TY - JOUR
T1 - Impact of route length on the performance of routing and flow admission control algorithms in wireless sensor networks
AU - Farooq, Muhammad Omer
AU - Kunz, Thomas
PY - 2016/2/1
Y1 - 2016/2/1
N2 - In this study, the impact of route length on the performance of a routing protocol and flow admission control is analysed. First, the authors present an end-to-end available-bandwidth-based proactive routing protocol for ad-hoc wireless sensor networks. The routing protocol maintains the best data forwarding path in terms of the end-to-end available bandwidth. Second, to determine the impact of route length on a routing protocol's performance, they modify the routing protocol. The modified available-bandwidth-based protocol trades-off the end-to-end available bandwidth against the route length. Third, they integrate a state-of-the-art flow admission control algorithm with the proposed protocols and a shortest hop-count-based protocol. Through simulations they evaluate the following: (i) performance of the proposed protocols and a state-of-the-art available-bandwidth-based opportunistic protocol and (ii) the effectiveness of a state-of-the-art flow admission control algorithm over proposed protocols and a shortest hopcount- based protocol. The simulation results demonstrate the following drawbacks of not considering the hop-count metric: longer data forwarding paths, higher number of retransmissions, and reduced effectiveness of the admission control algorithm. The modified available-bandwidth-based proactive protocol provides the best overall performance. Therefore, using their results they conclude that route length impacts the performance of routing and flow admission control algorithms, but is not a singularly decisive factor.
AB - In this study, the impact of route length on the performance of a routing protocol and flow admission control is analysed. First, the authors present an end-to-end available-bandwidth-based proactive routing protocol for ad-hoc wireless sensor networks. The routing protocol maintains the best data forwarding path in terms of the end-to-end available bandwidth. Second, to determine the impact of route length on a routing protocol's performance, they modify the routing protocol. The modified available-bandwidth-based protocol trades-off the end-to-end available bandwidth against the route length. Third, they integrate a state-of-the-art flow admission control algorithm with the proposed protocols and a shortest hop-count-based protocol. Through simulations they evaluate the following: (i) performance of the proposed protocols and a state-of-the-art available-bandwidth-based opportunistic protocol and (ii) the effectiveness of a state-of-the-art flow admission control algorithm over proposed protocols and a shortest hopcount- based protocol. The simulation results demonstrate the following drawbacks of not considering the hop-count metric: longer data forwarding paths, higher number of retransmissions, and reduced effectiveness of the admission control algorithm. The modified available-bandwidth-based proactive protocol provides the best overall performance. Therefore, using their results they conclude that route length impacts the performance of routing and flow admission control algorithms, but is not a singularly decisive factor.
UR - http://www.scopus.com/inward/record.url?scp=84957887161&partnerID=8YFLogxK
U2 - 10.1049/iet-wss.2014.0115
DO - 10.1049/iet-wss.2014.0115
M3 - Journal articles
AN - SCOPUS:84957887161
SN - 2043-6386
VL - 6
SP - 10
EP - 16
JO - IET Wireless Sensor Systems
JF - IET Wireless Sensor Systems
IS - 1
ER -