Link Delay Estimation via Expander Graphs

Author

Firooz, Mohammad Hamed ; Roy, Sandip

Author_Institution

Dept. of Electr. Eng., Univ. of Washington, Seattle, WA, USA

Volume

62

Issue

1

fYear

2014

fDate

Jan-14

Firstpage

170

Lastpage

181

Abstract

One of the purposes of network tomography is to infer the status of parameters (e.g., delay) for the links inside a network through end-to-end probing between (external) boundary nodes along predetermined routes. In this work, we apply concepts from compressed sensing and expander graphs to the delay estimation problem. We first show that a relative majority of network topologies are not expanders for existing expansion criteria. Motivated by this challenge, we then relax such criteria, enabling us to acquire simulation evidence that link delays can be estimated for 30% more networks. That is, our relaxation expands the list of identifiable networks with bounded estimation error by 30%. We conduct a simulation performance analysis of delay estimation and congestion detection on the basis of l₁ minimization, demonstrating that accurate estimation is feasible for an increasing proportion of networks.

Keywords

compressed sensing; graph theory; minimisation; protocols; telecommunication network management; telecommunication network routing; telecommunication network topology; boundary nodes; compressed sensing; congestion detection; end-to-end network tomography protocol; end-to-end probing; expander graphs; l₁ minimization; link delay estimation problem; network management framework; network tomography; parameter status inference; predetermined routes; simulation evidence acquisition; Bipartite graph; Delays; Optimization; Routing; Tomography; Vectors; Network tomography; compressed sensing; delay estimation; expander graphs; l_1 minimization;

fLanguage

English

Journal_Title

Communications, IEEE Transactions on

Publisher

ieee

ISSN

0090-6778

Type

jour

DOI

10.1109/TCOMM.2013.112413.120750

Filename

6679365