Joint Pilot and Unknown Data-based Localization for OFDM Opportunistic Radar Systems

TL;DR

This paper introduces a novel method for localization in OFDM radar systems that utilizes both pilot signals and unknown data payloads without decoding, enhancing accuracy in passive radar scenarios.

Contribution

The proposed approach extracts positioning information directly from data payloads in OFDM signals, improving localization performance without requiring data decoding.

Findings

Superior localization accuracy demonstrated through numerical simulations

Efficient implementation using Fast Fourier Transforms

Effective in opportunistic passive radar scenarios

Abstract

Integrating Sensing and Communications (ISAC) has emerged as a promising paradigm for Sixth Generation (6G) and Wi-Fi 7 networks, with the communication-centric approach being particularly attractive due to its compatibility with current standards. Typical communication signals comprise both deterministic known pilot signals and random unknown data payloads. Most existing approaches either rely solely on pilots for positioning, thereby ignoring the radar information present in the received data symbols that constitute the majority of each frame, or rely on data decisions, which bounds positioning performance to that of the communication system. To overcome these limitations, we propose a novel method that extracts positioning information from data payloads without decoding them. We consider an opportunistic scenario in which communication signals from a user are captured by a passive radar equipped with a uniform linear array of antennas. We show that, in this setting, the estimation can be efficiently implemented using Fast Fourier Transforms. Finally, we demonstrate superior localization performance compared to existing methods in the literature through numerical simulations.