Eaton's inequality

In probability theory, Eaton's inequality is a bound on the largest values of a linear combination of bounded random variables. This inequality was described in 1974 by Morris L. Eaton.^[1]

Statement of the inequality

Let X_i be a set of real independent random variables, each with a expected value of zero and bounded by 1 ( | X_i | ≤ 1, for 1 ≤ i ≤ n). The variates do not have to be identically or symmetrically distributed. Let a_i be a set of n fixed real numbers with

\sum _{i=1}^{n}a_{i}^{2}=1.

Eaton showed that

P\left(\left|\sum _{i=1}^{n}a_{i}X_{i}\right|\geq k\right)\leq 2\inf _{0\leq c\leq k}\int _{c}^{\infty }\left({\frac {z-c}{k-c}}\right)^{3}\phi (z)\,dz=2B_{E}(k),

where φ(x) is the probability density function of the standard normal distribution.

A related bound is Edelman's

P\left(\left|\sum _{i=1}^{n}a_{i}X_{i}\right|\geq k\right)\leq 2\left(1-\Phi \left[k-{\frac {1.5}{k}}\right]\right)=2B_{Ed}(k),

where Φ(x) is cumulative distribution function of the standard normal distribution.

Pinelis has shown that Eaton's bound can be sharpened:^[2]

B_{EP}=\min\{1,k^{-2},2B_{E}\}

A set of critical values for Eaton's bound have been determined.^[3]

Related inequalities

Let a_i be a set of independent Rademacher random variables – P( a_i = 1 ) = P( a_i = −1 ) = 1/2. Let Z be a normally distributed variate with a mean 0 and variance of 1. Let b_i be a set of n fixed real numbers such that

\sum _{i=1}^{n}b_{i}^{2}=1.

This last condition is required by the Riesz–Fischer theorem which states that

a_{i}b_{i}+\cdots +a_{n}b_{n}

will converge if and only if

\sum _{i=1}^{n}b_{i}^{2}

is finite.

Then

Ef(a_{i}b_{i}+\cdots +a_{n}b_{n})\leq Ef(Z)

for f(x) = | x |^p. The case for p ≥ 3 was proved by Whittle^[4] and p ≥ 2 was proved by Haagerup.^[5]

If f(x) = e^λx with λ ≥ 0 then

Ef(a_{i}b_{i}+\cdots +a_{n}b_{n})\leq \inf \left[{\frac {E(e^{\lambda Z})}{e^{\lambda x}}}\right]=e^{-x^{2}/2}

where inf is the infimum.^[6]

Let

S_{n}=a_{i}b_{i}+\cdots +a_{n}b_{n}

Then^[7]

P(S_{n}\geq x)\leq {\frac {2e^{3}}{9}}P(Z\geq x)

The constant in the last inequality is approximately 4.4634.

An alternative bound is also known:^[8]

P(S_{n}\geq x)\leq e^{-x^{2}/2}

This last bound is related to the Hoeffding's inequality.

In the uniform case where all the b_i = n^−1/2 the maximum value of S_n is n^1/2. In this case van Zuijlen has shown that^[9]

P(|\mu -\sigma |)\leq 0.5\,

where μ is the mean and σ is the standard deviation of the sum.

References

↑ Eaton, Morris L. (1974) "A probability inequality for linear combinations of bounded random variables." Annals of Statistics 2(3) 609–614
↑ Pinelis, I. (1994) "Extremal probabilistic problems and Hotelling's T² test under a symmetry condition." Annals of Statistics 22(1), 357–368
↑ Dufour, J-M; Hallin, M (1993) "Improved Eaton bounds for linear combinations of bounded random variables, with statistical applications", Journal of the American Statistical Association, 88(243) 1026–1033
↑ Whittle P (1960) Bounds for the moments of linear and quadratic forms in independent variables. Teor Verojatnost i Primenen 5: 331–335 MR0133849
↑ Haagerup U (1982) The best constants in the Khinchine inequality. Studia Math 70: 231–283 MR0654838
↑ Hoeffding W (1963) Probability inequalities for sums of bounded random variables. J Amer Statist Assoc 58: 13–30 MR144363
↑ Pinelis I (1994) Optimum bounds for the distributions of martingales in Banach spaces. Ann Probab 22(4):1679–1706
↑ de la Pena, VH, Lai TL, Shao Q (2009) Self normalized processes. Springer-Verlag, New York
↑ van Zuijlen Martien CA (2011) On a conjecture concerning the sum of independent Rademacher random variables. http://arxiv.org/abs/1112.4988

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