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Applied Linear Algebra 2

This is the courseware for MATH 225: Applied Linear Algebra 2 at the University of Waterloo.

Topics include a continued discussion on vector spaces. Linear transformations and matrices are examined more fully. Inner products, eigenvalues and eigenvectors, and diagonalization are introduced and disucssed. Applications to linear algebra are also examined.

Units

Vector Spaces

In this module, we take the basic properties of Rⁿ and create an object called a vector space. We then look at how the familiar concepts of subspace, span, linear independence, and basis behave in general vector spaces. Examples from Rⁿ, matrices, and the newly introduced polynomial spaces are used throughout these discussions.

Lesson: A Review of Vectors in \( \mathbb{R}^n \)

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Lesson: A Review of Matrices

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Lesson: Addition and Scalar Multiplication of Polynomials

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Lesson: Span and Linear Independence in Polynomials

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Lesson: Vector Spaces

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Lesson: Subspaces

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Lesson: Span and Linear Independence in Vector Spaces

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Lesson: Bases

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Lesson: Obtaining a Basis from an Arbitrary Finite Spanning Set

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Lesson: Dimension

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Lesson: Extending a Linearly Independent Subset to a Basis

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Lesson: Coordinates

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Lesson: The Change of Coordinates Matrix

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Lesson: Linear Mappings

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Lesson: Range and Nullspace

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Lesson: The Rank-Nullity Theorem

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Lesson: The Matrix of a Linear Mapping

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Lesson: Change of Coordinates and Linear Mappings

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Lesson: Isomorphisms of Vector Spaces

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Lesson: Solving Span and Linear Independence Problems

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Orthonormal Bases

In this module, we explore some properties of the “standard basis” for our known vector spaces, and generalize this to the idea of an orthonormal basis. We will learn the Gram-Schmidt procedure for finding an orthonormal basis, and will end by generalizing the idea of an orthonormal basis even further by generalizing the idea of the dot product in Rⁿ to the concept of an inner product.

Complex Vector Spaces

In this module, we expand our study of vector spaces by changing the numbers used for scalars from the real numbers to the complex numbers. We start with an introduction to the complex numbers, and then begin to look at the vector space Cⁿ. The topics of subspace, span, linear independence, and basis will be discussed in this setting, as well as orthonormal bases and inner product spaces. We also learn how to use complex numbers to diagonalize matrices from the real numbers.