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利用人工智能进行声学降噪,实现对蛀木害虫幼虫的早期监测。

Acoustic Denoising Using Artificial Intelligence for Wood-Boring Pests Larvae Early Monitoring.

机构信息

School of Information Science and Technology, Beijing Forestry University, Beijing 100083, China.

Engineering Research Center for Forestry-Oriented Intelligent Information Processing of National Forestry and Grassland Administration, Beijing 100083, China.

出版信息

Sensors (Basel). 2022 May 19;22(10):3861. doi: 10.3390/s22103861.

DOI:10.3390/s22103861
PMID:35632268
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9144394/
Abstract

Acoustic detection technology is a new method for early monitoring of wood-boring pests, and the effective denoising methods are the premise of acoustic detection in forests. This paper used sensors to record larval feeding sounds and various environmental noises, and two kinds of sounds were mixed to obtain the noisy feeding sounds with controllable noise intensity. Then, the time domain denoising models and frequency domain denoising models were designed, and the denoising effects were compared using the metrics of a signal-to-noise ratio (SNR), a segment signal-noise ratio (SegSNR), and log spectral distance (LSD). In the experiments, the average SNR increment could achieve 17.53 dB and 11.10 dB using the in the test data using the time domain features and frequency domain features, respectively. The average SegSNR increment achieved 18.59 dB and 12.04 dB, respectively, and the average LSD between pure feeding sounds and denoised feeding sounds were 0.85 dB and 0.84 dB, respectively. The experimental results demonstrated that the denoising models based on artificial intelligence were effective methods for . larval feeding sounds, and the overall denoising effect was more significant, especially at low SNRs. In view of that, the denoising models using time domain features were more suitable for the forest area and quarantine environment with complex noise types and large noise interference.

摘要

声学检测技术是一种用于早期监测蛀木害虫的新方法,而有效的去噪方法是在森林中进行声学检测的前提。本文使用传感器记录幼虫取食声和各种环境噪声,并将两种声音混合,以获得可控噪声强度的嘈杂取食声。然后,设计了时域去噪模型和频域去噪模型,并使用信噪比 (SNR)、分段信噪比 (SegSNR) 和对数谱距离 (LSD) 等指标比较了去噪效果。在实验中,使用时域特征和频域特征分别可使测试数据的平均 SNR 增量达到 17.53 dB 和 11.10 dB。平均 SegSNR 增量分别达到 18.59 dB 和 12.04 dB,纯取食声和去噪取食声之间的平均 LSD 分别为 0.85 dB 和 0.84 dB。实验结果表明,基于人工智能的去噪模型是蛀木幼虫取食声的有效处理方法,整体去噪效果更为显著,尤其是在低 SNR 情况下。鉴于此,使用时域特征的去噪模型更适用于噪声类型复杂、噪声干扰大的林区和检疫环境。

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