frc971/control_loops/drivetrain/localizer.h - RealtimeRoboticsGroup/test - Gitiles

 #ifndef FRC971_CONTROL_LOOPS_DRIVETRAIN_FIELD_ESTIMATOR_H_
 #define FRC971_CONTROL_LOOPS_DRIVETRAIN_FIELD_ESTIMATOR_H_

 #include "frc971/control_loops/drivetrain/drivetrain_config.h"
 #include "frc971/control_loops/drivetrain/hybrid_ekf.h"

 namespace frc971 {
 namespace control_loops {
 namespace drivetrain {

 // Defines an interface for classes that provide field-global localization.
 class LocalizerInterface {
  public:
   // Perform a single step of the filter, using the information that is
   // available on every drivetrain iteration.
   // The user should pass in the U that the real system experienced from the
   // previous timestep until now; internally, any filters will first perform a
   // prediction step to get the estimate at time now, and then will apply
   // corrections based on the encoder/gyro/accelerometer values from time now.
   // TODO(james): Consider letting implementations subscribe to the sensor
   // values themselves, and then only passing in U. This requires more
   // coordination on timing, however.
   virtual void Update(const ::Eigen::Matrix<double, 2, 1> &U,
                       ::aos::monotonic_clock::time_point now,
                       double left_encoder, double right_encoder,
                       double gyro_rate, double longitudinal_accelerometer) = 0;
   // There are several subtly different norms floating around for state
   // matrices. In order to avoid that mess, we jus tprovide direct accessors for
   // the values that most people care about.
   virtual double x() const = 0;
   virtual double y() const = 0;
   virtual double theta() const = 0;
   virtual double left_velocity() const = 0;
   virtual double right_velocity() const = 0;
   virtual double left_voltage_error() const = 0;
   virtual double right_voltage_error() const = 0;
 };

 // Uses the generic HybridEkf implementation to provide a basic field estimator.
 // This provides no method for using cameras or the such to get global
 // measurements and just assumes that you can dead-reckon perfectly.
 class DeadReckonEkf : public LocalizerInterface {
   typedef HybridEkf<double> Ekf;
   typedef typename Ekf::StateIdx StateIdx;
  public:
   DeadReckonEkf(const DrivetrainConfig<double> &dt_config) : ekf_(dt_config) {
     ekf_.ResetInitialState(::aos::monotonic_clock::now(), Ekf::State::Zero(),
                            ekf_.P());
   }

   void Update(const ::Eigen::Matrix<double, 2, 1> &U,
                       ::aos::monotonic_clock::time_point now,
                       double left_encoder, double right_encoder,
                       double gyro_rate,
                       double /*longitudinal_accelerometer*/) override {
     ekf_.UpdateEncodersAndGyro(left_encoder, right_encoder, gyro_rate, U, now);
   }

   double x() const override { return ekf_.X_hat(StateIdx::kX); }
   double y() const override { return ekf_.X_hat(StateIdx::kY); }
   double theta() const override { return ekf_.X_hat(StateIdx::kTheta); }
   double left_velocity() const override {
     return ekf_.X_hat(StateIdx::kLeftVelocity);
   }
   double right_velocity() const override {
     return ekf_.X_hat(StateIdx::kRightVelocity);
   }
   double left_voltage_error() const override {
     return ekf_.X_hat(StateIdx::kLeftVoltageError);
   }
   double right_voltage_error() const override {
     return ekf_.X_hat(StateIdx::kRightVoltageError);
   }

  private:
   Ekf ekf_;
 };

 }  // namespace drivetrain
 }  // namespace control_loops
 }  // namespace frc971

 #endif  // FRC971_CONTROL_LOOPS_DRIVETRAIN_FIELD_ESTIMATOR_H_
	#ifndef FRC971_CONTROL_LOOPS_DRIVETRAIN_FIELD_ESTIMATOR_H_
	#define FRC971_CONTROL_LOOPS_DRIVETRAIN_FIELD_ESTIMATOR_H_

	#include "frc971/control_loops/drivetrain/drivetrain_config.h"
	#include "frc971/control_loops/drivetrain/hybrid_ekf.h"

	namespace frc971 {
	namespace control_loops {
	namespace drivetrain {

	// Defines an interface for classes that provide field-global localization.
	class LocalizerInterface {
	public:
	// Perform a single step of the filter, using the information that is
	// available on every drivetrain iteration.
	// The user should pass in the U that the real system experienced from the
	// previous timestep until now; internally, any filters will first perform a
	// prediction step to get the estimate at time now, and then will apply
	// corrections based on the encoder/gyro/accelerometer values from time now.
	// TODO(james): Consider letting implementations subscribe to the sensor
	// values themselves, and then only passing in U. This requires more
	// coordination on timing, however.
	virtual void Update(const ::Eigen::Matrix<double, 2, 1> &U,
	::aos::monotonic_clock::time_point now,
	double left_encoder, double right_encoder,
	double gyro_rate, double longitudinal_accelerometer) = 0;
	// There are several subtly different norms floating around for state
	// matrices. In order to avoid that mess, we jus tprovide direct accessors for
	// the values that most people care about.
	virtual double x() const = 0;
	virtual double y() const = 0;
	virtual double theta() const = 0;
	virtual double left_velocity() const = 0;
	virtual double right_velocity() const = 0;
	virtual double left_voltage_error() const = 0;
	virtual double right_voltage_error() const = 0;
	};

	// Uses the generic HybridEkf implementation to provide a basic field estimator.
	// This provides no method for using cameras or the such to get global
	// measurements and just assumes that you can dead-reckon perfectly.
	class DeadReckonEkf : public LocalizerInterface {
	typedef HybridEkf<double> Ekf;
	typedef typename Ekf::StateIdx StateIdx;
	public:
	DeadReckonEkf(const DrivetrainConfig<double> &dt_config) : ekf_(dt_config) {
	ekf_.ResetInitialState(::aos::monotonic_clock::now(), Ekf::State::Zero(),
	ekf_.P());
	}

	void Update(const ::Eigen::Matrix<double, 2, 1> &U,
	::aos::monotonic_clock::time_point now,
	double left_encoder, double right_encoder,
	double gyro_rate,
	double /longitudinal_accelerometer/) override {
	ekf_.UpdateEncodersAndGyro(left_encoder, right_encoder, gyro_rate, U, now);
	}

	double x() const override { return ekf_.X_hat(StateIdx::kX); }
	double y() const override { return ekf_.X_hat(StateIdx::kY); }
	double theta() const override { return ekf_.X_hat(StateIdx::kTheta); }
	double left_velocity() const override {
	return ekf_.X_hat(StateIdx::kLeftVelocity);
	}
	double right_velocity() const override {
	return ekf_.X_hat(StateIdx::kRightVelocity);
	}
	double left_voltage_error() const override {
	return ekf_.X_hat(StateIdx::kLeftVoltageError);
	}
	double right_voltage_error() const override {
	return ekf_.X_hat(StateIdx::kRightVoltageError);
	}

	private:
	Ekf ekf_;
	};

	} // namespace drivetrain
	} // namespace control_loops
	} // namespace frc971

	#endif // FRC971_CONTROL_LOOPS_DRIVETRAIN_FIELD_ESTIMATOR_H_