BSc Mathematics with Mathematical Physics

advertisement
PROGRAMME SPECIFICATION
PROGRAMME SPECIFICATION
Programme title:
Mathematics with Mathematical Physics
Final award (BSc, MA etc):
BSc
(where stopping off points exist they should be
detailed here and defined later in the document)
UCAS code:
G1F3
(where applicable)
Cohort(s) to which this programme
specification is applicable:
Intakes from 2000
(e.g. from 2015 intake onwards)
Awarding institution/body:
University College London
Teaching institution:
University College London
Faculty:
Mathematical and Physical Sciences
Parent Department:
Mathematics
(the department responsible for the administration of
the programme)
Departmental web page address:
http://www.ucl.ac.uk/maths/
(if applicable)
Method of study:
Full time
Full-time/Part-time/Other
Criteria for admission to the
programme:
See:
http://www.ucl.ac.uk/maths/prospective-students/undergraduates
Length of the programme:
3 years
(please note any periods spent away from UCL, such
as study abroad or placements in industry)
Level on Framework for Higher
Education Qualifications (FHEQ)
(see Guidance notes)
Relevant subject benchmark statement
(SBS)
Advanced Level (Level 6)
Mathematics
(see Guidance notes)
Brief outline of the structure of the
programme
and
its
assessment
methods:
See: http://www.ucl.ac.uk/maths/prospectivestudents/undergraduates/degree-programmes
(see guidance notes)
Board of Examiners:
Professional body accreditation
(if applicable):
Name of Board of Examiners:
Mathematics
Date of next scheduled
accreditation visit:
EDUCATIONAL AIMS OF THE PROGRAMME:
To provide a three year degree programme for undergraduate students which is intellectually challenging and
rigorous as well as providing a qualification that will enable graduates to be well-placed to continue study for a
postgraduate qualification or to enter employment.
PROGRAMME OUTCOMES:
The programme provides opportunities for students to develop and demonstrate knowledge and understanding,
qualities, skills and other attributes in the following areas:
A: Knowledge and understanding
Knowledge and understanding of:
Teaching/learning methods and strategies:
1. Core topics in various branches of
advanced pure and applied
mathematics, particularly theoretical
physics.
Lectures, problem classes, tutorials and private study.
2. A range of optional advanced topics
in courses which are informed by the
scholarship and/or research interests
of the staff.
3. The application of critical and
analytical reasoning and the
presentation of logical and concise
arguments.
Assessment:
Written unseen examinations for all courses apart from
the totally computer-based courses that have project
based examinations. There is also an additional
coursework and/or project component to the
assessment for all core courses and most optional
courses.
B: Skills and other attributes
Intellectual (thinking) skills:
Teaching/learning methods and strategies:
1. Understanding sophisticated
mathematical arguments and rigorous
proofs.
2. Comprehension of high levels of
abstraction in pure mathematics.
Lectures, problem classes, tutorials and projects where
appropriate.
Assessment:
See above.
C: Skills and other attributes
Practical skills (able to):
Teaching/learning methods and strategies:
1. The assimilation and manipulation of
substantial bodies of knowledge.
Written presentations of solutions to problems set as
coursework and/or projects.
2. Apply physical insight and
mathematical techniques to the
solution of problems in applied
mathematics.
The accumulation of material necessary to write a report
on s project.
Written work produced under examination conditions.
3. Develop investigative skills required
for problem solving.
Assessment:
See above.
D: Skills and other attributes
Transferable skills (able to):
Teaching/learning methods and strategies:
1. Structure and communicate ideas
effectively.
2. Manage time and work to deadlines.
3. Work independently or within a group.
4. Develop self-confidence and reliance.
5. Use information technology and
retrieval systems in acquiring
investigative skills.
6. Assess the relevance and importance
of ideas and develop the ability to
identify the significant aspects in a
problem that is necessary in
mathematical modelling.
Courses with coursework and/or project work introduce
information that needs to be assessed critically.
Training in the presentation of logical and precise
arguments.
Contribute to Peer Assisted Learning programmes.
Encouragement to participate effectively in discussion
groups such as tutorials.
Assessment:
See above.
The following reference points were used in designing the programme:
 the Framework for Higher Education Qualifications
(http://www.qaa.ac.uk/en/Publications/Documents/Framework-Higher-Education-Qualifications-08.pdf);
 the relevant Subject Benchmark Statements (http://www.qaa.ac.uk/assuring-standards-and-quality/the-qualitycode/subject-benchmark-statements);
 the programme specifications for UCL degree programmes in relevant subjects (where applicable);
 UCL teaching and learning policies;
 staff research.
Please note: This specification provides a concise summary of the main features of the programme and the
learning outcomes that a typical student might reasonably be expected to achieve and demonstrate if he/she takes
full advantage of the learning opportunities that are provided. More detailed information on the learning outcomes,
content and teaching, learning and assessment methods of each course unit/module can be found in the
departmental course handbook. The accuracy of the information contained in this document is reviewed annually
by UCL and may be checked by the Quality Assurance Agency.
Programme Organiser(s)
Name(s):
Dr M L Roberts
Date of Production:
June 2003
Date of Review:
November 2014
Date approved by Head of
Department:
November 2014
Date approved by Chair of
Departmental Teaching
Committee:
Date approved by Faculty
Teaching Committee
November 2014
February 2015
APPENDIX
The Mathematics with Theoretical Physics BSc degree programme structure is summarised in the following
Table.
Year
1
2
Analysis
MATH1101/1102
Analysis 1 & 2 *
MATH 2101 Analysis 3:
Complex Analysis *
MATH 7102 Analysis 4: Real
Analysis
Algebra
MATH 1201/1202
Algebra 1 & 2 *
MATH 2201 Algebra 3: Further
Linear Algebra
MATH7112 Geometry and
Groups
MATH 7202 Algebra 4: Groups
and Rings
Applied
Mathematics
MATH 1301/1302
Applied
Mathematics 1 &
Newtonian
Mechanics *
MATH 1401/1402
Mathematical
Methods 1 & 2 *
MATH 2301 Fluid Mechanics *
MATH 7302 Analytic Dynamics
MATH7304 Electromagnetism
Methods
Probability and
Statistics
Numerical
Methods and
Programming
Number Theory
3
MATH 2401 Mathematical
Methods 3*
MATH 7402 Mathematical
Methods 4
MATH 7501 Probability and
Statistics
MATH 7601 Numerical
Computation
MATH 7701 Number Theory
Physics
PHAS2222 Quantum
Mechanics
Up to 1 unit
Outside Option
At most 1/2 unit
At most 1 unit
In the above table, * denotes a compulsory core course.
Years 1 and 2 are identical with the BSc Mathematics, except that students can choose Quantum Physics
instead of MATH2201 Further Linear Algebra
In Year 3 of the BSc programme, students are provided with a free choice from a wide range of options,
including a few selected courses given by the Departments of Statistical Science and Physics and may
also substitute two of their third year maths modules by Physics modules.
Up to one unit of "outside" options may also be taken.
Assessment includes a written unseen examination for each course except the too computer-based
courses. All core courses and some optional courses have a coursework component which contributes
10% to the total assessment mark. Some courses have a project that contributes to the assessment.
Download