Reconfigurable Intelligent Surfaces (RIS) integrated with Unmanned Aerial Vehicles (UAVs) have emerged as a promising technology in the evolution of next-generation wireless communication systems. Herein, the potential of RIS-assisted UAV architectures are discussed, focusing particularly on their role in supporting Backscatter Communication (BackCom)— a low-power paradigm suitable for passive IoT devices — which remains little explored. To fill this gap, two representative paradigms are introduced: (i) UAV-empowered RIS-enabled BackCom and (ii) UAV-assisted RIS-enabled BackCom. These use cases are analyzed through a structured framework based on Concepts of Operation (ConOps), mission-level attributes, and Key Performance Indicators (KPIs), offering a comprehensive assessment of their performance, scalability, and deployment feasibility. In addition, a theoretical throughput-oriented performance analysis is developed, deriving closed-form rate (R) and signal-to-noise ratio (SNR) scaling laws as a function of the number of RIS elements and UAV transmit power. The analytical results highlight the quadratic SNR scaling behavior under ideal conditions and clarify the fundamental trade-offs between RIS aperture size and power beacon requirements. The findings demonstrate that UAV–RIS–BackCom architectures can achieve scalable, low-power, and rapidly deployable connectivity in infrastructure-limited environments, while also revealing practical limitations related to hardware impairments, control overhead, and channel dynamics. This work provides a unified conceptual and analytical framework to guide the design of sustainable, adaptive, and high-efficiency wireless systems toward practical 6G implementations.
Zappia et al. (Thu,) studied this question.