
1997 / xiv + 220 pages / Softcover / ISBN: 9780898713961 / List Price $82.00 / SIAM Member Price $57.40 / Order Code FR17
"This graduatelevel textbook gives equal weights to iterative methods and preconditioning (including domain decomposition and multigrid), and it approaches Krylov space methods from a somewhat different angle. It also treats some subjects that appear for the first time in a textbook, like new results on roundoff effects in the Lanczos and conjugate gradient algorithms. This welldone introduction to the area can be strongly recommended. It is competently written by an author who has contributed much to the complete reshaping of this field in the last twenty years." – Martin H. Gutknecht, ETH Zurich.
"For a course in matrix iterations, this is just the right book. It is wideranging, careful about details, and appealingly writtena major addition to
the literature in this important area." – Nick Trefethen, Professor of Numerical Analysis, Oxford University, England.
"This book differs substantially from other books on iterative methods, including those recently published, in that it concentrates on several principles behind the derivation and analysis of the most important methods and preconditioning techniques. Individual algorithms serve as examples illustrating the discussed ideas. Strong emphasis is given to motivation and its relation to problems in other areas of mathematics. The book speaks in clear language about principal problems in the area of iterative methods. It represents a comprehensive introduction to the field and stimulates the interest of the reader. It is valuable for students and also for experts working in the area of iterative methods." – Zdenek Strakos, Professor, Czech Academy of Sciences, Institute of Computer Science.
"Anne Greenbaum is an admired authority in the field of iterative methods. Engineers and scientists often ask me about the puzzling behavior of iterative methods, which I almost always answer with a reference to Anne's work, now made easy to point to in her new book. " – Paul Saylor, Department of Computer Science, University of Illinois, UrbanaChampaign.
Much recent research has concentrated on the efficient solution of large sparse or structured linear systems using iterative methods. A language loaded with acronyms for a thousand different algorithms has developed, and it is often difficult even for specialists to identify the basic principles involved. Here is a book that focuses on the analysis of iterative methods. The author includes the most useful algorithms from a practical point of view and discusses the mathematical principles behind their derivation and analysis. Several questions are emphasized throughout: Does the method converge? If so, how fast? Is it optimal, among a certain class? If not, can it be shown to be nearoptimal? The answers are presented clearly, when they are known, and remaining important open questions are laid out for further study.
Greenbaum includes important material on the effect of rounding errors on iterative methods that has not appeared in other books on this subject. Additional important topics include a discussion of the open problem of finding a provably nearoptimal short recurrence for nonHermitian linear systems; the relation of matrix properties such as the field of values and the pseudospectrum to the convergence rate of iterative methods; comparison theorems for preconditioners and discussion of optimal preconditioners of specified forms; introductory material on the analysis of incomplete Cholesky, multigrid, and domain decomposition preconditioners, using the diffusion equation and the neutron transport equation as example problems. A small set of recommended algorithms and implementations is included.
Audience
This book is appropriate for classroom use at the graduate level, especially for students in numerical analysis. It will also be of interest to specialists in the field of iterative methods and mathematicians in other fields who want to learn more about the numerical solution of large linear systems. Scientists and engineers who solve such linear systems will find that the book provides useful theoretical background.
Contents
List of Algorithms; Preface; Chapter 1: Introduction. Brief Overview of the State of the Art; Notation; Review of Relevant Linear Algebra; Part I: Krylov Subspace Approximations. Chapter 2: Some Iteration Methods. Simple Iteration; Orthomin(1) and Steepest Descent; Orthomin(2) and CG; Orthodir, MINRES, and GMRES; Derivation of MINRES and CG from the Lanczos Algorithm; Chapter 3: Error Bounds for CG, MINRES, and GMRES. Hermitian ProblemsCG and MINRES; NonHermitian ProblemsGMRES; Chapter 4: Effects of Finite Precision Arithmetic. Some Numerical Examples; The Lanczos Algorithm; A Hypothetical MINRES/CG Implementation; A Matrix Completion Problem; Orthogonal Polynomials; Chapter 5: BiCG and Related Methods. The TwoSided Lanczos Algorithm; The Biconjugate Gradient Algorithm; The QuasiMinimal Residual Algorithm; Relation Between BiCG and QMR; The Conjugate Gradient Squared Algorithm; The BiCGSTAB Algorithm; Which Method Should I Use?; Chapter 6: Is There A Short Recurrence for a NearOptimal Approximation? The Faber and Manteuffel Result; Implications; Chapter 7: Miscellaneous Issues. Symmetrizing the Problem; Error Estimation and Stopping Criteria; Attainable Accuracy; Multiple RightHand Sides and Block Methods; Computer Implementation; Part II: Preconditioners. Chapter 8: Overview and Preconditioned Algorithms. Chapter 9: Two Example Problems. The Diffusion Equation; The Transport Equation; Chapter 10: Comparison of Preconditioners. Jacobi, GaussSeidel, SOR; The PerronFrobenius Theorem; Comparison of Regular Splittings; Regular Splittings Used with the CG Algorithm; Optimal Diagonal and Block Diagonal Preconditioners; Chapter 11: Incomplete Decompositions. Incomplete Cholesky Decomposition; Modified Incomplete Cholesky Decomposition; Chapter 12: Multigrid and Domain Decomposition Methods. Multigrid Methods; Basic Ideas of Domain Decomposition Methods.
ISBN: 9780898713961