Trajectory design and power control for multi-UAV assisted wireless networks: A machine learning approach
Trajectory design and power control for multi-UAV assisted wireless networks: A machine learning approach
A novel framework is proposed for the trajectory design of multiple unmanned aerial vehicles (UAVs) based on the prediction of users’ mobility information. The problem of joint trajectory design and power control is formulated for maximizing the instantaneous sum transmit rate while satisfying the rate
requirement of users. In an effort to solve this pertinent problem, a three-step approach is proposed which is based on machine learning techniques to obtain both the position information of users and the trajectory design of UAVs. Firstly, a multi-agent Qlearning based placement algorithm is proposed for determining
the optimal positions of the UAVs based on the initial location of the users. Secondly, in an effort to determine the mobility information of users based on a real dataset, their position data is collected from Twitter to describe the anonymous usertrajectories in the physical world. In the meantime, an echo
state network (ESN) based prediction algorithm is proposed for predicting the future positions of users based on the real dataset. Thirdly, a multi-agent Q-learning based algorithm is conceived for predicting the position of UAVs in each time slot based on the movement of users. In this algorithm, multiple UAVs act as agents to find optimal actions by interacting with their environment and learn from their mistakes. Additionally, we also prove that
the proposed multi-agent Q-learning based trajectory design and power control algorithm can converge under mild conditions. Numerical results are provided to demonstrate that as the size of the reservoir increases, the proposed ESN approach improves the prediction accuracy. Finally, we demonstrate that throughput gains of about 17% are achieved.
Liu, Xiao
10e71bbc-1ef4-4940-bc21-c42b4bb1b0e3
Liu, Yuanwei
edcf36fa-2653-46c0-8e36-e8144010498e
Chen, Yue
9b646fd4-7826-4d0b-b81a-c4bc5eae1be1
Hanzo, Lajos
66e7266f-3066-4fc0-8391-e000acce71a1
Liu, Xiao
10e71bbc-1ef4-4940-bc21-c42b4bb1b0e3
Liu, Yuanwei
edcf36fa-2653-46c0-8e36-e8144010498e
Chen, Yue
9b646fd4-7826-4d0b-b81a-c4bc5eae1be1
Hanzo, Lajos
66e7266f-3066-4fc0-8391-e000acce71a1
Liu, Xiao, Liu, Yuanwei, Chen, Yue and Hanzo, Lajos
(2019)
Trajectory design and power control for multi-UAV assisted wireless networks: A machine learning approach.
IEEE Transactions on Vehicular Technology.
(doi:10.1109/TVT.2019.2920284).
Abstract
A novel framework is proposed for the trajectory design of multiple unmanned aerial vehicles (UAVs) based on the prediction of users’ mobility information. The problem of joint trajectory design and power control is formulated for maximizing the instantaneous sum transmit rate while satisfying the rate
requirement of users. In an effort to solve this pertinent problem, a three-step approach is proposed which is based on machine learning techniques to obtain both the position information of users and the trajectory design of UAVs. Firstly, a multi-agent Qlearning based placement algorithm is proposed for determining
the optimal positions of the UAVs based on the initial location of the users. Secondly, in an effort to determine the mobility information of users based on a real dataset, their position data is collected from Twitter to describe the anonymous usertrajectories in the physical world. In the meantime, an echo
state network (ESN) based prediction algorithm is proposed for predicting the future positions of users based on the real dataset. Thirdly, a multi-agent Q-learning based algorithm is conceived for predicting the position of UAVs in each time slot based on the movement of users. In this algorithm, multiple UAVs act as agents to find optimal actions by interacting with their environment and learn from their mistakes. Additionally, we also prove that
the proposed multi-agent Q-learning based trajectory design and power control algorithm can converge under mild conditions. Numerical results are provided to demonstrate that as the size of the reservoir increases, the proposed ESN approach improves the prediction accuracy. Finally, we demonstrate that throughput gains of about 17% are achieved.
Text
Trajectory Design and Power Control for Multi-UAV Assisted Wireless Networks A Machine Learning Approach double column
- Accepted Manuscript
More information
Accepted/In Press date: 22 May 2019
e-pub ahead of print date: 31 May 2019
Identifiers
Local EPrints ID: 431634
URI: http://eprints.soton.ac.uk/id/eprint/431634
ISSN: 0018-9545
PURE UUID: bc14f628-9841-42f8-8a05-0fc990e8fdd6
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Date deposited: 11 Jun 2019 16:30
Last modified: 18 Mar 2024 02:36
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Contributors
Author:
Xiao Liu
Author:
Yuanwei Liu
Author:
Yue Chen
Author:
Lajos Hanzo
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