The computer graphics industry, and in particular those involved with films, games, simulation, virtual reality and military applications, continue to demand more realistic computer-generated images, that is computed images that more accurately match the real scene they are intended to represent. This is particularly challenging when considering images of the natural world, which presents our visual system with a wide range of colours and intensities. In most real scenes, for example, looking from inside a house towards a window, the ratio between the darkest areas (e.g. inside the room) and the brightest area (outside the window), the so-called contrast ratio, could be many thousands to one. A typical computer monitor only has a contrast ratio of about 100:1 and is thus incapable of accurately displaying such scenes.A number of appearance-preserving, or tone-mapping, operators (TMOs) have been developed in order to try achieve a perceptual match between the real-world scene and what is displayed on the computer monitor. However, it has not yet been possible to validate the fidelity of these TMOs thoroughly against the real scenes they are trying to portray. The recent development of novel, high dynamic range (HDR) displays, capable of 75,000:1 contrast ratio now provide the opportunity to compute and display computer-generated images that are perceptually much closer to the real world.This research proposal will use these novel HDR displays to evaluate existing TMOs to see how well they do preserve the appearance of the real scenes, and will use the insights gained to develop new, more accurate TMOs for existing computer monitors and HDR displays. A framework will also be produced that will provide a straightforward, objective way of comparing real and synthetic images. Two applications, which are critically dependent on the realism of computed images, are virtual archaeology and military simulations. When investigating past environments on a computer, failure to produce images that accurately match what the past environment may have looked like, may in fact lead to the archaeologists misinterpreting the past. Similarly, the incorrect display of a military vehicle attempting to camouflage in a certain terrain may lead to detection of the vehicle in the real battlefield scenario. We will use specific examples from archaeology and camouflage to test the results of our research.

The computer graphics industry, and in particular those involved with films, games, simulation, virtual reality and military applications, continue to demand more realistic computer-generated images, that is computed images that more accurately match the real scene they are intended to represent. This is particularly challenging when considering images of the natural world, which presents our visual system with a wide range of colours and intensities. In most real scenes, for example, looking from inside a house towards a window, the ratio between the darkest areas (e.g. inside the room) and the brightest area (outside the window), the so-called contrast ratio, could be many thousands to one. A typical computer monitor only has a contrast ratio of about 100:1 and is thus incapable of accurately displaying such scenes.A number of appearance-preserving, or tone-mapping, operators (TMOs) have been developed in order to try to achieve a perceptual match between the real-world scene and what is displayed on the computer monitor. However, it has not yet been possible to validate the fidelity of these TMOs thoroughly against the real scenes they are trying to portray. The recent development of novel, high dynamic range (HDR) displays, capable of 75,000:1 contrast ratio now provide the opportunity to compute and display computer-generated images that are perceptually much closer to the real world.This research proposal will use these novel HDR displays to evaluate existing TMOs to see how well they do preserve the appearance of the real scenes, and will use the insights gained to develop new, more accurate TMOs for existing computer monitors and HDR displays. A framework will also be produced that will provide a straightforward, objective way of comparing real and synthetic images. Two applications, which are critically dependent on the realism of computed images, are virtual archaeology and military simulations. When investigating past environments on a computer, failure to produce images that accurately match what the past environment may have looked like, may in fact lead to the archaeologists misinterpreting the past. Similarly, the incorrect display of a military vehicle attempting to camouflage in a certain terrain may lead to detection of the vehicle in the real battlefield scenario. We will use specific examples from archaeology and camouflage to test the results of our research.

This proposal seeks to establish a state-of-the-art plasma FIB at Surrey - only the second such instrument in the UK. The system will enable the removal of material in a controlled manner at the nanometre scale. This will enable the manufacture of nanostructures for a wide range of uses, from quantum devices to microscopic mechanical test pieces. The PFIB is equipped with scanning electron microscopy so that as material is removed in a controlled manner so a three dimensional image of the eroded area can be built up. This is tomography on the microscopic scale and enables one to image sub-surface features such as inclusions in a metal alloy, interpenetration of layers in a microelectronics device or corrosion around a second phase particle in a metal. Nanomachining is the other activity that a PFIB will perform well with samples of well defined geometry and/or thickness being produced with lengths varying from tens of nanometres (thickness of an electron transparent specimen) through to just under a millimetere. Once manufactured such specimens can be examined by transmission electron microscopy or a surface analysis technique such as secondary ion mass spectrometry. Thus this equipment bid will provide a new capability with far reaching impact across several themes and many sub-themes of the EPSRC portfolio significantly enhancing existing research both in Surrey and in collaborators across the UK as well as opening up new research possibilities. There are few single instruments currently available that can be applied to so many areas of scientific and engineering research. Materials research, one of the eight great technologies and a current government priority, is by far the most obvious benefactor but the manufacturing capability of the instrument will be applied to other nationally important areas such as experimental physics and metrology. This instrument will be very significant, its versatility and high efficiency has the potential to accelerate impact across many of these themes maintaining the United Kingdom's role as a leading science nation.

This grant will deliver a step change in the understanding and predictability of next generation cooling systems to enable the UK to establish a global lead in jet engine and hypersonic vehicle cooling technology. We aim to make transpiration cooling, recognised as the ultimate convective cooling system, a reality in UK produced jet engines and European hypersonic vehicles. Coolant has the potential to enable higher cycle temperatures (improving efficiency following the 2nd law of thermodynamics) but invariably introduces turbine stage losses (reducing efficiency). Cooling system improvement must enable higher Turbine Entry Temperature (TET) while using the minimum amount of coolant flow to achieve the required component life. For high speed flight, heat transfer is dominated by aerodynamic heating with gas temperatures on re-entry exceeding those at the surface of the sun. Any reduction in heat transfer to the Thermal Protection System will ultimately lead to lower mass, allowing for decreased launch costs Furthermore, the lower temperatures could serve as an enabler for higher performance technologies which are currently temperature limited. The highest temperatures achievable for both jet engines and hypersonic flight are limited by the materials and cooling technology used. The cooling benefits of transpiration flows are well established, but the application of this technology to aerospace in the UK has been prevented by the lack of suitable porous materials and the challenge of accurately modelling both the aerothermal and mechanical stress fields. Our approach will enale the coupling between the flow, thermal and stress fields to be researched simultaneously in an interdisciplinary approach which we believe is essential to arrive at the best transpiration systems. This Progreamme Grant will enable world leaders in their respective fields to work together to solve the combination of cross-disciplinary problems that arise from the application of transpiration cooling, leading to rapid innovations in this technology. The application is timely since the proposed research would enable the UK aerospace industry to capitalise on recent developments in materials, manufacturing capability, experimental facilities/measurement techniques and computational methods to develop the science for the application of transpiration cooling. The High Temperature Research Centre at Birmingham University will provide the means to cast super alloy turbine aerofoils with porosity. The proposed grant would allow innovation in the cast systems arising from combining casting expertise with aerothermal and stress modelling in recent EPSRC funded research programmes. It also builds upon material development of ultra-high temperature ceramics and carbon composites undertaken in EPSRC funded research, by use of controlled porosity and multilayer composites. It will also provide the first opportunity to undertake direct coupling of the flow with the materials (porous and non-porous) at true flight conditions and material temperatures. Recent investment in the UK's wind tunnels under the NWTF programme (EPSRC/ATI funded) at both Oxford University and at Imperial College will allow for direct replication of temperatures and heat fluxes seen in flight and interrogated using advanced laser techniques. Recent development of Fourier superposition in CFD grids for modelling film cooling can now be extended to provide a breakthrough method to predict cooling flow and metal effectiveness for high porosity/transpiration cooling systems. The European Space Agency has recently identified the pressing requirement for alternatives to one-shot ablative Thermal Protection Systems for hypersonic flight. Investment in this area is significant and transpiration cooling has been identified as a promising cooling technology. Rolls-Royce has embarked upon accelerated investment in new technologies for future jet engines including the ADVANCE

Our proposal requests five distinct bundles of equipment to enhance the University's capabilities in research areas ranging across aerospace, complex chemistry, electronics, healthcare, magnetic, microscopy and sensors. Each bundle includes equipment with complementary capabilities and this will open up opportunities for researchers across the University, ensuring maximum utilisation. This proposal builds on excellent research in these fields, identified by the University as strategically important, which has received significant external funding and University investment funding. The new facilities will strengthen capacity and capabilities at Glasgow and profit from existing mechanisms for sharing access and engaging with industry. The requested equipment includes: - Nanoscribe tool for 3D micro- and nanofabrication for development of low-cost printed sensors. - Integrated suite of real-time manipulation, spectroscopy and control systems for exploration of complex chemical systems with the aim of establishing the new field of Chemical Cybernetics. - Time-resolved Tomographic Particle Image Velocimetry - Digital Image correlation system to simultaneously measure and quantify fluid and surface/structure behaviour and interaction to support research leading to e.g. reductions in aircraft weight, drag and noise, and new environmentally friendly engines and vehicles. - Two microscopy platforms with related optical illumination and excitation sources to create a Microscopy Research Lab bringing EPS researchers together with the life sciences community to advance techniques for medical imaging. - Magnetic Property Measurement system, complemented by a liquid helium cryogenic sample holder for transmission electron microscopy, to facilitate a diverse range of new collaborations in superconductivity-based devices, correlated electronic systems and solid state-based quantum technologies. These new facilities will enable interdisciplinary teams of researchers in chemistry, computing science, engineering, medicine, physics, mathematics and statistics to come together in new areas of research. These groups will also work with industry to transform a multitude of applications in healthcare, aerospace, transport, energy, defence, security and scientific and industrial instrumentation. With the improved facilities: - Printed electronics will be developed to create new customized healthcare technologies, high-performance low-cost sensors and novel manufacturing techniques. - Current world-leading complex chemistry research will discover, design, develop and evolve molecules and materials, to include adaptive materials, artificial living systems and new paradigms in manufacturing. - Advanced flow control technologies inside aero engine and wing configurations will lead to greener products and important environmental impacts. - Researchers in microscopy and related life science disciplines can tackle biomedical science challenges and take those outputs forward so that they can be used in clinical settings, with benefits to healthcare. - Researchers will be able to develop new interfaces in advanced magnetics materials and molecules which will give new capabilities to biomedical applications, data storage and telecommunications devices. We have existing industry partners who are poised to make use of the new facilities to improve their current products and to steer new joint research activities with a view to developing new products that will create economic, social and environmental impacts. In addition, we have networks of industrialists who will be invited to access our facilities and to work with us to drive forward new areas of research which will deliver future impacts to patients, consumers, our environment and the wider public.