A Survey of OTFS-Based Index Modulation Techniques: Challenges, Benefits, and Future Directions for 6G and Beyond

TL;DR

This survey reviews OTFS-based index modulation techniques for 6G, highlighting their system architectures, performance benefits, challenges, and future research directions in wireless communications.

Contribution

It provides a comprehensive categorization and performance analysis of OTFS-IM schemes, including various variants and their potential for future wireless systems.

Findings

OTFS-IM enhances spectral efficiency and error performance.

Different OTFS-IM variants offer trade-offs in complexity and energy efficiency.

Challenges include channel estimation and hardware constraints.

Abstract

Orthogonal time frequency space (OTFS) is a two-dimensional modulation technique that uses the delay-Doppler (DD) domain and is a candidate for providing robust, high-capacity wireless communications for envisioned 6G and beyond networks. The OTFS technique maps data to the DD domain instead of the traditional time-frequency domain, enabling it to fully utilize channel diversity and transform fast time-varying channels into nearly static channels. Index modulation (IM) is a communication paradigm that conveys information not only through conventional modulation symbols but also by encoding data bits in the indices of the selected communication resources to improve error performance, spectral efficiency, and energy efficiency. In this survey, a comprehensive review of work on OTFS-based wireless communication systems is presented. In particular, the existing OTFS-IM schemes are reviewed and systematically categorized according to their system architectures, detection methods, and performance aspects such as capacity, peak-to-average power ratio, diversity, complexity, imperfect channel state information, spectral efficiency, and outage probability. Furthermore, the operating principles and system models of OTFS-IM variants-including OTFS-based space shift keying, OTFS-based spatial modulation, OTFS-based quadrature spatial modulation, OTFS-based media-based modulation, and OTFS-based code index modulation-are described, followed by a comparative performance analysis in terms of computational complexity, error performance, capacity, energy saving, spectral efficiency, and throughput. Finally, the challenges, benefits, and future directions for OTFS-IM systems are discussed, covering key aspects such as complexity, efficiency, latency, channel estimation, hardware constraints, synchronization, security, and potential integration with other advanced wireless communication techniques.