Abstract
Let $X, X_1, X_2, \cdots $ be i.i.d. random variables with zero mean and finite variance $\sigma^2$. It is well known that a finite exponential moment assumption is necessary to study limit theorems for large deviation for the standardized partial sums. In this paper, limit theorems for large deviation for self-normalized sums are derived only under finite moment conditions. In particular, we show that, if $EX^4 < \infty$, then $$ \frac{P(S_n /V_n \geq x)}{1-\Phi(x)} \exp\left\{ -\frac{x^3 EX^3}{3\sqrt{ n}\sigma^3} \right\} \left[ 1 + O\left(\frac{1+x} {\sqrt {n}}\right) \right], $$ for $x \ge 0$and $x = O(n^{1/6})$, where $S_n\sum_{i=1}^nX_i$ and $V_n (\sum_{i=1}^n X_i^2)^{1/2}$.
Highlights
Introduction and main resultsLet X, X1, X2, · · ·, be a sequence of non-degenerate independent and identically distributed (i.i.d.) random variables with zero mean
The self-normalized version of the classical central limit theorem states that, as n → ∞, sup P (Sn ≥ xVn) − 1 − Φ(x) → 0, x if and only if the distribution of X is in the domain of attraction of the normal law, where Φ(x) denotes the standard normal distribution function
This beautiful self-normalized central limit theorem was conjectured by Logan, Mallows, Rice and Shepp (1973), and latterly proved by Gine, Gotze and Mason (1997)
Summary
Let X, X1, X2, · · · , be a sequence of non-degenerate independent and identically distributed (i.i.d.) random variables with zero mean. One approach is to investigate the absolute error in the self-normalized central limit theorem via Berry-Esseen bounds or Edgeworth expansions. This has been done by many researchers. Zwet (1997), Putter and van Zwet (1998) and Wang, Jing and Zhao (2000) Another approach is to estimate the relative error P (Sn ≥ xVn)/(1 − Φ(x)). In this direction, Jing, Shao and Wang (2003) re£ned Shao (1999), Wang and Jing (1999) as well as Chistyakov and Gotze (2003), and obtained the following result: if 0 < σ2 = EX2 < ∞, there exists an absolute constant.
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