Artificial Intelligence-Based Handoff Management for Dense WLANs: A Deep Reinforcement Learning Approach

Han, Zijun; Lei, Tao; Lu, Zhaoming; Wen, Xiangming; Zheng, Wei; Guo, Lingchao

doi:10.1109/access.2019.2900445

Cited by 40 publications

(27 citation statements)

References 36 publications

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“…In [50], an artificial intelligence framework (AIF) for smart wireless network management was proposed. DCRQN [51] which is a novel Wi-Fi handoff management scheme based on Deep Q-Network (DQN) [52] effectively improves the data rate during the handoff process. In [53], the authors presented DeepNap, which uses a DQN to learn effective BS sleeping policies and reduces the energy consumption of Wi-Fi networks.…”

Section: Deep Reinforcement Learning In Wireless Networkmentioning

confidence: 99%

Energy Efficient 3-D UAV Control for Persistent Communication Service and Fairness: A Deep Reinforcement Learning Approach

Huang

et al. 2020

IEEE Access

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Recently, unmanned aerial vehicles (UAVs) as flying wireless communication platform have attracted much attention. Benefiting from the mobility, UAV aerial base stations can be deployed quickly and flexibly, and can effectively establish Line-of-Sight communication links. However, there are many challenges in UAV communication system. The first challenge is energy constraint, where the UAV battery lifetime is in the order of fraction of an hour. The second challenge is that the coverage area of UAV aerial base station is limited and the commercial UAV is usually expensive. Thus, covering a large target region all the time with sufficient UAVs is quite challenging. To solve above challenges, in this paper, we propose energy efficient and fair 3-D UAV scheduling with energy replenishment, where UAVs move around to serve users and recharge timely to replenish energy. Inspired by the success of deep reinforcement learning, we propose a UAV Control policy based on Deep Deterministic Policy Gradient (UC-DDPG) to address the combination problem of 3-D mobility of multiple UAVs and energy replenishment scheduling, which ensures energy efficient and fair coverage of each user in a large region and maintains the persistent service. Simulation results reveal that UC-DDPG shows a good convergence and outperforms other scheduling algorithms in terms of data volume, energy efficiency and fairness.

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Section: Deep Reinforcement Learning In Wireless Networkmentioning

confidence: 99%

Energy Efficient 3-D UAV Control for Persistent Communication Service and Fairness: A Deep Reinforcement Learning Approach

Huang

et al. 2020

IEEE Access

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“…To be specific, the feature extraction module [24,26] is the key module of the local SDN controller that extracts the spatial as well as temporal features of the raw wireless signal through CNN and RNN respectively. The CNN extracts the relative positions properties of the client in WLAN whereas the deep and wide network measurements are logged on the basis of timestamps that led to modelling of temporal features through RNN.…”

Section: Qaas: the Proposed Ai Framework For Ap Selectionmentioning

confidence: 99%

“…Authors in [25], presented a recurrent neural network based handover management scheme which extract the temporal features to make a handover decision in the SDN-based WLAN. Han et al [26] proposed a handoff management scheme based on the Deep Q Network (DQN) that learns the user behaviour and network state from the beginning in order to learn a good handover policy. Unfortunately, the above discussed works fail to guarantee the user QoS requirements in a dense WLAN environment.…”

Section: Introductionmentioning

confidence: 99%

“…This artificial intelligence framework achieved a significant improvement in throughput, but doesn't consider a holistic framework based on SDN. On the basis of a feature extraction module discussed in [24], authors in [26] proposed a self-learning SDN based artificial intelligence framework to solve the handover management problem in the dense WLAN environment. This DQN based model leverage signal-tointerference-plus-noise ratio (SINR) to define the network state and moreover learns the user behaviour and network status from the beginning without the need of any parameter configuration.…”

Section: Introductionmentioning

confidence: 99%

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QAAs: QoS provisioned artificial intelligence framework for AP selection in next-generation wireless networks

Priya¹,

Malhotra²

2020

Telecommun Syst

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Emerging trend of ubiquitous data access is driving the demand for effective wireless communication connectivity. In essence to this, wireless local area network (WLAN) technology seems to be a reliable and cost effective access for the next-generation wireless ecosystem. But the pivotal challenge for WLAN in the next generation wireless networks is to cater the legions of heterogeneous services with characteristic sets of quality of service requirements. However, the strategies present in the existing literature are not accoutered for the application-agnostic association and are incompetent in handling the enormous WLAN state space. Realising the pitfalls of the existing strategies, a novel software-defined networking enabled artificial intelligence framework has been proposed. The proposed framework implements a novel invalid action reduction scheme and double deep reinforcement learning to guarantee the flow based association in a multi-service WLAN environment. Moreover, it allows the multi-parametric optimisation of the association decision and faster convergence to the stable solution. The analytical results validated through the extensive simulations revealed that the proposed scheme achieves high performance gain in terms of convergence, stability and network utility as compared to the other solutions in the literature.

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“…When dealing with vertical handoffs, there are many challenges. First, because at one time there are more than one devices active, power consumption become a problem [13]. While multiple active network interfaces are running, power drain must be minimized.…”

Section: Vertical Handovermentioning

confidence: 99%

Handoff Decisions in Hetnets using Fuzzy Logic and Machine Learning Techniques

Mahajan,

Prof. Zaheeruddin

2019

IJEAT

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Handover is a vital part of any wireless Mobile Communication Network. Efficient handover algorithms provide a gain in monetary cost effective method for enhancement in the capacity and QOS(quality of services) of cellular system. The work reported here presents a handover decision support system for wireless heterogenous communication. Fuzzy inference system along with neural network techniques in Matlab has been used for the development of the system.Results for performance of five different neural network techniques have been drawn on basis of their training time,classification accuracy and number of neurons taken. The neural tools used here are Back propagation, Radial Basis Function, Nave Bayes, Bayes net and C4.5 decision tree. On the basis of their performance, a best neural tool has been selected for the use in making handover decisions in wireless communication systems and it is seen that among all the neural network tools C 4.5 decision tree gives the better results in terms of classification accuracy and training time for handover decisions

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Artificial Intelligence-Based Handoff Management for Dense WLANs: A Deep Reinforcement Learning Approach

Cited by 40 publications

References 36 publications

Energy Efficient 3-D UAV Control for Persistent Communication Service and Fairness: A Deep Reinforcement Learning Approach

Energy Efficient 3-D UAV Control for Persistent Communication Service and Fairness: A Deep Reinforcement Learning Approach

QAAs: QoS provisioned artificial intelligence framework for AP selection in next-generation wireless networks

Handoff Decisions in Hetnets using Fuzzy Logic and Machine Learning Techniques

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