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010   $a9786610636013
010   $a0-08-046398-3
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035   $a(EBL)274249
035   $a(OCoLC)190812137
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100   $a20060818d2006      uy         0
101 0 $aeng
135   $aur|n|---|||||
181   $ctxt
182   $cc
183   $acr
200 10$aStochastic dynamics and control /$fJian-Qiao Sun
205   $a1st ed.
210   $aBoston $cElsevier$d2006
215   $a1 online resource (427 p.)
225 1 $aMonograph series on nonlinear science and complexity,$x1574-6917 ;$v4
300   $aDescription based upon print version of record.
311   $a0-444-52230-1 
320   $aIncludes bibliographical references and index.
327   $aFront cover; Table of contents; Preface; Chapter 1. Introduction; 1.1. Stochastic dynamics; 1.2. Stochastic control; Chapter 2. Probability Theory; 2.1. Probability of random events; 2.2. Random variables; 2.3. Probability distributions; 2.4. Expectations of random variables; 2.5. Common probability distributions; 2.6. Two-dimensional random variables; 2.7. n-Dimensional random variables; 2.8. Functions of random variables; 2.9 Conditional probability; Exercises; Chapter 3. Stochastic Processes; 3.1. Definitions; 3.2. Expectations; 3.3. Vector process; 3.4 Gaussian process
327   $a3.5. Harmonic process3.6. Stationary process; 3.7. Ergodic process; 3.8. Poisson process; 3.9. Markov process; Exercises; Chapter 4. Spectral Analysis of Stochastic Processes; 4.1 Power spectral density function; 4.2. Spectral moments and bandwidth; 4.3. Process with rational spectral density function; 4.4. Finite time spectral analysis; Exercises; Chapter 5. Stochastic Calculus; 5.1. Modes of convergence; 5.2. Stochastic differentiation; 5.3. Stochastic integration; 5.4. Ito calculus; Exercises; Chapter 6. Fokker-Planck-Kolmogorov Equation; 6.1. Chapman-Kolmogorov-Smoluchowski equation
327   $a6.2. Derivation of the FPK equation6.3. Solutions of FPK equations for linear systems; 6.4. Short-time solution; 6.5. Path integral solution; 6.6. Exact stationary solutions; Exercises; Chapter 7. Kolmogorov Backward Equation; 7.1. Derivation of the backward equation; 7.2. Reliability formulation; 7.3. First-passage time probability; 7.4. Pontryagin-Vitt equations; Exercises; Capter 8. Random Vibration of SDOF Systems; 8.1. Solutions in the mean square sense; 8.2. Solutions with Ito calculus; Exercises; Chapter 9. Random Vibration of MDOF Discrete Systems; 9.1. Lagrange's equation
327   $a9.2. Modal solutions of MDOF systems9.3. Response statistics; 9.4. State space representation and Ito calculus; 9.5. Filtered white noise excitation; Exercises; Chapter 10. Random Vibration of Continuous Structures; 10.1. Distributed random excitations; 10.2. One-dimensional structures; 10.3. Two-dimensional structures; Exercises; Chapter 11. Structural Reliability; 11.1. Modes of failure; 11.2. Level crossing; 11.3. Vector process; 11.4. First-passage reliability based on level crossing; 11.5. First-passage time probability - general approach; 11.6. Structural fatigue
327   $a11.7. Dirlik's formula for fatigue prediction11.8. Extended Dirlik's formula for non-Gaussian stress; Exercises; Chapter 12. Monte Carlo Simulation; 12.1. Random numbers; 12.2. Random processes; 12.3. Stochastic differential equations; 12.4. Simulation of non-Gaussian processes; Exercises; Chapter 13. Elements of Feedback Controls; 13.1. Transfer function of linear dynamical systems; 13.2. Concepts of stability; 13.3. Effects of poles and zeros; 13.4. Time domain specifications; 13.5. PID controls; 13.6. Routh's stability criterion; 13.7. Root locus design; Exercises
327   $aChapter 14. Feedback Control of Stochastic Systems
330   $aThis book is a result of many years of author's research and teaching on random vibration and control.  It was used as lecture notes for a graduate course.  It provides a systematic review of theory of probability, stochastic processes, and stochastic calculus.  The feedback control is also reviewed in the book. Random vibration analyses of SDOF, MDOF and continuous structural systems are presented in a pedagogical order. The application of the random vibration theory to reliability and fatigue analysis is also discussed.  Recent research results on fatigue analysis of non-Gaussian stress proc
410  0$aMonograph series on nonlinear science and complexity ;$v4.
606   $aStochastic processes
606   $aProbabilities
615  0$aStochastic processes.
615  0$aProbabilities.
676   $a519.2
700   $aSun$b Jian-Qiao$0860940
801  0$bMiAaPQ
801  1$bMiAaPQ
801  2$bMiAaPQ
906   $aBOOK
912   $a9911006646103321
996   $aStochastic dynamics and control$94393112
997   $aUNINA