Some are familiar with the ability to programme computers such as PCs or laptops. However many individuals that do not engage in programming will purchase and use such applications. In contrast to these visible boxes , embedded computers hidden within appliances such as fridges and washing machines traditionally cannot be programmed by users. They are also used extensively in cars for engine control and supplementing breaking and steering. They are essentially invisible. However as computers become more powerful and cheaper we are witnessing a merging of these philosophies . Mobile phones contain computers which are both hidden and programmable with downloadable apps . There is now the potential to go further and make computers embedded in (say) appliances programmable after they are in place.Advances in communications now allow such computers to be linked together. They become networked computers . So screens on fridges can show web pages, cars can communicate speed and speed history to each other, and a mobile phone can control the lights in your home.In addition small cheap sensors, often with their own small computers are being developed. Small cheap actuators are also appearing. Actuators might simply switch lights on and off, but they can also control the flow of fuel to an engine. They too can communicate with each other. So in addition to sensing the environment, computer systems can use actuators to control and change it. But how is this control exercised? It may be manual so a user on a wireless PDA might set the temperature of the home central heating. However there is much excitement in the research community in how an array of networked small computers can cooperate to automatically alter the behaviour of a system. A simple example would be positional information on family mobile phones controlling their home environment.The integration of these technologies also offers the advent of new applications; in the home for homecare and healthcare; in the hospital for patient monitoring and support; and in the office to boost productivity. This project proposes to inform the public about this potent mix of technologies and explain the importance of their integration. We will develop a highly interactive show in partnership with the Glasgow Science Centre to be presented to large audiences through its Science Show programme. We want to describe the technologies, and use recent research work to show the audience the potential possibilities of their integration, and how this will radically alter the way we think about and use computers. To support the show we will provide additional, more detailed material for educational use and for those who wish to explore the topic further. While conventional web based interfaces will be used, we expect to have a presence in YouTube and also to explore newer virtual worlds such as Second Life. The project is being carried out by two universities, Glasgow and Stirling and each brings essential and compatible aspects to the project. Glasgow offers experience in effective public engagement, and evaluation, while Stirling will bring the research drive and technological expertise. The two groups have already collaborated together and with Glasgow Science Centre on successful PE and research projects.We plan to carry out the work in three phases. In the first three month phase we will design the show in detail. Once this is in place, the equipment will be assembled and the necessary software developed. This second phase will last just 9 months as existing research prototypes can be used as a base. In the final 4 month phase the show will be evaluated and refined using the Science Centre Theatre with audiences. Training of Science Centre staff will also take place in this phase. It is also at this stage that the Science Centre will take over the regular delivery of the show for both their regular in-house shows and to their external outreach programme

In a consortium led by Heriot-Watt with St Andrews, Glasgow, Strathclyde, Edinburgh, Dundee, Huddersfield and NPL, the "EPSRC CDT in Use-Inspired Photonic Sensing and Metrology" responds to the focus area of "Meeting a User-Need and/or Supporting Civic Priorities" and aligns to EPSRC's Frontiers in Engineering & Technology priority and its aim to produce "tools and technologies that form the foundation of future UK prosperity". Our theme recognises the key role that photonic sensing and metrology has in addressing 21st century challenges in transport (LiDAR), energy (wind-turbine monitoring), manufacturing (precision measurement), medicine (disease sensors), agri-food (spectroscopy), security (chemical sensing) and net-zero (hydrocarbon and H2 metrology). Building on the success of our earlier centres, the addition of NPL and Huddersfield to our team reflects their international leadership in optical metrology and creates a consortium whose REF standing, UKRI income and industrial connectivity makes us uniquely able to deliver this CDT. Photonics contributes £15.2bn annually to the UK economy and employs 80,000 people--equal to automotive production and 3x more than pharmaceutical manufacturing. By 2035, more than 60% of the UK economy will rely on photonics to stay competitive. UK companies addressing the photonic sensing and metrology market are therefore vital to our economy but are threatened by a lack of doctoral-level researchers with a breadth of knowledge and understanding of photonic sensing and metrology, coupled with high-level business, management and communication skills. By ensuring a supply of these individuals, our CDT will consolidate the UK industrial knowledge base, driving this high-growth, export-led sector whose products and services have far-reaching impacts on our society. The proposed CDT will train 55 students. These will comprise at least 40 EngD students, characterised by a research project originated by a company and hosted on their site. A complementary stream of up to 15 PhD students will pursue industrially relevant research in university labs, with more flexibility and technical risk than in an EngD project. In preparing this bid, we invited companies to indicate their support, resulting in £5.5M cash commitments for 102 new students, considerably exceeding our target of 55 students, and highlighting industry's appetite for a CDT in photonic sensing and metrology. Our request to EPSRC for £6.13M will support 35 students, with the remaining students funded by industrial (£2.43M) and university (£1.02M) cash contributions, translating to an exceptional 56% cash leverage of studentship costs. The university partners provide 166 named supervisors, giving the flexibility to identify the most appropriate expertise for industry-led EngD projects. These academics' links to >120 named companies also ensure that the networks exist to co-create university-led PhD projects with industry partners. Our team combines established researchers with considerable supervisory experience (>50 full professors) with many dynamic early-career researchers, including a number of prestigious research fellowship holders. A 9-month frontloaded residential phase in St Andrews and Edinburgh will ensure the cohort gels strongly, equipping students with the knowledge and skills they need before starting their research projects. These core taught courses, augmented with electives from the other universities, will total 120 credits and will be supplemented by accredited MBA courses and training in outreach, IP, communication skills, RRI, EDI, sustainability and trusted-research. Collectively, these training episodes will bring students back to Heriot-Watt a few times each year, consolidating their intra- and inter-cohort networks. Governance will follow our current model, with a mixed academic-industry Management Committee and an International Advisory Committee of world-leading experts.

Quantum Technology is based on quantum phenomena that govern physics on an atomic scale, enabling key breakthroughs that enhance the performance of classical devices and allow for entirely new applications in communications technology, imaging and sensing, and computation. Quantum networks will provide secure communication on a global scale, quantum sensors will revolutionise measurements in fields such as geology and biomedical imaging, and quantum computers will efficiently solve problems that are intractable even on the best future supercomputers. The economic and societal benefit will be decisive, impacting a wide range of industries and markets, including engineering, medicine, finance, defence, aerospace, energy and transport. Consequently, Quantum Technologies are being prioritised worldwide through large-scale national or trans-national initiatives, and a healthy national industrial Quantum Technology ecosystem has emerged including supply chain, business start-ups, and commercial end users. Our Centre for Doctoral Training in Applied Quantum Technologies (CDT-AQT) will address the national need to train cohorts of future quantum scientists and engineers for this emerging industry. The training program is a partnership between the Universities of Strathclyde, Glasgow and Heriot-Watt. In collaboration with more than 30 UK industry partners, CDT-AQT will offer advanced training in broad aspects of Quantum Technology, from technical underpinnings to applications in the three key areas of Quantum Measurement and Sensing, Quantum Computing and Simulation, and Quantum Communications. Our programme is designed to create a diverse community of responsible future leaders who will tackle scientific and engineering challenges in the emerging industrial landscape, bring innovative ideas to market, and work towards securing the UK's competitiveness in one of the most advanced and promising areas of the high-tech industry. The quality of our training provision is ensured by our supervisors' world-class research backgrounds, well-resourced research environments at the host institutions, and access to national strategic facilities. Industry engagement in co-creation and co-supervision is seen as crucial in equipping our students with the transferable skills needed to translate fundamental quantum physics into practical quantum technologies for research, industry, and society. To benefit the wider community immediately, we will make Quantum Technologies accessible to the general public through dedicated outreach activities, in which our students will showcase their research and exhibit at University Open Days, schools, science centres and science festivals.

Some are familiar with the ability to programme computers such as PCs or laptops. However many individuals that do not engage in programming will purchase and use such applications. In contrast to these visible boxes , embedded computers hidden within appliances such as fridges and washing machines traditionally cannot be programmed by users. They are also used extensively in cars for engine control and supplementing breaking and steering. They are essentially invisible. However as computers become more powerful and cheaper we are witnessing a merging of these philosophies . Mobile phones contain computers which are both hidden and programmable with downloadable apps . There is now the potential to go further and make computers embedded in (say) appliances programmable after they are in place.Advances in communications now allow such computers to be linked together. They become networked computers . So screens on fridges can show web pages, cars can communicate speed and speed history to each other, and a mobile phone can control the lights in your home.In addition small cheap sensors, often with their own small computers are being developed. Small cheap actuators are also appearing. Actuators might simply switch lights on and off, but they can also control the flow of fuel to an engine. They too can communicate with each other. So in addition to sensing the environment, computer systems can use actuators to control and change it. But how is this control exercised? It may be manual so a user on a wireless PDA might set the temperature of the home central heating. However there is much excitement in the research community in how an array of networked small computers can cooperate to automatically alter the behaviour of a system. A simple example would be positional information on family mobile phones controlling their home environment.The integration of these technologies also offers the advent of new applications; in the home for homecare and healthcare; in the hospital for patient monitoring and support; and in the office to boost productivity. This project proposes to inform the public about this potent mix of technologies and explain the importance of their integration. We will develop a highly interactive show in partnership with the Glasgow Science Centre to be presented to large audiences through its Science Show programme. We want to describe the technologies, and use recent research work to show the audience the potential possibilities of their integration, and how this will radically alter the way we think about and use computers. To support the show we will provide additional, more detailed material for educational use and for those who wish to explore the topic further. While conventional web based interfaces will be used, we expect to have a presence in YouTube and also to explore newer virtual worlds such as Second Life. The project is being carried out by two universities, Glasgow and Stirling and each brings essential and compatible aspects to the project. Glasgow offers experience in effective public engagement, and evaluation, while Stirling will bring the research drive and technological expertise. The two groups have already collaborated together and with Glasgow Science Centre on successful PE and research projects.We plan to carry out the work in three phases. In the first three month phase we will design the show in detail. Once this is in place, the equipment will be assembled and the necessary software developed. This second phase will last just 9 months as existing research prototypes can be used as a base. In the final 4 month phase the show will be evaluated and refined using the Science Centre Theatre with audiences. Training of Science Centre staff will also take place in this phase. It is also at this stage that the Science Centre will take over the regular delivery of the show for both their regular in-house shows and to their external outreach programme

In a consortium led by Heriot-Watt with St Andrews, Glasgow, Strathclyde and Dundee, this proposal is for an EPSRC CDT in Applied Photonics and responds to the Integrative Technologies priority area, but also impacts on the Measurement and Sensing, Photonic Materials and Innovative Production Processes priorities. Technologies integrating photonics and electronics pervade products and services in any modern economy, enabling vital activities in manufacturing, security, telecommunications, healthcare, retail, entertainment and transport. The success of UK companies in this technology space is threatened by a lack of doctoral-level researchers with a grasp of photonic- / electronic-engineering design, fabrication and systems integration, coupled with high-level business, management and communication skills. By ensuring a supply of these individuals, our CDT will deliver broad-ranging impacts on the UK industrial knowledge base, driving the high-growth export-led sectors of the UK economy whose photonics-enabled products and services have far-reaching impacts on society, from consumer technology and mobile computing devices to healthcare and security. Building on the success of our current IDC in Optics and Photonics Technologies, the proposed CDT will again be configured as an IDC but will enhance our existing programme to meet industry's need for engineers able to integrate photonic and electronic devices, circuits and systems to deliver high value products and processes. Our proposal was developed in partnership with industry, whose letters of support show a commitment to sponsoring 71-74 EngD and 14-17 PhD projects -- 40% more than the minimum required -- demonstrating exceptional industrial engagement. Major stakeholders include Fraunhofer UK, NPL, Renishaw, Thales, BAE Systems, Gooch and Housego and Selex ES, who are joined by a number of SMEs. The CDT follows a model in which (annually) EPSRC funds 7 EngD students, with 3 more supported by industrial / university contributions. In a progressive strategy supported by our industrial partners, we will, where appropriate, align university-funded PhD projects to the programme to leverage greater industry engagement with PhD research in the consortium. The focus of the CDT corresponds to areas of research excellence in the consortium, which comprises 89 academic supervisors, whose papers since 2008 total 584 in all optics journals , with 111 in Science / Nature / PRL, and whose active EPSRC PI photonics funding is £40.9M. All academics are experienced supervisors, having each supervised on average >6 doctoral students, with many previously acting as IDC supervisors. The strategic commitment by the participating universities is evidenced by their recruitment since 2008 of 29 new academic staff in relevant areas (including 9 professors). An 8-month frontloaded residential phase in St Andrews and Glasgow will ensure the cohort strongly gels together, and will equip students with the technical knowledge and skills they need before they begin their industrial research project. Business modules (x3) will bring each cohort back to Heriot-Watt for 1-week periods, and weekend skills workshops will be used to regularly reunite the cohort, further consolidating it to create opportunities for peer-to-peer interactions. Taught courses will total 120 credits, and will be supplemented by new Computational Methods, Systems Integration and Research Skills workshops delivered by our industry partners, as well as public-engagement training led by Glasgow Science Centre. Another innovation is an International Advisory Board, comprising leading academics / industrialists , who will benchmark and advise on our performance. The requested EPSRC support of £4.5M is complemented by £2.8M of industrial / academic cash, covering the cost of 3 students in each cohort of 10. In-kind industrial / academic contributions are worth a further £5.4M, providing exceptional value.