2019/20 Taught Postgraduate Module Catalogue
MATH5211M Metric Spaces and Functional Analysis
20 creditsClass Size: 40
Module manager: Professor Alexander Strohmaier
Taught: Semester 1 View Timetable
Year running 2019/20
Pre-requisite qualificationsMATH2016, or MATH2017, or equivalent.
This module is mutually exclusive with
|MATH3211||Metric and Function Spaces|
This module is not approved as an Elective
Module summaryThe notion of a metric space is a fundamental and extremely important one in mathematics. A metric space is a space with a notion of a distance between points. This includes for example subsets of real or complex Euclidean space, but also spaces of functions or more general sets can be made into metric spaces.The notion of a distance allows one to talk about convergence and completeness of a space. It also makes it possible to talk about continuity for functions in a more general context. For example, to view the space of continuous functions on an interval of the real line as a metric space turns out to be surprisingly useful. To illustrate this, we will use a simple result on metric spaces to establish one of the major theorems in the theory of ordinary differential equations. We will also derive and discuss two major theorems in real Analysis: the inverse and implicit function theorems.This module develops the theory of metric spaces with focus on applications in real Analysis. As part of this module integration and measure theory will be developed and linked to the theory of metric spaces.
ObjectivesOn completion of this module, students should be able to:
- Verify the axioms of a metric space for a range of examples and identify open sets and closed sets
- Handle convergent sequences and continuous functions in an abstract context and apply them to specific function spaces
- Work with Lebesgue integration theory
- Use the contraction mapping theorem to find approximate solutions of equations and differential equations
- Rewrite equations such as inverse functions as fixed point problems and solve them using the contraction mapping theorem
- Work with the notions of connectedness and compactness in abstract and concrete contexts
- Construct the Lebesgue integral by the process of completion
- Demonstrate a broad understanding of the concepts, information, practical competencies and techniques of the theory of metric spaces and measure theory.
- Appreciate the coherence, logical structure and broad applicability of the theory of complete metric spaces and measure theory.
- Use metric spaces, fixed point theory, and the Lebesgue measure to initiate and undertake problem solving.
- Solve advanced mathematical problems using the theory of complete metric spaces, fixed point theory, and measure theory.
(1) Definition and fundamental properties of a metric space. Open sets, closed sets, closure and interior. Convergence of sequences. Continuity of mappings.
(2) Cauchy sequences, completeness of R with the standard metric; uniform convergence and completeness of C[a,b] with the uniform metric, convergence in Ck[a,b].
(3) Completeness of Rn with the standard metric. For a compact set K in Rn uniform convergence and completeness of C(K) with the uniform metric, convergence in Ck(K).
(4) Measure spaces
(5) The Lebesgue measure and its properties. The space L1 as a completion.
(6) The contraction mapping theorem, with applications: the Picard-Lindelöf theorem, the inverse and implicit function theorems in higher dimension.
(7) Connectedness and path-connectedness. Introduction to compactness and sequential compactness, including subsets of Rn.
(8) Banach spaces, the Baire category theorem and applications to function spaces
|Delivery type||Number||Length hours||Student hours|
|Private study hours||156.00|
|Total Contact hours||44.00|
|Total hours (100hr per 10 credits)||200.00|
Private studyStudying and revising of course material. Completing of assignments and assessments.
Opportunities for Formative FeedbackRegular exercise sheets
Methods of assessment
|Exam type||Exam duration||% of formal assessment|
|Standard exam (closed essays, MCQs etc)||3 hr 00 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 listThere is no reading list for this module
Last updated: 20/03/2018
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