Optimal quantizer structure for binary discrete input continuous output channels under an arbitrary quantized-output constraint

Abstract

Given a channel having binary input X = (x1, x2) having the probability distribution pX = (px1, px2) that is corrupted by a continuous noise to produce a continuous output y ∈ Y = R. For a given conditional distribution p(y|x1) = φ1(y) and p(y|x2) = φ2(y), one wants to quantize the continuous output y back to the final discrete output Z = (z1, z2, ..., zN) with N ≤ 2 such that the mutual information between input and quantized-output I(X; Z) is maximized while the probability of the quantized-output pZ = (pz1, pz2, ..., pzN) has to satisfy a certain constraint. Consider a new variable ry=px1φ1(y)/ (px1φ1(y)+px2φ2(y)), we show that the optimal quantizer has a structure of convex cells in the new variable ry. Based on the convex cells property of the optimal quantizers, a fast algorithm is proposed to find the global optimal quantizer in a polynomial time complexity.