Subject overview

Programme outline

Engineers are rarely in a position where their only focus is the engineering. From a very early stage in their careers, engineers need to manage progress and financially control projects within a professional environment. As engineers progress in their careers, they will undoubtedly become involved in increasingly complex projects. One aspect of this complexity may result from the technology or technology combinations; however, this will not be the only source. Engineering projects often involve overseas collaboration, either as a result of supplier or project partner locations. As the number of suppliers and partners increases, so does the complexity of the project and the associated systems and processes. 

This course aims to advance academic and professional excellence for both newly qualified and practising engineers who wish to enhance their business and management knowledge and skills alongside their engineering specialism, with a view to a career in engineering management. 

You combine the study of advanced topics in business, management and finance with further study in specialist engineering topics and the opportunity to undertake an advanced engineering project. Your studies will benefit from company visits, simulations, case studies and a guest lecture series featuring international speakers and industry leaders. 

Depending on your prior qualifications, you follow one of three engineering pathways: 

• Advanced Engineering pathway: you can choose to study a range of specialist modules, which do not require specific prior experience 
• Advanced Mechanical Engineering pathway: you can choose to study advanced mechanical engineering modules and benefit from the excellent experimental and computational facilities in this area 
• Communications pathway: you can choose to take modules from our highly successful digital communications MScs. 

Assessment 

Modules are assessed by a range of methods, including laboratory reports, essays and unseen examinations. The MSc project is assessed by an interim report, a presentation and a substantial dissertation. The project is designed for you to excel in your personal and professional development and to consolidate the material covered in your modules. It will expose you to issues of project management, resourcing, planning, scheduling, documentation and communication, and will demand individual responsibility, critical awareness and creative thinking. 

Some projects are undertaken in groups and replicate the type of professional teamwork expected in industry. Topics are generated from the academic research and industrial collaborations in the Department, and the project will be supervised by a member of faculty. 

Course structure

We continue to develop and update our modules for 2014 entry to ensure you have the best student experience.

The aim of our taught degrees is to develop academic and professional excellence both for newly qualified and practising engineers who wish to extend their professional expertise in specialist areas. Each degree comprises eight taught modules, typically four core modules and four options, plus an MSc project accounting for a maximum of one third of the degree. The options allow you to choose a pathway that suits your personal interests. Taught modules are delivered in the autumn and spring terms, with examination periods in January and May. The MSc project is a substantial practical exercise undertaken over the spring term and the summer up to the end of August. 

The course structure includes five core modules in business and management topics: Accounting and Finance for Managers • Global Business • Management Innovation and Organisational Performance • Managing Complex Projects and Systems • Strategic Management. 

In addition, you choose four options from a range that depends on the pathway chosen, for example: 

Advanced Engineering pathway options: Advanced Digital Signal Processing • Advanced Manufacturing Technologies • Cybernetics and Neural Networks • Sustainable Energy and the Environment – Supply • Image Processing • Managing Intellectual Property • Satellite and Space Systems • Sustainable Energy and the Environment – Demand. 

Advanced Mechanical Engineering pathway options: Advanced Digital Signal Processing • Advanced Manufacturing Technologies • Advanced Thermofluids • Advanced Turbomachinery • Computational Fluid Dynamics • Cybernetics and Neural Networks • Finite Element Analysis • Gas Turbine Cycles and Turbocharging • Heat Transfer Applications • Image Processing • Managing Intellectual Property• Mechanical Dynamics • Satellite and Space Systems • Sustainable Energy and the Environment – Demand • Sustainable Energy and the Environment – Supply • Testing and Modelling for Auto Power Systems. 

Communications pathway options: Advanced Digital Signal Processing • Advanced Manufacturing Technologies • Advanced Networks • Cybernetics and Neural Networks • Image Processing • Mobile Communications • RF Circuit Design • Advanced Digital Communications • Advanced Electronic Systems • Advanced Microprocessor Systems • Fibre Optic Communications • Managing Intellectual Property• Satellite and Space Systems • Sustainable Energy and the Environment – Demand • Sustainable Energy and the Environment – Supply. 

Following the summer examinations, you work full time on your MSc project based on a real-life problem to which you apply the knowledge and skills acquired across your studies of business management and engineering. 

Entry requirements

UK entrance requirements

A first- or second-class undergraduate honours degree in engineering, mathematics or physics.

Overseas entrance requirements

Overseas qualifications

If your country is not listed below, please contact the University at E pg.enquiries@sussex.ac.uk

Country	Overseas qualification
Australia	Bachelor (Honours) degree with second-class lower division
Brazil	Bacharel, Licenciado or professional title with a final mark of at least 7
Canada	Bachelor degree with CGPA 3.0/4.0 (grade B)
China	Bachelor degree from a leading university with overall mark of 65%-85% depending on your university
Cyprus	Bachelor degree or Ptychion with a final mark of at least 6.5
France	Licence with mention assez bien or Maîtrise with final mark of at least 12
Germany	Bachelor degree or Magister Artium with a final mark of 2.7 or better
Ghana	Bachelor degree from a public university with second-class lower division
Greece	Ptychion from an AEI with a final mark of at least 6.5
Hong Kong	Bachelor (Honours) degree with second-class lower division
India	Bachelor degree from a leading institution with overall mark of at least 60% or equivalent
Iran	Bachelor degree (Licence or Karshenasi) with a final mark of at least 14
Italy	Diploma di Laurea with an overall mark of at least 100
Japan	Bachelor degree from a leading university with a minumum of B or equivalent
Malaysia	Bachelor degree with class 2 division 2
Mexico	Licenciado with a final mark of at least 7
Nigeria	Bachelor degree with second-class lower division or CGPA of at least 2.8/4.0
Pakistan	Four-year bachelor degree, normally with a GPA of at least 3.3
Russia	Magistr or Specialist Diploma with a minimum average mark of at least 4
South Africa	Bachelor (Honours) degree or Bachelor degree in Technology with an overall mark of at least 60%
Saudi Arabia	Bachelor degree with an overall mark of at least 65% or CGPA 3.0/5.0 or equivalent
South Korea	Bachelor degree from a leading university with CGPA of at least 3.0/4.0 or equivalent
Spain	Licenciado with a final mark of at least 2/4
Taiwan	Bachelor degree with overall mark of 70%-85% depending on your university
Thailand	Bachelor degree with CGPA of at least 2.8/4.0 or equivalent
Turkey	Lisans Diplomasi with CGPA of at least 3.0/4.0 or equivalent depending on your university
United Arab Emirates	Bachelor degree with CGPA of at least 3.0/4.0 or equivalent
USA	Bachelor degree with CGPA 3.3-3.5/4.0 depending on your university
Vietnam	Masters degree with CGPA 3.0/4.0 or equivalent

If you have any questions about your qualifications after consulting our overseas qualifications, contact the University at E pg.enquiries@sussex.ac.uk

Related programmes

• Advanced Computer Science MSc
• Energy Policy for Sustainability MSc
• Human-Computer Interaction MSc
• Information Technology with Business and Management MSc
• Management of Information Technology MSc
• Managing Innovation and Projects MSc
• Technology and Innovation Management MSc

Fees and funding

Fees

Home UK/EU students: £5,500¹
Overseas students: £16,200²

¹ The fee shown is for the academic year 2013.
² The fee shown is for the academic year 2013.

Funding

The funding sources listed below are for the subject area you are viewing and may not apply to all degrees listed within it. Please check the description of the individual funding source to make sure it is relevant to your chosen degree.

Faculty interests

Research groups

Research is a core activity of the Department of Engineering and Design and is organised into four main groups. Our research often entails collaborations between the groups, as well as with other schools of studies at Sussex and external academic, institutional and commercial partners. For more detailed information, refer to the groups listed below and visit Department of Engineering: Research.

Dynamics, Control and Vehicle Research Group

This group is known internationally for its high-quality automotive research and fundamental work in dynamics and control. The group has a broad range of interests such as the convergence of control, non-linear dynamics, signal processing activities applied mainly to automotive engineering, and tribological research. It has attracted research grants from, and formed collaborations with, a variety of local, national and international public and industrial sources including EPSRC, Royal Society, Jaguar Landrover and SKF.

The primary focus is directed towards CO₂ reduction in transport through energy conversion efficiency improvements in engines, and through ‘lightweighting’ and drag-reduction technologies. For dynamics and automotive engineering this means reducing vehicle CO₂ emissions by improving powertrain and vehicle efficiencies particularly of internal combustion (IC) engines in conventional and hybrid electric vehicles, and by better understanding vehicle noise emissions to allow weight reduction.

This links directly to tribological research, which is at the forefront of the efforts to address the demands of the advances in material science, manufacturing, technology and the needs for better products, improved human life, and contributing to energy savings and a cleaner environment. The group researches areas including lubrication, dynamics of lubricated contacts, mechanical transmissions, contact mechanics and numerical modelling of lubricated contacts. 

Facilities include two engine-test cells, an engine-test laboratory, a full range of emissions measurement equipment, calibration equipment for engine control, and laser-based vibration measurement hardware. Specifically for tribological research, facilities include a PCS instruments optical interferometry test rig of EHD film measurement, an optical interferometry rig with a high-speed imaging system for dynamic testing of liquid films, impedance/gain-phase analyser, and a range of viscometers.

Faculty research interests include:

Dr Julian Dunne Engineering dynamics. Nonlinear system modelling and analysis; optimal control; vehicle, engine and rotor dynamics; noise, vibration and harshness applications in automotive and aerospace engineering.

Dr Romeo Glovnea Tribology, fundamentals of lubrication, experimental techniques in thin-film lubrication, mechanical transmissions (CVTs).

Dr Yevgen Petrov Modelling, numerical methods, analysis and optimisation of forced and self-excited vibration of jointed structures with friction, gaps and other non-linear interactions at contact interfaces.

Dr William Wang Machine condition monitoring, digital signal processing techniques, vibrational analysis and structural dynamics, wavelets and neural networks, measurement fault diagnosis.

Industrial Informatics and Signal Processing Research Group

Research in this group is focused on digital image processing; computer vision; optical computing, holography and communication; optical metrology; network and control theory; devices and computational techniques for medical and biological imaging and image processing, with a particular focus on cancer diagnosis and treatment.

These activities find application in a wide range of strategically important areas including product security, biometrics, automated face recognition, event detection and traffic monitoring. As an example, mobile-phone hardware and software has been developed to allow the phone to scan and recognise human irises using novel algorithms that have been patented and commercialised.

The Group is also engaged in interdisciplinary collaborations with the School of Life Sciences, the Brighton and Sussex Medical School (BSMS), clinical practitioners and companies in the medical device and medical imaging sectors. The research provides imaging biomarkers in cancerous tissue by wavelet filtering in an apparently normal contrast-enhanced CT image of the liver. We are currently extending the technique to 3D-texture analysis of the whole liver and lung. This research is the subject of a patent and commercialisation of the software.

Faculty research interests include:

Professor Chris Chatwin Advanced manufacturing: manufacturing and enterprise simulation and modelling, integrated total quality management. Fibre-optic communications. 

Security and surveillance systems: machine vision and image-processing, neural networks, mobile image acquisition, biometrics, image processing for medical diagnosis.

Dr Phil Birch Fibre-optic communications: photo-refractive holography, holographic optical memory, four-wave mixing, spatial light modulators, dynamic light-shaping elements, optical pattern recognition, optical filtering, electro-optic systems design.

Machine vision and image processing: Wiener filtering, foveating systems, mobile image acquisition, autonomous mobile robots, biometrics, image processing for medical diagnosis.

Dr David Li Finite-element analysis of waveguide devices; numerical modelling of optical communication devices; imaging and sensing systems; mixed-signal circuits, imaging processors, and firmware design.

Dr Tai Yang Networks and control systems for power generation control applications and in-vehicle control systems, control of hybrid and electrical vehicles, wind power generation and energy storage.

Dr Rupert Young Advanced manufacturing, fibre-optic communications, photo-refractive holography, holographic optical memory, four-wave mixing, spatial light modulators, dynamic light-shaping elements, optical pattern recognition, optical filtering, and electro-optic systems design.

Machine vision and image-processing: neural networks, Wiener filtering, foveating systems, mobile image acquisition, biometrics, image processing for medical diagnosis.

Sensor Technology Research Centre (STRC)

The STRC is a world-leading centre focusing on electric and magnetic sensor technologies and their applications. The focus is on the acquisition of weak electrical signals in challenging environments. The research attracts funding from EPSRC, TSB, the EU and a number of industrial collaborators.

The Centre has pioneered a new class of device with generic measurement capability, the Electric Potential Sensor (EPS). This has attracted considerable attention, winning a number of prestigious awards and gaining wide publicity in the technical press. The first generation of the EPS has been licensed to industrial partners and is now being marketed as an integrated circuit device.

Research activity includes the fundamentals of sensor operation, modelling of measurement scenarios and application specific projects. These applications are very broad and include electrophysiological monitoring, such as cardiac imaging and wireless linked electroencephalogram arrays, muscle and eye signal detection for human-machine interfacing and assistive technologies, security, forensics, geophysical measurements in collaboration with the British Geological Survey, materials characterisation for the semiconductor industry, and electric field detection of nuclear magnetic resonance (NMR) signals. 

The research also covers the area of mobile and wireless communications focused on improving capacity, power and spectrum efficiency, reliability, quality of service, and low complexity implementations. Work involves theoretical studies, simulations, and implementations using advanced software tools and digital hardware. The research impacts a number of important areas in the communications industry and practical systems in different sectors such as health, transport, energy, security and environment.

The Centre is well resourced with electro-magnetically shielded rooms, clean rooms, electron beam lithography fabrication, electronic systems spanning dc-to-microwave, and surface mount fabrication facilities.

Faculty research interests include:

Dr Falah Ali Mobile communications: digital communication techniques, multiple access, multiple antenna/MIMO, channel coding, co-operative communications, distributed video coding.

Wireless networks: adhoc networks, wireless sensor networks, vehicular communications, real-time and high-reliability communications.

Embedded digital systems: advanced communication algorithms on embedded digital hardware, DSP and FPGA. Development of testbed demonstrators with integrated networks.

Dr Ahmet Aydin Non-invasive sensors, electric field sensors for geophysical measurements, electric field detection of NMR signals.

Dr Helen Prance Electric field sensors for assisted living, human-machine interfaces, remote detection of life signs and nuclear resonance detection.

Professor Robert Prance Sensors for electric and magnetic field imaging, charge fingerprint imaging, non-destructive testing of materials, and low-noise instrumentation.

Thermo-Fluid Mechanics Research Centre (TFMRC)

The TFMRC is a dedicated research laboratory specialising in flow and heat transfer, and has substantial experimental and computational facilities. It has a proven track record in research, particularly in relation to gas turbine engines, and has attracted significant funding over previous years from industry, the European Commission and the EPSRC to conduct cutting-edge research on a wide range of engineering problems. It is now engaged in a major collaboration with GE Aviation.

The Centre has a significant experimental research infrastructure including a number of high-pressure air supplies such as the Rolls-Royce DART engine-driven compressor. It also hosts the DANTEC Centre of Excellence in Non-Invasive Instrumentation and has an array of state-of-the-art flow instrumentation including laser anemometry, particle imaging velocimetry (PIV), phase Doppler anemometry (PDA) and hot wire anemometry.

The Centre has expertise in temperature measurements including thermal imaging and liquid crystal measurements, as well as an in-house computational fluid dynamics code, SURF, which is an unstructured general-purpose compressible flow and aeroelasticity solver. Current experimental projects funded by GE Aviation are focused on internal air systems of gas turbine engines.

Faculty research interests include:

Dr Vasudevan Kanjirakkad Experimental aerodynamics/heat transfer, turbomachinery aerodynamics, rotating disc and swirling flows, turbulence and boundary layer transition, flowinstrumentation, sustainable energy.

Dr Christopher Long Experimental heat transfer and fluid-flow measurements, turbulence, application of optically based measurements, and sustainable and renewable energy.

Dr Hao Xia Computational fluid dynamics, computational aeroacoustics, large-eddy simulation, turbomachinery heat transfer, level set method.

Dr Zhiyin Yang Large-eddy simulation, flow stability and transition, turbulent combustion, two phase flow, gas turbine combustion system, heat transfer, and turbine machinery flow.

Careers and profiles

The continued demand for highly qualified engineers worldwide ensures that our graduates are able to choose professional careers in industry and academia. 

Our Engineering Business Management degree is designed to meet the strong demand from engineering-based companies and organisations for their technical specialists to be proficient in project management, to be aware of and understand the global business environment and to be capable of achieving leadership management positions. The continued demand for highly qualified engineers worldwide means that – with a combination of technical, business and management knowledge you will have gained from this course – employment opportunities will be available in a wide range of sectors including transportation, manufacturing, energy-supply and sustainable-energy industries, telecommunications, electronics, automotive, and control. The combination of subjects, together with the project, ensures that on successful completion of this course doctoral study is also an option. 

School and contacts