Title:Discontinuous phase transition of feature detection in lateral predictive coding

Abstract:The brain adopts the strategy of lateral predictive coding (LPC) to construct optimal internal representations for salient features in input sensory signals to reduce the energetic cost of information transmission. Here we consider the task of distinguishing a non-Gaussian signal by LPC from $(N-1)$ Gaussian background signals of the same magnitude, which is intractable by principal component decomposition. We study the emergence of feature detection function from the perspective of statistical mechanics, and formulate a thermodynamic free energy to implement the tradeoff between energetic cost $E$ and information robustness. We define $E$ as the mean $L_1$-norm of the internal state vectors, and quantify the level of information robustness by an entropy measure $S$. We demonstrate that energy--information tradeoff may induce a discontinuous phase transition of the optimal matrix, from a very weak one with $S \approx 0$ to a functional LPC system with moderate synaptic weights in which a single unit responds selectively to the input non-Gaussian feature with high signal-to-noise ratio.