Paper Info
Title
Bayesian population decoding of spiking neurons.
Abstract
The timing of action potentials in spiking neurons depends on the temporal dynamics of their inputs and contains information about temporal fluctuations in the stimulus. Leaky integrate-and-fire neurons constitute a popular class of encoding models, in which spike times depend directly on the temporal structure of the inputs. However, optimal decoding rules for these models have only been studied explicitly in the noiseless case. Here, we study decoding rules for probabilistic inference of a continuous stimulus from the spike times of a population of leaky integrate-and-fire neurons with threshold noise. We derive three algorithms for approximating the posterior distribution over stimuli as a function of the observed spike trains. In addition to a reconstruction of the stimulus we thus obtain an estimate of the uncertainty as well. Furthermore, we derive a 'spike-by-spike' online decoding scheme that recursively updates the posterior with the arrival of each new spike. We use these decoding rules to reconstruct time-varying stimuli represented by a Gaussian process from spike trains of single neurons as well as neural populations.
Year
DOI
Venue
2009
10.3389/neuro.10.021.2009
FRONTIERS IN COMPUTATIONAL NEUROSCIENCE
Keywords
Field
DocType
Bayesian decoding,population coding,spiking neurons,approximate inference
Population,Neuroscience,Neural coding,Computer science,Approximate inference,Posterior probability,Artificial intelligence,Gaussian process,Neural decoding,Decoding methods,Machine learning,Bayesian probability
Journal
Volume
ISSN
Citations 
3
1662-5188
4
PageRank 
References 
Authors
0.59
0
3
Name
Order
Citations
PageRank
Gerwinn, Sebastian110712.84
Jakob H Macke215814.15
Matthias Bethge3131682.73