Abstract
To satisfy the increasing demand for wireless systems capacity, the industry is dramatically increasing the density of the deployed networks. Like other wireless technologies, Wi-Fi is following this trend, particularly because of its increasing popularity. In parallel, Wi-Fi is being deployed for new use cases that are atypically far from the context of its first introduction as an Ethernet network replacement. In fact, the conventional operation of Wi-Fi networks is not likely to be ready for these super dense environments and new challenging scenarios. For that reason, the high efficiency wireless local area network (HEW) study group (SG) was formed in May 2013 within the IEEE 802.11 working group (WG). The intents are to improve the “real world” Wi-Fi performance especially in dense deployments. In this context, this work proposes a new centralized solution to jointly adapt the transmission power and the physical carrier sensing based on artificial neural networks. The major intent of the proposed solution is to resolve the fairness issues while enhancing the spatial reuse in dense Wi-Fi environments. This work is the first to use artificial neural networks to improve spatial reuse in dense WLAN environments. For the evaluation of this proposal, the new designed algorithm is implemented in OPNET modeler. Relevant scenarios are simulated to assess the efficiency of the proposal in terms of addressing starvation issues caused by hidden and exposed node problems. The extensive simulations show that our learning-based solution is able to resolve the hidden and exposed node problems and improve the performance of high-density Wi-Fi deployments in terms of achieved throughput and fairness among contending nodes.
Highlights
Today, IEEE 802.11 wireless local area network (WLAN) [1] that is widely known as Wi-Fi is the dominant standard in WLAN technology
We consider a more complex scenario that reflects a real-world high-density deployment and we evaluate our proposal in such challenging circumstances. 1.7 Hidden node scenario We talk about a hidden node problem when a node that is not able to sense the signal transmitted by an another neighboring node operating at the same channel, and it assumes that the medium is free and transmits
2 Conclusions A key perspective considered in the ongoing development of the WLAN generation is increasing the spatial reuse in high-density deployments by adapting the MAC layer protocols
Summary
IEEE 802.11 wireless local area network (WLAN) [1] that is widely known as Wi-Fi is the dominant standard in WLAN technology. Artificial neural networks (ANNs) [13] derive their computing power through their parallel distributed structure that gives them the ability to learn and to generalize by producing reasonable outputs for new unseen inputs. I=1 where y is the output of the neurone, a(.) is the activation function, n is the number of inputs to the neuron, wi is the weight of input i, xi is the value of input i, and b is the bias value. 1.2.2 An artificial neural network An ANN is obtained by combining multiple artificial neurons. These single neurons are distributed over several layers, namely input, hidden, and output layers. The unsupervised approach consists on setting the weights and biases to values that minimize a predefined error function
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