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A Machine Learning Based Forwarding Algorithm Over Cognitive Radios in Wireless Mesh Networks

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arxiv 1608.03536 v1 pith:KTXT3ZCP submitted 2016-08-11 cs.NI

A Machine Learning Based Forwarding Algorithm Over Cognitive Radios in Wireless Mesh Networks

classification cs.NI
keywords bandwidthforwardingnodealgorithmlearningmeshmachinenext
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Wireless Mesh Networks improve their capacities by equipping mesh nodes with multi-radios tuned to non-overlapping channels. Hence the data forwarding between two nodes has multiple selections of links and the bandwidth between the pair of nodes varies dynamically. Under this condition, a mesh node adopts machine learning mechanisms to choose the possible best next hop which has maximum bandwidth when it intends to forward data. In this paper, we present a machine learning based forwarding algorithm to let a forwarding node dynamically select the next hop with highest potential bandwidth capacity to resume communication based on learning algorithm. Key to this strategy is that a node only maintains three past status, and then it is able to learn and predict the potential bandwidth capacities of its links. Then, the node selects the next hop with potential maximal link bandwidth. Moreover, a geometrical based algorithm is developed to let the source node figure out the forwarding region in order to avoid flooding. Simulations demonstrate that our approach significantly speeds up the transmission and outperforms other peer algorithms.

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