Sparse Functional Identification of Complex Cells from Spike Times and the Decoding of Visual Stimuli

Sparse Functional Identification of Complex Cells from Spike Times and the Decoding of Visual Stimuli

Abstract We investigate the sparse functional identification of complex cells and the decoding of spatio-temporal visual stimuli encoded by an ensemble of complex cells. The reconstruction algorithm is formulated as a rank minimization problem that significantly reduces the number of sampling measur...

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Bibliographic Details
Main Authors: Aurel A. Lazar, Nikul H. Ukani, Yiyin Zhou
Format: Article
Language:English
Published: SpringerOpen 2018-01-01
Series:Journal of Mathematical Neuroscience
Subjects:
Encoding of visual stimuli
Complex cells
Quadratic receptive fields
Dendritic stimulus processors
Sparse neural decoding
Sparse functional identification
Online Access:http://link.springer.com/article/10.1186/s13408-017-0057-1
Description
Summary:Abstract We investigate the sparse functional identification of complex cells and the decoding of spatio-temporal visual stimuli encoded by an ensemble of complex cells. The reconstruction algorithm is formulated as a rank minimization problem that significantly reduces the number of sampling measurements (spikes) required for decoding. We also establish the duality between sparse decoding and functional identification and provide algorithms for identification of low-rank dendritic stimulus processors. The duality enables us to efficiently evaluate our functional identification algorithms by reconstructing novel stimuli in the input space. Finally, we demonstrate that our identification algorithms substantially outperform the generalized quadratic model, the nonlinear input model, and the widely used spike-triggered covariance algorithm.
ISSN:2190-8567

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