frc971/zeroing/absolute_encoder.h - RealtimeRoboticsGroup/test - Gitiles

 #ifndef FRC971_ZEROING_ABSOLUTE_ENCODER_H_
 #define FRC971_ZEROING_ABSOLUTE_ENCODER_H_

 #include <vector>

 #include "flatbuffers/flatbuffers.h"

 #include "aos/containers/error_list.h"
 #include "frc971/zeroing/zeroing.h"

 namespace frc971::zeroing {

 // Estimates the position with an absolute encoder which also reports
 // incremental counts.  The absolute encoder can't spin more than one
 // revolution.
 class AbsoluteEncoderZeroingEstimator
     : public ZeroingEstimator<AbsolutePosition,
                               constants::AbsoluteEncoderZeroingConstants,
                               AbsoluteEncoderEstimatorState> {
  public:
   explicit AbsoluteEncoderZeroingEstimator(
       const constants::AbsoluteEncoderZeroingConstants &constants);

   // Resets the internal logic so it needs to be re-zeroed.
   void Reset() override;

   // Updates the sensor values for the zeroing logic.
   void UpdateEstimate(const AbsolutePosition &info) override;

   void TriggerError() override { error_ = true; }

   bool zeroed() const override { return zeroed_; }

   double offset() const override { return offset_; }

   bool error() const override { return error_; }

   // Returns true if the sample buffer is full.
   bool offset_ready() const override {
     return relative_to_absolute_offset_samples_.size() ==
            constants_.average_filter_size;
   }

   // Returns information about our current state.
   virtual flatbuffers::Offset<State> GetEstimatorState(
       flatbuffers::FlatBufferBuilder *fbb) const override;

  private:
   struct PositionStruct {
     PositionStruct(const AbsolutePosition &position_buffer)
         : absolute_encoder(position_buffer.absolute_encoder()),
           encoder(position_buffer.encoder()) {}
     double absolute_encoder;
     double encoder;
   };

   // The zeroing constants used to describe the configuration of the system.
   const constants::AbsoluteEncoderZeroingConstants constants_;

   // True if the mechanism is zeroed.
   bool zeroed_;
   // Marker to track whether an error has occurred.
   bool error_;
   // The first valid offset we recorded. This is only set after zeroed_ first
   // changes to true.
   double first_offset_;

   // The filtered absolute encoder.  This is used in the status for calibration.
   double filtered_absolute_encoder_ = 0.0;

   // Samples of the offset needed to line the relative encoder up with the
   // absolute encoder.
   ::std::vector<double> relative_to_absolute_offset_samples_;

   MoveDetector<PositionStruct, AbsolutePosition> move_detector_;

   // Estimated start position of the mechanism
   double offset_ = 0;
   // The next position in 'relative_to_absolute_offset_samples_' and
   // 'encoder_samples_' to be used to store the next sample.
   int samples_idx_ = 0;

   // Number of NANs we've seen in a row.
   size_t nan_samples_ = 0;

   // The filtered position.
   double position_ = 0.0;

   // Marker to track what kind of error has occured.
   aos::ErrorList<ZeroingError> errors_;
 };

 }  // namespace frc971::zeroing

 #endif  // FRC971_ZEROING_ABSOLUTE_ENCODER_H_
	#ifndef FRC971_ZEROING_ABSOLUTE_ENCODER_H_
	#define FRC971_ZEROING_ABSOLUTE_ENCODER_H_

	#include <vector>

	#include "flatbuffers/flatbuffers.h"

	#include "aos/containers/error_list.h"
	#include "frc971/zeroing/zeroing.h"

	namespace frc971::zeroing {

	// Estimates the position with an absolute encoder which also reports
	// incremental counts. The absolute encoder can't spin more than one
	// revolution.
	class AbsoluteEncoderZeroingEstimator
	: public ZeroingEstimator<AbsolutePosition,
	constants::AbsoluteEncoderZeroingConstants,
	AbsoluteEncoderEstimatorState> {
	public:
	explicit AbsoluteEncoderZeroingEstimator(
	const constants::AbsoluteEncoderZeroingConstants &constants);

	// Resets the internal logic so it needs to be re-zeroed.
	void Reset() override;

	// Updates the sensor values for the zeroing logic.
	void UpdateEstimate(const AbsolutePosition &info) override;

	void TriggerError() override { error_ = true; }

	bool zeroed() const override { return zeroed_; }

	double offset() const override { return offset_; }

	bool error() const override { return error_; }

	// Returns true if the sample buffer is full.
	bool offset_ready() const override {
	return relative_to_absolute_offset_samples_.size() ==
	constants_.average_filter_size;
	}

	// Returns information about our current state.
	virtual flatbuffers::Offset<State> GetEstimatorState(
	flatbuffers::FlatBufferBuilder *fbb) const override;

	private:
	struct PositionStruct {
	PositionStruct(const AbsolutePosition &position_buffer)
	: absolute_encoder(position_buffer.absolute_encoder()),
	encoder(position_buffer.encoder()) {}
	double absolute_encoder;
	double encoder;
	};

	// The zeroing constants used to describe the configuration of the system.
	const constants::AbsoluteEncoderZeroingConstants constants_;

	// True if the mechanism is zeroed.
	bool zeroed_;
	// Marker to track whether an error has occurred.
	bool error_;
	// The first valid offset we recorded. This is only set after zeroed_ first
	// changes to true.
	double first_offset_;

	// The filtered absolute encoder. This is used in the status for calibration.
	double filtered_absolute_encoder_ = 0.0;

	// Samples of the offset needed to line the relative encoder up with the
	// absolute encoder.
	::std::vector<double> relative_to_absolute_offset_samples_;

	MoveDetector<PositionStruct, AbsolutePosition> move_detector_;

	// Estimated start position of the mechanism
	double offset_ = 0;
	// The next position in 'relative_to_absolute_offset_samples_' and
	// 'encoder_samples_' to be used to store the next sample.
	int samples_idx_ = 0;

	// Number of NANs we've seen in a row.
	size_t nan_samples_ = 0;

	// The filtered position.
	double position_ = 0.0;

	// Marker to track what kind of error has occured.
	aos::ErrorList<ZeroingError> errors_;
	};

	} // namespace frc971::zeroing

	#endif // FRC971_ZEROING_ABSOLUTE_ENCODER_H_