MODERN COMPUTATIONAL TECHNIQUES - 2022/3
Module code: PHY3042
In light of the Covid-19 pandemic the University has revised its courses to incorporate the ‘Hybrid Learning Experience’ in a departure from previous academic years and previously published information. The University has changed the delivery (and in some cases the content) of its programmes. Further information on the general principles of hybrid learning can be found at: Hybrid learning experience | University of Surrey.
We have updated key module information regarding the pattern of assessment and overall student workload to inform student module choices. We are currently working on bringing remaining published information up to date to reflect current practice in time for the start of the academic year 2021/22.
This means that some information within the programme and module catalogue will be subject to change. Current students are invited to contact their Programme Leader or Academic Hive with any questions relating to the information available.
This module covers techniques in solving physics problems on computer in a more advanced way than lower-level courses. It combines use of scientific program libraries within Python, along with advanced algorithms for problem solving, and introduces the high-level Maple package for analytic computation, with applications to solving differential equations.
STEVENSON Paul (Physics)
Number of Credits: 15
ECTS Credits: 7.5
Framework: FHEQ Level 6
JACs code: F343
Module cap (Maximum number of students): N/A
Overall student workload
Independent Learning Hours: 95
Laboratory Hours: 22
Guided Learning: 11
Captured Content: 22
Prerequisites / Co-requisites
PHY2063: Energy, Entropy and Numerical Physics
Indicative content includes:
• Differential equations in physics; Linear algebra approach to their solution via Python libraries; Introduction to Maple, survey of its capabilities, and application to solution of differential equations (4 weeks)
• Algorithmic techniques: Optimisation; Neural Networks and machine learning, the Fast Fourier Transform (5 weeks)
• Monte Carlo Methods (2 weeks)
|Assessment type||Unit of assessment||Weighting|
|Coursework||COURSEWORK ASSIGNMENT - 1||50|
|Coursework||COURSEWORK ASSIGNMENT - 2||50|
The assessment strategy is designed to provide students with the opportunity to demonstrate ability to apply the range of techniques used in this course to tackle problems of relevance in broad areas of physics.
Thus, the summative assessment for this module consists of:
two assignments which feature programming exercises, covering the whole range of course material
The first assignment is due on Tuesday of Week 7 at 4pm and covers solution of a differential equation within physics using (a) Linear Algebra approach and (b) Maple-assisted analytic solution.
The second assignment is due on Tuesday of Week 12 at 4pm and covers the remainder of the material.
Weekly exit tests.
Each week's material features a short exit test which can be submitted for feedback. The first summative assignment will be returned with feedback during the teaching weeks. A discussion board provides written feedback to written questions, and the live sessions offer instant feedback.
- To advance skills in different areas of using computers to solve physics problems.
- To gain experience and confidence in using library routines for solving linear algebra problems.
- To learn advanced algorithms and techniques, such as the use of (fast) fourier transforms, the use of neural networks and machine learning, monte carlo techniques, and numerical minimization and optimization.
- To be able to take differential equations from physics problems and discretise them to form sets of linear equations to be solved by library routines.
- To visualise the output of these computations
- to equip students with sufficient familiarity with Maple to solve differential equations with it.
|001||Understand how to use scientific computational libraries within Python and how to apply them to physics problems||KPT|
|002||Appreciate the utility of Monte Carlo methods and make decisions about where to apply them||KCP|
|005||Understand and apply techniques of neural networks and machine learning to general optimization problems.||KCT|
|003||Understand the uses and applications of the Fast Fourier Transformation Algorithm||KPT|
|004||Employ the anaytic Maple package for the solution of differential equations and other problems in physics.||KCPT|
C - Cognitive/analytical
K - Subject knowledge
T - Transferable skills
P - Professional/Practical skills
Methods of Teaching / Learning
The learning and teaching strategy is designed to:
Build the skills and knowledge of students to apply advanced computational techniques to problems of physical relevance, and to be able to select appropriate tools for unseen problems
The learning and teaching methods include:
Weekly one-hour lecture session in which material is developed on the board with associated use of computer demonstration. These session are recorded for review.
Weekly two-hour classes in the computer lab with specific short formative excercises to help understand each week’s material
Use of online discussion board
Indicated Lecture Hours (which may also include seminars, tutorials, workshops and other contact time) are approximate and may include in-class tests where one or more of these are an assessment on the module. In-class tests are scheduled/organised separately to taught content and will be published on to student personal timetables, where they apply to taken modules, as soon as they are finalised by central administration. This will usually be after the initial publication of the teaching timetable for the relevant semester.
Upon accessing the reading list, please search for the module using the module code: PHY3042
Note that the principal language of tuition of this module is Python 3. Support and materials are provided for students with a background in Fortran.
Programmes this module appears in
|Physics with Astronomy BSc (Hons)||1||Optional||A weighted aggregate mark of 40% is required to pass the module|
|Physics with Quantum Technologies BSc (Hons)||1||Optional||A weighted aggregate mark of 40% is required to pass the module|
|Physics BSc (Hons)||1||Optional||A weighted aggregate mark of 40% is required to pass the module|
|Physics with Nuclear Astrophysics MPhys||1||Optional||A weighted aggregate mark of 40% is required to pass the module|
|Physics with Astronomy MPhys||1||Optional||A weighted aggregate mark of 40% is required to pass the module|
|Physics with Nuclear Astrophysics BSc (Hons)||1||Optional||A weighted aggregate mark of 40% is required to pass the module|
|Physics with Quantum Technologies MPhys||1||Optional||A weighted aggregate mark of 40% is required to pass the module|
|Physics MPhys||1||Optional||A weighted aggregate mark of 40% is required to pass the module|
Please note that the information detailed within this record is accurate at the time of publishing and may be subject to change. This record contains information for the most up to date version of the programme / module for the 2022/3 academic year.