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In statistics, Stein's unbiased risk estimate (SURE) is an unbiased estimator of the mean-squared error of "a nearly arbitrary, nonlinear biased estimator."^[1] In other words, it provides an indication of the accuracy of a given estimator. This is important since the true mean-squared error of an estimator is a function of the unknown parameter to be estimated, and thus cannot be determined exactly.

The technique is named after its discoverer, Charles Stein.^[2]

Formal statement

Let $\mu \in {\mathbb {R} }^{d}$ be an unknown parameter and let $x\in {\mathbb {R} }^{d}$ be a measurement vector whose components are independent and distributed normally with mean $\mu$ and variance 1. Suppose $h(x)$ is an estimator of $\mu$ from $x$ , and can be written $h(x)=x+g(x)$ , where $g$ is weakly differentiable. Then, Stein's unbiased risk estimate is given by ^[3]

\mathrm {SURE} (h)=d\sigma ^{2}+\|g(x)\|^{2}+2\sigma ^{2}\sum _{i=1}^{d}{\frac {\partial }{\partial x_{i}}}g_{i}(x),

where $g_{i}(x)$ is the $i$ th component of the function $g(x)$ , and $\|\cdot \|$ is the Euclidean norm.

The importance of SURE is that it is an unbiased estimate of the mean-squared error (or squared error risk) of $h(x)$ :

Theorem

E_{\mu }\{\mathrm {SURE} (h)\}=E_{\mu }\|h(x)-\mu \|^{2}.

Thus, minimizing SURE can act as a surrogate for minimizing the MSE. Note that there is no dependence on the unknown parameter $\mu$ in the expression for SURE above. Thus, it can be manipulated (e.g., to determine optimal estimation settings) without knowledge of $\mu$ .

Derivation

The

Applications

A standard application of SURE is to choose a parametric form for an estimator, and then optimize the values of the parameters to minimize the risk estimate. This technique has been applied in several settings. For example, a variant of the James–Stein estimator can be derived by finding the optimal shrinkage estimator.^[2] The technique has also been used by Donoho and Johnstone to determine the optimal shrinkage factor in a wavelet denoising setting.^[1]

References

^ ^a ^b Donoho, David L. (1995). "Adapting to Unknown Smoothness via Wavelet Shrinkage". Journal of the American Statistical Association. 90 (432). Journal of the American Statistical Association, Vol. 90, No. 432: 1200–1244. doi:10.2307/2291512. JSTOR 2291512. {{cite journal}}: Unknown parameter |coauthors= ignored (|author= suggested) (help); Unknown parameter |month= ignored (help)
^ ^a ^b Stein, Charles M. (1981). "Estimation of the Mean of a Multivariate Normal Distribution". The Annals of Statistics. 9 (6): 1135–1151. doi:10.1214/aos/1176345632. JSTOR 2240405. {{cite journal}}: Cite has empty unknown parameter: |coauthors= (help); Unknown parameter |month= ignored (help)
^ Wasserman, Larry (2005). All of Nonparametric Statistics.

[donoho95-1] Donoho, David L. (1995). "Adapting to Unknown Smoothness via Wavelet Shrinkage". Journal of the American Statistical Association. 90 (432). Journal of the American Statistical Association, Vol. 90, No. 432: 1200–1244. doi:10.2307/2291512. JSTOR 2291512. {{cite journal}}: Unknown parameter |coauthors= ignored (|author= suggested) (help); Unknown parameter |month= ignored (help)

[stein81-2] Stein, Charles M. (1981). "Estimation of the Mean of a Multivariate Normal Distribution". The Annals of Statistics. 9 (6): 1135–1151. doi:10.1214/aos/1176345632. JSTOR 2240405. {{cite journal}}: Cite has empty unknown parameter: |coauthors= (help); Unknown parameter |month= ignored (help)

[wasserman05-3] Wasserman, Larry (2005). All of Nonparametric Statistics.

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@@ Line 8: / Line 8: @@
 where <math>g_i(x)</math> is the <math>i</math>th component of the function <math>g(x)</math>, and <math>\|\cdot\|</math> is the [[Euclidean norm]].
-The importance of SURE is that it is an unbiased estimate of the mean-squared error (or squared error risk) of <math>h(x)</math>, i.e.
+The importance of SURE is that it is an unbiased estimate of the mean-squared error (or squared error risk) of <math>h(x)</math>:
+==== Theorem ====
-:<math>E_\mu \{ \mathrm{SURE}(h) \} = \mathrm{MSE}(h),\,\! </math>
+:<math>E_\mu \{ \mathrm{SURE}(h) \} = E_\mu \|h(x)-\mu\|^2.</math>
-with
-:<math>\mathrm{MSE}(h) = E_\mu \|h(x)-\mu\|^2.</math>
 Thus, minimizing SURE can act as a surrogate for minimizing the MSE.  Note that there is no dependence on the unknown parameter <math>\mu</math> in the expression for SURE above. Thus, it can be manipulated (e.g., to determine optimal estimation settings) without knowledge of <math>\mu</math>.
+== Derivation ==
+The
 == Applications ==