Abstract
In the context of Fifth Generation mobile networks (5G), Search and Rescue (SAR) missions using Unmanned Aerial Vehicles (UAVs) can benefit from a dynamic, intelligent, and autonomous placement of both Network Functions (NFs) and Artificial Intelligence (AI) systems to quickly adapt in minimal human intervention scenarios. This article examines current 5G architectures and timely standardization efforts within this context. The contribution of this work is to identify associated 5G components and propose AI modules that enable efficient UAV-based SAR missions: the System Intelligence (SI) and Edge Intelligence (EI) concepts. SI is conceived as the entity responsible for defining and orchestrating the placement and processing tasks of NFs and AI systems, while EI is responsible for the optimization of AI-based end-user applications. The article also presents an open-source virtualized testbed that enables a concrete example of SI and EI roles in a SAR mission based on object detection with Deep Neural Networks (DNNs). In this proof-of-concept, the DNN layers are partitioned and the tradeoffs between communication and computational costs are highlighted. For instance, the results indicate that the latency can severely degrade the UAV trajectory and different DNN partitioning options can reduce the required bit rate to transmit DNN scores by more than three times.
Highlights
Search and Rescue (SAR) operations are special critical missions targeting the location and retrieval of persons in distress [1]
OPEN ISSUES AND CONCLUSION In this article, the benefits and challenges of Artificial Intelligence (AI) in critical missions based on Unmanned Aerial Vehicles (UAVs) in 5th Generation Mobile Networks (5G)/Beyond 5G (B5G) networks were discussed
In UAV-enabled communication networks, there is a tradeoff between UAV performing the computation locally versus offloading the information to be processed elsewhere
Summary
Search and Rescue (SAR) operations are special critical missions targeting the location and retrieval of persons in distress [1]. Some technological challenges need to be overcome for improved UAV-based missions since current regular communication networks do not support the demands of highly dynamic SAR scenarios. A long-range network is essential to provide connectivity in the rescue area It offers extreme reach for UAV, voice communication for the rescuers and ransomed ones, and control for autonomous machines to diagnose the SDAR operation. A terrestrial Radio Access Network (RAN) is essential to cover all requirements imposed by the SDAR applications In this sense, the 5G radio interface is an attractive solution because it is very flexible and enables enhanced Mobile Broadband (eMBB) for video and ultra-Reliable Low Latency (URLL) for UAVs command and control.
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