Monitoring aerial insect biodiversity: a radar perspective

Bauer, Silke; Tielens, Elske K.; Haest, Birgen

doi:10.1098/rstb.2023.0113

Cited by 4 publications

(5 citation statements)

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“…Radars emit electromagnetic beams that are reflected by objects in the air, and based on their echoes, these objects can be characterized. A variety of radar systems exists that differ in specifications, in the level of detail they provide on aerial objects and in spatio-temporal resolution [ 55 ]: small-scale radars can identify individual animals and characterize their body shape, size, wing beat frequency and other characteristics, but cover only relatively small aerial volumes [ 56 ]. By contrast, weather radar networks survey the atmosphere above areas stretching several hundreds to thousands of square kilometres but provide fewer and coarser characteristics of the biological targets detected [ 57 ].…”

Section: The Contributions To Four Technological Approaches In This T...mentioning

confidence: 99%

“…The contributions in this theme issue show-case several of these developments and demonstrate the potential of radars for contributing macroecological patterns to insect monitoring: First, Bauer et al [ 55 ] review the use of radar for insect monitoring. Then, Drake et al [ 60 ] develop biodiversity metrics that can complement the biomass and abundance measures from radar reflections, thereby enhancing the information that can be gained from radar monitoring.…”

Section: The Contributions To Four Technological Approaches In This T...mentioning

confidence: 99%

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Towards a toolkit for global insect biodiversity monitoring

van Klink,

Sheard,

Høye

et al. 2024

Phil. Trans. R. Soc. B

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Insects are the most diverse group of animals on Earth, yet our knowledge of their diversity, ecology and population trends remains abysmally poor. Four major technological approaches are coming to fruition for use in insect monitoring and ecological research—molecular methods, computer vision, autonomous acoustic monitoring and radar-based remote sensing—each of which has seen major advances over the past years. Together, they have the potential to revolutionize insect ecology, and to make all-taxa, fine-grained insect monitoring feasible across the globe. So far, advances within and among technologies have largely taken place in isolation, and parallel efforts among projects have led to redundancy and a methodological sprawl; yet, given the commonalities in their goals and approaches, increased collaboration among projects and integration across technologies could provide unprecedented improvements in taxonomic and spatio-temporal resolution and coverage. This theme issue showcases recent developments and state-of-the-art applications of these technologies, and outlines the way forward regarding data processing, cost-effectiveness, meaningful trend analysis, technological integration and open data requirements. Together, these papers set the stage for the future of automated insect monitoring. This article is part of the theme issue ‘Towards a toolkit for global insect biodiversity monitoring’.

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Section: The Contributions To Four Technological Approaches In This T...mentioning

confidence: 99%

Section: The Contributions To Four Technological Approaches In This T...mentioning

confidence: 99%

Towards a toolkit for global insect biodiversity monitoring

van Klink,

Sheard,

Høye

et al. 2024

Phil. Trans. R. Soc. B

Self Cite

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show abstract

“…The correlation is particularly strong during the day and crepuscular evening (R=0.86) and least strong in crepuscular morning. Bauer et al (2024) define 'abundance and biomass estimates' as an essential biodiversity variable. Although the absolute values of detected insect concentrations by both instruments differ by several orders of magnitude, we investigated whether the ratio of detected insect concentrations between both measurements is constant through time and height.…”

Section: Correlation Between Both Radar Instrumentsmentioning

confidence: 99%

“…Scanning radars further have the potential to cover spatially large regions. During recent years, the deployment of specialized radar-based detection methods for aerial fauna has become more prevalent, especially for movements of up to several hundred meters up in the air (e.g., Hu et al 2016, Lukach et al 2022, Wainwright et al 2023, Haest et al 2024b, Bauer et al 2024). To study larger flying animals, like birds and bats, radar instruments with wavelengths of a few up to several centimeters, like X-band (λ = 2.5-3.75 cm; e.g.…”

Section: Introductionmentioning

confidence: 99%

“…S-band, and more rarely also C-Band (Mäkinen et al 2022), weather radars have been shown useful to study high-density insect movements (Tielens and Kelly 2024), including specific events like mayfly emergences (Stepanian et al 2020, Kwakye et al 2023). X-Band radars have repeatedly been shown useful to study larger individual insects (Chapman et al 2011, Hu et al 2016, Gao et al 2020, Haest et al 2024b, Bauer et al 2024), but mostly miss insects with smaller radar cross sections (Riley 1985), which, in fact, are often more abundant. Ku-Band (λ = 1.67-2.4 cm), K-Band (λ = 1.11-1.67 cm) and Ka-Band (λ = 0.75-1.11 cm) radars have seen some use for entomological purposes (e.g., Cai et al 2019), however, almost no studies have been published on W-Band radar insect detection.…”

Section: Introductionmentioning

confidence: 99%

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Derivation of aerial insect concentration with a 94 GHz FMCW cloud radar

Lochmann,

Kalesse-Los,

Haest

et al. 2024

Preprint

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Aerial insects are vital for nature and society. Though methods to observe flying insects have consistently improved in the last decades, insects remain difficult to monitor systematically and consistently over large spatial and temporal scales. Remote sensing with radars has proved to be one of the more effective tools for observation. However, as radars are most sensitive to targets similar in size to the radar wavelength, the detectable sub-group of aerial insects of a certain size range depends on the employed radar. Here, we present a novel method based on data of a zenith-pointing W-band (94 GHz, lambda = 0.32 cm) Doppler cloud radar to estimate insect concentration in a vertical profile. Multiple meteorological state-of-the-art algorithms are combined to extract insect signals from the radar data and quantify their abundance from 50m to 1000m above the ground. For evaluation, this method is applied to Doppler cloud radar data from a summertime 30 day observation period in central Germany. Results are compared to data from an X-band (9.4 GHz, lambda = 3.2 cm) radar in the same region. Aerial insect concentration derived from the W-band radar, which is sensitive to insects in the mm size range, is substantially higher than from the X-band radar, detecting insects in the cm size range. In addition, diel flight timings vary between the different sub-groups of aerial insects observed by the two radar instruments. With its superior sensitivity to smaller insects like aphids, the proposed methodology complements existing entomological radar techniques and contributes to achieving a more complete description of aerial insect activity.

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A comprehensive review of long‐distance hover fly migration (Diptera: Syrphidae)

Reynolds,

Clem,

Fitz‐Gerald

et al. 2024

Ecological Entomology

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Hover flies (Diptera: Syrphidae) are a group of insects containing many migratory species that provide critical ecosystem services including pollination, decomposition and biological control. Their migratory behaviour remains largely overlooked and unacknowledged, but an influx of contemporary research is beginning to shift this. The goal of this review is to summarise and synthesise the past 150+ years of global hover fly migration research from over 50 papers in multiple languages. Here, we provide comprehensive evidence for hover fly migration through the lens of the methodologies used for studying these phenomena, the biological mechanisms for migration and the associated ecological and economic impacts. We also include an inventory of all recognised migratory species and discuss taxonomic patterns. In total, we compiled accounts of 46 species that are considered migratory, most of which were sourced from Europe. Recent reports, however, have also described hover fly migration in North America, Asia, the Middle East and Australia. Approximately 70% of these species are from the subfamily Syrphinae, which are important biological control agents. The migratory behaviour of hover flies has substantial impacts on ecosystem services and may be linked to long‐distance gene flow for many angiosperms via pollen transportation. These insects are also likely redistributing biological control services at a continental scale on an annual basis, which has major repercussions for the management of crop pests such as aphids. The sensitivity of hover fly migration to anthropogenic impacts is not well known, but shifting climatic conditions, pollution and increased habitat fragmentation are likely impactful and should be further explored. Despite recent advances and increased interest in the subject, hover fly migration remains understudied and many major knowledge gaps continue to persist.

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Monitoring aerial insect biodiversity: a radar perspective

Cited by 4 publications

References 103 publications

Towards a toolkit for global insect biodiversity monitoring

Towards a toolkit for global insect biodiversity monitoring

Derivation of aerial insect concentration with a 94 GHz FMCW cloud radar

A comprehensive review of long‐distance hover fly migration (Diptera: Syrphidae)

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