Produktbild: Mathematical Analysis and Applications

Mathematical Analysis and Applications Selected Topics

168,99 €

inkl. gesetzl. MwSt., Versandkostenfrei

Lieferung nach Hause

Beschreibung

Produktdetails

Einband

Gebundene Ausgabe

Erscheinungsdatum

08.05.2018

Herausgeber

Michael Ruzhansky + weitere

Verlag

John Wiley & Sons Inc

Seitenzahl

768

Maße (L/B/H)

23,1/15,7/3 cm

Gewicht

1066 g

Auflage

1. Auflage

Sprache

Englisch

ISBN

978-1-119-41434-6

Beschreibung

Produktdetails

Einband

Gebundene Ausgabe

Erscheinungsdatum

08.05.2018

Herausgeber

Verlag

John Wiley & Sons Inc

Seitenzahl

768

Maße (L/B/H)

23,1/15,7/3 cm

Gewicht

1066 g

Auflage

1. Auflage

Sprache

Englisch

ISBN

978-1-119-41434-6

Herstelleradresse

Libri GmbH
Europaallee 1
36244 Bad Hersfeld
DE

Email: gpsr@libri.de

Noch keine Bewertungen vorhanden

Verfassen Sie die erste Bewertung zu diesem Artikel

Helfen Sie anderen Kundinnen und Kunden durch Ihre Meinung.

Kundinnen und Kunden meinen

Bewertungen (0)

Die Leseprobe wird geladen.
  • Produktbild: Mathematical Analysis and Applications
  • Preface xv

    About the Editors xxi

    List of Contributors xxiii

    1 Spaces of Asymptotically Developable Functions and Applications 1
    Sergio Alejandro Carrillo Torres and Jorge Mozo Fernández

    1.1 Introduction and Some Notations 1

    1.2 Strong Asymptotic Expansions 2

    1.3 Monomial Asymptotic Expansions 7

    1.4 Monomial Summability for Singularly Perturbed Differential Equations 13

    1.5 Pfaffian Systems 15

    References 19

    2 Duality for Gaussian Processes from Random Signed Measures 23
    Palle E.T. Jorgensen and Feng Tian

    2.1 Introduction 23

    2.2 Reproducing Kernel Hilbert Spaces (RKHSs) in the Measurable Category 24

    2.3 Applications to Gaussian Processes 30

    2.4 Choice of Probability Space 34

    2.5 A Duality 37

    2.A Stochastic Processes 40

    2.B Overview of Applications of RKHSs 45

    Acknowledgments 50

    References 51

    3 Many-Body Wave Scattering Problems for Small Scatterers and Creating Materials with a Desired Refraction Coefficient 57
    Alexander G. Ramm

    3.1 Introduction 57

    3.2 Derivation of the Formulas for One-Body Wave Scattering Problems 62

    3.3 Many-Body Scattering Problem 65

    3.3.1 The Case of Acoustically Soft Particles 68

    3.3.2 Wave Scattering by Many Impedance Particles 70

    3.4 Creating Materials with a Desired Refraction Coefficient 71

    3.5 Scattering by Small Particles Embedded in an Inhomogeneous Medium 72

    3.6 Conclusions 72

    References 73

    4 Generalized Convex Functions and their Applications 77
    Adem Kiliçman and Wedad Saleh

    4.1 Brief Introduction 77

    4.2 Generalized E-Convex Functions 78

    4.3 E¿-Epigraph 84

    4.4 Generalized s-Convex Functions 85

    4.5 Applications to Special Means 96

    References 98

    5 Some Properties and Generalizations of the Catalan, Fuss, and Fuss-Catalan Numbers 101
    Feng Qi and Bai-Ni Guo

    5.1 The Catalan Numbers 101

    5.1.1 A Definition of the Catalan Numbers 101

    5.1.2 The History of the Catalan Numbers 101

    5.1.3 A Generating Function of the Catalan Numbers 102

    5.1.4 Some Expressions of the Catalan Numbers 102

    5.1.5 Integral Representations of the Catalan Numbers 103

    5.1.6 Asymptotic Expansions of the Catalan Function 104

    5.1.7 Complete Monotonicity of the Catalan Numbers 105

    5.1.8 Inequalities of the Catalan Numbers and Function 106

    5.1.9 The Bell Polynomials of the Second Kind and the Bessel Polynomials 109

    5.2 The Catalan-Qi Function 111

    5.2.1 The Fuss Numbers 111

    5.2.2 A Definition of the Catalan-Qi Function 111

    5.2.3 Some Identities of the Catalan-Qi Function 112

    5.2.4 Integral Representations of the Catalan-Qi Function 114

    5.2.5 Asymptotic Expansions of the Catalan-Qi Function 115

    5.2.6 Complete Monotonicity of the Catalan-Qi Function 116

    5.2.7 Schur-Convexity of the Catalan-Qi Function 118

    5.2.8 Generating Functions of the Catalan-Qi Numbers 118

    5.2.9 A Double Inequality of the Catalan-Qi Function 118

    5.2.10 The q-Catalan-Qi Numbers and Properties 119

    5.2.11 The Catalan Numbers and the k-Gamma and k-Beta Functions 119

    5.2.12 Series Identities Involving the Catalan Numbers 119

    5.3 The Fuss-Catalan Numbers 119

    5.3.1 A Definition of the Fuss-Catalan Numbers 119

    5.3.2 A Product-Ratio Expression of the Fuss-Catalan Numbers 120

    5.3.3 Complete Monotonicity of the Fuss-Catalan Numbers 120

    5.3.4 A Double Inequality for the Fuss-Catalan Numbers 121

    5.4 The Fuss-Catalan-Qi Function 121

    5.4.1 A Definition of the Fuss-Catalan-Qi Function 121

    5.4.2 A Product-Ratio Expression of the Fuss-Catalan-Qi Function 122

    5.4.3 Integral Representations of the Fuss-Catalan-Qi Function 123

    5.4.4 Complete Monotonicity of the Fuss-Catalan-Qi Function 124

    5.5 Some Properties for Ratios of Two Gamma Functions 124

    5.5.1 An Integral Representation and Complete Monotonicity 125

    5.5.2 An Exponential Expansion for the Ratio of Two Gamma Functions 125

    5.5.3 A Double Inequality for the Ratio of Two Gamma Functions 125

    5.6 Some New Results on the Catalan Numbers 126

    5.7 Open Problems 126

    Acknowledgments 127

    References 127

    6 Trace Inequalities of Jensen Type for Self-adjoint Operators in Hilbert Spaces: A Survey of Recent Results 135
    Silvestru Sever Dragomir

    6.1 Introduction 135

    6.1.1 Jensen's Inequality 135

    6.1.2 Traces for Operators in Hilbert Spaces 138

    6.2 Jensen's Type Trace Inequalities 141

    6.2.1 Some Trace Inequalities for Convex Functions 141

    6.2.2 Some Functional Properties 145

    6.2.3 Some Examples 151

    6.2.4 More Inequalities for Convex Functions 154

    6.3 Reverses of Jensen's Trace Inequality 157

    6.3.1 A Reverse of Jensen's Inequality 157

    6.3.2 Some Examples 163

    6.3.3 Further Reverse Inequalities for Convex Functions 165

    6.3.4 Some Examples 169

    6.3.5 Reverses of Hölder's Inequality 174

    6.4 Slater's Type Trace Inequalities 177

    6.4.1 Slater's Type Inequalities 177

    6.4.2 Further Reverses 180

    References 188

    7 Spectral Synthesis and Its Applications 193
    László Székelyhidi

    7.1 Introduction 193

    7.2 Basic Concepts and Function Classes 195

    7.3 Discrete Spectral Synthesis 203

    7.4 Nondiscrete Spectral Synthesis 217

    7.5 Spherical Spectral Synthesis 219

    7.6 Spectral Synthesis on Hypergroups 238

    7.7 Applications 248

    Acknowledgments 252

    References 252

    8 Various Ulam-Hyers Stabilities of Euler-Lagrange-Jensen General (a, b; k = a + b)-Sextic Functional Equations 255
    John Michael Rassias and Narasimman Pasupathi

    8.1 Brief Introduction 255

    8.2 General Solution of Euler-Lagrange-Jensen General

    (a, b; k = a + b)-Sextic Functional Equation 257

    8.3 Stability Results in Banach Space 258

    8.3.1 Banach Space: Direct Method 258

    8.3.2 Banach Space: Fixed Point Method 261

    8.4 Stability Results in Felbin's Type Spaces 267

    8.4.1 Felbin's Type Spaces: Direct Method 268

    8.4.2 Felbin's Type Spaces: Fixed Point Method 269

    8.5 Intuitionistic Fuzzy Normed Space: Stability Results 270

    8.5.1 IFNS: Direct Method 272

    8.5.2 IFNS: Fixed Point Method 279

    References 281

    9 A Note on the Split Common Fixed Point Problem and its Variant Forms 283
    Adem Kiliçman and L.B. Mohammed

    9.1 Introduction 283

    9.2 Basic Concepts and Definitions 284

    9.2.1 Introduction 284

    9.2.2 Vector Space 284

    9.2.3 Hilbert Space and its Properties 286

    9.2.4 Bounded Linear Map and its Properties 288

    9.2.5 Some Nonlinear Operators 289

    9.2.6 Problem Formulation 294

    9.2.7 Preliminary Results 294

    9.2.8 Strong Convergence for the Split Common Fixed-Point Problems for Total Quasi-Asymptotically Nonexpansive Mappings 296

    9.2.9 Strong Convergence for the Split Common Fixed-Point Problems for Demicontractive Mappings 302

    9.2.10 Application to Variational Inequality Problems 306

    9.2.11 On Synchronal Algorithms for Fixed and Variational Inequality Problems in Hilbert Spaces 307

    9.2.12 Preliminaries 307

    9.3 A Note on the Split Equality Fixed-Point Problems in Hilbert Spaces 315

    9.3.1 Problem Formulation 315

    9.3.2 Preliminaries 316

    9.3.3 The Split Feasibility and Fixed-Point Equality Problems for Quasi-Nonexpansive Mappings in Hilbert Spaces 316

    9.3.4 The Split Common Fixed-Point Equality Problems for Quasi-Nonexpansive Mappings in Hilbert Spaces 320

    9.4 Numerical Example 322

    9.5 The Split Feasibility and Fixed Point Problems for Quasi-Nonexpansive Mappings in Hilbert Spaces 328

    9.5.1 Problem Formulation 328

    9.5.2 Preliminary Results 328

    9.6 Ishikawa-Type Extra-Gradient Iterative Methods for Quasi-Nonexpansive Mappings in Hilbert Spaces 329

    9.6.1 Application to Split Feasibility Problems 334

    9.7 Conclusion 336

    References 337

    10 Stabilities and Instabilities of Rational Functional Equations and Euler-Lagrange-Jensen (a, b)-Sextic Functional Equations 341
    John Michael Rassias, Krishnan Ravi, and Beri V. Senthil Kumar

    10.1 Introduction 341

    10.1.1 Growth of Functional Equations 342

    10.1.2 Importance of Functional Equations 342

    10.1.3 Functional Equations Relevant to Other Fields 343

    10.1.4 Definition of Functional Equation with Examples 343

    10.2 Ulam Stability Problem for Functional Equation 344

    10.2.1 ¿-Stability of Functional Equation 344

    10.2.2 Stability Involving Sum of Powers of Norms 345

    10.2.3 Stability Involving Product of Powers of Norms 346

    10.2.4 Stability Involving a General Control Function 347

    10.2.5 Stability Involving Mixed Product-Sum of Powers of Norms 347

    10.2.6 Application of Ulam Stability Theory 348

    10.3 Various Forms of Functional Equations 348

    10.4 Preliminaries 353

    10.5 Rational Functional Equations 355

    10.5.1 Reciprocal Type Functional Equation 355

    10.5.2 Solution of Reciprocal Type Functional Equation 356

    10.5.3 Generalized Hyers-Ulam Stability of Reciprocal Type Functional Equation 357

    10.5.4 Counter-Example 360

    10.5.5 Geometrical Interpretation of Reciprocal Type Functional Equation 362

    10.5.6 An Application of Equation (10.41) to Electric Circuits 364

    10.5.7 Reciprocal-Quadratic Functional Equation 364

    10.5.8 General Solution of Reciprocal-Quadratic Functional Equation 366

    10.5.9 Generalized Hyers-Ulam Stability of Reciprocal-Quadratic Functional Equations 368

    10.5.10 Counter-Examples 373

    10.5.11 Reciprocal-Cubic and Reciprocal-Quartic Functional Equations 375

    10.5.12 Hyers-Ulam Stability of Reciprocal-Cubic and Reciprocal-Quartic Functional Equations 375

    10.5.13 Counter-Examples 380

    10.6 Euler-Lagrange-Jensen (a, b; k = a + b)-Sextic Functional Equations 384

    10.6.1 Generalized Ulam-Hyers Stability of Euler-Lagrange-Jensen Sextic Functional Equation Using Fixed Point Method 384

    10.6.2 Counter-Example 387

    10.6.3 Generalized Ulam-Hyers Stability of Euler-Lagrange-Jensen Sextic Functional Equation Using Direct Method 389

    References 395

    11 Attractor of the Generalized Contractive Iterated Function System 401
    Mujahid Abbas and Talat Nazir

    11.1 Iterated Function System 401

    11.2 Generalized F-contractive Iterated Function System 407

    11.3 Iterated Function System in b-Metric Space 414

    11.4 Generalized F-Contractive Iterated Function System in b-Metric Space 420

    References 426

    12 Regular and Rapid Variations and Some Applications 429
    Ljubiša D.R. Ko¿inac, Dragan Djur¿i¿, and Jelena V. Manojlovi¿

    12.1 Introduction and Historical Background 429

    12.2 Regular Variation 431

    12.2.1 The Class Tr(RVs) 432

    12.2.2 Classes of Sequences Related to Tr(RVs) 434

    12.2.3 The Class ORVs and Seneta Sequences 436

    12.3 Rapid Variation 437

    12.3.1 Some Properties of Rapidly Varying Functions 438

    12.3.2 The Class ARVs 440

    12.3.3 The Class KRs,¿ 442

    12.3.4 The Class Tr(Rs,¿) 447

    12.3.5 Subclasses of Tr(Rs,¿) 448

    12.3.6 The Class ¿s 451

    12.4 Applications to Selection Principles 453

    12.4.1 First Results 455

    12.4.2 Improvements 455

    12.4.3 When ONE has a Winning Strategy? 460

    12.5 Applications to Differential Equations 463

    12.5.1 The Existence of all Solutions of (A) 464

    12.5.2 Superlinear Thomas-Fermi Equation (A) 466

    12.5.3 Sublinear Thomas-Fermi Equation (A) 470

    12.5.4 A Generalization 480

    References 486

    13 n-Inner Products, n-Norms, and Angles Between Two Subspaces 493
    Hendra Gunawan

    13.1 Introduction 493

    13.2 n-Inner Product Spaces and n-Normed Spaces 495

    13.2.1 Topology in n-Normed Spaces 499

    13.3 Orthogonality in n-Normed Spaces 500

    13.3.1 G-, P-, I-, and BJ- Orthogonality 503

    13.3.2 Remarks on the n-Dimensional Case 505

    13.4 Angles Between Two Subspaces 505

    13.4.1 An Explicit Formula 509

    13.4.2 A More General Formula 511

    References 513

    14 Proximal Fiber Bundles on Nerve Complexes 517
    James F. Peters

    14.1 Brief Introduction 517

    14.2 Preliminaries 518

    14.2.1 Nerve Complexes and Nerve Spokes 518

    14.2.2 Descriptions and Proximities 521

    14.2.3 Descriptive Proximities 523

    14.3 Sewing Regions Together 527

    14.3.1 Sewing Nerves Together with Spokes to Construct a Nervous System Complex 529

    14.4 Some Results for Fiber Bundles 530

    14.5 Concluding Remarks 534

    References 534

    15 Approximation by Generalizations of Hybrid Baskakov Type Operators Preserving Exponential Functions 537
    Vijay Gupta

    15.1 Introduction 537

    15.2 Baskakov-Szász Operators 539

    15.3 Genuine Baskakov-Szász Operators 542

    15.4 Preservation of eAx 545

    15.5 Conclusion 549

    References 550

    16 Well-Posed Minimization Problems via the Theory of Measures of Noncompactness 553
    Józef Banä and Tomasz Zaj¿c

    16.1 Introduction 553

    16.2 Minimization Problems and Their Well-Posedness in the Classical Sense 554

    16.3 Measures of Noncompactness 556

    16.4 Well-Posed Minimization Problems with Respect to Measures of Noncompactness 565

    16.5 Minimization Problems for Functionals Defined in Banach Sequence Spaces 568

    16.6 Minimization Problems for Functionals Defined in the Classical Space C([a, b])) 576

    16.7 Minimization Problems for Functionals Defined in the Space of Functions Continuous and Bounded on the Real Half-Axis 580

    References 584

    17 Some Recent Developments on Fixed Point Theory in Generalized Metric Spaces 587
    Poom Kumam and Somayya Komal

    17.1 Brief Introduction 587

    17.2 Some Basic Notions and Notations 593

    17.3 Fixed Points Theorems 596

    17.3.1 Fixed Points Theorems for Monotonic and Nonmonotonic Mappings 597

    17.3.2 PPF-Dependent Fixed-Point Theorems 600

    17.3.3 Fixed Points Results in b-Metric Spaces 602

    17.3.4 The generalized Ulam-Hyers Stability in b-Metric Spaces 604

    17.3.5 Well-Posedness of a Function with Respect to ¿-Admissibility in b-Metric Spaces 605

    17.3.6 Fixed Points for F-Contraction 606

    17.4 Common Fixed Points Theorems 608

    17.4.1 Common Fixed-Point Theorems for Pair of Weakly Compatible Mappings in Fuzzy Metric Spaces 609

    17.5 Best Proximity Points 611

    17.6 Common Best Proximity Points 614

    17.7 Tripled Best Proximity Points 617

    17.8 Future Works 624

    References 624

    18 The Basel Problem with an Extension 631
    Anthony Sofo

    18.1 The Basel Problem 631

    18.2 An Euler Type Sum 640

    18.3 The Main Theorem 645

    18.4 Conclusion 652

    References 652

    19 Coupled Fixed Points and Coupled Coincidence Points via Fixed Point Theory 661
    Adrian Petru¿el and Gabriela Petru¿el

    19.1 Introduction and Preliminaries 661

    19.2 Fixed Point Results 665

    19.2.1 The Single-Valued Case 665

    19.2.2 The Multi-Valued Case 673

    19.3 Coupled Fixed Point Results 680

    19.3.1 The Single-Valued Case 680

    19.3.2 The Multi-Valued Case 686

    19.4 Coincidence Point Results 689

    19.5 Coupled Coincidence Results 699

    References 704

    20 The Corona Problem, Carleson Measures, and Applications 709
    Alberto Saracco

    20.1 The Corona Problem 709

    20.1.1 Banach Algebras: Spectrum 709

    20.1.2 Banach Algebras: Maximal Spectrum 710

    20.1.3 The Algebra of Bounded Holomorphic Functions and the Corona Problem 710

    20.2 Carleson's Proof and Carleson Measures 711

    20.2.1 Wolff's Proof 712

    20.3 The Corona Problem in Higher Henerality 712

    20.3.1 The Corona Problem in ¿ 712

    20.3.2 The Corona Problem in Riemann Surfaces: A Positive and a Negative Result 713

    20.3.3 The Corona Problem in Domains of ¿n 714

    20.3.4 The Corona Problem for Quaternionic Slice-Regular Functions 715

    20.3.4.1 Slice-Regular Functions f ¿ D ¿ ¿ 715

    20.3.4.2 The Corona Theorem in the Quaternions 717

    20.4 Results on Carleson Measures 718

    20.4.1 Carleson Measures of Hardy Spaces of the Disk 718

    20.4.2 Carleson Measures of Bergman Spaces of the Disk 719

    20.4.3 Carleson Measures in the Unit Ball of ¿n 720

    20.4.4 Carleson Measures in Strongly Pseudoconvex Bounded Domains of ¿n 722

    20.4.5 Generalizations of Carleson Measures and Applications to Toeplitz Operators 723

    20.4.6 Explicit Examples of Carleson Measures of Bergman Spaces 724

    20.4.7 Carleson Measures in the Quaternionic Setting 725

    20.4.7.1 Carleson Measures on Hardy Spaces of ¿ ¿ ¿ 725

    20.4.7.2 Carleson Measures on Bergman Spaces of ¿ ¿ ¿ 726

    References 728

    Index 731