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Local authorities, the UK government and the European Commission have benefitted from the widespread application of new molecular methodologies, developed in 2005 and applied by the University of Reading's Vertebrate Pests Unit (VPU) to identify and quantify anticoagulant rodenticide resistance in rodent populations. Rodents are a major global pest that consumes our food, causes contamination with urine and faeces, damages structures through gnawing, transmits diseases, and impacts on species of conservation concern. Due to historical success and recent regulatory restrictions, anticoagulant rodenticides are the most common control method for these pests. However, physiological resistance to anticoagulants is now widespread and the VPU has been involved in mapping this resistance and identifying the genetic basis for the resistance. Their research has led to new methodologies to identify anticoagulant resistance that have been adopted by the global plant science industry and to new guidance in treating resistant populations that has been adopted by the European biocides industry.
The performance of absolute distance measuring systems has been improved in terms of accuracy, traceability, reliability and cost through the introduction of new methodology arising from research at the University of Oxford. This has brought commercial benefit to a German company making measurement systems, through the creation of a new product line. New capabilities for measurement have been delivered to a first customer in Germany. The research has also resulted in the establishment of new activity at the National Physical Laboratory, and influenced UK and European technology roadmaps for future manufacturing.
The case study captures and describes the outputs and impacts arising from cumulative research on the theme of accessibility in transport and urban design. Impacts are evidenced both through the research process in terms of end-user engagement, collaborative research and real world test bed research (local communities and neighbourhoods); and through intermediary and professional/ practitioner body validation, policy-making and take up of research findings and guidance/toolkits arising. Impacts have also occurred through wider dissemination, follow-up research and collaboration both nationally and internationally.
The Beazley Archive Online Database enables large and diverse audiences to access and understand ancient art through Oxford research. It allows users around the world to ask and answer their own research questions and to learn about ancient imagery. It is principally dedicated to the study of ancient Athenian figure-decorated pottery and ancient/neo-classical engraved gems. It makes available hundreds of thousands of pictures and information-fields which can be browsed and searched in a variety of ways, according to the level and requirements of the user. The Database is the foremost academic tool for the study of ancient Greek pottery, but its demonstrable impact extends far beyond academia, to an international audience of students, educators, museums, businesses, and private researchers.
Series of images from animal behaviour studies contain vast quantities of complex and highly valuable data. Extracting the value from this scientific data often requires expert annotation. This is frequently an intuitive process based on experience gained through years of training to make important decisions. Experts are rare, expensive and hard to train so the iBehave project at the University of Edinburgh (2006-2009) sought to reverse this model and deliver systems that learned to mimic expert annotation of video data. This effort resulted in a new spinout from the School of Informatics, a software company called Actual Analytics Ltd (Actual). Founded in 2010, Actual delivers innovative software solutions for behaviour analytics which use machine learning algorithms to process video data of laboratory animals to improve the accuracy of the experimental process and reduce the need to use animals in scientific research.
Climate change will have a profound impact on built environment performance over the next 50 years. More severe flooding and overheating will lead to more obsolete buildings and premature mortality across the UK and Europe. The research team explored the issues surrounding adaptation of the built environment to climate change, and developed a new model of built asset management that integrates adaptation decision making into the building life cycle. The model is being used by facilities managers and surveyors to produce long term asset management plans, and by central and local government policy makers to inform and develop adaptation strategies.
Reduction of unpleasant ambient noise during MRI has been enabled through innovative engineering solutions developed at the Medical Research Council Institute of Hearing Research (MRC IHR). Intellectual property was licensed to Optoacoustics Ltd and the resulting OptoActive™ active noise-cancelling headphones for MRI are the only one of their type commercially available, enabling free conversation between patients and clinicians. The product was formally launched in September 2012 and has worldwide sales including in the USA, Europe, Asia and the Middle East.
Founded in York in 1996, the Archaeology Data Service (ADS) has transformed how archaeological research is communicated in the UK, and impacted digital archiving throughout the world. Without the ADS, much of the fragile digital data (often the primary record of sites now destroyed) would have been lost. Instead, they are freely available to all. This impact extends across national heritage agencies, local government, commercial archaeology, and the public. Our resources are widely used with over two million page requests per month; almost half from beyond the HE sector. A recent study has concluded that the ADS is worth £5m per annum to the UK economy (Beagrie & Houghton 2013). The ADS has helped shape the digital preservation policy of English Heritage and informed practice in the United States, Australia, Canada, the Netherlands, Sweden, and Germany.
Using advanced mathematics and numerical modelling we have demonstrated how fundamental understanding of laminar-turbulent transitions in fluid flows can save energy. From 2008 we helped the cleantech company, Maxsys Fuel Systems Ltd, to understand and improve their technology and demonstrate to customers how it can reduce fuel use by 5-8%. Customers including Ford Motor, Dow Chemical and Findus testify to the impact from financial savings and reduced carbon emissions obtained by installing Maxsys products on industrial burners used widely in many industrial sectors including automotive, bulk chemicals and food. In 2010, Selas Heat Technology Company bought the Maxsys brand to invest in this success.
Research in materials modelling by the Computational Science and Engineering Group (CSEG) is helping aerospace, defence and transport companies design advanced materials and new manufacturing processes. From lightweight components like aeroengine turbine blades to the control of magnetic fields to stabilise the next generation of International Space Station levitation experiments, CSEG is supporting innovations which have:
In the assessment period, CSEG collaborated closely with leading industries in steel-making (ArcelorMittal, Corus), primary aluminium (Dubal, Rusal, Norsk-Hydro, SAMI) and lightweight structural materials for transport and aerospace (European Space Agency, Rolls-Royce).