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Optical interconnect

From Wikipedia, the free encyclopedia

In integrated circuits, optical interconnects refers to any system of transmitting signals from one part of an integrated circuit to another using light. Optical interconnects have been the topic of study due to the high latency and power consumption incurred by conventional metal interconnects in transmitting electrical signals over long distances, such as in interconnects classed as global interconnects. The International Technology Roadmap for Semiconductors (ITRS) has highlighted interconnect scaling as a problem for the semiconductor industry.

In electrical interconnects, nonlinear signals (e.g. digital signals) are transmitted by copper wires conventionally, and these electrical wires all have resistance and capacitance which severely limits the rise time of signals when the dimension of the wires are scaled down. Optical solution are used to transmit signals through long distances to substitute interconnection between dies within the integrated circuit (IC) package.

In order to control the optical signals inside the small IC package properly, microelectromechanical system (MEMS) technology can be used to integrate the optical components (i.e. optical waveguides, optical fibers, lens, mirrors, optical actuators, optical sensors etc.) and the electronic parts together effectively.

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Transcription

Problems of the current interconnect in the package

Conventional physical metal wires possess both resistance and capacitance, limiting the rise time of signals. Bits of information will overlap with each other when the frequency of signal is increased to a certain level.[1]

Benefits of using optical interconnection

Optical interconnections can provide benefits over conventional metal wires which include:[1]

  1. More predictable timing
  2. Reduction of power and area for clock distribution
  3. Distance independence of performance of optical interconnects
  4. No frequency-dependent Cross-talk
  5. Architectural advantages
  6. Reducing power dissipation in interconnects
  7. Voltage isolation
  8. Density of interconnects
  9. Reducing the wiring layers
  10. Chips could be tested in a non-contact optical test set
  11. Benefits of short optical pulses

Challenges for optical interconnect

However, there are still many technical challenges in implementing dense optical interconnects to silicon CMOS chips. These challenges are listed as below:[2]

  1. Receiver circuits and low-capacitance integration of photodetectors
  2. Evolutionary improvement in optoelectronic devices
  3. Absence of appropriate practical optomechanical technology
  4. Integration technologies
  5. Polarization control
  6. Temperature dependencies and process variation
  7. Losses and errors
  8. Testability
  9. Packaging

See also

References

  1. ^ a b David A. B. Miller, ‘Rationale and Challenges for Optical Interconnects to Electronic Chips’, Proceedings of the IEEE, Vol. 88, No. 6, June 2000
  2. ^ R.K. Dokania and A.B. Apsel, "Analysis of Challenges for On-Chip Optical Interconnects", ACM Proceedings of Great Lakes Symposium on VLSI, May 10–12, 2009, Boston
This page was last edited on 16 April 2024, at 01:24
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