- UCAS course code
- H400
- UCAS institution code
- M20
Bachelor of Engineering (BEng)
BEng Aerospace Engineering
Hands-on, highly transferable, and here at one of the most targeted Universities, there's no better place to launch your career (HiFliers 2024)
Duration: 3 years
Year of entry: 2025
UCAS course code: H400 / Institution code: M20
- Key features:
Scholarships available
Field trips
- Typical A-level offer: A*AA including specific subjects
- Typical contextual A-level offer: AAA including specific subjects
- Refugee/care-experienced offer: AAB including specific subjects
- Typical International Baccalaureate offer: 37 points overall with 7,6,6 at HL, including specific requirements
Fees and funding
Fees
Tuition fees for home students commencing their studies in September 2025 will be £9,535 per annum (subject to Parliamentary approval). Tuition fees for international students will be £34,000 per annum. For general information please see the undergraduate finance pages.
Policy on additional costs
All students should normally be able to complete their programme of study without incurring additional study costs over and above the tuition fee for that programme. Any unavoidable additional compulsory costs totalling more than 1% of the annual home undergraduate fee per annum, regardless of whether the programme in question is undergraduate or postgraduate taught, will be made clear to you at the point of application. Further information can be found in the University's Policy on additional costs incurred by students on undergraduate and postgraduate taught programmes (PDF document, 91KB).
Scholarships/sponsorships
Course unit details:
Control Engineering (Aerospace)
| Unit code | AERO30481 |
|---|---|
| Credit rating | 10 |
| Unit level | Level 3 |
| Teaching period(s) | Semester 1 |
| Available as a free choice unit? | No |
Overview
The module introduces classical control theory through the understanding of basic characteristics of open and closed loop control systems. It includes the use of Laplace transform method to represent and analyse system transient and steady-state response; the use of block diagram methods for representing system dynamics in the s domain; system stability analysis using root locus method, and the use of Nyquist and Bode diagrams for frequency response analysis. Practical industrial control system design and analysis is introduced through lectures given by industrial personnel with applications in the aerospace and process industries. Tutorial classes are used to reinforce lectures with worked examples and discussions, and a robotic laboratory session is used to illustrate the operation of a Proportional-Integral-Derivative controller – the system most widely used control system in industry.
Aims
To introduce the fundamental aims and principles of automatic control systems; to explain and analyse open- and closed-loop controllers; to understand and assess control system stability and to apply appropriate methods to determine this; and to understand and apply frequency response methods. The application and analysis of control systems within industry is illustrated using lectures given by professional engineers from the aerospace and process control sectors, as well as a practical laboratory that introduces the use of the widely-applied PID system to control the movement of a robotic vehicle.
Assessment methods
| Method | Weight |
|---|---|
| Written exam | 80% |
| Report | 20% |
Feedback methods
Feedback via script viewing
Study hours
| Scheduled activity hours | |
|---|---|
| Lectures | 18 |
| Practical classes & workshops | 2 |
| Tutorials | 6 |
| Independent study hours | |
|---|---|
| Independent study | 74 |
Teaching staff
| Staff member | Role |
|---|---|
| Timothy Abram | Unit coordinator |