Achieving Full-Bandwidth Sensing Performance with Partial Bandwidth Allocation for ISAC

TL;DR

This paper introduces a two-stage delay estimation method for uplink ISAC systems that achieves full-bandwidth sensing performance using only partial bandwidth, by combining coarse and fine delay estimation techniques.

Contribution

The novel two-stage delay estimation method enables full-bandwidth sensing performance with partial bandwidth allocation in DFT-s-OFDM based ISAC systems.

Findings

Achieves full-bandwidth delay resolution with at most half of the full bandwidth.

Provides large unambiguous range through coarse delay estimation.

Demonstrates superiority over conventional collocated subcarrier methods.

Abstract

This letter studies an uplink integrated sensing and communication (ISAC) system using discrete Fourier transform spread orthogonal frequency division multiplexing (DFT-s-OFDM) transmission. We try to answer the following fundamental question: With only a fractional bandwidth allocated to the user with sensing task, can the same delay resolution and unambiguous range be achieved as if all bandwidth were allocated to it? We affirmatively answer the question by proposing a novel two-stage delay estimation (TSDE) method that exploits the following facts: without increasing the allocated bandwidth, higher delay resolution can be achieved via distributed subcarrier allocation compared to its collocated counterpart, while there is a trade-off between delay resolution and unambiguous range by varying the decimation factor of subcarriers. Therefore, the key idea of the proposed TSDE method is to first perform coarse delay estimation with collocated subcarriers to achieve a large unambiguous range, and then use distributed subcarriers with optimized decimation factor to enhance delay resolution while avoiding delay ambiguity. Our analysis shows that the proposed TSDE method can achieve the full-bandwidth delay resolution and unambiguous range, by using only at most half of the full bandwidth, provided that the channel delay spread is less than half of the unambiguous range. Numerical results show the superiority of the proposed method over the conventional method with collocated subcarriers.