y2016/control_loops/superstructure/superstructure_controls.h - RealtimeRoboticsGroup/test - Gitiles

 #ifndef Y2016_CONTROL_LOOPS_SUPERSTRUCTURE_SUPERSTRUCTURE_CONTROLS_H_
 #define Y2016_CONTROL_LOOPS_SUPERSTRUCTURE_SUPERSTRUCTURE_CONTROLS_H_

 #include <memory>

 #include "frc971/control_loops/control_loop.h"
 #include "aos/util/trapezoid_profile.h"
 #include "frc971/control_loops/profiled_subsystem.h"
 #include "frc971/control_loops/simple_capped_state_feedback_loop.h"
 #include "frc971/control_loops/state_feedback_loop.h"

 #include "frc971/zeroing/zeroing.h"
 #include "y2016/control_loops/superstructure/integral_arm_plant.h"
 #include "y2016/control_loops/superstructure/superstructure_position_generated.h"

 namespace y2016 {
 namespace control_loops {
 namespace superstructure {
 namespace testing {
 class SuperstructureTest_DisabledGoalTest_Test;
 }  // namespace testing

 class ArmControlLoop
     : public ::frc971::control_loops::SimpleCappedStateFeedbackLoop<6, 2, 2> {
  public:
   ArmControlLoop(SimpleCappedStateFeedbackLoop<6, 2, 2> &&loop)
       : SimpleCappedStateFeedbackLoop<6, 2, 2>(::std::move(loop)) {}

   const Eigen::Matrix<double, 2, 1> ControllerOutput() override {
     const Eigen::Matrix<double, 2, 1> accelerating_ff =
         controller().coefficients(0).Kff *
         (next_R() - plant().coefficients(0).A * R());
     const Eigen::Matrix<double, 2, 1> accelerating_controller =
         controller().coefficients(0).K * error() + accelerating_ff;

     const Eigen::Matrix<double, 2, 1> decelerating_ff =
         controller().coefficients(1).Kff *
         (next_R() - plant().coefficients(1).A * R());
     const Eigen::Matrix<double, 2, 1> decelerating_controller =
         controller().coefficients(1).K * error() + decelerating_ff;

     const double bemf_voltage = X_hat(1, 0) / kV_shoulder;
     bool use_accelerating_controller = true;
     AOS_LOG(DEBUG, "Accelerating at %f, decel %f, bemf %f\n",
             accelerating_controller(0, 0), accelerating_controller(1, 0),
             bemf_voltage);
     if (IsAccelerating(bemf_voltage, accelerating_controller(0, 0))) {
       use_accelerating_controller = true;
     } else {
       use_accelerating_controller = false;
     }
     if (use_accelerating_controller) {
       set_index(0);
       ff_U_ = accelerating_ff;
       return accelerating_controller;
     } else {
       set_index(1);
       ff_U_ = decelerating_ff;
       return decelerating_controller;
     }
   }

  private:
   void CapU() override {
     // U(0)
     // U(1) = coupling * U(0) + ...
     // So, when modifying U(0), remove the coupling.
     if (U(0, 0) > max_voltage(0)) {
       const double overage_amount = U(0, 0) - max_voltage(0);
       mutable_U(0, 0) = max_voltage(0);
       const double coupled_amount = (controller().Kff().block<1, 2>(1, 2) *
                                      plant().B().block<2, 1>(2, 0))(0, 0) *
                                     overage_amount;
       AOS_LOG(DEBUG, "Removing coupled amount %f\n", coupled_amount);
       mutable_U(1, 0) += coupled_amount;
     }
     if (U(0, 0) < min_voltage(0)) {
       const double under_amount = U(0, 0) - min_voltage(0);
       mutable_U(0, 0) = min_voltage(0);
       const double coupled_amount = (controller().Kff().block<1, 2>(1, 2) *
                                      plant().B().block<2, 1>(2, 0))(0, 0) *
                                     under_amount;
       AOS_LOG(DEBUG, "Removing coupled amount %f\n", coupled_amount);
       mutable_U(1, 0) += coupled_amount;
     }

     // Uncapping U above isn't actually a problem with U for the shoulder.
     // Reset any change.
     mutable_U_uncapped(1, 0) = U(1, 0);
     mutable_U(1, 0) =
         ::std::min(max_voltage(1), ::std::max(min_voltage(1), U(1, 0)));
   }

   bool IsAccelerating(double bemf_voltage, double voltage) {
     if (bemf_voltage > 0) {
       return voltage > bemf_voltage;
     } else {
       return voltage < bemf_voltage;
     }
   }
 };

 class Intake : public ::frc971::control_loops::SingleDOFProfiledSubsystem<> {
  public:
   Intake();
 };


 class Arm : public ::frc971::control_loops::ProfiledSubsystem<6, 2> {
  public:
   Arm();

   // Updates our estimator with the latest position.
   void Correct(const ::frc971::PotAndIndexPosition *position_shoulder,
                const ::frc971::PotAndIndexPosition *position_wrist);

   // Forces the goal to be the provided goal.
   void ForceGoal(double unprofiled_goal_shoulder, double unprofiled_goal_wrist);
   // Sets the unprofiled goal.  The profiler will generate a profile to go to
   // this goal.
   void set_unprofiled_goal(double unprofiled_goal_shoulder,
                            double unprofiled_goal_wrist);

   // Runs the controller and profile generator for a cycle.
   void Update(bool disabled);

   // Limits our profiles to a max velocity and acceleration for proper motion.
   void AdjustProfile(double max_angular_velocity_shoulder,
                      double max_angular_acceleration_shoulder,
                      double max_angular_velocity_wrist,
                      double max_angular_acceleration_wrist);

   void set_shoulder_asymetric_limits(double shoulder_min_voltage,
                                      double shoulder_max_voltage) {
     loop_->set_asymetric_voltage(0, shoulder_min_voltage, shoulder_max_voltage);
   }

   // Returns true if we have exceeded any hard limits.
   bool CheckHardLimits();

   // Returns the requested shoulder and wrist voltages.
   double shoulder_voltage() const { return loop_->U(0, 0); }
   double wrist_voltage() const { return loop_->U(1, 0); }

   // Returns the current positions.
   double shoulder_angle() const { return Y_(0, 0); }
   double wrist_angle() const { return Y_(1, 0) + Y_(0, 0); }

   // For testing:
   // Triggers an estimator error.
   void TriggerEstimatorError() { estimators_[0].TriggerError(); }

  private:
   // Limits the provided goal to the soft limits.  Prints "name" when it fails
   // to aid debugging.
   void CapGoal(const char *name, Eigen::Matrix<double, 6, 1> *goal);

   // Updates the offset
   void UpdateWristOffset(double offset);
   void UpdateShoulderOffset(double offset);

   friend class testing::SuperstructureTest_DisabledGoalTest_Test;

   aos::util::TrapezoidProfile shoulder_profile_, wrist_profile_;

   // Current measurement.
   Eigen::Matrix<double, 2, 1> Y_;
   // Current offset.  Y_ = offset_ + raw_sensor;
   Eigen::Matrix<double, 2, 1> offset_;
 };

 }  // namespace superstructure
 }  // namespace control_loops
 }  // namespace y2016

 #endif  // Y2016_CONTROL_LOOPS_SUPERSTRUCTURE_SUPERSTRUCTURE_CONTROLS_H_
	#ifndef Y2016_CONTROL_LOOPS_SUPERSTRUCTURE_SUPERSTRUCTURE_CONTROLS_H_
	#define Y2016_CONTROL_LOOPS_SUPERSTRUCTURE_SUPERSTRUCTURE_CONTROLS_H_

	#include <memory>

	#include "frc971/control_loops/control_loop.h"
	#include "aos/util/trapezoid_profile.h"
	#include "frc971/control_loops/profiled_subsystem.h"
	#include "frc971/control_loops/simple_capped_state_feedback_loop.h"
	#include "frc971/control_loops/state_feedback_loop.h"

	#include "frc971/zeroing/zeroing.h"
	#include "y2016/control_loops/superstructure/integral_arm_plant.h"
	#include "y2016/control_loops/superstructure/superstructure_position_generated.h"

	namespace y2016 {
	namespace control_loops {
	namespace superstructure {
	namespace testing {
	class SuperstructureTest_DisabledGoalTest_Test;
	} // namespace testing

	class ArmControlLoop
	: public ::frc971::control_loops::SimpleCappedStateFeedbackLoop<6, 2, 2> {
	public:
	ArmControlLoop(SimpleCappedStateFeedbackLoop<6, 2, 2> &&loop)
	: SimpleCappedStateFeedbackLoop<6, 2, 2>(::std::move(loop)) {}

	const Eigen::Matrix<double, 2, 1> ControllerOutput() override {
	const Eigen::Matrix<double, 2, 1> accelerating_ff =
	controller().coefficients(0).Kff *
	(next_R() - plant().coefficients(0).A * R());
	const Eigen::Matrix<double, 2, 1> accelerating_controller =
	controller().coefficients(0).K * error() + accelerating_ff;

	const Eigen::Matrix<double, 2, 1> decelerating_ff =
	controller().coefficients(1).Kff *
	(next_R() - plant().coefficients(1).A * R());
	const Eigen::Matrix<double, 2, 1> decelerating_controller =
	controller().coefficients(1).K * error() + decelerating_ff;

	const double bemf_voltage = X_hat(1, 0) / kV_shoulder;
	bool use_accelerating_controller = true;
	AOS_LOG(DEBUG, "Accelerating at %f, decel %f, bemf %f\n",
	accelerating_controller(0, 0), accelerating_controller(1, 0),
	bemf_voltage);
	if (IsAccelerating(bemf_voltage, accelerating_controller(0, 0))) {
	use_accelerating_controller = true;
	} else {
	use_accelerating_controller = false;
	}
	if (use_accelerating_controller) {
	set_index(0);
	ff_U_ = accelerating_ff;
	return accelerating_controller;
	} else {
	set_index(1);
	ff_U_ = decelerating_ff;
	return decelerating_controller;
	}
	}

	private:
	void CapU() override {
	// U(0)
	// U(1) = coupling * U(0) + ...
	// So, when modifying U(0), remove the coupling.
	if (U(0, 0) > max_voltage(0)) {
	const double overage_amount = U(0, 0) - max_voltage(0);
	mutable_U(0, 0) = max_voltage(0);
	const double coupled_amount = (controller().Kff().block<1, 2>(1, 2) *
	plant().B().block<2, 1>(2, 0))(0, 0) *
	overage_amount;
	AOS_LOG(DEBUG, "Removing coupled amount %f\n", coupled_amount);
	mutable_U(1, 0) += coupled_amount;
	}
	if (U(0, 0) < min_voltage(0)) {
	const double under_amount = U(0, 0) - min_voltage(0);
	mutable_U(0, 0) = min_voltage(0);
	const double coupled_amount = (controller().Kff().block<1, 2>(1, 2) *
	plant().B().block<2, 1>(2, 0))(0, 0) *
	under_amount;
	AOS_LOG(DEBUG, "Removing coupled amount %f\n", coupled_amount);
	mutable_U(1, 0) += coupled_amount;
	}

	// Uncapping U above isn't actually a problem with U for the shoulder.
	// Reset any change.
	mutable_U_uncapped(1, 0) = U(1, 0);
	mutable_U(1, 0) =
	::std::min(max_voltage(1), ::std::max(min_voltage(1), U(1, 0)));
	}

	bool IsAccelerating(double bemf_voltage, double voltage) {
	if (bemf_voltage > 0) {
	return voltage > bemf_voltage;
	} else {
	return voltage < bemf_voltage;
	}
	}
	};

	class Intake : public ::frc971::control_loops::SingleDOFProfiledSubsystem<> {
	public:
	Intake();
	};


	class Arm : public ::frc971::control_loops::ProfiledSubsystem<6, 2> {
	public:
	Arm();

	// Updates our estimator with the latest position.
	void Correct(const ::frc971::PotAndIndexPosition *position_shoulder,
	const ::frc971::PotAndIndexPosition *position_wrist);

	// Forces the goal to be the provided goal.
	void ForceGoal(double unprofiled_goal_shoulder, double unprofiled_goal_wrist);
	// Sets the unprofiled goal. The profiler will generate a profile to go to
	// this goal.
	void set_unprofiled_goal(double unprofiled_goal_shoulder,
	double unprofiled_goal_wrist);

	// Runs the controller and profile generator for a cycle.
	void Update(bool disabled);

	// Limits our profiles to a max velocity and acceleration for proper motion.
	void AdjustProfile(double max_angular_velocity_shoulder,
	double max_angular_acceleration_shoulder,
	double max_angular_velocity_wrist,
	double max_angular_acceleration_wrist);

	void set_shoulder_asymetric_limits(double shoulder_min_voltage,
	double shoulder_max_voltage) {
	loop_->set_asymetric_voltage(0, shoulder_min_voltage, shoulder_max_voltage);
	}

	// Returns true if we have exceeded any hard limits.
	bool CheckHardLimits();

	// Returns the requested shoulder and wrist voltages.
	double shoulder_voltage() const { return loop_->U(0, 0); }
	double wrist_voltage() const { return loop_->U(1, 0); }

	// Returns the current positions.
	double shoulder_angle() const { return Y_(0, 0); }
	double wrist_angle() const { return Y_(1, 0) + Y_(0, 0); }

	// For testing:
	// Triggers an estimator error.
	void TriggerEstimatorError() { estimators_[0].TriggerError(); }

	private:
	// Limits the provided goal to the soft limits. Prints "name" when it fails
	// to aid debugging.
	void CapGoal(const char name, Eigen::Matrix<double, 6, 1> goal);

	// Updates the offset
	void UpdateWristOffset(double offset);
	void UpdateShoulderOffset(double offset);

	friend class testing::SuperstructureTest_DisabledGoalTest_Test;

	aos::util::TrapezoidProfile shoulder_profile_, wrist_profile_;

	// Current measurement.
	Eigen::Matrix<double, 2, 1> Y_;
	// Current offset. Y_ = offset_ + raw_sensor;
	Eigen::Matrix<double, 2, 1> offset_;
	};

	} // namespace superstructure
	} // namespace control_loops
	} // namespace y2016

	#endif // Y2016_CONTROL_LOOPS_SUPERSTRUCTURE_SUPERSTRUCTURE_CONTROLS_H_