| #ifndef FRC971_ZEROING_ZEROING_H_ |
| #define FRC971_ZEROING_ZEROING_H_ |
| |
| #include <cstdint> |
| #include <vector> |
| |
| #include "frc971/control_loops/control_loops.q.h" |
| #include "frc971/constants.h" |
| |
| // TODO(pschrader): Flag an error if encoder index pulse is not n revolutions |
| // away from the last one (i.e. got extra counts from noise, etc..) |
| // |
| // TODO(pschrader): Flag error if the pot disagrees too much with the encoder |
| // after being zeroed. |
| // |
| // TODO(pschrader): Watch the offset over long periods of time and flag if it |
| // gets too far away from the initial value. |
| |
| namespace frc971 { |
| namespace zeroing { |
| |
| // Estimates the position with encoder, |
| // the pot and the indices. |
| class PotAndIndexPulseZeroingEstimator { |
| public: |
| PotAndIndexPulseZeroingEstimator( |
| const constants::PotAndIndexPulseZeroingConstants &constants); |
| |
| // Update the internal logic with the next sensor values. |
| void UpdateEstimate(const PotAndIndexPosition &info); |
| |
| // Reset the internal logic so it needs to be re-zeroed. |
| void Reset(); |
| |
| // Manually trigger an internal error. This is used for testing the error |
| // logic. |
| void TriggerError(); |
| |
| // Returns true if an error has occurred, false otherwise. This gets reset to |
| // false when the Reset() function is called. |
| bool error() const { return error_; } |
| |
| // Returns true if the logic considers the corresponding mechanism to be |
| // zeroed. It return false otherwise. For example, right after a call to |
| // Reset() this returns false. |
| bool zeroed() const { return zeroed_; } |
| |
| // Return the estimated position of the corresponding mechanism. This value |
| // is in SI units. For example, the estimator for the elevator would return a |
| // value in meters for the height relative to absolute zero. |
| double position() const { return pos_; } |
| |
| // Return the estimated starting position of the corresponding mechansim. In |
| // some contexts we refer to this as the "offset". |
| double offset() const { return start_pos_; } |
| |
| // Return the estimated position of the corresponding mechanism not using the |
| // index pulse, even if one is available. |
| double filtered_position() const { return filtered_position_; } |
| |
| // Returns a number between 0 and 1 that represents the percentage of the |
| // samples being used in the moving average filter. A value of 0.0 means that |
| // no samples are being used. A value of 1.0 means that the filter is using |
| // as many samples as it has room for. For example, after a Reset() this |
| // value returns 0.0. As more samples get added with UpdateEstimate(...) the |
| // return value starts increasing to 1.0. |
| double offset_ratio_ready() const { |
| return start_pos_samples_.size() / static_cast<double>(max_sample_count_); |
| } |
| |
| // Returns true if the sample buffer is full. |
| bool offset_ready() const { |
| return start_pos_samples_.size() == max_sample_count_; |
| } |
| |
| private: |
| // This function calculates the start position given the internal state and |
| // the provided `latched_encoder' value. |
| double CalculateStartPosition(double start_average, |
| double latched_encoder) const; |
| |
| // The estimated position. |
| double pos_; |
| // The unzeroed filtered position. |
| double filtered_position_ = 0.0; |
| // The distance between two consecutive index positions. |
| double index_diff_; |
| // The next position in 'start_pos_samples_' to be used to store the next |
| // sample. |
| int samples_idx_; |
| // Last 'max_sample_count_' samples for start positions. |
| std::vector<double> start_pos_samples_; |
| // The number of the last samples of start position to consider in the |
| // estimation. |
| size_t max_sample_count_; |
| // The estimated starting position of the mechanism. We also call this the |
| // 'offset' in some contexts. |
| double start_pos_; |
| // The absolute position of any index pulse on the mechanism. This is used to |
| // account for the various ways the encoders get mounted into the robot. |
| double known_index_pos_; |
| // Flag for triggering logic that takes note of the current index pulse count |
| // after a reset. See `last_used_index_pulse_count_'. |
| bool wait_for_index_pulse_; |
| // After a reset we keep track of the index pulse count with this. Only after |
| // the index pulse count changes (i.e. increments at least once or wraps |
| // around) will we consider the mechanism zeroed. We also use this to store |
| // the most recent `PotAndIndexPosition::index_pulses' value when the start |
| // position was calculated. It helps us calculate the start position only on |
| // index pulses to reject corrupted intermediate data. |
| uint32_t last_used_index_pulse_count_; |
| // Marker to track whether we're fully zeroed yet or not. |
| bool zeroed_; |
| // Marker to track whether an error has occurred. This gets reset to false |
| // whenever Reset() is called. |
| bool error_; |
| // Stores the position "start_pos" variable the first time the program |
| // is zeroed. |
| double first_start_pos_; |
| // The fraction of index_diff (possibly greater than 1) after which an error |
| // is reported. |
| double allowable_encoder_error_; |
| }; |
| |
| // Populates an EstimatorState struct with information from the zeroing |
| // estimator. |
| void PopulateEstimatorState(const PotAndIndexPulseZeroingEstimator &estimator, |
| EstimatorState *state); |
| |
| } // namespace zeroing |
| } // namespace frc971 |
| |
| #endif // FRC971_ZEROING_ZEROING_H_ |