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100   $a20090918d2009      uy             0
101 0 $aeng
135   $aur|n|---|||||
181   $ctxt
182   $cc
183   $acr
200 00$aInterface problems and methods in biological and physical flows$b[electronic resource] /$feditors, Boo Cheong Khoo, Zhilin Li, Ping Lin
210   $aHackensack, NJ $cWorld Scientific$dc2009
215   $a1 online resource (184 p.)
225 1 $aLecture notes series / National University of Singapore. Institute for Mathematical Sciences,$x1793-0758 ;$v17
300   $aDescription based upon print version of record.
311   $a981-283-784-1 
320   $aIncludes bibliographical references.
327   $aForeword; Preface; CONTENTS; An Introduction to the Immersed Boundary and the Immersed Interface Methods Robert H. Dillon and Zhilin Li; 1. Introduction; Part I AN INTRODUCTION TO THE IMMERSED BOUNDARY METHOD; 2. Overview of Immersed Boundary Method; 3. Some Applications of the IB Method; 4. Some Technical Issues of the IB Method; Part II A TUTORIAL OF THE IMMERSED INTERFACE METHOD; 5. The Immersed Interface Method for Elliptic Interface Problems; 6. The Augmented Immersed Interface Method and Applications; 7. Simplifying the Immersed Interface Method by Removing Source Singularities
327   $a8. The Immersed Interface Method Using Finite Element Formulations9. The IIM for Free Boundary or Moving Interface Problems; 10. Acknowledgements; References; Lecture Notes on Nonlinear Tumor Growth: Modeling and Simulation John S. Lowengrub, Vittorio Cristini, Hermann B. Frieboes, Xiangrong Li, Paul Macklin, Sandeep Sanga, Steven M. Wise and Xiaoming Zheng; 0. Introduction; 1. Tumor Growth in Homogeneous Tissuea; 1.1. Overview; 1.2. Discrete modeling; 1.3. Continuum modeling; 1.4. Regimes of growth; 1.5. Comparison with experiment; 1.6. Linear analysis; 1.7. Nonlinear results
327   $a2. Tumor Growth in Heterogeneous Tissueb2.1. Overview; 2.2. Governing equations; 2.3. Nonlinear results; 3. Tumor Growth and Neovascularizationc; 3.1. Overview; 3.2. The model; 3.3. Nonlinear results; 4. Conclusion and Future Research Directions; References; Progress in Modeling Pulsed Detonations Frank K. Lu and R. Bellini; 1. Introduction and Literature Review; 2. Overview of Early Studies in Detonations; 2.1. Structure of detonation waves; 3. Review of Numerical Simulation of Pulse Detonation Engines; 3.1. Detonation initiation; 3.2. Detonation stability; 3.3. Numerics and algorithms
327   $a3.5. Turbulence modeling3.6. Chemical kinetics; 4. The Governing Equations; 5. Numerical Method; 5.1. Local ignition averaging method; 6. Numerical Simulations of Pulse Detonations; 6.1. One-dimensional detonation wave propagation; 6.2. Detonation wave propagation through an area enlargement; 7. Outlook and Conclusions; Acknowledgments; References; Direct Numerical Simulations of Multiphase Flows Gr etar Tryggvason and Jiacai Lu; 1. Introduction; 2. Governing Equations; 3. Numerical Method; 4. Results; 5. Conclusions; Acknowledgments; References
330   $aThis volume showcases lecture notes collected from tutorials presented at the Workshop on Moving Interface Problems and Applications in Fluid Dynamics that was held between January 8 and March 31, 2007 at the Institute for Mathematical Sciences, National University of Singapore. As part of the program, these tutorials were conducted by specialists within their respective areas such as Robert Dillon, Zhilin Li, John Lowengrub, Frank Lu and Gretar Tryggvason. The topics in the program encompass modeling and simulations of biological flow coupled to deformable tissue/elastic structure, shock wave
410  0$aLecture notes series (National University of Singapore. Institute for Mathematical Sciences) ;$vv. 17.
606   $aInterfaces (Physical sciences)$xMathematics$vCongresses
606   $aFluid dynamics$xMathematics$vCongresses
608   $aElectronic books.
615  0$aInterfaces (Physical sciences)$xMathematics
615  0$aFluid dynamics$xMathematics
676   $a532/.0510151
701   $aKhoo$b Boo Cheong$f1958-$0981634
701   $aLi$b Zhilin$f1956-$0981635
701   $aLin$b Ping$f1963-$0981636
801  0$bMiAaPQ
801  1$bMiAaPQ
801  2$bMiAaPQ
906   $aBOOK
912   $a9910457009303321
996   $aInterface problems and methods in biological and physical flows$92240404
997   $aUNINA