Contents

MATH 250 Linear Algebra

Students will develop skills in the basic concepts of linear algebra. These skills will cover areas such as vector spaces, systems of linear equations and matrices, determinants, similar matrices, diagonalizations, linear transformations, eigenvalues and eigenvectors, inner product spaces, quadratic forms, and complex vector spaces. Use of MATLAB, a computer algebra system, is required. Calculators are not permitted.

Credits

4

Prerequisite

MATH 181 or equivalent with a grade of C or higher

Hours Weekly

4 hours weekly

Course Objectives

  1. 1. Solve systems of linear equations using matrices with elementary row operations and determinant of a matrix.
  2. 2. Do basic vector arithmetic including calculating vector sums, differences, scalar products and inner products, and projections.
  3. 3. Use the basic rules of matrix arithmetic and algebra, and explore matrix LU factorizations.
  4. 4. Identify fundamental vector spaces and subspaces, find a basis for a vector space, and communicate mathematical reasoning symbolically, verbally, and in writing using proofs.
  5. 5. Find orthogonal and orthonormal bases using a Gram-Schmitz process, and coordinate vectors in general vector spaces.
  6. 6. Use concept of a linear transformation and apply it to geometry including matrix representations of linear transformations.
  7. 7. Use real/complex eigenvalues and eigenvectors to diagonalize/factor matrices.
  8. 8. solve applications dealing with quadratic forms.
  9. 9. Use MATLAB to solve problems, such as Markov Chains and Gram-Schmidt processes, and to complete projects.

Course Objectives

  1. 1. Solve systems of linear equations using matrices with elementary row operations and determinant of a matrix.
  2. 2. Do basic vector arithmetic including calculating vector sums, differences, scalar products and inner products, and projections.
  3. 3. Use the basic rules of matrix arithmetic and algebra, and explore matrix LU factorizations.
  4. 4. Identify fundamental vector spaces and subspaces, find a basis for a vector space, and communicate mathematical reasoning symbolically, verbally, and in writing using proofs.
  5. 5. Find orthogonal and orthonormal bases using a Gram-Schmitz process, and coordinate vectors in general vector spaces.
  6. 6. Use concept of a linear transformation and apply it to geometry including matrix representations of linear transformations.
  7. 7. Use real/complex eigenvalues and eigenvectors to diagonalize/factor matrices.
  8. 8. solve applications dealing with quadratic forms.
  9. 9. Use MATLAB to solve problems, such as Markov Chains and Gram-Schmidt processes, and to complete projects.