Abstract
Accurate occurrence data is necessary for the conservation of keystone or endangered species, but acquiring it is usually slow, laborious and costly. Automated acoustic monitoring offers a scalable alternative to manual surveys but identifying species vocalisations requires large manually annotated training datasets, and is not always possible (e.g. for lesser studied or silent species). A new approach is needed that rapidly predicts species occurrence using smaller and more coarsely labelled audio datasets. We investigated whether local soundscapes could be used to infer the presence of 32 avifaunal and seven herpetofaunal species in 20 min recordings across a tropical forest degradation gradient in Sabah, Malaysia. Using acoustic features derived from a convolutional neural network (CNN), we characterised species indicative soundscapes by training our models on a temporally coarse labelled point‐count dataset. Soundscapes successfully predicted the occurrence of 34 out of the 39 species across the two taxonomic groups, with area under the curve (AUC) metrics from 0.53 up to 0.87. The highest accuracies were achieved for species with strong temporal occurrence patterns. Soundscapes were a better predictor of species occurrence than above‐ground carbon density – a metric often used to quantify habitat quality across forest degradation gradients. Our results demonstrate that soundscapes can be used to efficiently predict the occurrence of a wide variety of species and provide a new direction for data driven large‐scale assessments of habitat suitability.
Highlights
Ecosystems are being subjected to increasing external pressures from land-use change and global warming (Walther et al 2002, Lambin and Meyfroidt 2011)
above-ground carbon density (ACD) is closely correlated with above-ground biomass (AGB) which has been used as a metric of forest intactness at Stability of Altered Forest Ecosystems (SAFE) Project regularly, as decreases in AGB are primarily driven by historical and current anthropogenic pressures (Brant et al 2016, Luke et al 2017, Riutta et al 2018, Williamson et al 2021)
Even with features averaged over almost five minutes, we were able to predict species occurrence from soundscapes with area under the curve (AUC) of up to 0.82
Summary
Ecosystems are being subjected to increasing external pressures from land-use change and global warming (Walther et al 2002, Lambin and Meyfroidt 2011). These pressures have resulted in global biodiversity declines, as the natural habitats required to support many species shrink and disappear (Newbold et al 2015). Efforts to slow this decline often aim to protect areas of high conservation value that may support. Populations of endangered or keystone species (Mills et al 1993) This leads to the key question: how can we identify such locations rapidly, accurately and on a large scale?. Audio data can be recorded and analysed inexpensively, in real-time and over extended durations, making it an increasingly powerful tool for ecologists and conservationists (Pijanowski et al 2011, Sueur and Farina 2015)
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