Abstract
Spatio-temporal receptive field (STRF) models are frequently used to approximate the computation implemented by a sensory neuron. Typically, such STRFs are assumed to be smooth and sparse. Current state-of-the-art approaches for estimating STRFs based empirical Bayes estimation encode such prior knowledge into a prior covariance matrix, whose hyperparameters are learned from the data, and thus provide STRF estimates with the desired properties even with little or noisy data. However, empirical Bayes methods are often not computationally efficient in high-dimensional settings, as encountered in sensory neuroscience. Here we pursued an alternative approach and encode prior knowledge for estimation of STRFs by choosing a set of basis function with the desired properties: a natural cubic spline basis. Our method is computationally efficient, and can be easily applied to Linear-Gaussian and Linear-Nonlinear-Poisson models as well as more complicated Linear-Nonlinear-Linear-Nonlinear cascade model or spike-triggered clustering methods. We compared the performance of spline-based methods to no-spline ones on simulated and experimental data, showing that spline-based methods consistently outperformed the no-spline versions. We provide a Python toolbox for all suggested methods ().
Highlights
Spatio-temporal receptive fields (STRFs) are frequently used in neuroscience to approximate the computation implemented by a sensory neuron
A modified wSTA that removes low power frequencies can result in smoother spatio-temporal receptive field (STRF), while the threshold for such a frequency cutoff is normally chosen by cross-validation [4]
We introduce diagnostic tools for assessing the quality of an estimated STRF: (1) a significance test based on the analytical solution of the STRF covariance matrix and (2) a permutation test based on model prediction
Summary
Spatio-temporal receptive fields (STRFs) are frequently used in neuroscience to approximate the computation implemented by a sensory neuron. Such models consist typically of one or more linear filters summing up sensory inputs across time and space, followed by a static nonlinearity and a probabilistic output process [1]. The simplest way to estimate a STRF for a given data set is arguably to compute the spike-triggered average (STA), the average over all stimuli preceding a spike [2]. The maximum likelihood estimate (MLE), known as whitened-STA (wSTA) [4], does not suffer from such shortcomings, but it requires even more data to converge as the whitening procedure tends to amplify noise at frequencies with low power, making it a less preferred option in many experimental settings. A modified wSTA that removes low power frequencies can result in smoother STRF, while the threshold for such a frequency cutoff is normally chosen by cross-validation [4]
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