Module Information | Study information

MODULE TITLE	Integral Equations	CREDIT VALUE	15
MODULE CODE	MTH3042	MODULE CONVENER	Prof Layal Hakim (Coordinator)

DURATION: TERM	1	2	3
DURATION: WEEKS	0	11	0

Number of Students Taking Module (anticipated)	150

DESCRIPTION - summary of the module content

Similarly to differential equations, integral equations provide an effective way to model real life situations, particularly those that arise in physics and engineering. Using certain techniques, many initial and boundary value problems can be converted to integral equations where the unknown function lies in the integrand. This module will introduce you to the mathematics of integral equations, techniques of analysing such equations, and methods of solving them, analytically or numerically.

The module MTH2003 is prerequisite for this. MTH2001 or MTH2008 are highly recommended.

AIMS - intentions of the module

Following the introduction integral equations, you will be introduced to a large class of integral equations. Volterra integral equations and Fredholm integral equations will be explained and methods on how to solve these equations will be described for cases of having integral equations of the first kind and the second kind, as well as looking at homogeneous and nonhomogeneous equations. Examples, that model real life problems, will be given and solutions will be interpreted.

INTENDED LEARNING OUTCOMES (ILOs) (see assessment section below for how ILOs will be assessed)

On successful completion of this module you should be able to:

Module Specific Skills and Knowledge:

1. Classify integral equations;

2. Define the Laplace transform and implement its use to solve integral equations;

3. Explicitly solve several classes of integral equations, both analytically and numerically;

4. Deploy the analysis of integral equations;

5. Illustrate the use of integral equations to model real life problems.

Discipline Specific Skills and Knowledge:

6. Analyse qualitative information about the solution;

7. Develop further the ability of problem structuring, problem solving, and logical thinking;

8. Assemble the necessary parts of a proof that form a final result by a chain of reasoning.

Personal and Key Transferable / Employment Skills and Knowledge:

9. Describe real life applications using integral equations through examples and exercises;

10. Build the ability to identify which techniques are suitable for which problems;

11. Communicate ideas effectively by learning the analysis of integral equations.

SYLLABUS PLAN - summary of the structure and academic content of the module

Classification of integral equations:

- Linear/nonlinear, Fredholm/Volterra, homogeneous/inhomogeneous, first/second kind.

Structure of kernels:

- convolution/non-convolution type, separable kernels, finite rank kernels, and weakly singular kernels.

Laplace transforms:

- An introduction to Laplace transforms with a focus on integral equations with a convolution type kernel;

- When to use, and how to obtain, the inverse Laplace transform.

Linear integral equations:

- Conditions under which the solutions to first and second kind integral equations exist;

- Linear operators and The Fredholm Alternative;

- Methods of obtain the exact and numerical solutions to Fredholm and Volterra integral equations;

- Bounded linear integral operators and how to find the bound using norms of integral operators;

- Iterative techniques, particularly the Neumann iteration method, for second kind equations;

- Approximation techniques using Taylor series;

- Analysis of integral equations: criteria for convergence; existence and uniqueness of solutions; continuity of integral operators;

- The Fredholm Theorem and its proof, the Herbert-Shmidt Theorem for self-adjoint kernels and its proof;

- Error estimates in the numerical solution;

- Nonlinear integral equations: Methods of obtaining solutions to simple cases of the Fredholm integral equation of the Hammerstein type;

- Applications to where integral equations are used to model the behaviour of real life problems.

LEARNING AND TEACHING

LEARNING ACTIVITIES AND TEACHING METHODS (given in hours of study time)

Scheduled Learning & Teaching Activities	33	Guided Independent Study	117	Placement / Study Abroad	0

DETAILS OF LEARNING ACTIVITIES AND TEACHING METHODS

Category	Hours of study time	Description
Scheduled Learning & Teaching Activities	28	Lectures
Scheduled Learning & Teaching Activities	5	Tutorials
Guided Independent Study	117	Independent reading and problem solving

ASSESSMENT

FORMATIVE ASSESSMENT - for feedback and development purposes; does not count towards module grade

Form of Assessment	Size of Assessment (e.g. duration/length)	ILOs Assessed	Feedback Method
Exercise sheets	5 x 10 hours	1-11	The lecturer will discuss problems during tutorials. Solutions to the sheets will be uploaded onto the VLE at some point after the tutorial.

SUMMATIVE ASSESSMENT (% of credit)

Coursework	20	Written Exams	80	Practical Exams	0

DETAILS OF SUMMATIVE ASSESSMENT

Form of Assessment	% of Credit	Size of Assessment (e.g. duration/length)	ILOs Assessed	Feedback Method
Coursework 1- based on questions submitted for assessment	10	10 hours	1-11	Annotated script and written/verbal feedback
Coursework 2- based on questions submitted for assessment	10	10 hours	1-11	Annotated script and written/verbal feedback
Written Exam – closed book	80	2 hours	1-11	Written/verbal on request, SRS

DETAILS OF RE-ASSESSMENT (where required by referral or deferral)

Original Form of Assessment	Form of Re-assessment	ILOs Re-assessed	Time Scale for Re-assessment
Written Exam	Written Exam (2 hours)	1-11	Referral/deferral period
Coursework 1	Coursework 1	1-11	Referral/deferral period
Coursework 2	Coursework 2	1-11	Referral/deferral period

RE-ASSESSMENT NOTES

Deferral – if you have been deferred for any assessment, you will be expected to complete relevant deferred assessments as determined by the Mitigation Committee. The mark given for re-assessment taken because of deferral will not be capped and will be treated as if it were your first attempt at the assessment.

Referral – if you have failed the module overall (i.e. a final overall module mark of less than 40%) you will be required to undertake re-assessments as described in the table above for any of the original assessments that you failed. The mark given for a re-assessment taken because of referral will be capped at 40%.

RESOURCES

INDICATIVE LEARNING RESOURCES - The following list is offered as an indication of the type & level of
information that you are expected to consult. Further guidance will be provided by the Module Convener

Web based and electronic resources:

ELE

Reading list for this module:

Type	Author	Title	Edition	Publisher	Year
Set	RP Kanwal	Linear Integral Equations	2nd ed.	Birkhauser, Boston	1997
Set	AC Pipkin	A Course on Integral Equations		Springer-Verlag, New York	1991
Set	BJ Moiseiwitsch	Integral Equations		Longman, London	1977
Set	D Porter	Integral Equations. A practical treatment, from Spectral Theory to Applications		DSG, Stirling, CUP	1990

CREDIT VALUE	15	ECTS VALUE	7.5

PRE-REQUISITE MODULES	MTH2003
CO-REQUISITE MODULES

NQF LEVEL (FHEQ)	6	AVAILABLE AS DISTANCE LEARNING	No
ORIGIN DATE	Tuesday 12th March 2024	LAST REVISION DATE	Wednesday 13th March 2024

KEY WORDS SEARCH	Integral equations; Volterra integral equations; Fredholm integral equations; Laplace transforms

Integral Equations - 2024 entry