DualStack: Multi-Resolution Spectrogram Fusion Improves Bird Sound Classification for Ecological Monitoring

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Abstract

Automated bird sound classification plays a critical role in biodiversity assessment, ecological monitoring, and conservation research. Many current approaches use single-resolution spectrograms, which fail to fully capture the multi-scale acoustic features of avian vocalizations. We present DualStack, a new method that vertically stacks high-resolution and low-resolution Mel spectrograms into a single image, allowing convolutional neural networks to jointly learn fine temporal and broad spectral patterns. Using a dataset of 967 recordings from 22 species sourced from Xeno-Canto, DualStack achieved 86.63% classification accuracy, outperforming both single-resolution baselines and a BiParallel ResNet18 multi-branch architecture. This method improves species identification accuracy while remaining applicable to real-time monitoring, supporting more effective conservation efforts and large-scale ecological studies.
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This is a Preprint and has not been peer reviewed. This is version 1 of this Preprint. You must log in to post a comment. There are no comments or no comments have been made public for this article. This is a Preprint and has not been peer reviewed. This is version 1 of this Preprint. Add a Comment You must log in to post a comment. Comments There are no comments or no comments have been made public for this article. Automated bird sound classification plays a critical role in biodiversity assessment, ecological monitoring, and conservation research. Many current approaches use single-resolution spectrograms, which fail to fully capture the multi-scale acoustic features of avian vocalizations. We present DualStack, a new method that vertically stacks high-resolution and low-resolution Mel spectrograms into a single image, allowing convolutional neural networks to jointly learn fine temporal and broad spectral patterns. Using a dataset of 967 recordings from 22 species sourced from Xeno-Canto, DualStack achieved 86.63% classification accuracy, outperforming both single-resolution baselines and a BiParallel ResNet18 multi-branch architecture. This method improves species identification accuracy while remaining applicable to real-time monitoring, supporting more effective conservation efforts and large-scale ecological studies. https://doi.org/10.32942/X2TD2Z Engineering bird sound classification, bioacoustics, Biodiversity monitoring, ecological informatics, species identification, conservation technology, acoustic monitoring, spectrogram analysis, machine learning Published: 2025-08-11 06:53 Last Updated: 2025-08-11 06:53 CC BY Attribution 4.0 International Language: English

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License: CC-BY-4.0