Engineering (MSc by Research)

2020-21 (also available for 2021-22)

This course is eligible for Master's loan funding. Find out more.

Start date

21 September 2020

18 January 2021

19 April 2021

Duration

The maximum duration for a full-time MSc by Research is 1 year (12 months) with an optional submission pending (writing up period) of 4 months.

Sometimes it may be possible to mix periods of both full-time and part-time study.

Application deadlines

For PGR start date January 2021

20 November 2020

For PGR start date April 2021

26 February 2021

For PGR start date July 2021

11 June 2021

For PGR start date September 2021

02 July 2021

About the research degree

A Master's by Research (MSc) allows you to undertake a one year (full-time) research degree. It contains little or no formal taught component. This type of study gives you the chance to explore a research topic over a shorter time than a more in-depth doctoral programme.

Research Master's students choose a specific project to work on and have a greater degree of independence in their work than is the case with a taught Master’s course.

You’ll be expected to work to an approved programme of work which you will develop in conjunction with your supervisor within the first few months of starting your studies.

Whilst undertaking the research project you will also have the opportunity to develop your research skills by taking part in training courses and events .

The approved programme of training and research combines advanced study, research methodology and a substantial research project, or series of research projects in a chosen field.

You will be appointed a main supervisor who will normally be part of a supervisory team, comprising up to three members to advise and support you on your project.

At the end of the project you write up your findings in the form of a short thesis not normally exceeding 25,000 words (excluding ancillary data), which will then be examined.

On successful completion, you will be awarded your degree and if you have enjoyed this taste of research you may then decide to apply for the full research doctoral degree (PhD).

Entry requirements

The normal entry requirements for enrolment on a MSc by Research is an upper second honours degree (2.1) from a UK university or a qualification of an equivalent standard, in a discipline appropriate to that of the proposed programme to be followed.

If your first language is not English, you will need to meet the minimum requirements of an English Language qualification. The minimum for IELTS is 6.0 overall with no element lower than 5.5, or equivalent will be considered acceptable. Read more about the University’s entry requirements for students outside of the UK on our Where are you from information pages.

Why choose Huddersfield?


There are many reasons to choose the University of Huddersfield and here are just five of them:

  1. We were named University of the Year by Times Higher Education in 2013.
  2. Huddersfield is the only University where 100% of permanent teaching staff are Fellows of the Higher Education Authority.
  3. Our courses have been accredited by 41 professional bodies.
  4. 94.6% of our postgraduate students go on to work and/or further study within six months of graduating.
  5. We have world-leading applied research groups in Biomedical Sciences, Engineering and Physical Sciences, Social Sciences and Arts and Humanities.

What can I research?

There are several research topics available for this degree. See below examples of research areas including an outline of the topics, the supervisor, funding information and eligibility criteria:

Outline

Wind farm efficiency is somewhat determined by turbine efficiency, which in tum depends upon wake effects. Turbines situated wholly or partially in the wake of leading turbines are severely restricted in their efficiency, according to size, wind speed and direction and spacing between turbines. The aim of the project is to create a semi-analytical model of air flow behind a horizontal axis wind turbine, principally for use by wind farm designers in the industry. Current models are either too crude to be of certain value or too sophisticated (or time­ consuming) to be incorporated into iterative turbine placement design schemes or software. The most common and crudest model still in use was devised in 1983. Applicants will need a sound Mechanical or Energy Engineering background and a good understanding of the near field aerodynamics of a horizontal axis wind turbine. The project requires a very numerate approach and a good background in applications of mathematics would also be required. For calibration and validation of the model a number of simulations using Computational Fluid Dynamics will be necessary and applicants should be well versed in this type of work, preferably using ANSYS Fluent or similar software.

Funding

Please see our Research Scholarships page to find out about funding or studentship options available.

Deadline

Our standard University deadlines apply. Please see our Deadlines for Applications page to find out more.

Supervisors

How to apply

Outline

Renewable energy is an essential source for harnessing natural forces such as wind energy in an age which is very conscious of the environmental effects of burning fossil fuels, and where sustainability is an ethical norm. Therefore, the focus is currently on both the adequacy of long-term energy supply, as well as the environmental implications of particular sources. In that regard, the near certainty of costs being imposed on carbon dioxide emissions in developed countries has profoundly changed the economic outlook of clean energy sources. Wind turbines have vastly been developed in recent decades due to technology becoming more advanced. Since there is a continuous exhaustion of fossil fuels, it is of high interest with government encouragement to utilise wind technology. Wind turbines are currently advancing into cross-flow vertical axis operation, whereby research has shown a significant increase in performance compared to existing technologies. The need for sustainable energy sources becomes greater each year due to the continued depletion of fossil fuels and the resulting energy crisis. Solutions to this problem are potentially in the form of wind turbines, for sustainable urban environment, that have been receiving increased support. At present, a number of wind turbines have been developed that show significant increase in performance compared to existing technologies.

Funding

Please see our Research Scholarships page to find out about funding or studentship options available.

Deadline

Our standard University deadlines apply. Please see our Deadlines for Applications page to find out more.

Supervisors

How to apply

Outline

Multi component and multiphase mixture flows take place through a number of industrial stems and contribute to a number of processes. Some practical examples of such flows are solid-liquid flow, solid-gas flow, solid-liquid-gas flow, oil - water flow etc. Some of the most common industries where these flows are encountered are Nuclear Industry, Mining Industry, and Chemical Industry etc. The operation, monitoring and control of these flows need detailed knowledge about the flow characteristics of individual components and individual phases. The problem becomes especially complex if the flows are taking place through complex geometries for example helical pipes, elbows valves etc. Through this project novel techniques will be developed to understand local flow features associated with individual components and phases and integrating this information to develop design tools/standards for these processes. The special computational/experimental techniques developed will enable quantification of interphase interaction mechanism. It is expected that the work carried out under this project will enable removal of empiricism embedded in design methodologies to a large extent. It will further allow development of methodologies to trouble free operation and energy use optimisation for such systems.

Funding

Please see our Research Scholarships page to find out about funding or studentship options available.

Deadline

Our standard University deadlines apply. Please see our Deadlines for Applications page to find out more.

Supervisors

How to apply

Outline

A prilling tower is an integral part of any fertilizer plant. A hot fluid (normally urea) is sprayed from a nozzle at the top of the tower forming droplets of urea. These droplets fall under the action of gravity, releasing their energy content, and hence, forming solid prills of urea, which is extensively used as a fertilizer. It is often seen that a lot of the prills formed at the base of the tower doesn't have enough strength to remain in the form of a prill; hence, they disintegrate into powder, wasting an excessive amount of the product. This happens because of ineffective cooling in the tower. The current research work will look into the dynamic of vortex rings for effective cooling purposes within a prilling tower. Vortex rings are inherent in nature and have been a topic of interest for almost a millennium. The urge to utilise vortex rings for multi-purpose applications, such as in cooling of urea droplets in a prilling tower, has led to the development of various types of vortex rings. However, in-depth analysis of the flow phenomena associated with vortex rings is still very little known. This study will investigate the dynamics of a vortex ring's generation, propagation and its ultimate dissipation within a prilling tower. The effect of the geometrical, flow and fluid parameters on the rolling—upof the fluid's shear layers will be analysed using a number of analytical, experimental and numerical techniques. It is expected that this study will result into a practical device that can be installed on the top of the prilling tower, which can enhance the cooling process, hence substantially reducing the waste powder.

Funding

Please see our Research Scholarships page to find out about funding or studentship options available.

Deadline

Our standard University deadlines apply. Please see our Deadlines for Applications page to find out more.

Supervisors

How to apply

Outline

In recorded and mixed form, the history of metal music has involved a broad focus on achieving greater heaviness (Berger & Fales 2005). Importantly though, there is a broad lack of detailed understanding of what heaviness actually is. Changes in performance approaches (especially performance speed), levels of down-tuning - and aspects such as design developments in guitar and bass amplifiers - have impacted our perceptions of heaviness. However, regardless of how these characteristics might or might not inform a given production, a valuable parameter of effective heaviness is clarity. “Sonic clarity can enhance the energy, intensity and impact of each and every sound in a metal production, collectively strengthening the power and drive of the music’s rhythm structures.” Mynett, 2016. With this in mind, by focussing on the mix stage of the music production process, this project sets out to gain a detailed understanding of the correlation between heaviness and clarity.

Funding

Please see our Research Scholarships page to find out about funding or studentship options available.

Deadline

Our standard University deadlines apply. Please see our Deadlines for Applications page to find out more.

Supervisors

How to apply

Outline

Most polymers are limited in their scope of use as a replacement for metals due to the differences in material properties such as strength, thermal expansion, creep, brittleness etc. In order to achieve the required properties, the components need to be redesigned to take the different material properties into account. To allow accurate design analysis, these properties need to be characterised and suitable mathematical models defined. The project will include characterisation of materials with suitable bulk properties to include the variable properties which can be used to improve the performance of the end product, such as polymer chain or reinforcing strand alignment. If a suitable constitutive model is not available, then the relevant mathematical modelling will need to be undertaken to provide the basis for design analysis. This will need to take into account the proposed manufacturing method, which may have influences on the final localised properties of the material. The models developed can then be used to design components which will be tested under typical operating conditions to validate their suitability for replacement of metal components. The student will need a thorough understanding of polymeric materials and non-linear modelling techniques, and preferably some experience of test methodologies.

Funding

Please see our Research Scholarships page to find out about funding or studentship options available.

Deadline

Our standard University deadlines apply. Please see our Deadlines for Applications page to find out more.

Supervisors

How to apply

Outline

Infrastructure systems consist of a number of sub-systems carrying a wide variety of solid-liquid-gaseous materials. Failure of one of the sub-systems may result in release of these materials in an uncontrolled manner. Risk mitigation strategies need to be designed keeping variety of leak scenarios. Furthermore, an array of sensors is needed to provide dispersion characteristics through a well-developed formulation. The information provided through such methods is limited in scope and accuracy in the present work a CFD based solution algorithm will be developed that integrates pre-developed flow scenarios with sensor array information to provide qualitative and quantitative pollutant dispersion characteristics. The developed system will be capable of informing real time pollution dispersion characteristics and will help in developing risk mitigation strategies.

Funding

Please see our Research Scholarships page to find out about funding or studentship options available.

Deadline

Our standard University deadlines apply. Please see our Deadlines for Applications page to find out more.

Supervisors

How to apply

Outline

Development of suitable mathematical models to describe the solar pump demonstrator models as provided by the sponsoring company, and using those models to design a pump suitable to deliver specified amounts of water for agricultural irrigation.

Funding

Please see our Research Scholarships page to find out about funding or studentship options available.

Deadline

Our standard University deadlines apply. Please see our Deadlines for Applications page to find out more.

Supervisors

How to apply

Outline

In the oil-gas fields, slurry flow, gas-in-water two phase flows, and oil-gas-water three phase flows are frequently encountered. Generally, the measurement of volumetric flow rate for each phase is of most interest, especially in subsea oil-gas production applications, where it is essential to obtain oil, water and gas flow rates in inclined oil wells. The problem of how to accurately measure these flow parameters for such complicated flow phenomena, without using expensive test separators and intrusive technique, is a major challenge for the industry. Most conventional multiphase flow meters have severe limitations regarding types of flow and their measurement reliability. Some useful techniques containing radioactive sources are available but they are expensive and potential harmful to humans. Thus, the new developed system will be capable of measuring the local volume fraction local distribution and local velocity distributions of each phase based on tomographic techniques that does not contain a radioactive source.

Funding

Please see our Research Scholarships page to find out about funding or studentship options available.

Deadline

Our standard University deadlines apply. Please see our Deadlines for Applications page to find out more.

Supervisors

How to apply

Outline

The project proposed is to work with a partner company to progress their existing design to a working prototype stage. The company have a patented design for a solar powered generation system which they have demonstrated at laboratory scale, but now want to produce a full scale demonstrator to prove the concept at a workable level. The system is based on a standard steam Rankine cycle, but with significant efficiency improvements. It will provide a means of generating electricity 24/7 with no fossil fuel requirements. The module can be “stand alone” supplying several homes, “tied in” to a local grid to completely power a group of houses or small village type commune, or to operate a medical centre, emergency services. It can be positioned virtually anywhere that power is needed.

Funding

Please see our Research Scholarships page to find out about funding or studentship options available.

Deadline

Our standard University deadlines apply. Please see our Deadlines for Applications page to find out more.

Supervisors

How to apply

Outline

In this project the use of aerodynamic bearings to support the rotor shaft in automotive turbochargers will be investigated. The proposed bearing is supported by a metal foil structure when the shaft rotation is insufficient to generate the aerodynamic forces required to make the bearing self-supporting. The project will include:

• Investigation of the operational requirements for automotive turbocharger rotor bearings comprising load, stiffness and damping characteristics, operating conditions including temperature, shaft speed, gas and inertial loading and importantly, bearing and shaft sizes.

•Development of the multi-physics numerical models required to simulate the aerodynamic effect, the interaction of the generated air film with the metal foil support structure and the damping characteristics provided by friction between the components of the foil support structure.

•Generation of experimental data to validate the numerical models including the design and manufacture of a bearing test rig.

•Production of characteristic load, stiffness and damping curves for foil backed aerodynamic bearings using the validated numerical model.

•Use of a constrained optimization approach to identify the range of feasible bearing designs for automotive applications.

•Modification of an existing hydrodynamic turbocharger bearing housing to use an example aerodynamic bearing and demonstrate the bearing’s feasibility on an engine test bed.

Funding

Please see our Research Scholarships page to find out about funding or studentship options available.

Deadline

Our standard University deadlines apply. Please see our Deadlines for Applications page to find out more.

Supervisors

How to apply

Outline

Additive manufacturing technology, also called 3D printing, enables the construction of customised structures not possible with traditional fabrication methods. 3D printing for medical applications is expanding rapidly and is expected to revolutionize healthcare. For instance, nowadays many personalised healthcare products, e.g. joint implants, dental implants, personalised pharmaceutical drugs, are made by 3D printing. However, a barrier that impedes the increased uptake of 3D printed products to be used as more critical parts is their quality control and verification. Particularly, metrology is essential to ensure that products have correct geometries in all scales to achieve the desired function. Traditional tactile and optical metrology techniques are of limited use due to the light-of-sight restriction. This project will investigate how to use XCT to measure healthcare products, and to develop a set of characterisation methods to evaluate their dimensional accuracy, surface roughness and structural compliance.

(1) Dimensional accuracy The dimensions of customised healthcare products are patient-specific, which allows products to be personalised to match each patient’s individual needs. The measurement and assessment of dimensions of healthcare products are challenging, particularly for products with freeform shapes and lattice/porous structures. Effective approaches to evaluate dimensional geometry of healthcare products with complex shapes will be investigated.

(2) Surface roughness Surface roughness is playing a critical role in boosting functional performance of healthcare products, e.g. osseointegration of joint implants. As-built 3D printed surface is usually rough and often presents various surface topography depending on building orientation, layer thick as well as other relevant process parameters. Assessment of surface roughness in region of interest and the global uniformity using XCT will be investigated.

(3) Structural compliance For healthcare products with lattice and porous structures (e.g. porous scaffold in bone implant and porous lattice for drug release), structural compliance is directly relevant to product’s functioning. The connectivity of lattice cells, porosity rate, pore size distribution, surface areas and structure volume directly influence component’s function, e.g. stiffness, permeability. The evaluation of these measurands using XCT and their relation to functional performance will be investigated.

(4) Case studies A key case study will be to use XCT to quantitatively analyse the internal microstructure of AM lattice structure intended for drug delivery applications. This is via a UoH internal collaboration project with the School of Applied Science.

Funding

Please see our Research Scholarships page to find out about funding or studentship options available.

Deadline

Our standard University deadlines apply. Please see our Deadlines for Applications page to find out more.

Supervisors

How to apply

Outline

This project aims to explore the use of internet of things (IOT) connected wearables in a care home setting to improve early diagnosis of health problems while minimising contact for observations in a post-COVID healthcare environment. The research will determine if automatic periodic measurement of temperature, heart rate and blood pressure and transfer of data to the cloud will allow proactive not reactive treatment of certain conditions, with an aim to reduce resident admission to hospital and hence improve quality of life while reducing care costs and unnecessary risks to patients.

This research will investigate the technology and data management strategy necessary to track long-term health data of residents while considering what architecture is necessary to gain wide acceptance and achieve compliance. Usage of the technology by both residents, care givers and management staff will be analysed and appropriate technology chosen or developed to minimise care disruption while maximising potential benefits. The MSc by research will focus on research and demonstration of appropriate technology and development of a demonstrator and plan to implement it in UK care homes as an early warning system for virus outbreak and resident health challenges.

Funding

Please see our Research Scholarships page to find out about funding or studentship options available.

Deadline

Our standard University deadlines apply. Please see our Deadlines for Applications page to find out more.

Supervisors

How to apply

Outline

This project will deliver a code for inverse design of blade surface for different climatic conditions. The wind turbine systems incorporating these blades will be expected to be effective in extreme weather conditions. The main benefit of this work will be to increase the efficiency of operation of wind turbines in cold regions which will also contribute to the improvement of turbine safety and lifetime.

Funding

Please see our Research Scholarships page to find out about funding or studentship options available.

Deadline

Our standard University deadlines apply. Please see our Deadlines for Applications page to find out more.

Supervisors

How to apply

Outline

This research wishes to investigate ways in which new developments in audio measurement can be utilised in the mixing and mastering process. The study will look at the design and implementation of key developments in Music Information Retrieval (MIR) both from a historical and technical perspective. In addition, recent developments in such areas as touch screen technology will be explored along with visualisation and parameter control. Proposals for new visualisation strategies will be developed along with working prototypes where applicable. The developed ideas could be implemented in C/C++ and/or MATLAB and consequently some of these skills are required. Experience of GUI programming and/or embedded systems and interfacing would be highly desirable but not essential.

Funding

Please see our Research Scholarships page to find out about funding or studentship options available.

Deadline

Our standard University deadlines apply. Please see our Deadlines for Applications page to find out more.

Supervisors

How to apply

Outline

Do modern music production tools provide the user with the necessary information in an intuitive format to quickly and easily produce intended sonic outcomes? Do the physical interfaces enable the user to interact with the provided information effectively? Should music production user interfaces remain reliant on the traditional paradigms or is there a better alternative?

This project aims to reconsider traditional music production interfaces to develop more effective yet simpler interfaces, that provide better visual feedback, interaction and afford greater sonic outcomes. The premise is that music production interfaces should be freed from the constraints of real and visual representations of physical hardware components, such as faders and knobs/encoders, to construct new and intuitive metaphorical interfaces that harness alternative visualisation and sensor technologies. In comparison to the plethora of innovative interfaces for musical expression, core music production tool interfaces have remained largely unchanged since the 1970’s. Furthermore, these interfaces have received relatively scant attention with regard to usability evaluation, leading researchers to question whether these established paradigms really meet the needs and desires of the user.

Funding

Please see our Research Scholarships page to find out about funding or studentship options available.

Deadline

Our standard University deadlines apply. Please see our Deadlines for Applications page to find out more.

Supervisors

How to apply

Outline

This project will address the following hardware constraints of 5G mm-Wave system:

• The mm-Wave band allows us to pack more antennas in the same place which reduces the antenna aperture, resulting in less power captured by the receiver. • The wider bandwidth makes the multipath profile sparse, resulting in a large number of resolvable multipath at the receiver. The complexity of the receiver will be extreme if all these multipaths are resolved. • This wider bandwidth requires an analogue to digital converters (ADC) of higher resolution resulting in a large amount of energy dissipated.

The project will tackle the above issues by designing new signal processing algorithms.

• Proposed signal to noise ratio (SNR) algorithms and the 30 channel will allow rejecting the nearby interferers by the help of angle of arrival (AoA) and angle of departure (AoD) improving the power captured by the receiver. • New techniques will be proposed where multipaths with higher energy are selected and resolved, resulting in reduced complexity and similar performance. • ADCs will be designed that will not operate at the Nyquist rate resulting in less power dissipated.

Funding

Please see our Research Scholarships page to find out about funding or studentship options available.

Deadline

Our standard University deadlines apply. Please see our Deadlines for Applications page to find out more.

Supervisors

How to apply

Outline

The aim of this project is to provide a robust methodology for simulating the interaction between failed wheels in turbochargers and the housings designed to contain them. The project will require the use of advanced numerical simulation techniques and the acquisition of validation data by experimental means. The project will include:

•Investigation of the mechanical properties of wheel and housing materials over the range of typical operating temperatures.

•Development of a data bank of burst wheel configurations (i.e. size and shape of fragments) together with wheel speed and materials. This will be based on historical data held at Huddersfield.

•Expansion of the wheel failure data bank based on continued wheel testing.

•Development of experimental techniques to record the burst event and capture wheel fragments following burst to prevent secondary damage.

•Development of finite element models to simulate impact of the wheel fragments with the turbocharger housing. These models will allow for fragments of a range of sizes and shapes, a range of wheel speeds and variable relative position of fragments and housing features at the moment of burst.

•Use of the finite element models combined with stochastic analysis to determine the probability of worst case scenarios occurring.

Funding

Please see our Research Scholarships page to find out about funding or studentship options available.

Deadline

Our standard University deadlines apply. Please see our Deadlines for Applications page to find out more.

Supervisors

How to apply

Outline

The aim of the research work is to develop an inverse design methodology to develop a unique surface profile for a required functional performance (flow behaviour) and hence it will involve development of an algorithm to generate surface profiles from geometrical parameters characterising the surface as well as develop molecular flow model for flow near the wall surface having artificially created roughness and establish quantitative dependence of surface parameters with flow features very close to the wall. Furthermore development of computational fluid dynamic simulations (continuum based) for flow over wall surface and establish quantitative dependence of surface roughness parameters with flow features away from the wall will be an essential part of this project.

Funding

Please see our Research Scholarships page to find out about funding or studentship options available.

Deadline

Our standard University deadlines apply. Please see our Deadlines for Applications page to find out more.

Supervisors

How to apply

Outline

Additive manufacturing (AM) is paving its way toward the next industrial revolution. However many technical barriers still hinder its full commercialisation today. One major issue is that AM processes are not robust enough and AM needs measurement methods to control its process. This project aims to develop a set of advanced surface topography analysis techniques for the characterisation of additively manufactured (AM) products. Through characterising AM surface topography, the project will contribute to the optimisation of AM process variables, facilitate the functional evaluation of complex AM components and benefit the accurate geometrical measurement of AM products. The proposed research work include: (1) development of numerical analysis methods, including filtration and segmentation, to extract AM process signature features; (2) investigation of the relevance of area surface texture parameters to AM processes; (3) proposal of new parameters to reflect the unique characteristics of AM surfaces; (4) comparison of various surface metrology techniques for AM surfaces, including tactile, optical and x-ray computed tomography; (5) investigation of the influence of AM roughness texture on dimensional measurement; (6) investigation of the impact of AM process variables on produced surface topography; (7) prediction of AM surface topography in terms of AM process variables.

Funding

Please see our Research Scholarships page to find out about funding or studentship options available.

Deadline

Our standard University deadlines apply. Please see our Deadlines for Applications page to find out more.

Supervisors

How to apply

We offer supervision to PhD level in a wide range of areas where we are carrying out state of the art research.

The School of Computing and Engineering has three institutes and a number of research centres and groups that cover a diverse range of topics within Mechanical and Electronic Engineering:

[*] [Institute of Railway Research|http://www.hud.ac.uk/research/researchcentres/irr/]

[*] [Turbocharger Research Institute|http://www.hud.ac.uk/tri/]

[*] [Centre for Innovative Manufacturing in Advanced Metrology|http://www.hud.ac.uk/research/researchcentres/cimam/]

[*] [Institute for Accelerator Applications|http://www.hud.ac.uk/research/researchcentres/iiaa/]

[*] [Centre for Efficiency and Performance Engineering|http://www.hud.ac.uk/research/researchcentres/cepe/]

[*] [Centre for Precision Technologies|http://www.hud.ac.uk/research/researchcentres/cpt/]

[*] [Adaptive Music Technologies Research Group|http://www.hud.ac.uk/research/researchcentres/amtrg/]

[*] [Energy, Emissions and the Environment Group|http://www.hud.ac.uk/research/researchcentres/eeerg/]

[*] [Condition Monitoring and Diagnosis Group|http://www.hud.ac.uk/research/researchcentres/cmdg/]

[*] [Measurement and Data Analysis Group|http://www.hud.ac.uk/research/researchcentres/mdag/]

[*] [Electron Microscopy and Materials Analysis Group|http://www.hud.ac.uk/research/researchcentres/emma/]

[*] [Automotive and Marine Engineering Research Group|http://www.hud.ac.uk/research/researchcentres/ameg/]

[*] [Music Technology and Production Research Group|http://www.hud.ac.uk/research/researchcentres/mtprg/]

[*] [Systems Engineering Research Group|http://www.hud.ac.uk/research/researchcentres/serg/]

To find out more about the research we conduct, take a look at our Research, Innovation and Skills webpages, where you will find information on each research area. To find out about our staff visit ‘Our experts’ which features profiles of all our academic staff.

Researcher Environment

The University of Huddersfield has a thriving research community made up of over 1,350 postgraduate research students. We have students studying on a part-time and full-time basis from all over the world with around 43% from overseas and 57% from the UK.

Research plays an important role in informing all our teaching and learning activities. Through undertaking research our staff remain up-to-date with the latest developments in their field, which means you develop knowledge and skills which are current and relevant to your specialist area.

[Find out more about our research staff and centres|http://www.hud.ac.uk/research/]

Student support

At the University of Huddersfield, you'll find support networks and services to help you get ahead in your studies and social life. Whether you study at undergraduate or postgraduate level, you'll soon discover that you're never far away from our dedicated staff and resources to help you to navigate through your personal student journey. Find out more about all our support services.

Important information

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The Office for Students (OfS) is the principal regulator for the University.