This project will develop sound methods for future climate change data for building designers to use for new buildings and refurbishments that could last to the end of this century. The principal application output will be a draft Technical Memorandum (TM) for the Chartered Institution of Building Services Engineers, CIBSE, suitable for practising designers. This will be supported by extensive case studies to validate the new weather data design methodology and be used in research tasks described later. 'Story lines' relevant to different scenarios for the climate and built environment will be developed as well as risk levels in building design to enable designers to use the weather data with confidence. The TM will provide CIBSE with a consistent methodology for the selection and use of future data for its new Design Guide, a fundamental document used by designers of buildings and their services and a supporting document for the Government's Building Regulations. The basis for this project will be the UK Climate Impacts Programme (UKCIP) future scenarios to be published in 2008 (UKCIP08) from which may be derived probabilities of different weather outcomes over this century. Academic outputs will include an extensive assessment of the carbon reduction potential of active and passive systems and designs for new and refurbished buildings. They will utilise case studies with PC simulation of the building and systems, employing the new probabilistic weather data. These assessments will provide designers and policy makers with guidelines to help reduce the growth in greenhouse gases (GHGs) from buildings, which at present contribute about 50% of the UK emissions. Other academic outputs will provide the theoretical basis underlying the proposed consistent PC-based and manual design methodology with coincident, probabilistic future weather data parameters such as solar radiation, air temperature, wind speed and direction. It is known that solar radiation and air temperature have peak values at different times and on different days but current design methods do necessarily separate them so that over-design often occurs. A related academic output will be a theory underpinning the selection of the proposed new Design Reference Year (DRY) which will facilitate building design (including passive and active heating and cooling systems and comfort assessment) with simulation on a PC. The DRY will replace the currently unsatisfactory Design Summer Year. Solar radiation data, not covered in detail in the HadRM3 and UKCIP02 models, will be developed to satisfy designers' requirements. Likewise wind data (crucial to include since wind drives natural ventilation) although the confidence level will be lower. Rainfall duration and quantity are also important in the building design process because of drainage and rain penetration damage and designers' requirements will again be reviewed.'Urban heat island' effects (urban areas are often hotter than the nearby rural areas), briefly mentioned in the present Guide, will be incorporated in the new data, developing on SCORCHIO work to provide more realistic urban weather data. Local modification or downscaling will also be applied to generate data for other sites in the UK. This will enable the new Guide to cover more than the current 14 sites for which data were developed by Manchester for CIBSE.To ensure that the new, probabilistic outputs will be useful to professionals, and to reflect best practice in design, there will be strong stakeholder involvement through the formation of a Stakeholders Group, including Corresponding Members, which will include CIBSE, architects and software houses and housebuilders. Policy interests will be reached via the Department for Communities and Local Government, and DEFRA and their contractors, such as BRE. There will be links to the Manchester-led EPSRC SCORCHIO urban heat island and climate change project, UKCIP and the Tyndall Centre.

Reducing carbon emissions and securing energy supplies are crucial international goals to which energy demand reduction must make a major contribution. On a national level, demand reduction, deployment of new and renewable energy technologies, and decarbonisation of the energy supply are essential if the UK is to meet its legally binding carbon reduction targets. As a result, this area is an important theme within the EPSRC's strategic plan, but one that suffers from historical underinvestment and a serious shortage of appropriately skilled researchers. Major energy demand reductions are required within the working lifetime of Doctoral Training Centre (DTC) graduates, i.e. by 2050. Students will thus have to be capable of identifying and undertaking research that will have an impact within their 35 year post-doctoral career. The challenges will be exacerbated as our population ages, as climate change advances and as fuel prices rise: successful demand reduction requires both detailed technical knowledge and multi-disciplinary skills. The DTC will therefore span the interfaces between traditional disciplines to develop a training programme that teaches the context and process-bound problems of technology deployment, along with the communication and leadership skills needed to initiate real change within the tight time scale required. It will be jointly operated by University College London (UCL) and Loughborough University (LU); two world-class centres of energy research. Through the cross-faculty Energy Institute at UCL and Sustainability Research School at LU, over 80 academics have been identified who are able and willing to supervise DTC students. These experts span the full range of necessary disciplines from science and engineering to ergonomics and design, psychology and sociology through to economics and politics. The reputation of the universities will enable them to attract the very best students to this research area.The DTC will begin with a 1 year joint MRes programme followed by a 3 year PhD programme including a placement abroad and the opportunity for each DTC student to employ an undergraduate intern to assist them. Students will be trained in communication methods and alternative forms of public engagement. They will thus understand the energy challenges faced by the UK, appreciate the international energy landscape, develop people-management and communication skills, and so acquire the competence to make a tangible impact. An annual colloquium will be the focal point of the DTC year acting as a show-case and major mechanism for connection to the wider stakeholder community.The DTC will be led by internationally eminent academics (Prof Robert Lowe, Director, and Prof Kevin J Lomas, Deputy Director), together they have over 50 years of experience in this sector. They will be supported by a management structure headed by an Advisory Board chaired by Pascal Terrien, Director of the European Centre and Laboratories for Energy Efficiency Research and responsible for the Demand Reduction programme of the UK Energy Technology Institute. This will help secure the international, industrial and UK research linkages of the DTC.Students will receive a stipend that is competitive with other DTCs in the energy arena and, for work in certain areas, further enhancement from industrial sponsors. They will have a personal annual research allowance, an excellent research environment and access to resources. Both Universities are committed to energy research at the highest level, and each has invested over 3.2M in academic appointments, infrastructure development and other support, specifically to the energy demand reduction area. Each university will match the EPSRC funded studentships one-for-one, with funding from other sources. This DTC will therefore train at least 100 students over its 8 year life.

The Innovative Construction Research Centre (ICRC) is dedicated to socio-technical systems research within the built environment, with particular emphasis on through-life performance in support of the client's business operations. Our vision is for a research centre that not only supports the competitiveness of the architectural, engineering, construction and facilities management sectors, but also supports societal needs for built infrastructure and the broader competitiveness of the UK economy. The domain of enquiry lies at the crucial interface between human and technical systems, thereby requiring an inter-disciplinary approach that combines engineering research methods with those derived from the social sciences. The ICRC's research portfolio is organised into six themes: (1) Integration of design, construction and facilities management. Concerns the through-life management of socio-technical systems within the built environment. Topics of consideration include: integrated logistic support, design for reliability and systems integration for building services. Of particular concern is the way that firms within the supply chain are integrated to provide solutions that add value to the client's business. (2) Knowledge management and organisational learning. Addresses the means of supporting knowledge flows across extended supply chains and the extent to which procurement systems learn across projects. Of particular importance is the design of learning mechanisms that extend across organisational boundaries. Also investigates the degree to which the construction sector can learn from other sectors, i.e. aerospace, automotive, retail, defence. (3) Human resource management and the culture of the industry. The construction sector is too often characterised by regressive approaches to human resource management (HRM) with little emphasis on developmental to support innovation. Of particular importance is the concept of 'high commitment management' that has emerged as a central component in the quest to link people management to business performance. Any attempt to improve HRM practices in the construction sector must also recognise cultural barriers to the implementation of new ways of working.(4) Innovative procurement. Includes legal, economic and organisational aspects of procurement systems. The last twenty years has seen a plethora of new procurement methods seeking to encourage different behaviours and allocations of risk. Many such initiatives experienced significant reality gaps between technological intent and resultant behaviours. Of particular importance in the current context is the notion of performance-based contracting which seeks to reward parties on the basis of building performance.(5) Innovation in through-life service provision. Most innovation in facilities management (FM) is concerned with service provision rather than the design and construction of the built asset. The inclusion of FM-service provision reflects the ICRC's strategic focus on through-life issues. The shift towards service provision is reflected in practice through procurement approaches such as PFI/PPP. But the issue has a wider significance as construction contractors increasingly embrace service philosophy. (6) Competitiveness, productivity and performance. Focuses on techniques for performance improvement, coupled with a broader emphasis on competitiveness and profitability within the marketplace. Techniques for performance improvement include: process mapping, benchmarking, value management, risk management and life-cycle costing. Also seeks to assess the competitiveness of the construction sector in comparison to other countries, and to achieve a broader understanding of the economic context within which firms operate.

This project will develop sound methods for future climate change data for building designers to use for new buildings and refurbishments that could last to the end of this century. The principal application output will be a draft Technical Memorandum (TM) for the Chartered Institution of Building Services Engineers, CIBSE, suitable for practising designers. This will be supported by extensive case studies to validate the new weather data design methodology and be used in research tasks described later. 'Story lines' relevant to different scenarios for the climate and built environment will be developed as well as risk levels in building design to enable designers to use the weather data with confidence. The TM will provide CIBSE with a consistent methodology for the selection and use of future data for its new Design Guide, a fundamental document used by designers of buildings and their services and a supporting document for the Government's Building Regulations. The basis for this project will be the UK Climate Impacts Programme (UKCIP) future scenarios to be published in 2008 (UKCIP08) from which may be derived probabilities of different weather outcomes over this century. Academic outputs will include an extensive assessment of the carbon reduction potential of active and passive systems and designs for new and refurbished buildings. They will utilise case studies with PC simulation of the building and systems, employing the new probabilistic weather data. These assessments will provide designers and policy makers with guidelines to help reduce the growth in greenhouse gases (GHGs) from buildings, which at present contribute about 50% of the UK emissions. Other academic outputs will provide the theoretical basis underlying the proposed consistent PC-based and manual design methodology with coincident, probabilistic future weather data parameters such as solar radiation, air temperature, wind speed and direction. It is known that solar radiation and air temperature have peak values at different times and on different days but current design methods do necessarily separate them so that over-design often occurs. A related academic output will be a theory underpinning the selection of the proposed new Design Reference Year (DRY) which will facilitate building design (including passive and active heating and cooling systems and comfort assessment) with simulation on a PC. The DRY will replace the currently unsatisfactory Design Summer Year. Solar radiation data, not covered in detail in the HadRM3 and UKCIP02 models, will be developed to satisfy designers' requirements. Likewise wind data (crucial to include since wind drives natural ventilation) although the confidence level will be lower. Rainfall duration and quantity are also important in the building design process because of drainage and rain penetration damage and designers' requirements will again be reviewed.'Urban heat island' effects (urban areas are often hotter than the nearby rural areas), briefly mentioned in the present Guide, will be incorporated in the new data, developing on SCORCHIO work to provide more realistic urban weather data. Local modification or downscaling will also be applied to generate data for other sites in the UK. This will enable the new Guide to cover more than the current 14 sites for which data were developed by Manchester for CIBSE.To ensure that the new, probabilistic outputs will be useful to professionals, and to reflect best practice in design, there will be strong stakeholder involvement through the formation of a Stakeholders Group, including Corresponding Members, which will include CIBSE, architects and software houses and housebuilders. Policy interests will be reached via the Department for Communities and Local Government, and DEFRA and their contractors, such as BRE. There will be links to the Manchester-led EPSRC SCORCHIO urban heat island and climate change project, UKCIP and the Tyndall Centre.

This project will develop sound methods for future climate change data for building designers to use for new buildings and refurbishments, most of which will last to the end of this century. The outputs will primarily be: academic papers and a draft for a Chartered Institution of Building Services Engineers, CIBSE, Technical Memorandum, suitable for practising designers; case studies to validate the new weather data design methodology and assess the potential adaptation of new and refurbished buildings to reduce carbon emissions. This TM will also be useful for CIBSE to use to determine a consistent future weather design methodology and future data for its new Design Guide, which is the fundamental document used by Building Services Engineers for designing buildings and their services. It is a supporting document for the Government's Building Regulations. The basis for this CIBSE data will be the new UK Climate Impacts Programme, UKCIP, future scenarios due in 2008, UKCIP08, with probabilities of various future weather outcomes for this century.To ensure that the new, probabilistic outputs will be useful to professionals, and to reflect best practice in design, there will be strong stakeholder involvement through the formation of a Stakeholders Group, via CIBSE, (Weather Task Force and collaborating consultancies), the Manchester-led EPSRC SCORCHIO project, (looking at urban heat island and climate change vulnerability, with contacts to UKCIP and the Tyndall Centre), architects and software houses. Policy makers will be reached via the Stakeholder Group Corresponding Members linked to the Department for Communities and Local Government and their contractors, including BRE. Risk levels will be assessed and data provided to enable designers to use the data with confidence. This bottom-up approach will serve to inform policy makers of what can be achieved practically. In addition there will be numerous case studies for validating the new methodology andTo provide this consistency, a novel method will be developed which will allow UKCIP08 scenarios and probabilistic weather data to be the basis of design which takes into account coincident weather parameters, e.g. solar radiation, air temperature, wind speed and direction. It is known that solar and air temperature have profound and sometimes differing influences on the comfort and carbon emissions of the building and that design values in the Guide are not necessarily coincident. Thus the hottest summer (or summer day) may well not be the sunniest summer (or day). New building design indices will be developed, with the aid of the current building designs contributed by members of the Stakeholder Group and collaborators. Solar radiation data, not covered in detail in the HadRM3 and UKCIP02 models, will be developed to satisfy designers' requirements. Likewise wind data, although the confidence level will be lower. It will be crucial to include wind data since wind drives natural ventilation. Rainfall duration and quantity are also important in the building design process because of drainage and rain penetration damage and designers' requirements will again be reviewed.Urban heat island effects, (where the urban areas are often hotter than the nearby rural areas), briefly mentioned in the present Guide, will be developed from the EPSRC SCORCHIO work to provide more realistic urban weather data. Local modification or downscaling will also be applied to generate data for other sites in the UK. This will enable the new Guide to cover more than the current 14 sites for which data were developed by Manchester for CIBSE