Sensors and actuators are key components in a mechatronic system. In recent years, the inclusion of electronics in many vehicle functions has created the demand for engineers who can design systems with integrated mechanical and electrical components. The modern car contains a large number of sensors and actuators that are integrated in mechatronic systems found throughout the vehicle. In addition, many producers are showing great interest in virtual prototyping, which requires the ability to derive an accurate mathematical model of a system, and to create simulations that accurately predict system performance. This module is dedicated to the study of such components, including devices that are based on new and emerging technologies such as micro electromechanical systems (MEMS).

This module adds game-specific techniques and material to the general-purpose programming abilities acquired previously. Topics include fundamental game classes and loops; working with 2D graphics, images and sound; collision detection, Game AI, particle effects, procedural content generation, physics engines and more. Students showcase their programming skills and creative flair by designing and implementing a 2D video game.

The aim of this module is to provide an introduction to the C++ programming language. The contents covered by this module include basic concepts and features of C++ programming (e.g., operator overloading), C++ Standard Template Library, and inheritance, function overriding and exceptions.

This module provides you with a basic understanding of the analysis of linear systems and introduces you to filter design techniques for analogue signal processing. The Laplace transform and its application in circuit and system theory are introduced, together with the concepts of system transfer function and impulse response, and techniques for deriving the transfer function of a circuit. The steady-state response of systems to sinusoidal inputs is presented. Bode plotting techniques are covered, and the effects of feedback are investigated, and techniques for ensuring stability are discussed. Butterworth and Chebyshev filter approximations are introduced. After covering the concepts of frequency and impedance transformations, selected standard analysis and design techniques applied to low-pass, high-pass, band-pass and band-stop filters of both passive and active types are examined.