Publication Date:1964 Availability:Usually ships in 1-2 business days Condition:Former Owner Signature Inside Front Cover; Not A Library Book; Includes Dust Jacket; No Markings Or Highlighting
Suitable for advanced undergraduates and graduate students, this text presents selected aspects of matrix theory that are most useful in developing computational methods for solving linear equations and finding characteristic roots. Topics include norms, bounds and convergence; localization theorems and other inequalities; and methods of solving systems of linear equations. 1964 edition.
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Table of contents
1. SOME BASIC IDENTITIES AND INEQUALITIES 1.0 Objectives; Notation 1.1 Elementary Matrices 1.2 Some Factorizations 1.3 Projections, and the General Reciprocal 1.4 Some Determinantal Identities 1.5 Lanczos Algorithm for Tridiagonalization 1.6 Orthogonal Polynomials References Problems and Exercises
2. NORMS, BOUNDS, AND CONVERGENCE 2.0 The Notion of a Norm 2.1 Convex Sets and Convex Bodies 2.2 Norms and Bounds 2.3 Norms, Bounds, and Spectral Radii 2.4 Nonnegative Matrices 2.5 Convergence; Functions of Matrices References Problems and Exercises
3. LOCALIZATION THEOREMS AND OTHER INEQUALITIES 3.0 Basic Definitions 3.1 Exclusion Theorems 3.2 Inclusion and Separation Theorems 3.3 Minimax Theorems and the Field of Values 3.4 Inequalities of Wielandt Kantorovich References Problems and Exercises
4. THE SOLUTION OF LINEAR SYSTEMS: METHODS OF SUCCESSIVE APPROXIMATION 4.0 Direct Methods and Others 4.1 The Inversion of Matrices 4.2 Methods of Projection 4.3 Norm-Reducing Methods References Problems and Exercises
5. DIRECT METHODS OF INVERSION 5.0 Uses of the Inverse 5.1 The Method of Modification 5.2 Triangularization 5.3 A More General Formulation 5.4 Orthogonal Triangularization 5.5 Orthogonalization 5.6 Orthogonalization and Projection 5.7 The Method of Conjugate Gradients References Problems and Exercises
6. PROPER VALUES AND VECTORS: NORMALIZATION AND REDUCTION OF THE MATRIX 6.0 Purpose of Normalization 6.1 The Method of Krylov 6.2 The Weber-Voetter Method 6.3 The Method of Danilevskii 6.4 The Hessenberg and the Lanczos Reductions 6.5 Proper Values and Vectors 6.6 The Method of Samuelson and Bryan 6.7 The Method of Leverrier References Problems and Exercises
7. PROPER VALUES AND VECTORS: SUCCESSIVE APPROXIMATION 7.0 Methods of Successive Approximation 7.1 The Method of Jacobi 7.2 The Method of Collar and Jahn 7.3 Powers of a Matrix 7.4 Simple Iteration (the Power Method) 7.5 Multiple Roots and Principal Vectors 7.6 Staircase Iteration (Treppeniteration) 7.7 The LR-Transformation 7.8 Bi-iteration 7.9 The QR-Transformation References Problems and Exercises
