Module aims

This module introduces theoretical approaches for the modelling and control of multi-body mechanical systems. Special emphasis is given to the use of computer tools for the modelling aspect.

Learning outcomes

Upon successful completion of this module, you will be able to:

  1. Distinguish between the two main branches of Classical Mechanics: Newtonian (vectorial) and Lagrangian (analytical) mechanics
  2. Make confident use of the basic tools of Classical Mechanics related to these two main branches
  3. Represent real mechanical systems as multibody systems
  4. Develop models, in the form of differential equations, of real mechanical systems using the two main methods from Classical Mechanics (Newton's laws and Lagrangian equations of motion)
  5. Derive equations of motion for mechanical systems with holonomic and nonholonomic constraints
  6. Apply techniques from control theory to improve the behaviour of systems represented by multibody models
  7. Model and control multibody systems using SimScape Multibody software tool

Module content

  • Basic vector calculus
  • Newtonian mechanics
  • Holonomic and nonholonomic systems
  • Control of nonholonomic systems
  • Kinematics of rigid body motion
  • Dynamics of rigid body motion
  • Variational principles and analytical mechanics: Calculus of variations and Lagrange multipliers, Euler-Lagrange differential equations, Virtual work, D'Alembert's principle, Hamilton's principle and Lagrangian equations of motion
  • Multi-body building software.

Module lead

Simos Evangelou

ECTS/FHEQ

5/7

Module code

ELEC70022

Host department

Department of Electrical and Electronic Engineering

Term

Autumn

Time slot

PM

Teaching weeks

TBC

August resit opportunity?

Yes

How to apply

Please follow the instructions

Application deadline

17.00 Friday 27 October

Places available (approximate)

No cap

Number of applicants (historic)

22 (2022-23)

Criteria used for student selection

N/A

Further information

EEE Intranet

 

 

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