2011
DOI: 10.1016/j.jspi.2011.05.016
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On matrix variance inequalities

Abstract: Olkin and Shepp (2005, J. Statist. Plann. Inference, vol. 130, pp. 351-358) presented a matrix form of Chernoff's inequality for Normal and Gamma (univariate) distributions. We extend and generalize this result, proving Poincaré-type and Bessel-type inequalities, for matrices of arbitrary order and for a large class of distributions.MSC: Primary 60E15.

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Cited by 7 publications
(27 citation statements)
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“…The conditions appearing in the definition of F(A ,η p ) are tailored to ensure that all identities and manipulations follow immediately. For instance, the requirement that L p η(·)g(· − ) ∈ F (1) (p) in the definition of F(A ,η p ) guarantees that the resulting functions A ,η p g(x) have p-mean 0 and the condition (L p η)∆ − g ∈ L 1 (p) guarantees that the expectations of the individual summands on the r.h.s. of (2.7) exist.…”
Section: Stein Operators and Stein Equationsmentioning
confidence: 99%
“…The conditions appearing in the definition of F(A ,η p ) are tailored to ensure that all identities and manipulations follow immediately. For instance, the requirement that L p η(·)g(· − ) ∈ F (1) (p) in the definition of F(A ,η p ) guarantees that the resulting functions A ,η p g(x) have p-mean 0 and the condition (L p η)∆ − g ∈ L 1 (p) guarantees that the expectations of the individual summands on the r.h.s. of (2.7) exist.…”
Section: Stein Operators and Stein Equationsmentioning
confidence: 99%
“…Chernoff proved that Var 1(Z)E(1(Z))2, provided that E(1(Z))2 is finite, where the equality holds iff g is a linear function; see also the previous papers by Nash , Brascamp and Lieb . This inequality has been generalized and extended by many authors (see, e.g., ).…”
Section: Introductionmentioning
confidence: 89%
“…As mentioned in the introduction, a matrix extension of Chernoff's gaussian bound (1.16) is due to [59], and the result is obtained by expanding the test functions in the Hermite basis. An extension of this result to a wide class of multivariate densities is proposed in [2] (see also references therein). Once again, our notations allow to extend this result to arbitrary densities of real-valued random variables.…”
Section: Olkin-shepp-type Boundsmentioning
confidence: 96%
“…More recently, the contributions [4], [5] [3] and [1] and [51,52] begin to fully explore connections with Stein's method. In the Gaussian framework, an enlightening first order matrix variance bound is proposed in [59] for the Gaussian distribution, and in a more general setting in [2] (and also to arbitrary order). Finally, we mention [66,65] and [64]'s revisiting of this classical literature enticed us to begin the work that ultimately led to the present paper.…”
Section: Some Referencesmentioning
confidence: 99%