Towards Standardizing OTFS: A Candidate Waveform for Next-Generation Wireless Networks

TL;DR

This paper explores OTFS as a promising waveform for 6G wireless networks, addressing OFDM's limitations by leveraging delay-Doppler domain properties for improved resilience and efficiency.

Contribution

It investigates the feasibility and practical implementation of OTFS modulation within existing OFDM-based systems for next-generation wireless networks.

Findings

OTFS offers enhanced resilience to Doppler and multipath effects.

OTFS can be integrated into current OFDM systems with practical modifications.

OTFS demonstrates potential for improved spectral efficiency and robustness.

Abstract

The standardization of the sixth-generation (6G) has recently commenced to address the rapidly growing demands for enhanced wireless network services. Nevertheless, existing wireless systems, particularly at the physical layer waveform level, remain inadequate for achieving the ambitious key performance indicators (KPIs) envisioned for 6G. Specifically, orthogonal frequency division multiplexing (OFDM), the widely adopted waveform in fifth-generation new radio (5G-NR) networks, suffers from inherent limitations in satisfying these stringent requirements. In practice, OFDM can experience severe inter-carrier interference (ICI), resulting in a pronounced data rate error floor caused by high Doppler shifts. Additionally, the repetitive usage of cyclic prefixes (CPs), intended to combat multipath delays, results in significant spectral inefficiency. These fundamental drawbacks pose critical obstacles to fulfilling 6G performance objectives. Orthogonal time frequency space (OTFS) modulation has recently emerged as a promising waveform candidate, addressing the aforementioned challenges by exploiting the unique characteristics of the delay-Doppler (DD) domain channel. Unlike OFDM, OTFS is inherently resilient to channel distortions induced by delay and Doppler effects, while remaining sensitive to time and frequency shifts. Such intrinsic properties are instrumental in enabling OTFS, with joint communication and sensing capabilities, to embrace, rather than combat, dynamic channel conditions. Motivated by these compelling advantages, this article investigates the feasibility and practical implementation of OTFS modulation leveraging the current OFDM-based wireless systems.