Volume 5 , Issue 2 , PP: 64-76, 2022 | Cite this article as | XML | Html | PDF | Full Length Article
Harith Yas 1 * , Manal M. Nasir 2
Doi: https://doi.org/10.54216/IJWAC.050205
Numerous research has been conducted in order to investigate the performance of IEEE 802.11LEACH for a single-cell Wireless Local Area Network (WLAN) under saturation conditions. Saturation conditions are those in which it is anticipated that the queues of nodes will never be empty. To put it another way, there is always a packet waiting to be sent out from each and every node in the network. The term "infinite load" refers to the condition of saturation, which is a situation that may be regarded as having an endless load. Even though conducting an analysis under saturated conditions may provide some insight into how well the network operates in a high-pressure setting, this strategy does not appear to be practical because there is a possibility that the network will not always be at capacity. Even though conducting such an analysis under saturation circumstances may provide some insight into how well the network operates in a high-pressure setting, it is still not practical. When using CQSR, the source is aware of the correlation that exists between the many different paths that go to the destination. When it comes to the provision of quality service in an ad hoc network, having several pathways among a specific cause and an endpoint may be of assistance in the following scenarios. Having multiple pathways between a source and a destination may also be of assistance when it comes to the provision of quality service. It is feasible that a single channel will not be able to deliver adequate resources to meet the desired quality of service if the resources of mobile nodes are limited. This scenario might occur if mobile nodes are subject to resource limitations. The requirements of the application in terms of the quality of service might, however, be satisfied by the resources located along any one of the many possible paths that could exist between the specified pair of nodes. It seems likely that this will turn out to be the situation. The task force may be dispersed over a number of different routes if there are adequate resources available along each route. To put it another way, data packets are sent along each path that satisfies the criteria for acceptable quality-of-service levels. If you use many routes instead of just one, you may be able to obtain a throughput that is far higher than you would with a single route. In the previous proposed work, we did an analysis of IEEE 802.11 LEACH for an ad hoc network under saturation conditions. Saturation circumstances refer to scenarios in which it is believed that the queues of nodes are never empty. On the other hand, it is likely that the nodes that make up an ad hoc network will not always be totally filled.
Adhoc network , Quality of Service , Wireless Local Area Network , IEEE 802.11 , mobile nodes
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