Interpretation of the space-bandwidth product as the entropy of distinct connection patterns in multifacet optical interconnection architectures
Date
1993Source Title
Journal of the Optical Society of America A: Optics and Image Science, and Vision
Print ISSN
0740-3232
Publisher
Optical Society of America
Volume
10
Issue
3
Pages
418 - 422
Language
English
Type
ArticleItem Usage Stats
111
views
views
83
downloads
downloads
Metadata
Show full item recordAbstract
We show that the entropy of the distinct connection patterns that are possible with multifacet optical interconnection architectures is approximately equal to the space-bandwidth product of the optical system.
Keywords
Approximation theoryEntropy
Mathematical models
Optical interconnects
Optical systems
Pattern recognition
Numerical analysis
Optical data processing
Distinct connection pattern entropy
Multifacet optical interconnection architectures
Space bandwidth products
Distinct connection patterns
Entropy
Optical data processing
Optical interconnects
Permalink
http://hdl.handle.net/11693/26049Published Version (Please cite this version)
https://doi.org/10.1364/JOSAA.10.000418Collections
Related items
Showing items related by title, author, creator and subject.
-
An optical microcantilever with integrated grating coupler
(IEEE, 2009-06)In this paper, we have fabricated an optical cantilever with an integrated grating coupler. We have used an inexpensive and repeatable method for integrating the grating to the silicon cantilever with a microfabrication ... -
Dimensioning shared-per-node recirculating fiber delay line buffers in an optical packet switch
(Elsevier, 2013)Optical buffering based on fiber delay lines (FDLs) has been proposed as a means for contention resolution in an optical packet switch. In this article, we propose a queuing model for feedback-type shared-per-node recirculating ... -
Engineering particle trajectories in microfluidic flows using speckle light fields
(SPIE, 2014)Optical tweezers have been widely used in physics, chemistry and biology to manipulate and trap microscopic and nanoscopic objects. Current optical trapping techniques rely on carefully engineered setups to manipulate ...
