Book contents
- Frontmatter
- Contents
- List of Contributors
- Preface
- 1 How optical computers, architectures, and algorithms impact system design
- 2 Noise issues in optical linear algebra processor design
- 3 Effects of diffraction, scatter, and design on the performances of optical information processors
- 4 Comparison between holographic and guided wave interconnects for VLSI multiprocessor systems
- 5 High speed compact optical correlator design and implementation
- 6 Optical and mechanical issues in free-space digital optical logic systems
- Index
4 - Comparison between holographic and guided wave interconnects for VLSI multiprocessor systems
Published online by Cambridge University Press: 20 October 2009
- Frontmatter
- Contents
- List of Contributors
- Preface
- 1 How optical computers, architectures, and algorithms impact system design
- 2 Noise issues in optical linear algebra processor design
- 3 Effects of diffraction, scatter, and design on the performances of optical information processors
- 4 Comparison between holographic and guided wave interconnects for VLSI multiprocessor systems
- 5 High speed compact optical correlator design and implementation
- 6 Optical and mechanical issues in free-space digital optical logic systems
- Index
Summary
Introduction
This chapter is dedicated to the evaluation of optical interconnects between electronic processors in multiprocessor systems. Each processor is fully electronic except for the incorporation of a number of photodetectors and optical signal transmitters (e.g., laser diodes, light emitting diodes (LEDs) or optical modulators).
The motivation for this analysis stems from fundamental advantages of optics as well as those of electronics. While electrons are charged fermions, subject to strong mutual interactions and strong reactions to other charged particles, photons are neutral bosons, virtually unaffected by mutual interactions and Coulomb forces. Thus, unlike electrons, multiple beams of photons can cross paths without significant interference. This property allows holographic interconnects to achieve a 3-D (three-dimensional) connection density with only 2-D optical elements. Similarly, photons can propagate through transparent materials without appreciable attenuation or power dissipation. Thus, neglecting speed of light delays, the speed of an optical link is limited only by the switching speed and capacitance of the transmitters and detectors. (For a 10 cm connection length, and a 50° hologram deflection angle, the speed-of-light delay is 0.5 ns.) Hence, the speed and power requirements of an optical interconnect are independent of the connection length. Since electrical very large scale integration (VLSI) connections have a switching energy directly proportional to the line length and an RC delay that grows quadratically with line length, for long enough communication links, optical connections will dissipate less power and provide faster data rate communication.
- Type
- Chapter
- Information
- Design Issues in Optical Processing , pp. 137 - 168Publisher: Cambridge University PressPrint publication year: 1995