DSC based Dual-Resunet for radio frequency interference identification

Yan Jun Zhang; Yan Zuo Li; Jun Cheng; Yi Hua Yan

doi:10.1088/1674-4527/ac2944

DSC based Dual-Resunet for radio frequency interference identification

Yan Jun Zhang, Yan Zuo Li, Jun Cheng^*, Yi Hua Yan

^*此作品的通讯作者

网络空间安全学院

科研成果: 期刊稿件 › 文章 › 同行评审

8 引用（Scopus）

摘要

Radio frequency interference (RFI) will pollute the weak astronomical signals receivedby radio telescopes, which in return will seriously affect the time-domain astronomical observation and research. In this paper, we use a deep learning method to identify RFI in frequency spectrum data, and propose a neural network based on Unet that combines the principles of depthwise separable convolution and residual, named DSC Based Dual-Resunet. Compared with the existing Unet network, DSC Based Dual-Resunet performs better in terms ofaccuracy, F1 score, and MIoU, and is also better in terms of computation cost where the model size and parameter amount are 12.5% of Unet and the amount of computation is 38%ofUnet. The experimental results show that the proposed network is a high-performance and lightweight network, and it is hopeful to be applied to RFI identification of radio telescopes on a large scale.

源语言	英语
文章编号	299
期刊	Research in Astronomy and Astrophysics
卷	21
期	12
DOI	https://doi.org/10.1088/1674-4527/ac2944
出版状态	已出版 - 12月 2021

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title = "DSC based Dual-Resunet for radio frequency interference identification",

abstract = "Radio frequency interference (RFI) will pollute the weak astronomical signals receivedby radio telescopes, which in return will seriously affect the time-domain astronomical observation and research. In this paper, we use a deep learning method to identify RFI in frequency spectrum data, and propose a neural network based on Unet that combines the principles of depthwise separable convolution and residual, named DSC Based Dual-Resunet. Compared with the existing Unet network, DSC Based Dual-Resunet performs better in terms ofaccuracy, F1 score, and MIoU, and is also better in terms of computation cost where the model size and parameter amount are 12.5% of Unet and the amount of computation is 38%ofUnet. The experimental results show that the proposed network is a high-performance and lightweight network, and it is hopeful to be applied to RFI identification of radio telescopes on a large scale.",

keywords = "Sun: radio radiation, radio frequency interference, techniques: deep learning and image processing, telescopes",

author = "Zhang, {Yan Jun} and Li, {Yan Zuo} and Jun Cheng and Yan, {Yi Hua}",

note = "Publisher Copyright: {\textcopyright} 2021 National Astronomical Observatories, CAS and IOP Publishing Ltd..",

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doi = "10.1088/1674-4527/ac2944",

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T1 - DSC based Dual-Resunet for radio frequency interference identification

AU - Zhang, Yan Jun

AU - Li, Yan Zuo

AU - Cheng, Jun

AU - Yan, Yi Hua

PY - 2021/12

Y1 - 2021/12

N2 - Radio frequency interference (RFI) will pollute the weak astronomical signals receivedby radio telescopes, which in return will seriously affect the time-domain astronomical observation and research. In this paper, we use a deep learning method to identify RFI in frequency spectrum data, and propose a neural network based on Unet that combines the principles of depthwise separable convolution and residual, named DSC Based Dual-Resunet. Compared with the existing Unet network, DSC Based Dual-Resunet performs better in terms ofaccuracy, F1 score, and MIoU, and is also better in terms of computation cost where the model size and parameter amount are 12.5% of Unet and the amount of computation is 38%ofUnet. The experimental results show that the proposed network is a high-performance and lightweight network, and it is hopeful to be applied to RFI identification of radio telescopes on a large scale.

AB - Radio frequency interference (RFI) will pollute the weak astronomical signals receivedby radio telescopes, which in return will seriously affect the time-domain astronomical observation and research. In this paper, we use a deep learning method to identify RFI in frequency spectrum data, and propose a neural network based on Unet that combines the principles of depthwise separable convolution and residual, named DSC Based Dual-Resunet. Compared with the existing Unet network, DSC Based Dual-Resunet performs better in terms ofaccuracy, F1 score, and MIoU, and is also better in terms of computation cost where the model size and parameter amount are 12.5% of Unet and the amount of computation is 38%ofUnet. The experimental results show that the proposed network is a high-performance and lightweight network, and it is hopeful to be applied to RFI identification of radio telescopes on a large scale.

KW - Sun: radio radiation

KW - radio frequency interference

KW - techniques: deep learning and image processing

KW - telescopes

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DSC based Dual-Resunet for radio frequency interference identification

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