Breaking the Interference and Fading Gridlock in Backscatter Communications: State-of-the-Art, Design Challenges, and Future Directions
With the rapid advancement of the Internet of Things (IoT) and mobile communication technologies, a multitude of devices are becoming interconnected, marking the onset of an era where all things are connected. While this growth opens opportunities for novel products and applications, it also leads to increased energy demand and battery reliance in IoT devices, creating a significant bottleneck that hinders sustainable progress. Traditional energy harvesting (EH) techniques, although promising, face limitations such as insufficient efficiency, high costs, and practical constraints that impede widespread adoption. Backscatter communication (BackCom), a low-power and passive method, emerges as a promising solution to these challenges, directly addressing stranded energy impasse by reducing manufacturing costs and energy consumption in IoT devices. We perform an in-depth analysis of three primary BackCom architectures: Monostatic, Bistatic, and Ambient BackComs. In our exploration, we identify fundamental challenges, such as complex interference environments (including the direct-link interference and the mutual interference among tags) and double-path fading, which contribute to suboptimal performance in BackCom systems. This review aims to furnish a comprehensive examination of existing solutions designed to combat complex interference environments and double-path fading, offering insightful analysis and comparison to select effective strategies to address these challenges. We also delve into emerging trends and challenges in BackCom, forecasting potential paths for technological advancement and providing insights into navigating the intricate landscape of future communication needs. Our work provides researchers and engineers with a clear and comprehensive perspective, enabling them to better understand and creatively tackle the ongoing challenges in BackCom systems.
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