|| MA13310 |
|| MATHEMATICAL TECHNIQUES FOR COMPUTER SCIENCE |
|| 2004/2005 |
|| Professor Tim Phillips |
|| Intended for use in future years (Taught over 2 semesters) |
|Next year offered
|| N/A |
|Next semester offered
|| N/A |
|| CS12220 or CS12320, CS12420. May also be taken as part of the first year of the Ordinary Degree in Mathematics. |
| Course delivery
|| Lecture || 22 x 1 hour lectures |
|| Practical || 11 x 1 hour workshops |
|Assessment Type||Assessment Length/Details||Proportion|
|Semester Exam||2 Hours ||50%|
|Semester Assessment|| Course Work: 2 assessed workshops. ||50%|
|Supplementary Assessment||2 Hours Continuous assessment passed: same format as above; otherwise 2-hour written examination (as above). ||100%|
On completion of this module, a student should be able to:
describe some number systems;
explain how different types of numbers can be represented in computers;
compute with sets, relations, functions and the rates of growth of functions;
determine properties of sequences and series;
perform computations in propositional and predicate calculus.
This module covers the bulk of the mathematical prerequisites for the first two years of honours degree courses in Computer Science and Software Engineering. It provides a basic introduction to number systems, sets and relations, rates of growth of functions, mathematical induction, sequences and series, and propositional and predicate calcutus. The material is presented in an accessible manner and draws on examples from computer science to emphasise the importance of the concepts introduced. No prior mathematical knowledge, beyond GCSE level, is assumed.
To provide the mathematical prerequisites for modules in the first two years of the honours degree courses in Computer Science and Software Engineering.
1. NUMBER SYSTEMS: Natural numbers, integers, rational numbers, real numbers. Radix r representation of integers: change of radix, representing negative and rational numbers, twos complement and computational arithmetic.
2. PROPOSITIONAL CALCULUS: Formulae, semantics, truth tables. Notions of tautology, validity, contradiction, satisfaction, equivalence and consequence. De Morgan's law. Disjunctive normal form, conjunctive normal form.
3. DIGITAL LOGIC GATES: Design and analysis.
4. PREDICATE CALCULUS: Terms and formulae, quantification, semantics.
5. SETS AND RELATIONS: Basic notation, Venn diagrams, ordered sequences, relations. Functions.
6. RATES OF GROWTH OF FUNCTIONS: Polynomials, logarithms and exponentials, and factorials.
7. SEQUENCES AND SERIES: The concepts of a sequence, a series. An application to computer science.
** Recommended Text
J K Truss (1999) Discrete Mathematics for Computer Sciences
2nd. Addison-Wesley 0201360616
R P Grimaldi (1999) Discrete and Combinatorial Mathematics
4th. Addison-Wesley 0201304244
This module is at CQFW Level 4