Saved in:
Bibliographic Details
Main Authors: Yang, Han Qing, Dai, Jun Yan, Li, Hui Dong, Wu, Lijie, Zhang, Meng Zhen, Shen, Zi Hang, Wang, Si Ran, Wang, Zheng Xing, Tang, Wankai, Jin, Shi, Wu, Jun Wei, Cheng, Qiang, Cui, Tie Jun
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2411.08538
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866917837128335360
author Yang, Han Qing
Dai, Jun Yan
Li, Hui Dong
Wu, Lijie
Zhang, Meng Zhen
Shen, Zi Hang
Wang, Si Ran
Wang, Zheng Xing
Tang, Wankai
Jin, Shi
Wu, Jun Wei
Cheng, Qiang
Cui, Tie Jun
author_facet Yang, Han Qing
Dai, Jun Yan
Li, Hui Dong
Wu, Lijie
Zhang, Meng Zhen
Shen, Zi Hang
Wang, Si Ran
Wang, Zheng Xing
Tang, Wankai
Jin, Shi
Wu, Jun Wei
Cheng, Qiang
Cui, Tie Jun
contents The programmable metasurface is regarded as one of the most promising transformative technologies for next-generation wireless system applications. Due to the lack of effective perception ability of the external electromagnetic environment, there are numerous challenges in the intelligent regulation of wireless channels, and it still relies on external sensors to reshape electromagnetic environment as desired. To address that problem, we propose an adaptive metasurface (AMS) which integrates the capabilities of acquiring wireless environment information and manipulating reflected electromagnetic (EM) waves in a programmable manner. The proposed design endows the metasurfaces with excellent capabilities to sense the complex electromagnetic field distributions around them and then dynamically manipulate the waves and signals in real time under the guidance of the sensed information, eliminating the need for prior knowledge or external inputs about the wireless environment. For verification, a prototype of the proposed AMS is constructed, and its dual capabilities of sensing and manipulation are experimentally validated. Additionally, different integrated sensing and communication (ISAC) scenarios with and without the aid of the AMS are established. The effectiveness of the AMS in enhancing communication quality is well demonstrated in complex electromagnetic environments, highlighting its beneficial application potential in future wireless systems.
format Preprint
id arxiv_https___arxiv_org_abs_2411_08538
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Intelligent Adaptive Metasurface in Complex Wireless Environments
Yang, Han Qing
Dai, Jun Yan
Li, Hui Dong
Wu, Lijie
Zhang, Meng Zhen
Shen, Zi Hang
Wang, Si Ran
Wang, Zheng Xing
Tang, Wankai
Jin, Shi
Wu, Jun Wei
Cheng, Qiang
Cui, Tie Jun
Applied Physics
Systems and Control
The programmable metasurface is regarded as one of the most promising transformative technologies for next-generation wireless system applications. Due to the lack of effective perception ability of the external electromagnetic environment, there are numerous challenges in the intelligent regulation of wireless channels, and it still relies on external sensors to reshape electromagnetic environment as desired. To address that problem, we propose an adaptive metasurface (AMS) which integrates the capabilities of acquiring wireless environment information and manipulating reflected electromagnetic (EM) waves in a programmable manner. The proposed design endows the metasurfaces with excellent capabilities to sense the complex electromagnetic field distributions around them and then dynamically manipulate the waves and signals in real time under the guidance of the sensed information, eliminating the need for prior knowledge or external inputs about the wireless environment. For verification, a prototype of the proposed AMS is constructed, and its dual capabilities of sensing and manipulation are experimentally validated. Additionally, different integrated sensing and communication (ISAC) scenarios with and without the aid of the AMS are established. The effectiveness of the AMS in enhancing communication quality is well demonstrated in complex electromagnetic environments, highlighting its beneficial application potential in future wireless systems.
title Intelligent Adaptive Metasurface in Complex Wireless Environments
topic Applied Physics
Systems and Control
url https://arxiv.org/abs/2411.08538