y2020/control_loops/drivetrain/localizer.h - RealtimeRoboticsGroup/test - Gitiles

 #ifndef Y2020_CONTROL_LOOPS_DRIVETRAIN_LOCALIZER_H_
 #define Y2020_CONTROL_LOOPS_DRIVETRAIN_LOCALIZER_H_

 #include <string_view>

 #include "aos/containers/ring_buffer.h"
 #include "aos/events/event_loop.h"
 #include "aos/network/message_bridge_server_generated.h"
 #include "frc971/control_loops/drivetrain/hybrid_ekf.h"
 #include "frc971/control_loops/drivetrain/localizer.h"
 #include "y2020/control_loops/superstructure/superstructure_status_generated.h"
 #include "y2020/vision/sift/sift_generated.h"

 namespace y2020 {
 namespace control_loops {
 namespace drivetrain {

 // This class handles the localization for the 2020 robot. In order to handle
 // camera updates, we get the ImageMatchResult message from the cameras and then
 // project the result onto the 2-D X/Y plane and use the implied robot
 // position/heading from that as the measurement. This is distinct from 2019,
 // when we used a heading/distance/skew measurement update. This is because
 // updating with x/y/theta directly seems to be better conditioned (even if it
 // may not reflect the measurement noise quite as accurately). The poor
 // conditioning seemed to work in 2019, but due to the addition of a couple of
 // velocity offset states that allow us to use the accelerometer more
 // effectively, things started to become unstable.
 class Localizer : public frc971::control_loops::drivetrain::LocalizerInterface {
  public:
   typedef frc971::control_loops::TypedPose<double> Pose;
   typedef frc971::control_loops::drivetrain::HybridEkf<double> HybridEkf;
   typedef typename HybridEkf::State State;
   typedef typename HybridEkf::StateIdx StateIdx;
   typedef typename HybridEkf::StateSquare StateSquare;
   typedef typename HybridEkf::Input Input;
   typedef typename HybridEkf::Output Output;
   Localizer(aos::EventLoop *event_loop,
             const frc971::control_loops::drivetrain::DrivetrainConfig<double>
                 &dt_config);
   State Xhat() const override { return ekf_.X_hat(); }
   frc971::control_loops::drivetrain::TrivialTargetSelector *target_selector()
       override {
     return &target_selector_;
   }

   void Update(const ::Eigen::Matrix<double, 2, 1> &U,
               aos::monotonic_clock::time_point now, double left_encoder,
               double right_encoder, double gyro_rate,
               const Eigen::Vector3d &accel) override;

   void Reset(aos::monotonic_clock::time_point t, const State &state) {
     ekf_.ResetInitialState(t, state, ekf_.P());
   }

   void ResetPosition(aos::monotonic_clock::time_point t, double x, double y,
                      double theta, double /*theta_override*/,
                      bool /*reset_theta*/) override {
     const double left_encoder = ekf_.X_hat(StateIdx::kLeftEncoder);
     const double right_encoder = ekf_.X_hat(StateIdx::kRightEncoder);
     ekf_.ResetInitialState(t, (Ekf::State() << x, y, theta, left_encoder, 0,
                                right_encoder, 0, 0, 0, 0, 0, 0).finished(),
                            ekf_.P());
   };

  private:
   // Storage for a single turret position data point.
   struct TurretData {
     aos::monotonic_clock::time_point receive_time =
         aos::monotonic_clock::min_time;
     double position = 0.0;  // rad
     double velocity = 0.0;  // rad/sec
   };

   // Processes new image data from the given pi and updates the EKF.
   void HandleImageMatch(std::string_view pi,
                         const frc971::vision::sift::ImageMatchResult &result);

   // Processes the most recent turret position and stores it in the turret_data_
   // buffer.
   void HandleSuperstructureStatus(
       const y2020::control_loops::superstructure::Status &status);

   // Retrieves the turret data closest to the provided time.
   TurretData GetTurretDataForTime(aos::monotonic_clock::time_point time);

   aos::EventLoop *const event_loop_;
   const frc971::control_loops::drivetrain::DrivetrainConfig<double> dt_config_;
   HybridEkf ekf_;

   std::vector<aos::Fetcher<frc971::vision::sift::ImageMatchResult>>
       image_fetchers_;

   aos::Fetcher<aos::message_bridge::ServerStatistics> clock_offset_fetcher_;

   // Buffer of recent turret data--this is used so that when we receive a camera
   // frame from the turret, we can back out what the turret angle was at that
   // time.
   aos::RingBuffer<TurretData, 200> turret_data_;

   // Target selector to allow us to satisfy the LocalizerInterface requirements.
   frc971::control_loops::drivetrain::TrivialTargetSelector target_selector_;
 };

 }  // namespace drivetrain
 }  // namespace control_loops
 }  // namespace y2020

 #endif  // Y2020_CONTROL_LOOPS_DRIVETRAIN_LOCALIZER_H_
	#ifndef Y2020_CONTROL_LOOPS_DRIVETRAIN_LOCALIZER_H_
	#define Y2020_CONTROL_LOOPS_DRIVETRAIN_LOCALIZER_H_

	#include <string_view>

	#include "aos/containers/ring_buffer.h"
	#include "aos/events/event_loop.h"
	#include "aos/network/message_bridge_server_generated.h"
	#include "frc971/control_loops/drivetrain/hybrid_ekf.h"
	#include "frc971/control_loops/drivetrain/localizer.h"
	#include "y2020/control_loops/superstructure/superstructure_status_generated.h"
	#include "y2020/vision/sift/sift_generated.h"

	namespace y2020 {
	namespace control_loops {
	namespace drivetrain {

	// This class handles the localization for the 2020 robot. In order to handle
	// camera updates, we get the ImageMatchResult message from the cameras and then
	// project the result onto the 2-D X/Y plane and use the implied robot
	// position/heading from that as the measurement. This is distinct from 2019,
	// when we used a heading/distance/skew measurement update. This is because
	// updating with x/y/theta directly seems to be better conditioned (even if it
	// may not reflect the measurement noise quite as accurately). The poor
	// conditioning seemed to work in 2019, but due to the addition of a couple of
	// velocity offset states that allow us to use the accelerometer more
	// effectively, things started to become unstable.
	class Localizer : public frc971::control_loops::drivetrain::LocalizerInterface {
	public:
	typedef frc971::control_loops::TypedPose<double> Pose;
	typedef frc971::control_loops::drivetrain::HybridEkf<double> HybridEkf;
	typedef typename HybridEkf::State State;
	typedef typename HybridEkf::StateIdx StateIdx;
	typedef typename HybridEkf::StateSquare StateSquare;
	typedef typename HybridEkf::Input Input;
	typedef typename HybridEkf::Output Output;
	Localizer(aos::EventLoop *event_loop,
	const frc971::control_loops::drivetrain::DrivetrainConfig<double>
	&dt_config);
	State Xhat() const override { return ekf_.X_hat(); }
	frc971::control_loops::drivetrain::TrivialTargetSelector *target_selector()
	override {
	return &target_selector_;
	}

	void Update(const ::Eigen::Matrix<double, 2, 1> &U,
	aos::monotonic_clock::time_point now, double left_encoder,
	double right_encoder, double gyro_rate,
	const Eigen::Vector3d &accel) override;

	void Reset(aos::monotonic_clock::time_point t, const State &state) {
	ekf_.ResetInitialState(t, state, ekf_.P());
	}

	void ResetPosition(aos::monotonic_clock::time_point t, double x, double y,
	double theta, double /theta_override/,
	bool /reset_theta/) override {
	const double left_encoder = ekf_.X_hat(StateIdx::kLeftEncoder);
	const double right_encoder = ekf_.X_hat(StateIdx::kRightEncoder);
	ekf_.ResetInitialState(t, (Ekf::State() << x, y, theta, left_encoder, 0,
	right_encoder, 0, 0, 0, 0, 0, 0).finished(),
	ekf_.P());
	};

	private:
	// Storage for a single turret position data point.
	struct TurretData {
	aos::monotonic_clock::time_point receive_time =
	aos::monotonic_clock::min_time;
	double position = 0.0; // rad
	double velocity = 0.0; // rad/sec
	};

	// Processes new image data from the given pi and updates the EKF.
	void HandleImageMatch(std::string_view pi,
	const frc971::vision::sift::ImageMatchResult &result);

	// Processes the most recent turret position and stores it in the turret_data_
	// buffer.
	void HandleSuperstructureStatus(
	const y2020::control_loops::superstructure::Status &status);

	// Retrieves the turret data closest to the provided time.
	TurretData GetTurretDataForTime(aos::monotonic_clock::time_point time);

	aos::EventLoop *const event_loop_;
	const frc971::control_loops::drivetrain::DrivetrainConfig<double> dt_config_;
	HybridEkf ekf_;

	std::vector<aos::Fetcher<frc971::vision::sift::ImageMatchResult>>
	image_fetchers_;

	aos::Fetcher<aos::message_bridge::ServerStatistics> clock_offset_fetcher_;

	// Buffer of recent turret data--this is used so that when we receive a camera
	// frame from the turret, we can back out what the turret angle was at that
	// time.
	aos::RingBuffer<TurretData, 200> turret_data_;

	// Target selector to allow us to satisfy the LocalizerInterface requirements.
	frc971::control_loops::drivetrain::TrivialTargetSelector target_selector_;
	};

	} // namespace drivetrain
	} // namespace control_loops
	} // namespace y2020

	#endif // Y2020_CONTROL_LOOPS_DRIVETRAIN_LOCALIZER_H_