Discrete Wavelet Transformation for the Sensitive Detection of Ultrashort Radiation Pulse With Radiation-Induced Acoustics

Rick J.P. van Bergen; Leshan Sun; Prabodh Kumar Pandey; Siqi Wang; Kristina Bjegovic; Gilberto Gonzalez; Yong Chen; Richard G.P. Lopata; Liangzhong Xiang

doi:10.1109/TRPMS.2023.3314339

Discrete Wavelet Transformation for the Sensitive Detection of Ultrashort Radiation Pulse With Radiation-Induced Acoustics

Rick J.P. van Bergen, Leshan Sun, Prabodh Kumar Pandey, Siqi Wang, Kristina Bjegovic, Gilberto Gonzalez, Yong Chen, Richard G.P. Lopata, Liangzhong Xiang (Corresponding author)

Research output: Contribution to journal › Article › Academic › peer-review

3 Citations (Scopus)

17 Downloads (Pure)

Abstract

Radiation-induced acoustics (RIA) shows promise in advancing radiological imaging and radiotherapy dosimetry methods. However, RIA signals often require extensive averaging to achieve reasonable signal-to-noise ratios, which increases patient radiation exposure and limits real-time applications. Therefore, this article proposes a discrete wavelet transform (DWT)-based filtering approach to denoise the RIA signals and avoid extensive averaging. The algorithm was benchmarked against low-pass filters and tested on various types of RIA sources, including low-energy X-rays, high-energy X-rays, and protons. The proposed method significantly reduced the required averages (1000 times less averaging for low-energy X-ray RIA, 32 times less averaging for high-energy X-ray RIA, and four times less averaging for proton RIA) and demonstrated robustness in filtering signals from different sources of radiation. The coif5 wavelet in conjunction with the sqtwolog threshold selection algorithm yielded the best results. The proposed DWT filtering method enables high-quality, automated, and robust filtering of RIA signals, with a performance similar to low-pass filtering, aiding in the clinical translation of radiation-based acoustic imaging for radiology and radiation oncology.

Original language	English
Article number	10248961
Pages (from-to)	76-87
Number of pages	12
Journal	IEEE Transactions on Radiation and Plasma Medical Sciences
Volume	8
Issue number	1
DOIs	https://doi.org/10.1109/TRPMS.2023.3314339
Publication status	Published - Jan 2024

Funding

This work was supported in part by the National Institute of Health under Grant R37CA240806; in part by the American Cancer Society under Grant 133697-RSG-19-110-01-CCE; and in part by the UCI Chao Family Comprehensive Cancer Center under Grant P30CA062203.

Funders	Funder number
National Institutes of Health	R37CA240806

Keywords

Discrete wavelet filtering
radiation induced acoustics (RIA)
radiation monitoring

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10.1109/TRPMS.2023.3314339

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van Bergen, R. J. P., Sun, L., Kumar Pandey, P., Wang, S., Bjegovic, K., Gonzalez, G., Chen, Y., Lopata, R. G. P., & Xiang, L. (2024). Discrete Wavelet Transformation for the Sensitive Detection of Ultrashort Radiation Pulse With Radiation-Induced Acoustics. IEEE Transactions on Radiation and Plasma Medical Sciences, 8(1), 76-87. Article 10248961. https://doi.org/10.1109/TRPMS.2023.3314339

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title = "Discrete Wavelet Transformation for the Sensitive Detection of Ultrashort Radiation Pulse With Radiation-Induced Acoustics",

abstract = "Radiation-induced acoustics (RIA) shows promise in advancing radiological imaging and radiotherapy dosimetry methods. However, RIA signals often require extensive averaging to achieve reasonable signal-to-noise ratios, which increases patient radiation exposure and limits real-time applications. Therefore, this article proposes a discrete wavelet transform (DWT)-based filtering approach to denoise the RIA signals and avoid extensive averaging. The algorithm was benchmarked against low-pass filters and tested on various types of RIA sources, including low-energy X-rays, high-energy X-rays, and protons. The proposed method significantly reduced the required averages (1000 times less averaging for low-energy X-ray RIA, 32 times less averaging for high-energy X-ray RIA, and four times less averaging for proton RIA) and demonstrated robustness in filtering signals from different sources of radiation. The coif5 wavelet in conjunction with the sqtwolog threshold selection algorithm yielded the best results. The proposed DWT filtering method enables high-quality, automated, and robust filtering of RIA signals, with a performance similar to low-pass filtering, aiding in the clinical translation of radiation-based acoustic imaging for radiology and radiation oncology.",

keywords = "Ultrasound, Radiation, Dosimetry, Signal Processing, Wavelet Transform, Discrete wavelet filtering, radiation induced acoustics (RIA), radiation monitoring",

author = "{van Bergen}, {Rick J.P.} and Leshan Sun and {Kumar Pandey}, Prabodh and Siqi Wang and Kristina Bjegovic and Gilberto Gonzalez and Yong Chen and Lopata, {Richard G.P.} and Liangzhong Xiang",

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van Bergen, RJP, Sun, L, Kumar Pandey, P, Wang, S, Bjegovic, K, Gonzalez, G, Chen, Y, Lopata, RGP & Xiang, L 2024, 'Discrete Wavelet Transformation for the Sensitive Detection of Ultrashort Radiation Pulse With Radiation-Induced Acoustics', IEEE Transactions on Radiation and Plasma Medical Sciences, vol. 8, no. 1, 10248961, pp. 76-87. https://doi.org/10.1109/TRPMS.2023.3314339

Discrete Wavelet Transformation for the Sensitive Detection of Ultrashort Radiation Pulse With Radiation-Induced Acoustics. / van Bergen, Rick J.P.; Sun, Leshan; Kumar Pandey, Prabodh et al.
In: IEEE Transactions on Radiation and Plasma Medical Sciences, Vol. 8, No. 1, 10248961, 01.2024, p. 76-87.

Research output: Contribution to journal › Article › Academic › peer-review

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T1 - Discrete Wavelet Transformation for the Sensitive Detection of Ultrashort Radiation Pulse With Radiation-Induced Acoustics

AU - van Bergen, Rick J.P.

AU - Sun, Leshan

AU - Kumar Pandey, Prabodh

AU - Wang, Siqi

AU - Bjegovic, Kristina

AU - Gonzalez, Gilberto

AU - Chen, Yong

AU - Lopata, Richard G.P.

AU - Xiang, Liangzhong

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N2 - Radiation-induced acoustics (RIA) shows promise in advancing radiological imaging and radiotherapy dosimetry methods. However, RIA signals often require extensive averaging to achieve reasonable signal-to-noise ratios, which increases patient radiation exposure and limits real-time applications. Therefore, this article proposes a discrete wavelet transform (DWT)-based filtering approach to denoise the RIA signals and avoid extensive averaging. The algorithm was benchmarked against low-pass filters and tested on various types of RIA sources, including low-energy X-rays, high-energy X-rays, and protons. The proposed method significantly reduced the required averages (1000 times less averaging for low-energy X-ray RIA, 32 times less averaging for high-energy X-ray RIA, and four times less averaging for proton RIA) and demonstrated robustness in filtering signals from different sources of radiation. The coif5 wavelet in conjunction with the sqtwolog threshold selection algorithm yielded the best results. The proposed DWT filtering method enables high-quality, automated, and robust filtering of RIA signals, with a performance similar to low-pass filtering, aiding in the clinical translation of radiation-based acoustic imaging for radiology and radiation oncology.

AB - Radiation-induced acoustics (RIA) shows promise in advancing radiological imaging and radiotherapy dosimetry methods. However, RIA signals often require extensive averaging to achieve reasonable signal-to-noise ratios, which increases patient radiation exposure and limits real-time applications. Therefore, this article proposes a discrete wavelet transform (DWT)-based filtering approach to denoise the RIA signals and avoid extensive averaging. The algorithm was benchmarked against low-pass filters and tested on various types of RIA sources, including low-energy X-rays, high-energy X-rays, and protons. The proposed method significantly reduced the required averages (1000 times less averaging for low-energy X-ray RIA, 32 times less averaging for high-energy X-ray RIA, and four times less averaging for proton RIA) and demonstrated robustness in filtering signals from different sources of radiation. The coif5 wavelet in conjunction with the sqtwolog threshold selection algorithm yielded the best results. The proposed DWT filtering method enables high-quality, automated, and robust filtering of RIA signals, with a performance similar to low-pass filtering, aiding in the clinical translation of radiation-based acoustic imaging for radiology and radiation oncology.

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KW - Radiation

KW - Dosimetry

KW - Signal Processing

KW - Wavelet Transform

KW - Discrete wavelet filtering

KW - radiation induced acoustics (RIA)

KW - radiation monitoring

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SN - 2469-7311

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EP - 87

JO - IEEE Transactions on Radiation and Plasma Medical Sciences

JF - IEEE Transactions on Radiation and Plasma Medical Sciences

IS - 1

M1 - 10248961

ER -

Discrete Wavelet Transformation for the Sensitive Detection of Ultrashort Radiation Pulse With Radiation-Induced Acoustics

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