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A Survey on Channel Assignment for Multi-Radio Meshed Networks

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Presentation on theme: "A Survey on Channel Assignment for Multi-Radio Meshed Networks"— Presentation transcript:

1 A Survey on Channel Assignment for Multi-Radio Meshed Networks
Maria Dolores Salmerón Pérez

2 Introduction: Wireless mesh networks
Wireless Mesh Networks (WMNs): mix between two wireless networks topologies: ad-hoc networks and structural topology. Differences between ad-hoc networks and WMNs Topology changes Mobility Scenario of application Important research area Increasing the coverage area of the network Larger number of access points

3 Introduction: Wireless mesh networks
WMNs and Ad hoc networks: Normally single radio systems Disadvantages: Lower throughput Nodes with half-duplex mode Many channel changes due to dynamic network traffic Interference from external sources Shared Spectrum Solution: Multiradio systems (most of the current WMN deployments adopt the multi-radio multi- channel architecture)

4 Introduction: Wireless mesh networks
Based on the standards: IEEE a (5 GHz) / IEEE b (2.4 GHz) IEEE a/b standards provide respectively 12 and 3 non-overlapped frequency channel Ability to use multiple channels substantially increase the effective bandwidth available to wireless networks

5 Introduction: Wireless mesh networks
In the standard IEEE b there are 12 available channels but only the channels 1, 6 and 11 have low interference and/or overlapping with each other.

6 Problem formulation A pair of nodes that use the same channel and within interference range may interfere with each other’s communication Figure (b) is an example of channel assignment for figure (a) that minimizes the number of interfering links for nodes A and B

7 Solution: channel assignment
For any mesh network, there are multiple ways to assign channels to the radios Solution: Find a proper channel assignment in every node of the network CA algorithms Goals: Increased bandwidth Performance improvement

8 Solution: channel assignment
Classification of Channel Assignment approaches for MR-MC WMNs : Centralized: central control Distributed: no central control

9 Solution: channel assignment
Centralized algorithm: CLICA (Connected Low Interference Channel Assignment) Polinomial time greedy heuristic Traffic independent Based on the connectivity graph and on the conflict graph Every node is associated with a priority Coloring decisions are made node by node basis in the order of this priority Reducing interference

10 Solution: channel assignment
Example of CLICA algorithm:

11 Solution: channel assignment
Distributed algorithm: DCA (Distributed Coloring Algorithm) Clustering algorithm is applied previously to make set of nodes. Distributed Clustering Algorithm that find the cluster-head Cluster-head is the responsible of the graph coloring i.e. of the channel assignment Every cluster-head has a priority or weight and knows the priorities of its neighbours nodes Cluster-head colors its cluster only if highest priority cluster-head neighbors have colored completely their clusters

12 Solution: channel assignment
Example of DCA algorithm: There are 3 types of messages that determine the action of every node: CA: allows any node to know its color UP: updates the color of one node INF: inform about forbidden colors

13 Solution: channel assignment
Distributed algorithm: MIX (Minimum Interference Channel Selection) Clustering algorithm is applied previosly to make set of nodes. Highest Connectivity Cluster algorithm that find a cluster-head MIX is based on minimizing co-channel interference between clusters Access points have two interfaces: First interface: for inter-cluster communication Second interface: for intra-cluster communications using the channel selected by the cluster-head through MIX algorithm

14 Solution: channel assignment
Example of MIX algorithm:

15 Conclusions DCA is an algorithm designed for devices on a single radio interface and a relatively low consumption MIX algorithm is the most appropriate algorithm for a larger size of network and the throughput is better than DCA CLICA has some limitations but compared with the distributed algorithms the performance is a bit better

16 Conclusions Centralized algorithms usually have in the most of the cases a better performance because they used entire network information Centralized algorithms: nearer throughput to the optimal Problem of the algorithms NP-hard problems (difficult to find an optimal solution and exponential runtime ) Heuristics approximation modes (not optimal results)

17 QUESTIONS

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