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Impact: Economic gains
PHYESTA research has led to the setting up of a company now known as ForthDD. Since 2008 it has increased its annual revenue by more than 25% to around US $5M, and its global workforce from 25 to 35. It has released new products directly underpinned by PHYESTA research as recently as October 2012.
Significance:
A consortium involving PHYESTA staff in collaboration with Edinburgh's School of Engineering and five industrial partners realised the world's first high-resolution ferroelectric liquid crystal over silicon (FLCOS) microdisplay. This digital display attracted investment from the UK, Taiwan, and USA of over $40m, and was taken forward to production by MicroPix, MicroVue, and Forth Dimension Displays.
Reach:
ForthDD now has offices in Valencia, USA, and Berlin, Germany. The company designs, develops and manufactures single chip microdisplays used in the demanding near to eye (NTE) training and simulation systems, HD video camera viewfinders, medical imaging systems and virtual reality and head-mounted displays.
Beneficiaries:
ForthDD, its customers and business partners (e.g. in the medical imaging sector).
Attribution: This work was led within PHYESTA by Professor David Vass involving PHYESTA and done in collaboration with Edinburgh's School of Engineering.
Today's global telecom systems are powered by technology developed at the University of Glasgow. This technology has been utilised, endorsed and developed by a series of internationally successful companies, facilitating multimillion pound investment from across Europe and the USA for the companies.
Gemfire Europe acquired the University of Glasgow IP and technology and between 2008 and 2012 launched a range of `green' products with reduced power consumption. The company's revenues reached $12m annually and in 2013, Gemfire was one of the world's top five planar lightwave circuit companies. Gemfire was bought by Kaiam, one of the world's market-leading optical networking companies in April 2013, stimulating further innovation and investment in the production of high-speed components for the global data networking market.
Natural photonics research by Professor Pete Vukusic at the University of Exeter was responsible for shaping the successful global communications strategy of Bausch & Lomb, a world-leading supplier of eye health products. Drawing on Vukusic's studies into bio-inspiration, Bausch & Lomb built its core brand messaging for a major new lens product around the ability of nature to inspire technological breakthroughs. Outreach campaigns targeting media and optometry professionals took Vukusic's research to an international audience, raising wider public awareness of the concept of bio-inspiration. Bausch & Lomb attributed their subsequent rapid sales growth to Vukusic's work.
Metamaterials deliver electromagnetic properties not available in natural materials. Transformation optics replaces the ray picture of Snell's law with the field lines of Maxwell's equations and is an exact description of classical optics. These powerful concepts, originally developed by Prof John Pendry, have engendered massive interest in the electromagnetic community encompassing radio frequency (RF) through to optical applications. His advice is sought by numerous companies and these concepts are now filtering through into products. In the last 5 years there has been great involvement of industry and particularly of the defence establishment in the USA who run several multi mullion dollar programs on metamaterials based at DARPA, WPAFB and Sandia. A company, KYMETA, was formed in 2012 to market this technology with $12M of investment funding, and is developing a laptop-sized antenna that gives instant Internet hotspot access anywhere in the world, with an ultimate application allowing cheap and fast Internet connections for the everyday consumer. In the UK, BAE Systems is using metamaterials for several applications including compact, directional antennas.
Implementation of photonic quasi-crystals on light emitting diodes (LEDs) can produce more light using less energy. This technology was brought to the global market via the successful commercialisation of laboratory devices derived from research in nanophotonics and the subsequent development of photonic quasi-crystals by a multi-disciplinary team from the University of Southampton. The intellectual property of the technology was acquired and adopted in 2008 by Luxtaltek Corporation, a global manufacturer of LEDs. In the period 2008-2012 Luxtaltek Corporation, made total profits of £35 million utilising the photonic quasi-crystal LED technology, employing more than 300 people in its production facilities.
Work undertaken at the Applied DSP and VLSI Research Group since the early/mid nineties, has led to a number of significant contributions underpinning the development and commercial exploitation by industry of power efficient and complexity reduced integrated Digital Signal Processing (DSP) systems and products. These developments have paved the way for a new paradigm in the design of complexity reduced electronic systems aiding the emergence of numerous new commercial application areas and products in a diversity of fields. Indeed, these developments continue their currency and applicability in today's electronic products sector and thus shall be at the core of this case study.
High-power lasers developed at the University of Glasgow now lie at the heart of state-of-the-art technologies in the commercial printing, medical and defence markets. University of Glasgow spin-out company Intense has introduced more than 10 new diode laser products with superior brightness, longer lifetimes and increased reliability to these markets since 2008. [text removed for publication.] In 2011 Intense was bought by ORIX USA Corporate Finance Group for an undisclosed sum.
This case study describes the impact of the EnCore microprocessor, and the associated ArcSim simulation software, created in 2009 by the Processor Automated Synthesis by iTerative Analysis (PASTA) research group under Professor Nigel Topham at the University of Edinburgh. Licensing to Synopsys Inc. in 2012 brought the EnCore and ArcSim technologies to the market. Synopsys Inc. is a world-leading Silicon Valley company. It is the largest Electronic Design Automation (EDA) company in the world, and the second largest supplier of semiconductor IP. EnCore is achieving a global impact through this worldwide channel. The commercial derivatives of the EnCore technology provide manufacturers of consumer electronics devices with an innovative low-power, high-performance microprocessor that they can customize to their specific application requirements, enabling the next generation of electronic devices.
Researchers, and the work they undertook at the University of Exeter during the 1990s, led to the formation of the Defence Evaluation and Research Agency's (now QinetiQ) first spinout company: ZBD Displays Ltd. Achieving revenue growth of 17,910% over the last five years, ZBD's unique electronic retail signage and shelf-edge labelling technology is used by major retailers all over the world. The invention used the know-how developed by ZBD's company founders whose R&D and engineering teams all include former postgraduates from the School of Physics and Astronomy, who acquired their expertise under the supervision of Professors Roy Sambles and Bill Barnes.
A facility for precision diamond machining of optical components arose from research at Durham University to produce instruments for large telescopes, including NASA's James Webb Space telescope. This now provides a specialist service to industry, with contracts worth over £2.0M from >20 companies over the past 5 years. The users span applications including ophthalmics, automotive optics, microstructures for backlit displays and IR optics. An emerging application is the use of high precision machine metal moulds to reproduce ophthalmic lenses for spectacles. Examples include PixelOptics (USA) who make high-end electronically corrective eyewear, which has won several ophthalmic industry R&D awards, and Eyejusters (UK), which employs complex surface slide lens technology to provide low cost spectacles aimed at improving the lives of people in the developing world.