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Real Analysis: Series, Functions of Several Variables, and Applications 1st ed. 2017 [Kietas viršelis]

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  • Formatas: Hardback, 392 pages, aukštis x plotis: 235x155 mm, weight: 769 g, 44 Illustrations, black and white; IX, 392 p. 44 illus., 1 Hardback
  • Serija: Undergraduate Texts in Mathematics
  • Išleidimo metai: 16-Dec-2017
  • Leidėjas: Springer-Verlag New York Inc.
  • ISBN-10: 1493973673
  • ISBN-13: 9781493973675
Kitos knygos pagal šią temą:
Real Analysis: Series, Functions of Several Variables, and Applications 1st ed. 2017Didesnis paveikslėlis
  • Formatas: Hardback, 392 pages, aukštis x plotis: 235x155 mm, weight: 769 g, 44 Illustrations, black and white; IX, 392 p. 44 illus., 1 Hardback
  • Serija: Undergraduate Texts in Mathematics
  • Išleidimo metai: 16-Dec-2017
  • Leidėjas: Springer-Verlag New York Inc.
  • ISBN-10: 1493973673
  • ISBN-13: 9781493973675
Kitos knygos pagal šią temą:
Pastovi nuoroda: https://www.kriso.lt/db/9781493973675.html
Raktažodžiai:
This book develops the theory of multivariable analysis, building on the single variable foundations established in the companion volume, Real Analysis: Foundations and Functions of One Variable. Together, these volumes form the first English edition of the popular Hungarian original, Valós Analķzis I & II, based on courses taught by the authors at Eötvös Lorįnd University, Hungary, for more than 30 years. Numerous exercises are included throughout, offering ample opportunities to master topics by progressing from routine to difficult problems. Hints or solutions to many of the more challenging exercises make this book ideal for independent study, or further reading.

Intended as a sequel to a course in single variable analysis, this book builds upon and expands these ideas into higher dimensions. The modular organization makes this text adaptable for either a semester or year-long introductory course. Topics include: differentiation and integration of functions of several variables; infinite numerical series; sequences and series of functions; and applications to other areas of mathematics. Many historical notes are given and there is an emphasis on conceptual understanding and context, be it within mathematics itself or more broadly in applications, such as physics. By developing the students intuition throughout, many definitions and results become motivated by insights from their context.

Recenzijos

This book develops a thorough treatment of multivariate derivatives, viewing them both as linear transformations and as partial derivatives. The book is consistent in addressing the classical analysis of real functions of several variables. This volume will appeal to students in pure and applied mathematics, as well as scientists looking to acquire a firm footing in mathematical analysis. (Teodora-Liliana Rdulescu, zbMATH 1407.26001, 2019)



The explicit intent of the authors is to present material gradually, and to develop precision based on intuition with the help of well-designed examples. The book contains 600 exercises. In my opinion this interesting book represents an alternative viewpoint in real analysis. (Zbigniew Grande, Mathematical Reviews, August, 2018)

1 Rp → R functions
1(66)
1.1 Euclidean Spaces
1(2)
1.2 Real Functions of Several Variables and Their Graphs
3(2)
1.3 Convergence of Point Sequences
5(3)
1.4 Basics of Point Set Theory
8(12)
1.5 Limits
20(4)
1.6 Continuity
24(6)
1.7 Partial Derivatives
30(5)
1.8 Differentiability
35(11)
1.9 Higher-Order Derivatives
46(6)
1.10 Applications of Differentiation
52(11)
1.11 Appendix: Tangent Lines and Tangent Planes
63(4)
2 Functions from Rp to Rq
67(28)
2.1 Limits and Continuity
67(3)
2.2 Differentiability
70(4)
2.3 Differentiation Rules
74(5)
2.4 Implicit and Inverse Functions
79(16)
3 The Jordan Measure
95(28)
3.1 Definition and Basic Properties of the Jordan Measure
95(11)
3.2 The measure of a Few Particular Sets
106(9)
3.3 Linear Transformations and the Jordan Measure
115(4)
3.4 Appendix: The Measurability of Bounded Convex Sets
119(4)
4 Integrals of Multivariable Functions I
123(32)
4.1 The Definition of the Multivariable Integral
123(5)
4.2 The Multivariable Integral on Jordan Measurable Sets
128(7)
4.3 Calculating Multivariable Integrals
135(11)
4.4 First Appendix: Proof of Theorem 4.12
146(2)
4.5 Second Appendix: Integration by Substitution (Proof of Theorem 4.22)
148(7)
5 Integrals of Multivariable Functions II
155(38)
5.1 The Line Integral
155(8)
5.2 Conditions for the Existence of the Primitive Function
163(12)
5.3 Green's Theorem
175(8)
5.4 Surface and Surface Area
183(4)
5.5 Integral Theorems in Three Dimension
187(6)
6 Infinite Series
193(36)
6.1 Basics on Infinite Series
193(4)
6.2 Operations on Infinite Series
197(5)
6.3 Absolute and Conditionally Convergent Series
202(7)
6.4 Other Convergence Criteria
209(8)
6.5 The Product of Infinite Series
217(5)
6.6 Summable Series
222(5)
6.7 Appendix: On the History of Infinite Series
227(2)
7 Sequences and Series of Functions
229(74)
7.1 The Convergence of Sequences of Functions
229(10)
7.2 The Convergence of Series of Functions
239(10)
7.3 Taylor Series and Power Series
249(15)
7.4 Abel Summation
264(4)
7.5 Fourier Series
268(15)
7.6 Further Applications
283(9)
7.7 First Appendix: The Cauchy-Hadamard Formula
292(3)
7.8 Second Appendix: Complex Series
295(2)
7.9 Third Appendix: On the History of the Fourier Series
297(6)
8 Miscellaneous Topics
303(58)
8.1 Approximation of Sums
303(8)
8.2 Approximation of Definite Integrals
311(10)
8.3 Parametric Integrals
321(18)
8.4 Sets with Lebesgue Measure Zero and the Lebesgue Criterion for Integrability
339(4)
8.5 Two Applications of Lebesgue's Theorem
343(3)
8.6 Some Applications of Integration in Number Theory
346(6)
8.7 Brouwer's Fixed-Point Theorem
352(6)
8.8 The Peano Curve
358(3)
9 Hints, Solutions
361(22)
Notation 383(2)
References 385(2)
Index 387
Miklós Laczkovich is a member of the Hungarian Academy of Sciences and professor emeritus at Eötvös Lorįnd University Budapest and University College London. He was awarded the Ostrowski Prize in 1993 and the Széchenyi Prize in 1998.

Vera T. Sós is a member of the Hungarian Academy of Sciences and professor emeritus at Eötvös Lorįnd Univesity Budapest and the Alfred Renyi Mathematical Institute of the Hungarian Academy of Sciences. She was awarded the Széchenyi Prize in 1997.