1 / 64

Applications of Hahn Banach Theorem

Applications of Hahn Banach Theorem. E: normed vector space, assumed to be real for definitions. Known:. Taking. We have. Corollary 1. Proof:. Corollary 2. Proof in next page. This corollary implies that. We may consider E as embedded in as normed space, then is a

magnar
Télécharger la présentation

Applications of Hahn Banach Theorem

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. Applications of Hahn Banach Theorem

  2. E: normed vector space, assumed to be real for definitions Known: Taking We have

  3. Corollary1 Proof:

  4. Corollary2 Proof in next page This corollary implies that We may consider E as embedded in as normed space, then is a complete space which is the completion of E.

  5. A dual variational principle

  6. Example Why? See next page

  7. 1 1 -1

  8. Claim In this example

  9. Exercise

  10. Suppose that such that , then

  11. Applications of Mazm- Orlich Theorem

  12. is the space of the probability measure of S

  13. Mazm-Orlich Theorem

  14. Mazur-Orlicz (1953) S : arbitary set E : real vector space sublinear (I)

  15. Corollary 1 be as in Mazur-Orlicz Theorem Let then

  16. Corollary 2 If in Corollary 1 sastisfies the condition: For each there is such that then

  17. Example p.1 S: arbitary set defined by Then

  18. Example p.2 is q-convex

  19. Example p.3 In particular, S is a convex set in a linear map is convex i.e. Then This implies von Neumann Minimax Theorem

  20. Duality map p.1 J(x) is w-compact (see next page) Let E be a real reflexive Banach space. For J is a Duality map. If E is a Hilbert space, then

  21. Lemma p.1 Let S be a compact convex subset of a linear function +constant topological linear space. Define If and F is the space of all affine functions then

  22. Theorem p.1 Let E be a real reflexive Banach space is bilinear such that (i) There is c>0 such that (ii)

  23. Theorem p.2 Then for each there is a unique such that with

  24. Variational Inequality(Stampachia-Hartmam) p.1 E: reflexive Banach space C: closed bounded convex set in E satisfies (i) f is monotone i.e. (ii) f is weakly continuous on each line segment in C.

  25. Variational Inequality(Stampachia-Hartmam) p.2 Then there is such that

  26. Applications of Mazm- Orlich Theorem Inequality after mixing of functions

  27. Theorem Let S be an arbitary set. The following two statements are equivalent:

More Related