Local asymptotic normality - Alchetron, the free social encyclopedia

In statistics, local asymptotic normality is a property of a sequence of statistical models, which allows this sequence to be asymptotically approximated by a normal location model, after a rescaling of the parameter. An important example when the local asymptotic normality holds is in the case of iid sampling from a regular parametric model.

Definition

A sequence of parametric statistical models { P_n,θ: θ ∈ Θ } is said to be locally asymptotically normal (LAN) at θ if there exist matrices r_n and I_θ and a random vector Δ_n,θ ~ N(0, I_θ) such that, for every converging sequence h_n → h,

ln ⁡ d P n , θ + r n − 1 h n d P n , θ = h ′ Δ n , θ − 1 2 h ′ I θ h + o P n , θ ( 1 ) ,

where the derivative here is a Radon–Nikodym derivative, which is a formalised version of the likelihood ratio, and where o is a type of big O in probability notation. In other words, the local likelihood ratio must converge in distribution to a normal random variable whose mean is equal to minus one half the variance:

ln ⁡ d P n , θ + r n − 1 h n d P n , θ → d N ( − 1 2 h ′ I θ h , h ′ I θ h ) .

The sequences of distributions P n , θ + r n − 1 h n and P n , θ are contiguous.

Example

The most straightforward example of a LAN model is an iid model whose likelihood is twice continuously differentiable. Suppose { X₁, X₂, …, X_n } is an iid sample, where each X_i has density function f(x, θ). The likelihood function of the model is equal to

p n , θ ( x 1 , … , x n ; θ ) = ∏ i = 1 n f ( x i , θ ) .

If f is twice continuously differentiable in θ, then

ln ⁡ p n , θ + δ θ ≈ ln ⁡ p n , θ + δ θ ′ ∂ ln ⁡ p n , θ ∂ θ + 1 2 δ θ ′ ∂ 2 ln ⁡ p n , θ ∂ θ ∂ θ ′ δ θ = ln ⁡ p n , θ + δ θ ′ ∑ i = 1 n ∂ ln ⁡ f ( x i , θ ) ∂ θ + 1 2 δ θ ′ [ ∑ i = 1 n ∂ 2 ln ⁡ f ( x i , θ ) ∂ θ ∂ θ ′ ] δ θ .

Plugging in δθ = h / √n, gives

ln ⁡ p n , θ + h / n p n , θ = h ′ ( 1 n ∑ i = 1 n ∂ ln ⁡ f ( x i , θ ) ∂ θ ) − 1 2 h ′ ( 1 n ∑ i = 1 n − ∂ 2 ln ⁡ f ( x i , θ ) ∂ θ ∂ θ ′ ) h + o p ( 1 ) .

By the central limit theorem, the first term (in parentheses) converges in distribution to a normal random variable Δ_θ ~ N(0, I_θ), whereas by the law of large numbers the expression in second parentheses converges in probability to I_θ, which is the Fisher information matrix:

I θ = E [ − ∂ 2 ln ⁡ f ( X i , θ ) ∂ θ ∂ θ ′ ] = E [ ( ∂ ln ⁡ f ( X i , θ ) ∂ θ ) ( ∂ ln ⁡ f ( X i , θ ) ∂ θ ) ′ ] .

Thus, the definition of the local asymptotic normality is satisfied, and we have confirmed that the parametric model with iid observations and twice continuously differentiable likelihood has the LAN property.

References

Local asymptotic normality Wikipedia

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Contents

Definition

Example

References