David B. Haab scite author profile

Recent works have demonstrated Filter Bank Multicarrier Spread Spectrum (FBMC-SS) to be a robust communication scheme in the presence of high-power interferers. Existing FBMC-SS symbol detector designs based on analysis filter banks (AFB) suggest using an optimal combining scheme to suppress the interferers, necessitating some noise/interference power estimation method. In this paper, we introduce a symbol detector with blind interference suppression by extending a recently developed packet detection method. We then provide an analysis to show that the existing AFB-based symbol detector and the one proposed in this paper are equivalent in typical usage scenarios. A fully-fledged receiver design is proposed utilizing this symbol detector, with specifics presented for estimation of the channel impulse response and carrier frequency offset (CFO). We also outline a method of iterating upon the channel and CFO estimations to improve the quality of both parameters. Moreover, a modification to allow improved performance of the symbol detector at high SNR is provided. Finally, simulated performance results are presented to corroborate these findings and demonstrate the efficiency of this receiver design.

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Examining the Performance of Walsh-DSSS Against FBMC-SS in HF Channels

Hunt

Haab

Sego

et al. 2021

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Examining the Performance of MIL-STD-188-110D Waveform 0 Against FBMC-SS Over Skywave HF Channels

Hunt

Haab

Sego

et al. 2022

IEEE Trans. Veh. Technol.

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Multicode Signaling in a Filter Bank Multicarrier Spread Spectrum System and Its Application to HF Communications

Haab

Sego

Holschuh

et al. 2023

IEEE Open J. Commun. Soc.

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The use of filter banks for implementing multicarrier spread spectrum systems leads to a class of effective waveforms that are highly resilient to partial-band interferers. Such waveforms can be also designed to keep the peak-to-average power ratio (PAPR) of the resulting signal at a minimum level. The use of multiple spreading gain vectors (known as multicodes), on the other hand, is an effective method for increasing the data rate in spread spectrum systems, in general. This paper presents a detailed analysis of a class of filter bank multicarrier spread spectrum (FBMC-SS) waveforms and demonstrates an effective receiver implementation of them when multicodes are applied. Application of the developed multicode waveform for communications over high-frequency (HF) skywave channels is also explored, and the benefits that it provides are studied both numerically, through computer simulations, and experimentally, by examining the receivers performance over a variety of skywave links.

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David B. Haab

Filter Bank Multi-Carrier Spread Spectrum with Biorthogonal Signaling for High Speed Data Transmission Through HF Skywave Channels

Spread Spectrum Symbol Detection With Blind Interference Suppression in FBMC-SS

Examining the Performance of Walsh-DSSS Against FBMC-SS in HF Channels

Examining the Performance of MIL-STD-188-110D Waveform 0 Against FBMC-SS Over Skywave HF Channels

Multicode Signaling in a Filter Bank Multicarrier Spread Spectrum System and Its Application to HF Communications

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