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This case study describes how spin-out company, Antrum Ltd (founded in 2001) realises the commercial potential of Loughborough University's extensive antenna research. Antrum has been consistently profitable typically turning over between £150K - £300K. Examples of how research projects, through industrial partnership, have evolved to commercial products illustrate the success of Antrum's business model and the effectiveness of the partnership between the University and its spin out company. The Case Study describes how the University's wireless communications research, between 1998 - 2011, consistently challenged accepted antenna design to meet demand for products that are more efficient, robust, smaller and commercially viable.
We have developed enabling technologies for the defence, automotive and identification industries, the health service and the wider community where our contributions enable end users to maximise performance for a given cost. Work on Frequency Selective Surfaces (FSS) produced sub-reflectors for aerospace (BAE Systems — mm/sub-mm satellite radiometers for earth observations). Small antenna and RFID work led to new products in the automotive industry (Harada Industries), on-line fuel management systems (Timeplan Ltd), wireless smoke detectors (EMS Group), connectors (Martec), antennas (Panorama Antennas Ltd) and for Digital TV (Mitsubishi). Millimetre-wave over fibre systems linked antennas have supported the acquisition of new astronomical data, through the international ALMA (Atacama Large Millimetre Array) project, facilitating deeper public understanding of the universe.
Antenova Ltd, a spin out company created to exploit University of Sheffield research, is a leading developer and supplier of high performance antennas and radio frequency (RF) antenna modules for wireless communication and consumer electronic devices such as smartphones, laptop computers and tablets. Significant commercial impact has been generated: Antenova has 6% of the global mobile antenna market (2 Billion units) and is a leader in the global antenna design market with a 15% share, employing 40 staff worldwide and with an annual turnover of about $8 million. To gain commercial advantage Microsoft Corporation bought out Antenova in 2013.
Small high dielectric constant chip antennas resulting from the underpinning research allow multiple wireless services to be provided on small devices such as smart phones and as these antennas are very efficient, save energy, extend battery life and so bring environmental benefit.
In this case study, two specific examples of impact are reported. One is cost-effective and high-performance smart antennas for the offender tagging system and marine navigation system for Guidance Navigation Ltd (Guidance). This collaboration has resulted in new and leading products and also helped the company to win a range of contracts. The other example is the development of a novel intelligent drilling system_for Zetica Ltd. This system can detect deeply buried unexploded ordinance and other objects. It has given Zetica a unique new product to significantly improve operational safety and win business worldwide.
State-of-the-art radio systems require antennas that are a) able to cover an ultra-wide range of operating frequency bands, and b) compact and yet robust enough to be mounted in settings that range from satellites to the human body. Our pioneering work in this area has led to the significant contributions to the UK Ofcom Spectrum Framework Review and the developments of new products and business opportunities, new technologies for assessing the EM emission on the mobile handset and for smart meter deployment, and wearable antennas deployed in the battlefield to reduce the load and smart communications for dismounted soldiers.
WiFi technologies are integral to our internet-connected lives. Most of the world's wireless data passes over one of the global WiFi standards. For more than 20 years the University's Communication Systems & Networks (CS&N) Group has contributed towards the development of these technologies, and to products that conform to them.
The WiFi standards are vital since they ensure that computers, mobile phones, set-top boxes and tablets all use the same waveforms and protocols to wirelessly connect to the Internet. They ensure inter-operability between different products and manufacturers.
CS&N pioneered the use of multicarrier modulation and multiple antenna (MIMO) technologies. These underpin the current WiFi standards (802.11g/n), ratified in 2003/2009. Research on wireless and video communications led, via spin-out ProVision Communications, to a range of robust wireless-video products for high definition video transmission in the home. These products are now manufactured and sold by Global Invacom.
In partnership with Farncombe, the Group has developed a defacto WiFi test standard. This combines the Group's rigorous WiFi antenna validation & verification measurements with its system level in-home modelling and measurement tools. [text removed for publication]. To date, more than five million WiFi routers have benefited from the University's WiFi test process.
The impact described in this case study is the more efficient use of transport infrastructure through the application of our research into the use of wireless components and wireless communication devices. This gives passengers reduced travel times, better business performance for operators, and, for everyone, reduced pollution (including CO2) and a more pleasant urban environment as a result of reduced congestion. The impact has benefitted transport systems throughout Europe, including Nottingham and Coventry in the UK, Gouda in the Netherlands, Leuven in Belgium and Sofia in Bulgaria.
Practical Waveform Engineering, developed at Cardiff, is having a major impact on how modern- day microwave power amplifiers are designed, delivering real competitive advantages for global communications companies such as Nokia-Siemens-Networks and M/A-COM.
Economic impact is through reduced time-to-market and lower design costs, leading to high- performance power amplifier products. Examples include $40M revenue and employment of additional staff for M/A-Com, and the successful spin-off company Mesuro Ltd., generating revenue in excess of £2.5M.
Impact on practice is through successful demonstration of new device technologies and amplifier architectures, the introduction of PWE-based CAD models, and most significantly, the introduction of the "Cardiff Model" into mainstream simulation tools.
Environmental Impact is by improving the efficiency of power amplifiers and significantly reducing the carbon contribution of mobile communications systems, translating into savings of approximately £2.5M/year and a 17 kiloton reduction in CO2 emission for a typical EU network.
Research at the University of Cambridge Department of Engineering (DoEng) created a novel wideband active Distributed Antenna System (DAS). The research was commercialised by Zinwave, a DoEng spin-off company [text removed for publication]. Zinwave has developed a network of over 40 System Integrator partners to deliver DAS solutions to enterprises and building owners. It has also been selected by Verizon Wireless, one of the largest mobile operators in the world, to support its 4G network rollout in the USA. The first sales were recorded in 2009. Zinwave systems have been successfully deployed across the world. Zinwave's annual revenue has grown three-fold since first sales and was nearly GBP3M in the year ending December 2012.
Femtocells provide short-range (e.g. 10m) wireless coverage which enables a conventional cellular communication system to be accessed indoors. Their widespread and growing use has been aided by the work in UoA11 by the University of Bedfordshire (UoB).
In 2008, while the femtocell concept was still in its infancy, researchers at UoB with expertise in wireless networks recognised that coverage prediction and interference reduction techniques would be essential if the benefits of that concept were to be realised.
Collaboration with two industrial partners (an international organisation and a regional SME) resulted in tools that enable operators to simulate typical femtocell deployment scenarios, such as urban, dense apartments, terraced house and small offices, before femtocells can be reliably deployed by users without affecting the rest of the network (a benefit of the technology). These tools have been deployed by those partners to support their businesses. A widely-cited textbook, written for network engineers, researchers and final year students, has brought knowledge of femtocell operation to a wider audience.