现代傅里叶分析 第2版 英文影印版
作者:(美)格拉法克斯 著
出版时间: 2011年版
内容简介
The great response to the publication of the book Classical and Modern Fourier Analysis has been very gratifying. I am delighted that Springer has offered to publish the second edition of this book in two volumes: Classical Fourier Analysis, 2nd Edition, and Modern Fourier Analysis, 2nd Edition.These volumes are mainly addressed to graduate students who wish to study Fourier analysis. This second volume is intended to serve as a text for a second-semester course in the subject. It is designed to be a continuation of the first volume. Chapters 1-5 in the first volume contain Lebesgue spaces, Lorentz spaces and interpolation, maximal functions, Fourier transforms and distributions, an introduction to Fourier analysis on the n-torus, singular integrals of convolution type, and Littlewood-Paley theory.
目录
6 smoothness and function spaces
6.1 riesz and bessel potentials, fractional integrals
6.1.1 riesz potentials
6.1.2 bessel potentials
exercises
6.2 sobolev spaces
6.2.1 definition and basic properties of general sobolevspaces
6.2.2 littlewood-paley characterization of inhomogeneous
sobolev spaces
6.2.3 littlewood-paley characterization of homogeneous
sobolev spaces
exercises
6.3 lipschitz spaces
6.3.1 introduction to lipschitz spaces
6.3.2 littlewood-paley characterization of homogeneous
lipschitz spaces
6.3.3 littlewood-paley characterization of inhomogeneous
lipschitz spaces
exercises
6.4 hardy spaces
6.4.1 definition of hardy spaces
6.4.2 quasinorm equivalence of several maximal functions
6.4.3 consequences of the characterizations of hardy spaces
6.4.4 vector-valued hp and its characterizations
6.4.5 singular integrals on hardy spaces
6.4.6 the littlewood-paley characterization of hardy spaces
exercises
6.5 besov-lipschitz and triebel-lizorkin spaces
6.5.1 introduction of function spaces
6.5.2 equivalence of definitions
exercises
6.6 atomic decomposition
6.6.1 the space of sequences fa,qp
6.6.2 the smooth atomic decomposition of fa,q
6.6.3 the nonsmooth atomic decomposition of fa,q
6.6.4 atomic decomposition of hardy spaces
exercises
6.7 singular integrals on function spaces
6.7.1 singular integrals on the hardy space ht
6.7.2 singular integrals on besov-lipschitz spaces
6.7.3 singular integrals on hp(rn)
6.7.4 a singular integral characterization ofh1 (rn)
exercises
7 bmo and carleson measures
7.1 functions of bounded mean oscillation
7.1.1 definition and basic properties of bmo
7.1.2 the john-nirenberg theorem
7.1.3 consequences of theorem 7.1.6
exercises
7.2 duality between h1 and bmo
exercises
7.3 nontangential maximal functions and carleson measures
7.3.1 definition and basic properties of carleson measures
7.3.2 bmo functions and carleson measures
exercises
7.4 the sharp maximal function
7.4.1 definition and basic properties of the sharp maximalfunction
7.4.2 a good lambda estimate for the sharp function
7.4.3 interpolation using bmo
7.4.4 estimates for singular integrals involving the sharpfunction
exercises
7.5 commutators of singular integrals with bmo functions
7.5.1 an orlicz-type maximal function
7.5.2 a pointwise estimate for the commutator
7.5.3 lp boundedness of the commutator
exercises z
8 singular integrals of nonconvolution type
8.1 general background and the role of bmo
8.1.1 standard kernels
8.1.2 operators associated with standard kernels
8.1.3 calder6n-zygmund operators acting on boundedfunctions
exercises
8.2 consequences of l2 boundedness
8.2.1 weaktype (1, i) and/_,p boundedness of singularintegrals
8.2.2 boundedness of maximal singular integrals
8.2.3 h1 → l1 and l∞→bmo boundedness of singular integrals
exercises
8.3 the t(1) theorem
8.3.1 preliminaries and statement of the theorem
8.3.2 the proof of theorem 8.3.3
8.3.3 an application
exercises
8.4 paraproducts
8.4.1 introduction to paraproducts
8.4.2 l2 boundedness of paraproducts
8.4.3 fundamental properties of paraproducts
exercises
8.5 an almost orthogonality lemma and applications
8.5.1 the cotlar-knapp-stein almost orthogonality lemma
8.5.2 an application
8.5.3 almost orthogonality and the t(1) theorem
8.5.4 pseudodifferential operators
exercises
8.6 the cauchy integral of caldertn and the t(b) theorem
8.6.1 introduction of the cauchy integral operator along alipschitz curve
8.6.2 resolution of the cauchy integral and reduction of its l2boundedness to a quadratic estimate
8.6.3 a quadratic t(1) type theorem
8.6.4 a t(b) theorem and the l2 boundedness of the cauchyintegral
exercises
8.7 square roots of elliptic operators
8.7.1 preliminaries and statement of the main result
8.7.2 estimates for elliptic operators on rn
8.7.3 reduction to a quadratic estimate
8.7.4 reduction to a carleson measure estimate
8.7.5 the t(b) argument
8.7.6 the proof of lemma 8.7.9
exercises
9 weighted inequalities
9.1 the at, condition
9.1.1 motivation for the at, condition
9.1.2 properties of at, weights
exercises
9.2 reverse htlder inequality and consequences
9.2.1 the reverse helder property of at, weights
9.2.2 consequences of the reverse holder property
exercises
9.3 the a∞ condition
9.3.1 the class of a∞ weights
9.3.2 characterizations of a∞ weights
exercises
9.4 weighted norm inequalities for singular integrals
9.4.1 a review of singular integrals
9.4.2 a good lambda estimate for singular integrals
9.4.3 consequences of the good lambda estimate
9.4.4 necessity of the at, condition
exercises
9.5 further properties of ap weights
9.5.1 factorization of weights
9.5.2 extrapolation from weighted estimates on a single d~0
9.5.3 weighted inequalities versus vector-valuedinequalities
exercises
10 boundedness and convergence of fourier integrals
10.1 the multiplier problem for the ball
10.1.1 sprouting of triangles
10.1.2 the counterexample
exercises
10.2 bochner-riesz means and the carleson-sjolin theorem
10.2.1 the bochner-riesz kernel and simple estimates
10.2.2 the carleson-sj01in theorem
10.2.3 the kakeya maximal function
10.2.4 boundedness of a square function
10.2.5 the proof of lemma 10.2.5
exercises
10.3 kakeya maximal operators
10.3.1 maximal functions associated with a set ofdirections
10.3.2 the boundedness of σn on lp(r2)
10.3.3 the higher-dimensional kakeya maximal operator
exercises
10.4 fourier transform restriction and bochner-riesz means
10.4.1 necessary conditions for rp→q(sn-1) to hold
10.4.2 a restriction theorem for the fourier transform
10.4.3 applications to bochner-riesz multipliers
10.4a the full restriction theorem on r2
exercises
10.5 almost everywhere convergence of bochner-riesz means
10.5.1 a counterexample for the maximal bochner-rieszoperator
10.5.2 almost everywhere summability of the bochner-rieszmeans
10.5.3 estimates for radial multipliers
exercises
11 time--frequency analysis and the carleson-hunt theorem
11.1 almost everywhere convergence of fourier integrals
11.1.1 preliminaries
11.1.2 discretization of the carleson operator
11.1.3 linearization of a maximal dyadic sum
11.1.4 iterative selection of sets of tiles with large massand
energy
11.1.5 proof of the mass lemma 11.1.8
11.1.6 proof of energy lemma 11.1.9
11.1.7 proof of the basic estimate lemma 11.1.10
exercises
11.2 distributional estimates for the carleson operator
1.2.1 the main theorem and preliminary reductions
11.2.2 the proof of estimate (11.2.8)
11.2.3 the proof of estimate (11.2.9)
11.2.4 the proof of lemma 11.2.2
exercises
11.3 the maximal carleson operator and weighted estimates
exercises
glossary
references
index
