1 / 28

STATISTICAL INFERENCE PART II POINT ESTIMATION

STATISTICAL INFERENCE PART II POINT ESTIMATION. SUFFICIENT STATISTICS. X, f(x; ), . X 1 , X 2 ,…,X n be a sample rvs. Y=U(X 1 , X 2 ,…,X n ) is a statistic. A sufficient statistic , Y is a statistic which contains all the information for the estimation of .

njohn
Download Presentation

STATISTICAL INFERENCE PART II POINT ESTIMATION

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. STATISTICAL INFERENCEPART IIPOINT ESTIMATION

  2. SUFFICIENT STATISTICS • X, f(x;),  • X1, X2,…,Xn be a sample rvs • Y=U(X1, X2,…,Xn ) is a statistic. • A sufficient statistic, Y is a statistic which contains all the information for the estimation of .

  3. SUFFICIENT STATISTICS • Given the value of Y, the sample contains no further information for the estimation of . • Y is a sufficient statistic (ss) for  if the conditional distribution h(x1,x2,…,xn|y) does not depend on  for every given Y=y. • A ss for is not unique. • If Y is a ss for , then a 1-1 transformation of Y, say Y1=fn(Y) is also a ss for .

  4. SUFFICIENT STATISTICS • The conditional distribution of sample rvs given the value of y of Y, is defined as • If Y is a ss for , then Not depend on  for every given y. ss for  may include y or constant. • Also, the conditional range of Xi given y not depend on .

  5. SUFFICIENT STATISTICS EXAMPLE: X~Ber(p). For a r.s. of size n, show that is a ss for p.

  6. SUFFICIENT STATISTICS • Neyman’s Factorization Theorem:Y is a ss for  iff Not depend on  for every given y (also in the conditional range of xi.) The likelihood function Does not contain any other xi where k1and k2 are non-negative functions and k2 does not depend on  or y.

  7. EXAMPLES 1. X~Ber(p). For a r.s. of size n, find a ss for p if exists.

  8. EXAMPLES 2. X~Beta(θ,2). For a r.s. of size n, find a ss for θ.

  9. SUFFICIENT STATISTICS • A ss may not exist. • Jointly ss Y1,Y2,…,Yk may be needed. Example: Example 10.2.5 in Bain and Engelhardt (page 342 in 2nd edition), X(1) and X(n) are jointly ss for  • If the MLE of  exists and unique and if a ss for  exists, then MLE is a function of a ss for .

  10. EXAMPLE X~N(,2). For a r.s. of size n, find jss for  and 2.

  11. MINIMAL SUFFICIENT STATISTICS • If is a ss for θ, then, is also a SS for θ. But, the first one does a better job in data reduction. A minimalss achieves the greatest possible reduction.

  12. MINIMAL SUFFICIENT STATISTICS • A ss T(X) is called minimal ss if, for any other ss T’(X),T(x) is a function of T’(x). • THEOREM: Let f(x;) be the pmf or pdf of a sampleX1, X2,…,Xn. Suppose there exist a function T(x) such that, for two sample points x1,x2,…,xn and y1,y2,…,yn, the ratio is constant as a function of  iff T(x)=T(y). Then, T(X) is a minimal sufficient statistic for .

  13. EXAMPLE • X~N(,2) where 2 is known. For a r.s. of size n, find minimal ss for . Note: A minimal ss is also not unique. Any 1-to-1 function is also a minimal ss.

  14. RAO-BLACKWELL THEOREM • Let X1, X2,…,Xn have joint pdf or pmf f(x1,x2,…,xn;) and let S=(S1,S2,…,Sk) be a vector of jss for . If T is an UE of () and (T)=E(TS), then • (T) is an UE of() . • (T) is a fn of S, so it is also jss for . • Var((T) ) Var(T) for all . • (T) is a uniformly better unbiased estimator of () .

  15. RAO-BLACKWELL THEOREM • Notes: • (T)=E(TS) is at least as good as T. • For finding the best UE, it is enough to consider UEs that are functions of a ss, because all such estimators are at least as good as the rest of the UEs.

  16. Example • Hogg & Craig, Exercise 10.10 • X1,X2~Exp(θ) • Find joint p.d.f. of ss Y1=X1+X2 for θ and Y2=X2. • Show that Y2 is UE of θ with variance θ². • Find φ(y1)=E(Y2|Y1) and variance of φ(Y1).

  17. ANCILLARY STATISTIC • A statistic S(X) whose distribution does not depend on the parameter  is called an ancillary statistic. • An ancillary statistic contains no information about .

  18. Example • Example 6.1.8 in Casella & Berger, page 257: Let Xi~Unif(θ,θ+1) for i=1,2,…,n Then, range R=X(n)-X(1) is an ancillary statistic because its pdf does not depend on θ.

  19. COMPLETENESS • Let {f(x; ), } be a family of pdfs (or pmfs) and U(x) be an arbitrary function of x not depending on . If requires that the function itself equal to 0 for all possible values of x; then we say that this family is a complete family of pdfs (or pmfs).

  20. EXAMPLES 1. Show that the family {Bin(n=2,); 0<<1} is complete.

  21. EXAMPLES 2. X~Uniform(,). Show that the family {f(x;), >0}is not complete.

  22. (n-1)S2/ 2 ~ By Basu theorem, and S2are independent. BASU THEOREM • If T(X) is a complete and minimal sufficient statistic, then T(X) is independent of every ancillary statistic. • Example:X~N(,2). S2 Ancillary statistic for 

  23. COMPLETE AND SUFFICIENT STATISTICS (css) • Y is a complete and sufficient statistic (css) for  if Y is a ss for  and the family is complete. The pdf of Y. 1) Y is a ss for . 2) u(Y) is an arbitrary function of Y. E(u(Y))=0 for all  implies that u(y)=0 for all possible Y=y.

  24. THE MINIMUM VARIANCE UNBIASED ESTIMATOR • Rao-Blackwell Theorem: If T is an unbiased estimator of , and S is a ss for , then (T)=E(TS)is • an UE of , i.e.,E[(T)]=E[E(TS)]= and • the MVUE of .

  25. LEHMANN-SCHEFFE THEOREM • Let Y be a cssfor . If there is a function Y which is an UE of , then the function is the unique Minimum Variance Unbiased Estimator (UMVUE) of . • Y css for . • T(y)=fn(y) and E[T(Y)]=. • T(Y) is the UMVUE of . • So, it is the best estimator of .

  26. THE MINIMUM VARIANCE UNBIASED ESTIMATOR • Let Y be a cssfor . Since Y is complete, there could be only a unique function of Y which is an UE of . • Let U1(Y) and U2(Y) be two function of Y. Since they are UE’s, E(U1(Y)U2(Y))=0 imply W(Y)=U1(Y)U2(Y)=0 for all possible values of Y. Therefore, U1(Y)=U2(Y) for all Y.

  27. Example • Let X1,X2,…,Xn ~Poi(μ). Find UMVUE of μ. • Solution steps: • Show that is css for μ. • Find a statistics (such as S*) that is UE of μ and a function of S. • Then, S* is UMVUE of μ by Lehmann-Scheffe Thm.

  28. Note • The estimator found by Rao-Blackwell Thm may not be unique. But, the estimator found by Lehmann-Scheffe Thm is unique.

More Related