04751nam 2200709 450 991046085370332120200520144314.01-118-99632-11-118-95368-1(CKB)3710000000460085(EBL)1895800(SSID)ssj0001530658(PQKBManifestationID)12537119(PQKBTitleCode)TC0001530658(PQKBWorkID)11531322(PQKB)10478913(PQKBManifestationID)16040957(PQKB)20891689(MiAaPQ)EBC4530805(MiAaPQ)EBC1895800(Au-PeEL)EBL1895800(CaPaEBR)ebr11088046(OCoLC)908554603(EXLCZ)99371000000046008520150817h20162016 uy 0engurcnu||||||||txtccrFundamentals of matrix analysis with applications /Edward Barry Saff, Arthur David SniderHoboken, New Jersey :John Wiley & Sons, Inc.,2016.©20161 online resource (410 p.)Description based upon print version of record.1-118-95365-7 1-118-99634-8 Includes bibliographical references and index.Title Page; Copyright Page; Contents; Preface; PART I INTRODUCTION: THREE EXAMPLES; Chapter 1 Systems of Linear Algebraic Equations; 1.1 Linear Algebraic Equations; 1.2 Matrix Representation of Linear Systems and the Gauss-Jordan Algorithm ; 1.3 The Complete Gauss Elimination Algorithm; 1.4 Echelon Form and Rank; 1.5 Computational Considerations; 1.6 Summary; Chapter 2 Matrix Algebra; 2.1 Matrix Multiplication; 2.2 Some Physical Applications of Matrix Operators; 2.3 The Inverse and the Transpose; 2.4 Determinants; 2.5 Three Important Determinant Rules; 2.6 Summary; Group Projects for Part IA. LU Factorization B. Two-Point Boundary Value Problem; C. Electrostatic Voltage; D. Kirchhoff's Laws; E. Global Positioning Systems; F. Fixed-Point Methods; PART II INTRODUCTION: THE STRUCTURE OF GENERAL SOLUTIONS TO LINEAR ALGEBRAIC EQUATIONS; Chapter 3 Vector Spaces; 3.1 General Spaces, Subspaces, and Spans; 3.2 Linear Dependence; 3.3 Bases, Dimension, and Rank; 3.4 Summary; Chapter 4 Orthogonality; 4.1 Orthogonal Vectors and the Gram-Schmidt Algorithm; 4.2 Orthogonal Matrices; 4.3 Least Squares; 4.4 Function Spaces; 4.5 Summary; Group Projects for Part II; A. Rotations and ReflectionsB. Householder Reflectors C. Infinite Dimensional Matrices; PART III INTRODUCTION: REFLECT ON THIS; Chapter 5 Eigenvectors and Eigenvalues; 5.1 Eigenvector Basics; 5.2 Calculating Eigenvalues and Eigenvectors; 5.3 Symmetric and Hermitian Matrices; 5.4 Summary; Chapter 6 Similarity; 6.1 Similarity Transformations and Diagonalizability; 6.2 Principle Axes and Normal Modes; 6.3 Schur Decomposition and Its Implications; 6.4 The Singular Value Decomposition; 6.5 The Power Method and the QR Algorithm; 6.6 Summary; Chapter 7 Linear Systems of Differential Equations; 7.1 First-Order Linear Systems7.2 The Matrix Exponential Function 7.3 The Jordan Normal Form; 7.4 Matrix Exponentiation via Generalized Eigenvectors; 7.5 Summary; Group Projects for Part III; A. Positive Definite Matrices; B. Hessenberg Form; C. Discrete Fourier Transform; D. Construction of the SVD; E. Total Least Squares; F. Fibonacci Numbers; Answers to Odd Numbered Exercises; Index; EULAThis book provides comprehensive coverage of matrix theory from a geometric and physical perspective, and the authors address the functionality of matrices and their ability to illustrate and aid in many practical applications. Readers are introduced to inverses and eigenvalues through physical examples such as rotations, reflections, and projections, and only then are computational details described and explored. MATLAB is utilized to aid in reader comprehension, and the authors are careful to address the issue of rank fragility so readers are not flummoxed when MATLAB displays conflict withMatricesAlgebras, LinearOrthogonalization methodsEigenvaluesElectronic books.Matrices.Algebras, Linear.Orthogonalization methods.Eigenvalues.512.9/434Saff E. B.1944-57326Snider Arthur DavidMiAaPQMiAaPQMiAaPQBOOK9910460853703321Fundamentals of matrix analysis with applications2219976UNINA