University of Essex

CE812-7-SP-CO:
Physics-Based Games

The details

Year: 2023/24

Department: Computer Science and Electronic Engineering (School of)

Campus: Colchester Campus

Term: Spring

Level: Postgraduate: Level 7

Status: Current

Start date: Monday 15 January 2024

End date: Friday 22 March 2024

Credits: 15

Last updated: 17 June 2022

Requisites for this module

Pre-requisites: (none)

Co-requisites: (none)

Pre and / or co-requisites: (none)

Prohibited modules: (none)

Key module (requisite for): (none)

Key module for

MSC G61012 Computer Games

Module description

This module covers the fundamentals of simulating physical systems and teaches how to use physics engines to simulate a wide range of physical interactions. The course also covers many examples of implementing physics-based games, and students learn to do this both by using physics engines, and by implementing physics directly for simpler examples.

The module teaches the necessary mathematics, algorithms and data structures used in modelling and building efficient simulations of physical systems. The mathematics is covered in an accessible hands-on way and supported with many illustrative examples and accompanying graphical computer simulations where appropriate.

Module aims

The course aims to provide students with a solid knowledge of writing physics-based games by briefly covering the underlying physics models and mathematical equations, showing how these can be translated into code in a high-level language, or simulated using a physics-engine.

Several example physics-based games will be covered. Each week the students will create a small physics-based game, which will allow practice of the concepts taught in that week’s lecture. The course concludes with students designing and implementing a larger physics-based game.

Module learning outcomes

On successful completion of the course students should be able to:

1. Write equations to model physical systems
2. Implement simulations of simple physical systems in a high-level language
3. Implement simulations of complex physical systems in 2D or 3D using an appropriate engine
4. Design and implement a physics-based game

Module information

Syllabus

A refresher on vectors and matrices as used in the course
A refresher on physics principles such as velocity, acceleration, collisions, forces, gravity, elasticity.
Modelling physical systems: the differential equations and their numerical integration: rigid bodies, connected bodies.
Writing software to directly implement simple simulations in a high-level language
Collision detection and collision reaction
Spring-Mass models, Rag-Doll Physics,
Architecture of a physics engine, 2D and 3D engines
Implementing simulations using a physics engine
Example simulations ranging from simple to complex: cart-pole systems, 2D physics games, car racing, aeroplane flight, snooker.
Game Case Studies
Physics Game Design
Physics Game Implementation

The course will be taught via lectures and extensive laboratory exercises, using Java as the main programming language, and will include the use of open-source physics simulators such as JBullet and JBox2D. Note students should either be strong programmers or have some previous Java programming experience to take this module.

Learning and teaching methods

2 hours of lectures and 2 hours of labs per week Weekly Moodle Quizzes

Bibliography

Bourg, D.M., Humphreys, K. and Bywalec, B. (2012) Physics for game developers: leverage physics in games and more. 2nd ed. Farnham: O’Reilly. Available at: https://search.ebscohost.com/login.aspx?direct=true&scope=site&db=nlebk&db=nlabk&AN=565704.
Parberry, I. (no date) Introduction to game physics with Box2D. Boca Raton: CRC Press. Available at: https://search.ebscohost.com/login.aspx?direct=true&scope=site&db=nlebk&db=nlabk&AN=573118.
Millington, I. (2010) Game physics engine development: how to build a robust commercial-grade physics engine for your game. 2nd ed. Amsterdam: Morgan Kaufmann Publishers. Available at: https://search.ebscohost.com/login.aspx?direct=true&scope=site&db=nlebk&db=nlabk&AN=345066.
Dickinson, C. (2013) Learning game physics with bullet physics and OpenGL: practical 3D physics simulation experience with modern feature-rich graphics and physics APIs. Birmingham: Packt Publishing. Available at: https://search.ebscohost.com/login.aspx?direct=true&scope=site&db=nlebk&db=nlabk&AN=655574.

The above list is indicative of the essential reading for the course.
The library makes provision for all reading list items, with digital provision where possible, and these resources are shared between students.
Further reading can be obtained from this module's reading list.

Assessment items, weightings and deadlines

Coursework / exam	Description	Coursework weighting
Coursework	Progress Test 1	20%
Coursework	Progress Test 2	20%
Coursework	Lab Exercises & Moodle Quizzes	20%
Coursework	Main Assignment	40%

Exam format definitions

Remote, open book: Your exam will take place remotely via an online learning platform. You may refer to any physical or electronic materials during the exam.
In-person, open book: Your exam will take place on campus under invigilation. You may refer to any physical materials such as paper study notes or a textbook during the exam. Electronic devices may not be used in the exam.
In-person, open book (restricted): The exam will take place on campus under invigilation. You may refer only to specific physical materials such as a named textbook during the exam. Permitted materials will be specified by your department. Electronic devices may not be used in the exam.
In-person, closed book: The exam will take place on campus under invigilation. You may not refer to any physical materials or electronic devices during the exam. There may be times when a paper dictionary, for example, may be permitted in an otherwise closed book exam. Any exceptions will be specified by your department.

Your department will provide further guidance before your exams.

Overall assessment

Coursework	Exam
100%	0%

Reassessment

Coursework	Exam
100%	0%

Module supervisor and teaching staff

Supervisor: Dr Michael Fairbank, email: m.fairbank@essex.ac.uk.

Teaching staff: Dr Michael Fairbank

Contact details: School Office, email: csee-schooloffice (non-Essex users should add @essex.ac.uk to create full e-mail address), Telephone 01206 872770

Availability

Available to incoming Essex Abroad / Exchange students: Yes

Available to Outside Option: No

Available to Audit: Yes

External examiner

Name: Dr MARJORY CRISTIANY Da COSTA ABREU

Institution: Sheffield Hallam University

Academic role: Senior Lecturer

Resources

Teaching materials: Available via Moodle

Lecture recording: Of 58 hours, 17 (29.3%) hours available to students:
33 hours not recorded due to service coverage or fault;
8 hours not recorded due to opt-out by lecturer(s), module, or event type.

Further information

Department website: Computer Science and Electronic Engineering (School of)

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Module Directory

CE812-7-SP-CO:Physics-Based Games