by N. Bertrand, A. Charles, J. Lee, P. Dunn and C.J. Rozell
Abstract:
Tracking algorithms such as the Kalman filter aim to improve inference performance by leveraging the temporal dynamics in streaming observations. However, the tracking regularizers are often based on the $\ell_p$-norm which cannot account for important geometrical relationships between neighboring signal elements. We propose a practical approach to using the earth mover's distance (EMD) via the earth mover's distance dynamic filtering (EMD-DF) algorithm for causally tracking time-varying sparse signals when there is a natural geometry to the coefficient space that should be respected (e.g., meaningful ordering). Specifically, this paper presents a new Beckmann formulation that dramatically reduces computational complexity, as well as an evaluation of the performance and complexity of the proposed approach in imaging and frequency tracking applications with real and simulated neurophysiology data.
Reference:
Efficient Tracking of Sparse Signals via an Earth Mover's Distance Dynamics RegularizerN. Bertrand, A. Charles, J. Lee, P. Dunn and C.J. Rozell. IEEE Signal Processing Letters, vol. 27, pp. 1120-1124, June 2020.
Bibtex Entry:
@Article{bertrand.20c,
author = {Bertrand, N. and Charles, A. and Lee, J. and Dunn, P. and Rozell, C.J.},
title = {Efficient Tracking of Sparse Signals via an Earth Mover's Distance Dynamics Regularizer},
year = 2020,
volume={27},
month = jun,
pages={1120-1124},
abstract = {
Tracking algorithms such as the Kalman filter aim to improve inference performance by leveraging the temporal dynamics in streaming observations.
However, the tracking regularizers are often based on the $\ell_p$-norm which cannot account for important geometrical relationships between neighboring signal elements.
We propose a practical approach to using the earth mover's distance (EMD) via the earth mover's distance dynamic filtering (EMD-DF) algorithm for causally tracking time-varying sparse signals when there is a natural geometry to the coefficient space that should be respected (e.g., meaningful ordering).
Specifically, this paper presents a new Beckmann formulation that dramatically reduces computational complexity, as well as an evaluation of the performance and complexity of the proposed approach in imaging and frequency tracking applications with real and simulated neurophysiology data.
},
journal = {IEEE Signal Processing Letters},
url = {https://arxiv.org/abs/1806.04674}
}