An adaptive filter-based method for robust, automatic detection and frequency estimation of whistles
An adaptive filter-based method for robust, automatic detection and frequency estimation of whistles
This paper proposes an adaptive filter-based method for detection and frequency estimation of whistle calls, such as the calls of birds and marine mammals, which are typically analyzed in the time-frequency domain using a spectrogram. The approach taken here is based on adaptive notch filtering, which is an established technique for frequency tracking. For application to automatic whistle processing, methods for detection and improved frequency tracking through frequency crossings as well as interfering transients are developed and coupled to the frequency tracker. Background noise estimation and compensation is accomplished using order statistics and pre-whitening. Using simulated signals as well as recorded calls of marine mammals and a human whistled speech utterance, it is shown that the proposed method can detect more simultaneous whistles than two competing spectrogram-based methods while not reporting any false alarms on the example datasets. In one example, it extracts complete 1.4 and 1.8 s bottlenose dolphin whistles successfully through frequency crossings. The method performs detection and estimates frequency tracks even at high sweep rates. The algorithm is also shown to be effective on human whistled utterances
acoustic noise, acoustic signal detection, acoustic signal processing, adaptive filters, frequency estimation, notch filters, spectral analysis, speech
893-903
Johansson, A. Torbjorn
f8e5c635-deae-4af4-aa4b-deeb300e6ba5
White, Paul R.
2dd2477b-5aa9-42e2-9d19-0806d994eaba
August 2011
Johansson, A. Torbjorn
f8e5c635-deae-4af4-aa4b-deeb300e6ba5
White, Paul R.
2dd2477b-5aa9-42e2-9d19-0806d994eaba
Johansson, A. Torbjorn and White, Paul R.
(2011)
An adaptive filter-based method for robust, automatic detection and frequency estimation of whistles.
Journal of the Acoustical Society of America, 130 (2), .
(doi:10.1121/1.3609117).
Abstract
This paper proposes an adaptive filter-based method for detection and frequency estimation of whistle calls, such as the calls of birds and marine mammals, which are typically analyzed in the time-frequency domain using a spectrogram. The approach taken here is based on adaptive notch filtering, which is an established technique for frequency tracking. For application to automatic whistle processing, methods for detection and improved frequency tracking through frequency crossings as well as interfering transients are developed and coupled to the frequency tracker. Background noise estimation and compensation is accomplished using order statistics and pre-whitening. Using simulated signals as well as recorded calls of marine mammals and a human whistled speech utterance, it is shown that the proposed method can detect more simultaneous whistles than two competing spectrogram-based methods while not reporting any false alarms on the example datasets. In one example, it extracts complete 1.4 and 1.8 s bottlenose dolphin whistles successfully through frequency crossings. The method performs detection and estimates frequency tracks even at high sweep rates. The algorithm is also shown to be effective on human whistled utterances
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Published date: August 2011
Keywords:
acoustic noise, acoustic signal detection, acoustic signal processing, adaptive filters, frequency estimation, notch filters, spectral analysis, speech
Organisations:
Signal Processing & Control Grp
Identifiers
Local EPrints ID: 194919
URI: http://eprints.soton.ac.uk/id/eprint/194919
ISSN: 0001-4966
PURE UUID: 69832edd-a9c9-4e3a-8b9e-bf36a66b94c4
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Date deposited: 12 Aug 2011 13:54
Last modified: 11 Jul 2024 01:33
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Author:
A. Torbjorn Johansson
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