Author_Institution :
Nonlinearity & Complexity Res. Group, Aston Univ., Birmingham, UK
Abstract :
Unwanted `spike noise´ in a digital signal is a common problem in digital filtering. However, sometimes the spikes are wanted and other, superimposed, signals are unwanted, and linear, time invariant (LTI) filtering is ineffective because the spikes are wideband - overlapping with independent noise in the frequency domain. So, no LTI filter can separate them, necessitating nonlinear filtering. However, there are applications in which the `noise´ includes drift or smooth signals for which LTI filters are ideal. We describe a nonlinear filter formulated as the solution to an elastic net regularization problem, which attenuates band-limited signals and independent noise, while enhancing superimposed spikes. Making use of known analytic solutions a novel, approximate path-following algorithm is given that provides a good, filtered output with reduced computational effort by comparison to standard convex optimization methods. Accurate performance is shown on real, noisy electrophysiological recordings of neural spikes.
Keywords :
Gaussian noise; bioelectric phenomena; biology computing; convex programming; frequency-domain analysis; nonlinear filters; signal denoising; Gaussian noise removal; LTI filtering; approximate path-following algorithm; band-limited signals; convex optimization methods; digital filtering; digital signal; drift signals; elastic net based nonlinear spike enhancement; elastic net regularization problem; frequency domain; independent noise; linear filtering; neural spikes; noisy electrophysiological recordings; nonlinear filtering; smooth signals; superimposed spike enhancment; time invariant filtering; unwanted spike noise; wideband-overlapping; Approximation algorithms; Digital filters; Filtering algorithms; Maximum likelihood detection; Noise; Nonlinear filters; Filter; noise; nonlinear; regularization; spike;
