Time Resolution Dependence of Information Measures for Spiking Neurons:
Scaling and Universality

Sarah E. Marzen and Micheal R. DeWeese

Redwood Center for Theoretical Neuroscience
Physics Department
University of California at Berkeley
Berkeley, CA 94720

and

James P. Crutchfield

Complexity Sciences Center
Physics Department
University of California at Davis
Davis, CA 95616

ABSTRACT: The mutual information between stimulus and spike-train response is commonly used to monitor neural coding efficiency, but neuronal computation broadly conceived requires more refined and targeted information measures of input-output joint processes. A first step towards that larger goal is to develop information measures for individual output processes, including information generation (entropy rate), stored information (statistical complexity), predictable information (excess entropy), and active information accumulation (bound information rate). We calculate these for spike trains generated by a variety of noise-driven integrate-and-fire neurons as a function of time resolution and for alternating renewal processes. We show that their time-resolution dependence reveals coarse-grained structural properties of interspike interval statistics; e.g., τ-entropy rates that diverge less quickly than the firing rate indicate interspike interval correlations. We also find evidence that the excess entropy and regularized statistical complexity of different types of integrate-and-fire neurons are universal in the continuous-time limit in the sense that they do not depend on mechanism details. This suggests a surprising simplicity in the spike trains generated by these model neurons. Interestingly, neurons with gamma-distributed ISIs and neurons whose spike trains are alternating renewal processes do not fall into the same universality class. These results lead to two conclusions. First, the dependence of information measures on time resolution reveals mechanistic details about spike train generation. Second, information measures can be used as model selection tools for analyzing spike train processes.


Sarah E. Marzen, Michael R. DeWeese, and James P. Crutchfield, "Time Resolution Dependence of Information Measures for Spiking Neurons: Scaling, and Universality", Frontiers in Computational Neuroscience 9 (2015) 109.
doi:XXXX/XXXX.
[pdf] 894 KB
Santa Fe Institute Working Paper 15-04-012.
arxiv.org:1504.04756 [q-bio.NC].