count;
				}
				//set brake (because near)
				if(fabs(PIDLift->GetError()) < 0.01 && !lift->isBraking() && !disengageBrake)
				{
					if(liftCount == 0) liftCount = count;
					if(count - liftCount > 3)
					{
						PIDLift->Reset();
						liftMotor1->Set(LIFTNEUTRALPOWER);
						liftMotor2->Set(LIFTNEUTRALPOWER);
						Wait(0.02);
						lift->brakeOn();
						Wait(0.02);
						liftMotor1->Set(0.0);
						liftMotor2->Set(0.0);
						PIDLift->Enable();
						PIDLift->SetSetpoint(lift->getPosition());
						liftCount = 0;
					}
					//if(!(count%50)) printf("Braking/Not PID \n");
				}
				if(lift->isBraking() && !(count%10)) PIDLift->SetSetpoint(lift->getPosition());
				if(fabs(PIDLift->GetError()) < 0.01 && disengageBrake && count - liftCount > 3)
				{
					disengageBrake = false;
					if(liftEncoder->PIDGet() < liftSP) PIDLift->SetPID(LIFTPROPGAIN, LIFTINTGAIN, LIFTDERIVGAIN - 0.015);
					else PIDLift->SetPID(LIFTPROPGAIN, LIFTINTGAIN, LIFTDERIVGAIN + 0.015);
					liftCount = 0;
				}
				
				//pid
				/*
				else if(!(fabs(PIDLift->GetError()) < 0.04) && !lift->isBraking() && liftPos == -20)
				{
					PIDLift->Enable();
					liftPos = -10;
					printf("PID GO PID GO PID GO PID GO PID GO \n");
				}
				*/
				//when liftPos is positive, measures position
				//when liftPos = -10, is pidding
				//when liftPos = -20, has just released brake
			}
			else //(MODESWITCH)
			{
				if(PIDLift->IsEnabled()) PIDLift->Reset();
				liftPower = .8*pow(2*((log(LIFTSLIDER + 0.003/.0208116511)/LOG17) + 0.116), 2)*(2*((log(LIFTSLIDER + 0.003/.0208116511)/LOG17) + 0.116)/fabs(2*((log(LIFTSLIDER + 0.003/.0208116511)/LOG17) + 0.116)));
				liftPowerAbs = fabs(liftPower);
				if(liftPowerAbs > 1) liftPower /= liftPowerAbs;
				//if(!(count%5)) printf("Slider: %f", liftPower);
				
				if(lift->isBraking() && liftPowerAbs > 0.05) lift->brakeOff();
				else if(!lift->isBraking() && liftPowerAbs <= 0.05 && !(count%5)) lift->brakeOn();
				if (liftPowerAbs > 0.05)
				{
					liftMotor1->Set(liftPower);
					liftMotor2->Set(liftPower);
				}
				else
				{
					liftMotor1->Set(0);
					liftMotor2->Set(0);
				}
			}
			if(MODESWITCH && LIFTLOW1BUTTON && LIFTMID1BUTTON && LIFTHIGH1BUTTON) liftEncoder->Reset();
			/*
			if(!(count%5))
			{
				printf("Lift pos: %f Lift error: %f Lift SP: %f \n", liftPIDSource->PIDGet(),
						PIDLift->GetError(), PIDLift->GetSetpoint());
			}
			*/
			if(!(count%5) && MODESWITCH && GRIPPERPOSUP && GRIPPERPOSDOWN && GRIPPERPOP)
			{	
				gripPIDOn = !gripPIDOn;
				printf("Switch'd\n");
			}
			if(gripPIDOn)	
			{
				if(!PIDGrip->IsEnabled()) PIDGrip->Enable();
				if(GRIPPERPOSUP && !GRIPPERPOSDOWN)
				{
					goalGripSP = 0;
				}
				else if(GRIPPERPOSDOWN && !GRIPPERPOSUP && lift->getPosition() < 0.5)
				{
					goalGripSP = 1;
				}
				/*
				else if(!GRIPPERPOSDOWN && !GRIPPERPOSUP)
				{
					goalGripSP = 0.5;
				}
				*/
				
				gripError = PIDGrip->GetError();
				gripErrorAbs = fabs(gripError);
				PIDGrip->SetSetpoint(goalGripSP);
				
				if(gripErrorAbs < 0.4) PIDGrip->SetOutputRange(-0.4, 0.6); //negative is up
				else PIDGrip->SetOutputRange(-0.9, 0.8); //negative is up
				if(gripErrorAbs > 0.0 && gripErrorAbs < 0.2)
				{
					PIDGrip->SetPID(GRIPPROPGAIN - 1.25*(1 - gripErrorAbs) + gripPropMod, GRIPINTGAIN + gripIntMod, 0.3 + 0.1*(1 - gripPIDSource->PIDGet()));
				}
				else
				{
					PIDGrip->SetPID(GRIPPROPGAIN - 1.*(1 - gripErrorAbs) + gripPropMod, 0, 0.02);
				}
				if(fabs(gripPIDSource->PIDGet()) < 0.03 && PIDGrip->GetSetpoint() == 0)
				{
					gripLatch1->Set(true);
					gripLatch2->Set(false);
				}
				else if(!(gripLatch1->Get() && PIDGrip->GetSetpoint() == 0) || 
						gripPIDSource->PIDGet() < 0) 
				{
					gripLatch1->Set(false);
					gripLatch2->Set(true);
				}
					
				if(gripLatch1->Get() && !(count%20)) 
				{
					PIDGrip->Reset();
					PIDGrip->Enable();
				}
				/*
				if(stickL.GetRawButton(1) && !(count%5)){
					gripIntMod -= 0.001;
				}
				
				if(stickR.GetRawButton(1) &&!(count%5))
				{
					gripIntMod += 0.001;
				}
				if(stickL.GetRawButton(2) && !(count%5))
				{
					gripPropMod -= 0.1;
				}
				if(stickL.GetRawButton(3) && !(count%5))
				{
					gripPropMod += 0.1;
				}
				*/
				/*
				if(LIFTBOTTOMBUTTON)
				{
					PIDGrip->Reset();
					PIDGrip->Enable();
				}
				*/
				
				if(!(count%5))
				{
					printf("Gripper pos: %f Gripper error: %f Grip power: %f \n",
							gripPIDSource->PIDGet(), PIDGrip->GetError(), gripMotor1->Get());
				}
				
			
			}

			//Calibration routine
			else
			{
				if(gripLatch1->Get() == true) 
				{
					gripLatch1->Set(false);
					gripLatch2->Set(true);
				}
				if(PIDGrip->IsEnabled()) PIDGrip->Reset();
				if(GRIPPERPOSUP)
				{
					gripMotor1->Set(-0.5);
					//gripMotor2->Set(0.5);
				}
				else if(GRIPPERPOSDOWN)
				{
					gripMotor1->Set(0.5);
					//gripMotor2->Set(-0.5);
					
				}
				else
				{
					gripMotor1->Set(0);
					//gripMotor2->Set(0);
				}
			}
			//if(!(count%5)) printf("Grip volts: %f \n", gripPot->GetVoltage());
			//if(!(count%5)) printf("Grip 1 voltage: %f \n", gripMotor1->Get());
			if(GRIPPEROPEN && !popStage)
			{
#if !(INNERGRIP)
				gripOpen1->Set(true);
				gripOpen2->Set(false);
#else
				gripOpen1->Set(false);
				gripOpen2->Set(true);
#endif
			}
			else if(!popStage)
			{
#if !(INNERGRIP)
				gripOpen1->Set(false);
				gripOpen2->Set(true);
#else
				gripOpen1->Set(true);
				gripOpen2->Set(false);
#endif
			}
			if(GRIPPERPOP && !popStage && goalGripSP == 0 && !(GRIPPEROPEN && GRIPPERCLOSE)) popStage = 1;
			if(popStage) popTime = GetClock();
			if(popStage == 1)
			{
				//popCount = count;
				popStart = GetClock();
				popStage++;
				//printf("POP START POP START POP START \n");
			}
			if(popStage == 2)
			{
#if !(INNERGRIP)
				gripOpen1->Set(true);
				gripOpen2->Set(false);
#else
				gripOpen1->Set(false);
				gripOpen2->Set(true);
#endif
				popStage++;
				//printf("GRIP OPEN GRIP OPEN GRIP OPEN \n");
			}
			if(popStage == 3 && popTime - popStart > 0.0) //used to be 0.15
			{
				gripPop1->Set(true);
				gripPop2->Set(false);
				popStage++;
				//printf("POP OUT POP OUT POP OUT \n");
			}
			if(popStage == 4 && popTime - popStart > .75) //time was 0.9
			{
				gripPop1->Set(false);
				gripPop2->Set(true);
				popStage++;
				//printf("POP IN POP IN POP IN \n");
			}
			if(popStage == 5 && popTime - popStart > 0.9)	popStage = 0; //time was 1.05
			
			if(MINIBOTSWITCH && !(MODESWITCH && stickR.GetRawButton(1) && stickL.GetRawButton(1))) miniDep->Set(miniDep->kReverse);
			else if(MINIBOTSWITCH && MODESWITCH && stickR.GetRawButton(1) && stickL.GetRawButton(1)) miniDep->Set(miniDep->kOn);
#endif			
			if(!compSwitch->Get()) compressor->Set(compressor->kReverse);
			else compressor->Set(compressor->kOff);
			/*
			if(stickR.GetRawButton(1)) compressor->Set(compressor->kReverse);
			else compressor->Set(compressor->kForward);
			*/
			Wait(0.02);				// wait for a motor update time
		}
	}
// Starts at the beginning of the autonomous period
void Robot::AutonomousInit() {
	autoLoopCounter = 0;

	encoder1.Reset();
	encoder2.Reset();
}
	void Autonomous(void)
	{
#if 1
		/*int autoMode = 0;
		autoMode |= bcd1->Get();
		autoMode <<= 1;
		autoMode |= bcd2->Get();
		autoMode <<= 1;
		autoMode |= bcd3->Get()
		;*/
		//double ignoreLineStart = 0;
		GetWatchdog().SetEnabled(true);
		GetWatchdog().SetExpiration(0.2);		
		float liftSP = 0;
		PIDLift->SetTolerance(10);
		PIDLift->SetContinuous(false);
		PIDLift->SetOutputRange(-0.75, 1); //BUGBUG
		PIDLift->SetPID(LIFTPROPGAIN, LIFTINTGAIN, LIFTDERIVGAIN);
		PIDLift->Enable();
		PIDGrip->SetSetpoint(0);
		PIDGrip->Enable();
		stopCount = 0;

		float reduction;
		int counts = 0;
		leftEncoder->Start();
		rightEncoder->Start();
		leftEncoder->Reset();
		rightEncoder->Reset();
		liftEncoder->Start();
		liftEncoder->Reset();
		leftEncoder->SetDistancePerPulse((6 * PI / 500)/reduction);
		rightEncoder->SetDistancePerPulse((6 * PI / 500)/reduction);
		double avgEncoderCount;
		float leftSpeed = .2, rightSpeed = .2;
		short int lsL,lsM,lsR;
		lineFollowDone = false;
		counts = 0;
		//int fancyWaiter = 0;
		int popstage = 0;
		goPop = false;
		double backStart = 0;
		double backTime = 0;
		double popStart = 0;
		double popTime = 0;
		bool backDone = false;
		miniDep->Set(miniDep->kForward);
		
		int liftCount = 0;
		bool disengageBrake = false;
		float lastLiftSP = 0;
		
		gripOpen1->Set(true);
		gripOpen2->Set(false);
		
		gripLatch1->Set(true);
		gripLatch2->Set(false);
		
		
		while(IsAutonomous())
		{
			if(!(counts % 100))printf("%2.2f \n",getDistance());
			if(backStart) backTime = GetClock();
			if(popStart) popTime = GetClock();
			
			//if(!ignoreLineStart)ignoreLineStart = GetClock();
			
			if(!compSwitch->Get()) compressor->Set(compressor->kReverse);
			else compressor->Set(compressor->kOff);
			
			if(counts%3 == 0)
			{
				leftValue = lsLeft->Get();
				middleValue = lsMiddle->Get();
				rightValue = lsRight->Get();
			}
			counts++;
			GetWatchdog().Feed();
			//avgEncoderCount = (leftEncoder->Get() + rightEncoder->Get())/2;
			//myRobot.SetLeftRightMotorOutputs(.2,.2);
			
			//All three/five autonomous programs will do the same thing up until 87 inches from the wall
			
			if (counts % 100 == 0){//TESTING
				if(lsLeft->Get()){
					lsL = 1;
				}else{
					lsL = 0;
				}
				if(lsRight->Get()){
					lsR = 1;
				}else{
					lsR = 0;
				}
				if(lsMiddle->Get()){
					lsM = 1;
				}else{
					lsM = 0;
				}
				//printf("Encoder: %2.2f \n", (float)avgEncoderCount);
				//printf("Distance: %2.2f SensorL:%1d SensorM:%1d SensorR:%1d\n",getDistance(),lsL,lsM,lsR);//TESTING
			}
			
#if FOLLOWLINE
			/*if(GetClock() - ignoreLineStart <= 0.5)
			{
				frontLeftMotor->Set(-.4);
				rearLeftMotor->Set(-.4);
				frontRightMotor->Set(.4);
				rearRightMotor->Set(.4);
			}
			else */if (false){//(avgEncoderCount <= SECONDBREAKDISTANCE){
				followLine();
			}
#else
			if (getDistance() > 24){
				frontLeftMotor->Set(-leftSpeed);
				rearLeftMotor->Set(-leftSpeed);
				frontRightMotor->Set(rightSpeed);
				rearRightMotor->Set(rightSpeed);
				if(leftEncoder->Get() > rightEncoder->Get() && leftSpeed == .2){
					rightSpeed += .03;
				}else if(leftEncoder->Get() >rightEncoder->Get() && leftSpeed > .2){
					leftSpeed -= .03;
				}else if(leftEncoder->Get() < rightEncoder->Get() && rightSpeed == .2){
					leftSpeed += .03;
				}else if(leftEncoder->Get() < rightEncoder->Get() && rightSpeed > .2){
					rightSpeed -= .03;
				}
			}
#endif
			else{
				if(counts % 100 == 0) {printf("DISTANCE: %2.2f\n",getDistance());}
				switch(FOLLOWLINE)
				{
				case STRAIGHTLINEMODE: //Straight line. Scores on middle column of left or right grid.
					//if(lineFollowDone && !(counts %50)) printf("Lift error: %f \n", PIDLift->GetError());
					lastLiftSP = liftSP;
					
					if(!lineFollowDone)
					{
						followLine();
					}
					else if(!PIDLift->GetSetpoint() && !popstage && !backStart)
					{
						//if(counts % 50 == 0)printf("Go backward\n");
						frontLeftMotor->Set(.3);
						rearLeftMotor->Set(.3);
						frontRightMotor->Set(-.3);
						rearRightMotor->Set(-.3);
						//PIDLift->SetSetpoint(LIFTMID2);
						liftSP = LIFTHIGH2 + 0.025;
						//fancyWaiter = counts;
						backStart = GetClock();
						printf("Setpoint set setpoint set setpoint set \n");
						/*
						if(leftValue && middleValue && rightValue)
						{
							printf("Stopped 2nd time\n");
							goPop = true;
							frontLeftMotor->Set(0);
							rearLeftMotor->Set(0);
							frontRightMotor->Set(0);
							rearRightMotor->Set(0);
							PIDLift->SetSetpoint(LIFTHIGH2);
						}
						*/
					}
#if 1				//if we've backed up for half a second and we're not popping
					else if((backTime - backStart) > 0.65 && !backDone)
					{
						printf("Stopping!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!ONE\n");
						frontLeftMotor->Set(0);
						rearLeftMotor->Set(0);
						frontRightMotor->Set(0);
						rearRightMotor->Set(0);
						//PIDLift->SetSetpoint(LIFTMID2);
						liftSP = LIFTHIGH2;
						backDone = true;
						//Wait(.01);
						//lift->brakeOff();
						//fancyWaiter = counts;
						//printf("Fancy waiter set Fancy waiter set Fancy waiter set");
					}
					/*
					else if(lift->getPosition() < LIFTHIGH2)
					{
						//Move teh lifts
						//if(counts % 100 == 0) printf("Stopping because lineFollowDone == true\n");
						PIDLift->SetSetpoint(LIFTHIGH2);
					}
					*/
					//if the lift is at the top and we're done backing up
					else if(PIDLift->GetSetpoint() && fabs(liftSP - lift->getPosition()) < 0.015 && backDone)
					{
						if(!popStart) popStart = GetClock();
						if(popstage == 0)
						{
							//lift->brakeOn();
							//PIDLift->SetSetpoint(lift->getPosition());
							popstage++;
							printf("BRAKE BRAKE BRAKE BRAKE BRAKE \n");
						}
						else if(popstage == 1 && popTime - popStart > 0.1)
						{
#if !(INNERGRIP)
							gripOpen1->Set(true);
							gripOpen2->Set(false);
#else
							gripOpen1->Set(false);
							gripOpen2->Set(true);
#endif
							popstage++;
							printf("OPEN OPEN OPEN OPEN OPEN \n");
						}
						else if(popstage == 2 && popTime - popStart > 0.35)
						{
							gripPop1->Set(true);
							gripPop2->Set(false);
							popstage++;
							printf("POP POP POP POP POP POP POP \n");
						}
						else if(popstage == 3 && popTime - popStart > 1.35)
						{
							gripPop1->Set(false);
							gripPop2->Set(true);
							
							frontLeftMotor->Set(.2);
							rearLeftMotor->Set(.2);
							frontRightMotor->Set(-.2);
							rearRightMotor->Set(-.2);
							
							popstage++;
							printf("UNPOP UNPOP UNPOP UNPOP UNPOP \n");
						}
						else if(popstage == 4 && popTime - popStart > 1.85)
						{
							printf("DOWN DOWN DOWN DOWN DOWN DOWN \n");
							frontLeftMotor->Set(0);
							rearLeftMotor->Set(0);
							frontRightMotor->Set(0);
							rearRightMotor->Set(0);
							//PIDLift->SetSetpoint(0);
							liftSP = 0;
						}
						/*
						 else if(popstage == 4 && popTime - popStart > 1.85)
						{
							printf("DOWN DOWN DOWN DOWN DOWN DOWN \n");
							frontLeftMotor->Set(min(0.3, 0.25*(popTime - popStart - 1.85)));
							rearLeftMotor->Set(min(0.3, 0.25*(popTime - popStart - 1.85)));
							frontRightMotor->Set(max(-0.3, -0.25*(popTime - popStart - 1.85)));
							rearRightMotor->Set(max(-0.3, -0.25*(popTime - popStart - 1.85)));
							//PIDLift->SetSetpoint(0);
							liftSP = 0;
							popstage++;
						}
						else if(popstage == 5 && popTime - popStart > 4.85)
						{
							frontLeftMotor->Set(0);
							rearLeftMotor->Set(0);
							frontRightMotor->Set(0);
							rearRightMotor->Set(0);
						}
						*/
					}
					
					//Start tele-op lift code
					if(!lift->isBraking() && !disengageBrake)
					{
						PIDLift->SetSetpoint(liftSP);
						if(liftSP == 0 && liftPIDSource->PIDGet() < 0.1)
						{
							//PIDLift->SetPID(LIFTPROPGAIN, LIFTINTGAIN, 3*LIFTDERIVGAIN);
							PIDLift->SetOutputRange(-liftPIDSource->PIDGet() - 0.1, 1);
						}
						else PIDLift->SetOutputRange(-0.75, 1);
					}
					if(lift->isBraking() && lastLiftSP != liftSP)
					{
						PIDLift->SetSetpoint(lift->getPosition() + 0.04);
						PIDLift->SetPID(11.5 + 2*lift->getPosition(), LIFTINTGAIN + 0.4 + 3*lift->getPosition()/10, 0);
						lift->brakeOff();
						disengageBrake = true;
						if(!liftCount) liftCount = counts;
					}
					//set brake (because near)
					if(fabs(PIDLift->GetError()) < 0.015 && !lift->isBraking() && !disengageBrake)
					{
						if(liftCount == 0) liftCount = counts;
						if(counts - liftCount > 1000)
						{
							PIDLift->Reset();
							liftMotor1->Set(LIFTNEUTRALPOWER);
							liftMotor2->Set(LIFTNEUTRALPOWER);
							Wait(0.02);
							lift->brakeOn();
							Wait(0.02);
							liftMotor1->Set(0.0);
							liftMotor2->Set(0.0);
							PIDLift->Enable();
							//PIDLift->SetSetpoint(lift->getPosition());
							liftCount = 0;
						}
						if(counts%3000) printf("Braking/Not PID \n");
					}
					if(lift->isBraking() && !(counts%100000)) PIDLift->SetSetpoint(lift->getPosition());
					if(fabs(PIDLift->GetError()) < 0.01 && disengageBrake && counts - liftCount > 1000)
					{
						disengageBrake = false;
						PIDLift->SetPID(LIFTPROPGAIN, LIFTINTGAIN, LIFTDERIVGAIN);
						liftCount = 0;
					}
					//End tele-op lift code
#endif
					//myRobot.SetLeftRightMotorOutputs(0,0);
					break;
				case NOLINEMODE: //Fork turn left. Scores on far right column of left grid.
					lineFollowDone = true;
					if(!lineFollowDone){}
					else if(!PIDLift->GetSetpoint() && !popstage && !backStart)
					{
					//if(counts % 50 == 0)printf("Go backward\n");
						frontLeftMotor->Set(.3);
						rearLeftMotor->Set(.3);
						frontRightMotor->Set(-.3);
						rearRightMotor->Set(-.3);
						//PIDLift->SetSetpoint(LIFTMID2);
						liftSP = LIFTHIGH2;
						//fancyWaiter = counts;
						backStart = GetClock();
						printf("Setpoint set setpoint set setpoint set \n");
						/*
						if(leftValue && middleValue && rightValue)
						{
							printf("Stopped 2nd time\n");
							goPop = true;
							frontLeftMotor->Set(0);
							rearLeftMotor->Set(0);
							frontRightMotor->Set(0);
							rearRightMotor->Set(0);
							PIDLift->SetSetpoint(LIFTHIGH2);
						}
						*/
					}
#if 1				//if we've backed up for half a second and we're not popping
					else if((backTime - backStart) > 0.65 && !backDone)
					{
						printf("Stopping!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!ONE\n");
						frontLeftMotor->Set(0);
						rearLeftMotor->Set(0);
						frontRightMotor->Set(0);
						rearRightMotor->Set(0);
						//PIDLift->SetSetpoint(LIFTMID2);
						liftSP = LIFTHIGH2;
						backDone = true;
						//Wait(.01);
						//lift->brakeOff();
						//fancyWaiter = counts;
						//printf("Fancy waiter set Fancy waiter set Fancy waiter set");
					}
					/*
					else if(lift->getPosition() < LIFTHIGH2)
					{
						//Move teh lifts
						//if(counts % 100 == 0) printf("Stopping because lineFollowDone == true\n");
						PIDLift->SetSetpoint(LIFTHIGH2);
					}
					*/
					//if the lift is at the top and we're done backing up
					else if(PIDLift->GetSetpoint() && fabs(liftSP - lift->getPosition()) < 0.015 && backDone)
					{
						if(!popStart) popStart = GetClock();
						if(popstage == 0)
						{
							//lift->brakeOn();
							//PIDLift->SetSetpoint(lift->getPosition());
							popstage++;
							printf("BRAKE BRAKE BRAKE BRAKE BRAKE \n");
						}
						else if(popstage == 1 && popTime - popStart > 0.1)
						{
#if !(INNERGRIP)
							gripOpen1->Set(true);
							gripOpen2->Set(false);
#else
							gripOpen1->Set(false);
							gripOpen2->Set(true);
#endif
							popstage++;
							printf("OPEN OPEN OPEN OPEN OPEN \n");
						}
						else if(popstage == 2 && popTime - popStart > 0.35)
						{
							gripPop1->Set(true);
							gripPop2->Set(false);
							popstage++;
							printf("POP POP POP POP POP POP POP \n");
						}
						else if(popstage == 3 && popTime - popStart > 1.35)
						{
							gripPop1->Set(false);
							gripPop2->Set(true);
							
							frontLeftMotor->Set(.2);
							rearLeftMotor->Set(.2);
							frontRightMotor->Set(-.2);
							rearRightMotor->Set(-.2);
							
							popstage++;
							printf("UNPOP UNPOP UNPOP UNPOP UNPOP \n");
						}
						else if(popstage == 4 && popTime - popStart > 1.85)
						{
							printf("DOWN DOWN DOWN DOWN DOWN DOWN \n");
							frontLeftMotor->Set(0);
							rearLeftMotor->Set(0);
							frontRightMotor->Set(0);
							rearRightMotor->Set(0);
							//PIDLift->SetSetpoint(0);
							liftSP = 0;
						}
					}
					
					//Start tele-op lift code
					if(!lift->isBraking() && !disengageBrake)
					{
						PIDLift->SetSetpoint(liftSP);
						if(liftSP == 0 && liftPIDSource->PIDGet() < 0.1) //BUGBUG
						{
							//PIDLift->SetPID(LIFTPROPGAIN, LIFTINTGAIN, 3*LIFTDERIVGAIN);
							PIDLift->SetOutputRange(-liftPIDSource->PIDGet() - 0.1, 1.); //BUGBUG
						}
						else PIDLift->SetOutputRange(-0.75, 1.); //BUGBUG
					}
					if(lift->isBraking() && lastLiftSP != liftSP)
					{
						PIDLift->SetSetpoint(lift->getPosition() + 0.04);
						PIDLift->SetPID(11.5 + 2*lift->getPosition(), LIFTINTGAIN + 0.4 + 3*lift->getPosition()/10, 0);
						lift->brakeOff();
						disengageBrake = true;
						if(!liftCount) liftCount = counts;
					}
					//set brake (because near)
					if(fabs(PIDLift->GetError()) < 0.015 && !lift->isBraking() && !disengageBrake)
					{
						if(liftCount == 0) liftCount = counts;
						if(counts - liftCount > 1000)
						{
							PIDLift->Reset();
							liftMotor1->Set(LIFTNEUTRALPOWER);
							liftMotor2->Set(LIFTNEUTRALPOWER);
							Wait(0.02);
							lift->brakeOn();
							Wait(0.02);
							liftMotor1->Set(0.0);
							liftMotor2->Set(0.0);
							PIDLift->Enable();
							//PIDLift->SetSetpoint(lift->getPosition());
							liftCount = 0;
						}
						if(counts%3000) printf("Braking/Not PID \n");
					}
					if(lift->isBraking() && !(counts%100000)) PIDLift->SetSetpoint(lift->getPosition());
					if(fabs(PIDLift->GetError()) < 0.01 && disengageBrake && counts - liftCount > 1000)
					{
						disengageBrake = false;
						PIDLift->SetPID(LIFTPROPGAIN, LIFTINTGAIN, LIFTDERIVGAIN);
						liftCount = 0;
					}
					//End tele-op lift code
#endif
					//myRobot.SetLeftRightMotorOutputs(0,0);
					break;
				case FORKRIGHTMODE://Fork turn right. Scores on far left column of right grid.
					if(leftEncoder->GetDistance() <= rightEncoder->GetDistance() + 6)
					{
						frontLeftMotor->Set(.2);
						rearLeftMotor->Set(.2);
						frontRightMotor->Set(0);
						rearRightMotor->Set(0);
					}
					else if(getDistance() >= SCOREDISTANCE) 
					{
						followLine();
					}
					//score here				
					//myRobot.SetLeftRightMotorOutputs(0,0);
					break;
				}
			}
		}
		/*frontRightMotor->Set(0);
		rearRightMotor->Set(0);
		frontLeftMotor->Set(0);
		rearLeftMotor->Set(0);*/
		Wait(.02);
#endif
	}
Beispiel #22
0
	/**
	 * Drive left & right motors for 2 seconds then stop
	 */ 
	void Autonomous()
	{
		init();
		lcd->PrintfLine(DriverStationLCD::kUser_Line1, "Entered Autonomous");
		driveTrain.SetSafetyEnabled(false);
		bool checkBox1 = SmartDashboard::GetBoolean("Checkbox 1");
		m_FromAutonomous = true;
		//float rightDriveSpeed = -1.0;
		//float leftDriveSpeed = -1.0;
		//int rangeToWallClose = 60;
		//int rangeToWallFar = 120;
		//Initialize encoder.
		//int distanceToShoot = 133;
		//int shootDelay = 0;
		//ballGrabber.elevatorController.SetSetpoint(PHOENIX2014_INITIAL_AUTONOMOUS_ELEVATOR_ANGLE);
		//TODO Remove encoders from code??
		driveDistanceRight.Reset();
		driveDistanceLeft.Reset();
		driveDistanceRight.SetDistancePerPulse(PHOENIX2014_DRIVE_DISTANCE_PER_PULSE_RIGHT);
		driveDistanceLeft.SetDistancePerPulse(PHOENIX2014_DRIVE_DISTANCE_PER_PULSE_LEFT);
		driveDistanceRight.Start();
		driveDistanceLeft.Start();
		//int printDelay = 0;
		float minDistance = 52.0;  // Closer to the wall than this is too close
		float maxDistance = 12.0*11.0; // Once at least this close, within shooting range
		//float closeDistance = maxDistance + 24.0;
		float autoDriveSpeed = 0.55;
		//float autoDriveSlowSpeed = 0.38;
		int time = 0;
		int maxDriveLoop = 4*200; // 4 seconds @200 times/sec

		bool shootingBall = false;
		bool wantFirstShot = true;

		if(checkBox1 == false){
			int printDelay = 0;
			//Ultrasonic Autonomous
			//bool isInRange = false;
			while(IsAutonomous() && IsEnabled())
			{
				float currentDistance = frontUltrasonic.GetAverageDistance();
				// Transition isInRange from false to true once
				if((minDistance < currentDistance) && (currentDistance < maxDistance)){
					//isInRange = true;
				}
				time++;
				bool motorDriveTimeExceeded = time > maxDriveLoop;
				bool motorMinMet = time > m_MinDriveLoop;
				if(/*isInRange ||*/ motorMinMet){
					driveTrain.TankDrive(0.0,0.0);
					if((ballGrabber.elevatorAngleSensor.GetVoltage() > PHOENIX2014_AUTONOMOUS_ELEVATOR_ANGLE - 0.1) &&
							(ballGrabber.elevatorAngleSensor.GetVoltage() < PHOENIX2014_AUTONOMOUS_ELEVATOR_ANGLE + 0.1)){
						//Enough to cover break release and start winding again.
						
						shootingBall = shooter.OperateShooter(wantFirstShot);
					}
					if(shootingBall == true){
						wantFirstShot = false;
					}
				}
				else if(motorDriveTimeExceeded){
					driveTrain.TankDrive(0.0,0.0);
				}
				else{
					//if((currentDistance < closeDistance) && motorMinMet){
					//	autoDriveSpeed = autoDriveSlowSpeed;
					//}
					driveTrain.TankDrive(-0.97 * autoDriveSpeed, -1.0 * autoDriveSpeed);//the DriveTrain is BACKWARD
				}
				ballGrabber.RunElevatorAutonomous(PHOENIX2014_AUTONOMOUS_ELEVATOR_ANGLE);
				printDelay = printDelay++;
				if(printDelay >= 200){
					lcd->Clear();
					lcd->PrintfLine(DriverStationLCD::kUser_Line1, "In Autonomous");
					shooter.DisplayDebugInfo(DriverStationLCD::kUser_Line2, lcd);
					shooter.PrintShooterState(DriverStationLCD::kUser_Line3, lcd);
					lcd->PrintfLine(DriverStationLCD::kUser_Line4, "Ulra=%f", frontUltrasonic.GetAverageDistance());
					//lcd->PrintfLine(DriverStationLCD::kUser_Line5, "CEV=%f", ballGrabber.elevatorAngleSensor.GetVoltage());
					//lcd->PrintfLine(DriverStationLCD::kUser_Line6, "DEV=%f", ballGrabber.m_desiredElevatorVoltage);
					lcd->UpdateLCD();
					printDelay = 0;
				}
				Wait(0.005);
			}
			lcd->Clear();
			lcd->UpdateLCD();
			lcd->PrintfLine(DriverStationLCD::kUser_Line2, "Exiting Autonomous");
		} else {
			//Timer Autonomous
			driveTrain.TankDrive(-0.5,-0.5);
			ballGrabber.DriveElevatorTestMode(-1.0);
			lcd->Clear();
			lcd->PrintfLine(DriverStationLCD::kUser_Line1, "Skip Auto");
			lcd->PrintfLine(DriverStationLCD::kUser_Line2, "CheckBox Checked");
			lcd->UpdateLCD();
			Wait(2.0);
			bool shooting = true;
			driveTrain.TankDrive(0.0,0.0);
			int counter = 0;
			while(counter < 600){
				shooter.OperateShooter(shooting);
				Wait(0.005);
			}
		}
	}
Beispiel #23
0
	/**
	 * Runs the motors with Mecanum drive.
	 */
	void OperatorControl()//teleop code
	{
		robotDrive.SetSafetyEnabled(false);
		gyro.Reset();
		grabEncoder.Reset();
		timer.Start();
		timer.Reset();
		double liftHeight = 0; //variable for lifting thread
		int liftHeightBoxes = 0; //another variable for lifting thread
		int liftStep = 0; //height of step in inches
		int liftRamp = 0; //height of ramp in inches
		double grabPower;
		bool backOut;
		uint8_t toSend[10];//array of bytes to send over I2C
		uint8_t toReceive[10];//array of bytes to receive over I2C
		uint8_t numToSend = 1;//number of bytes to send
		uint8_t numToReceive = 0;//number of bytes to receive
		toSend[0] = 1;//set the byte to send to 1
		i2c.Transaction(toSend, 1, toReceive, 0);//send over I2C
		bool isGrabbing = false;//whether or not grabbing thread is running
		bool isLifting = false;//whether or not lifting thread is running
		bool isBraking = false;//whether or not braking thread is running
		float driveX = 0;
		float driveY = 0;
		float driveZ = 0;
		float driveGyro = 0;
		bool liftLastState = false;
		bool liftState = false; //button pressed
		double liftLastTime = 0;
		double liftTime = 0;
		bool liftRan = true;
		Timer switchTimer;
		Timer grabTimer;
		switchTimer.Start();
		grabTimer.Start();


		while (IsOperatorControl() && IsEnabled())
		{
			// Use the joystick X axis for lateral movement, Y axis for forward movement, and Z axis for rotation.
			// This sample does not use field-oriented drive, so the gyro input is set to zero.

			toSend[0] = 1;
			numToSend = 1;


			driveX = driveStick.GetRawAxis(Constants::driveXAxis);//starts driving code
			driveY = driveStick.GetRawAxis(Constants::driveYAxis);
			driveZ = driveStick.GetRawAxis(Constants::driveZAxis);
			driveGyro = gyro.GetAngle() + Constants::driveGyroTeleopOffset;


			if (driveStick.GetRawButton(Constants::driveOneAxisButton)) {//if X is greater than Y and Z, then it will only go in the direction of X
				toSend[0] = 6;
				numToSend = 1;

				if (fabs(driveX) > fabs(driveY) && fabs(driveX) > fabs(driveZ)) {
					driveY = 0;
					driveZ = 0;
				}
				else if (fabs(driveY) > fabs(driveX) && fabs(driveY) > fabs(driveZ)) {//if Y is greater than X and Z, then it will only go in the direction of Y
					driveX = 0;
					driveZ = 0;
				}
				else {//if Z is greater than X and Y, then it will only go in the direction of Z
					driveX = 0;
					driveY = 0;
				}
			}

			if (driveStick.GetRawButton(Constants::driveXYButton)) {//Z lock; only lets X an Y function
				toSend[0] = 7;
				driveZ = 0;//Stops Z while Z lock is pressed
			}

			if (!driveStick.GetRawButton(Constants::driveFieldLockButton)) {//robot moves based on the orientation of the field
				driveGyro = 0;//gyro stops while field lock is enabled
			}

			driveX = Constants::scaleJoysticks(driveX, Constants::driveXDeadZone, Constants::driveXMax * (.5 - (driveStick.GetRawAxis(Constants::driveThrottleAxis) / 2)), Constants::driveXDegree);
			driveY = Constants::scaleJoysticks(driveY, Constants::driveYDeadZone, Constants::driveYMax * (.5 - (driveStick.GetRawAxis(Constants::driveThrottleAxis) / 2)), Constants::driveYDegree);
			driveZ = Constants::scaleJoysticks(driveZ, Constants::driveZDeadZone, Constants::driveZMax * (.5 - (driveStick.GetRawAxis(Constants::driveThrottleAxis) / 2)), Constants::driveZDegree);
			robotDrive.MecanumDrive_Cartesian(driveX, driveY, driveZ, driveGyro);//makes the robot drive




			if (pdp.GetCurrent(Constants::grabPdpChannel) < Constants::grabManualCurrent) {
				pickup.setGrabber(Constants::scaleJoysticks(grabStick.GetX(), Constants::grabDeadZone, Constants::grabMax, Constants::grabDegree)); //defines the grabber
				if(grabTimer.Get() < 1) {
					toSend[0] = 6;
				}
			}
			else {
				pickup.setGrabber(0);
				grabTimer.Reset();
				toSend[0] = 6;
			}

			if (Constants::grabLiftInverted) {
				pickup.setLifter(-Constants::scaleJoysticks(grabStick.GetY(), Constants::liftDeadZone, Constants::liftMax, Constants::liftDegree)); //defines the lifter
			}
			else {
				pickup.setLifter(Constants::scaleJoysticks(grabStick.GetY(), Constants::liftDeadZone, Constants::liftMax, Constants::liftDegree)); //defines the lifter
			}


			SmartDashboard::PutNumber("Lift Power", Constants::scaleJoysticks(grabStick.GetY(), Constants::liftDeadZone, Constants::liftMax, Constants::liftDegree));
			SmartDashboard::PutBoolean("Is Lifting", isLifting);

			if (Constants::scaleJoysticks(grabStick.GetY(), Constants::liftDeadZone, Constants::liftMax, Constants::liftDegree) != 0 || isLifting) { //if the robot is lifting
				isBraking = false; //stop braking thread
				SmartDashboard::PutBoolean("Braking", false);
			}
			else if(!isBraking) {
				isBraking = true; //run braking thread
				pickup.lifterBrake(isBraking);//brake the pickup
			}



			if (grabStick.GetRawButton(Constants::liftFloorButton)) {
				liftHeight = 0;
				pickup.lifterPosition(liftHeight, isLifting, grabStick);//start lifting thread
				liftRan = true;
			}

			liftTime = timer.Get();
			liftState = grabStick.GetRawButton(Constants::liftButton);

			if (liftState) { //if button is pressed
				if (!liftLastState) {
					if (liftTime - liftLastTime < Constants::liftMaxTime) {
						if (liftHeightBoxes < Constants::liftMaxHeightBoxes) {
							liftHeightBoxes++; //adds 1 to liftHeightBoxes
						}
					}
					else {
						liftHeightBoxes = 1;
						liftRamp = 0;
						liftStep = 0;
					}
				}
				liftLastTime = liftTime;
				liftLastState = true;
				liftRan = false;
			}
			else if (grabStick.GetRawButton(Constants::liftRampButton)) {
				if (liftTime - liftLastTime > Constants::liftMaxTime) {
					liftHeight = 0;
					liftStep = 0;
				}
				liftRamp = 1; //prepares to go up ramp
				liftLastTime = liftTime;
				liftRan = false;
			}
			else if (grabStick.GetRawButton(Constants::liftStepButton)) {
				if (liftTime - liftLastTime > Constants::liftMaxTime) {
					liftHeight = 0;
					liftRamp = 0;
				}
				liftStep = 1; //prepares robot for step
				liftLastTime = liftTime;
				liftRan = false;
			}
			else {
				if (liftTime - liftLastTime > Constants::liftMaxTime && !liftRan) {

					liftHeight = liftHeightBoxes * Constants::liftBoxHeight + liftRamp * Constants::liftRampHeight + liftStep * Constants::liftStepHeight; //sets liftHeight
					if (liftHeightBoxes > 0) {
						liftHeight -= Constants::liftBoxLip;
					}
					pickup.lifterPosition(liftHeight, isLifting, grabStick);//start lifting thread
					liftRan = true;
				}
				liftLastState = false;
			}

			if (grabStick.GetRawButton(Constants::grabToteButton)) {//if grab button is pressed
				grabPower = Constants::grabToteCurrent;
				backOut = true;
				if (!isGrabbing) {
					pickup.grabberGrab(isGrabbing, grabPower, backOut, grabStick);//start grabber thread
				}
			}
			else if (grabStick.GetRawButton(Constants::grabBinButton)) {//if grab button is pressed
				grabPower = Constants::grabBinCurrent;

				backOut = false;
				if (!isGrabbing) {
					pickup.grabberGrab(isGrabbing, grabPower, backOut, grabStick);//start grabber thread
				}
			}
			else if (grabStick.GetRawButton(Constants::grabChuteButton)) {//if grab button is presset
				SmartDashboard::PutBoolean("Breakpoint -2", false);
				SmartDashboard::PutBoolean("Breakpoint -1", false);
				SmartDashboard::PutBoolean("Breakpoint 0", false);
				SmartDashboard::PutBoolean("Breakpoint 1", false);
				SmartDashboard::PutBoolean("Breakpoint 2", false);
				SmartDashboard::PutBoolean("Breakpoint 3", false);
				SmartDashboard::PutBoolean("Breakpoint 4", false);
				//Wait(.5);
				if (!isGrabbing) {
					//pickup.grabberChute(isGrabbing, grabStick);//start grabber thread
				}
			}

			//determines what the LED's look like based on what the Robot is doing
			if (isGrabbing) {
				toSend[0] = 5;
				numToSend = 1;
			}
			if (isLifting) {//if the grabbing thread is running
				if (Constants::encoderToDistance(liftEncoder.Get(),Constants::liftEncoderTicks, Constants::liftEncoderBase, Constants::liftEncoderRadius) < liftHeight) {
					toSend[0] = 3;
				}
				else {
					toSend[0] = 4;
				}
				numToSend = 1;//sends 1 byte to I2C
			}

			if(!grabOuterLimit.Get()) { //tells if outer limit is hit with lights
				if(switchTimer.Get() < 1) {
					toSend[0] = 6;
				}
			}
			else {
				switchTimer.Reset();
			}

			if (driveStick.GetRawButton(Constants::sneakyMoveButton)) {
				toSend[0] = 0;
				numToSend = 1;
			}

			float distance = prox.GetVoltage() * Constants::ultrasonicVoltageToInches / 12;	// distance from ultrasonic sensor
			float rotations = (float) liftEncoder.Get();	// rotations on encoder
			SmartDashboard::PutNumber("Distance", distance);	// write stuff to smart dash
			SmartDashboard::PutNumber("Current", pdp.GetCurrent(Constants::grabPdpChannel));
			SmartDashboard::PutNumber("LED Current", pdp.GetCurrent(Constants::ledPdpChannel));
			SmartDashboard::PutNumber("Lift Encoder", rotations);
			SmartDashboard::PutNumber("Lift Height", liftHeight);
			SmartDashboard::PutNumber("Grab Encoder", grabEncoder.Get());
			SmartDashboard::PutBoolean("Grab Inner", grabInnerLimit.Get());
			SmartDashboard::PutBoolean("Grab Outer", grabOuterLimit.Get());
			SmartDashboard::PutNumber("Drive Front Left Current", pdp.GetCurrent(Constants::driveFrontLeftPin));
			SmartDashboard::PutNumber("Drive Front Right Current", pdp.GetCurrent(Constants::driveFrontRightPin));
			SmartDashboard::PutNumber("Drive Rear Left Current", pdp.GetCurrent(Constants::driveRearLeftPin));
			SmartDashboard::PutNumber("Drive Rear Right Current", pdp.GetCurrent(Constants::driveRearRightPin));
			SmartDashboard::PutNumber("Throttle", grabStick.GetZ());


			i2c.Transaction(toSend, 1, toReceive, 0);//send and receive information from arduino over I2C
			Wait(0.005); // wait 5ms to avoid hogging CPU cycles
		} //end of teleop
		isBraking = false;
		toSend[0] = 0;
		i2c.Transaction(toSend, numToSend, toReceive, numToReceive);
	}
	void OperatorControl()//TODO remember that this is the beginning of operator controll
	{
		printf(
				"****************************VERSION .00017****************************\n");
#if CAMERA
		AxisCamera &camera = AxisCamera::GetInstance("10.26.43.11");
#endif
		GetWatchdog().SetEnabled(true);
		shooter_reset ->Start();
#if TIMER_RESET
		pid_code_timer->Reset();
#endif
		front_shooter_encoder->Reset();
		back_shooter_encoder->Reset();
		/*float prev_error_front = 0;
		 float prev_error_back = 0;
		 int test_back = 5;
		 int test_front = 6;*/
		integral_back = 0.0;
		integral_front = 0.0;
		desired_RPS_control = 0.0;
		//RETRACTS PISTON WHEN TELEOP STARTS

		override_timer->Reset();
		stabilizing_timer ->Reset();
		retraction_timer ->Reset();

		shooter_fire_piston_A ->Set(true);
		shooter_fire_piston_B ->Set(false);
		shooter_stop_timer->Start();
		while (IsOperatorControl() && IsEnabled())
		{
			GetWatchdog().Feed();
			//---------------------Display Output---------------------------
			dsLCD = DriverStationLCD::GetInstance();
			DriverLCD();
			//printf("PRINTFS\n");
			printfs();

			//-------------------------Climber-----------------------------
			//climber_code();
			//dumb_climber_code();
			climber_state();

			//---------------------------Drive-----------------------------
			arcade_tank_code();
			constant_RPS_code();
			//dumb_drive_code();   // In case our smart code doesnt work

			//--------------------------PID-------------------------------
			integral_reset();

			//-------------------------Shooter----------------------------
			pneumatic_shooter_angler_code();
			pneumatic_feeder_code();
			//dump_code();
			//intelligent_shooter();

			//-------------------------Test Code--------------------------
			//camera_test();
			//cin_code_get();
			//prev_error_back = RPS_control_code(shooter_motor_back, back_shooter_encoder, prev_error_back, desired_RPS_control);
			//interpolated_test_code();
			//pointer_test(shooter_motor_front);
			//PIDController(first_pterm, iterm, dterm, front_shooter_encoder, shooter_motor_front);

			//------------cRIO Housekeeping Timing-MUST HAVE--------------
			Wait(0.005);

		}//while operator
	}//operator ctrl
	void Autonomous()
	{
		GetWatchdog().SetEnabled(true);
		autonomous_timer->Reset();
#if TIMER_RESET
		pid_code_timer->Reset();
#endif
		front_shooter_encoder->Reset();
		back_shooter_encoder->Reset();
		shooter_angle_1 ->Set(true);
		shooter_angle_2 ->Set(false);
		retraction_timer->Reset();
		stabilizing_timer->Reset();
		override_timer->Reset();
		//shooter_motor_front->Set(0.8);
		//shooter_motor_front->Set(0.8);
		integral_back = 0.0;
		integral_front = 0.0;
		error_back = 0.0;
		error_front = 0.0;
		desired_RPS_control = back_position_RPS_1;
		smart_autonomous_state = unstable;//default is unstable


		while (IsAutonomous() && IsEnabled())
		{
			printfs();
			GetWatchdog().Feed();
			RPS_control_code(desired_RPS_control);
			Wait(.001);
			if (autonomous_timer->Get() >= first_fire && autonomous_timer->Get() <(first_fire + 1))//fire
			{
				shooter_fire_piston_A ->Set(false);
				shooter_fire_piston_B ->Set(true);
			}
			if (autonomous_timer->Get() >= first_retract && autonomous_timer->Get() < (first_retract + 2))//retract

			{
				shooter_fire_piston_A ->Set(true);
				shooter_fire_piston_B ->Set(false);
			}
			if (autonomous_timer->Get() >= second_fire && autonomous_timer->Get() < (second_fire + 1))//fire

			{
				shooter_fire_piston_A ->Set(false);
				shooter_fire_piston_B ->Set(true);
			}
			if (autonomous_timer->Get() >= second_retract && autonomous_timer->Get() < (second_retract +2))//retract

			{
				shooter_fire_piston_A ->Set(true);
				shooter_fire_piston_B ->Set(false);
			}
			if (autonomous_timer->Get() >= third_fire && autonomous_timer->Get() < (third_fire + 1))//fire

			{
				shooter_fire_piston_A ->Set(false);
				shooter_fire_piston_B ->Set(true);
			}
			if (autonomous_timer->Get() >= third_retract)//final retract

			{
				shooter_fire_piston_A ->Set(true);
				shooter_fire_piston_B ->Set(false);
			}
		}

		autonomous_timer->Reset();
	}
Beispiel #26
0
	void Autonomous()
	{
		GetWatchdog().SetEnabled(false);
		Timer* hotGoalTimer = new Timer();
		Timer* reloadTimer = new Timer();
		Timer* intakeTimer = new Timer();
		Timer* intakeDropTimer = new Timer();
		bool goalFound = false;
		//bool rightSideHot = false;
		hotGoalTimer->Reset();
		hotGoalTimer->Start();
		gyro->Reset();
		leftEnco->Reset();
		rightEnco->Reset();
		LEDLight->Set(Relay::kForward);

		//Find out the type of autonomous we are using
		int autonType = (int)SmartDashboard::GetNumber(NUM_BALL_AUTO);
		if(autonType == 2)//Set the auton mode to two if we are doing a two ball auto
		{
			autonMode = TWO_BALL_AUTON;
			autonStep = AUTON_TWO_WAIT_FOR_INTAKE;
		}
		else//Set the auton to one if the value on SD is set to 1 or another random value
		{
			autonMode = ONE_BALL_AUTON;
			autonStep = AUTON_ONE_FIND_HOT;
		}

		//Bring the intake down
		intake->DropIntake();
		intakeDropTimer->Reset();
		intakeDropTimer->Start();

		while(IsAutonomous() && !IsDisabled())
		{
			rpi->Read();
			lcd->Printf(DriverStationLCD::kUser_Line1, 1, "L: %f", leftEnco->GetDistance());
			lcd->Printf(DriverStationLCD::kUser_Line2, 1, "R: %f", rightEnco->GetDistance());
			lcd->Printf(DriverStationLCD::kUser_Line3, 1, "T: %f", hotGoalTimer->Get());
			lcd->Printf(DriverStationLCD::kUser_Line4, 1, "i: %i", rpi->GetMissingPacketcount());
			lcd->Printf(DriverStationLCD::kUser_Line5, 1, "%i", rpi->GetXPos());
			lcd->Printf(DriverStationLCD::kUser_Line6, 1, "%i", rpi->GetYPos());
			lcd->UpdateLCD();
			LEDLight->Set(Relay::kForward);
			if(autonMode == ONE_BALL_AUTON)
			{
				switch(autonStep)
				{
				case AUTON_ONE_FIND_HOT:
					//Reload the catapult and find the hot goal
					rpi->Read();
					if(!goalFound)
					{
						//This is put into an if statement to protect against the 
						//rpi finding the hot goal and then losing it
						goalFound = ((rpi->GetXPos() != RPI_ERROR_VALUE) ||
								(rpi->GetYPos() != RPI_ERROR_VALUE));
					}
					//Wait for the goal to be hot and the intake to move down
					if(((goalFound) || (hotGoalTimer->Get() >= 6.75)) && intakeDropTimer->Get() >= INTAKE_DROP_WAIT)
					{
						autonStep = AUTON_ONE_SHOOT;
						catapult->StartRelease();
					}
					break;
				case AUTON_ONE_SHOOT:
					//Shoot the catapult
					if(!catapult->ReleaseHold())
					{
						//Move on to the next step when the catapult is released
						autonStep = AUTON_ONE_WAIT;
						//Start the wait timer
						reloadTimer->Reset();
						reloadTimer->Start();
					}
					break;
				case AUTON_ONE_WAIT:
					if(reloadTimer->Get() >= CATAPULT_WAIT_TIME)
					{
						autonStep = AUTON_ONE_DRIVE_FORWARDS;
						reloadTimer->Stop();
						//Start reloading the catapult
						catapult->StartLoad();
						gyro->Reset();
					}
					break;
				case AUTON_ONE_DRIVE_FORWARDS:
					//Drive forwards into the alliance zone and reload the catapult
					if((!GyroDrive(0, 0.75, 36)) && (!(bool)catapult->Load()))
					{
						autonStep = AUTON_END;
					}
					break;
				case AUTON_END:
					break;
				}
			}
			else if(autonMode == TWO_BALL_AUTON)
			{
				switch(autonStep)
				{
				/*case AUTON_TWO_RELOAD:
					//Determine if the hot goal is on the right
					if((rpi->GetXPos() != RPI_ERROR_VALUE) && 
							(rpi->GetYPos() != RPI_ERROR_VALUE))
					{
						rightSideHot = true;
					}
					//Reload the catapult
					if(!((bool)catapult->Load()))
					{
						autonStep = AUTON_TWO_FIRST_SHOOT;
						catapult->StartShoot();
					}
					if((goalFound))
					{
						//If the goal is found, the right side is hot and we can go to the next step
						rightSideHot = true;
						autonStep = AUTON_TWO_FIRST_SHOOT;
					}
					else if(hotGoalTimer->Get() >= 0.5)
					{
						//If the timer runs of, the right side is not hot and we can go to the next step
						rightSideHot = false;
						autonStep = AUTON_TWO_FIRST_TURN;
					}
					break;*/
				case AUTON_TWO_WAIT_FOR_INTAKE:
					//wait for the intake to drop down
					if(intakeDropTimer->Get() >= INTAKE_DROP_WAIT)
					{
						autonStep = AUTON_TWO_FIRST_SHOOT;
						catapult->StartShoot();
					}
					break;
				case AUTON_TWO_FIRST_SHOOT:
					if(catapult->GetLoadingState() == LOAD_RELEASE_TENSION)
					{
						intake->RollIn();
					}
					if(!((bool)catapult->Shoot()))
					{
						autonStep = AUTON_TWO_INTAKE;
						intakeTimer->Reset();
						intakeTimer->Start();
					}
					break;
				case AUTON_TWO_INTAKE:
					intake->RollIn();
					if(intakeTimer->Get() >= 1.5)
					{
						intake->Stop();
						intakeTimer->Stop();
						autonStep = AUTON_TWO_SECOND_SHOOT;
						catapult->StartRelease();
					}
					break;
				case AUTON_TWO_SECOND_SHOOT:
					if(!catapult->ReleaseHold())
					{
						autonStep = AUTON_TWO_WAIT;
						reloadTimer->Reset();
						reloadTimer->Start();
					}
					break;
				case AUTON_TWO_WAIT:
					if(reloadTimer->Get() >= 0.5)
					{
						reloadTimer->Stop();
						leftEnco->Reset();
						rightEnco->Reset();
						catapult->StartLoad();
						gyro->Reset();
						autonStep = AUTON_TWO_DRIVE_FORWARDS;
					}
					break;
				case AUTON_TWO_DRIVE_FORWARDS:
					if((!GyroDrive(0, 0.9, 36)) && (!((bool)catapult->Load())))
					{
						autonStep = AUTON_END;
					}
					break;
					/*case AUTON_TWO_FIRST_TURN:
					//Turn to the left 5* if the right goal is not hot
					if(!rightSideHot)
					{
						if(!GyroTurn(-5, 0.5))
						{
							autonStep = AUTON_TWO_FIRST_SHOOT;
						}
					}
					else
					{
						autonStep = AUTON_TWO_FIRST_SHOOT;
					}
					break;
				case AUTON_TWO_FIRST_SHOOT:
					//Release the catapult to shoot
					if(!catapult->ReleaseHold())
					{
						autonStep = AUTON_TWO_FIRST_WAIT;
						reloadTimer->Reset();
						reloadTimer->Start();
					}
					break;
				case AUTON_TWO_FIRST_WAIT:
					if(reloadTimer->Get() >= CATAPULT_WAIT_TIME)
					{
						autonStep = AUTON_TWO_SECOND_TURN;
						catapult->StartLoad();
						reloadTimer->Stop();
					}
					break;
				case AUTON_TWO_SECOND_TURN:
					//Turn the robot so it's facing forwards and reload the catapult
					if((!GyroTurn(0, 0.5)) && (!(bool)catapult->Load()))
					{
						autonStep = AUTON_TWO_GET_SECOND_BALL;
					}
					break;
				case AUTON_TWO_GET_SECOND_BALL:
					//Start up the intake and drive back to pick up the second ball
					intake->RollIn();
					if(!GyroDrive(0, -0.5, -12))
					{
						autonStep = AUTON_TWO_THIRD_TURN;
						leftEnco->Reset();
						rightEnco->Reset();
					}
					break;
				case AUTON_TWO_THIRD_TURN:
					//If the right goal was originally hot, turn left
					if(rightSideHot)
					{
						if(!GyroTurn(-5, 0.5))
						{
							autonStep = AUTON_TWO_SECOND_SHOOT;
						}
					}
					else
					{
						autonStep = AUTON_TWO_SECOND_SHOOT;
					}
					break;
				case AUTON_TWO_SECOND_SHOOT:
					intake->Stop();
					if(!catapult->ReleaseHold())
					{
						autonStep = AUTON_TWO_SECOND_WAIT;
						reloadTimer->Reset();
						reloadTimer->Start();
					}
					break;
				case AUTON_TWO_SECOND_WAIT:
					if(reloadTimer->Get() >= CATAPULT_WAIT_TIME)
					{
						autonStep = AUTON_TWO_DRIVE_FORWARDS;
						catapult->StartLoad();
						reloadTimer->Stop();
					}
					break;
				case AUTON_TWO_DRIVE_FORWARDS:
					if(!GyroDrive(0, 0.75, 60) && (!(bool)catapult->Load()))
					{
						autonStep = AUTON_END;
					}
					break;*/
				case AUTON_END:
					break;
				}
			}
		}
	}
Beispiel #27
0
/**
 * Reset the count for the encoder object.
 * Resets the count to zero.
 *
 * @param aSlot The digital module slot for the A Channel on the encoder
 * @param aChannel The channel on the digital module for the A Channel of the encoder
 * @param bSlot The digital module slot for the B Channel on the encoder
 * @param bChannel The channel on the digital module for the B Channel of the encoder
 */
void ResetEncoder(UINT32 aSlot, UINT32 aChannel, UINT32 bSlot, UINT32 bChannel)
{
	Encoder *encoder = AllocateEncoder(aSlot, aChannel, bSlot, bChannel);
	if (encoder != NULL)
		encoder->Reset();
}
// During every loop intervel of the teleop period
void Robot::TeleopPeriodic() {
	// Choose the teleop drive option
	DriverControl(driveOption);


	// A simple thing to test a motor
	if (gamePad.GetRawButton(GAMEPAD_BUTTON_A) == true)
		ballManipulator.GoUp();
	else
		ballManipulator.StopAll();



	// Edits the gyro rate to account for drift
	/*
	editedGyroRate = gyro.GetRate();
	if (gyro.GetRate() > GYRO_DRIFT_VALUE_MIN && gyro.GetRate() < GYRO_DRIFT_VALUE_MAX) {
		editedGyroRate = 0;
	} else {
		editedGyroRate += GYRO_DRIFT_VALUE_AVERAGE;
	}
	*/

	// Edits the gyro angle to account for drift
	if (fabs(gyro.GetRate()) > GYRO_DRIFT_VALUE)
		editedGyroAngle = gyro.GetAngle();
	else {
		gyro.Reset();
		editedGyroAngle = 0;
	}


	// Reset the buttons
	for(int c=0; c<7; c++)
		buttonDone[c] = false;



	// To reset encoder data for the wheels
	if (gamePad.GetRawButton(GAMEPAD_BUTTON_Y) == true) {
			encoder1.Reset();
			encoder2.Reset();
	}

	// Print gyro data
	if (showGyro == true) {
		SmartDashboard::PutNumber("Gyro Angle (Raw)", gyro.GetAngle()*GYRO_SCALE_FACTOR);
		SmartDashboard::PutNumber("Gyro Angle (Edited)", editedGyroAngle*GYRO_SCALE_FACTOR);
		SmartDashboard::PutNumber("Gyro Rate (Raw)", gyro.GetRate()*GYRO_SCALE_FACTOR);
		SmartDashboard::PutNumber("Gyro Rate (Edited)", editedGyroRate*GYRO_SCALE_FACTOR);
	}


	// Print out the encoder data
	// Raw encoder data
//	if (showEncoderRaw == true) {
		SmartDashboard::PutNumber("Encoder L get raw", encoder1.GetRaw());
		SmartDashboard::PutNumber("Encoder R get raw", encoder2.GetRaw());

//	}

	// The delta encoder change
	if (showEncoderRate == true) {
		SmartDashboard::PutNumber("Encoder L get rate", encoder1.GetRate());
		SmartDashboard::PutNumber("Encoder R (reversed) get rate", encoder2.GetRate());
	}

	// Print the encoder index
	if (showEncoderIndex == true) {
		SmartDashboard::PutNumber("Encoder L index", encoder1.GetFPGAIndex());
		SmartDashboard::PutNumber("Encoder R index", encoder2.GetFPGAIndex());
	}
}
Beispiel #29
0
	/**
	 * Runs the motor from the output of a Joystick.
	 */
	void OperatorControl() {

		LifterEncoder.StartLiveWindowMode();
		LifterEncoder.Reset();



		while (IsOperatorControl() && IsEnabled()) {
			// Set the motor controller's output.
			// This takes a number from -1 (100% speed in reverse) to +1 (100% speed forwards).
			// lifterA_motor.Set(joy.GetY());
			// lifterB_motor.Set(joy.GetY());


			if ( stick.GetRawButton(1))
			{
			}
			else if (stick.GetRawButton(2))
			{
			}
			else if (stick.GetRawButton(3))
			{
				// Elevator down
				if (BottomLimitSwitch.Get() == 0) {
					lifterA_motor.Set(0.5);
					lifterB_motor.Set(0.5);
				} else {
					lifterA_motor.Set(0);
					lifterB_motor.Set(0);
				}
			}
			else if (stick.GetRawButton(4))
			{
			}
			else if (stick.GetRawButton(5))
			{
				// Elevator up
				if (TopLimitSwitch.Get() == 0) {
					lifterA_motor.Set(-0.5);
					lifterB_motor.Set(-0.5);
				} else {
					lifterA_motor.Set(0);
					lifterB_motor.Set(0);
				}
			}
			else if (stick.GetRawButton(6))
			{
			}
			else if (stick.GetRawButton(7))
			{
			}
			else if (stick.GetRawButton(8))
			{
			}
			else if (stick.GetRawButton(9))
			{
			}
			else if (stick.GetRawButton(10))
			{
			}
			else if (stick.GetRawButton(11))
			{
			}
			else if (stick.GetRawButton(12))
			{
			}
			else
			{
				lifterA_motor.Set(0.0);
				lifterB_motor.Set(0.0);
			}


			if(BottomLimitSwitch.Get()==true)
			{
				LifterEncoder.Reset();
			}

			// Send some stuff to the dashboard
			SmartDashboard::PutBoolean("Top Limit Switch", TopLimitSwitch.Get());
			SmartDashboard::PutBoolean("Bottom Limit Switch", BottomLimitSwitch.Get());
			SmartDashboard::PutNumber("Encoder Position",LifterEncoder.GetRaw());

			Wait(kUpdatePeriod); // Wait 5ms for the next update.
		}
	}