Neural decision boundaries for maximal information transmission. Author Tatyana Sharpee, William Bialek Publication Year 2007 Type Journal Article Abstract We consider here how to separate multidimensional signals into two categories, such that the binary decision transmits the maximum possible information about those signals. Our motivation comes from the nervous system, where neurons process multidimensional signals into a binary sequence of responses (spikes). In a small noise limit, we derive a general equation for the decision boundary that locally relates its curvature to the probability distribution of inputs. We show that for Gaussian inputs the optimal boundaries are planar, but for non-Gaussian inputs the curvature is nonzero. As an example, we consider exponentially distributed inputs, which are known to approximate a variety of signals from natural environment. Keywords Animals, Signal Transduction, Humans, Entropy, Models, Neurological, Neurons, Synaptic Transmission, Nerve Net, Visual Perception, Probability, Automatic Data Processing, Decision Making, Learning, Nervous System Physiological Phenomena, Normal Distribution, Space Perception Journal PLoS One Volume 2 Issue 7 Pages e646 Alternate Journal PLoS ONE Google ScholarBibTeXEndNote X3 XML