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Main Authors: Chen, Shao Nan, Chen, Zhan Ye, Wang, Si Ran, Rui, Bi, Kang, Jin Feng, Wang, Zheng Xing, Qi, Zhen Jie, Wu, Lijie, Li, Hui Dong, Dai, Jun Yan, Cheng, Qiang, Cui, Tie Jun
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2601.07213
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author Chen, Shao Nan
Chen, Zhan Ye
Wang, Si Ran
Rui, Bi
Kang, Jin Feng
Wang, Zheng Xing
Qi, Zhen Jie
Wu, Lijie
Li, Hui Dong
Dai, Jun Yan
Cheng, Qiang
Cui, Tie Jun
author_facet Chen, Shao Nan
Chen, Zhan Ye
Wang, Si Ran
Rui, Bi
Kang, Jin Feng
Wang, Zheng Xing
Qi, Zhen Jie
Wu, Lijie
Li, Hui Dong
Dai, Jun Yan
Cheng, Qiang
Cui, Tie Jun
contents Information metasurfaces have emerged as pivotal components in next-generation electronic systems, with significant progress in their applications to communication, radar, and sensing. However, the current researches are mainly focused on their physical structures and system functions, while radio-frequency (RF) signal processing and calculation remain constrained to digital-domain operations. This reliance on digital conversion inherently increases hardware complexity and power consumption. To address this challenge, we propose a programmable RF calculation system based on a space-time-coding metasurface (STCM), which can control the wave-matter interactions through space-time-coding (STC) strategies and achieve direct RF calculations in the electromagnetic (EM) space in a reprogrammable way. Particularly, the fundamental signal operations - Fourier transform and convolution - are implemented in the EM-wave domain successfully. We validate the RF calculation capabilities in radar scenarios, facilitating the accurate detection of target velocity and range. Theoretical analysis, numerical simulations, and experimental results collectively demonstrate that the STCM-based RF calculation system exhibits superior precision, enhanced operational efficiency, and notable cost-effectiveness, highlighting its significant potentials for the next-generation electronic system deployments.
format Preprint
id arxiv_https___arxiv_org_abs_2601_07213
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Programmable radio-frequency calculations in electromagnetic-wave domain
Chen, Shao Nan
Chen, Zhan Ye
Wang, Si Ran
Rui, Bi
Kang, Jin Feng
Wang, Zheng Xing
Qi, Zhen Jie
Wu, Lijie
Li, Hui Dong
Dai, Jun Yan
Cheng, Qiang
Cui, Tie Jun
Optics
Information metasurfaces have emerged as pivotal components in next-generation electronic systems, with significant progress in their applications to communication, radar, and sensing. However, the current researches are mainly focused on their physical structures and system functions, while radio-frequency (RF) signal processing and calculation remain constrained to digital-domain operations. This reliance on digital conversion inherently increases hardware complexity and power consumption. To address this challenge, we propose a programmable RF calculation system based on a space-time-coding metasurface (STCM), which can control the wave-matter interactions through space-time-coding (STC) strategies and achieve direct RF calculations in the electromagnetic (EM) space in a reprogrammable way. Particularly, the fundamental signal operations - Fourier transform and convolution - are implemented in the EM-wave domain successfully. We validate the RF calculation capabilities in radar scenarios, facilitating the accurate detection of target velocity and range. Theoretical analysis, numerical simulations, and experimental results collectively demonstrate that the STCM-based RF calculation system exhibits superior precision, enhanced operational efficiency, and notable cost-effectiveness, highlighting its significant potentials for the next-generation electronic system deployments.
title Programmable radio-frequency calculations in electromagnetic-wave domain
topic Optics
url https://arxiv.org/abs/2601.07213