Li Zhang, Zixiang Ren, Yuan Fang, Ling Qiu, and Jie Xu. (2024). Sensing-assisted Near-field Energy Beam Focusing with ELAA Over Non-stationary Channels. arXiv preprint arXiv:2410.12579.
This paper investigates a novel approach to achieve efficient energy beam focusing in near-field wireless power transfer (WPT) systems with extremely large-scale antenna arrays (ELAA) over non-stationary channels, addressing the challenges of high pilot overhead in traditional channel estimation methods and the limitations of active signal feedback from energy receivers (ERs).
The authors propose a two-stage transmission protocol. In the first stage, the access point (AP) utilizes wireless radar sensing to identify the visibility regions (VRs) and estimate the three-dimensional (3D) positions of multiple ERs, constructing the corresponding channel state information (CSI). The second stage involves the AP performing energy beam focusing based on the constructed CSI to efficiently charge the ERs. The sensing duration in the first stage is minimized while ensuring a specific accuracy threshold for position estimation. The energy beamformers at the AP are optimized in the second stage to maximize the weighted harvested energy among all ERs, subject to a maximum transmit power constraint.
The proposed sensing-assisted energy beam focusing design demonstrates significant performance improvements compared to benchmark schemes. It achieves near-optimal performance close to the upper bound with perfect VR and CSI knowledge. The design effectively addresses the challenges of channel estimation in near-field ELAA WPT systems with non-stationary channels by leveraging radar sensing and optimizing time allocation between sensing and energy transmission.
The research highlights the potential of integrating sensing capabilities into WPT systems to overcome the limitations of traditional channel estimation methods. The proposed two-stage protocol and optimization framework provide a practical and efficient solution for achieving accurate energy beam focusing in challenging near-field environments with ELAA. The results advocate for further exploration of sensing-assisted techniques in future near-field integrated sensing, communication, and powering (ISCAP) networks.
This work contributes significantly to the field of WPT by introducing a novel sensing-assisted approach for efficient energy beam focusing in near-field ELAA systems. It addresses the practical challenges of channel estimation in non-stationary environments and paves the way for developing high-performance and scalable WPT solutions for future wireless networks.
The study assumes a contiguous sub-array representation of the VR, which might not always hold in practical scenarios. Future research could explore methods for identifying non-contiguous VRs. Additionally, investigating the impact of different radar sensing waveforms and localization algorithms on the overall system performance could be beneficial.
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