Constructions of Fault Tolerant Linear Compressors and Linear Decompressors

Abstract

The constructions of optical buffers is one of the most critically sought after optical technologies in all-optical packet-switched networks, and constructing optical buffers directly via optical switches and fiber delay lines (SDL) has received a lot of attention recently in the literature. A practical and challenging issue of the constructions of optical buffers that has not been addressed before is on the fault tolerant capability of such constructions. In this paper, we focus on the constructions of fault tolerant linear compressors and linear decompressors. The basic network element for our constructions is scaled optical memory cell, which is constructed by a 2 x 2 optical crossbar switch and a fiber delay line. We give a multistage construction of a self-routing linear compressor by a concatenation of scaled optical memory cells. We also show that if the delays, say d1,d2,... ,dm , of the fibers in the scaled optical memory cells satisfy a certain condition (specifically, the condition in (A 2) given in Section I), then our multistage construction can be operated as a self-routing linear compressor with maximum delay Sigma M-F i=1 d i even after up to F of the M scaled optical memory cells fail to function properly, where 0 les F les M - 1. Furthermore, we prove that our multistage construction with the fiber delays d1, d2, ... , d M given by the generalized Fibonacci sequence of order F is the best among all constructions of a linear compressor that can tolerate up to F faulty scaled optical memory cells by using M scaled optical memory cells. Similar results are also obtained for the constructions of fault tolerant linear decompressors.