Polymer Wave Guide Optical Interconnect Manufacturing
Transcript of Polymer Wave Guide Optical Interconnect Manufacturing
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Packaging and Interconnection for Electronics and Sensors – Past, Present and Future, Wednesday 10th
February 2010, Riverside Offices, Granta Park, Great Abington, Cambridge © UCL 2010
1
Polymer Wave Guide Optical Interconnect
Manufacturing
David R. Selviah
Department of Electronic and Electrical Engineering,
University College London, UCL, UK,
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Outline
Electronic versus Optical interconnects
The OPCB project
OPCB University Research Overview
Heriot Watt
Loughborough
UCL
System Demonstrator
Optical and Electronic
Interconnects
Backplane
Mezzanine Board (Daughter
Board, Line Card)
Optical Connector
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Copper Tracks versus Optical Waveguides for
High Bit Rate Interconnects
Copper Track
EMI Crosstalk
Loss
Impedance control to minimize back reflections, additional equalisation, costly
board material
Optical Waveguides
Low loss
Low cost
Low power consumption
Low crosstalk
Low clock skew
WDM gives higher aggregate bit rate
Cannot transmit electrical power
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On-board Platform Applications
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On-board Platform Applications
Reconfigurable Network
Interconnections
High Bandwidth Signals
RF/EO Sensors& comms data
Aircraft utilities
Signal concentrator
coreprocessor
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The Integrated Optical and Electronic
Interconnect PCB Manufacturing (OPCB) project
Hybrid Optical and Electronic PCB Manufacturing Techniques
8 Industrial and 3 University Partners led by industry end user
Multimode waveguides at 10 Gb/s on a 19 inch PCB
Project funded by UK Engineering and Physical Sciences Research Council
(EPSRC) via the Innovative Electronics Manufacturing Research Centre
(IeMRC) as a Flagship Project
3 year, £1.6 million project, half direct and indirect contributions from
industry
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Integration of Optics and Electronics
Backplanes
Butt connection of “plug-in” daughter cards
In-plane interconnection
Focus of OPCB project
Out-of-plane connection
45 mirrors
Chip to chip connection possible
Multilayer organic substrate
Core
CladdingVC
SE
L
Daughte
r ca
rd
De
tect
or
Daughte
r ca
rd
DetectorVCSEL
Core
Cladding
Multilayer organic substrate
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NPL
Physical measurements
End Users
Xyratex
Network storage
interconnect
BAE Systems
In-flight
interconnect
Renishaw
Precision
measurement
Loughborough
University
Laser ablation and
ink-jet printing
of waveguides
Cadence
PCB design
tools and rules
Exxelis
Polymer supply
and photolithography
Heriot -Watt
University
Polymer formulation
Supply of laser
written waveguides
Stevenage Circuits Ltd
Sample PCBs, dry film
CAD conversion, laser work
UCL
Optical modelling
Waveguide design rules
Optical measurements
NPL
Physical Measurements
Dow CorningPolymer supply
and photolithography
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• Slotted baseplate mounted vertically over translation,
rotation & vertical stages; components held in place with magnets
• By using two opposing 45º beams we minimise the
amount of substrate rotation needed
Direct Laser-writing Setup: Schematic
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Writing sharply defined features
Gaussian Beam Imaged aperture
Images of the resulting waveguide core cross-sections
Beam: ~1.2 mm
– flat-top, rectangular laser spot
TEM00
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Laser written polymer structures
SEM images of polymer
structures written using
imaged 50 µm square
aperture (chrome on glass)
• Writing speed: ~75 µm / s
• Optical power: ~100 µW
• Flat-top intensity profile
• Oil immersion
• Single pass
Optical microscope image
showing end on view of the
45º surfaces
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Out-of-plane coupling,
using 45-deg mirror (silver)
Microscope image looking
down on mirror
coupling light towards camera
OPTICAL INPUT
Waveguide terminated with 45-deg mirror
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Current Results
Laser-writing Parameters:
- Intensity profile: Gaussian
- Optical power: ~8 mW
- Cores written in oil
Polymer:
- Custom multifunctional
acrylate photo-polymer
- Fastest “effective” writing speed
to date: 50 mm/s
(Substrate: FR4 with
polymer undercladding)
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Large Board Processing: Writing
• 600 x 300 mm travel• Requires a minimum of
700 x 1000 mm space on optical bench
• Height: ~250 mm• Mass:
• 300 mm: 21 kg• 600 mm: 33 kg• Vacuum tabletop
• Stationary “writing head” with board moved using
Aerotech sub-µm precision stages
• Waveguide trajectories produced using CAD program
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The spiral was fabricated using a Gaussian intensity profile at a
writing speed of 2.5 mm/s on a 10 x 10 cm lower clad FR4
substrate. Total length of spiral waveguide is ~1.4 m. The spiral
was upper cladded at both ends for cutting.
Large Board Processing: Writing
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Laser Ablation of Optical Waveguides
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Research Straight waveguides
2D & 3D integrated mirrors
Approach Excimer laser – Loughborough
CO2 laser - Loughborough
UV Nd:YAG – Stevenage Circuits Ltd
Optical polymer Truemode® – Exxelis
Polysiloxane – Dow Corning
Schematic diagram (side view) showing
stages in the fabrication of optical
waveguides by laser ablation
Stage1 : Spin coating of clad and core layers which are
UV-cured individually.
Stage2 : Laser ablation of optical layer from the core through to clad layer
Stage3 : Deposition of upper cladding
FR-4 substrate
Lower clad Core
Pitch
Clad materialCore
FR-4 substrate
FR-4 substrate
Lower clad
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Machining of Optical Polymer with CO2 Laser
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System 10 Watt(max.) power CW beam
Wavelength = 10.6 µm (infrared)
Process Thermally-dominated ablation process
Machining quality Curved profile
Waveguide fabrication underway
FR4 layer
Ablated profile
Side view of machined trench
Waveguides (side view)Machined trench
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UV Nd:YAG machining in collaboration with Stevenage Circuits Ltd
Waveguide of 71 µm x 79 µm fabricated using UV Nd:YAG
Waveguide detected using back lighting
Side view Plan view
System 355 nm (UV) Pulsed laser with 60 ns pulse
width and Gaussian beam (TEM00) or “Tophat”
profile at Stevenage Circuits Ltd.
Process Photochemically-dominated ablation process.
Waveguide quality Minimum Heat Affected Zone
Propagation loss measurement underway
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Machining of Optical Polymer with Excimer Laser
Straight structures machined in an optical polymer.
Future work to investigate preparation of mirrors for in
and out of plane bends.
FR-4 layer
Waveguide structureMachined trenches
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Inkjetting as a Route to Waveguide Deposition
Deposit
Lower CladdingDeposit
Core
Deposit
Upper Cladding
Print polymer then UV cure
Advantages:
controlled, selective deposition of core and clad
less wastage: picolitre volumes
large area printing
low cost
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Challenges of Inkjet Deposition
Viscosity tailored to inkjet head
via addition of solvent
“Coffee stain” effects
15 20 25 30 35 40 45
3
4
5
6
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8
9
10
11
12
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15
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Solvent A
Solvent B
Vis
cosi
ty (
cSt)
Temperature (deg C)
A 2 x 2 array of inkjet
printed drops
Cross-section of dried droplet
“coffee-stain” effect
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Changing Surface Wettability
Core material on cladding Core material on modified
glass surface (hydrophobic)
Identical inkjetting conditions - spreading inhibited on modified surface
Large wetting - broad inkjetted lines
Contact Angles
Reduced wetting – discrete droplets
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Towards Stable Structures
Stable line structures with periodic
features
Cross section of inkjetted core
material surrounded by cladding
(width 80 microns)
A balance between wettability, line stability and adhesion
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• Straight waveguides 480 mm x 70 µm x 70 µm
• Bends with a range of radii
• Crossings
• Spiral waveguides
• Tapered waveguides
• Bent tapered waveguides
• Loss
• Crosstalk
• Misalignment tolerance
• Surface Roughness
• Bit Error Rate, Eye Diagram
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Waveguide components and measurements
Copyright © 2009 UCL
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Optical Power Loss in 90 Waveguide Bends
w
lin
lout
Rs
Rs+ΔR
Rf = Rs + NΔR
A
B
I
Output
Input
O
Schematic diagram of one set of
curved waveguides.
Light through a bent waveguide of R =
5.5 mm – 34.5 mm
• Radius R, varied between 5.5 mm < R < 35 mm, ΔR = 1 mm
• Light lost due to scattering, transition loss, bend loss, reflection and back-
scattering
• Illuminated by a MM fiber with a red-laser.Copyright © 2009 UCL
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BPM, beam propagation method modeling of
optical field in bend segments
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w = 50 μm, R = 13 mm
(left picture) in the first segment (first 10°).
(right picture) in the 30° to 40° degree segment.Copyright © 2009 UCL
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Differences in misalignment tolerance and
loss as a function of taper ratio
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• Graph plots the differences between a tapered bend and a bend
• There is a trade off between insertion loss and misalignment toleranceCopyright © 2009 UCL
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Crosstalk in Chirped Width Waveguide Array
• Light launched from VCSEL imaged via a GRIN lens into 50 µm x 150 µm waveguide
• Photolithographically fabricated chirped with waveguide array
• Photomosaic with increased camera gain towards left
100 µm 110 µm 120 µm 130 µm 140 µm 150 µm
Copyright © 2009 UCL
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Surface roughness
• RMS side wall roughness: 9
nm to 74 nm
• RMS polished end surface
roughness: 26 nm to 192 nm.
29Copyright © 2009 UCL
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Design rules for waveguide width depending
on insertion loss and cross-talk
6~7dB for a 70 μm width waveguideCopyright © 2009 UCL
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Bit error rate for laterally misaligned 1550 nm
2.5 Gb/s DFB laser
10-2
10-3
10-4
10-5
10-6
10-7
10-8
Power at the
receiver (dBm)
BE
R
(+) Direction 10-2
10-3
10-4
10-5
10-6
10-7
10-8
(-) Direction
Power at the
receiver (dBm)
-30 -28 -26 -24 -22 -20 -18
R = 9.5 mm
R = 13.5 mm
R = 20.5 mm
Straight
No wvg.
-30 -28 -26 -24 -22 -20 -18
Copyright © 2009 UCL
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Contour map of VCSEL and PD misalignment
(a) Contour map of relative insertion loss compared to the maximum coupling position for VCSEL misalignment at z = 0.
(b) Same for PD misalignment at
z = 0. Resolution step was Δx
= Δy = 1 µm.
• Dashed rectangle is the expected relative insertion loss according to the
calculated misalignments along x and y.
• The minimum insertion loss was 4.4 dB, corresponded to x = 0, y = 0, z = 0
Copyright © 2009 UCL
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0
0.5
1
1.5
2
2.5
3
3.5
4
0 20 40 60 80 100 120 140 160 180 200
axial distance z (μm)
Inse
rtio
n L
oss
(d
B)
VCSEL
Photo Detector
Coupling Loss for VCSEL and PD
for misalignments along optic axis
Copyright © 2009 UCL
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Fabrication Techniques and Waveguides Samples
Copyright © 2009 UCL
Straight waveguides – Optical InterLinks 90° Crossings – Dow Corning
90° Crossings – Heriot Watt University 50° Crossings – Exxelis
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Photolithographic Fabrication of Waveguides
Copyright © 2009 UCL
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36Copyright © 2009 UCL
Optical Loss Measurement
850
nm
VCSE
L
Integrating sphere
photodetector
70 μm pinhole
nW Power Meter
50/125 μm step
index fibre
mode
scrambler R
Index
matching
fluid
0 dBm
-1.63
dBm-1.63 dBm
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Source: ULM Photonics GmbH
Source: Microsemi Corporation
Source: GRINTech GmbH
VCSEL Array
PIN Array
GRIN Lens Array
MT compatible
interface
VCSEL Array for Crosstalk Measurement
Copyright © 2009 UCL
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3838
• 70 μm × 70 μm waveguide cross sections and 10 cm long
• In the cladding power drops linearly at a rate of 0.011 dB/µm
• Crosstalk reduced to -30 dB for waveguides 1 mm apart
Copyright © 2009 UCL
Design Rules for Inter-waveguide Cross TalkPD with
pinhole
VCSEL x (µm)
Normalized
Transmitted
Power (dB)
0th 1st 2nd 3rd 4th 5th 6th-1st
y
xz
1 mm
Recommended
Used
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39Copyright © 2009 UCL
Schematic Diagram Of Waveguide Crossings at
90° and at an Arbitrary Angle, θ
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4040Copyright © 2009 UCL
Design Rules for Arbitrary Angle Crossings
• Loss of 0.023 dB per 90° crossing consistent with other reports
• The output power dropped by 0.5% at each 90° crossing
• The loss per crossing (Lc) depends on crossing angle (θ), Lc=1.0779 · θ -0.8727
Recommended
Used
Loss per crossing
(dB)
Crossing angle (degree)
Power drops
0.08 dB at 20°
0.023 @ 90
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Width (μm) Optimum Radius (mm) Maximum Power (dB)
50 13.5 -0.74
75 15.3 -0.91
100 17.7 -1.18
50 µm × 50 µm
75 µm × 50 µm
100 µm × 50 µm
Bend radius (mm)
Transmitted
power (dB)
41Copyright © 2009 UCL
Loss of Waveguide Bends
Recommended
Used
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4242
System Demonstrator
Fully connected waveguide layout using design rules
Copyright © 2009 UCL
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Input power (dBm/mW) -2.07 / 0.62
Bend 90°
Radii (mm) 15.000 15.250 15.500 15.725 16.000 16.250
Loss per bend (dB) 0.94 0.91 0.94 0.94 0.95 0.95
Crossings
Crossing angles (°) 22.27 29.45 36.23 42.10 47.36
Loss per crossing (dB) 0.078 0.056 0.047 0.041 0.037
Min. detectable power
(dBm)-15 / 0.03
Min. power no bit error
rate-12 / 0.06
43Copyright © 2009 UCL
Power Budget
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Demonstrator Dummy Board
Copyright © 2009 UCL
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46Copyright © 2009 UCL
Waveguide with 2 Crossings Connected 1st to 3rd
Linecard Interconnect
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www.scsita.org
20132012201120102009200820072006200520042003 2014 2015
Source: SCSI Trade Association Sep 08
3Gb/s SAS
6Gb/s SAS
12Gb/s SAS
Disk drive form factors decreasing
Data storage protocol and form factor trends
3.5” HDD 2.5” HDD 2.5” SSD 1.8” SSD
Data storage interconnect speeds increasing
Xyratex Optical Research and Development R. Pitwon
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Design and performance constraints
Xyratex Optical Research and Development R. Pitwon
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ELECTRO-OPTICAL BACKPLANE
Hybrid Electro-Optical Printed
Circuit Board
Standard Compact PCI
backplane architecture
12 electrical layers for power
and C-PCI signal bus and
peripheral connections
Electrical C-PCI connector slots
for SBC and line cards
1 polymeric optical layer for
high speed 10 GbE traffic
4 optical connector sites
Dedicated point-to-point optical
waveguide architecture
Optical
connector site
Compact PCI slots
for line cardsCompact PCI slot
for single board
computer
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ELECTRO-OPTICAL BACKPLANE
Hybrid Electro-Optical Printed
Circuit Board
Standard Compact PCI
backplane architecture
12 electrical layers for power
and C-PCI signal bus and
peripheral connections
Electrical C-PCI connector slots
for SBC and line cards
1 polymeric optical layer for
high speed 10 GbE traffic
4 optical connector sites
Dedicated point-to-point optical
waveguide architecture
Optical
connector site
Compact PCI slot
for single board
computer
Compact PCI slots
for line cards
Polymer optical
waveguides on
optical layer
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HIGH SPEED SWITCHING LINE CARD
XFP ports
8 x 8
Crosspoint
switch
SMP connector sites
Transceiver
programming port
Compact PCI bus
connector
FPGA
Array connector for pluggable
active optical connector
PCI Bridge
XFP ports
Research and Development Overview | Richard Pitwon
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Active optical backplane
connector
Xyratex Optical Research and Development R. Pitwon
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BackplaneLens
Interface
Parallel optical
transceiver
Connector
housing
Copper layers
FR4 layers
Optical layer
Optical backplane connection architecture
Orthogonal docking
Xyratex Optical Research and Development R. Pitwon
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VCSELs PINs
Optical backplane connection architecture
Single waveguide
illuminated
Butt-coupled in-plane connection
Xyratex Optical Research and Development R. Pitwon
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MT pins
Drivers
Optical
platform
Microlens array plate
Mechanically flexible optical platform
MT compatible optical interface
Geometric microlens array
Quad VCSEL driver and TIA/LA
VCSEL / PIN arrays on pre-aligned frame
Parallel optical transceiver
Xyratex Optical Research and Development R. Pitwon
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Spring loaded platform Microcontroller
Active pluggable connector
Parallel optical transceiver Connector module
Xyratex Optical Research and Development R. Pitwon
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Undocked
Cam track
Docked
Ramped
plug
Connector engagement mechanism
Cam
followers
Xyratex Optical Research and Development R. Pitwon
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Peripheral test cards
XFP front end
8 x 8 crosspoint
switch
FPGA
Array
connector
PCI bridge
C-PCI
connector
Optical
connector site
Xyratex Optical Research and Development R. Pitwon
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Demonstration platform
Single board
computer
Peripheral test
card
Compact PCI
chassis
Pluggable optical
connector
Electro-optical
midplane
Xyratex Optical Research and Development R. Pitwon
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Target test card
Electro-optical midplane
High speed data transmission measurements
10 GbE LAN test data
Injected into front end
Pluggable connectors
Polymer waveguides
1st test card
Retrieved through front end
Signal integrity measured
Xyratex Optical Research and Development R. Pitwon
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Acknowledgments
• University College London, UK
– Kai Wang, Hadi Baghsiahi, F. Aníbal Fernández, Ioannis Papakonstantinou
• Loughborough University, UK
– David A. Hutt, Paul P. Conway, John Chappell, Shefiu S. Zakariyah
• Heriot Watt University
– Andy C. Walker, Aongus McCarthy, Himanshu Suyal
• BAE Systems, UK
– Henry White
• Stevenage Circuits Ltd. (SCL), UK
– Dougal Stewart, Jonathan Calver, Jeremy Rygate, Steve Payne, Witold Kandulski
• Xyratex Technology Ltd., UK
– Dave Milward, Richard Pitwon, Ken Hopkins, Malcolm Muggeridge
• Exxelis Ltd
– Navin Suyal, Habib Rehman
• Dow Corning
– Dave DeShazer, Jon DeGroot
• Cadence
– Gary Hinde, Martin Cole
• National Physical Laboratory, NPL
– David Ives, Robert Fergusson
• EPSRC, IeMRC and all partner companies for funding + IBM Zurich for fabrication© UCL 2010