# 2020/21 Undergraduate Module Catalogue

## MATH3225 Topology

### 15 creditsClass Size: 101

**Module manager:** Prof. Paul Martin**Email:** P.P.Martin@leeds.ac.uk

**Taught:** Semester 2 (Jan to Jun) View Timetable

**Year running** 2020/21

### Pre-requisite qualifications

MATH2020 or MATH2022, or equivalent.**This module is not approved as a discovery module**

### Module summary

Topology is the study of those properties of a mathematical space which are unchanged by continuous deformations. Indeed, a topology is the minimal extra structure with which we must equip a set so that the idea of "continuity" makes sense in the first place. In this module we introduce topology in an abstract setting and show how it generalizes the familiar notion of continuity from calculus. We then study various topological invariants of spaces, such as connectedness, path connectedness, compactness and the Hausdorff property. The second half of the module is more algebraic: we describe how a certain group, called the fundamental group, can be associated to each topological space. This assignment has the beautiful property that continuous mappings between spaces naturally induce homomorphisms between their associated groups.### Objectives

On completion of this module, students should be able to:- Verify the axioms of a topological space for a range of examples and identify whether a space is Hausdorff, connected, path connected, compact;

- Determine whether a given map between topological spaces is continuous and construct homotopies between simple maps;

- Use topological invariants to prove that suitable pairs of spaces are not homeomorphic;

- Compute the fundamental group of a simple space using Van Kampen's Theorem;

- Determine the induced homomorphism of fundamental groups induced by a suitable continuous map.

### Syllabus

- Review of set notation; indexed collections of sets, their union and intersection;

- Topological spaces: axioms, the usual topology on R, the Hausdorff property, closed sets, continuity, the Glue Lemma;

- New spaces from old: the subspace, product and quotient topologies;

- Topological invariants: connectedness, path connectedness, compactness, Tychonoff's Theorem, the Heine-Borel Theorem for R;

- Homotopy: homotopic maps, homotopy equivalence of spaces, deformation retractions;

- The fundamental group: defintion, the fundamental group of a product, the fundamental group of a circle (statement only)

- The induced homomorphism of a continuous map: definition, contravariance, deformation retractions induce isomorphisms;

- Free products of groups, Van Kampen's Theorem (statement only), computation of fundamental groups of simple spaces (e.g. wedge sums, finite graphs, Polygons with egde identification).

### Teaching methods

Due to COVID-19, teaching and assessment activities are being kept under review - see module enrolment pages for information

Delivery type | Number | Length hours | Student hours |

Lecture | 17 | 1.00 | 17.00 |

Private study hours | 133.00 | ||

Total Contact hours | 17.00 | ||

Total hours (100hr per 10 credits) | 150.00 |

### Private study

Studying and revising of course material.Completing of assignments and assessments.

### Opportunities for Formative Feedback

Regular exercise sheets.### Methods of assessment

Due to COVID-19, teaching and assessment activities are being kept under review - see module enrolment pages for information

**Exams**

Exam type | Exam duration | % of formal assessment |

Open Book exam | 2 hr 30 mins | 100.00 |

Total percentage (Assessment Exams) | 100.00 |

Normally resits will be assessed by the same methodology as the first attempt, unless otherwise stated

### Reading list

The reading list is available from the Library websiteLast updated: 11/09/2020 12:32:18

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- Undergraduate module catalogue
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- Undergraduate programme catalogue
- Taught Postgraduate programme catalogue

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