4: Matrices and Determinants

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4.1: Matrix Arithmetic
You have now solved systems of equations by writing them in terms of an augmented matrix and performing row operations on this matrix. Matrices, however, are important not only for solving systems of equations but also for many other applications. In this section, you will learn several matrix operations, including matrix addition, scalar multiplication, and matrix multiplication.
4.2: The Transpose
Another important operation on matrices is that of taking the transpose.
4.3: The Identity and Inverses
In this section, we learn about identity matrices and the inverse of a matrix. We also explore how to find \(A^{-1}\).
4.4: Elementary Matrices
We now turn our attention to a special type of matrix called an elementary matrix.
4.5: More on Matrix Inverses
In this section, we will prove three theorems which will clarify the concept of matrix inverses.
4.6: LU
An \(LU\) factorization of a matrix involves writing the given matrix as the product of a lower triangular matrix \(L\) which has the main diagonal consisting entirely of ones, and an upper triangular matrix \(U\) in the indicated order.
4.7: Determinants
Let A be an n×n matrix. That is, let A be a square matrix. The determinant of A, denoted by det(A) is a very important number which we will explore throughout this section.
4.8: Applications of the Determinant
The determinant of a matrix also provides a way to find the inverse of a matrix.
4.9: Eigenvalues and Eigenvectors of a Matrix
Spectral Theory refers to the study of eigenvalues and eigenvectors of a matrix. It is of fundamental importance in many areas and is the subject of our study for this chapter.
4.10: Diagonalization
When a matrix is similar to a diagonal matrix, the matrix is said to be diagonalizable.
4.11: Determinant Exercises
4.E: Exercises

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