SAR/ISAR Imaging in 6G Network

TL;DR

This paper introduces two novel 6G radio imaging schemes, BI-SAR and BI-ISAR, that utilize Doppler information for high-resolution imaging with limited bandwidth, demonstrated through real-world experiments.

Contribution

The paper proposes bandwidth-independent imaging schemes for 6G that do not rely on high-resolution range estimation, using Doppler-based techniques and an iterative adaptive algorithm.

Findings

Effective Doppler-based imaging without range information

Feasibility demonstrated through real-world experiments

Resolution analysis characterizes reconstruction quality

Abstract

Imaging is a crucial sensing function that finds wide applications in environmental reconstruction, autonomous driving, etc. However, the signal processing methods for existing radio imaging techniques, such as millimeter wave (mmWave) imaging, require high-resolution range estimation enabled by Gigahertz-level or even Terahertz-level bandwidth, and cannot be applied in 6G integrated sensing and communication (ISAC) network with Megahertz-level bandwidth. This paper proposes two novel high-resolution radio imaging schemes that can work on the 6G signals with limited bandwidth - bandwidth-independent synthetic aperture radar (BI-SAR), where the movable base station (BS) revolves along the static targets by 360 degrees; as well as bandwidth-independent inverse synthetic aperture radar (BI-ISAR), where the BS is static and the targets revolve along an axis by 360 degrees. Different from conventional SAR and ISAR counterparts that rely on range estimation, our proposed imaging schemes solely utilize Doppler information to perform imaging without any range information. The main technical challenge of our schemes lies in the anisotropic scattering functions over different directions, which hinder the coherent synthesis of the backscattered signals from all directions. We design an iterative adaptive approach-based Doppler association (IAA-DA) algorithm to tackle the above issue. Moreover, we also derive the imaging resolution to characterize the reconstruction quality. Real-world experiments are provided to show the feasibility and the effectiveness of our proposed 6G imaging schemes.