# Module Information

#### Course Delivery

Delivery Type | Delivery length / details |
---|---|

Lecture | 19 Hours. (19 x 1 hour lectures) |

Seminars / Tutorials | 3 Hours. (3 x 1 hour example classes) |

#### Assessment

Assessment Type | Assessment length / details | Proportion |
---|---|---|

Semester Exam | 2 Hours (written examination) | 100% |

Supplementary Assessment | 2 Hours (written examination) | 100% |

### Learning Outcomes

On completion of this module, a student should be able to:

1. determine whether given algebraic structures are vector spaces;

2. apply criteria for subspaces of a vector space;

3. determine bases for vector spaces;

4. prove and apply propositions in the theory of vector spaces;

5. describe the concept of linear transformation;

6. calculate matrices representing linear transformations;

7. determine the rank and nullity of linear transformations and matrices;

8. perform calculations in inner product spaces;

9. diagonalise matrices, especially symmetric matrices, and draw inferences concerning the geometrical context.

### Brief description

In this module the concept of a vector space is introduced. This develops some ideas which have occurred in the first year courses. It will be seen that superficially different problems in mathematics can be unified. For example, the solution of systems of linear equations and linear differential equations are essentially the same process and can be dealt with simultaneously in this context.

### Aims

To develop some matrix theory techniques which have occurred in the first year courses in an abstract setting. To introduce the concepts of a vector space and a mapping between vector spaces. To develop further techniques for computation in vector spaces and to study some geometrical applications.

### Content

2. LINEAR TRANSFORMATIONS:Definition and exmples, the matrix of a linear transformation, change of basis. The kernel and image of a linear transformation, rank and nullity. The dimension theorem.

3. INNER PRODUCT SPACES: Definition and examples. Orthogonality and Gram-Schmidt orthogonalisation process.

4. DIAGONALISATION OF MATRICES: Eigenvalues and eigenvectors, characteristic equation. Diagonalisation of matrices.

### Reading List

**Recommended Text**

H Anton & C Rorres (2000) Elementary Linear Algebra, the applications version 8th J Wiley Primo search

**Supplementary Text**

A O Morris (1982) Linear Algebra - An Introduction 2nd Chapman & Hall Primo search D H Griffel Linear Algebra and its applications Vol. 1 & 2 Ellis Horwood Primo search Ph Gillett (1975) Introduction to Linear Algebra Houghton Mifflin Co. Primo search R B J T Allenby (1995) Linear Algebra Edward Arnold Primo search S I Grossman (1984) Elementary Linear Algebra 2nd Wadsworth Primo search T A Whitelaw (1983) An Introduction to Linear Algebra Blackie Primo search T S Blyth and E F Robertson (1998) Basic Linear Algebra Springer Primo search

### Notes

This module is at CQFW Level 6