E. Zeidler
Nonlinear Functional Analysis and Its Applications
II/ A: Linear Monotone Operators
Übersetzer: Boron, Leo F.; Zeidler, E.
E. Zeidler
Nonlinear Functional Analysis and Its Applications
II/ A: Linear Monotone Operators
Übersetzer: Boron, Leo F.; Zeidler, E.
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This is the second of a five-volume exposition of the main principles of nonlinear functional analysis and its applications to the natural sciences, economics, and numerical analysis. The presentation is self -contained and accessible to the nonspecialist. Part II concerns the theory of monotone operators. It is divided into two subvolumes, II/A and II/B, which form a unit. The present Part II/A is devoted to linear monotone operators. It serves as an elementary introduction to the modern functional analytic treatment of variational problems, integral equations, and partial differential…mehr
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This is the second of a five-volume exposition of the main principles of nonlinear functional analysis and its applications to the natural sciences, economics, and numerical analysis. The presentation is self -contained and accessible to the nonspecialist. Part II concerns the theory of monotone operators. It is divided into two subvolumes, II/A and II/B, which form a unit. The present Part II/A is devoted to linear monotone operators. It serves as an elementary introduction to the modern functional analytic treatment of variational problems, integral equations, and partial differential equations of elliptic, parabolic and hyperbolic type. This book also represents an introduction to numerical functional analysis with applications to the Ritz method along with the method of finite elements, the Galerkin methods, and the difference method. Many exercises complement the text. The theory of monotone operators is closely related to Hilbert's rigorous justification of the Dirichlet principle, and to the 19th and 20th problems of Hilbert which he formulated in his famous Paris lecture in 1900, and which strongly influenced the development of analysis in the twentieth century. TOC:Preface to Part II/A * Introduction to the Subject * Chapter 18 Variational Problems, the Ritz Method, and the Idea of Orthogonality * Chapter 19 The Galerkin Method for Differential and Integral Equations, the Friedrichs Extension, and the Idea of Self-Adjointness * Chapter 20 Difference Methods and Stability * Linear Monotone Problems * Chapter 21 Auxiliary Tools and the Convergence of the Galerkin Method for Linear Operator Equations * Chapter 22 Hilbert Space Methods and Linear Elliptic Differential Equations * Chapter 23 Hilbert Space Methods and Linear Parabolic Differential Equations * Chapter 24 Hilbert Space Methods and Linear Hyperbolic Differential Equations
Produktdetails
- Produktdetails
- Verlag: Springer New York / Springer US
- 1990
- Seitenzahl: 488
- Erscheinungstermin: 11. Dezember 1989
- Englisch
- Abmessung: 241mm x 160mm x 32mm
- Gewicht: 893g
- ISBN-13: 9780387968025
- ISBN-10: 0387968024
- Artikelnr.: 21203752
- Verlag: Springer New York / Springer US
- 1990
- Seitenzahl: 488
- Erscheinungstermin: 11. Dezember 1989
- Englisch
- Abmessung: 241mm x 160mm x 32mm
- Gewicht: 893g
- ISBN-13: 9780387968025
- ISBN-10: 0387968024
- Artikelnr.: 21203752
to the Subject.
18 Variational Problems, the Ritz Method, and the Idea of Orthogonality.
§18.1. The Space C0?(G) and the Variational Lemma.
§18.2. Integration by Parts.
§18.3. The First Boundary Value Problem and the Ritz Method.
§18.4. The Second and Third Boundary Value Problems and the Ritz Method.
§18.5. Eigenvalue Problems and the Ritz Method.
§18.6. The Hölder Inequality and its Applications.
§18.7. The History of the Dirichlet Principle and Monotone Operators.
§18.8. The Main Theorem on Quadratic Minimum Problems.
§18.9. The Inequality of Poincaré
Friedrichs.
§18.10. The Functional Analytic Justification of the Dirichlet Principle.
§18.11. The Perpendicular Principle, the Riesz Theorem, and the Main Theorem on Linear Monotone Operators.
§18.12. The Extension Principle and the Completion Principle.
§18.13. Proper Subregions.
§18.14. The Smoothing Principle.
§18.15. The Idea of the Regularity of Generalized Solutions and the Lemma of Weyl.
§18.16. The Localization Principle.
§18.17. Convex Variational Problems, Elliptic Differential Equations, and Monotonicity.
§18.18. The General Euler
Lagrange Equations.
§18.19. The Historical Development of the 19th and 20th Problems of Hilbert and Monotone Operators.
§18.20. Sufficient Conditions for Local and Global Minima and Locally Monotone Operators.
19 The Galerkin Method for Differential and Integral Equations, the Friedrichs Extension, and the Idea of Self
Adjointness.
§19.1. Elliptic Differential Equations and the Galerkin Method.
§19.2. Parabolic Differential Equations and the Galerkin Method.
§19.3. Hyperbolic Differential Equations and the Galerkin Method.
§19.4. Integral Equations and the Galerkin Method.
§19.5. Complete Orthonormal Systems and Abstract Fourier Series.
§19.6. Eigenvalues of Compact Symmetric Operators (Hilbert
Schmidt Theory).
§19.7. Proof of Theorem 19.B.
§19.8. Self
Adjoint Operators.
§19.9. The Friedrichs Extension of Symmetric Operators.
§19.10. Proof of Theorem 19.C.
§19.11. Application to the Poisson Equation.
§19.12. Application to the Eigenvalue Problem for the Laplace Equation.
§19.13. The Inequality of Poincaré and the Compactness Theorem of Rellich.
§19.14. Functions of Self
Adjoint Operators.
§19.15. Application to the Heat Equation.
§19.16. Application to the Wave Equation.
§19.17. Semigroups and Propagators, and Their Physical Relevance.
§19.18. Main Theorem on Abstract Linear Parabolic Equations.
§19.19. Proof of Theorem 19.D.
§19.20. Monotone Operators and the Main Theorem on Linear Nonexpansive Semigroups.
§19.21. The Main Theorem on One
Parameter Unitary Groups.
§19.22. Proof of Theorem 19.E.
§19.23. Abstract Semilinear Hyperbolic Equations.
§19.24. Application to Semilinear Wave Equations.
§19.25. The Semilinear Schrödinger Equation.
§19.26. Abstract Semilinear Parabolic Equations, Fractional Powers of Operators, and Abstract Sobolev Spaces.
§19.27. Application to Semilinear Parabolic Equations.
§19.28. Proof of Theorem 19.I.
§19.29. Five General Uniqueness Principles and Monotone Operators.
§19.30. A General Existence Principle and Linear Monotone Operators.
20 Difference Methods and Stability.
§20.1. Consistency, Stability, and Convergence.
§20.2. Approximation of Differential Quotients.
§20.3. Application to Boundary Value Problems for Ordinary Differential Equations.
§20.4. Application to Parabolic Differential Equations.
§20.5. Application to Elliptic Differential Equations.
§20.6. The Equivalence Between Stability and Convergence.
§20.7. The Equivalence Theorem of Lax for Evolution Equations.
Linear Monotone Problems.
21 Auxiliary Tools and the Convergence of the Galerkin Method for Linear Operator Equations.
§21.1. Generalized Derivatives.
§21.2. Sobolev Spaces.
§21.3. The Sobolev Embedding Theorems.
§21.4. Proof of the Sobolev Embedding Theorems.
§21.5. Duality in B
Spaces.
§21.6. Duality in H
Spaces.
§21.7. The Idea of Weak Convergence.
§21.8. The Idea of Weak* Convergence.
§21.9. Linear Operators.
§21.10. Bilinear Forms.
§21.11. Application to Embeddings.
§21.12. Projection Operators.
§21.13. Bases and Galerkin Schemes.
§21.14. Application to Finite Elements.
§21.15. Riesz
Schauder Theory and Abstract Fredholm Alternatives.
§21.16. The Main Theorem on the Approximation
Solvability of Linear Operator Equations, and the Convergence of the Galerkin Method.
§21.17. Interpolation Inequalities and a Convergence Trick.
§21.18. Application to the Refined Banach Fixed
Point Theorem and the Convergence of Iteration Methods.
§21.19. The Gagliardo
Nirenberg Inequalities.
§21.20. The Strategy of the Fourier Transform for Sobolev Spaces.
§21.21. Banach Algebras and Sobolev Spaces.
§21.22. Moser
Type Calculus Inequalities.
§21.23. Weakly Sequentially Continuous Nonlinear Operators on Sobolev Spaces.
22 Hilbert Space Methods and Linear Elliptic Differential Equations.
§22.1. Main Theorem on Quadratic Minimum Problems and the Ritz Method.
§22.2. Application to Boundary Value Problems.
§22.3. The Method of Orthogonal Projection, Duality, and a posteriori Error Estimates for the Ritz Method.
§22.4. Application to Boundary Value Problems.
§22.5. Main Theorem on Linear Strongly Monotone Operators and the Galerkin Method.
§22.6. Application to Boundary Value Problems.
§22.7. Compact Perturbations of Strongly Monotone Operators, Fredholm Alternatives, and the Galerkin Method.
§22.8. Application to Integral Equations.
§22.9. Application to Bilinear Forms.
§22.10. Application to Boundary Value Problems.
§22.11. Eigenvalue Problems and the Ritz Method.
§22.12. Application to Bilinear Forms.
§22.13. Application to Boundary
Eigenvalue Problems.
§22.14. Gårding Forms.
§22.15. The Gårding Inequality for Elliptic Equations.
§22.16. The Main Theorems on Gårding Forms.
§22.17. Application to Strongly Elliptic Differential Equations of Order 2m.
§22.18. Difference Approximations.
§22.19. Interior Regularity of Generalized Solutions.
§22.20. Proof of Theorem 22.H.
§22.21. Regularity of Generalized Solutions up to the Boundary.
§22.22. Proof of Theorem 22.I.
23 Hilbert Space Methods and Linear Parabolic Differential Equations.
§23.1. Particularities in the Treatment of Parabolic Equations.
§23.2. The Lebesgue Space Lp(0, T; X) of Vector
Valued Functions.
§23.3. The Dual Space to Lp(0, T; X).
§23.4. Evolution Triples.
§23.5. Generalized Derivatives.
§23.6. The Sobolev Space WP1 (0, T; V, H).
§23.7. Main Theorem on First
Order Linear Evolution Equations and the Galerkin Method.
§23.8. Application to Parabolic Differential Equations.
§23.9. Proof of the Main Theorem.
24 Hilbert Space Methods and Linear Hyperbolic Differential Equations.
§24.1. Main Theorem on Second
Order Linear Evolution Equations and the Galerkin Method.
§24.2. Application to Hyperbolic Differential Equations.
§24.3. Proof of the Main Theorem.
18 Variational Problems, the Ritz Method, and the Idea of Orthogonality.
§18.1. The Space C0?(G) and the Variational Lemma.
§18.2. Integration by Parts.
§18.3. The First Boundary Value Problem and the Ritz Method.
§18.4. The Second and Third Boundary Value Problems and the Ritz Method.
§18.5. Eigenvalue Problems and the Ritz Method.
§18.6. The Hölder Inequality and its Applications.
§18.7. The History of the Dirichlet Principle and Monotone Operators.
§18.8. The Main Theorem on Quadratic Minimum Problems.
§18.9. The Inequality of Poincaré
Friedrichs.
§18.10. The Functional Analytic Justification of the Dirichlet Principle.
§18.11. The Perpendicular Principle, the Riesz Theorem, and the Main Theorem on Linear Monotone Operators.
§18.12. The Extension Principle and the Completion Principle.
§18.13. Proper Subregions.
§18.14. The Smoothing Principle.
§18.15. The Idea of the Regularity of Generalized Solutions and the Lemma of Weyl.
§18.16. The Localization Principle.
§18.17. Convex Variational Problems, Elliptic Differential Equations, and Monotonicity.
§18.18. The General Euler
Lagrange Equations.
§18.19. The Historical Development of the 19th and 20th Problems of Hilbert and Monotone Operators.
§18.20. Sufficient Conditions for Local and Global Minima and Locally Monotone Operators.
19 The Galerkin Method for Differential and Integral Equations, the Friedrichs Extension, and the Idea of Self
Adjointness.
§19.1. Elliptic Differential Equations and the Galerkin Method.
§19.2. Parabolic Differential Equations and the Galerkin Method.
§19.3. Hyperbolic Differential Equations and the Galerkin Method.
§19.4. Integral Equations and the Galerkin Method.
§19.5. Complete Orthonormal Systems and Abstract Fourier Series.
§19.6. Eigenvalues of Compact Symmetric Operators (Hilbert
Schmidt Theory).
§19.7. Proof of Theorem 19.B.
§19.8. Self
Adjoint Operators.
§19.9. The Friedrichs Extension of Symmetric Operators.
§19.10. Proof of Theorem 19.C.
§19.11. Application to the Poisson Equation.
§19.12. Application to the Eigenvalue Problem for the Laplace Equation.
§19.13. The Inequality of Poincaré and the Compactness Theorem of Rellich.
§19.14. Functions of Self
Adjoint Operators.
§19.15. Application to the Heat Equation.
§19.16. Application to the Wave Equation.
§19.17. Semigroups and Propagators, and Their Physical Relevance.
§19.18. Main Theorem on Abstract Linear Parabolic Equations.
§19.19. Proof of Theorem 19.D.
§19.20. Monotone Operators and the Main Theorem on Linear Nonexpansive Semigroups.
§19.21. The Main Theorem on One
Parameter Unitary Groups.
§19.22. Proof of Theorem 19.E.
§19.23. Abstract Semilinear Hyperbolic Equations.
§19.24. Application to Semilinear Wave Equations.
§19.25. The Semilinear Schrödinger Equation.
§19.26. Abstract Semilinear Parabolic Equations, Fractional Powers of Operators, and Abstract Sobolev Spaces.
§19.27. Application to Semilinear Parabolic Equations.
§19.28. Proof of Theorem 19.I.
§19.29. Five General Uniqueness Principles and Monotone Operators.
§19.30. A General Existence Principle and Linear Monotone Operators.
20 Difference Methods and Stability.
§20.1. Consistency, Stability, and Convergence.
§20.2. Approximation of Differential Quotients.
§20.3. Application to Boundary Value Problems for Ordinary Differential Equations.
§20.4. Application to Parabolic Differential Equations.
§20.5. Application to Elliptic Differential Equations.
§20.6. The Equivalence Between Stability and Convergence.
§20.7. The Equivalence Theorem of Lax for Evolution Equations.
Linear Monotone Problems.
21 Auxiliary Tools and the Convergence of the Galerkin Method for Linear Operator Equations.
§21.1. Generalized Derivatives.
§21.2. Sobolev Spaces.
§21.3. The Sobolev Embedding Theorems.
§21.4. Proof of the Sobolev Embedding Theorems.
§21.5. Duality in B
Spaces.
§21.6. Duality in H
Spaces.
§21.7. The Idea of Weak Convergence.
§21.8. The Idea of Weak* Convergence.
§21.9. Linear Operators.
§21.10. Bilinear Forms.
§21.11. Application to Embeddings.
§21.12. Projection Operators.
§21.13. Bases and Galerkin Schemes.
§21.14. Application to Finite Elements.
§21.15. Riesz
Schauder Theory and Abstract Fredholm Alternatives.
§21.16. The Main Theorem on the Approximation
Solvability of Linear Operator Equations, and the Convergence of the Galerkin Method.
§21.17. Interpolation Inequalities and a Convergence Trick.
§21.18. Application to the Refined Banach Fixed
Point Theorem and the Convergence of Iteration Methods.
§21.19. The Gagliardo
Nirenberg Inequalities.
§21.20. The Strategy of the Fourier Transform for Sobolev Spaces.
§21.21. Banach Algebras and Sobolev Spaces.
§21.22. Moser
Type Calculus Inequalities.
§21.23. Weakly Sequentially Continuous Nonlinear Operators on Sobolev Spaces.
22 Hilbert Space Methods and Linear Elliptic Differential Equations.
§22.1. Main Theorem on Quadratic Minimum Problems and the Ritz Method.
§22.2. Application to Boundary Value Problems.
§22.3. The Method of Orthogonal Projection, Duality, and a posteriori Error Estimates for the Ritz Method.
§22.4. Application to Boundary Value Problems.
§22.5. Main Theorem on Linear Strongly Monotone Operators and the Galerkin Method.
§22.6. Application to Boundary Value Problems.
§22.7. Compact Perturbations of Strongly Monotone Operators, Fredholm Alternatives, and the Galerkin Method.
§22.8. Application to Integral Equations.
§22.9. Application to Bilinear Forms.
§22.10. Application to Boundary Value Problems.
§22.11. Eigenvalue Problems and the Ritz Method.
§22.12. Application to Bilinear Forms.
§22.13. Application to Boundary
Eigenvalue Problems.
§22.14. Gårding Forms.
§22.15. The Gårding Inequality for Elliptic Equations.
§22.16. The Main Theorems on Gårding Forms.
§22.17. Application to Strongly Elliptic Differential Equations of Order 2m.
§22.18. Difference Approximations.
§22.19. Interior Regularity of Generalized Solutions.
§22.20. Proof of Theorem 22.H.
§22.21. Regularity of Generalized Solutions up to the Boundary.
§22.22. Proof of Theorem 22.I.
23 Hilbert Space Methods and Linear Parabolic Differential Equations.
§23.1. Particularities in the Treatment of Parabolic Equations.
§23.2. The Lebesgue Space Lp(0, T; X) of Vector
Valued Functions.
§23.3. The Dual Space to Lp(0, T; X).
§23.4. Evolution Triples.
§23.5. Generalized Derivatives.
§23.6. The Sobolev Space WP1 (0, T; V, H).
§23.7. Main Theorem on First
Order Linear Evolution Equations and the Galerkin Method.
§23.8. Application to Parabolic Differential Equations.
§23.9. Proof of the Main Theorem.
24 Hilbert Space Methods and Linear Hyperbolic Differential Equations.
§24.1. Main Theorem on Second
Order Linear Evolution Equations and the Galerkin Method.
§24.2. Application to Hyperbolic Differential Equations.
§24.3. Proof of the Main Theorem.
to the Subject.
18 Variational Problems, the Ritz Method, and the Idea of Orthogonality.
§18.1. The Space C0?(G) and the Variational Lemma.
§18.2. Integration by Parts.
§18.3. The First Boundary Value Problem and the Ritz Method.
§18.4. The Second and Third Boundary Value Problems and the Ritz Method.
§18.5. Eigenvalue Problems and the Ritz Method.
§18.6. The Hölder Inequality and its Applications.
§18.7. The History of the Dirichlet Principle and Monotone Operators.
§18.8. The Main Theorem on Quadratic Minimum Problems.
§18.9. The Inequality of Poincaré
Friedrichs.
§18.10. The Functional Analytic Justification of the Dirichlet Principle.
§18.11. The Perpendicular Principle, the Riesz Theorem, and the Main Theorem on Linear Monotone Operators.
§18.12. The Extension Principle and the Completion Principle.
§18.13. Proper Subregions.
§18.14. The Smoothing Principle.
§18.15. The Idea of the Regularity of Generalized Solutions and the Lemma of Weyl.
§18.16. The Localization Principle.
§18.17. Convex Variational Problems, Elliptic Differential Equations, and Monotonicity.
§18.18. The General Euler
Lagrange Equations.
§18.19. The Historical Development of the 19th and 20th Problems of Hilbert and Monotone Operators.
§18.20. Sufficient Conditions for Local and Global Minima and Locally Monotone Operators.
19 The Galerkin Method for Differential and Integral Equations, the Friedrichs Extension, and the Idea of Self
Adjointness.
§19.1. Elliptic Differential Equations and the Galerkin Method.
§19.2. Parabolic Differential Equations and the Galerkin Method.
§19.3. Hyperbolic Differential Equations and the Galerkin Method.
§19.4. Integral Equations and the Galerkin Method.
§19.5. Complete Orthonormal Systems and Abstract Fourier Series.
§19.6. Eigenvalues of Compact Symmetric Operators (Hilbert
Schmidt Theory).
§19.7. Proof of Theorem 19.B.
§19.8. Self
Adjoint Operators.
§19.9. The Friedrichs Extension of Symmetric Operators.
§19.10. Proof of Theorem 19.C.
§19.11. Application to the Poisson Equation.
§19.12. Application to the Eigenvalue Problem for the Laplace Equation.
§19.13. The Inequality of Poincaré and the Compactness Theorem of Rellich.
§19.14. Functions of Self
Adjoint Operators.
§19.15. Application to the Heat Equation.
§19.16. Application to the Wave Equation.
§19.17. Semigroups and Propagators, and Their Physical Relevance.
§19.18. Main Theorem on Abstract Linear Parabolic Equations.
§19.19. Proof of Theorem 19.D.
§19.20. Monotone Operators and the Main Theorem on Linear Nonexpansive Semigroups.
§19.21. The Main Theorem on One
Parameter Unitary Groups.
§19.22. Proof of Theorem 19.E.
§19.23. Abstract Semilinear Hyperbolic Equations.
§19.24. Application to Semilinear Wave Equations.
§19.25. The Semilinear Schrödinger Equation.
§19.26. Abstract Semilinear Parabolic Equations, Fractional Powers of Operators, and Abstract Sobolev Spaces.
§19.27. Application to Semilinear Parabolic Equations.
§19.28. Proof of Theorem 19.I.
§19.29. Five General Uniqueness Principles and Monotone Operators.
§19.30. A General Existence Principle and Linear Monotone Operators.
20 Difference Methods and Stability.
§20.1. Consistency, Stability, and Convergence.
§20.2. Approximation of Differential Quotients.
§20.3. Application to Boundary Value Problems for Ordinary Differential Equations.
§20.4. Application to Parabolic Differential Equations.
§20.5. Application to Elliptic Differential Equations.
§20.6. The Equivalence Between Stability and Convergence.
§20.7. The Equivalence Theorem of Lax for Evolution Equations.
Linear Monotone Problems.
21 Auxiliary Tools and the Convergence of the Galerkin Method for Linear Operator Equations.
§21.1. Generalized Derivatives.
§21.2. Sobolev Spaces.
§21.3. The Sobolev Embedding Theorems.
§21.4. Proof of the Sobolev Embedding Theorems.
§21.5. Duality in B
Spaces.
§21.6. Duality in H
Spaces.
§21.7. The Idea of Weak Convergence.
§21.8. The Idea of Weak* Convergence.
§21.9. Linear Operators.
§21.10. Bilinear Forms.
§21.11. Application to Embeddings.
§21.12. Projection Operators.
§21.13. Bases and Galerkin Schemes.
§21.14. Application to Finite Elements.
§21.15. Riesz
Schauder Theory and Abstract Fredholm Alternatives.
§21.16. The Main Theorem on the Approximation
Solvability of Linear Operator Equations, and the Convergence of the Galerkin Method.
§21.17. Interpolation Inequalities and a Convergence Trick.
§21.18. Application to the Refined Banach Fixed
Point Theorem and the Convergence of Iteration Methods.
§21.19. The Gagliardo
Nirenberg Inequalities.
§21.20. The Strategy of the Fourier Transform for Sobolev Spaces.
§21.21. Banach Algebras and Sobolev Spaces.
§21.22. Moser
Type Calculus Inequalities.
§21.23. Weakly Sequentially Continuous Nonlinear Operators on Sobolev Spaces.
22 Hilbert Space Methods and Linear Elliptic Differential Equations.
§22.1. Main Theorem on Quadratic Minimum Problems and the Ritz Method.
§22.2. Application to Boundary Value Problems.
§22.3. The Method of Orthogonal Projection, Duality, and a posteriori Error Estimates for the Ritz Method.
§22.4. Application to Boundary Value Problems.
§22.5. Main Theorem on Linear Strongly Monotone Operators and the Galerkin Method.
§22.6. Application to Boundary Value Problems.
§22.7. Compact Perturbations of Strongly Monotone Operators, Fredholm Alternatives, and the Galerkin Method.
§22.8. Application to Integral Equations.
§22.9. Application to Bilinear Forms.
§22.10. Application to Boundary Value Problems.
§22.11. Eigenvalue Problems and the Ritz Method.
§22.12. Application to Bilinear Forms.
§22.13. Application to Boundary
Eigenvalue Problems.
§22.14. Gårding Forms.
§22.15. The Gårding Inequality for Elliptic Equations.
§22.16. The Main Theorems on Gårding Forms.
§22.17. Application to Strongly Elliptic Differential Equations of Order 2m.
§22.18. Difference Approximations.
§22.19. Interior Regularity of Generalized Solutions.
§22.20. Proof of Theorem 22.H.
§22.21. Regularity of Generalized Solutions up to the Boundary.
§22.22. Proof of Theorem 22.I.
23 Hilbert Space Methods and Linear Parabolic Differential Equations.
§23.1. Particularities in the Treatment of Parabolic Equations.
§23.2. The Lebesgue Space Lp(0, T; X) of Vector
Valued Functions.
§23.3. The Dual Space to Lp(0, T; X).
§23.4. Evolution Triples.
§23.5. Generalized Derivatives.
§23.6. The Sobolev Space WP1 (0, T; V, H).
§23.7. Main Theorem on First
Order Linear Evolution Equations and the Galerkin Method.
§23.8. Application to Parabolic Differential Equations.
§23.9. Proof of the Main Theorem.
24 Hilbert Space Methods and Linear Hyperbolic Differential Equations.
§24.1. Main Theorem on Second
Order Linear Evolution Equations and the Galerkin Method.
§24.2. Application to Hyperbolic Differential Equations.
§24.3. Proof of the Main Theorem.
18 Variational Problems, the Ritz Method, and the Idea of Orthogonality.
§18.1. The Space C0?(G) and the Variational Lemma.
§18.2. Integration by Parts.
§18.3. The First Boundary Value Problem and the Ritz Method.
§18.4. The Second and Third Boundary Value Problems and the Ritz Method.
§18.5. Eigenvalue Problems and the Ritz Method.
§18.6. The Hölder Inequality and its Applications.
§18.7. The History of the Dirichlet Principle and Monotone Operators.
§18.8. The Main Theorem on Quadratic Minimum Problems.
§18.9. The Inequality of Poincaré
Friedrichs.
§18.10. The Functional Analytic Justification of the Dirichlet Principle.
§18.11. The Perpendicular Principle, the Riesz Theorem, and the Main Theorem on Linear Monotone Operators.
§18.12. The Extension Principle and the Completion Principle.
§18.13. Proper Subregions.
§18.14. The Smoothing Principle.
§18.15. The Idea of the Regularity of Generalized Solutions and the Lemma of Weyl.
§18.16. The Localization Principle.
§18.17. Convex Variational Problems, Elliptic Differential Equations, and Monotonicity.
§18.18. The General Euler
Lagrange Equations.
§18.19. The Historical Development of the 19th and 20th Problems of Hilbert and Monotone Operators.
§18.20. Sufficient Conditions for Local and Global Minima and Locally Monotone Operators.
19 The Galerkin Method for Differential and Integral Equations, the Friedrichs Extension, and the Idea of Self
Adjointness.
§19.1. Elliptic Differential Equations and the Galerkin Method.
§19.2. Parabolic Differential Equations and the Galerkin Method.
§19.3. Hyperbolic Differential Equations and the Galerkin Method.
§19.4. Integral Equations and the Galerkin Method.
§19.5. Complete Orthonormal Systems and Abstract Fourier Series.
§19.6. Eigenvalues of Compact Symmetric Operators (Hilbert
Schmidt Theory).
§19.7. Proof of Theorem 19.B.
§19.8. Self
Adjoint Operators.
§19.9. The Friedrichs Extension of Symmetric Operators.
§19.10. Proof of Theorem 19.C.
§19.11. Application to the Poisson Equation.
§19.12. Application to the Eigenvalue Problem for the Laplace Equation.
§19.13. The Inequality of Poincaré and the Compactness Theorem of Rellich.
§19.14. Functions of Self
Adjoint Operators.
§19.15. Application to the Heat Equation.
§19.16. Application to the Wave Equation.
§19.17. Semigroups and Propagators, and Their Physical Relevance.
§19.18. Main Theorem on Abstract Linear Parabolic Equations.
§19.19. Proof of Theorem 19.D.
§19.20. Monotone Operators and the Main Theorem on Linear Nonexpansive Semigroups.
§19.21. The Main Theorem on One
Parameter Unitary Groups.
§19.22. Proof of Theorem 19.E.
§19.23. Abstract Semilinear Hyperbolic Equations.
§19.24. Application to Semilinear Wave Equations.
§19.25. The Semilinear Schrödinger Equation.
§19.26. Abstract Semilinear Parabolic Equations, Fractional Powers of Operators, and Abstract Sobolev Spaces.
§19.27. Application to Semilinear Parabolic Equations.
§19.28. Proof of Theorem 19.I.
§19.29. Five General Uniqueness Principles and Monotone Operators.
§19.30. A General Existence Principle and Linear Monotone Operators.
20 Difference Methods and Stability.
§20.1. Consistency, Stability, and Convergence.
§20.2. Approximation of Differential Quotients.
§20.3. Application to Boundary Value Problems for Ordinary Differential Equations.
§20.4. Application to Parabolic Differential Equations.
§20.5. Application to Elliptic Differential Equations.
§20.6. The Equivalence Between Stability and Convergence.
§20.7. The Equivalence Theorem of Lax for Evolution Equations.
Linear Monotone Problems.
21 Auxiliary Tools and the Convergence of the Galerkin Method for Linear Operator Equations.
§21.1. Generalized Derivatives.
§21.2. Sobolev Spaces.
§21.3. The Sobolev Embedding Theorems.
§21.4. Proof of the Sobolev Embedding Theorems.
§21.5. Duality in B
Spaces.
§21.6. Duality in H
Spaces.
§21.7. The Idea of Weak Convergence.
§21.8. The Idea of Weak* Convergence.
§21.9. Linear Operators.
§21.10. Bilinear Forms.
§21.11. Application to Embeddings.
§21.12. Projection Operators.
§21.13. Bases and Galerkin Schemes.
§21.14. Application to Finite Elements.
§21.15. Riesz
Schauder Theory and Abstract Fredholm Alternatives.
§21.16. The Main Theorem on the Approximation
Solvability of Linear Operator Equations, and the Convergence of the Galerkin Method.
§21.17. Interpolation Inequalities and a Convergence Trick.
§21.18. Application to the Refined Banach Fixed
Point Theorem and the Convergence of Iteration Methods.
§21.19. The Gagliardo
Nirenberg Inequalities.
§21.20. The Strategy of the Fourier Transform for Sobolev Spaces.
§21.21. Banach Algebras and Sobolev Spaces.
§21.22. Moser
Type Calculus Inequalities.
§21.23. Weakly Sequentially Continuous Nonlinear Operators on Sobolev Spaces.
22 Hilbert Space Methods and Linear Elliptic Differential Equations.
§22.1. Main Theorem on Quadratic Minimum Problems and the Ritz Method.
§22.2. Application to Boundary Value Problems.
§22.3. The Method of Orthogonal Projection, Duality, and a posteriori Error Estimates for the Ritz Method.
§22.4. Application to Boundary Value Problems.
§22.5. Main Theorem on Linear Strongly Monotone Operators and the Galerkin Method.
§22.6. Application to Boundary Value Problems.
§22.7. Compact Perturbations of Strongly Monotone Operators, Fredholm Alternatives, and the Galerkin Method.
§22.8. Application to Integral Equations.
§22.9. Application to Bilinear Forms.
§22.10. Application to Boundary Value Problems.
§22.11. Eigenvalue Problems and the Ritz Method.
§22.12. Application to Bilinear Forms.
§22.13. Application to Boundary
Eigenvalue Problems.
§22.14. Gårding Forms.
§22.15. The Gårding Inequality for Elliptic Equations.
§22.16. The Main Theorems on Gårding Forms.
§22.17. Application to Strongly Elliptic Differential Equations of Order 2m.
§22.18. Difference Approximations.
§22.19. Interior Regularity of Generalized Solutions.
§22.20. Proof of Theorem 22.H.
§22.21. Regularity of Generalized Solutions up to the Boundary.
§22.22. Proof of Theorem 22.I.
23 Hilbert Space Methods and Linear Parabolic Differential Equations.
§23.1. Particularities in the Treatment of Parabolic Equations.
§23.2. The Lebesgue Space Lp(0, T; X) of Vector
Valued Functions.
§23.3. The Dual Space to Lp(0, T; X).
§23.4. Evolution Triples.
§23.5. Generalized Derivatives.
§23.6. The Sobolev Space WP1 (0, T; V, H).
§23.7. Main Theorem on First
Order Linear Evolution Equations and the Galerkin Method.
§23.8. Application to Parabolic Differential Equations.
§23.9. Proof of the Main Theorem.
24 Hilbert Space Methods and Linear Hyperbolic Differential Equations.
§24.1. Main Theorem on Second
Order Linear Evolution Equations and the Galerkin Method.
§24.2. Application to Hyperbolic Differential Equations.
§24.3. Proof of the Main Theorem.