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A 10GHz Hybrid OpticalElectrical Clock

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1) Proposed system concept: System constraints for GHz ... Design for Manufacturability. Proposed Solution. GSI Chip. Detector. tw. tg. tsolder. tPackage ... – PowerPoint PPT presentation

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Title: A 10GHz Hybrid OpticalElectrical Clock


1
A 10GHz Hybrid Optical/Electrical Clock
Distribution Network for Gigascale Integration
Anthony V. Mule, Stephen M. Schultz Thomas K.
Gaylord , and James D. Meindl
Wednesday, Nov. 10th, 1999
2
Outline
  • 1) Proposed system concept
  • System constraints for GHz ?P clock network
  • Proposed solution Optical Clock Distribution
    Network (OCDN)
  • System schematic / Optical properties
  • Key component Focusing grating coupler
  • 2) Components of optical power budget
  • Minimum fanout of distribution
  • Optical power required by receivers
  • Optical power available for detection
  • 3) Conclusions

3
System Constraints
  • Given
  • 1) ITRS projections for 50nm generation
  • Area of 750mm2 (ASIC)
  • 1.4 billion transistors
  • flocal 10GHz
  • Vdd 0.55 V
  • Maximum power density of 50 W/cm2
  • 2) Architectural projections of single chip
    multiprocessor for generations beyond 100nm

Question How to clock the system?
4
Proposed Solution
Optical Clock Distribution Network (OCDN)
  • No on-chip photonic sources
  • Monolithic silicon-based detection
  • Board-level, guided-wave, global propagation
    of local clock frequency
  • Surface-relief focusing grating couplers to
    overcome misalignment of flip-chip assembly

? Design for Manufacturability
5
System Concept
GSI Chip
Detector
twiring
Package
tPackage
Waveguide
Focusing Grating Coupler
tg
tsolder
tw
Printed Wiring Board
6
Key Optical System Properties
7
Focusing Grating Couplers
Focal spot size under non-ideal wavelength,
spatial variations
Grating-to-chip optical path trace to
estimate total output coupling into preferential
order
8
Optical Power Budget
Three components 1) Minimum fanout of
distribution to reach all nodes operating at
local clock frequency, flocal,and maximum
power density of 50 W/cm2 FOmin 2)
Incident optical power required by receivers
to operate at BER of 10E-15, bit rate of
flocal (Gb/s ) Prec 3) Amount of optical power
available at the output of an m-level H-tree
distribution Pout
9
Minimum Fanout of Distribution FOmin
Given
Ngatesx106 (total) 177.5 Ngatesx103 (node)
106.3 Nodes, total 1024

a) Model for ave. wire length, Lavg
b)
c)
d) Asymptotic limit Cw .4CL
10
Receiver Sensitivity1 Prec
BER 10-15RZ Bit Rate 10 Gb/s 50nm
Technology ? Prec 16.5?W
(1)
(2)
1 J.J. Morikuni et. al, Improvements to the
standard theory for photoreceiver noise. J.
Lightwave Tech., vol.12, pp.1174-1183, July 1994.
11
Output Power Pout
a) b) c) d) e) f)
a) Y-junction TE b) Laser-waveguide CE c) Grating
CE d) Air/package TE e) Arc bending loss f)
Propagation loss
TE Transmission Efficiency CE Coupling
Efficiency
12
Receiver Sensitivity1 (Prec) and Output Power
(Pout)
13
Conclusions
  • Approximately 1W of optical input power will
    be required to clock 10GHz system
  • Main sources of optical loss
  • Y-junction scattering loss
  • Grating coupler loss
  • Laser-waveguide coupling loss
  • Overcome bandwidth limitations of global
    electrical interconnects at cost of high optical
    input power

14
Related Research Efforts
  • J.W. Goodman et. al. (Stanford), Optical
    interconnections for VLSI systems. Proceedings
    of the IEEE vol.72, no.7, p.850-66, 1984.
  • L.C. Kimerling, et al. (MIT), Materials for
    monolithic silicon microphotonics. Materials
    and Devices for Silicon- Based Optoelectronics
    Symposium pp.45-56, 1998.
  • R.T.Chen et.al (UT Austin), Optical clock
    distribution in supercomputers using
    polyimide-based waveguides. Proceedings of
    the SPIE - The International Society for
    Optical Engineering vol.3632 p.123-33, 1999.

15
Focusing Grating Couplers
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