Time Delay Estimation from Low Rate Samples: A Union of Subspaces Approach

TL;DR

This paper introduces a unified low-rate sampling approach for accurate time delay estimation in multipath channels, achieving perfect recovery even with overlapping pulses and minimal sampling rates.

Contribution

It develops a novel method combining union of subspaces sampling theory with ESPRIT for precise delay estimation from low-rate samples, independent of signal bandwidth.

Findings

Perfect delay recovery at minimal sampling rates

Method works with overlapping pulses

Sampling rate depends only on multipath components

Abstract

Time delay estimation arises in many applications in which a multipath medium has to be identified from pulses transmitted through the channel. Various approaches have been proposed in the literature to identify time delays introduced by multipath environments. However, these methods either operate on the analog received signal, or require high sampling rates in order to achieve reasonable time resolution. In this paper, our goal is to develop a unified approach to time delay estimation from low rate samples of the output of a multipath channel. Our methods result in perfect recovery of the multipath delays from samples of the channel output at the lowest possible rate, even in the presence of overlapping transmitted pulses. This rate depends only on the number of multipath components and the transmission rate, but not on the bandwidth of the probing signal. In addition, our development allows for a variety of different sampling methods. By properly manipulating the low-rate samples, we show that the time delays can be recovered using the well-known ESPRIT algorithm. Combining results from sampling theory with those obtained in the context of direction of arrival estimation methods, we develop necessary and sufficient conditions on the transmitted pulse and the sampling functions in order to ensure perfect recovery of the channel parameters at the minimal possible rate. Our results can be viewed in a broader context, as a sampling theorem for analog signals defined over an infinite union of subspaces.