Stein's lemma

Stein's lemma, named in honor of Charles Stein, is a theorem of probability theory that is of interest primarily because of its applications to statistical inference — in particular, to James–Stein estimation and empirical Bayes methods — and its applications to portfolio choice theory.^[1] The theorem gives a formula for the covariance of one random variable with the value of a function of another, when the two random variables are jointly normally distributed.

Note that the name "Stein's lemma" is also commonly used^[2] to refer to a different result in the area of statistical hypothesis testing, which connects the error exponents in hypothesis testing with the Kullback–Leibler divergence. This result is also known as the Chernoff–Stein lemma^[3] and is not related to the lemma discussed in this article.

Suppose X is a normally distributed random variable with expectation μ and variance σ². Further suppose g is a differentiable function for which the two expectations E(g(X) (X − μ)) and E(g ′(X)) both exist. (The existence of the expectation of any random variable is equivalent to the finiteness of the expectation of its absolute value.) Then

${\displaystyle E(g(X)(X-\mu ))={\sigma }^{2}E(g^{\prime }(X)).}$

In general, suppose X and Y are jointly normally distributed. Then

${\displaystyle \mathrm{Cov}(g(X),Y)=\mathrm{Cov}(X,Y)E(g^{\prime }(X)).}$

For a general multivariate Gaussian random vector ${\displaystyle (X_1,...,X_n)\sim N(\mu ,\mathrm{\Sigma })}$ it follows that

${\displaystyle E(g(X)(X-\mu ))=\mathrm{\Sigma }\cdot E(\mathrm{\nabla }g(X)).}$

The univariate probability density function for the univariate normal distribution with expectation 0 and variance 1 is

${\displaystyle \phi (x)=\frac{1}{\sqrt{2\pi }}{e}^{-x^2/2}}$

Since ${\displaystyle \int x\exp (-x^2/2)dx=-\exp (-x^2/2)}$ we get from integration by parts:

${\displaystyle E[g(X)X]=\frac{1}{\sqrt{2\pi }}\int g(x)x\exp (-x^2/2)dx=\frac{1}{\sqrt{2\pi }}\int g^{\prime }(x)\exp (-x^2/2)dx=E[g^{\prime }(X)]}$.

The case of general variance ${\displaystyle {\sigma }^2}$ follows by substitution.

Isserlis' theorem is equivalently stated as$${\displaystyle \mathrm{E}(X_{1}f(X_1,\dots ,X_n))={\displaystyle \sum _{i=1}^n}\mathrm{Cov}(X_1{X}_i)\mathrm{E}({\partial }_{X_i}f(X_1,\dots ,X_n)).}$$where ${\displaystyle (X_1,\dots X_n)}$ is a zero-mean multivariate normal random vector.

Suppose X is in an exponential family, that is, X has the density

${\displaystyle f_{\eta }(x)=\exp ({\eta }^{\prime }T(x)-\mathrm{\Psi }(\eta ))h(x).}$

Suppose this density has support ${\displaystyle (a,b)}$ where ${\displaystyle a,b}$ could be ${\displaystyle -\mathrm{\infty },\mathrm{\infty }}$ and as ${\displaystyle x\to a\text{ or }b}$, ${\displaystyle \exp ({\eta }^{\prime }T(x))h(x)g(x)\to 0}$ where ${\displaystyle g}$ is any differentiable function such that ${\displaystyle E|g^{\prime }(X)|<\mathrm{\infty }}$ or ${\displaystyle \exp ({\eta }^{\prime }T(x))h(x)\to 0}$ if ${\displaystyle a,b}$ finite. Then

${\displaystyle E[(\frac{h^{\prime }(X)}{h(X)}+\sum {\eta }_i{T_i}^{\prime }(X))\cdot g(X)]=-E[g^{\prime }(X)].}$

The derivation is same as the special case, namely, integration by parts.

If we only know ${\displaystyle X}$ has support ${\displaystyle \mathbb{ℝ}}$, then it could be the case that ${\displaystyle E|g(X)|<\mathrm{\infty }\text{ and }E|g^{\prime }(X)|<\mathrm{\infty }}$ but ${\displaystyle \underset{x\to \mathrm{\infty }}{\lim }{f}_{\eta }(x)g(x)=0}$. To see this, simply put ${\displaystyle g(x)=1}$ and ${\displaystyle f_{\eta }(x)}$ with infinitely spikes towards infinity but still integrable. One such example could be adapted from ${\displaystyle f(x)=\{\begin{array}{ll}1& x\in [n,n+2^{-n})\\ 0& \text{otherwise}\end{array}}$ so that ${\displaystyle f}$ is smooth.

Extensions to elliptically-contoured distributions also exist.^[4][5][6]

• Stein's method
• Taylor expansions for the moments of functions of random variables
• Stein discrepancy

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