The tutor's mark is made up from marks for answers to the assessed weekly problems (50%) and from work associated with five worksheets (50%). The worksheets cover some background mathematical material assumed by other modules. The material covered includes complex numbers, vectors, matrices, multiple integration and integration over surfaces and along contours.
To cover some background mathematical material assumed by other modules, to give students experience of learning by self-study, to develop the habit of keeping up with the problem sheets handed out in physics modules
This is an indicative module outline only to give an indication of the sort of topics that may be covered. Actual sessions held may differ.
Their construction from the reals; norm, argument, real and imaginary parts; addition, subtraction, multiplication and division; the Argand diagram and geometric view of complex numbers. de Moivre's theorem, exponential representation of a complex number in terms of its norm and its argument.
Vectors have magnitude and direction. Addition and subtraction, the null vector. Geometry of simple figures written in vector notation, equation of lines and planes, equation for centroid of a triangle. The dot product, the normal to a plane and alternative form for equations of planes, perpendiculars from points of a triangle to opposite sides meet at a point. Cross-product and the notion of an area in three dimensions as a vector. Equation of line of intersection of two planes. Triple scalar product, associative law, relation to volume of parallelopiped. Triple vector product
Motivation and definition. The 2 x 2 case: operations on vectors. Eigenvalues and eigenvectors. Diagonalizing matrices. Exponential of a diagonalizable matrix. Mention of the 3 x 3 and N x N cases.
Integration of functions of more than one variable. The domain of integration and changing the order of integration. Computing the mass of an object with variable density. Changing variables and the Jacobian with particular reference to the transformation cartesian to polar coordinates
Integration over Lines, Surfaces and Volumes:
Notation for integration of both scalar and vector quantities over lines, surfaces and volumes. Integration along lines using parameterised curves, circulation around a contour. Infinitesimal surface element as a vector in 3D, use to compute flux across a surface. Volume integrals and revision of the Jacobian.
You should answer the questions on each of the worksheets and hand in your answers to your personal tutors as directed.
Weekly Problem Sheets:
You will be asked to hand in written answers to designated problems from the problem sheets and attempt designated problems from the Mastering Physics package.
By the end of the module, students should be able to:
- Work with vectors, partial differentiation, multiple integration and integration over lines, surfaces and volumes at a level necessary to cope with all first year physics modules and to start the second year core module.
- Analyse a simple problem and decide on an approach to its solution
Subject specific skills
Mathematical techniques, physics problem-solving
Communication, group working, problem-solving, self-study
|Seminars||25 sessions of 1 hour (21%)|
|Tutorials||25 sessions of 1 hour (21%)|
|Private study||70 hours (58%)|
Private study description
Studying material on worksheets, answering associated questions. Working on weekly problem sheets and computer problems
No further costs have been identified for this module.
You do not need to pass all assessment components to pass the module.
Assessment group A1
Worksheets and examples sheets
Feedback on assessment
Personal tutorials and examples classes
This module is Core for:
- Year 1 of UPXA-FG33 Undergraduate Mathematics and Physics (BSc MMathPhys)
- Year 1 of UPXA-GF13 Undergraduate Mathematics and Physics (BSc)
- Year 1 of UPXA-FG31 Undergraduate Mathematics and Physics (MMathPhys)