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Continuous and Distributed Systems II

✍ Scribed by Sadovnichiy V.A., Zgurovsky M.Z (ed.)

Publisher
Springer
Year
2015
Tongue
English
Leaves
395
Category
Library
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✦ Table of Contents

Preface......Page 7
Editors......Page 8
Acknowledgments......Page 9
Contents......Page 10
Contributors......Page 18
Part I Applied Methods of Modern Algebraand Analysis......Page 21
1.1 Introduction......Page 22
1.2 Main Results......Page 24
1.3 Proofs......Page 25
References......Page 29
2.1 Atoms'' and Morse Functions......Page 30<br> 2.2 Complicated Atoms and Molecules......Page 34<br> 2.3 Topology of Integrable Hamiltonian Systems with Two Degrees of Freedom......Page 35<br> 2.4 Geodesic Flows with Potential on the Surfaces of Revolution......Page 39<br> 2.5 The Case of Gravitational Potential: Topological Classification......Page 40<br> 2.6 Topological Equivalence Between Different Integrable Systems......Page 43<br> References......Page 45<br> 3.1 Additive Problems......Page 47<br> 3.2 Multiplicative Problems......Page 51<br> References......Page 54<br>4 Critical Analysis of Amino Acids and Polypeptides Geometry......Page 55<br> 4.2 Protein Data Bank......Page 56<br> 4.2.1 Extracting Information from PDB......Page 57<br> 4.2.2 The First Steps in Polypeptides Visualization......Page 58<br> 4.2.3 Some Difficulties in PDB-Files Treatment......Page 61<br> 4.3.1 Estimation of Spread in Lengths of Covalent Bonds in Amino Acids......Page 66<br> 4.3.2 Spread Estimation of Distances Between Consecutive Alpha Carbons (Beginning)......Page 71<br> 4.3.3 Spread Estimation of the Lengths of Peptide Bonds......Page 72<br> 4.3.4 Pauling Plane Law......Page 73<br> 4.3.5 Spread Estimation of Distances Between Consecutive Alpha Carbons (End)......Page 78<br> 4.3.6 Spread Estimation of Angles Between Covalent Bonds in Polypeptides......Page 79<br> 4.4 Amino Acids' Mobility......Page 80<br> 4.4.1 Orientation of Amino Acids......Page 82<br> 4.5 Addendum (in collaboration with E.A. Vilkul)......Page 84<br> 4.5.1 The Number of Models' Distribution......Page 85<br> 4.5.2Representativity'' of the First Model from the Pathologies Point of View......Page 87
4.5.3 Representativity'' of the First Model from the Plane Law Point of View......Page 89<br> 4.6 Geometry of Planar and Space Polygonal Lines: Spirals Detecting......Page 92<br> 4.7 Torsion and Curvature of Space Curves......Page 97<br> References......Page 99<br> 5.1 Setting up the Problem......Page 100<br> 5.2.1 Critical Manifold Σ+ : Condition of Jordanity......Page 101<br> 5.3.1 Stabilization Conditions: The Choice of Parameters of Problem......Page 102<br> 5.3.3 The ODE System for Two-Front Solution......Page 103<br> 5.3.5 Lax's Condition : One-Front Solution......Page 104<br> 5.3.6 Lax's Condition for Two-Front Solution: Condition of Monotonicity......Page 105<br> 5.4.1 The Existence of One-Front Solution then Moving in the Noncritical Eigenvector Direction......Page 106<br> 5.4.2 One-Front Solution as the Traveling Wave for ω=λ+|q=0......Page 107<br> 5.5 The Existence of Two-Front Solutions as ω=λ+|q=0......Page 108<br> 5.5.1 Different Forms of Two-Front Solutions......Page 111<br> 5.5.3 The Conditions for Two-Front Solutions of Humped Kink Type in the ω Terms......Page 112<br> 5.6 Bifurcation of Rarefaction Waves on the Critical Manifold Σ+......Page 113<br> 5.6.2 The Proof of the Existence of rs-Type Solution......Page 114<br> References......Page 115<br>Part II Non-autonomous and StochasticDynamical Systems......Page 117<br>6 Dynamics of Nonautonomous Chemostat Models......Page 118<br> 6.1 Introduction......Page 119<br> 6.2 Preliminaries on Nonautonomous Dynamical Systems......Page 120<br> 6.3 Properties of Solutions......Page 122<br> 6.4.1 Chemostats with Wall Growth, Variable Delays, and Fixed Inputs......Page 125<br> 6.4.2 Chemostat with Wall Growth, Variable Inputs, and No Delays......Page 126<br> 6.4.3 Chemostat with No Wall Growth or Delays......Page 130<br> 6.5 Random Chemostat Models......Page 131<br> 6.6 Overyield in Nonautonomous Chemostats......Page 132<br> References......Page 134<br> 7.1 Introduction......Page 136<br> 7.2 Preliminaries on Random Dynamical Systems......Page 137<br> 7.3.1 Mathematical Settings......Page 140<br> 7.3.2 Selected Results for First-Order SLDEs......Page 142<br> 7.3.3 A Brief on Second-Order SLDEs......Page 146<br> 7.3.4 Mathematical Setting......Page 147<br> 7.3.5 Existence of Random Attractors......Page 148<br> 7.4 Closing Remarks......Page 149<br> References......Page 150<br> 8.1 Introduction......Page 152<br> 8.2 Setting of the Problem......Page 154<br> 8.3 A Priori Estimates......Page 156<br> 8.4 The Continuous Semigroup......Page 159<br> References......Page 162<br> 9.1 Introduction......Page 164<br> 9.2 Abstract Theory of Pullback calD-Attractors for Multivalued Processes......Page 165<br> 9.3 Application......Page 171<br> References......Page 180<br> 10.1 Introduction......Page 182<br> 10.2 The Construction of (ωotimesSω) for a Fractional Brownian motion......Page 186<br> 10.3 The Construction of (ωotimesSω) for a Brownian motion......Page 191<br> 10.4 Additional Properties of (ωotimesSω)......Page 200<br> References......Page 202<br> 11.1 Introduction......Page 204<br> 11.2 Notation......Page 205<br> 11.3 Existence of Random Inertial Manifolds......Page 207<br> 11.4 Periodicity and Almost Periodicity of Inertial Manifolds......Page 221<br> References......Page 223<br> 12.1 Introduction......Page 224<br> 12.2 Notations, Definitions, and Some Properties on the Multivalued Process......Page 225<br> 12.3 Pullback Attraction and Properties on ω-limit Sets......Page 228<br> References......Page 233<br> 13.1 Introduction and Setting of the Problem......Page 235<br> 13.2 Preliminary Properties of Weak Solutions......Page 238<br> 13.3 Uniform Trajectory Attractor and Main Result......Page 240<br> 13.4 Proof of Theorem 13.1......Page 242<br> References......Page 245<br> 14.1 Introduction and Regularity of All Weak Solutions......Page 247<br> 14.2 A Lyapunov Type Function and Strongest Convergence Results for All Weak Solutions......Page 249<br> 14.3 Structure Properties and Regularity of Global and Trajectory Attractors......Page 252<br> 14.4 Faedo--Galerkin Approximation for the Global and Trajectory Attractors......Page 253<br> 14.5 Applications......Page 254<br> References......Page 255<br>Part III Optimization, Control and DecisionSciences for Continuum MechanicsProblems......Page 258<br>15 Robust Stability, Minimax Stabilization and Maximin Testing in Problems of Semi-Automatic Control......Page 259<br> 15.2 Robust Stability of Linear Systems......Page 260<br> 15.3 Minimax Stabilization and Antagonistic Game......Page 267<br> 15.4 Maximin Testing of Quality of Control Algorithm......Page 272<br> 15.4.1 Program Strategy of Testing......Page 273<br> 15.4.2 Closed-Loop Strategy of Testing......Page 274<br> 15.5 Conclusions......Page 276<br> References......Page 277<br>16 Dynamics of Solutions for Controlled Piezoelectric Fields with MultivaluedReaction-Displacement'' Law......Page 278
16.1 Introduction and the Main Problem......Page 279
16.2 Setting of the Problem and the Main Results......Page 280
References......Page 286
17.1 Introduction......Page 288
17.2.1 Problem Statement......Page 289
17.2.2 Formal Solution of the Problem......Page 290
17.3.1 Problem Statement......Page 299
17.3.2 Formal Solution of the Problem......Page 300
References......Page 307
18.1 Introduction......Page 308
18.2 Setting of the Problem......Page 309
18.3 Some Facts from the Theory of Fourier-Bessel Series......Page 311
18.4 Existence of Classical Solution of the Problem (??) with Fixed Control......Page 314
18.5 The Optimal Control Problem (??) and (??)......Page 322
References......Page 325
19.1 Introduction......Page 326
19.2 Notation and Preliminaries......Page 328
19.3 mathbbSN-Valued Radon Measures and Weak Convergence in Variable Lp-Spaces......Page 331
19.4 Auxiliary Results......Page 338
19.5 Setting of the Optimal Control Problem......Page 341
19.6 Existence of Weak Optimal Solutions......Page 344
References......Page 347
Part IV Fundamental and ComputationalMechanics......Page 349
20.1 Postulates of Continuum Mechanics......Page 350
20.2 Ideal Liquid and Gas......Page 351
20.3 Newtonian Viscous Fluid......Page 354
20.4 Linear Anisotropic Elastic Solid......Page 356
References......Page 361
21.1 Introduction......Page 362
21.2 Mathematical Formulation of the Problem......Page 364
21.3 Standing Vortex Within the Groove in the Stationary Flow......Page 367
21.4 Standing Vortex in the Groove in Periodically Perturbed Flow......Page 372
21.5 Summary......Page 375
References......Page 376
22.1 Introduction......Page 377
22.2 Problem Statement......Page 379
22.3.1 General Principles......Page 381
22.3.2 Free-Surface Modeling......Page 382
22.3.3 The Vortex Method for 2-D Flows......Page 386
22.4 Results and Disscussion......Page 387
22.5 Conclusions......Page 393
References......Page 394

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