OTFS-IM-Assisted Non-Terrestrial Networks Relying on Autoencoder-Aided Soft-Decision Detection

Abstract

Orthogonal Time Frequency Space (OTFS) modulation offers significant advantages over Orthogonal Frequency Division Multiplexing (OFDM), particularly in high speed environments. Hence, we consider OTFS transmission over high-Doppler Non-Terrestrial Networks (NTN). However, OTFS-based systems inherit some deficiencies from OFDM, such as its high peak to average power ratio, the bandwidth efficiency loss due to the cyclic prefix, and the sensitivity to the carrier frequency offset. Against this background, we harness both Multi-Band Discrete Fourier Transform-based Spreading (MB-DFT-S) and Index Modulation (IM) in our OTFS system, termed as MB-DFT-S-OTFS-IM. More explicitly, 1) DFT-S has been shown to reduce the PAPR; 2) IM is capable of improving the throughput by harnessing it in the Delay and Doppler (DD) domain; and 3) MB-DFT-S-OTFS-IM provides frequency diversity gain, which benefits the tolerance to carrier frequency offset. Furthermore, we propose a PAPR reduction method based on a Deep Learning (DL) Autoencoder (AE) architecture for both hard- and soft-decision detection, where the encoder is specifically trained for minimizing PAPR and the decoder is conceived for accurately reconstructing the transmitted signal. Finally, we extend the proposed AE-aided OTFS-IM scheme constructed for a practical NTN channel model, representing a variety of satellite-to-ground schemes.