Over thirty six months, this project aims to demonstrate the potential of a highly disruptive zero emission, high efficiency electricity generator concept for use in transport and power generation applications. A Zero-Emission Closed-loop linear-Joule CYcle (ZECCY) engine generator which yields only liquid water as an emission (i.e. no particulates, or gas phase emissions). As such, it is analogous with hydrogen-fuel cell technology but more lightweight, potentially more efficient and based on a well-established UK manufacturing base. This project will demonstrate the true potential of this technology for vehicle applications by: a. Completing the manufacture, assembly and commissioning of a concept demonstrator through the development of an existing test platform b. Gather the evidence required to advance the project successfully by conducting a robust testing programme underpinned by rigorous simulation and performance improvement. c. Establish the future case of ZECCY generator technology through the development of a technical and commercial roadmap to deployment.

Over thirty six months, this project aims to demonstrate the potential of a highly disruptive zero emission, high efficiency electricity generator concept for use in transport and power generation applications. A Zero-Emission Closed-loop linear-Joule CYcle (ZECCY) engine generator which yields only liquid water as an emission (i.e. no particulates, or gas phase emissions). As such, it is analogous with hydrogen-fuel cell technology but more lightweight, potentially more efficient and based on a well-established UK manufacturing base. This project will demonstrate the true potential of this technology for vehicle applications by: a. Completing the manufacture, assembly and commissioning of a concept demonstrator through the development of an existing test platform b. Gather the evidence required to advance the project successfully by conducting a robust testing programme underpinned by rigorous simulation and performance improvement. c. Establish the future case of ZECCY generator technology through the development of a technical and commercial roadmap to deployment.

The Foot-LITE project will deliver innovative driver/vehicle interface systems and services to encourage sustained changes to driving styles and behaviours which are safer, reduce congestion, enhance sustainability, help reduce traffic pollution emissions, and reduce other social and environmental impacts. Fundamental research will be used to support the strong industry base in the project through prototype systems development and design, impact assessments and the further development of research tools and processes, including the SRIF/TRW funded instrumented vehicle to deliver a credible evidence-based validation of the system through to real-world operational experiences with user feedback and evaluation. The Foot-LITE system is seen as a tool to encourage and challenge drivers to achieve very real benefits that are already available in the current vehicle fleet but whose benefits cannot be readily maximised without an advisory interface to the driver. The approach has the ultimate choice and control still resting with the individual. This is seen to be crucial to the public and commercial acceptability of Foot-LITE. The aim of the Foot-LITE project is to create a revolutionary driver information system designed to educate and encourage safer and greener driving and longer term behavioural changes. The project consists of four Foot-LITE Work Areas. Effective Project Management is crucial to the delivery and testing of technologies and the assessment of their impacts. This Work Area will be the responsibility of the Lead Partner MIRA who encompasses both commercial as well as research expertise. The second Work Area is Market Reviews and Delivery which is focussed on the development of the concept and identification of product opportunities and system enhancements. The third work area, Technical Implementation, will create innovative applications which influence driver behaviour; this will be led by TRW. The fourth Work Area, which is led by TRG (the Academic Lead Partner), uses a variety of approaches, including simulation and large scale fleet trials, to produce an Impact Assessment of the systems and services and to identify those characteristics which will support applications in a future policy and market environment and deliver a tool that has the potential in instigating a step change in driver behaviour to tackle the twin problems of safety and the environment. The project will undertake all the necessary research and development to produce a prototype system which will be evaluated by fleets of drivers in normal driving conditions. The necessary data collection/data base systems for the vehicle fleet will also be developed so that robust evidence of the effectiveness (or otherwise) of the system will be collected, analysed and published to better the overall knowledge in this area. Additional surveys of other user groups to determine long term effects will be undertaken to better determine market opportunities and implementation strategies to deliver future intelligent vehicles and associated infrastructure. The system to be developed in the project comprises an aftermarket, standalone vehicle interface (although installation during vehicle build will not be excluded) giving moment-to-moment feedback during a drive (similar to SatNav), plus a back office support tool for off-line analysis of journeys and retrospective feedback.

The Foot-LITE project will deliver innovative driver/vehicle interface systems and services to encourage sustained changes to driving styles and behaviours which are safer, reduce congestion, enhance sustainability, help reduce traffic pollution emissions, and reduce other social and environmental impacts. Fundamental research will be used to support the strong industry base in the project through prototype systems development and design, impact assessments and the further development of research tools and processes, including the SRIF/TRW funded instrumented vehicle to deliver a credible evidence-based validation of the system through to real-world operational experiences with user feedback and evaluation. The Foot-LITE system is seen as a tool to encourage and challenge drivers to achieve very real benefits that are already available in the current vehicle fleet but whose benefits cannot be readily maximised without an advisory interface to the driver. The approach has the ultimate choice and control still resting with the individual. This is seen to be crucial to the public and commercial acceptability of Foot-LITE. The aim of the Foot-LITE project is to create a revolutionary driver information system designed to educate and encourage safer and greener driving and longer term behavioural changes. The project consists of four Foot-LITE Work Areas. Effective Project Management is crucial to the delivery and testing of technologies and the assessment of their impacts. This Work Area will be the responsibility of the Lead Partner MIRA who encompasses both commercial as well as research expertise. The second Work Area is Market Reviews and Delivery which is focussed on the development of the concept and identification of product opportunities and system enhancements. The third work area, Technical Implementation, will create innovative applications which influence driver behaviour; this will be led by TRW. The fourth Work Area, which is led by TRG (the Academic Lead Partner), uses a variety of approaches, including simulation and large scale fleet trials, to produce an Impact Assessment of the systems and services and to identify those characteristics which will support applications in a future policy and market environment and deliver a tool that has the potential in instigating a step change in driver behaviour to tackle the twin problems of safety and the environment. The project will undertake all the necessary research and development to produce a prototype system which will be evaluated by fleets of drivers in normal driving conditions. The necessary data collection/data base systems for the vehicle fleet will also be developed so that robust evidence of the effectiveness (or otherwise) of the system will be collected, analysed and published to better the overall knowledge in this area. Additional surveys of other user groups to determine long term effects will be undertaken to better determine market opportunities and implementation strategies to deliver future intelligent vehicles and associated infrastructure. The system to be developed in the project comprises an aftermarket, standalone vehicle interface (although installation during vehicle build will not be excluded) giving moment-to-moment feedback during a drive (similar to SatNav), plus a back office support tool for off-line analysis of journeys and retrospective feedback.

Power electronics and electrical machines are key components in a low-carbon future, enabling energy-efficient conversion and control solutions for a wide variety of energy and transportation applications. The strength of the UK manufacturing base and its strategic importance to the UK was highlighted in the UK government strategy document "Power Electronics: A Strategy for Success" (UK government Department for Business Innovation and Skills, October 2011). This calls for concerted action across the industrial and academic communities to ensure that the full potential of this growing global market can be realised for the UK economy. Specific recommendations relevant to the UK academic community include: 1) the development of a co-ordinated strategy for postgraduate training; 2) support for research focussing on underpinning the core technology areas whilst ensuring that the national capability in Power Electronics remains internationally leading; 3) establishment of a Virtual Centre linking world-class UK universities with each other and with industry. A core team including the universities of Bristol, Cambridge, Greenwich, Imperial College, Manchester, Newcastle, Nottingham, Sheffield, Strathclyde and Warwick, has been formed to develop this proposal for a UK Virtual Centre. Our vision is that the Centre will be the UK's internationally recognised provider of world-leading, underpinning power electronics research, combining the UK's best academic talent. It will focus on sustaining and growing power electronics in the UK by delivering transformative and exploitable new technologies, highly skilled people and by providing long-term strategic value to the UK power electronics industry. Centre activities will be divided into three main strands: research, community and pathways to impact. Our research activities will bring together the leading academic research groups from across the UK to address key research challenges, build critical mass and develop a widely recognised internationally leading research capability. We will develop a UK research strategy for power electronics which will build on foresight activities to inform our research direction. Our community support activities will build capacity through the training of researchers at doctoral and postdoctoral level. We will extend our research funding to the broader community through themed calls for pump priming, strategic support and feasibility projects. In addition we will support and coordinate responses to major initiatives from national and international funding bodies. Pathways to impact will include: 1) the establishment and development of the Centre brand and communication mechanisms, 2) the development and implementation of an exploitation plan which benefits UK industry, 3) support for government policy development and 4) the development of collaborative links with key power electronic research teams around the world. The Centre programme focuses on fundamental power electronics research at low technology readiness level (TRL) and hence supports a wide range of application areas with a medium to long-term time horizon. Key challenges to be addressed are: increased efficiency, increased power density, increased robustness, lower electromagnetic interference (EMI), higher levels of integration and lower through life cost. The work programme is split into four high-level themes of Devices, Components, Converters and Drives, each of which will address the key challenges, supported by a coordinating Hub. The themes will deliver the majority of the technical output of the Centre.