Vector 13 Week 4 Learning Goals
Here are the knowledge and skills you should master by the end of the fourth week.
13.1 Vector Spaces and the Determinant
I should be able to do the following tasks:
- Prove/disprove that a subset of a vector space is a subspace.
- Prove/disprove that a set of vectors is linearly dependent.
- Prove/disprove that a set of vectors span a vector space (or a subspace).
- Find the kernel and image of \(T(\mathsf{x}) = Ax\).
- Determine whether a set of vectors is a basis.
- Find a basis for \(\mathrm{Nul}(A)\) and a basis for \(\mathrm{Col}(A)\).
- Find the change-of-coordinate matrix \(P_{\mathcal{B}}\) from basis \({\mathcal{B}}\) to the standard basis \(\mathcal{S}\).
- Use matrix inverses (and RStudio) to find the change-of-coordinate matrix \(P_{\mathcal{B}}^{-1}\) from basis \({\mathcal{S}}\) to the standard basis \(\mathcal{B}\).
- Find the coordinate vector with respect to a given basis.
- Find the dimension of a vector space (or subspace) by finding or verifying a basis.
- Find the determinant of a \(2 \times 2\) matrix by hand.
- Find the determinant of a \(3 \times 3\) matrix by using row operations/cofactor expansion/permutation method.
- Use RStudio to calculate the determinant of a square matrix.
- Use \(\det(A)\) to decide whether the square matrix \(A\) is invertible.
13.2 Vocabulary
I should know and be able to use and explain the following terms or properties.
- every one of these Important Definitions
- subspace
- null space and column space of a matrix
- kernel and image of a linear transformation
- basis
- coordinate vector with respect to a basis
- change-of-coordinates matrix
- the coordinate vector with respect to a basis
- the dimension of a vector space (or a subspace)
- determinant
13.3 Conceptual Thinking
I should understand and be able to explain the following concepts:
- A vector space consists of a collection of vectors and all of their linear combinations.
- A subspace is a subset of a vector space that is also a vector space by itself (closed under linear combinations).
- The solutions to \(A \mathsf{x} = \mathbb{0}\) form a subspace.
- The span of the columns of \(A\) form a subspace.
- How the kernel and image of \(T(\mathsf{x}) = Ax\) correspond to the nullspace and columnspace of \(A\).
- Every basis of a given vector space (or subspace) contains the same number of vectors.
- Why every vector in a vector space has a unique representation as a linear combination of a given basis \({\mathcal{B}}\).
- How dimension relates to span and linear independence.
- Interpret \(\det(A)\) as a measure the expansion/contraction of “volumes” in \(\mathbb{R}^n\) under the linear transformation \(T(\mathsf{x})=A\mathsf{x}\).