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This book represents the outcome of the cross-fertilization of nonlinear functional analysis and mathematical modelling, demonstrating its application to solid and contact mechanics. This book illustrates the use of various functional methods in the study of various nonlinear problems in analysis and mechanics.
This book represents the outcome of the cross-fertilization of nonlinear functional analysis and mathematical modelling, demonstrating its application to solid and contact mechanics. This book illustrates the use of various functional methods in the study of various nonlinear problems in analysis and mechanics.
Hinweis: Dieser Artikel kann nur an eine deutsche Lieferadresse ausgeliefert werden.
Hinweis: Dieser Artikel kann nur an eine deutsche Lieferadresse ausgeliefert werden.
Produktdetails
- Produktdetails
- Verlag: CRC Press
- 2nd edition
- Seitenzahl: 340
- Erscheinungstermin: 10. Dezember 2024
- Englisch
- Abmessung: 254mm x 178mm x 21mm
- Gewicht: 821g
- ISBN-13: 9781032587165
- ISBN-10: 1032587164
- Artikelnr.: 71301702
- Herstellerkennzeichnung
- Libri GmbH
- Europaallee 1
- 36244 Bad Hersfeld
- 06621 890
- Verlag: CRC Press
- 2nd edition
- Seitenzahl: 340
- Erscheinungstermin: 10. Dezember 2024
- Englisch
- Abmessung: 254mm x 178mm x 21mm
- Gewicht: 821g
- ISBN-13: 9781032587165
- ISBN-10: 1032587164
- Artikelnr.: 71301702
- Herstellerkennzeichnung
- Libri GmbH
- Europaallee 1
- 36244 Bad Hersfeld
- 06621 890
Mircea Sofonea earned his PhD from the University of Bucarest, Romania, and his habilitation at the Université Blaise Pascal of Clermont-Ferrand (France).He is currently a Distinguished Profesor of Applied Mathematics at the University of Perpignan Via Domitia, France and a honorary member of the Institute of Mathematics, Romanian Academy of Sciences. His areas of interest and expertise include multivalued operators, variational and hemivariational inequalities, solid mechanics, contact mechanics and numerical methods for partial differential equations. Most of his reseach is dedicated to the Mathematical Theory of Contact Mechanics, of which he is one of the main contributors. His ideas and results were published in nine books, four monographs, and more than three hundred research articles. Stanislaw Migórski earned his PhD degree and the habilitation from the Jagiellonian University in Krakow, Poland. He is currently a Full Honorary Professor and Chair of Optimization and Control Theory at Jagiellonian University in Krakow. His areas of interest and expertise include mathematical analysis, differential equations, mathematical modelling, methods and technics of nonlinear analysis, homogenization, control theory, computational methods and pplications of partial differential equations to mechanics. His research results are internationally recognized and were published in six books, four monographs, and more than two hundred research articles.
I. Variational Problems in Solid Mechanics. 1. Elliptic Variational
Inequalities. 1.1. Background on functional analysis. 1.2. Existence and
uniqueness results. 1.3. Convergence results. 1.4. Optimal control. 1.5.
Well-posedness results. 2. History-Dependent Operators. 2.1. Spaces of
continuous functions. 2.2. Definitions and basic properties. 2.3. Fixed
point properties. 2.4. History-dependent equations in Hilbert spaces. 2.5.
Nonlinear implicit equations in Banach spaces. 2.6. History-dependent
variational inequalities. 2.7. Relevant particular cases. 3.
Displacement-Traction Problems in Solid Mechanics. 3.1. Modeling of
displacement-traction problems. 3.2. A displacement-traction problem with
locking materials. 3.3. One-dimensional elastic examples. 3.4. Two
viscoelastic problems. 3.5. One-dimensional examples. 3.6. A viscoplastic
problem. II. Variational-Hemivariational Inequalities. 4. Elements of
Nonsmooth Analysis. 4.1. Monotone and pseudomonotone operators. 4.2.
Bochner-Lebesgue spaces. 4.3. Subgradient of convex functions. 4.4.
Subgradient in the sense of Clarke. 4.5. Mixed equilibrium problem. 4.6.
Miscellaneous results. 5. Elliptic Variational-Hemivariational
Inequalities. 5.1. An existence and uniqueness result. 5.2. Convergence
results. 5.3. Optimal control. 5.4. Penalty methods. 5.5. Well-posedness
results. 5.6. Relevant particular cases. 6. History-Dependent
Variational-Hemivariational Inequalities. 6.1. An existence and uniqueness
result. 6.2. Convergence results. 6.3. Optimal control. 6.4. A penalty
method. 6.5. A well-posedness result. 6.6. Relevant particular cases. 7.
Evolutionary Variational-Hemivariational Inequalities. 7.1. A class of
inclusions with history-dependent operators. 7.2. History-dependent
inequalities with unilateral constraints. 7.3. Constrainted differential
variational-hemivariational inequalities. 7.4. Relevant particular cases.
III. Applications to Contact Mechanics. 8. Static Contact Problems. 8.1.
Modeling of static contact problems. 8.2. A contact problem with normal
compliance. 8.3. A contact problem with unilateral constraints. 8.4.
Convergence and optimal control results. 8.5. A contact problem for locking
materials. 8.6. Convergence and optimal control results. 8.7. Penalty
methods. 9. Time-Dependent and Quasistatic Contact Problems. 9.1. Physical
setting and mathematical models. 9.2. Two time-dependent elastic contact
problems. 9.3. A quasistatic viscoplastic contact problem. 9.4. A
time-dependent viscoelastic contact problem. 9.5. Convergence and optimal
control results. 9.6. A frictional viscoelastic contact problem. 9.7. A
quasistatic contact problem with locking materials. 10. Dynamic Contact
Problems. 10.1. Mathematical models of dynamic contact. 10.2. A
viscoelastic contact problem with normal damped response. 10.3. A
unilateral viscoelastic frictional contact problem. 10.4. A unilateral
viscoplastic frictionless contact problem.
Inequalities. 1.1. Background on functional analysis. 1.2. Existence and
uniqueness results. 1.3. Convergence results. 1.4. Optimal control. 1.5.
Well-posedness results. 2. History-Dependent Operators. 2.1. Spaces of
continuous functions. 2.2. Definitions and basic properties. 2.3. Fixed
point properties. 2.4. History-dependent equations in Hilbert spaces. 2.5.
Nonlinear implicit equations in Banach spaces. 2.6. History-dependent
variational inequalities. 2.7. Relevant particular cases. 3.
Displacement-Traction Problems in Solid Mechanics. 3.1. Modeling of
displacement-traction problems. 3.2. A displacement-traction problem with
locking materials. 3.3. One-dimensional elastic examples. 3.4. Two
viscoelastic problems. 3.5. One-dimensional examples. 3.6. A viscoplastic
problem. II. Variational-Hemivariational Inequalities. 4. Elements of
Nonsmooth Analysis. 4.1. Monotone and pseudomonotone operators. 4.2.
Bochner-Lebesgue spaces. 4.3. Subgradient of convex functions. 4.4.
Subgradient in the sense of Clarke. 4.5. Mixed equilibrium problem. 4.6.
Miscellaneous results. 5. Elliptic Variational-Hemivariational
Inequalities. 5.1. An existence and uniqueness result. 5.2. Convergence
results. 5.3. Optimal control. 5.4. Penalty methods. 5.5. Well-posedness
results. 5.6. Relevant particular cases. 6. History-Dependent
Variational-Hemivariational Inequalities. 6.1. An existence and uniqueness
result. 6.2. Convergence results. 6.3. Optimal control. 6.4. A penalty
method. 6.5. A well-posedness result. 6.6. Relevant particular cases. 7.
Evolutionary Variational-Hemivariational Inequalities. 7.1. A class of
inclusions with history-dependent operators. 7.2. History-dependent
inequalities with unilateral constraints. 7.3. Constrainted differential
variational-hemivariational inequalities. 7.4. Relevant particular cases.
III. Applications to Contact Mechanics. 8. Static Contact Problems. 8.1.
Modeling of static contact problems. 8.2. A contact problem with normal
compliance. 8.3. A contact problem with unilateral constraints. 8.4.
Convergence and optimal control results. 8.5. A contact problem for locking
materials. 8.6. Convergence and optimal control results. 8.7. Penalty
methods. 9. Time-Dependent and Quasistatic Contact Problems. 9.1. Physical
setting and mathematical models. 9.2. Two time-dependent elastic contact
problems. 9.3. A quasistatic viscoplastic contact problem. 9.4. A
time-dependent viscoelastic contact problem. 9.5. Convergence and optimal
control results. 9.6. A frictional viscoelastic contact problem. 9.7. A
quasistatic contact problem with locking materials. 10. Dynamic Contact
Problems. 10.1. Mathematical models of dynamic contact. 10.2. A
viscoelastic contact problem with normal damped response. 10.3. A
unilateral viscoelastic frictional contact problem. 10.4. A unilateral
viscoplastic frictionless contact problem.
I. Variational Problems in Solid Mechanics. 1. Elliptic Variational
Inequalities. 1.1. Background on functional analysis. 1.2. Existence and
uniqueness results. 1.3. Convergence results. 1.4. Optimal control. 1.5.
Well-posedness results. 2. History-Dependent Operators. 2.1. Spaces of
continuous functions. 2.2. Definitions and basic properties. 2.3. Fixed
point properties. 2.4. History-dependent equations in Hilbert spaces. 2.5.
Nonlinear implicit equations in Banach spaces. 2.6. History-dependent
variational inequalities. 2.7. Relevant particular cases. 3.
Displacement-Traction Problems in Solid Mechanics. 3.1. Modeling of
displacement-traction problems. 3.2. A displacement-traction problem with
locking materials. 3.3. One-dimensional elastic examples. 3.4. Two
viscoelastic problems. 3.5. One-dimensional examples. 3.6. A viscoplastic
problem. II. Variational-Hemivariational Inequalities. 4. Elements of
Nonsmooth Analysis. 4.1. Monotone and pseudomonotone operators. 4.2.
Bochner-Lebesgue spaces. 4.3. Subgradient of convex functions. 4.4.
Subgradient in the sense of Clarke. 4.5. Mixed equilibrium problem. 4.6.
Miscellaneous results. 5. Elliptic Variational-Hemivariational
Inequalities. 5.1. An existence and uniqueness result. 5.2. Convergence
results. 5.3. Optimal control. 5.4. Penalty methods. 5.5. Well-posedness
results. 5.6. Relevant particular cases. 6. History-Dependent
Variational-Hemivariational Inequalities. 6.1. An existence and uniqueness
result. 6.2. Convergence results. 6.3. Optimal control. 6.4. A penalty
method. 6.5. A well-posedness result. 6.6. Relevant particular cases. 7.
Evolutionary Variational-Hemivariational Inequalities. 7.1. A class of
inclusions with history-dependent operators. 7.2. History-dependent
inequalities with unilateral constraints. 7.3. Constrainted differential
variational-hemivariational inequalities. 7.4. Relevant particular cases.
III. Applications to Contact Mechanics. 8. Static Contact Problems. 8.1.
Modeling of static contact problems. 8.2. A contact problem with normal
compliance. 8.3. A contact problem with unilateral constraints. 8.4.
Convergence and optimal control results. 8.5. A contact problem for locking
materials. 8.6. Convergence and optimal control results. 8.7. Penalty
methods. 9. Time-Dependent and Quasistatic Contact Problems. 9.1. Physical
setting and mathematical models. 9.2. Two time-dependent elastic contact
problems. 9.3. A quasistatic viscoplastic contact problem. 9.4. A
time-dependent viscoelastic contact problem. 9.5. Convergence and optimal
control results. 9.6. A frictional viscoelastic contact problem. 9.7. A
quasistatic contact problem with locking materials. 10. Dynamic Contact
Problems. 10.1. Mathematical models of dynamic contact. 10.2. A
viscoelastic contact problem with normal damped response. 10.3. A
unilateral viscoelastic frictional contact problem. 10.4. A unilateral
viscoplastic frictionless contact problem.
Inequalities. 1.1. Background on functional analysis. 1.2. Existence and
uniqueness results. 1.3. Convergence results. 1.4. Optimal control. 1.5.
Well-posedness results. 2. History-Dependent Operators. 2.1. Spaces of
continuous functions. 2.2. Definitions and basic properties. 2.3. Fixed
point properties. 2.4. History-dependent equations in Hilbert spaces. 2.5.
Nonlinear implicit equations in Banach spaces. 2.6. History-dependent
variational inequalities. 2.7. Relevant particular cases. 3.
Displacement-Traction Problems in Solid Mechanics. 3.1. Modeling of
displacement-traction problems. 3.2. A displacement-traction problem with
locking materials. 3.3. One-dimensional elastic examples. 3.4. Two
viscoelastic problems. 3.5. One-dimensional examples. 3.6. A viscoplastic
problem. II. Variational-Hemivariational Inequalities. 4. Elements of
Nonsmooth Analysis. 4.1. Monotone and pseudomonotone operators. 4.2.
Bochner-Lebesgue spaces. 4.3. Subgradient of convex functions. 4.4.
Subgradient in the sense of Clarke. 4.5. Mixed equilibrium problem. 4.6.
Miscellaneous results. 5. Elliptic Variational-Hemivariational
Inequalities. 5.1. An existence and uniqueness result. 5.2. Convergence
results. 5.3. Optimal control. 5.4. Penalty methods. 5.5. Well-posedness
results. 5.6. Relevant particular cases. 6. History-Dependent
Variational-Hemivariational Inequalities. 6.1. An existence and uniqueness
result. 6.2. Convergence results. 6.3. Optimal control. 6.4. A penalty
method. 6.5. A well-posedness result. 6.6. Relevant particular cases. 7.
Evolutionary Variational-Hemivariational Inequalities. 7.1. A class of
inclusions with history-dependent operators. 7.2. History-dependent
inequalities with unilateral constraints. 7.3. Constrainted differential
variational-hemivariational inequalities. 7.4. Relevant particular cases.
III. Applications to Contact Mechanics. 8. Static Contact Problems. 8.1.
Modeling of static contact problems. 8.2. A contact problem with normal
compliance. 8.3. A contact problem with unilateral constraints. 8.4.
Convergence and optimal control results. 8.5. A contact problem for locking
materials. 8.6. Convergence and optimal control results. 8.7. Penalty
methods. 9. Time-Dependent and Quasistatic Contact Problems. 9.1. Physical
setting and mathematical models. 9.2. Two time-dependent elastic contact
problems. 9.3. A quasistatic viscoplastic contact problem. 9.4. A
time-dependent viscoelastic contact problem. 9.5. Convergence and optimal
control results. 9.6. A frictional viscoelastic contact problem. 9.7. A
quasistatic contact problem with locking materials. 10. Dynamic Contact
Problems. 10.1. Mathematical models of dynamic contact. 10.2. A
viscoelastic contact problem with normal damped response. 10.3. A
unilateral viscoelastic frictional contact problem. 10.4. A unilateral
viscoplastic frictionless contact problem.