Biotic sound SNR influence analysis on acoustic indices

Lei Chen, Zhi-yong Xu, Zhao Zhao
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引用次数: 1

Abstract

In recent years, passive acoustic monitoring (PAM) has become increasingly popular. Many acoustic indices (AIs) have been proposed for rapid biodiversity assessment (RBA), however, most acoustic indices have been reported to be susceptible to abiotic sounds such as wind or rain noise when biotic sound is masked, which greatly limits the application of these acoustic indices. In this work, in order to take an insight into the influence mechanism of signal-to-noise ratio (SNR) on acoustic indices, four most commonly used acoustic indices, i.e., the bioacoustic index (BIO), the acoustic diversity index (ADI), the acoustic evenness index (AEI), and the acoustic complexity index (ACI), were investigated using controlled computational experiments with field recordings collected in a suburban park in Xuzhou, China, in which bird vocalizations were employed as typical biotic sounds. In the experiments, different signal-to-noise ratio conditions were obtained by varying biotic sound intensities while keeping the background noise fixed. Experimental results showed that three indices (acoustic diversity index, acoustic complexity index, and bioacoustic index) decreased while the trend of acoustic evenness index was in the opposite direction as signal-to-noise ratio declined, which was owing to several factors summarized as follows. Firstly, as for acoustic diversity index and acoustic evenness index, the peak value in the spectrogram will no longer correspond to the biotic sounds of interest when signal-to-noise ratio decreases to a certain extent, leading to erroneous results of the proportion of sound occurring in each frequency band. Secondly, in bioacoustic index calculation, the accumulation of the difference between the sound level within each frequency band and the minimum sound level will drop dramatically with reduced biotic sound intensities. Finally, the acoustic complexity index calculation result relies on the ratio between total differences among all adjacent frames and the total sum of all frames within each temporal step and frequency bin in the spectrogram. With signal-to-noise ratio decreasing, the biotic components contribution in both the total differences and the total sum presents a complex impact on the final acoustic complexity index value. This work is helpful to more comprehensively interpret the values of the above acoustic indices in a real-world environment and promote the applications of passive acoustic monitoring in rapid biodiversity assessment.
生物声信噪比对声学指标的影响分析
近年来,被动声监测(PAM)越来越受到人们的欢迎。目前已经提出了许多用于生物多样性快速评价的声学指标(AIs),但大多数声学指标在生物声音被掩盖的情况下容易受到风、雨等非生物声音的影响,这极大地限制了这些声学指标的应用。为了深入了解信噪比(SNR)对声学指标的影响机制,本文采用控制计算实验方法,对中国徐州郊区公园现场录音进行了研究,研究了生物声学指数(BIO)、声学多样性指数(ADI)、声学均匀度指数(AEI)和声学复杂性指数(ACI)这四个最常用的声学指标。其中鸟类的叫声被用作典型的生物声音。实验中,在保持背景噪声不变的情况下,通过改变生物声强获得不同的信噪比条件。实验结果表明,随着信噪比的下降,声多样性指数、声复杂性指数和生物声学指数呈下降趋势,而声均匀度指数呈相反趋势,其原因主要有以下几个方面:首先,对于声多样性指数和声均匀度指数,当信噪比降低到一定程度时,谱图中的峰值将不再与感兴趣的生物声音对应,从而导致各频段声音出现比例的结果错误。其次,在生物声学指数计算中,随着生物声强的减小,各频带内声级与最小声级之差的累积量会急剧下降。最后,声学复杂性指数的计算结果依赖于所有相邻帧之间的总差与频谱图中每个时间步长内所有帧的总差和频率bin的比值。随着信噪比的降低,生物组分在总差值和总差值中的贡献对最终声学复杂性指数值的影响都是复杂的。本文的工作有助于更全面地解释上述声学指标在真实环境中的价值,促进被动声学监测在生物多样性快速评价中的应用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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