Introduction To Linear Algebra (classic Version) by Lee JohnsonIntroduction To Linear Algebra (classic Version) by Lee Johnson

Introduction To Linear Algebra (classic Version)

byLee Johnson, Dean Riess, Jimmy Arnold

Paperback | March 7, 2017

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For courses in introductory linear algebra

This title is part of the Pearson Modern Classics series. Pearson Modern Classics are acclaimed titles at a value price. Please visit for a complete list of titles.

Introduction to Linear Algebra, 5th Edition is a foundation book that bridges both practical computation and theoretical principles. Due to its flexible table of contents, the book is accessible for both students majoring in the scientific, engineering, and social sciences, as well as students that want an introduction to mathematical abstraction and logical reasoning. In order to achieve the text's flexibility, the book centers on 3 principal topics: matrix theory and systems of linear equations, elementary vector space concepts, and the eigenvalue problem. This highly adaptable text can be used for a one-quarter or one-semester course at the sophomore/junior level, or for a more advanced class at the junior/senior level.

Title:Introduction To Linear Algebra (classic Version)Format:PaperbackDimensions:624 pages, 9.2 × 7.4 × 1 inPublished:March 7, 2017Publisher:Pearson EducationLanguage:English

The following ISBNs are associated with this title:

ISBN - 10:0134689534

ISBN - 13:9780134689531


Table of Contents

1. Matrices and Systems of Linear Equations.

Introduction to Matrices and Systems of Linear Equations.

Echelon Form and Gauss-Jordan Elimination.

Consistent Systems of Linear Equations.

Applications (Optional).

Matrix Operations.

Algebraic Properties of Matrix Operations.

Linear Independence and Nonsingular Matrices.

Data Fitting, Numerical Integration, and Numerical Differentiation (Optional).

Matrix Inverses and Their Properties.

2. Vectors in 2-Space and 3-Space.

Vectors in the Plane.

Vectors in Space.

The Dot Product and the Cross Product.

Lines and Planes in Space.

3. The Vector Space Rn.


Vector Space Properties of Rn.

Examples of Subspaces.

Bases for Subspaces.


Orthogonal Bases for Subspaces.

Linear Transformations from Rn to Rm.

Least-Squares Solutions to Inconsistent Systems, with Applications to Data Fitting.

Theory and Practice of Least Squares.

4. The Eigenvalue Problem.

The Eigenvalue Problem for (2 x 2) Matrices.

Determinants and the Eigenvalue Problem.

Elementary Operations and Determinants (Optional).

Eigenvalues and the Characteristic Polynomial.

Eigenvectors and Eigenspaces.

Complex Eigenvalues and Eigenvectors.

Similarity Transformations and Diagonalization.

Difference Equations; Markov Chains, Systems of Differential Equations (Optional).

5. Vector Spaces and Linear Transformations.


Vector Spaces.


Linear Independence, Bases, and Coordinates.


Inner-Product Spaces, Orthogonal Bases, and Projections (Optional).

Linear Transformations.

Operations with Linear Transformations.

Matrix Representations for Linear Transformations.

Change of Basis and Diagonalization.

6. Determinants.


Cofactor Expansions of Determinants.

Elementary Operations and Determinants.

Cramer's Rule.

Applications of Determinants: Inverses and Wronksians.

7. Eigenvalues and Applications.

Quadratic Forms.

Systems of Differential Equations.

Transformation to Hessenberg Form.

Eigenvalues of Hessenberg Matrices.

Householder Transformations.

The QR Factorization and Least-Squares Solutions.

Matrix Polynomials and the Cayley-Hamilton Theorem.

Generalized Eigenvectors and Solutions of Systems of Differential Equations.

Appendix: An Introduction to MATLAB.

Answers to Selected Odd-Numbered Exercises.