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Elementary Linear Algebra, Sixth Edition provides a solid introduction to both the computational and theoretical aspects of linear algebra, covering many important real-world applications, including graph theory, circuit theory, Markov chains, elementary coding theory, least-squares polynomials and least-squares solutions for inconsistent systems, differential equations, computer graphics and quadratic forms. In addition, many computational techniques in linear algebra are presented, including iterative methods for solving linear systems, LDU Decomposition, the Power Method for finding eigenvalues, QR Decomposition, and Singular Value Decomposition and its usefulness in digital imaging.Prepares students with a thorough coverage of the fundamentals of introductory linear algebraPresents each chapter as a coherent, organized theme, with clear explanations for each new conceptBuilds a foundation for math majors in the reading and writing of elementary mathematical proofs
Preface for the Instructor
Preface to the Student
A Light-Hearted Look at Linear Algebra Terms
Symbol Table
Computational & Numerical Techniques, Applications
Vectors and Matrices
Fundamental Operations With Vectors
The Dot Product
An Introduction to Proof Techniques
Fundamental Operations With Matrices
Matrix Multiplication
Systems of Linear Equations
Solving Linear Systems Using Gaussian Elimination
Gauss-Jordan Row Reduction and Reduced Row Echelon Form
Equivalent Systems, Rank, and Row Space
Inverses of Matrices
Determinants and Eigenvalues
Introduction to Determinants
Determinants and Row Reduction
Further Properties of the Determinant
Eigenvalues and Diagonalization
Summary of Techniques
Techniques for Solving a System AX=B of m Linear Equations in n Unknowns
Techniques for Finding the Inverse (If It Exists) of an nxn Matrix A
Techniques for Finding the Determinant of an nxn Matrix A
Techniques for Finding the Eigenvalues of an nxn Matrix A
Technique for Finding the Eigenvectors of an nxn Matrix A
Finite Dimensional Vector Spaces
Introduction to Vector Spaces
Subspaces
Span
Linear Independence
Basis and Dimension
Constructing Special Bases
Coordinatization
Linear Transformations
Introduction to Linear Transformations
The Matrix of a Linear Transformation
The Dimension Theorem
One-to-One and Onto Linear Transformations
Isomorphism
Diagonalization of Linear Operators
Orthogonality
Orthogonal Bases and the Gram-Schmidt Process
Orthogonal Complements
Orthogonal Diagonalization
Complex Vector Spaces and General Inner Products
Complex n-Vectors and Matrices
Complex Eigenvalues and Complex Eigenvectors
Complex Vector Spaces
Orthogonality in Cn
Inner Product Spaces
Additional Applications
Graph Theory
Ohm's Law
Least-Squares Polynomials
Markov Chains
Hill Substitution: An Introduction to Coding Theory
Linear Recurrence Relations and the Fibonacci Sequence
Rotation of Axes for Conic Sections
Computer Graphics
Differential Equations
Least-Squares Solutions for Inconsistent Systems
Quadratic Forms
Numerical Techniques
Numerical Techniques for Solving Systems
LDU Decomposition
The Power Method for Finding Eigenvalues
QR Factorization
Singular Value Decomposition
Functions
Exercises for Appendix B
Complex Numbers
Elementary Matrices
Index
Equivalent Conditions for Singular and Nonsingular Matrices
Diagonalization Method
Simplified Span Method (Simplifying Span(S))
Independence Test Method (Testing for Linear Independence of S)
Equivalent Conditions for Linearly Independent and Linearly Dependent Sets
Coordinatization Method (Coordinatizing v with Respect to an Ordered Basis B)
Transition Matrix Method (Calculating a Transition Matrix from B to C)
Kernel Method (Finding a Basis for the Kernel of L)
Range Method (Finding a Basis for the Range of L)
Equivalence Conditions for One-to-One, Onto, and Isomorphism
Dimension Theorem