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Autores principales: Zhao, Yufei, Lin, Deyu, Zhang, Qian, Shi, Haoyang, Niu, Hong, Ismail, Afkar Mohamed, Guan, Yong Liang, Yuen, Chau
Formato: Preprint
Publicado: 2025
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Acceso en línea:https://arxiv.org/abs/2512.19702
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author Zhao, Yufei
Lin, Deyu
Zhang, Qian
Shi, Haoyang
Niu, Hong
Ismail, Afkar Mohamed
Guan, Yong Liang
Yuen, Chau
author_facet Zhao, Yufei
Lin, Deyu
Zhang, Qian
Shi, Haoyang
Niu, Hong
Ismail, Afkar Mohamed
Guan, Yong Liang
Yuen, Chau
contents In this paper, we propose a novel secure wireless transmission architecture that enables the co-existence of spatial field modulation (SFM) and digital bandpass modulation (DBM), utilizing multi-mode vortex waves and programmable meta-surfaces (PMS). Distinct from conventional joint modulation schemes, our approach establishes two logically independent transmission channels--SFM and DBM--thereby eliminating the need for joint signal design or time synchronization. Specifically, the orthogonality of vortex wave modes is exploited to construct a high-capacity multi-mode DBM channel, in which each mode carries modulated symbols independently. As the composite waveform passes through the PMS, energy from different vortex modes is spatially focused onto distinct positions, dynamically determined by the PMS configuration. This spatial mapping forms a unique lookup table that encodes additional information in the electro-magnetic (EM) field distribution, effectively enabling a second, concurrent SFM channel. To enhance physical-layer security, the DBM channel transmits encrypted symbols transformed via dynamic symbol-domain mapping, while the corresponding mapping relations--or key information--are carried by the SFM channel. This lightweight dual-channel encryption strategy provides strong confidentiality without requiring complex joint decoding. To validate the feasibility of the proposed architecture, we design and implement a proof-of-concept prototype system, and conduct experimental demonstrations under real-world wireless communication conditions. The experimental results confirm the effectiveness of the co-existent DBM-SFM design in achieving reliable and secure transmission. The proposed architecture offers a scalable, low-complexity, and secure transmission solution for future IoT networks, especially in scenarios demanding both spectral efficiency and physical-layer confidentiality.
format Preprint
id arxiv_https___arxiv_org_abs_2512_19702
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Enhanced Information Security via Wave-Field Selectivity and Structured Wavefront Manipulation
Zhao, Yufei
Lin, Deyu
Zhang, Qian
Shi, Haoyang
Niu, Hong
Ismail, Afkar Mohamed
Guan, Yong Liang
Yuen, Chau
Signal Processing
Applied Physics
In this paper, we propose a novel secure wireless transmission architecture that enables the co-existence of spatial field modulation (SFM) and digital bandpass modulation (DBM), utilizing multi-mode vortex waves and programmable meta-surfaces (PMS). Distinct from conventional joint modulation schemes, our approach establishes two logically independent transmission channels--SFM and DBM--thereby eliminating the need for joint signal design or time synchronization. Specifically, the orthogonality of vortex wave modes is exploited to construct a high-capacity multi-mode DBM channel, in which each mode carries modulated symbols independently. As the composite waveform passes through the PMS, energy from different vortex modes is spatially focused onto distinct positions, dynamically determined by the PMS configuration. This spatial mapping forms a unique lookup table that encodes additional information in the electro-magnetic (EM) field distribution, effectively enabling a second, concurrent SFM channel. To enhance physical-layer security, the DBM channel transmits encrypted symbols transformed via dynamic symbol-domain mapping, while the corresponding mapping relations--or key information--are carried by the SFM channel. This lightweight dual-channel encryption strategy provides strong confidentiality without requiring complex joint decoding. To validate the feasibility of the proposed architecture, we design and implement a proof-of-concept prototype system, and conduct experimental demonstrations under real-world wireless communication conditions. The experimental results confirm the effectiveness of the co-existent DBM-SFM design in achieving reliable and secure transmission. The proposed architecture offers a scalable, low-complexity, and secure transmission solution for future IoT networks, especially in scenarios demanding both spectral efficiency and physical-layer confidentiality.
title Enhanced Information Security via Wave-Field Selectivity and Structured Wavefront Manipulation
topic Signal Processing
Applied Physics
url https://arxiv.org/abs/2512.19702