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Research at the University of Southampton's Airbus Noise Technology Centre (ANTC) and the Rolls-Royce University Technology Centre (UTC) in Gas Turbine Noise has given Airbus and Rolls-Royce tools to understand, predict and reduce noise pollution from commercial aircraft, ensuring that they are on track to meet the EU's stringent noise reduction targets, and maintaining their competitive edge over key rivals Boeing, GE and Pratt and Whitney. The implementation of new low-noise technology from Southampton has already begun to benefit the millions of people who live near our busiest airports (250,000 within the inner 57dBA Leq contour at Heathrow alone).
Work at the Institute of Sound and Vibration Research (ISVR) has led to a sophisticated new understanding of a number of multiple-input multiple-output (MIMO) problems in acoustics. The effects are wide ranging, attracting heavyweight industry sponsors and driving valuable new innovations in home entertainment, construction, aviation and defence. In particular, research has led to the deployment of new "active" methods for controlling noise and vibration within aircraft. Systems have been installed in over 200 propeller aircraft since January 2008, giving a total number of 1000 aircraft treated to date and benefitting 177 million passengers worldwide. Noise reduction systems based on patents resulting from the unique ISVR methods are being developed for maritime use by BAE Systems. The underpinning science has significantly cut the cost of noise tests on Rolls-Royce jet engines, saving US$4 million to date and reducing their environmental impact. It has led to the development of mass-produced systems for living-room 3D sound, global sales of which have reached US$7.2 million.
Research at the University of Bradford has resulted in more accurate and efficient predictions of traffic sound propagation and faster determination of sound reflection effects, enabling more effective design and positioning of noise barriers. Software derived from our research is used in 40 countries to map traffic noise and plan evidence-based targeting of Noise Reduction Devices (NRDs), thus increasing efficiency and sustainability. Beneficiaries include the public, through improved quality of life from reduced noise pollution from transport and wind turbine sound, and governments and public administrations through policy tools to influence noise management. The reach of our research is demonstrated by its incorporation into national and EU-wide policy and guidance on sustainability in design and use of NRDs.
The School of Engineering at MMU has longstanding research into many aspects of railway engineering. This commenced in 1998 under the leadership of Professor Simon Iwnicki, who carried out research into the interaction between railway vehicles and the track. The understanding of the dynamics of the wheel rail contact that has resulted from this work has been developed into a number of tools and techniques that are being used on a daily basis by the rail industry both to design new railway systems and to predict the deterioration of railway wheels and rails. This allows railway engineers to predict and control roughness growth on rails and to optimise wheel profiles and maintenance intervals on wheel and track.
This work is now helping the railway industry internationally to realise both economic and environmental impacts as track maintenance costs are reduced, safety levels are enhanced and passengers continue to switch from road to rail in increasing numbers. This is evidenced by the award of new research contracts and industry funding and by direct input into industry standards.
Research carried out in UCL's Department of Mathematics addresses the accurate coupling of acoustic source fields to noise propagation models, for the determination of far-field environmental noise exposure. The work has increased understanding of issues related to noise propagation from infrastructure including roads and wind turbines, in the UK and internationally. For example, it has led to changes in thinking about freeway noise mitigation strategies at Arizona Department of Transportation (ADOT), discussion of concerns about the UK's assessment of noise propagation from wind turbines by the Institute of Acoustics, and improved understanding of sound-related issues associated with a gas compressor station in the southwestern US that are of interest to local Indian tribes. The research also stimulated interest and discourse by groups and individuals including the Acoustic Ecology Institute in the US, a community group in Germany, Washington State Department of Transportation, the US Federal Aviation Administration, and an artist based in Berlin.
Research undertaken at the University of Manchester (UoM) considers the association between aircraft noise, human health and everyday life. In partnership with an eminent Japanese acoustic scientist, the issue of noise emanating out of the Kadena US airbase (Okinawa Island) and Tokyo Narita Airport was addressed through the creation of an innovative exhibition. The key impact is that local government officials in Japan used the exhibition to enhance their own and citizen groups' understanding of acoustic science. This has helped to breach a long-standing impasse in negotiations over aircraft noise, involving citizens, local authorities, the military and the private sector. In addition, the research has been utilised by the makers of a leading sound-monitoring device (Nittobo), and the multimedia exhibition has been displayed and discussed outside Japan.
Theoretical and experimental research on urban sound environments has been carried out by Professor Kang and his team at the University of Sheffield since 1999. This includes acoustic theories and models for urban sound propagation, soundscape theory and framework, and acoustic theories for sustainable building elements. Consequently, they have developed design guides/ tools that have become common standards in professional practice; invented sustainable low-noise products that have led to commercial outputs; organised networks and workshops that have set up the practice agenda for designing better urban sound environments; and delivered keynote presentations to international audiences of planning professionals and government policy-making organisations.
In research that challenges the dichotomy of music/ noise, Drever has investigated the properties and subjective effects of the high volumes produced by ultrafast hand dryers, finding that it is highly aversive for vulnerable groups including people with dementia, sensory impairments, and autistic spectrum disorders, in some cases exacerbating their social avoidance. These effects have been communicated to the public, industry professionals, and policymakers through a combination of creative art works and presentations of the research findings in varied public settings. They have been widely reported in the international media, via both general interest and specialist publications and programmes. He has worked closely with the UK's Noise Abatement Society and with industrial designers, who have welcomed his input to helping them improve hand dryer design.
ERPE, through the application of XiTRACK technology (using advanced polyurethane polymers to reinforce the ballast matrix, enhancing strength, stiffness and resilience) — has reduced track maintenance by a factor of up to 40, increased maintenance intervals from 3-monthly to 10 years with track speeds increased up to 125 mph in critical sections of the UK, Italy and Hong Kong rail networks. Developments in Finite Element (FE) geomechanics related to Rayleigh waves are used by HS2; and FE backed artificial neural networks are informing US High Speed operators on ground borne vibrations. The financial impact of XiTrack is estimated at least £50M; and avoidance of Rayleigh wave problems and ground borne vibration mitigation, in the region of £10M; plus benefits to millions of passengers.
The UK Rail Industry has set itself a target of increasing capacity by a factor of two within 30 years for both passengers and freight. A central problem is to increase the capacity and performance of the (existing) rail network. Signalling systems and their safety is a major consideration. It is towards this long-term goal that we direct our research activity on signalling. Our research impacts both current practices and strategic planning within the Railway Industry: