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Sweep signal time-delay estimation with time–frequency cross-correlation algorithm

Sweep signal time-delay estimation with time–frequency cross-correlation algorithm

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Sweep signal is usually employed as a source signal in active detection such as radar and sonar. Since the frequency spectrum of the sweep signal varies against time, a novel algorithm, namely a time–frequency cross-correlation (TFCC) algorithm based on wavelet packet transform (WPT), is proposed to estimate the time delay of sweep signal. In this algorithm, the source sweep and the received signals are decomposed with WPT to obtain their time–frequency representations and the TFCC between the source sweep and the received signals is performed. Each reflected sweep in the received signal is converted into a time–frequency correlation peak whose position can indicate its time delay. The TFCC algorithm can suppress ambient noise effectively and improve the performance of sweep extraction and can match more precisely the source and the reflected sweeps to their known time–frequency characters. Numerical experiments were performed to compare the performance of the TFCC algorithm with that of the conventional cross-correlation and phase-data algorithms. The results proved that the TFCC algorithm can extract the reflected sweeps effectively and its performance is better than that of the conventional algorithms.

Inspec keywords: delays; signal detection; correlation methods; wavelet transforms; time-frequency analysis

Other keywords: time-frequency cross-correlation algorithm; sweep signal time-delay estimation; WPT; wavelet packet transform

Subjects: Integral transforms; Signal detection; Mathematical analysis; Mathematical analysis; Integral transforms; Signal processing theory

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