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6: Vector Spaces

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Building on the work on \(\mathbb{R}^n\) in Chapter 5, the basic theory of abstract finite dimensional vector spaces is developed emphasizing new examples like matrices, polynomials and functions. This is the first acquaintance most students have had with an abstract system, so not having to deal with spanning, independence and dimension in the general context eases the transition to abstract thinking. Applications to polynomials and to differential equations are included.

6.1: Prelude to Vector Spaces
6.2: Examples and Basic Properties
This page provides an overview of vector spaces, outlining their definition, operations, and axioms. Vectors, which can include diverse objects like matrices and polynomials, must satisfy specific properties for vector space qualification. The significance of polynomials and functions as vector spaces is highlighted, alongside concepts of vector subtraction, scalar multiplication, and simplification of expressions. The zero vector space is also defined, confirming it meets vector space criteria.
- 6.2E: Examples and Basic Properties Exercises
6.3: Subspaces and Spanning Sets
This page covers the concept of subspaces in vector spaces, detailing the criteria for a subset to qualify as a subspace, including closure under addition and scalar multiplication. It discusses specific examples such as polynomial spaces and differentiable functions as subspaces, while introducing the idea of spans.
- 6.3E: Subspaces and Spanning Sets Exercises
6.4: Linear Independence and Dimension
This page covers linear independence, dependence, and the concept of dimension in vector spaces. It defines linear independence in terms of trivial solutions in linear combinations and presents examples, alongside properties of independent sets. The Fundamental Theorem establishes limits on the size of linearly independent sets, while the Invariance Theorem implies that all bases for a vector space have the same number of vectors, defining its dimension.
- 6.4E: Linear Independence and Dimension Exercises
6.5: Finite Dimensional Spaces
This page covers key concepts in vector space theory, including basis, dimension, and linear independence. It emphasizes that finite-dimensional vector spaces can be constructed from independent subsets and discusses methods to form bases, including examples from polynomial and matrix spaces. The pages also explore properties of vector space sums and direct sums, establishing the relationship between subspaces and their dimensions.
- 6.5E: Finite Dimensional Spaces Exercises
6.6: An Application to Polynomials
This page covers the vector space of polynomials of degree at most \(n\), \(\mathbf{P}_{n}\), highlighting its dimension of \(n + 1\) and basis formed by polynomials of distinct degrees. It introduces key theorems for polynomial factorization and expansion, and discusses Taylor's Theorem for determining polynomial coefficients.
- 6.6E: An Application to Polynomials Exercises
6.7: Linear Transformations of Vector Spaces
This page covers linear transformations \(T: V \to W\), outlining their defining properties, such as preserving vector addition and scalar multiplication, and the concept of linear operators. It details key attributes like the preservation of the zero vector and linear combinations, establishing criteria for equality of transformations based on their action on a spanning set.
- 6.7E: Examples and Elementary Properties Exercises
6.8: Kernel and Image of a Linear Transformation
This page covers essential aspects of linear transformations, focusing on the kernel and image. The kernel identifies vectors mapping to zero, while the image reflects the outputs from these transformations. It discusses properties of one-to-one (trivial kernel) and onto (complete image) transformations, the Dimension Theorem linking dimensions (nullity + rank), and verifying polynomial evaluation mappings.
- 6.8E: Kernel and Image of a Linear Transformation Exercises
6.E: Supplementary Exercises for Chapter 6
This page covers linear independence of functions using the Wronskian determinant, stating that three functions are linearly independent if their Wronskian is nonzero at a point. It also examines an invertible \( n \times n \) matrix \( A \), discussing its implications on the basis of \( \mathbb{R}^n \), as well as the connections between a matrix's column space, rank, and nullity.

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