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IEEE Journal of Lightwave Technology
Volume 18 Number 11, November 2000

Table of Contents for this issue

Complete paper in PDF format

An 8-Gb/s Optical Backplane Bus Based on Microchannel Interconnects: Design, Fabrication, and Performance Measurements

Gicherl Kim, Xuliang Han and Ray T. Chen Senior Member, IEEE

Page 1477.

Abstract:

We describe the characteristics of a microchannel-based optical backplane including signal-to-noise ratio (SNR), interconnect distances, and data transfer rates. The backplane employs 250µm-spacing two-dimensional (2-D) vertical cavity surface emitting lasers (VCSELs) and a microlens array to implement 500 µm-,750 µm-, and 1-mm optical beam arrays. By integrating the transmitter and a multiplexed polymeric hologram as a deflector/beam-splitter for the guided-wave optical backplane, the result demonstrates a multibus line architecture and its high-speed characteristics. Maximum interconnect distances of 6 cm and 14 cm can be achieved to satisfy 10-12 bit error rate (BER) using 2 × 2 beams of 500µm-and 1 mm-spacing array devices. The total data transfer rate of the developed backplane has shown 8 Gb/s from eye diagram measurements.

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