Near-Field ISAC for THz Wireless Systems

TL;DR

This paper explores the unique propagation characteristics of THz near-field for 6G ISAC systems, highlighting new opportunities and challenges in leveraging near-field effects for enhanced sensing and communication.

Contribution

It systematically investigates THz near-field propagation features and reviews techniques to exploit these for improved ISAC system performance.

Findings

Analysis of three fundamental THz near-field propagation characteristics

Review of state-of-the-art techniques leveraging near-field features

Proposal of resource allocation for multi-angle sensing and multi-user communication

Abstract

Sixth-generation (6G) wireless networks are expected not only to provide high-speed connectivity but also to support reliable sensing capabilities, giving rise to the integrated sensing and communication (ISAC) paradigm. To enable higher data rates and more accurate sensing, terahertz (THz) systems empowered by extremely large multiple-input-multiple-output (XL-MIMO) technology are envisioned as key enablers for future ISAC systems. Owing to the substantial increase in both effective array aperture and carrier frequency, a considerable portion of future ISAC applications is anticipated to fall within the near-field coverage region, instead of the conventional far-field. However, most existing ISAC techniques are designed under the far-field planar wave assumption, struggling to accommodate the unique characteristics of THz near-field propagation. To motivate future research into near-field ISAC research, we systematically investigate the characteristics of THz near-field propagation and explore its potential to facilitate ISAC systems. Specifically, we analyze three fundamental characteristics of THz near-field propagation and review state-of-the-art techniques that exploit these features to boost both communication and sensing performance. To further harness the angular-range coupling effect, we zoom into a particularly interesting approach to near-field sensing based on wavenumber domain. Besides, to exploit the beam squint effect, an ISAC resource allocation framework is introduced to support integrated multi-angle sensing and multi-user communication. Finally, we outline promising directions for future research in this emerging area.