Commercialisation of Ferroelectric Liquid Crystal over Silicon Microdisplays
Submitting Institutions
University of St Andrews,
University of EdinburghUnit of Assessment
PhysicsSummary Impact Type
TechnologicalResearch Subject Area(s)
Physical Sciences: Other Physical Sciences
Engineering: Materials Engineering
Technology: Communications Technologies
Summary of the impact
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.
Underpinning research
The Applied Optics Group at the University of Edinburgh was a
cross-departmental research unit involving the Schools of Physics (now
PHYESTA) and Engineering (now ERPE — the Edinburgh Research Partnership in
Engineering). The Group operated under the direction of Professor David
Vass (PHYESTA), who was working on liquid crystal over silicon (LCOS)
devices with initial interest in their use for optical correlators, beam
steerers, and beam shapers. The ferroelectric class of liquid crystals
offered response times an order of magnitude faster than nematic crystals,
and could be operated in a binary mode suited to driving digital
applications. However, ferroelectric liquid crystal devices posed severe
design and manufacturing challenges, as the thickness of the required cell
was much thinner than conventional nematic liquid crystal based devices.
Typically a sub-micron thickness is required and flatness, cell
parallelism and uniformity are also needed to make these devices viable.
At first commercial manufacturers of silicon wafers regarded such tight
tolerances as unattainable using conventional processing and polishing
methods. Vass, Hossack (PHYESTA) and collaborators in the School of
Engineering developed designs, pulsed illumination methods, polishing
techniques and silicon planarization (removal of excess curvature that can
reduce optical coherence and lead to colour artefacts), which produced
cells of excellent flatness and high reflectivity sufficient for coherent
optical applications [R1, R2]. This work was undertaken with a SERC SCIOS
rolling grant, SERC/DTI Link grant SASLM and EU ESPRIT grant HICPOBS over
the period 1993-1995 for which Vass was Principal Investigator.
Further refinements in the device design led to the realisation of smart
pixel structures including light blocking layers and robust backplane
electronics enabling a fast digital FLCOS Spatial Light Modulator [R3],
which was able to operate under intense illumination. This led to
applications in routers for telecoms, holographic projectors, and optical
tweezers. The smart algorithms, binary phase holograms, and fast device
operation were critical in realising real time full speed operation in
these application areas. The realisation of the FLCOS based holographic
optical tweezers, permitted for the first time multiple trapping and
real-time capture of freely moving microbes, as described in a well cited
paper [R4].
While more generally applicable these advances directly addressed
requirements of the emerging technology of microdisplays, which demanded
improved manufacturing methods to enhance image quality and colour
fidelity above threshold levels for a practical display. To the basic
spatial light modulator device we added fast image processing algorithms
in collaboration with GEC, STC, Admit Design, and Davin Optronics, thereby
producing the world's first high resolution, video speed, full colour
FLCOS digital microdisplay. This device was first showcased at the 6th
International Conference on Ferroelectric Devices hosted by ENST and
subsequently published in the leading journal for ferroelectric technology
[R5,R6]. This prototype device was a key development bringing together
VLSI design, surface planarisation, light blocking layers, fast electronic
interface and ferroelectric liquid crystals in a fully operational FLCOS
device. This work was undertaken over the period 1995-1998.
Personnel:
The key PHYESTA researchers involved were Professor David Vass
(1993-2004; category A in 2001 RAE return), Dr Will Hossack (Academic
staff, 1993-present), Professor Jason Crain (1993-present) and Dr Jochen
Arlt (Senior PDRA and COSMIC laboratory manager).
References to the research
The quality of the underpinning research is best illustrated by R1, R2
and R3. [Number of citations]
| [R1] |
A. O’Hara, J.R. Hannah, D.C. Burns, I. Underwood ,
D.G. Vass, R.J. Holwill, ‘Mirror
quality and efficiency improvements of reflective spatial light
modulators by use of dielectric coatings and chemical-mechanical
polishing’, Applied Optics, 32,
p. 5549, (1993), DOI: 10.1364/AO.32.005549, URL: tinyurl.com/mhydpes,
[14]
|
| >[R2] |
I. Underwood, D.G.Vass, A. O’Hara, et al., ‘Improving
the performance of liquid crystal-over-silicon spatial light
modulators – issues and achievements’, Applied Optics,33,
p. 2768, (1994), DOI: 10.1364/AO.33.002768, URL: tinyurl.com/n7tpurb,
[18]
|
| [R3] |
D. Burns, J. Gourlay, A. O’Hara, I. Underwood, D.G.Vass, ‘A
256x256 SRAM-XOR pixel ferroelectric liquid crystal over silicon
spatial light modulator’, Optics Communications, 119,
p. 623, (1995), DOI: 10.1016/0030-4018(95)00414-4, URL: tinyurl.com/knsfftm,
[11]
|
| [R4] |
W.J. Hossack, E. Theofanidou, J. Crain, K. Heggarty, M. Birch, ‘High-speed
holographic optical tweezers using a ferroelectric liquid crystal
microdisplay’, Optics Express, 11,
p.2053, (2003), DOI: 10.1364/OE.11.002053, URL: tinyurl.com/llgftlt,
[58]
|
| [R5] |
I.D. Rankin, I. Underwood, D.G. Vass, and M.R. Worboys, ‘Full
colour miniature display’, Proc SPIE on "Liquid Crystal
Materials, Devices and Applications”, 2651,
p.16, (1996), DOI: 10.1117/12.235358, URL: tinyurl.com/mclqaef,
[1]
|
| [R6] |
D. Vass et al., ‘A high
resolution full colour head mounted ferroelectric liquid
crystal-over-silicon display’, Ferroelectrics, 213,
p.209 - 218, (1998), DOI: 10.1080/00150199808016486, URL: tinyurl.com/mpsn54d
|
Details of the impact
The Applied Optics group formed a consortium with Thorn, GEC, BNR, Davin
Optronics, STC, and ENST, to perform research and development of FLCOS
devices with DTI funding. The local Scottish company, ADMIT Design, used
the FLCOS demonstrator to attract interest and investment. ADMIT was then
bought by Central Research Laboratories of Thorn EMI, forming MicroPix
Technologies Ltd in 1998. They developed the FLCOS microdisplay technology
into a commercial product. Subsequently in 1995, in a joint venture with
PicVue Electronics a pilot production company, Microvue, was created in
Scotland, and an investment of £20m was raised to build a volume
production plant in Taiwan.
ForthDD [S1], is the successor company of MicroPix and MicroVue, founded
in 2005, and based in Dalgety Bay, Fife. They succeeded in bringing the
technology to production demonstrating that FLCOS microdisplays could be
made to adequate standard in wafer scale production. Since its formation,
and over the period of the REF impact window, it has raised in excess of
US $33M in investment including the 2011 injection of US $14M by the
leading US microdisplay company, Kopin Corporation [S2]. ForthDD designs,
develops and manufactures single chip micro-displays used in the most
demanding segments of markets such as training and simulation systems, HD
video camera viewfinders, medical imaging systems and virtual-reality and
head-mounted displays. Entirely digital, providing 24-bit full colour
images, and capable of handling high-speed motion with no visible
artefacts, Forth DD's single chip imagers are especially well-matched to
the new solid state LED and laser diode light sources and provide very
high native resolution. In late 2012, ForthDD reaffirmed its position as
the world's leading supplier of advanced microdisplays when it released
the world's highest resolution full colour microdisplay. ForthDD employs
over 35 staff, many in posts requiring undergraduate and post-graduate
qualifications. It has annual revenues in excess of £3M, with exports
accounting for 95% of its sales. "A key selling point for Forth
Dimension Displays is our ability to produce high quality images in
applications where competing technologies do not quite make the grade.
Underpinning this image quality are product features enabled by
technical specifications such as high pixel aperture ratio and accurate
liquid crystal alignment, that were first established through the
PHYESTA research on backplane surface quality improvement. The backplane
surface quality improvement techniques described by the PHYESTA research
have been adopted by CMOS foundries, such as those from which ForthDD
obtains the substrates for its current product range."
Director of Product Design, ForthDD [F1].
The improvements particularly in surface planarity and pixel fill factor
achieved by PHYESTA researchers were critical enablers in FLCoS
microdisplay technology, allowing them to exceed the threshold of image
quality necessary to satisfy customers. The underlying manufacturing
processes were made available to ForthDD's commercial CMOS foundry
supplier, through publication and direct transfer, and thus were
incorporated into product manufacture. The CMOS foundry has continued to
refine these. Thus the manufacturability, image quality and optical
efficiency of the current product range and the newly released product
range rely upon PHYESTA's underlying research into manufacturing
techniques. Improvements in active device surface planarity and pixel
filling factors achieved by PHYESTA and collaborators were key
translational steps. With the exception of the liquid crystal materials
themselves and aspects of the drive circuitry, the entire ForthDD product
line is substantially and directly underpinned by PHYESTA innovations in
optical sciences and materials processing. The collaboration with ForthDD
remains active with Hossack and other staff continuing to consult and work
with them.
PHYESTA/ERPE research [R6], was quickly incorporated into early products
and has been continually developed and refined within the company to
encompass higher colour depth, higher frame rates and higher definition. "Thus
every Forth Dimension Displays product, including the most recent
product range, the QXGA (2048 x 1536 pixel) microdisplay launched in
October 2012, has used and continues to use pulsed RGB LED illumination
based upon the original ERPE scheme that was published [R2, R3] as an
outcome of the foundational ERPE research." CEO of ForthDD [F2].
Sources to corroborate the impact