The IoT4Win will establish a European Industrial Doctorates (EID) training program and extend the traditional academic research training setting, equipping researchers with right combination of research-related and transferable competences, joint research training programme combines an interdisciplinary expertise of European research group, industry partners and user organisations, bring together all required knowledge, skills, and stakeholders to offer a comprehensive set of transferable skills and a training programme on ICT, data science and water engineering, including industry practice and longer-term benefit in further industrial partner collaborations and further knowledge transfer. IoT4Win will respond to well defined and interdisciplinary scientific questions and challenges on IoTs for Smart Water Network (SWN) technological area cooperating to recruit 3 ESRs to undertake research in the context of a joint research training on concepts and methodologies of IoT enabled SWN towards the PhD. IoT4Win designs 3 individual and personalised research projects covering the core SWN research areas, i.e. smart sensing and trusted communication within energy limited heterogeneous devices in IoT enabled urban water environment; dynamic sensor web and interoperable open platform with Integrated Knowledge Management for smart water networks; data security and intelligence in IoT enabled SWN. The interdisciplinary collaborations and cross industrial interactions between ICT and water sector, will expose researchers to the academic, non-academic sectors. By combining three projects, an interoperable, secure and intelligent underlying technology leading to an open platform for IoT enabled SWN applications will be developed. This platform will then be applied to and evaluated in the real water scenarios with our end user industrial partner, leading to a specialised technology platform for SWN and a best-practice smart water network demonstrator.

To develop flexible secure access to product histories to stimulate new markets and communicate design developments for AGA R&D, their suppliers, and specifying architects/designers.

STEAM thinking is a process which promotes collaboration between the Arts, Science, Technology, Engineering and Maths. Its direct relation, STEM thinking (prioritising Science, Technology, Engineering and Maths, only), has typically been understood as a way of delivering the skills required for high-tech, high-value jobs, and so seen as critical to economic prosperity. Increasingly, this position has been expanded to incorporate the benefits that ‘artistic’ practice can provide. In particular, approaches that favour clear application of creativity and imagination, in combination with more typically understood STEM skills such as numeracy and analysis, are considered to be routes to deeper insight and more transformative innovation. Obviously, what constitutes creativity and imagination is a potentially contentious point, but an outlook that focuses on the areas of intersection between the arts and the sciences leads to certain, tangible benefits, including: techniques for collaborating across disciplines; the ability to consider varied perspectives; and the identification of points of common ground between seemingly unrelated areas of thought. The resulting competencies are combinatorial in nature and, in an HE setting, find expression in courses such as design engineering, digital arts and data visualisation.Whilst arguments for supporting STEM are well rehearsed, STEAM, is becoming more and more prevalent in the HE sector. This is not only as a way of ensuring that students acquire the multi- trans- and inter-disciplinary skills required for the future jobs market, but also to increase intellectual curiosity and, through collaborative approaches, to prime them in developing solutions to multi-aspect global challenges. Furthermore, an HE institution with STEAM at its centre, is well positioned to develop new and responsive curricula that move beyond the traditional segregation of faculties and schools found in most European universities.Whilst a number of approaches to multi-, trans- and inter-disciplinary learning currently exist, to date, no comprehensive scheme has been developed to identify the specific effectiveness of HE STEAM approaches. The STEAM INC project seeks to address this, and the rising importance of STEAM in HE, by way of three objectives:1. Identify points of intersection across current European HE STEAM approaches and develop a collaborative definition of HE STEAM2. Produce methodologies for the implementation of STEAM thinking in HE education, policy and engagement3. Create an evaluation framework for measuring the effectiveness of STEAM processes in HEIs and HE partner organisationsThe partnership is made up of six higher educational institutions currently delivering STEAM approaches. They have been selected for their foresight in adopting process which span traditionally separate areas of thought.Birmingham City University (lead partner)Central St Martins College, University of Arts LondonTrinity College - Science Gallery DublinAalto University, Helsinki Amsterdam University Dresden Technical UniversityThe seventh partner is Ars Electronica, which is a unique, world-renowned platform for art, technology and society, hosting an annual festival in September each year, where the work of the project will be showcased, tested and demonstrated. The activities in STEAM INC will centre on five, linked processes: 1) collaborative definition of work packages at transnational partner meetings 2) cross-partner development of STEAM learning resources through working-group leads 3) international training events at which HE staff, students and partners are invited to experience new STEAM methods and approaches 4) pre and post questionnaires identifying increased understanding of STEAM thinking 5) refinement and publication of final STEAM resources. This will result in a STEAM approaches Handbook; guidance for STEAM implementation across HE education, policy and engagement; and a framework for STEAM evaluation.It is envisaged that the impacts of the project will be wide-ranging and sustainable, including:•More confident and effective arguments for including cross-disciplinary collaboration in HE strategies•Clearer positioning on the value of STEAM in HE and so more streamlined routes to implementation•Deeper student competencies in multi-, trans- and inter- disciplinary practices•More stimulating curriculum design•Expansion of methods for assessing student work•Better designed cross-faculty and cross-school projects and proposals•More rewarding external partnershipsThe potential longer-term benefits of the project include an increased awareness of the value of 'artistic' skills and their application; a more agile HE sector (through appreciation of different perspectives and competencies); and an increased ability for Universities to tackle global challenges and generate innovations.

To establish an innovative manufacturing process management capability.

To develop a bespoke Knowledge-Based Engineering software design tool to simplify design processes and accelerate take up of modular-build housing.