Abstract
We evaluate the performance of optical network designs using relatively few
switch nodes at which wavelength conversion and electronic regeneration is possible.
A simple heuristic for placing the fewest such nodes to reach a given blocking
probability is based on the ranked frequency of shortest-path routes transiting each
node. This strategy is found to be efficient in designing a translucent optical
network with sparse electronic switch placement that performs very close in blocking
to that of an opaque optical network. In addition, we apply a new two-dimensional
Dijkstra algorithm for routing and wavelength assignment in the resultant
translucent optical network. Simulation results indicate that a translucent optical
network with sparse electronic switch placement based on the heuristic has much
lower blocking than a fully transparent optical network when the constraint of the
maximum transparent distance before regeneration is also considered. Moreover, when
the switches are placed according to the heuristic, lightpath blocking can approach
that of a fully opaque network with significantly fewer total electronic switches.
In our results, lightpath blocking as low as that with the fully opaque network case
was obtained with electronic switches selectively placed at approximately one node
in three on average. The heuristic also performs well against random searching for
an effective subset of electronic switch nodes and performs better than a prior
optimal method that is based on a combinatorially exhaustive search and that is
limited to assuming fixed shortest-path routing.
© 2002 Optical Society of America
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