Programme Specification
Undergraduates Physics Programmes
Academic Year: 2014/15
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 full advantage is taken of the learning opportunities that are provided.
This specification applies to delivery of the programme in the Academic Year indicated above. Prospective students reviewing this information for a later year of study should be aware that these details are subject to change as outlined in our Terms and Conditions of Study.
This specification should be read in conjunction with:
- Reg. XX (Undergraduate Awards) (see University Regulations)
- Module Specifications
- Summary
- Aims
- Learning outcomes
- Structure
- Progression & weighting
Programme summary
Awarding body/institution | Loughborough University |
Teaching institution (if different) | |
Owning school/department | Department of Physics |
Details of accreditation by a professional/statutory body | Institute of Physics |
Final award | BSc/ BSc+DIS/BSc+DInts/MPhys/MPhys+DIS/MPhys+DIntS |
Programme title | Physics, Engineering Physics, Physics with Cosmology/Physics with Astrophysics and Cosmology, Physics and Mathematics, Sport Science and Physics, Physics and Management, Physics with Sport Science |
Programme code | See Programme Structure |
Length of programme | |
UCAS code | See Programme Structure |
Admissions criteria | http://www.lboro.ac.uk/departments/physics/undergraduate/courses/ |
Date at which the programme specification was published | Mon, 29 Sep 2014 09:55:31 BST |
1. Programme Aims
PH BSc & Mphys | EngPH BSc & Mphys | PHMA BSc & Mphys | PHCos BSc & Mphys | PH w AstroCos BSc & Mphys | SS&PH BSc | Ph w SS BSc & Mphys | Ph w Man BSc | |
Formulate problems in precise terms and identify key issues, construct logical arguments and use technical language correctly. | x | x | x | x | x | x | x | x |
To enable students to apply a broad understanding of the basic principles of physics to the solution of physical problems. | x | x | x | x | x | x | x | x |
To enhance students' skills in mathematics, problem solving, experimental techniques, scientific report writing and the collection and analysis of information. | x | x | x | x | x | x | x | x |
To enhance students' skills in presenting information and the use of information technology. | x | x | x | x | x | x | x | x |
To provide an environment that gives students opportunities to develop their own interests, self-reliance and career aspirations. | x | x | x | x | x | x | x | x |
To educate students as physicists in preparation for employment in industry, public service or academic research by providing the knowledge, competence and skills expected of a physicist. | x | x | x | x | x | x | x | x |
To prepare students for the transition to a career as a professional physicist | Mphys only | |||||||
To provide students with a sound grounding in chosen aspects of engineering related to physics | x | |||||||
To provide students with a solid foundation of the core areas of mathematics and allow students to further their own mathematical interests through module selection. | x | |||||||
To provide a sound mathematics and physics based intellectual education appropriate to the needs of society | x | |||||||
To educate students as physicists and mathematicians in preparation for employment in industry, public service or academic research by providing the knowledge, competence and skills expected of a mathematical physicist | x | |||||||
The programme aims to provide a Physics core with additional modules that develop the students’ knowledge and understanding of Astrophysics and Cosmology | x | x | ||||||
To develop knowledge, understanding and skills in core sport sciences | x | x | ||||||
To provide students with selected specialised areas of study so that they experience the frontiers of research in sports science | x | x | ||||||
To provide students with a sound understanding of the main functions of management and how they integrate into overall business planning and management | x |
2. Relevant subject benchmark statements and other external reference points used to inform programme outcomes:
- The national benchmark statement for Physics.
- Institute of Physics degree accreditation guidelines.
- University Teaching and Learning Strategy.
- Framework for Higher Education Qualifications.
3. Programme Learning Outcomes
3.1 Knowledge and Understanding
On successful completion of this programme, students should be able to demonstrate knowledge and understanding of: | PH BSc & MPhys | EngPH BSc & MPhys | PHMA BSc & MPhys | PHCos BSc & MPhys | PH w AstroCos BSc & Mphys | SS&PH BSc | Ph w SS BSc & Mphys | Ph w Man |
K1 | x | x | x | x | x | x | x | x |
Knowledge and understanding of most fundamental physical laws and principles and competence in the application of these principles to diverse areas of physics | ||||||||
K2 | x | x | x | x | x | x | x | x |
An ability to identify physical principles relevant to a problem and to make approximations necessary to obtain solutions | ||||||||
K3 | x | x | x | x | x | x | x | x |
An ability to execute and analyse critically the results of an experimental investigation and to draw valid conclusions with an estimate of the uncertainty in the result. The ability to critically compare experimental results with the predictions of theory | ||||||||
K4 | x | x | x | x | x | x | x | x |
Knowledge of the primary mathematical methods for the analysis of physical problems | ||||||||
K5 | x | x | x | x | x | x | x | x |
An ability to solve problems in physics using appropriate mathematical tools | ||||||||
K6 | x | x | x | x | x | x | x | x |
An ability to communicate scientific information especially in the form of clear and accurate scientific reports | ||||||||
K7 | x | x | x | x | x | |||
An ability to use competently IT packages and knowledge of computer programming | ||||||||
K8 | MPhys Only | MPhys only | MPhys only | MPhys only | MPhys only | |||
Knowledge of the fundamental principles and applications of some advanced areas of physics or astrophysics at, or informed by, the forefront of the discipline | ||||||||
K9 | MPhys Only | MPhys only | MPhys only | MPhys only | MPhys only | MPhys only | ||
An ability to use competently advanced experimental techniques, theoretical and/or computer modelling to tackle an advanced problem and to interpret results obtained | ||||||||
K10 | x | |||||||
Knowledge and understanding of the general engineering principles and the particular problems of application in the chosen subject area | ||||||||
K11 | x | |||||||
Knowledge of the primary mathematical methods for the analysis of physical and engineering problems | ||||||||
K12 | x | |||||||
An ability to identify physical principles relevant to a physics or engineering problem and to make approximations necessary to obtain solutions | ||||||||
K13 | MPhys only | |||||||
Knowledge and understanding of a number of specialist engineering science disciplines in greater depth than is normally associated with a first degree award | ||||||||
K14 | BSc only | |||||||
An understanding of core concepts in mathematics | ||||||||
K15 | BSc only | |||||||
Knowledge and understanding of a range of analytical, numerical and qualitative mathematical techniques | ||||||||
K16 | x | |||||||
An ability to use competently IT packages and a knowledge of the use of mathematical software in problem solving | ||||||||
K17 | x | x | ||||||
Knowledge and understanding of most fundamental physical laws and principles and competence in the application of these principles to diverse areas of physics, astrophysics and cosmology | ||||||||
K18 | x | x | ||||||
An ability to solve problems in physics, astrophysics and cosmology using appropriate mathematical tools | ||||||||
K19 | x | x | ||||||
Understanding of core sports science from both a theoretical and practical perspective | ||||||||
K20 | x | x | ||||||
Knowledge of the techniques required for a range of sports | ||||||||
K21 | x | x | ||||||
Understanding of the tactical/strategic factors involved in sport | ||||||||
K22 | x | |||||||
An ability to apply competently computer software for the solution of physics and business problems | ||||||||
K23 | x | |||||||
Knowledge of the foundational disciplines of management, including economics, business mathematics and statistics | ||||||||
K24 | x | |||||||
An understanding of Business Finance and Financial Reporting |
3.2 Skills and other attributes
a. Subject-specific cognitive skills:
On successful completion of this programme, students should be able to: | PH BSc & MPhys | EngPH BSc & Mphys | PHMA BSc & MPhys | PHCos BSc & MPhys | PH w AstroCos BSc & MPhys | SS&PH BSc | PH w SS BSc & Mphys |
C1 | x | x | x | x | x | x | x |
Recognise and analyse novel problems and plan strategies for their solution | |||||||
C2 | x | x | x | x | x | x | x |
Evaluate, interpret and collate information and data | |||||||
C3 | x | x | x | x | x | x | x |
Use mathematics to describe the physical world, selecting appropriate equations, constructing mathematical models, interpreting results and, where appropriate, critically comparing them with experiment and observation | |||||||
C4 | BSc only | BSc only | BSc only | BSc only | BSc only | x | BSc only |
Apply appropriate knowledge and understanding to the solution of qualitative and quantitative problems of a familiar and unfamiliar nature | |||||||
C5 | MPhys only | MPhys only | MPhys only | MPhys only | MPhys only | MPhys only | |
Apply appropriate knowledge and understanding to the solution of qualitative and quantitative problems of a familiar and unfamiliar nature some of which are close to the forefront of the discipline | |||||||
C6 | x | ||||||
Demonstrate knowledge and understanding of essential facts, concept, principles and theories relating to areas of physics and engineering | |||||||
C7 | x | ||||||
The ability to construct logical mathematical and physical arguments | |||||||
C8 | x | ||||||
The ability to select appropriate mathematical tools to model the behaviour of the physical world |
b. Subject-specific practical skills:
On successful completion of this programme, students should be able to: | PH BSc & MPhys | EngPH BSc & MPhys | PHMA BSc & MPhys | PHCos BSc & MPhys | PH w AstroCos BSc & Mphys | SS&PH BSc | Ph w SS BSc & Mphys | Ph w Man |
P1 | x | x | x | x | x | x | x | x |
Observe, accurately record and analyse, including estimates of accuracy, the results of experiments into physical processes | ||||||||
P2 | x | x | x | x | x | x | x | x |
Communicate ideas effectively by means of written reports and orally | ||||||||
P3 | x | x | x | x | x | x | x | x |
Draw valid conclusions from results obtained through experiment or investigation and compare these with expected outcomes or published data | ||||||||
P4 | x | BSc only | x | x | x | x | x | |
Apply appropriate mathematical or computing tools to a physical problem | ||||||||
P5 | BSc only | BSc only | BSc only | BSc only | BSc only | x | BSc only | x |
Plan and execute, under supervision, a research project on a topic of current scientific and/or engineering interest | ||||||||
P6 | MPhys only | MPhys only | MPhys only | MPhys only | MPhys only | MPhys only | ||
Under supervision, plan and execute a research project on a topic close to the frontiers of knowledge | ||||||||
P7 | MPhys only | MPhys only | MPhys only | MPhys only | MPhys only | |||
Show competence in the use of advanced experimental equipment | ||||||||
P8 | x | |||||||
Apply appropriate mathematical or computational tools to a physical or engineering problem | ||||||||
P9 | MPhys only | |||||||
Apply appropriate mathematical or computing tools to an advanced physical problem | ||||||||
P10 | MPhys only | |||||||
Relate mathematics to physical processes, and thus obtain quantitative and qualitative information about the real world | ||||||||
P11 | x | x | ||||||
Analyse skills, techniques and tactics in sport | ||||||||
P12 | x | x | ||||||
Demonstrate practical skills relevant to a range of core sports | ||||||||
P13 | x | x | ||||||
Show skills specific to their chosen specialist area of sports science | ||||||||
P14 | x | |||||||
Prepare and interpret financial reports | ||||||||
P15 | x | |||||||
Show the relationship between the business context and financial reporting | ||||||||
P16 | x | |||||||
Apply techniques for understanding and managing people at work | ||||||||
P17 | x | |||||||
Apply the principles of marketing and the role of marketing management |
c. Key transferable skills:
On successful completion of this programme, students should be able to: | PH BSc & MPhys | EngPH BSc & MPhys | PHMA BSc & MPhys | PHCos BSc & MPhys | PH w AstroCos BSc & MPhys | SS&PH BSc | PhwSS BSc & MPhys | Ph w Man |
T1 | x | x | x | x | x | x | x | x |
Formulate problems in precise terms and identify key issues, construct logical arguments and use technical language correctly | ||||||||
T2 | x | x | x | x | x | x | x | x |
Communicate ideas concisely, accurately and informatively using both written and oral means | ||||||||
T3 | MPhys only | MPhys only | MPhys only | MPhys only | MPhys only | MPhys only | ||
Communicate complex scientific ideas concisely, accurately and informatively using both written and oral means | ||||||||
T4 | x | x | x | x | x | |||
Use standard IT packages and write computer programs | ||||||||
T5 | x | x | x | |||||
Make effective use of IT tools for acquiring and processing information | ||||||||
T6 | x | x | x | x | x | x | x | |
Retrieve and evaluate information from a range of primary and secondary sources and present complex information in a clear and concise manner | ||||||||
T7 | x | x | x | x | x | x | x | |
Work with others, as required, when carrying out tasks | ||||||||
T8 | x | x | x | x | x | x | x | |
Demonstrate general study skills, including the ability to learn independently using a variety of media | ||||||||
T9 | MPhys only | MPhys only | MPhys only | MPhys only | MPhys only | MPhys only | ||
Demonstrate self-direction in tackling and solving problems and act autonomously in planning and implementing tasks | ||||||||
T10 | x | x | x | x | x | x | x | |
Demonstrate time management and organisational skills | ||||||||
T11 | x | |||||||
Apply an engineering approach to the solution of problems |
4. Programme structure
Programme titles and codes: | ||||||||||
Programme Code | Title | Award | Abbreviation | |||||||
PHUB01 | Physics | BSc | Ph | |||||||
PHUM01 | Physics | MPhys | Ph | |||||||
PHUB02 | Engineering Physics | BSc | Eng Ph | |||||||
PHUM02 | Engineering Physics | MPhys | Eng Ph | |||||||
PHUB03 | Physics and Mathematics | BSc | Ph & Math | |||||||
PHUM03 | Physics and Mathematics | MPhys | Ph & Math | |||||||
PHUB05 (pre 2014 entry) | Physics with Cosmology | BSc | Ph w Cos | |||||||
PHUM05(pre 2014 entry) | Physics with Cosmology | MPhys | Ph w Cos | |||||||
PHUB05 (2014 entry) | Physics with Astrophysics and Cosmology | BSc | Ph w AstroCos | |||||||
PHUM05 (2014 entry) | Physics with Astrophysics and Cosmology | MPhys | Ph w AstroCos | |||||||
PHUB14 | Sport Science and Physics | BSc | SS & Ph | |||||||
PHUB15 | Physics and Management | BSc | Ph w Man | |||||||
PHUB14 (from 2014) | Physics with Sport Science | BSc | Ph w SS | |||||||
PHUM14 (from 2014) | Physics with Sport Science | MPhys | Ph w SS | |||||||
Programme structure | ||||||||||
Key | ||||||||||
x | Compulsory Module | |||||||||
o | Optional Module | |||||||||
4.1 PART A | ||||||||||
Cred | Sem | Ph | Eng Ph | Ph w AstroCos | Ph & Math | Ph w SS | ||||
MAA108 | Mathematics for Physics 1 | 10 | 1 | x | x | x | x | |||
MAA208 | Mathematics for Physics 2 | 10 | 2 | x | x | x | x | |||
MPA107 | Mechanics of Materials | 10 | 2 | x | x | x | ||||
PHA101 | Mechanics | 15 | 1 | x | x | x | x | x | ||
PHA102 | Electricity & Magnetism | 15 | 1 | x | x | x | x | x | ||
PHA181 | Physics Laboratory 1 | 10 | 1 | x | x | x | ||||
PHA190 | Information Skills | 10 | 1 | x | x | x | ||||
PHA201 | Atomic and Thermal Physics | 10 | 2 | x | x | x | x | x | ||
PHA290 | Computing | 10 | 2 | x | x | x | x | x | ||
PHA220 | Astronomy | 10 | 2 | x | x | x | ||||
PHA282 | Physics Laboratory 2 | 10 | 2 | x | x | x | ||||
PHA285 | Joint Physics Lab 1 | 10 | 2 | x | x | |||||
MAA160 | Computer Applications in Mathematics | 10 | 1 | x | ||||||
MAA150 | Mathematical Methods 1 | 10 | 1 | x | ||||||
MAA142 | Linear Algebra | 10 | 1 | x | ||||||
MAA270 | Introduction to Probability and Statistics | 10 | 2 | x | ||||||
MAA250 | Mathematical Methods 2 | 10 | 2 | x | ||||||
MAA242 | Geometry and Groups | 10 | 2 | x | ||||||
PSA020 | Introduction to Human and Exercise Physiology | 10 | 1 | x | ||||||
PSA028 | Biomechanics of Sport | 10 | 1 | x | ||||||
PSA027 | Acquiring Movement Skills | 10 | 2 | x | ||||||
PSA026 | Foundation of Sport and Exercise Psychology | 10 | 2 | x | ||||||
4.2 PART B | ||||||||||
Cred | Sem | Ph | Eng Ph | Ph w Cos (Ph w AstroCos from 2015) | Ph & Math | Ph w SS (from 2014 entry) | SS & Ph | |||
PHA285 | Joint Physics Laboratory 1 | 10 | 2 | x | ||||||
PHB020 | Practical Astronomy | 10 | 1+2 | x | ||||||
PHB101 | Waves | 10 | 1 | x | x | x | x | x | x | |
PHB102 | Physical Cosmology | 10 | 1 | o | x | |||||
PHB104 | Quantum Mechanics | 10 | 1 | x | x | x | x | x | x | |
PHB106 | Nuclear Physics | 10 | 1 | x | x | x | x | x | ||
PHB180 | Physics Laboratory 3 | 10 | 1 | x | x | x | ||||
PHB201 | Fields | 10 | 2 | x | x | x | x | x | x | |
PHB203 | Thermal Physics | 10 | 2 | x | x | x | x | x | x | |
PHB204 | Radio Astronomy | 10 | 2 | o | x | |||||
PHB207 | Electronics | 10 | 2 | x | x | |||||
PHB110 | Solid State Physics | 10 | 2 | x | x | x | x | x | ||
PHB280 | Physics Laboratory 4 | 10 | 2 | x | x | x | ||||
PHB285 | Joint Physics Laboratory 2 | 10 | 2 | x | x | |||||
MAB108 | Mathematics for Physics 3 | 10 | 1 | x | x | x | x | x | ||
MMB300 | Engineering Computation | 10 | 1+2 | o | x | |||||
MMB104 | Control Engineering | 10 | 1 | o | x | |||||
EULxxx | Language in Sem 1 | 10 | 1 | o | ||||||
EULxxx | Language in Sem 2 | 10 | 2 | o | ||||||
MAA140 | Analysis 1 | 10 | 1 | x | ||||||
MAA155 | Introduction to Applied Mathematics | 10 | 1 | x | ||||||
MAB160 | Numerical Methods 1 | 10 | 1 | x | ||||||
MAA240 | Analysis 2 | 10 | 2 | x | ||||||
MAB240 | Fourier Analysis and Partial Differential Equations | 10 | 2 | x | ||||||
PSB211 | Exercise Physiology | 20 | 1+2 | x | o | |||||
PSB027 | Acquiring Movement Skills | 10 | 1 | o | ||||||
PSB029 | Biomechanics of Sports Movements | 10 | 1 | o | ||||||
PSB031 | Psychological Issues and Strategies in Sport | 10 | 1 | x | o | |||||
PSB002 | Structural Kinesiology | 10 | 2 | x | ||||||
PSB026 | Psycho-social Factors in Competitive Sport | 10 | 2 | o | ||||||
PSB028 | Methods of Analysis in Sports Biomechanics | 10 | 2 | x | o | |||||
4.3 PART C | ||||||||||
Cred | Sem | Ph | Eng Ph | Ph w Cos (Ph w AstroCos from 2016) | Ph & Math | Ph w SS | SS & Ph | Ph & Man | ||
PHB203 | Thermal Physics | 10 | 2 | x | ||||||
PHB106 | Nuclear Physics | 10 | 1 | x | x | |||||
PHB110 | Solid State Physics | 10 | 2 | x | x | |||||
PHC001 | Physics Project | 30 | 1+2 (minimum of 10 credits in each semester) | xBSc | xBSc | o† | xBSc | |||
PHC002 | Astrophysics Project | 30 | 1+2 (minimum of 10 credits in each semester) | xBSc | ||||||
PHC003 | Physics and Management Project | 20 | 1+2 (minimum of 10 credits in each semester) | x | ||||||
PHC011 | General Relativity and Cosmology | 20 | 1+2 | o | o | x | o | o BSc only | o=20 | o>=10 |
PHC012 | Quantum Physics | 20 | 1+2 | x | x | x | x | x | o=20 | o>=10 |
PHC013 | Statistical Physics | 10 | 1 | x | x | x | x | x | o=20 | o>=10 |
PHC014 | Condensed Matter Physics | 20 | 1+2 | o BSc x MPhys | o | o BSc x MPhys | o | o=20 | o>=10 | |
PHC108 | Modern Optics | 10 | 2 | o | o | o | o | o | o=20 | o>=10 |
PHC120 | Surfaces, Thin Films and High Vacuum | 10 | 1 | o | o | o | o | o | o=20 | o>=10 |
PHC130 | Fundamentals of Quantum Information | 10 | 1 | o BSc only (2014 only) | o BSc only (2014 only) | o BSc only (2014 only) | o BSc only (2014 only) | o=20 (2014 only) | o>=10 | |
PHC150 | Business Skills for Scientists | 10 | 1 | o | o | o | o | o | o=20 | |
PHC180 | Advanced Physics Laboratory | 20 | 1+2 | xMPhys | xMPhys | xMPhys | xMPhys | |||
PHC186 | Joint Physics Laboratory 3 | 10 | 1 | x | ||||||
PHC202 | Superconductivity and Nanoscience | 10 | 2 | o BSc only (2014 only) | o BSc only (2014 only) | o BSc only (2014 only) | o BSc only (2014 only) | o=20 (2014 only) | o>=10 | |
PHC205 | Elementary Particle Physics | 10 | 2 | o | o | x | o | o | o=20 | o>=10 |
PHC207 | Climate Physics | 10 | 2 | o | o | o | o | o | o=20 | o>=10 |
PHC230 | Quantum Computing | 10 | 2 | o BSc only (2014 only) | o BSc only (2014 only) | o BSc only (2014 only) | o BSc only (2014 only) | o=20 (2014 only) | o>=10 | |
PHC286 | Sport Science and Physics Project | 10 | 2 | x | ||||||
DSC023 | Studies in Science and Mathematics Education | 10 | 2 | o | o | o | o | o | o=20 | o>=10 |
CMB010(CAP) | Atomic Spectrometric Analysis | 10 | 2 | o<=30 | o<=30 | |||||
CMB020(CAP) | Introduction to Forensic Science | 10 | 2 | o<=30 | o<=30 | |||||
EULxxx | Language Module, Sem 1 | 10 | 1 | o<=30 | o<=30 | o<=30 | o(BSc<=30), (MPhys<=10) | |||
EULxxx | Language Module, Sem 2 | 10 | 2 | o<=30 | o<=30 | o<=30 | o(BSc<=30), (MPhys<=10) | |||
ELC003 | Renewable Energy Sources | 15 | 1&2 | o<=30 | o>=50 | o<=30 | o<=30 | |||
ELC014 | Biophotonics Engineering | 15 | 1&2 | o<=30 | o>=50 | o<=30 | o<=30 | |||
ELC022 | Power Electronics for Renewables | 15 | 1&2 | o<=30 | o>=50 | o<=30 | ||||
ELC030 | Bioelectricity - Fundamentals and Applications | 15 | 1&2 | o<=30 | o>=50 | o<=30 | o<=30 | |||
MPC111 | Advanced Principles of Materials | 10 | 1 | o<=30 | o>=50 | o<=30 | o<=30 | o(BSc<=30), (MPhys<=10) | ||
MPC114 | Composite Materials | 10 | 1 | o<=30 | o>=50 | o<=30 | o<=30 | o(BSc<=30), (MPhys<=10) | ||
MPC101 | Sustainability, Recycling and Environmental Issues | 10 | 1 | o<=30 | o>=50 | o<=30 | o<=30 | o(BSc<=30), (MPhys<=10) | ||
MMC101 | Vibration and Noise | 10 | 2 | o<=30 | o>=50 | o<=30 | ||||
MMC301 | Computer Aided Engineering | 10 | 2 | o<=30 | o>=50 | o<=30 | ||||
MMC700 | Sports Engineering | 10 | 2 | o<=30 | o>=50 | o<=30 | o<=30 | o(BSc<=30), (MPhys<=10) | ||
MMC800 | Internal Combustion Engines | 20 | 2 | o<=30 | o>=50 | o<=30 | ||||
MMC802 | Computational Fluid Dynamics I | 10 | 2 | o<=30 | o>=50 | o<=30 | o<=30 | |||
MPC014 | Materials in Service | 10 | 2 | o<=30 | o>=50 | o<=30 | o<=30 | o(BSc<=30), (MPhys<=10) | ||
MPC108 | Surface Engineering | 10 | 2 | o<=30 | o>=50 | o<=30 | o<=30 | |||
MAC108 | Mathematics for Physics 4 | 10 | 1 | o BSc x MPhys | o | o BSc x MPhys | o BSc x MPhys | o=20 | o>=10 | |
MAC150 | Inviscid Fluid Mechanics | 10 | 1 | o<=30 | o<=30 | o>=30 | o<=30 | |||
MAC300 | BSc Mathematics Project | 20 | 1+2 | o† | ||||||
MAB170 | Probability Theory | 10 | 1 | o>=30 | ||||||
MAC148 | Introduction to Dynamical Systems | 10 | 1 | o>=30 | ||||||
MAC175 | Operational Research | 10 | 1 | o>=30 | ||||||
MAC197 | Introduction to Differential Geometry | 10 | 1 | o>=30 | ||||||
MAB250 | ODEs and Calculus of Variations | 10 | 2 | o>=30 | ||||||
MAB270 | Statistical Modelling | 10 | 2 | o>=30 | ||||||
MAC249 | Linear Differential Equations | 10 | 2 | o>=30 | ||||||
MAC251 | Vibrations and Waves | 10 | 2 | o>=30 | ||||||
MAC272 | Random Processes and Time Series Analysis | 10 | 2 | o>=30 | ||||||
MAC297 | Mathematical Biology | 10 | 2 | o>=30 | ||||||
MAC298 | Elements of Topology | 10 | 2 | o>=30 | ||||||
PSC021 | Physiology of Exercise and Health | 20 | 1 | o=60 | ||||||
PSC022 | Sport and Exercise Medicine | 10 | 1 | o=60 | ||||||
PSC028 | Advanced Methods of Analysis in Sports Biomechanics | 10 | 1 | o/x* | o=60 | |||||
PSC019 | Applied Physiology of Sports Performance | 10 | 1 | x | o=60 | |||||
PSC031 | Applied Sport and Performance Psychology | 20 | 1 | o=60 | ||||||
PSC020 | Sport Nutrition | 10 | 2 | o=60 | ||||||
PSC026 | Exercise Psychology | 20 | 2 | x | o=60 | |||||
PSC027 | Motor Control of Sports Movement | 10 | 2 | o=60 | ||||||
PSC029 | Mechanics of Sport Techniques | 10 | 2 | o/x* | o=60 | |||||
BSC570 | Strategic Management | 20 | 1 | x | ||||||
BSC105 | International Human Resource Management | 10 | 1 | o>=20 | ||||||
BSC110 | Marketing Strategy and Planning | 10 | 1 | o>=20 | ||||||
BSC124 | Marketing Communications | 10 | 1 | o>=20 | ||||||
BSC522 | Entrepreneurship and Innovation | 10 | 1 | o>=20 | ||||||
BSC042 | Corporate and Wholesale Banking | 10 | 2 | o>=20 | ||||||
BSC140 | Lean Operations | 10 | 2 | o>=20 | ||||||
Part C Key | ||||||||||
† BSc Physics and Mathematics must take either PHC001 or MAC300. Please note that only students who achieve an average of at least 65% in their Part B Mathematics modules will be eligible for MAC300. Not available to MPhys students. | ||||||||||
BSc Compulsory only for BSC students | ||||||||||
MPhys Compulsory only for MPhys students | ||||||||||
* Ph w SS, PSC029 and PSC028: BSc students MUST choose one of these two options. For MPhys students both are compulsory. | ||||||||||
<=30 Up to 30 credits of engineering options can be taken from the list supplied | ||||||||||
>=50 Students must take at least 50 credits of engineering options from the list supplied | ||||||||||
=30 Students must take 30 credits of physics and related optional modules from the list supplied | ||||||||||
=60 Students must take 60 credits of Sport Science optional modules from the list supplied | ||||||||||
>=30 Students must take at least 30 credits of Mathematics optional modules from the list supplied | ||||||||||
>=20 Students must take at least 20 credits of Business School optional modules from the list supplied | ||||||||||
>=10 Students must take at least 10 credits of physics and related optional modules from the list supplied | ||||||||||
(CAP) Please note numbers may be capped. A-level Chemistry is a pre-requisite for these modules. |
||||||||||
All students in Part C may take a maximum of 30 credits of Part B level modules |
||||||||||
4.4 PART D | ||||||||||
Cred | Sem | Ph | Eng Ph | Ph w Cos (Ph w AstroCos from 2017) | Ph & Math | Ph w SS | ||||
PHD001 | Physics Research Project | 60 | 1+2 (minimum of 20 credits in any semester) | x | x | x | ||||
PHD002 | Astrophysics Research Project | 60 | 1+2 (minimum of 20 credits in any semester) | x | ||||||
PHD004 | Mathematical Physics Research Project | 60 | 1+2 (minimum of 20 credits in any semester) | x | ||||||
PHD013 | Statistical Physics | 10 | 1 | o♦ | o♦ | o♦ | o♦ | o♦ | ||
PHD120 | Surfaces, Thin Films and High Vacuum | 10 | 1 | o♦ | o♦ | o♦ | o♦ | o♦ | ||
PHD130 | Fundamentals of Quantum Information | 10♥ | 1 | o ¥ | o | o | o | o | ||
PHD202 | Superconductivity and Nanoscience | 10♥ | 2 | o ¥ | o | o | o | o | ||
PHD205 | Elementary Particle Physics | 10 | 2 | o♦ | o♦ | o~♦ | o♦ | o♦ | ||
PHD230 | Quantum Computing | 10♥ | 2 | o ¥ | o | o | o | o | ||
PHD109 | Characterisation Methods for Solid State Physics | 15 | 2 (for 2014/15 only) | o ¥ 2015 onwards | o 2015 onwards | o 2015 onwards | o 2015 onwards | o 2015 onwards | ||
PHD100 | Mathematical Methods for Research | 15 | 1 | o ¥ 2015 onwards | o 2015 onwards | o 2015 onwards | o 2015 onwards | o 2015 onwards | ||
PHD201 | Non-Linear Physics | 15 | 2 | o ¥ 2015 onwards | o 2015 onwards | o 2015 onwards | o 2015 onwards | o 2015 onwards | ||
MAD102 | Regular and Chaotic Dynamics | 15 | 1 | o | o | o | o | o | ||
MAP102 | Programming and Numerical Methods | 15 | 1 | o | o | o | o | o | ||
MAP111 | Mathematical Modelling of Industrial Problems 1 | 15 | 1 | o | o | o | o | o | ||
MAP202 | Static and Dynamic Optimisation | 15 | 2 | o | o | o | o | o | ||
MAP211 | Mathematical Modelling of Industrial Problems 2 | 15 | 2 | o | o | o | o | o | ||
MAP213 | Fluid Mechanics | 15 | 2 | o | o | o | o | o | ||
ELD533 | Solar Power 1 | 15 | 1 | o<=30 | o30-60 | o<=30 | o<=30 | o<=30 | ||
ELD534 | Wind Power 1 | 15 | 1 | o<=30 | o30-60 | o<=30 | o<=30 | o<=30 | ||
ELP002 | MATLAB as a Scientific Programming Language | 15 | 1 | o<=30 | o30-60 | o<=30 | o<=30 | o<=30 | ||
ELD535 | Water Power | 15 | 1 | o<=30 | o30-60 | o<=30 | o<=30 | o<=30 | ||
MMP130 | Structural Analysis | 15 | 1 | o<=30 | o30-60 | o<=30 | o<=30 | o<=30 | ||
MPP501 | Polymer Properties | 15 | 1 | o<=30 | o30-60 | o<=30 | o<=30,2014/15 only | o<=30 | ||
MPP502 | Polymer Science | 15 | 1 | o<=30 | o30-60 | o<=30 | o<=30,2014/15 only | o<=30 | ||
MPP551 | Advanced Characterisation Techniques | 15 | 1 | o<=30 | o30-60 | o<=30 | o<=30,2014/15 only | o<=30 | ||
ELD540 | Advanced Photovoltaics | 10 | 2 | o<=30,2014/15 only | o30-60 | o<=30,2014/15 only | o<=30,2014/15 only | |||
ELD541 | Wind Power 2 | 10 | 2 | o<=30,2014/15 only | o30-60 | o<=30,2014/15 only | o<=30,2014/15 only | |||
MMD902 | Laser and Optical Measurements | 20 | 2 | o<=30 | o30-60 | o<=30 | o<=30 | |||
MMP103 | Simulation of Advanced Materials and Processes | 15 | 2 | o<=30 | o30-60 | o<=30 | o<=30 | o<=30 | ||
MPD103 | Tomorrow's Materials | 10 | 2 | o<=30 | o30-60 | o<=30 | o<=30 | o<=30 | ||
MPP556 | Materials Modelling | 15 | 2 | o<=30 | o30-60 | o<=30 | o<=30 | o<=30 | ||
Part D Key | ||||||||||
o♦ Only available to students entering Part C in 2013/14 or earlier | ||||||||||
♥ Credit weighting change to 15 credits from 2015/16 onwards | ||||||||||
¥ From 2015 students must take a minimum of weight 30 PH coded modules excluding project modules | ||||||||||
<=30 Students can take up to 30 credits of engineering D or P modules from the list provided | ||||||||||
30-60 Engineering Physics students must take between 30 and 60 credits of engineering D or P modules from the list provided | ||||||||||
Total Modular Weighting per Semester | ||||||||||
Students normally study modules with a total weight of 60 in each semester. However, in Part C and D, students may be allowed to study modules up to a total weight of 70 in a semester, 120 in the Part, subject to the consent of the Head of Department. | ||||||||||
Optional Modules not Listed | ||||||||||
In exceptional circumstances and at the discretion of the Director of Studies or Head of Department, candidates may be allowed to substitute an alternative Loughborough University module of the appropriate Part for any of the optional modules above. | ||||||||||
Part I of the BSc and MPhys Programmes | ||||||||||
BSc candidates opting to take eight semester and MPhys candidates opting to take ten semesters are required to spend the year following Part B either (a) an approved course of study at a University abroad or (b) professional training. These lead to the awards of the Diploma in International Studies or the Diploma in Industrial Studies respectively in accordance with Regulation XI. | ||||||||||
With the permission of the Programme Tutor, MPhys candidates may take this study/training following Part C. |
5. Criteria for Progression and Degree Award
In order to progress from Part A to Part B, from Part B to C, from C to D (if applicable) and to be eligible for the award of an Honours degree, candidates must satisfy the minimum credit requirements set out in Regulation XX.
Physics and Mathematics BSc and MPhys Additional Progression Requirements
Part A to Part B
Candidates must, in addition, achieve at least 40% in three of the four core Mathematics Modules MAA150 Mathematical Methods 1, MAA142 Linear Algebra, MAA270 Introduction to Probability and Statistics, MAA250 Mathematical Methods 2
MPhys Additional Progression Requirements
Part B to Part C
In order to progress from Part B to Part C the overall average mark for Part B must be at least 50%
MPhys candidates who fail, after any re-assessment
At the discretion of the Programme Board any MPhys candidate who fails, after any re-assessment, at the end of Part C or Part D, who has satisfied the credit requirements for the equivalent BSc award may be awarded that degree, the classification being based on the average mark obtained in Parts B and C in exactly the same way as for the BSc Degree (see table in Section 6 'Relative Weighting of Parts of the Programme for the Purposes of Final Degree Classification' below).
6. Relative Weighting of Parts of the Programme for the Purposes of Final Degree Classification
Relative Weighting of Parts of the Programme for the purposes of Final Degree Classification
Candidates' final degree classification will be determined on the basis of their performance in degree level Module Assessments in Parts B and C (and D if applicable). The average percentage mark for each Part will be combined in the ratio specified in the following table.
BSc Candidates |
Part B : Part C |
40 : 60 |
MPhys Candidates |
Part B : Part C : Part D |
20 : 40 : 40
|