The Estimation Method of Sensing Parameters Based on OTFS

In an integrated sensing and communication (ISAC) system, improving the accuracy of delay and Doppler shift sensing parameter estimation is a critical task that sustains the performance of the communication system. To tackle this task, we introduce a two-stage estimation algorithm named matched filt...

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Veröffentlicht in:	IEEE access 2023-01, Vol.11, p.1-1
Hauptverfasser:	Tang, Zhiling, Jiang, Zhou, Pan, Wanghua, Zeng, Lizhen
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Sprache:	eng
Schlagworte:	Accuracy Algorithms Approximation Communications systems Computer simulation Delay delay-Doppler (DD) domain super-resolution estimation Delays Domains Doppler effect Fibonacci numbers Hardware Integers integrated sensing and communication (ISAC) low complexity Matched filters Parameter estimation Radar Receivers Robustness (mathematics) Search methods Search process Sensors Sequences signal modulation Symbols Time-frequency analysis Transmitters Waveforms
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description	In an integrated sensing and communication (ISAC) system, improving the accuracy of delay and Doppler shift sensing parameter estimation is a critical task that sustains the performance of the communication system. To tackle this task, we introduce a two-stage estimation algorithm named matched filter-Fibonacci (MF-F), which employs the orthogonal time frequency space (OTFS) waveform characteristics in the delay-Doppler (DD) domain. In the first step (MF), the sensing parameters are approximated on an integer grid using the relationship between the input and output signals of the DD domain ISAC model. This approximation is executed on an integer grid using the cyclic shift property of the matrix. In the following step (F), we implement a two-dimensional (2D) searching technique based on the Fibonacci sequence, called the Fibonacci search method, to achieve sensing parameter estimation with fractional accuracy. This method decreases the number of comparisons needed and enhances the search process speed. Finally, the proposed method in this study was tested using numerical simulations and hardware experiments. The results demonstrate that the MF-F method can precisely estimate the speed and distance with millimeter-level accuracy and has robustness and low complexity in numerical simulation. Moreover, the estimated Doppler and delay parameters in the hardware experiment can respectively reach the centimeter and meter level.
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The results demonstrate that the MF-F method can precisely estimate the speed and distance with millimeter-level accuracy and has robustness and low complexity in numerical simulation. 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subjects	Accuracy Algorithms Approximation Communications systems Computer simulation Delay delay-Doppler (DD) domain super-resolution estimation Delays Domains Doppler effect Fibonacci numbers Hardware Integers integrated sensing and communication (ISAC) low complexity Matched filters Parameter estimation Radar Receivers Robustness (mathematics) Search methods Search process Sensors Sequences signal modulation Symbols Time-frequency analysis Transmitters Waveforms
title	The Estimation Method of Sensing Parameters Based on OTFS
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