Refining Concentration for Gaussian Quadratic Chaos with Applications in Sonar and Communications

Abstract

The paper studies concentration of measure for Gaussian quadratic chaos in the non-asymptotic regime where existing bounds are improved and new bounds are proposed. We begin by slightly tightening Hanson-Wright inequality (HWI) by increasing its absolute constant from the largest known value of 0.125 to at least 0.145 in the symmetric case. A sharper version of an inequality of Laurent and Massart (LMI) is presented. It results in an increase in the absolute constant in HWI from the largest available value of 1-32 due to LMI to 9-1732 in the positive-semidefinite case. Moving beyond HWI, we develop a sequence of inequalities indexed by m1 that involves Schatten norms of the underlying symmetric matrix. The case m=1 recovers HWI and the case m=∞ leads to a novel bound called the m∞-bound. Avoiding Markov's inequality, we introduce the strong χ2-inequality and its loosened version, the weak χ2-inequality. To investigate the m∞-bound, we explore all concentration bounds that only involve the operator norm of the underlying positive-definite matrix. Five candidates are examined, namely, the m∞-bound, relaxed versions of HWI and LMI, the weak χ2-bound and the large deviations bound. The sharpest among these bounds is either the m∞-bound or the weak χ2-bound. If the matrix dimension is n=2,4,6, the weak χ2-bound is tighter than the m∞-bound. For even n8, the m∞-bound is sharper than the weak χ2-bound if and only if the ratio of the tail parameter over the operator norm lies inside an open interval which expands indefinitely as n grows. Modified versions of HW, m∞ and strong χ2 inequalities of various orders are proposed. Their effectiveness is demonstrated by two applications in signal detection for sonar and wireless communications.

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