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We've Been Undercounting the Insects. There May Be Three Times as Many Species as We Knew

TIME - Tech

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New estimate: Earth has 14 to 20 million insect species

Popular Science

For 40 years, we thought Earth was home to six million insect species. Turns out, it could be three times that. More information Adding us as a Preferred Source in Google by using this link indicates that you would like to see more of our content in Google News results. Insect species make up the largest percentage of Earth's known species. Breakthroughs, discoveries, and DIY tips sent six days a week.


TerraIncognita: A Dynamic Benchmark for Species Discovery Using Frontier Models

arXiv.org Artificial Intelligence

The rapid global loss of biodiversity, particularly among insects, represents an urgent ecological crisis. Current methods for insect species discovery are manual, slow, and severely constrained by taxonomic expertise, hindering timely conservation actions. We introduce TerraIncognita, a dynamic benchmark designed to evaluate state-of-the-art multimodal models for the challenging problem of identifying unknown, potentially undescribed insect species from image data. Our benchmark dataset combines a mix of expertly annotated images of insect species likely known to frontier AI models, and images of rare and poorly known species, for which few/no publicly available images exist. These images were collected from underexplored biodiversity hotspots, realistically mimicking open-world discovery scenarios faced by ecologists. The benchmark assesses models' proficiency in hierarchical taxonomic classification, their capability to detect and abstain from out-of-distribution (OOD) samples representing novel species, and their ability to generate explanations aligned with expert taxonomic knowledge. Notably, top-performing models achieve over 90\% F1 at the Order level on known species, but drop below 2\% at the Species level, highlighting the sharp difficulty gradient from coarse to fine taxonomic prediction (Order $\rightarrow$ Family $\rightarrow$ Genus $\rightarrow$ Species). TerraIncognita will be updated regularly, and by committing to quarterly dataset expansions (of both known and novel species), will provide an evolving platform for longitudinal benchmarking of frontier AI methods. All TerraIncognita data, results, and future updates are available \href{https://baskargroup.github.io/TerraIncognita/}{here}.


Multisensor Data Fusion for Automatized Insect Monitoring (KInsecta)

arXiv.org Artificial Intelligence

Insect populations are declining globally, making systematic monitoring essential for conservation. Most classical methods involve death traps and counter insect conservation. This paper presents a multisensor approach that uses AI-based data fusion for insect classification. The system is designed as low-cost setup and consists of a camera module and an optical wing beat sensor as well as environmental sensors to measure temperature, irradiance or daytime as prior information. The system has been tested in the laboratory and in the field. First tests on a small very unbalanced data set with 7 species show promising results for species classification. The multisensor system will support biodiversity and agriculture studies.


Low Cost Machine Vision for Insect Classification

arXiv.org Artificial Intelligence

Preserving the number and diversity of insects is one of our society's most important goals in the area of environmental sustainability. A prerequisite for this is a systematic and up-scaled monitoring in order to detect correlations and identify countermeasures. Therefore, automatized monitoring using live traps is important, but so far there is no system that provides image data of sufficient detailed information for entomological classification. In this work, we present an imaging method as part of a multisensor system developed as a low-cost, scalable, open-source system that is adaptable to classical trap types. The image quality meets the requirements needed for classification in the taxonomic tree. Therefore, illumination and resolution have been optimized and motion artefacts have been suppressed. The system is evaluated exemplarily on a dataset consisting of 16 insect species of the same as well as different genus, family and order. We demonstrate that standard CNN-architectures like ResNet50 (pretrained on iNaturalist data) or MobileNet perform very well for the prediction task after re-training. Smaller custom made CNNs also lead to promising results. Classification accuracy of $>96\%$ has been achieved. Moreover, it was proved that image cropping of insects is necessary for classification of species with high inter-class similarity.


How to count insects from space

MIT Technology Review

But there is a glimmer of hope in an unexpected place: space. And it doesn't require fancy sensors or expensive new satellites. As researchers from the University of Würzburg reported in a 2019 paper in Nature Communications, "Radar Vision in the Mapping of Forest Biodiversity from Space," it turns out that freely available radar data can be used to figure out where even the smallest insects live. To make this work, scientists first perform comprehensive "ground truth" studies. They take a thorough look at just which insects are living in an area, attracting them using bright lights or setting out pitfall traps to lure and contain them.


InsectUp: Crowdsourcing Insect Observations to Assess Demographic Shifts and Improve Classification

arXiv.org Machine Learning

Insects play such a crucial role in ecosystems that a shift in demography of just a few species can have devastating consequences at environmental, social and economic levels. Despite this, evaluation of insect demography is strongly limited by the difficulty of collecting census data at sufficient scale. We propose a method to gather and leverage observations from bystanders, hikers, and entomology enthusiasts in order to provide researchers with data that could significantly help anticipate and identify environmental threats. Finally, we show that there is indeed interest on both sides for such collaboration.