Classical and Multilinear Harmonic Analysis

This contemporary graduate-level text in harmonic analysis introduces the reader to a wide array of analytical results and techniques.

Camil Muscalu (Author), Wilhelm Schlag (Author)

9780521882453, Cambridge University Press

Hardback, published 31 January 2013

387 pages, 25 b/w illus. 200 exercises
23.4 x 15.5 x 2.4 cm, 0.7 kg

Review of the set: 'The two-volume set under review is a worthy addition to this tradition from two of the younger generation of researchers. It is remarkable that the authors have managed to fit all of this into [this number of] smaller-than-average pages without omitting to provide motivation and helpful intuitive remarks. Altogether, these books are a most welcome addition to the literature of harmonic analysis.' Gerald B. Folland, Mathematical Reviews

This two-volume text in harmonic analysis introduces a wealth of analytical results and techniques. It is largely self-contained and will be useful to graduate students and researchers in both pure and applied analysis. Numerous exercises and problems make the text suitable for self-study and the classroom alike. This first volume starts with classical one-dimensional topics: Fourier series; harmonic functions; Hilbert transform. Then the higher-dimensional Calderón–Zygmund and Littlewood–Paley theories are developed. Probabilistic methods and their applications are discussed, as are applications of harmonic analysis to partial differential equations. The volume concludes with an introduction to the Weyl calculus. The second volume goes beyond the classical to the highly contemporary and focuses on multilinear aspects of harmonic analysis: the bilinear Hilbert transform; Coifman–Meyer theory; Carleson's resolution of the Lusin conjecture; Calderón's commutators and the Cauchy integral on Lipschitz curves. The material in this volume has not previously appeared together in book form.

Preface
Acknowledgements
1. Fourier series: convergence and summability
2. Harmonic functions, Poisson kernel
3. Conjugate harmonic functions, Hilbert transform
4. The Fourier Transform on Rd and on LCA groups
5. Introduction to probability theory
6. Fourier series and randomness
7. Calderón–Zygmund theory of singular integrals
8. Littlewood–Paley theory
9. Almost orthogonality
10. The uncertainty principle
11. Fourier restriction and applications
12. Introduction to the Weyl calculus
References
Index.

Subject Areas: Integral calculus & equations [PBKL], Differential calculus & equations [PBKJ], Complex analysis, complex variables [PBKD], Real analysis, real variables [PBKB]