Delay Differential Equations and Applications NATO Science Series ASeries presenting the results of scientific meetings supported under the NATO Science Programme. The Series is published by IOS Press, Amsterdam, and Springer in conjunction with the NATO Public Diplomacy Division Sub-Series I. Life and Behavioural Sciences IOS Press II. Mathematics, Physics and Chemistry Springer III.Computer and Systems Science IOS Press IV.Earth and Environmental Sciences Springer The NATO Science Series continues the series of books published formerly as the NATO ASI Series. The NATO Science Programme offers support for collaboration in civil science between scientists of countries of the Euro-Atlantic Partnership Council. The types of scientific meeting generally supported are “Advanced Study Institutes” and “Advanced Research Workshops”, and the NATO Science Series collects together the results of these meetings. The meetings are co-organized bij scientists from NATO countries and scientists from NATO’s Partner countries – countries of the CIS and Central and Eastern Europe. Advanced Study Institutes are high-level tutorial courses offering in-depth study of latest advances in a field. Advanced Research Workshops are expert meetings aimed at critical assessment of a field, and identification of directions for future action. As a consequence of the restructuring of the NATO Science Programme in 1999, the NATO Science Series was re-organised to the four sub-series noted above. Please consult the following web sites for information on previous volumes published in the Series. http://www.nato.int/science http://www.springer.com http://www.iospress.nl Series II:Mathematics,Physics and Chemistry – Vol.205 Delay Differential Equations and Applications edited by O.Arino University of Pau, France M.L.Hbid University Cadi Ayyad, Marrakech, Morocco and E.Ait Dads University Cadi Ayyad, Marrakech, Morocco Published in cooperation with NATO Public Diplomacy Division Proceedings of the NATO Advanced Study Institute on Delay Differential Equations and Applications Marrakech, Morocco 9–21 September 2002 A C.I.P.Catalogue record for this book is available from the Library of Congress. ISBN-10 1-4020-3646-9 (PB) ISBN-13 978-1-4020-3646-0 (PB) ISBN-10 1-4020-3645-0 (HB) ISBN-13 978-1-4020-3645-3 (HB) ISBN-10 1-4020-3647-7 (e-book) ISBN-13 978-1-4020-3647-7 (e-book) Published by Springer, P.O.Box 17, 3300 AADordrecht, The Netherlands. www.springer.com Printed on acid-free paper All Rights Reserved © 2006 Springer No part of this work may be reproduced, stored in a retrieval system, or transmitted in any form or by any means, electronic, mechanical, photocopying, microfilming, recording or otherwise, without written permission from the Publisher, with the exception of any material supplied specifically for the purpose of being entered and executed on a computer system, for exclusive use by the purchaser of the work. Contents List of Figures xiii Preface xvii Contributing Authors xxi Introduction xxiii M. L. Hbid 1 History Of Delay Equations 1 J.K. Hale 1 Stability of equilibria and Lyapunov functions 3 2 Invariant Sets, Omega-limits and Lyapunov functionals. 7 3 Delays may cause instability. 10 4 Linear autonomous equations and perturbations. 12 5 Neutral Functional Differential Equations 16 6 Periodically forced systems and discrete dynamical systems. 20 7 Dissipation, maximal compact invariant sets and attractors. 21 8 Stationary points of dissipative flows 24 Part I General Results and Linear Theory of Delay Equations in Finite Dimensional Spaces 29 2 SomeGeneralResultsandRemarksonDelayDifferentialEquations 31 E. Ait Dads 1 Introduction 31 2 A general initial value problem 33 2.1 Existence 34 2.2 Uniqueness 35 2.3 Continuation of solutions 37 2.4 Dependence on initial values and parameters 38 2.5 Differentiability of solutions 40 v vi DELAY DIFFERENTIAL EQUATIONS 3 Autonomous Functional Differential Equations 41 Franz Kappel 1 Basic Theory 41 1.1 Preliminaries 41 1.2 Existence and uniqueness of solutions 44 1.3 The Laplace-transform of solutions. The fundamental matrix 46 1.4 Smooth initial functions 54 1.5 The variation of constants formula 55 1.6 The Spectrum 59 1.7 The solution semigroup 68 2 Eigenspaces 71 2.1 Generalized eigenspaces 71 2.2 Projections onto eigenspaces 90 2.3 Exponential dichotomy of the state space 101 3 Small Solutions and Completeness 104 3.1 Small solutions 104 3.2 Completeness of generalized eigenfunctions 109 4 Degenerate delay equations 110 4.1 A necessary and sufficient condition 110 4.2 A necessary condition for degeneracy 116 4.3 Coordinate transformations with delays 119 4.4 The structure of degenerate systems with commensurate delays 124 Appendix: A 127 Appendix: B 129 Appendix: C 131 Appendix: D 132 References 137 Part II Hopf Bifurcation, Centre manifolds and Normal Forms for De- lay Differential Equations 141 4 Variation of Constant Formula for Delay Differential Equations 143 M.L. Hbid and K. Ezzinbi 1 Introduction 143 2 Variation Of Constant Formula Using Sun-Star Machinery 145 2.1 Duality and semigroups 145 2.1.1 The variation of constant formula: 146 2.2 Application to delay differential equations 147 2.2.1 The trivial equation: 147 2.2.2 The general equation 149 3 Variation Of Constant Formula Using Integrated Semigroups Theory 149 3.1 Notations and basic results 150 3.2 The variation of constant formula 153 Contents vii 5 Introduction to Hopf Bifurcation Theory for Delay Differential 161 Equations M.L. Hbid 1 Introduction 161 1.1 Statement of the Problem: 161 1.2 History of the problem 163 1.2.1 The Case of ODEs: 163 1.2.2 The case of Delay Equations: 164 2 TheLyapunovDirectMethodAndHopfBifurcation: TheCase Of Ode 166 3 The Center Manifold Reduction Of DDE 168 3.1 The linear equation 169 3.2 The center manifold theorem 172 3.3 Back to the nonlinear equation: 177 3.4 The reduced system 179 4 Cases Where The Approximation Of Center Manifold Is Needed 182 4.1 Approximation of a local center manifold 183 4.2 The reduced system 188 6 An Algorithmic Scheme for Approximating Center Manifolds 193 and Normal Forms for Functional Differential Equations M. Ait Babram 1 Introduction 193 2 Notations and background 195 3 Computational scheme of a local center manifold 199 3.1 Formulation of the scheme 202 3.2 Special cases. 209 3.2.1 Case of Hopf singularity 209 3.2.2 The case of Bogdanov -Takens singularity. 210 4 Computational scheme of Normal Forms 213 4.1 Normal form construction of the reduced system 214 4.2 Normal form construction for FDEs 221 7 NormalFormsandBifurcationsforDelayDifferentialEquations 227 T. Faria 1 Introduction 227 2 Normal Forms for FDEs in Finite Dimensional Spaces 231 2.1 Preliminaries 231 2.2 The enlarged phase space 232 2.3 Normal form construction 234 2.4 Equations with parameters 240 2.5 More about normal forms for FDEs in Rn 241 3 Normal forms and Bifurcation Problems 243 3.1 The Bogdanov-Takens bifurcation 243 3.2 Hopf bifurcation 246 viii DELAY DIFFERENTIAL EQUATIONS 4 Normal Forms for FDEs in Hilbert Spaces 253 4.1 Linear FDEs 254 4.2 Normal forms 256 R 4.3 The associated FDE on 258 4.4 Applications to bifurcation problems 260 5 Normal Forms for FDEs in General Banach Spaces 262 5.1 Adjointtheory 263 5.2 Normal forms on centre manifolds 268 5.3 A reaction-diffusion equation with delayand Dirichlet conditions 270 References 275 Part III Functional Differential Equations in Infinite Dimensional Spaces 283 8 A Theory of Linear Delay Differential Equations in Infinite Di- 285 mensional Spaces O. Arino and E. Sa´nchez 1 Introduction 285 1.1 A model of fish population dynamics with spatial dif- fusion (11) 286 1.2 An abstract differential equation arising from cell pop- ulation dynamics 288 1.3 Fromintegro-differencetoabstractdelaydifferentialequa- tions (8) 292 1.3.1 The linear equation 292 1.3.2 Delaydifferentialequationformulationofsystem(1.5)- (1.6) 295 1.4 The linearized equation of equation (1.17) near non- trivial steady-states 297 1.4.1 The steady-state equation 297 1.4.2 Linearization of equation (1.17)near (n,N) 298 1.4.3 Exponential solutions of (1.20) 299 1.5 Conclusion 303 2 The Cauchy Problem For An Abstract Linear Delay Differen- tial Equation 303 2.1 Resolution of the Cauchy problem 304 2.2 Semigroup approach to the problem (CP) 306 2.3 Some results about the range of λI −A 310 3 Formal Duality 311 3.1 The formal adjoint equation 313 ∗ 3.2 The operator A formal adjointof A 316 3.3 Application to the model of cell population dynamics 317 3.4 Conclusion 320 4 Linear Theory Of Abstract Functional Differential Equations Of Retarded Type 320 4.1 Some spectral properties of C -semigroups 321 0 Contents ix 4.2 Decomposition of the state space C([−r,0];E) 324 4.3 A Fredholm alternative principle 326 4.4 CharacterizationofthesubspaceR(λI−A)m forλin (σ\σ )(A) 326 e 4.5 Characterization of the projection operator onto the subspace Q 331 Λ 4.6 Conclusion 335 5 AVariationOfConstantsFormulaForAnAbstractFunctional Differential Equation Of Retarded Type 335 5.1 The nonhomogeneous problem 336 5.2 Semigroup defined in L(E) 337 5.3 The fundamental solution 338 5.4 Thefundamentalsolutionandthenonhomogeneous problem 341 5.5 Decomposition of the nonhomogeneous problem in C([−r,0];E) 344 9 TheBasicTheoryofAbstractSemilinearFunctionalDifferential 347 Equations with Non-Dense Domain K. Ezzinbi and M. Adimy 1 Introduction 347 2 Basic results 350 3 Existence, uniqueness and regularity of solutions 354 4 Thesemigroupandtheintegratedsemigroupintheautonomous case 372 5 Principle of linearized stability 381 6 Spectral Decomposition 383 7 Existence of bounded solutions 385 8 Existence of periodic or almost periodic solutions 391 9 Applications 393 References 399 Part IV More on Delay Differential Equations and Applications 409 10 Dynamics of Delay Differential Equations 411 H.O. Walther 1 Basic theory and some results for examples 411 1.1 Semiflowsofretardedfunctionaldifferentialequations 411 1.2 Periodic orbits and Poincar´e return maps 416 1.3 Compactness 418 1.4 Global attractors 418 1.5 Linear autonomous equations and spectral decomposition 419 1.6 Local invariant manifolds for nonlinear RFDEs 423 1.7 Floquet multipliers of periodic orbits 425 1.8 Differential equations with state-dependent delays 435