The Internet is expanding towards mobile wireless connectivity rapidly. However, to enable this for increasing numbers of users and connected devices, and increasingly bandwidth-, processing power- and energy-hungry applications, will require a transformation in the way in which current mobile and wireless networks perform. Shorter wireless distances (small cells, picocells, femtocells) and different network types for the connection (WiFi, 3G, 4G, 5G) depending on the availability and suitability for different applications, is a process that is already happening and expected to continue. This will manifest itself with simpler remote radio heads providing coverage in otherwise difficult to penetrate locations (and the main processing functions gathered together in a centralised pool of base station baseband units), and with the appearance of new wireless standards. NIRVANA takes this evolution and proposes a transformative step: the incorporation of fast, hardware-based, network monitoring, and intelligence (using the monitoring/gathered information) close to the pool of base stations. The proximity of the intelligence enables low-overhead control of a range of operational functions, which allow users to be moved from one connection type to another, according to their application and the load on the network, and to match the network's resources precisely to user needs. It allows energy efficiency to be optimised throughout the network and in the mobile device, too. The latter is augmented by locating the computing resources for a "mobile cloud" near the base station pool. Some processing is offloaded to the mobile cloud instead of being done on the mobile, and even some mobile-to- mobile communication may be done within this cloud - saving the mobile device (and the network) energy that would have been used in radio transmissions. Finally, among the new wireless connection types to be investigated, millimetre-wave communications, using the most up-to-date releases of the wireless local area network standard (802.11ad/j), will be fashioned into a device-to-device mesh network, for mobile distributed caching, which will be shown to further enhance the capacity of the network and its energy efficiency.

The Communications sector is a vital component within the UK economy, with revenues in this area totalling around 129B. Recognised as a key enabler of telecommunications, broadcasting and ICT, communications is also poised to be a transformational technology in areas such as energy, the environment, health and transport. The UK is well placed to reap the full economic and social benefits enabled by communications and investment in a CDT, embracing the breath and reach of the discipline, will help to facilitate our economic recovery and growth and enhance our global standing.There is a serious and growing concern over the future availability of suitably skilled staff to work in the communications sector in the UK. International competition is fierce, with large investments being made by competitor countries in research and in the training of personnel. IT and telecoms companies in the UK are reporting difficulties in attracting candidates with the right skills. In this context, the National Microelectronics Institute and the IET have warned that the ICT sector is facing a growing recruitment crisis with little confidence that the problem will improve in the short or medium term. Various organisations (eg DC-KTN and Royal Academy of Engineering) with support from industry are addressing this issue but acknowledge that it cannot be achieved without relevant high quality under- and postgraduate degrees through which specialist skills can be obtained.To address this shortage, a new Centre for Doctoral Training (CDT) in 'Future Communication' is proposed. The University of Bristol has a world leading reputation in this field, focused on its Centre for Communications Research (CCR), but built on close collaboration between colleagues from Mathematics, Computer Science, Safety Systems and industry. Our vision is to establish a world-leading research partnership which is focused on demand and firmly footed in a commercial context, but with freedom to conduct academically lead blue skies research.The Bristol CDT will be focused on people: not just as research providers, but also as technology consumers and, importantly, as solutions to the UK skills shortage. It will develop the skilled entrepreneurial engineers of the future, provide a coherent advanced training network for the communications community that will be recognised internationally and produce innovative solutions to key emerging research challenges. Over the next eight years, the CDT will build on Bristol's core expertise in Efficient Systems and Enabling Technologies to engineer novel solutions, offering enhanced performance, lower cost and reduced environmental impact. The taught component of the Programme will build on our MSc programme in Communication Systems & Signal Processing, acknowledged as leading in the UK, complemented by additional advanced material in statistics, optimisation and Human-Computer Interaction. This approach will leverage existing commitment and teaching expertise. Enterprise will form a core part of the programme, including: Project Management, Entrepreneurship, Public Communication, Marketing and Research Methods. Through its research programme and some 50 new PhD students, the CDT will undertake fundamental work in communication theory, optimisation and reliability. This will be guided by the commercial imperatives from our industry partners, and motivated by application drivers in Smart Grid, transport, healthcare, military/homeland security, safety critical systems and multimedia delivery. While communications technology is the enabler it is humans that are the consumers, users and beneficiaries in terms of its broader applications. In this respect we will focus our research programme on the challenges within and interactions between the key domains of People, Power and Performance.

The eFutures network seeks to maximise the impact of UK electronics research. It currently has 320 members from 55 institutions. It seeks to grow this membership by a further 200-300 in the coming years. It offers a necessary link between industry and the academic community at a time when the UK electronics systems community is seeking to consolidate, for example through the ESCO initiative (electronic systems challenges and opportunities) recently launched by a government minister and endorsed by leading UK industry. Industry and industry-facing organisations agree that the continuation of eFutures represents a valuable building block for the ongoing health and vitality of the electronic systems community. In 2012 the direct economic contribution of this community to the UK was £78Billion (5.4% of GDP). There are opportunities for exciting new research at the boundaries between disciplines. The eFutures network will work to build bridges with other research communities where we can establish a dialogue in order to shed light on where working together will allow new challenges to be met. Early career researchers are key to the future of a knowledge based economy wishing to innovate electronics systems. The eFutures network will support many of those new to research or early in their careers, to network with one another and to be connected with more experienced academics and industry experts. Links to industry allow new ideas from university to translate into commercial products. It also allows industry to discuss their current challenges with academic experts and by working together new innovations will emerge. The combined academic and industry community is best placed to scan the horizon and create a shared vision for the best research agenda for UK electronics. The academic electronics community has many facets and the eFutures network will help to bring these elements together. This activity will include linking to experts in Europe as well as building a better understanding between UK researchers in disciplines closely related to electronics such as power electronics and energy harvesting.

As IBM's 2nm chip is pushing Moore's law approaching its limit, conventional computing techniques are struggling to offer high performance computing within power consumption constraints. Inspired by the fault tolerance capability of the human brain, approximate computing, which is error tolerant, can offer a huge reduction in computer power consumption without affecting the results (such as accuracy) of certain human perception and recognition related computation that only require a result to be approximate, rather than accurate. Examples include Artificial Intelligence (AI), Deep Learning (DL), image processing and even some cryptographic schemes. However, approximate computing has been shown to have security vulnerabilities due to the unpredictability of intrinsic errors that may be indistinguishable from malicious modifications. Due to the inherent power and area savings achieved by approximate computing, security countermeasures shold also be lightweight ande efficient. Hence, the aim of this proposal is to use advanced hardware security techniques to enable the development of approximate computing technologies that have both optimal security protection and optimal system efficiency. Currently, no comprehensive research has been conducted to date into security of approximate computing or into countermeasures that protect such designs. Physical unclonable function (PUF), as a lightweight hardware security primitive, is one of the best candidates for securing resource-constrained applications, such as approximate computing. A PUF can be used to generate a unique digital fingerprint for an electronic device based on manufacturing process variations of silicon chips. Currently, PUFs have been widely studied for conventional computing but no effective intrinsic PUF designs using approximate techniques have been presented. This project is timely because approximate computing has rapidly attracted attention from both academica and industry, as it addresses one of the fundamental barriers in computing systems, power dissipation, but it has also opened new vectors of attacks. This project will develop an intrinsic PUF design based on the normal operations of an approximate processor without the need for addtional hardware resource. The project will aslo address for the first time how to achieve secure and effective approximate computing designs. Thales UK, a leader in designing and building mission-critical information systems for the defence, security, aerospace, and transportation sections, has already invited the PI to join the Thales CyRes-Advance project to investigate security protection for connected and autonomous vechicles (CAVs) by considering hardware security. Thales will provide £250k in-kind support, such as technical advice/review of the hardware design, access to Thales CAV test platform and experimental validation for the project, to accelerate the research process and produce high-quality research outputs.

Following the Moore's law the semiconductor industry has delivered continuous increase of systems functionality and speed over the last 50 years through the aggressive downscaling of the transistors. In the last 20 years the UK IC-design based industry has grown to a level of national and international importance. While IC designers in the past enjoyed the freedom that all transistors in a chip could be treated identically, this is no longer the case for the nano-meter sized transistors used in the present and future technologies. Statistical device-to-device variation is introduced by the discreteness of charge and granularity of matter and is inversely proportional to gate area, so that its impact on circuits increases with the reduction of transistor dimensions. When the number of logic gates in a system increases and the architecture becomes more complex, the tolerance to variability is greatly reduced. Even if two devices were identical after fabrication, they could suffer from different aging during operation, causing a time-dependent variability (TDV). TDV is becoming a major threat to the correctness of electronic systems, but there are no tools for its verification because of the lack of a complete understanding. The aim of this project is to carry out an in-depth investigation of the defects and mechanisms responsible for TDV and, based on that, to develop a test-proven TDV simulator, allowing IC designers to assess the impact of TDV on their circuits. The researchers at Glasgow University have pioneered variability simulation and the researchers at Liverpool John Moores University have specialised in experimental characterization of defects. Their highly complementary skills bring them together and make them well positioned to tackle this challenge. By working together with UK companies, the impact of their work on UK industry will be direct. The collaboration with IMEC and its industrial consortium also opens an effective impact pathway on an international scale. The successful control of TDV will deliver reliable electronic products and minimize their power consumption.