Efficient beacon placement for network tomography

Kumar, R. Arockia; Kaur, Jasleen

doi:10.1145/1028788.1028810

Cited by 30 publications

(22 citation statements)

References 12 publications

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“…S2 = {P3 (1,4,6), P4 (1,3,6,7,8), P5 (1,2,5,4,7,8)} is an optimal corresponding path set. In the first scenario, the links (1, 3), (3,6) and (7,8) are monitored twice; they belong each to two monitored paths. The deployment of an additional monitor in the second scenario reduces the number of bi-monitored links to one link (6,7).…”

Section: Problem Formulationmentioning

confidence: 99%

“…In the first scenario, the links (1, 3), (3,6) and (7,8) are monitored twice; they belong each to two monitored paths. The deployment of an additional monitor in the second scenario reduces the number of bi-monitored links to one link (6,7). We conclude that the less monitors are deployed in the network, the more redundant measurements of links we obtain.…”

Section: Problem Formulationmentioning

confidence: 99%

“…Several works proposed schemes to place as few monitoring devices as possible at strategic locations of the network such that all network links are covered (e.g. [7]- [9]). The works in [1]- [6] addressed the minimization of the overhead of the inference techniques.…”

Section: Related Workmentioning

confidence: 99%

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Joint optimization of monitor location and network anomaly detection

Salhi

Lahoud

Cousin

2010

IEEE Local Computer Network Conference

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Abstract-Achieving cost-effective systems for network performance monitoring has been the subject of many research works over the last few years. Most of them adopt a two-step approach. The first step assigns optimal locations to monitoring devices, whereas the second step selects a minimal set of paths to be monitored. However, such an approach does not consider the trade-off between the optimization objectives of each step, and hence may lead to sub-optimal usage of network resources and biased measurements. In this paper, we propose to evaluate and reduce this tradeoff. Toward this end, we come up with two ILP formulations for a novel monitoring cost model. The aim is to jointly minimize the monitor location cost and the anomaly detection cost, thereby obtaining a monitoring solution that minimizes the total monitoring cost. Our formulations apply for both active and passive monitoring architectures. We show that the problem is NP-hard by mapping it to the uncapacitated facility location problem. Simulation results illustrate the interplay between the optimization objectives and evaluate the quality of the obtained monitoring solution.

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Section: Problem Formulationmentioning

confidence: 99%

Section: Problem Formulationmentioning

confidence: 99%

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Joint optimization of monitor location and network anomaly detection

Salhi

Lahoud

Cousin

2010

IEEE Local Computer Network Conference

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“…Many routers frequently disable the source routing option. Authors in [17] and [18] propose placement of monitoring stations that is robust to route changes. Horton and Lopez-Ortiz [17] propose a strategy to use high arity nodes for beacon placement to test for connectivity on all relevant edges of the network.…”

Section: Related Workmentioning

confidence: 99%

“…Horton and Lopez-Ortiz [17] propose a strategy to use high arity nodes for beacon placement to test for connectivity on all relevant edges of the network. However the beacon set size could be quite large for real ISP topologies [18]. Kumar and Kaur [18] propose an approach for beacon placement by identifying edge sets that can be monitored by a beacon under all possible route configurations.…”

Section: Related Workmentioning

confidence: 99%

Probe Station Placement for Robust Monitoring of Networks

Natu¹,

Sethi

2008

J Netw Syst Manage

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We address the problem of selecting probe station locations from where probes can be sent to monitor all the nodes in the network. Probe station placement involves instrumentation overhead. Hence, the number of probe stations should be minimal to reduce the deployment cost. Also, probe station placement should be such that the network can be monitored even in the presence of failures. We present algorithms to select locations of probe stations so that the entire network can be monitored for computing various performance metrics. We aim to find a minimal set of probe station nodes so as to minimize the instrumentation overhead. The algorithm presented provides robust monitoring in presence of node failures. We then present algorithms to make the solution resilient to probe station failures, and to deal with weakly connected nodes. We provide an experimental evaluation of the proposed algorithms through simulation results.

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Algorithmic Foundations of the Internet: Roundup

López-Ortíz

2005

Combinatorial and Algorithmic Aspects of Networking

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Efficient beacon placement for network tomography

Cited by 30 publications

References 12 publications

Joint optimization of monitor location and network anomaly detection

Joint optimization of monitor location and network anomaly detection

Probe Station Placement for Robust Monitoring of Networks

Algorithmic Foundations of the Internet: Roundup

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