Feasibility study of a scalable optical interconnection network for massively parallel processing systems

Ahmed Louri, Stephen Furlonge

Research output: Contribution to journalArticle

10 Scopus citations

Abstract

The theoretical modeling of a novel topology for scalable optical interconnection networks, called optical multimesh hypercube (OMMH), is developed to predict size, bit rate, bit-error rate, power budget, noise, efficiency, interconnect distance, pixel density, and misalignment sensitivity. The numerical predictions are validated with experimental data from commercially available products to assess the effects of various thermal, system, and geometric parameters on the behavior of the sample model. OMMH is a scalable network architecture that combines positive features of the hypercube (small diameter, regular, symmetric, and fault tolerant) and the mesh (constant node degree and size scalability). The OMMH is implemented by a free-space imaging system incorporated with a space-invariant hologram for the hypercube links and fiber optics to provide the mesh connectivity. The results of this work show that the free-space links can operate at 368 Mbits/s and the fiber-based links at 228 Mbits/s for a bit-error rate of 10-17 per channel. The predicted system size for 32 nodes in the OMMH is 4.16 mm 3 4.16 mm × 3.38 cm. Using 16-bit, bit-parallel transmission per node, the system can operate at a bit rate of up to 5.88 Gbits/s for a size of 1.04 cm × 1.04 cm × 3.38 cm.

Original languageEnglish (US)
Pages (from-to)1296-1308
Number of pages13
JournalApplied optics
Volume35
Issue number8
DOIs
StatePublished - Mar 10 1996

Keywords

  • Holographic grating
  • Hypercube
  • Interconnection network
  • Mesh
  • Modeling
  • Optical interconnect
  • Parallel computing
  • Scalability
  • Space invariance

ASJC Scopus subject areas

  • Atomic and Molecular Physics, and Optics
  • Engineering (miscellaneous)
  • Electrical and Electronic Engineering

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