Over-the-Air Transmission of Zak-OTFS on mmWave Communications Testbed

TL;DR

This paper demonstrates the first over-the-air implementation of Zak-OTFS modulation at mmWave frequencies, validating its robustness and potential for future high-mobility wireless systems through experimental results.

Contribution

It provides an OTA system design for Zak-OTFS at mmWave, including signal modeling with impairments and experimental validation on a testbed, advancing practical high-mobility communication solutions.

Findings

Zak-OTFS is feasible at mmWave frequencies.

The system maintains robustness under realistic impairments.

Experimental results confirm potential for beyond-5G systems.

Abstract

Millimeter-wave (mmWave) communication offers vast bandwidth for next-generation wireless systems but faces severe path loss, Doppler effects, and hardware impairments. Orthogonal Time Frequency Space (OTFS) modulation has emerged as a robust waveform for high-mobility and doubly dispersive channels, outperforming OFDM under strong Doppler. However, the most studied multicarrier OTFS (MC-OTFS) is not easily predictable because the input-output (I$/$O) relation is not given by (twisted) convolution. Recently, the Zak-transform based OTFS (Zak-OTFS or OTFS 2$.$0) was proposed, which provides a single domain delay Doppler (DD) processing framework with predictable I$/$O behavior. This paper presents one of the first over-the-air (OTA) demonstrations of Zak-OTFS at mmWave frequencies. We design a complete Zak-OTFS based mmWave OTA system featuring root-raised-cosine (RRC) filtering for enhanced DD-domain predictability, higher-order modulations up to 16-QAM, and a low-overhead preamble for synchronization. A comprehensive signal model incorporating carrier frequency offset (CFO) and timing impairments is developed, showing these effects can be jointly captured within the effective DD-domain channel. Experimental validation on the COSMOS testbed confirms the feasibility and robustness of Zak-OTFS under realistic mmWave conditions, highlighting its potential for efficient implementations in beyond-5G and 6G systems.