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2: Systems of Linear Equations and Matrices

2: Systems of Linear Equations and Matrices

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Learning Objectives

In this chapter, you will learn to:

Do matrix operations.
Solve linear systems using the Gauss-Jordan method.
Solve linear systems using the matrix inverse method.
Do application problems.

2.1: Introduction to Systems of Equations and Inequalities
In this chapter, we will investigate matrices and their inverses, and various ways to use matrices to solve systems of equations. First, however, we will study systems of equations on their own: linear and nonlinear, and then partial fractions. We will not be breaking any secret codes here, but we will lay the foundation for future courses.
2.2: Systems of Linear Equations - Two Variables
A system of linear equations consists of two or more equations made up of two or more variables such that all equations in the system are considered simultaneously. The solution to a system of linear equations in two variables is any ordered pair that satisfies each equation independently. Systems of equations are classified as independent with one solution, dependent with an infinite number of solutions, or inconsistent with no solution.
2.3: Introduction to Matrices
A matrix is a 2 dimensional array of numbers arranged in rows and columns. Matrices provide a method of organizing, storing, and working with mathematical information. Matrices have an abundance of applications and use in the real world. Matrices provide a useful tool for working with models based on systems of linear equations. We’ll use matrices in sections 2.2, 2.3, and 2.4 to solve systems of linear equations with several variables in this chapter.
- 2.3.1: Introduction to Matrices (Exercises)
2.4: Systems of Linear Equations and the Gauss-Jordan Method
In this section, we learn to solve systems of linear equations using a process called the Gauss-Jordan method by first expressing the system as a matrix, and then reducing it to an equivalent system by simple row operations. The process is continued until the solution is obvious from the matrix. The matrix that represents the system is called the augmented matrix, and the arithmetic manipulation that is used to move from a system to a reduced equivalent system is called a row operation.
- 2.4.1: Systems of Linear Equations and the Gauss-Jordan Method (Exercises)
2.5: Systems of Linear Equations – Special Cases
- 2.5.1: Systems of Linear Equations – Special Cases (Exercises)
2.6: Inverse Matrices
In this section, we will learn to find the inverse of a matrix, if it exists. Later, we will use matrix inverses to solve linear systems.
- 2.6.1: Inverse Matrices (Exercises)
2.7: Application of Matrices in Cryptography
In this section, we will learn to find the inverse of a matrix, if it exists. Later, we will use matrix inverses to solve linear systems.
- 2.7.1: Application of Matrices in Cryptography (Exercises)
2.8: Applications – Leontief Models
In this section we will examine an application of matrices to model economic systems.
- 2.8.1: Applications – Leontief Models (Exercises)
2.9: Chapter Review

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