Introductory description

30 hours over 2 weeks consisting of interactive presentations, question and answer sessions, talks from industrial practitioners and discussion, videos, and hands on computer simulation sessions.

Module aims

Outline syllabus

This is an indicative module outline only to give an indication of the sort of topics that may be covered. Actual sessions held may differ.

• 1-D Multi Physics System Simulation within the electrical, mechanical and hydraulic domains.
• Physical Modelling using ordinary differential equations (ODE's) and state variable block diagram modelling methods for both linear and non-linear systems.
• Eigen-value calculation & transfer-function analysis of physical automotive systems within the frequency domain and time domain.
• Understanding and application of data-driven modelling
• Numerical integration methods including solver selection and its impact on simulation stability and accuracy.
• The use of simulation methods, including Co-Simulation/Embedded/Real Time Application
• The role of verification and validation techniques within systems modelling and simulation analysis.

Learning outcomes

By the end of the module, students should be able to:

• Demonstrate a comprehensive understanding of the practical application of the different approaches to mathematical modelling and analysis of one-dimensional physical systems
• Derive, translate, solve & analyse 1D functional models of physical systems in sequential block diagram & state variable forms.
• Critically evaluate a range of numerical solver methods and evaluate the correct usage and errors for each within the context of simulation efficiency and accuracy. Demonstrate understanding in model linearization and parameter estimation methods.
• Critically evaluate different methods of model verification and validation and synthesise a framework for data driven modelling within the context of model aims and objectives.
• Develop integrated models of automotive systems to gain a practical understanding of multi-physics simulation techniques.

Subject specific skills

• Understand dynamical systems,
• How to model electrical, mechanical, thermal, fluid systems as analogous systems,
• Numerical methods to solve ordinary differential dynamical systems
• Implement data-driven modelling
• Validating and verification of dynamical models
• How industries use such models and approaches
• Matlab programming

Transferable skills

• Technology literacy
• Dependability
• Communication
• Adaptability