The world's manufacturing economy has been transformed by the phenomenon of globalisation, with benefits for economies of scale, operational flexibility, risk sharing and access to new markets. It has been at the cost of a loss of manufacturing and other jobs in western economies, loss of core capabilities and increased risks of disruption in the highly interconnected and interdependent global systems. The resource demands and environmental impacts of globalisation have also led to a loss of sustainability. New highly adaptable manufacturing processes and techniques capable of operating at small scales may allow a rebalancing of the manufacturing economy. They offer the possibility of a new understanding of where and how design, manufacture and services should be carried out to achieve the most appropriate mix of capability and employment possibilities in our economies but also to minimise environmental costs, to improve product specialisation to markets and to ensure resilience of provision under natural and socio-political disruption. This proposal brings together an interdisciplinary academic team to work with industry and local communities to explore the impact of this re-distribution of manufacturing (RDM) at the scale of the city and its hinterland, using Bristol as an example in its European Green Capital year, and concentrating on the issues of resilience and sustainability. The aim of this exploration will be to develop a vision, roadmap and research agenda for the implications of RDM for the city, and at the same time develop a methodology for networked collaboration between the many stakeholders that will allow deep understanding of the issues to be achieved and new approaches to their resolution explored. The network will study the issues from a number of disciplinary perspectives, bringing together experts in manufacturing, design, logistics, operations management, infrastructure, resilience, sustainability, engineering systems, geographical sciences, mathematical modelling and beyond. They will consider how RDM may contribute to the resilience and sustainability of a city in a number of ways: firstly, how can we characterise the economic, social and environmental challenges that we face in the city for which RDM may contribute to a solution? Secondly, what are the technical developments, for example in manufacturing equipment and digital technologies, that are enablers for RDM, and what are their implications for a range of manufacturing applications and for the design of products and systems? Thirdly, what are the social and political developments, for example in public policy, in regulation, in the rise of social enterprise or environmentalism that impact on RDM and what are their implications? Fourthly, what are the business implications, on supply networks and logistics arrangements, of the re-distribution? Finally, what are the implications for the physical and digital infrastructure of the city? In addition, the network will, through the way in which it carries out embedded focused studies, explore mechanisms by which interdisciplinary teams may come together to address societal grand challenges and develop research agendas for their solution. These will be based on working together using a combination of a Collaboratory - a centre without walls - and a Living Lab - a gathering of public-private partnerships in which businesses, researchers, authorities, and citizens work together for the creation of new services, business ideas, markets, and technologies.

We are witnessing huge global shifts towards cleaner growth and more resource efficient economies. The drive to lower carbon emissions is resulting in dramatic changes in how we travel and the ways we generate and use energy worldwide. Electrical machines are at the heart of the accelerating trends in the electrification of transport and the increased use of renewable energy such as offshore wind. To address the pressing drivers for clean growth and meet the increasing demands of new applications, new electrical machines with improved performance - higher power density, lower weight, improved reliability - are being designed by researchers and industry. However, there are significant manufacturing challenges to be overcome if UK industry is going to be able to manufacture these new machines with the appropriate cost, flexibility and quality. The Hub's vision is to put UK manufacturing at the forefront of the electrification revolution. The Hub will address key manufacturing challenges in the production of high integrity and high value electrical machines for the aerospace, energy, high value automotive and premium consumer sectors. The Hub will work in partnership with industry to address some common and fundamental barriers limiting manufacturing capability and capacity: the need for in-process support to manual operations in electrical machine manufacture - e.g. coil winding, insertions, electrical connections and wiring - to improve productivity and provide quality assurance; the sensitivity of high value and high integrity machines to small changes in tolerance and the requirement for high precision in manufacturing for safety critical applications; the increasing drive to low batch size, flexibility and customisation; and the need to train the next generation of manufacturing scientists and engineers. The Hub's research programme will explore new and emerging manufacturing processes, new materials for enhanced functionality and/or light-weighting, new approaches for process modelling and simulation, and the application of digital approaches with new sensors and Industrial Internet of Things (IoT) technologies.

High Performance Embedded and Distributed Systems (HiPEDS), ranging from implantable smart sensors to secure cloud service providers, offer exciting benefits to society and great opportunities for wealth creation. Although currently UK is the world leader for many technologies underpinning such systems, there is a major threat which comes from the need not only to develop good solutions for sharply focused problems, but also to embed such solutions into complex systems with many diverse aspects, such as power minimisation, performance optimisation, digital and analogue circuitry, security, dependability, analysis and verification. The narrow focus of conventional UK PhD programmes cannot bridge the skills gap that would address this threat to the UK's leadership of HiPEDS. The proposed Centre for Doctoral Training (CDT) aims to train a new generation of leaders with a systems perspective who can transform research and industry involving HiPEDS. The CDT provides a structured and vibrant training programme to train PhD students to gain expertise in a broad range of system issues, to integrate and innovate across multiple layers of the system development stack, to maximise the impact of their work, and to acquire creativity, communication, and entrepreneurial skills. The taught programme comprises a series of modules that combine technical training with group projects addressing team skills and system integration issues. Additional courses and events are designed to cover students' personal development and career needs. Such a comprehensive programme is based on aligning the research-oriented elements of the training programme, an industrial internship, and rigorous doctoral research. Our focus in this CDT is on applying two cross-layer research themes: design and optimisation, and analysis and verification, to three key application areas: healthcare systems, smart cities, and the information society. Healthcare systems cover implantable and wearable sensors and their operation as an on-body system, interactions with hospital and primary care systems and medical personnel, and medical imaging and robotic surgery systems. Smart cities cover infrastructure monitoring and actuation components, including smart utilities and smart grid at unprecedented scales. Information society covers technologies for extracting, processing and distributing information for societal benefits; they include many-core and reconfigurable systems targeting a wide range of applications, from vision-based domestic appliances to public and private cloud systems for finance, social networking, and various web services. Graduates from this CDT will be aware of the challenges faced by industry and their impact. Through their broad and deep training, they will be able to address the disconnect between research prototypes and production environments, evaluate research results in realistic situations, assess design tradeoffs based on both practical constraints and theoretical models, and provide rapid translation of promising ideas into production environments. They will have the appropriate systems perspective as well as the vision and skills to become leaders in their field, capable of world-class research and its exploitation to become a global commercial success.

The UK has an international reputation for excellence in the aero-propulsion and power generation industry and is at the forefront of research into the underpinning aero-thermal science and technology. Through the current CDT in Gas Turbine Aerodynamics, the UK has also established itself as the global leader in graduate training in the field. But this sector is entering a period of accelerated change and market disruption. In aerospace, the continuing drive to reduce emissions is necessitating major architecture changes in jet engines as well as entirely new electrified concepts with integrated engine-airframe designs. In power generation, fast response and flexible operation gas turbines are required to support the increasing capacity of renewables. In addition, the traditional physical (experimental tests) and digital (computational simulation) worlds are merging with the advent of rapid multi-disciplinary design tools and additive manufacturing. The common thread in these challenges is the rapid increase in the rate of generation of data and the requirement for engineers to convert this information into innovative design changes. To maintain its leadership position, the UK must train a new generation of engineers with the skills needed to innovate in this data-rich environment. The new CDT in Future Propulsion and Power will train engineers with the Data, Learning and Design, and Systems Integration skills required by aero-thermal engineers of the future. Engineers will need to handle an unprecedented volume of Data from the latest multi-disciplinary simulations, experimental tests, or from real engines in the field. From this, engineers will need to distil Learning by a critical evaluation of the data, using AI and data science as appropriate, against hypotheses developed with reference to the underpinning aero-thermal science. The critical output from this Learning is improved Design, be that of a an individual component or process, or an Integrated System (e.g. electrically driven propulsor, urban air taxi, fast-response power generation). This set of coupled, aero-thermal focussed skills will be provided by the new CDT in Future Propulsion and Power. The Centre is a collaboration between three universities and four industry partners, each with complimentary expertise and skills, but with a shared vision to deliver a training experience that sets the global benchmark for Propulsion and Power education. The laboratories of the partner institutions have a track record of research leadership in turbomachinery aerodynamics (Cambridge), heat transfer (Oxford) and combustor aerodynamics (Loughborough). The new Master's course will use expertise from the three universities to train students in the underpinning aero-thermal science, in the experimental and computational data generation and critical evaluation, and in the process of aerodynamic design. Data Science training will be provided by Workshops delivered by the Alan Turing Institute and by researchers using advanced data analytics in the Centre's universities. The Industry Partners (Rolls-Royce, Siemens, Mitsubishi Heavy Industries and Dyson) are committed to defining, delivering and supporting the Centre (they will fund a minimum of 35 studentships). As well as providing a pathway for research projects to contribute to real products, the sponsoring companies also deliver bespoke industry courses to the students of the CDT; they provide a manufacturing, operation and Systems Integration context that only industry can offer. The Industry Partners will include data analytics (from R2 Data Labs - Rolls-Royce, and MindSphere/IoT - Siemens) in their industry courses. These companies, and others in related sectors in the UK, ensure a demand for the graduates of the new CDT with their unique, aerodynamics-focussed, Data, Learning and Design skill set.

Introducing porosity onto an aerofoil has been shown to have a significant influence on the boundary layer and provide significant reductions in its noise radiation. This proposal describes a multi-disciplinary research project aimed at understanding and exploiting the interactions between porous aerofoils and the boundary layers developing over them for the purpose of optimising noise reductions without compromising aerodynamic performance. The use of adaptive manufacturing technology will be investigated for providing the optimum porosity at different operating conditions.