پیشرفتها در تحلیل هارمونیک و معادلات دیفرانسیل جزئی: جلسه ویژه AMS در تحلیل هارمونیک و معادلات دیفرانسیل جزئی، 21-22 آوریل 2018، دانشگاه شمال شرقی، بوستون، ماساچوست
Advances in harmonic analysis and partial differential equations : AMS special session on Harmonic Analysis and Partial Differential Equations, April 21-22, 2018, Northeastern University, Boston, MA
معرفی کتاب «پیشرفتها در تحلیل هارمونیک و معادلات دیفرانسیل جزئی: جلسه ویژه AMS در تحلیل هارمونیک و معادلات دیفرانسیل جزئی، 21-22 آوریل 2018، دانشگاه شمال شرقی، بوستون، ماساچوست» (با عنوان لاتین Advances in harmonic analysis and partial differential equations : AMS special session on Harmonic Analysis and Partial Differential Equations, April 21-22, 2018, Northeastern University, Boston, MA) نوشتهٔ Donatella Danielli (editor), Irina Mitrea (editor)، منتشرشده توسط نشر American Mathematical
Society در سال 2020. این کتاب در فرمت pdf، زبان انگلیسی ارائه شده است.
This volume contains the proceedings of the AMS Special Session on Harmonic Analysis and Partial Differential Equations, held from April 21-22, 2018, at Northeastern University, Boston, Massachusetts. The book features a series of recent developments at the interface between harmonic analysis and partial differential equations and is aimed toward the theoretical and applied communities of researchers working in real, complex, and harmonic analysis, partial differential equations, and their applications. The topics covered belong to the general areas of the theory of function spaces, partial differential equations of elliptic, parabolic, and dissipative types, geometric optics, free boundary problems, and ergodic theory, and the emphasis is on a host of new concepts, methods, and results. Cover Title page Contents Preface BMO on shapes and sharp constants 1. Introduction 2. Preliminaries 3. BMO spaces with respect to shapes 4. Shapewise inequalities on BMO 5. Rearrangements and the absolute value 6. Truncations 7. The John-Nirenberg inequality 8. Product decomposition Acknowledgments References Applications of harmonic analysis techniques to regularity problems of dissipative equations 1. Overview 2. Harmonic analysis tools 3. Low modes regularity criteria for fluid equations Acknowledgments References Two classical properties of the Bessel quotient I_{ν+1}/I_{ν} and their implications in pde’s 1. Introduction 2. The Bessel semigroup 3. A curvature-dimension inequality 4. An inequality of Li-Yau type for the Bessel semigroup 5. A comparison with the results of Chiarenza-Serapioni and of Epstein-Mazzeo 6. A sharp Harnack inequality for the parabolic extension problem 7. Monotonicity formulas of Struwe and Almgren-Poon type for the Bessel semigroup 8. Appendix: The modified Bessel function I_{ν}(z) Acknowledgments References On the existence of dichromatic single element lenses 1. Introduction 2. Preliminaries 3. The collimated case: Problem A 3.1. Estimates of the upper surfaces for two colors 4. First order functional differential equations 4.1. Uniqueness of solutions 5. One point source case: Problem B 5.1. Two dimensional case, w∈Ω. 5.2. Derivation of a system of functional equations from the solvability of problem B in the plane. 5.3. Solutions of (5.4)yield local solutions to the optical problem. 5.4. On the solvability of the algebraic system (4.3) 5.5. Existence of local solutions to (5.4) Acknowledgments References Free boundary regularity near the fixed boundary for the fully nonlinear obstacle problem 1. Introduction 2. Non-transversal intersection and classification of blow-up limits 3. C1 regularity 4. Appendix Acknowledgments References The Poisson integral formula for variable-coefficient elliptic systems in rough domains 1. Introduction 2. Preliminary matters 3. Proof of main result Acknowledgment References Variations on quantum ergodic theorems, II 1. Introduction 2. Quantum ergodic theorems with discontinuous symbols 2.1. Quantization of discontinuous symbols 2.2. Weyl law 2.3. Quantum ergodic theorems 2.4. L^{p} eigenfunction estimates and quantum ergodic theorems 3. Quantum ergodic theorems for conjugates e^{-itΛ}Ae^{itΛ} 3.1. Complements to Weyl laws and Egorov’s theorem 3.2. Proof of Theorem 3.0.3 3.3. Comments and examples References Back Cover "The back-up contains a draft title page, copyright page, toc, and preface"-- Provided by publisher