Machine Learning-Based Field Data Analysis and Modeling for Drone Communications

In recent years, unmanned aerial vehicle (UAV), also called a drone, is getting more and more important in many emerging technology areas. For communication area, the drone also takes an important role in lots of significant topics like emergency communications, device-to-device (D2D) communications, and the Internet of Things (IoT). One of the important drone applications is to collect and share data among drones and other aircraft, which is useful for drone control so that dangerous conditions can be avoided. In particular, the drone control and safety guarantees are difficult to attain, especially, when drones fly beyond the line of sight (BLOS). For this reason, we develop a drone location information sharing system using the 920-MHz band. We use this system to do a long distance propagation field experiment for model establishment. Unfortunately, the current data collection for model establishment work needs a great effort and time to do experiments to collect a huge number of data for data analysis so that a suitable model can be established. Therefore, in this paper, we propose a novel method, which is based on machine learning approach, to data analysis and model establishment for drone communications, so that the effort and cost for establishing model can be reduced and a model, which captures more details about the drone communications, can be obtained. The results of this paper validate that the proposed method can indeed establish a more complicated model with less effort. Specifically, from the distribution of the training error, it can be known that there are over 80% training errors with intensity less than 5, which ensures the error performance of the proposed method.

[1]  Jaesung Lim,et al.  Design of Future UAV-Relay Tactical Data Link for Reliable UAV Control and Situational Awareness , 2018, IEEE Communications Magazine.

[2]  Lynne Martin,et al.  Technical capability level 2 unmanned aircraft system traffic management (UTM) flight demonstration: Description and analysis , 2017, 2017 IEEE/AIAA 36th Digital Avionics Systems Conference (DASC).

[3]  Wenxin Yu,et al.  Jointly Optimized Extreme Learning Machine for Short-Term Prediction of Fading Channel , 2018, IEEE Access.

[4]  Insoo Koo,et al.  Feature Selection–Based Detection of Covert Cyber Deception Assaults in Smart Grid Communications Networks Using Machine Learning , 2018, IEEE Access.

[5]  Guan Gui,et al.  Echo-State Restricted Boltzmann Machines: A Perspective on Information Compensation , 2019, IEEE Access.

[6]  Fumiyuki Adachi,et al.  Deep-Learning-Based Millimeter-Wave Massive MIMO for Hybrid Precoding , 2019, IEEE Transactions on Vehicular Technology.

[7]  Richard D. Gitlin,et al.  Unsupervised machine learning in 5G networks for low latency communications , 2017, 2017 IEEE 36th International Performance Computing and Communications Conference (IPCCC).

[8]  Masahiro Morikura,et al.  Machine-Learning-Based Throughput Estimation Using Images for mmWave Communications , 2017, 2017 IEEE 85th Vehicular Technology Conference (VTC Spring).

[9]  Ryu Miura,et al.  A dynamic trajectory control algorithm for improving the communication throughput and delay in UAV-aided networks , 2016, IEEE Network.

[10]  Walid Saad,et al.  Unmanned Aerial Vehicle With Underlaid Device-to-Device Communications: Performance and Tradeoffs , 2015, IEEE Transactions on Wireless Communications.

[11]  Geoffrey Ye Li,et al.  Power of Deep Learning for Channel Estimation and Signal Detection in OFDM Systems , 2017, IEEE Wireless Communications Letters.

[12]  Ryu Miura,et al.  Toward Future Unmanned Aerial Vehicle Networks: Architecture, Resource Allocation and Field Experiments , 2019, IEEE Wireless Communications.

[13]  Mohamed S. Shehata,et al.  Drone-Based Highway-VANET and DAS Service , 2018, IEEE Access.

[14]  Guan Gui,et al.  Deep Learning for Super-Resolution Channel Estimation and DOA Estimation Based Massive MIMO System , 2018, IEEE Transactions on Vehicular Technology.

[15]  Ryu Miura,et al.  AC-POCA: Anticoordination Game Based Partially Overlapping Channels Assignment in Combined UAV and D2D-Based Networks , 2017, IEEE Transactions on Vehicular Technology.

[16]  Jie Yang,et al.  Data-Driven Deep Learning for Automatic Modulation Recognition in Cognitive Radios , 2019, IEEE Transactions on Vehicular Technology.

[17]  Wenchao Xu,et al.  Multiple Drone-Cell Deployment Analyses and Optimization in Drone Assisted Radio Access Networks , 2018, IEEE Access.

[18]  Nei Kato,et al.  Location Awareness System for Drones Flying Beyond Visual Line of Sight Exploiting the 400 MHz Frequency Band , 2019, IEEE Wireless Communications.

[19]  Joonhyuk Kang,et al.  Mobile Edge Computing via a UAV-Mounted Cloudlet: Optimization of Bit Allocation and Path Planning , 2016, IEEE Transactions on Vehicular Technology.

[20]  John Collura,et al.  Unmanned Aircraft System traffic management: Concept of operation and system architecture , 2016 .

[21]  Lav Gupta,et al.  Survey of Important Issues in UAV Communication Networks , 2016, IEEE Communications Surveys & Tutorials.

[22]  Mohsen Guizani,et al.  Multiple Moving Targets Surveillance Based on a Cooperative Network for Multi-UAV , 2018, IEEE Communications Magazine.

[23]  Jie Yang,et al.  DSF-NOMA: UAV-Assisted Emergency Communication Technology in a Heterogeneous Internet of Things , 2019, IEEE Internet of Things Journal.

[24]  Kentaro Ishizu,et al.  Big Data Analytics, Machine Learning, and Artificial Intelligence in Next-Generation Wireless Networks , 2017, IEEE Access.

[25]  E.J. Candes,et al.  An Introduction To Compressive Sampling , 2008, IEEE Signal Processing Magazine.