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A total of 34 British Olympic Gold medal triumphs in Beijing (2008), Vancouver (2010) and London (2012), [redact 14 words] relied to a greater or lesser extent on research in fluid dynamics, instrumentation and [redact 4 words] originating from the University of Southampton's Performance Sport Engineering Laboratory (PSEL). Global media coverage of the science behind these victories has raised the profile of British engineering. PSEL was awarded a 2012 Queen's Anniversary Prize for its sustained contribution to the competitiveness of the UK's sailing and motorsport industries worldwide through its research, specialist consultancy services and its high-quality engineering graduates.
From strains within a single carbon fibre to deflections in a bridge, dam or railway line, accurate measurement is vital to industry and public infrastructure. In many engineering contexts, traditional approaches to measurement are inadequate or involve unacceptable costs and delays. These shortcomings have been addressed by the University of Bristol's research into high-precision, video-based metrology and its application through Imetrum, a spin-out company. Imetrum was founded in 2003 and launched its first product - the Video Gauge - in 2007. In the area of mechanical testing, the company has brought the first video-based extensometry system that can be supplied calibrated to international standards to market. For structural monitoring and safety inspections, deformation measurements are usually required. The Imetrum system is being used to precisely measure such deformations in rail bridges and other vital parts of the infrastructure without costly and inconvenient interruptions to their operation. Imetrum has approximately doubled its turnover each year since 2007. [text removed for publication].
Low-cost wireless solutions beyond the technologies available previously and developed at Loughborough University since 2005 are used by IDC, and Sure, who integrate these technologies in several products and services so generating impacts in terms of:
The technologies have been deployed in a logistics distribution centre (ToysRUs), an automotive manufacturing process (Toyota), and a safety and security system (Sure).
Modern processor architectures (networked multi/many-core nodes), together with society's expectation of evermore-complex applications, require fluent mastery of concurrency. To enable this mastery, in the last two decades our group has taught, researched and developed fundamental notions of concurrency, new programming languages (occam-pi, and the KRoC toolset), libraries (JCSP, CCSP, C++CSP, CHP), runtime systems (the KRoC/CCSP multicore scheduler) and tools based on formal process algebra (Hoare's CSP, and Milner's pi-calculus).
Our work has had impact in providing new mechanisms for software development in a number of sectors such as chip design, large-scale real-time systems, formal interfaces and testing and the space industry. Testimonials supporting this are available from a variety of industrial and commercial sources (NXP Semiconductors, Big Bee Consultants, Philips Healthcare, 4Links Ltd. and Microsoft Research Cambridge). The breadth of impact of the work is evidenced by download statistics, as well as by third-party contributions to libraries and documentation.
Practical Waveform Engineering, developed at Cardiff, is having a major impact on how modern- day microwave power amplifiers are designed, delivering real competitive advantages for global communications companies such as Nokia-Siemens-Networks and M/A-COM.
Economic impact is through reduced time-to-market and lower design costs, leading to high- performance power amplifier products. Examples include $40M revenue and employment of additional staff for M/A-Com, and the successful spin-off company Mesuro Ltd., generating revenue in excess of £2.5M.
Impact on practice is through successful demonstration of new device technologies and amplifier architectures, the introduction of PWE-based CAD models, and most significantly, the introduction of the "Cardiff Model" into mainstream simulation tools.
Environmental Impact is by improving the efficiency of power amplifiers and significantly reducing the carbon contribution of mobile communications systems, translating into savings of approximately £2.5M/year and a 17 kiloton reduction in CO2 emission for a typical EU network.
The Imperial College Pile `ICP' effective-stress pile design approaches for offshore foundations offer much better design reliability than conventional methods. Their use delivers substantial economies in many hydrocarbon and renewable energy projects, better safety and confidence in developing adventurous structures in others. The ICP has enabled production in otherwise unviable marginal hydrocarbon fields, new options in high-value deep-water projects and helped eliminate installation failures that can cost hundreds of £million. We present evidence that the research delivered direct benefits exceeding £400m since 2008 in projects known to us, with larger worldwide benefits through project risk reduction and independent exploitation.
Impact: New business, technology, intellectual property and employment resulting from the invention and exploitation of a micro-scale laboratory device (ScreenTapeTM).
Significance: New business and technology commercialised resulting in sales of novel products worldwide, acquisition by Agilent Technologies Limited (Agilent) for £[text removed for publication] in 2011, product sales of over £[text removed for publication] to August 2013, generation of sustained employment for 50-160 people, major inward investment (£6M) by local investors followed by a US multinational.
Beneficiaries: The economy, commerce, employment, research and diagnostic laboratories, Agilent Technologies Inc. (Agilent).
Attribution: UoE Prof Peter Ghazal and Dr Douglas Roy inventors on granted patent, establishment of multi-disciplinary research in biochip medicine, collaborators with ex-Motorola engineers, co-founders of spin-out company for commercialisation of intellectual property.
Reach: Worldwide, including employment and product sales. Inward investment to UK.
The supply of electrical energy to centres of demand is an increasingly important issue as our power generation sources decarbonise. Without innovation in our use of high voltage cables, security of supply to our major cities cannot be guaranteed. Our research has:
The GRANIT system is a non-destructive technique for assessing the condition of rock bolts and ground anchors used to support structures such as tunnels. It applies a small impulse to the bolt and interprets the resulting vibration response to provide estimates of load and unbonded length. Initial development of the system was based on the findings of EPSRC projects in tunnels undertaken by the Universities of Aberdeen and Bradford from 1989-1997, resulting in an empirically based method. However, research undertaken at the University of Aberdeen since 1998 has provided the understanding of the process and developed the fundamental engineering science needed to underpin the development of a full commercial system. The GRANIT system is patented, and has been subject to worldwide licence to Halcrow who have undertaken testing and provided a method of ensuring the safety of mines, tunnels and similar structures. Halcrow received the NCE award for Technical Innovation Award for GRANIT in December 2010. The impact of the research has been in part economic, but largely on practitioners and professional services.
Driven by concerns over public health and intensifying legislative demands of the food industry in Europe and USA, the reliable and effective removal of unwanted objects from food products at a processing stage is increasingly important. The assurance of food quality and safety throughout the pre- and post-harvest food chain makes this issue even more significant. The effective implementation of relevant technological solutions for food safety and quality can dictate the survival, growth and competitive edge of some major sectors of the economy.
Food sorting machines are essential for eliminating unwanted food items from the production process to ensure that quality is maintained at the highest level for consumers. Key research at City University London has led to the development of a unique solenoid actuator valve (ejector), which opens and closes a high-pressure air jet in such machines to remove defective food items more accurately and efficiently from the production line.
The sorting machines which use it have a fivefold improvement in consumer food quality and safety and are 20% more energy efficient. Sales of these machines have been enhanced by 50% as a consequence of these improvements. The new valve delivers approximately 50% less food waste during the first sorting pass and offers a fourfold reduction in power consumption, contributing positively to global agricultural sustainability. The work undertaken has also assisted the industrial partner in opening up a new market for sorting machines for sorting plastics.