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kalman.c
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kalman.c
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/* Kalman filters. */
#include "kalman.h"
KalmanFilter alloc_filter(int state_dimension,
int observation_dimension) {
KalmanFilter f;
f.timestep = 0;
f.state_dimension = state_dimension;
f.observation_dimension = observation_dimension;
f.state_transition = alloc_matrix(state_dimension,
state_dimension);
f.observation_model = alloc_matrix(observation_dimension,
state_dimension);
f.process_noise_covariance = alloc_matrix(state_dimension,
state_dimension);
f.observation_noise_covariance = alloc_matrix(observation_dimension,
observation_dimension);
f.observation = alloc_matrix(observation_dimension, 1);
f.predicted_state = alloc_matrix(state_dimension, 1);
f.predicted_estimate_covariance = alloc_matrix(state_dimension,
state_dimension);
f.innovation = alloc_matrix(observation_dimension, 1);
f.innovation_covariance = alloc_matrix(observation_dimension,
observation_dimension);
f.inverse_innovation_covariance = alloc_matrix(observation_dimension,
observation_dimension);
f.optimal_gain = alloc_matrix(state_dimension,
observation_dimension);
f.state_estimate = alloc_matrix(state_dimension, 1);
f.estimate_covariance = alloc_matrix(state_dimension,
state_dimension);
f.vertical_scratch = alloc_matrix(state_dimension,
observation_dimension);
f.small_square_scratch = alloc_matrix(observation_dimension,
observation_dimension);
f.big_square_scratch = alloc_matrix(state_dimension,
state_dimension);
return f;
}
void free_filter(KalmanFilter f) {
free_matrix(f.state_transition);
free_matrix(f.observation_model);
free_matrix(f.process_noise_covariance);
free_matrix(f.observation_noise_covariance);
free_matrix(f.observation);
free_matrix(f.predicted_state);
free_matrix(f.predicted_estimate_covariance);
free_matrix(f.innovation);
free_matrix(f.innovation_covariance);
free_matrix(f.inverse_innovation_covariance);
free_matrix(f.optimal_gain);
free_matrix(f.state_estimate);
free_matrix(f.estimate_covariance);
free_matrix(f.vertical_scratch);
free_matrix(f.small_square_scratch);
free_matrix(f.big_square_scratch);
}
void update(KalmanFilter f) {
predict(f);
estimate(f);
}
void predict(KalmanFilter f) {
f.timestep++;
/* Predict the state */
multiply_matrix(f.state_transition, f.state_estimate,
f.predicted_state);
/* Predict the state estimate covariance */
multiply_matrix(f.state_transition, f.estimate_covariance,
f.big_square_scratch);
multiply_by_transpose_matrix(f.big_square_scratch, f.state_transition,
f.predicted_estimate_covariance);
add_matrix(f.predicted_estimate_covariance, f.process_noise_covariance,
f.predicted_estimate_covariance);
}
void estimate(KalmanFilter f) {
/* Calculate innovation */
multiply_matrix(f.observation_model, f.predicted_state,
f.innovation);
subtract_matrix(f.observation, f.innovation,
f.innovation);
/* Calculate innovation covariance */
multiply_by_transpose_matrix(f.predicted_estimate_covariance,
f.observation_model,
f.vertical_scratch);
multiply_matrix(f.observation_model, f.vertical_scratch,
f.innovation_covariance);
add_matrix(f.innovation_covariance, f.observation_noise_covariance,
f.innovation_covariance);
/* Invert the innovation covariance.
Note: this destroys the innovation covariance.
TODO: handle inversion failure intelligently. */
destructive_invert_matrix(f.innovation_covariance,
f.inverse_innovation_covariance);
/* Calculate the optimal Kalman gain.
Note we still have a useful partial product in vertical scratch
from the innovation covariance. */
multiply_matrix(f.vertical_scratch, f.inverse_innovation_covariance,
f.optimal_gain);
/* Estimate the state */
multiply_matrix(f.optimal_gain, f.innovation,
f.state_estimate);
add_matrix(f.state_estimate, f.predicted_state,
f.state_estimate);
/* Estimate the state covariance */
multiply_matrix(f.optimal_gain, f.observation_model,
f.big_square_scratch);
subtract_from_identity_matrix(f.big_square_scratch);
multiply_matrix(f.big_square_scratch, f.predicted_estimate_covariance,
f.estimate_covariance);
}