Abstract
With the availability of low-cost and efficient digital cameras, ecologists can now survey the world’s biodiversity through image sensors, especially in the previously rather inaccessible marine realm. However, the data rapidly accumulates, and ecologists face a data processing bottleneck. While computer vision has long been used as a tool to speed up image processing, it is only since the breakthrough of deep learning (DL) algorithms that the revolution in the automatic assessment of biodiversity by video recording can be considered. However, current applications of DL models to biodiversity monitoring do not consider some universal rules of biodiversity, especially rules on the distribution of species abundance, species rarity and ecosystem openness. Yet, these rules imply three issues for deep learning applications: the imbalance of long-tail datasets biases the training of DL models; scarce data greatly lessens the performances of DL models for classes with few data. Finally, the open-world issue implies that objects that are absent from the training dataset are incorrectly classified in the application dataset. Promising solutions to these issues are discussed, including data augmentation, data generation, cross-entropy modification, few-shot learning and open set recognition. At a time when biodiversity faces the immense challenges of climate change and the Anthropocene defaunation, stronger collaboration between computer scientists and ecologists is urgently needed to unlock the automatic monitoring of biodiversity.
Highlights
In the age of climate change and anthropogenic defaunation [1,2] innovative methodology is needed to monitor ecosystems at large-spatial scales and high-temporal frequencies.Since the beginning of time, humans have learned from nature through visual observation, gradually using drawings, paintings, photographs and videos
While computer vision has long been used to speed up image processing, it is only since the emergence of deep learning (DL) algorithms that the revolution in the automatic assessment of biodiversity by video recording can be considered [3]
Efficient deep networks working with few data, such as few-shot learners and one-shot learners, improvement of the robustness to data imbalances through a built learning process, and the ability to treat information absent from the training datasets with Open Set Recognition paves the way for an interdisciplinary branch of science between computer sciences and ecology
Summary
In the age of climate change and anthropogenic defaunation [1,2] innovative methodology is needed to monitor ecosystems at large-spatial scales and high-temporal frequencies. While computer vision has long been used to speed up image processing, it is only since the emergence of deep learning (DL) algorithms that the revolution in the automatic assessment of biodiversity by video recording can be considered [3]. This revolution is underway, as shown by the exponential number of publications combining the words “biodiversity” and “deep learning”. The current work of deep learning applications to automatically detect and classify animals in imagery is based on two premises: (1) an important database of each class of interest (thereafter “species”), and (2) a balanced dataset These hypotheses are not verified for unconstrained wildlife video census. The aim of this work is (1) to point out ecological questions that can or cannot yet be tackled through DL applications by understanding its possibilities and limitations, and (2) to highlight recent advances of DL to unclog unconstrained wildlife video census
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