04545nam 2200709 450 991046266860332120211216014617.03-11-027043-910.1515/9783110270433(CKB)2670000000432658(EBL)1037918(OCoLC)858761731(SSID)ssj0001002217(PQKBManifestationID)11534566(PQKBTitleCode)TC0001002217(PQKBWorkID)10997810(PQKB)10400442(MiAaPQ)EBC1037918(DE-B1597)173928(OCoLC)862247500(DE-B1597)9783110270433(Au-PeEL)EBL1037918(CaPaEBR)ebr10786193(CaONFJC)MIL807758(EXLCZ)99267000000043265820130922h20132013 uy 0engurcnu||||||||txtccrNonconservative stability problems of modern physics /by Oleg N. KirillovBerlin ;Boston :Walter de Gruyter GmbH & Co., KG,[2013]©20131 online resource (448 p.)De Gruyter Studies in Mathematical Physics ;14Description based upon print version of record.3-11-027034-X Includes bibliographies (pages [387]-422) and indexes.Front matter --Preface --Contents --Chapter 1: Introduction --Chapter 2: Lyapunov stability and linear stability analysis --Chapter 3: Hamiltonian and gyroscopic systems --Chapter 4: Reversible and circulatory systems --Chapter 5: Influence of structure of forces on stability --Chapter 6: Dissipation-induced instabilities --Chapter 7: Nonself-adjoint boundary eigenvalue problems for differential operators and operator matrices dependent on parameters --Chapter 8: The destabilization paradox in continuous circulatory systems --Chapter 9: The MHD kinematic mean field α2-dynamo --Chapter 10: Campbell diagrams of gyroscopic continua and subcritical friction-induced flutter --Chapter 11: Non-Hermitian perturbation of Hermitian matrices with physical applications --Chapter 12: Magnetorotational instability --References --IndexThis work gives a complete overview on the subject of nonconservative stability from the modern point of view. Relevant mathematical concepts are presented, as well as rigorous stability results and numerous classical and contemporary examples from mechanics and physics. It deals with both finite- and infinite-dimensional nonconservative systems and covers the fundamentals of the theory, including such topics as Lyapunov stability and linear stability analysis, Hamiltonian and gyroscopic systems, reversible and circulatory systems, influence of structure of forces on stability, and dissipation-induced instabilities, as well as concrete physical problems, including perturbative techniques for nonself-adjoint boundary eigenvalue problems, theory of the destabilization paradox due to small damping in continuous circulatory systems, Krein-space related perturbation theory for the MHD kinematic mean field α²-dynamo, analysis of Campbell diagrams and friction-induced flutter in gyroscopic continua, non-Hermitian perturbation of Hermitian matrices with applications to optics, and magnetorotational instability and the Velikhov-Chandrasekhar paradox. The book serves present and prospective specialists providing the current state of knowledge in the actively developing field of nonconservative stability theory. Its understanding is vital for many areas of technology, ranging from such traditional ones as rotor dynamics, aeroelasticity and structural mechanics to modern problems of hydro- and magnetohydrodynamics and celestial mechanics.De Gruyter Studies in Mathematical PhysicsEigenvaluesMechanical impedanceOscillationsStabilityMathematical modelsElectronic books.Eigenvalues.Mechanical impedance.Oscillations.StabilityMathematical models.530.4/74530.474SK 950rvkKirillov Oleg N.1972-933374MiAaPQMiAaPQMiAaPQBOOK9910462668603321Nonconservative stability problems of modern physics2472054UNINA