Abstract
Kalman filtering methods have long been regarded as efficient adaptive Bayesian techniques for estimating hidden states in models of linear dynamical systems under Gaussian uncertainty. Recent advents of the Cubature Kalman filter (CKF) have extended this efficient estimation property to nonlinear systems, and also to hybrid nonlinear problems where by the processes are continuous and the observations are discrete (continuous-discrete CD-CKF). Employing CKF techniques, therefore, carries high promise for modeling many biological phenomena where the underlying processes exhibit inherently nonlinear, continuous, and noisy dynamics and the associated measurements are uncertain and time-sampled. This paper investigates the performance of cubature filtering (CKF and CD-CKF) in two flagship problems arising in the field of neuroscience upon relating brain functionality to aggregate neurophysiological recordings: (i) estimation of the firing dynamics and the neural circuit model parameters from electric potentials (EP) observations, and (ii) estimation of the hemodynamic model parameters and the underlying neural drive from BOLD (fMRI) signals. First, in simulated neural circuit models, estimation accuracy was investigated under varying levels of observation noise (SNR), process noise structures, and observation sampling intervals (dt). When compared to the CKF, the CD-CKF consistently exhibited better accuracy for a given SNR, sharp accuracy increase with higher SNR, and persistent error reduction with smaller dt. Remarkably, CD-CKF accuracy shows only a mild deterioration for non-Gaussian process noise, specifically with Poisson noise, a commonly assumed form of background fluctuations in neuronal systems. Second, in simulated hemodynamic models, parametric estimates were consistently improved under CD-CKF. Critically, time-localization of the underlying neural drive, a determinant factor in fMRI-based functional connectivity studies, was significantly more accurate under CD-CKF. In conclusion, and with the CKF recently benchmarked against other advanced Bayesian techniques, the CD-CKF framework could provide significant gains in robustness and accuracy when estimating a variety of biological phenomena models where the underlying process dynamics unfold at time scales faster than those seen in collected measurements.
Highlights
Physiological signal recordings have long played a central role in probing and deciphering the functional state of the underlying biological process
In order to compare the performance of Cubature Kalman filter (CKF) and Continuous-Discrete Cubature Kalman Filter (CD-CKF), we consider two scenarios of the underlying continuous system and its mathematical representation by the continuous stochastic process equation that is modeled as an SDE driven by a Wiener process: 1. The underlying continuous system is subject to stochastic noise given by a Wiener process
We evaluate the performance of CKF and CD-CKF as the accumulative mean square error (MSE) of all normalized states excluding the observation state, over a total of 100 Monte-Carlo simulations
Summary
Physiological signal recordings have long played a central role in probing and deciphering the functional state of the underlying biological process. At the measurement level, observation of the process is attained indirectly through one or more continuous-time variables that relate to the neuronal activity and are limited by spatial smearing (e.g. extracellular currents) or temporal filtering (e.g. blood oxygenation levels). Both of the underlying processes are continuous, the temporal bandwidth of the hemodynamic process is considerably smaller than that of the neuronal dynamics (or its output contains much lower frequencies) and can be recorded at much larger time intervals (Nyquist rate). By taking “snapshots” or images of the hemodynamic process at regular intervals in time, the observations constitute a sequence of noisy discrete-time physiological recordings
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