Spectral methods for neural characterization using generalized quadratic models

Part of Advances in Neural Information Processing Systems 26 (NIPS 2013)

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Authors

Il Memming Park, Evan W. Archer, Nicholas Priebe, Jonathan W. Pillow

Abstract

We describe a set of fast, tractable methods for characterizing neural responses to high-dimensional sensory stimuli using a model we refer to as the generalized quadratic model (GQM). The GQM consists of a low-rank quadratic form followed by a point nonlinearity and exponential-family noise. The quadratic form characterizes the neuron's stimulus selectivity in terms of a set linear receptive fields followed by a quadratic combination rule, and the invertible nonlinearity maps this output to the desired response range. Special cases of the GQM include the 2nd-order Volterra model (Marmarelis and Marmarelis 1978, Koh and Powers 1985) and the elliptical Linear-Nonlinear-Poisson model (Park and Pillow 2011). Here we show that for canonical form" GQMs, spectral decomposition of the first two response-weighted moments yields approximate maximum-likelihood estimators via a quantity called the expected log-likelihood. The resulting theory generalizes moment-based estimators such as the spike-triggered covariance, and, in the Gaussian noise case, provides closed-form estimators under a large class of non-Gaussian stimulus distributions. We show that these estimators are fast and provide highly accurate estimates with far lower computational cost than full maximum likelihood. Moreover, the GQM provides a natural framework for combining multi-dimensional stimulus sensitivity and spike-history dependencies within a single model. We show applications to both analog and spiking data using intracellular recordings of V1 membrane potential and extracellular recordings of retinal spike trains."