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Details of Grant 

EPSRC Reference: EP/M50676X/1
Title: Hyper Flux
Principal Investigator: Vincent, Dr P E
Other Investigators:
Researcher Co-Investigators:
Project Partners:
Department: Aeronautics
Organisation: Imperial College London
Scheme: Technology Programme
Starts: 15 September 2014 Ends: 14 September 2016 Value (£): 191,981
EPSRC Research Topic Classifications:
Design & Testing Technology Fluid Dynamics
Manufacturing Machine & Plant
EPSRC Industrial Sector Classifications:
Manufacturing
Related Grants:
Panel History:  
Summary on Grant Application Form
Computer simulations of fluid flow are playing an increasingly important role in aerodynamic design of numerous complex

systems, including aircraft, cars, ships and wind turbines. It is becoming apparent, however, that for a wide range of flow

problems current generation software packages used for aerodynamic design are not fit for purpose.

Specifically, for scenarios where flow is unsteady (highly separated flows, vortex dominated flows, acoustics problems etc.)

current generation software packages lack the required accuracy; since they are ubiquitously based on 'low-order' (first- or

second-order) accurate numerical methods. To solve challenging unsteady flow problems, and remove the need for

expensive physical prototyping, newer software based on advanced 'high-order' accurate numerical methods is required.

Additionally, this software must be able to achieve high-order accuracy on so-called 'unstructured grids' - used to mesh

complex engineering geometries, and it must be able to make effective use of next-generation 'many-core' computing

hardware (such as Nvidia Tesla GPUs, Intel Xeon Phi Co-Processors, and AMD FirePro GPUs), which will likely underpin

future HPC platforms.

Advanced high-order Flux Reconstruction (FR) methods, combined with many-core accelerators, could provide a `gamechanging'

technology capable of performing currently intractable unsteady turbulent flow simulations within the vicinity of

complex engineering geometries. However, various technical issues still need to be addressed before the above technology can be used `in anger' to solve real-world flow problems, which often involve `sliding planes' (situations when

two computational meshes slide across one another in a non-conforming fashion). The key objectives (of the academic

component) of the proposal are to develop a treatment for sliding planes that works effectively with FR methods on manycore

accelerators, and demonstrate the performance of FR methods on many-core accelerators for a range of industry led

test cases proposed by the financial (CFMS and Zenotech) and non-financial (Airbus, EADS, BAE, Rolls-Royce, ARA, UK

Aerodynamics Centre) project partners.

The academic component of the proposal will be lead by Dr. Peter Vincent (a Lecturer in the department of Aeronautics at

Imperial College London), and will build upon current work funded by 3 x EPSRC DTAs, 1 x Airbus/EPSRC iCASE DTA,

and an EPSRC Early Career Fellowship (EP/K027379/1).
Key Findings
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Potential use in non-academic contexts
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Summary
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Further Information:  
Organisation Website: http://www.imperial.ac.uk