# Proximate determinants of the frequency of mosquito sounds: separating species-specific effects from environmentally driven variations - Implications for AI species recognition

**Authors:** Julie Augustin, Sándor Zsebők, Dorottya Kovács, Zoltán Jánki, András Bánhalmi, Zoltán Soltész, Péter Seffer, Vilmos Bilicki, László Zsolt Garamszegi, Muzafar Riyaz, Muzafar Riyaz, Muzafar Riyaz, Muzafar Riyaz

PMC · DOI: 10.1371/journal.pone.0343060 · PLOS One · 2026-03-04

## TL;DR

This study explores how environmental and individual factors affect mosquito wingbeat sounds, which are used for AI-based species identification.

## Contribution

The study identifies how species-specific sound patterns become more distinct when environmental and morphological factors are controlled.

## Key findings

- Species-specific sound signals become more robust when environmental and morphological factors are considered.
- Temperature and sex significantly influence mosquito wingbeat frequency, with species-specific differences in temperature response.
- Integrating biotic and environmental variables improves AI species recognition accuracy in real-life conditions.

## Abstract

In recent years, several technologies have been developed for the monitoring and control of insect vector species. Many of them aim to use mosquito wingbeat frequency in the form of sound or opto-acoustic measurements to identify mosquito species, often through the training of AI classification models. However, these models often struggle to be accurate in real-life conditions, as the training data rarely captures the variability range of different species across many individual and environmental conditions, or does not explicitly control for it. Here, we use lab recordings of mosquito sounds to evaluate the impact of several environmental and life history factors on the mean frequency of the first harmonic of mosquito sounds. We recorded 475 individuals of 15 species in several environmental conditions, varying in temperature and humidity, while we also characterized the effect of body size (wing length), sex and age on the frequency of wingbeat sound at the among-individual level. Only species that comprised at least 2 recorded individuals were included in the analysis (N = 10 species). Variances at the within-individual and within-species level varied consistently, as the repeatability of the trait was 0.411 and 0.466, respectively. However, when we controlled for morphological and environmental effects, the proportion of between-individual variance decreased, while the between-species component increased (repeatabilities: 0.267 and 0.630). This suggests that species-specific signals in the sound are more robust once factors introducing variances due to real life conditions are involved in the models. Sex and temperature both had a significant effect on mosquito sound: an increase in temperature led to an increase in wingbeat frequency. In addition, the random slope analysis showed that response to temperature differ between species, with strong between-species differences, especially for males. Therefore, advancing AI species recognition requires that biotic and environmental variables be either explicitly integrated into classification models or sufficiently represented in training data to reflect real-life variability.

## Full-text entities

- **Diseases:** malaria (MESH:D008288), MINOR (MESH:D004832), vector (MESH:D000079426), yellow fever (MESH:D015004), chikungunya (MESH:D065632), N (MESH:C536108), deaths (MESH:D003643), MAJOR COMMENTS (MESH:D004830), WBF (MESH:D006316), AI (MESH:C538142), dengue (MESH:D003715), injuries (MESH:D014947)
- **Chemicals:** DL-210TH (-), water (MESH:D014867), N (MESH:D009584), sugar (MESH:D000073893)
- **Species:** Culiseta longiareolata (species) [taxon 1206072], Anopheles claviger (species) [taxon 120868], Culex modestus (species) [taxon 545656], Apis mellifera (bee, species) [taxon 7460], Drosophila melanogaster (fruit fly, species) [taxon 7227], Culiseta annulata (species) [taxon 332058], Anopheles gambiae (African malaria mosquito, species) [taxon 7165], Culex hortensis (species) [taxon 1464559], Aedes japonicus (species) [taxon 140438], Culex pipiens (common house mosquito, species) [taxon 7175], Homo sapiens (human, species) [taxon 9606], Culiseta morsitans (species) [taxon 329107], Culex pipiens pipiens (subspecies) [taxon 38569], Culex quinquefasciatus (southern house mosquito, species) [taxon 7176], Ochlerotatus sticticus (species) [taxon 120878], Aedes koreicus (species) [taxon 586676], Ochlerotatus rusticus (species) [taxon 120877], Aedes geniculatus (species) [taxon 120874], Aedes vexans (species) [taxon 7163], Aedes albopictus (Asian tiger mosquito, species) [taxon 7160], Aedes aegypti (yellow fever mosquito, species) [taxon 7159]

## Full text

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## Figures

3 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12959652/full.md

## References

113 references — full list in the complete paper: https://tomesphere.com/paper/PMC12959652/full.md

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Source: https://tomesphere.com/paper/PMC12959652