Improved Capon Beamformer Using Fourier Integral Method (FIM)

Xionghou Liu; Cong Wang; Chao Sun; Yixin Yang; Jie Zhuo; Guoqing Jiang; Wenjun Duan

doi:10.1109/IEEECONF38699.2020.9389395

Improved Capon Beamformer Using Fourier Integral Method (FIM)

Xionghou Liu, Cong Wang, Chao Sun, Yixin Yang, Jie Zhuo, Guoqing Jiang, Wenjun Duan

School of Marine Science and Technology

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

5 Scopus citations

Abstract

When compared to the conventional beamformer (CBF), the Capon beamformer often shows a better target detection performance. However, when the array aperture (or, the degrees of freedoms-DOFs) is limited and the signal-to-noise ratio (SNR) is relatively low, the performance of the Capon beamformer will degrade severely. Unfortunately, for the practical application the target of interest is often submerged in loud interferences and high-level fluctuated noises. Thus, it is very hard for a small-aperture array to find the target of interest. In this paper, to improve the beamforming performance of the small-aperture linear array, we propose an improved Capon beamformer based on Fourier integral method (FIM), which is termed as FIM-Capon for short. FIM-Capon firstly uses the basic theory of FIM to obtain 2N-1 outputs (the number of hydrophones in the array is N), which is actually the Toeplitz averaged covariance matrix calculated from the sampled array covariance matrix. And then, FIM-Capon uses the subarray smoothing and the Capon beamformer to process the 2N-1 outputs of the Toeplitz averaged covariance matrix to produce the final beamforming output. The proposed FIM-Capon method have two advantages; one is making use of the noise suppression ability of FIM, and the other is using the extended DOFs coming from the Toeplitz averaging. Hence, FIM-Capon has a higher input SNR and a larger DOF than the traditional Capon beamformer. As a result, when the aperture is limited and the input SNR is low, FIM-Capon shows a better weak target detection performance than the traditional Capon beamformer. Numerical simulations validate the effectiveness of the proposed FIM-Capon method.

Original language	English
Title of host publication	2020 Global Oceans 2020
Subtitle of host publication	Singapore - U.S. Gulf Coast
Publisher	Institute of Electrical and Electronics Engineers Inc.
ISBN (Electronic)	9781728154466
DOIs	https://doi.org/10.1109/IEEECONF38699.2020.9389395
State	Published - 5 Oct 2020
Event	2020 Global Oceans: Singapore - U.S. Gulf Coast, OCEANS 2020 - Biloxi, United States Duration: 5 Oct 2020 → 30 Oct 2020

Publication series

Name	2020 Global Oceans 2020: Singapore - U.S. Gulf Coast

Conference

Conference	2020 Global Oceans: Singapore - U.S. Gulf Coast, OCEANS 2020
Country/Territory	United States
City	Biloxi
Period	5/10/20 → 30/10/20

Keywords

Adaptive beamformer
Capon beamformer
Fourier integral method (FIM)
low signal-to-noise (SNR) ratio
underwater acoustics
underwater clutters suppression
underwater weak target detection

Access to Document

10.1109/IEEECONF38699.2020.9389395

Cite this

Liu, X., Wang, C., Sun, C., Yang, Y., Zhuo, J., Jiang, G., & Duan, W. (2020). Improved Capon Beamformer Using Fourier Integral Method (FIM). In 2020 Global Oceans 2020: Singapore - U.S. Gulf Coast Article 9389395 (2020 Global Oceans 2020: Singapore - U.S. Gulf Coast). Institute of Electrical and Electronics Engineers Inc.. https://doi.org/10.1109/IEEECONF38699.2020.9389395

@inproceedings{821d277f0cf644b590ee65331ccaa23e,

title = "Improved Capon Beamformer Using Fourier Integral Method (FIM)",

abstract = "When compared to the conventional beamformer (CBF), the Capon beamformer often shows a better target detection performance. However, when the array aperture (or, the degrees of freedoms-DOFs) is limited and the signal-to-noise ratio (SNR) is relatively low, the performance of the Capon beamformer will degrade severely. Unfortunately, for the practical application the target of interest is often submerged in loud interferences and high-level fluctuated noises. Thus, it is very hard for a small-aperture array to find the target of interest. In this paper, to improve the beamforming performance of the small-aperture linear array, we propose an improved Capon beamformer based on Fourier integral method (FIM), which is termed as FIM-Capon for short. FIM-Capon firstly uses the basic theory of FIM to obtain 2N-1 outputs (the number of hydrophones in the array is N), which is actually the Toeplitz averaged covariance matrix calculated from the sampled array covariance matrix. And then, FIM-Capon uses the subarray smoothing and the Capon beamformer to process the 2N-1 outputs of the Toeplitz averaged covariance matrix to produce the final beamforming output. The proposed FIM-Capon method have two advantages; one is making use of the noise suppression ability of FIM, and the other is using the extended DOFs coming from the Toeplitz averaging. Hence, FIM-Capon has a higher input SNR and a larger DOF than the traditional Capon beamformer. As a result, when the aperture is limited and the input SNR is low, FIM-Capon shows a better weak target detection performance than the traditional Capon beamformer. Numerical simulations validate the effectiveness of the proposed FIM-Capon method.",

keywords = "Adaptive beamformer, Capon beamformer, Fourier integral method (FIM), low signal-to-noise (SNR) ratio, underwater acoustics, underwater clutters suppression, underwater weak target detection",

author = "Xionghou Liu and Cong Wang and Chao Sun and Yixin Yang and Jie Zhuo and Guoqing Jiang and Wenjun Duan",

note = "Publisher Copyright: {\textcopyright} 2020 IEEE.; 2020 Global Oceans: Singapore - U.S. Gulf Coast, OCEANS 2020 ; Conference date: 05-10-2020 Through 30-10-2020",

year = "2020",

month = oct,

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doi = "10.1109/IEEECONF38699.2020.9389395",

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Liu, X, Wang, C, Sun, C , Yang, Y, Zhuo, J, Jiang, G & Duan, W 2020, Improved Capon Beamformer Using Fourier Integral Method (FIM). in 2020 Global Oceans 2020: Singapore - U.S. Gulf Coast., 9389395, 2020 Global Oceans 2020: Singapore - U.S. Gulf Coast, Institute of Electrical and Electronics Engineers Inc., 2020 Global Oceans: Singapore - U.S. Gulf Coast, OCEANS 2020, Biloxi, United States, 5/10/20. https://doi.org/10.1109/IEEECONF38699.2020.9389395

Improved Capon Beamformer Using Fourier Integral Method (FIM). / Liu, Xionghou; Wang, Cong; Sun, Chao et al.
2020 Global Oceans 2020: Singapore - U.S. Gulf Coast. Institute of Electrical and Electronics Engineers Inc., 2020. 9389395 (2020 Global Oceans 2020: Singapore - U.S. Gulf Coast).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

TY - GEN

T1 - Improved Capon Beamformer Using Fourier Integral Method (FIM)

AU - Liu, Xionghou

AU - Wang, Cong

AU - Sun, Chao

AU - Yang, Yixin

AU - Zhuo, Jie

AU - Jiang, Guoqing

AU - Duan, Wenjun

PY - 2020/10/5

Y1 - 2020/10/5

N2 - When compared to the conventional beamformer (CBF), the Capon beamformer often shows a better target detection performance. However, when the array aperture (or, the degrees of freedoms-DOFs) is limited and the signal-to-noise ratio (SNR) is relatively low, the performance of the Capon beamformer will degrade severely. Unfortunately, for the practical application the target of interest is often submerged in loud interferences and high-level fluctuated noises. Thus, it is very hard for a small-aperture array to find the target of interest. In this paper, to improve the beamforming performance of the small-aperture linear array, we propose an improved Capon beamformer based on Fourier integral method (FIM), which is termed as FIM-Capon for short. FIM-Capon firstly uses the basic theory of FIM to obtain 2N-1 outputs (the number of hydrophones in the array is N), which is actually the Toeplitz averaged covariance matrix calculated from the sampled array covariance matrix. And then, FIM-Capon uses the subarray smoothing and the Capon beamformer to process the 2N-1 outputs of the Toeplitz averaged covariance matrix to produce the final beamforming output. The proposed FIM-Capon method have two advantages; one is making use of the noise suppression ability of FIM, and the other is using the extended DOFs coming from the Toeplitz averaging. Hence, FIM-Capon has a higher input SNR and a larger DOF than the traditional Capon beamformer. As a result, when the aperture is limited and the input SNR is low, FIM-Capon shows a better weak target detection performance than the traditional Capon beamformer. Numerical simulations validate the effectiveness of the proposed FIM-Capon method.

AB - When compared to the conventional beamformer (CBF), the Capon beamformer often shows a better target detection performance. However, when the array aperture (or, the degrees of freedoms-DOFs) is limited and the signal-to-noise ratio (SNR) is relatively low, the performance of the Capon beamformer will degrade severely. Unfortunately, for the practical application the target of interest is often submerged in loud interferences and high-level fluctuated noises. Thus, it is very hard for a small-aperture array to find the target of interest. In this paper, to improve the beamforming performance of the small-aperture linear array, we propose an improved Capon beamformer based on Fourier integral method (FIM), which is termed as FIM-Capon for short. FIM-Capon firstly uses the basic theory of FIM to obtain 2N-1 outputs (the number of hydrophones in the array is N), which is actually the Toeplitz averaged covariance matrix calculated from the sampled array covariance matrix. And then, FIM-Capon uses the subarray smoothing and the Capon beamformer to process the 2N-1 outputs of the Toeplitz averaged covariance matrix to produce the final beamforming output. The proposed FIM-Capon method have two advantages; one is making use of the noise suppression ability of FIM, and the other is using the extended DOFs coming from the Toeplitz averaging. Hence, FIM-Capon has a higher input SNR and a larger DOF than the traditional Capon beamformer. As a result, when the aperture is limited and the input SNR is low, FIM-Capon shows a better weak target detection performance than the traditional Capon beamformer. Numerical simulations validate the effectiveness of the proposed FIM-Capon method.

KW - Adaptive beamformer

KW - Capon beamformer

KW - Fourier integral method (FIM)

KW - low signal-to-noise (SNR) ratio

KW - underwater acoustics

KW - underwater clutters suppression

KW - underwater weak target detection

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U2 - 10.1109/IEEECONF38699.2020.9389395

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M3 - 会议稿件

AN - SCOPUS:85104634497

T3 - 2020 Global Oceans 2020: Singapore - U.S. Gulf Coast

BT - 2020 Global Oceans 2020

PB - Institute of Electrical and Electronics Engineers Inc.

T2 - 2020 Global Oceans: Singapore - U.S. Gulf Coast, OCEANS 2020

Y2 - 5 October 2020 through 30 October 2020

ER -

Improved Capon Beamformer Using Fourier Integral Method (FIM)

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Keywords

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