Precoded Zak-OTFS for Per-Carrier Equalization

TL;DR

This paper introduces a novel precoding technique for Zak-OTFS modulation that enables per-carrier equalization, reduces complexity, and enhances spectral efficiency by minimizing guard carriers.

Contribution

It develops a new precoding method for doubly spread channels in Zak-OTFS, allowing separate carrier equalization and reducing guard carrier overhead.

Findings

Enables separate equalization of each DD carrier.

Reduces complexity compared to joint equalization.

Improves spectral efficiency by minimizing guard carriers.

Abstract

In Zak-OTFS (orthogonal time frequency space) modulation the carrier waveform is a pulse in the delay-Doppler (DD) domain, formally a quasi-periodic localized function with specific periods along delay and Doppler. When the channel delay spread is less than the delay period, and the channel Doppler spread is less than the Doppler period, the response to a single Zak-OTFS carrier provides an image of the scattering environment and can be used to predict the effective channel at all other carriers. The image of the scattering environment changes slowly, making it possible to employ precoding at the transmitter. Precoding techniques were developed more than thirty years ago for wireline modem channels (V.34 standard) defined by linear convolution where a pulse in the time domain (TD) is used to probe the one-dimensional partial response channel. The action of a doubly spread channel on Zak-OTFS modulation determines a two-dimensional partial response channel defined by twisted convolution, and we develop a novel precoding technique for this channel. The proposed precoder leads to separate equalization of each DD carrier which has significantly lower complexity than joint equalization of all carriers. Further, the effective precoded channel results in non-interfering DD carriers which significantly reduces the overhead of guard carriers separating data and pilot carriers, which improves the spectral efficiency significantly.