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Main Authors: Bloch, Itai, Troupin, David, Toledo, Sivan, Nathan, Ran, Sapir, Nir
Format: Artículo científico
Language:en
Published: eLife 2025
Subjects:
Online Access:https://pubmed.ncbi.nlm.nih.gov/39869495/
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author Bloch, Itai
Troupin, David
Toledo, Sivan
Nathan, Ran
Sapir, Nir
author_facet Bloch, Itai
Troupin, David
Toledo, Sivan
Nathan, Ran
Sapir, Nir
Bloch, Itai
Troupin, David
Toledo, Sivan
Nathan, Ran
Sapir, Nir
collection PubMed - marine biology
contents Combining radio-telemetry and radar measurements to test optimal foraging in an aerial insectivore bird. Bloch, Itai Troupin, David Toledo, Sivan Nathan, Ran Sapir, Nir Animals Radar Telemetry Feeding Behavior Birds Flight, Animal Israel Predatory Behavior Optimal foraging theory posits that foragers adjust their movements based on prey abundance to optimize food intake. While extensively studied in terrestrial and marine environments, aerial foraging has remained relatively unexplored due to technological limitations. This study, uniquely combining BirdScan-MR1 radar and the Advanced Tracking and Localization of Animals in Real-Life Systems biotelemetry system, investigates the foraging dynamics of Little Swifts () in response to insect movements over Israel's Hula Valley. Insect movement traffic rate (MoTR) substantially varied across days, strongly influencing swift movement. On days with high MoTR, swifts exhibited reduced flight distance, increased colony visit rate, and earlier arrivals at the breeding colony, reflecting a dynamic response to prey availability. However, no significant effects were observed in total foraging duration, flight speed, or daily route length. Notably, as insect abundance increased, inter-individual distances decreased. These findings suggest that Little Swifts optimize their foraging behavior in relation to aerial insect abundance, likely influencing reproductive success and population dynamics. The integration of radar technology and biotelemetry systems provides a unique perspective on the interactions between aerial insectivores and their prey, contributing to a comprehensive understanding of optimal foraging strategies in diverse environments.
format Artículo científico
id pubmed_39869495
institution PubMed
language en
publishDate 2025
publisher eLife
record_format pubmed
spellingShingle Combining radio-telemetry and radar measurements to test optimal foraging in an aerial insectivore bird.
Bloch, Itai
Troupin, David
Toledo, Sivan
Nathan, Ran
Sapir, Nir
Animals
Radar
Telemetry
Feeding Behavior
Birds
Flight, Animal
Israel
Predatory Behavior
Combining radio-telemetry and radar measurements to test optimal foraging in an aerial insectivore bird. Bloch, Itai Troupin, David Toledo, Sivan Nathan, Ran Sapir, Nir Animals Radar Telemetry Feeding Behavior Birds Flight, Animal Israel Predatory Behavior Optimal foraging theory posits that foragers adjust their movements based on prey abundance to optimize food intake. While extensively studied in terrestrial and marine environments, aerial foraging has remained relatively unexplored due to technological limitations. This study, uniquely combining BirdScan-MR1 radar and the Advanced Tracking and Localization of Animals in Real-Life Systems biotelemetry system, investigates the foraging dynamics of Little Swifts () in response to insect movements over Israel's Hula Valley. Insect movement traffic rate (MoTR) substantially varied across days, strongly influencing swift movement. On days with high MoTR, swifts exhibited reduced flight distance, increased colony visit rate, and earlier arrivals at the breeding colony, reflecting a dynamic response to prey availability. However, no significant effects were observed in total foraging duration, flight speed, or daily route length. Notably, as insect abundance increased, inter-individual distances decreased. These findings suggest that Little Swifts optimize their foraging behavior in relation to aerial insect abundance, likely influencing reproductive success and population dynamics. The integration of radar technology and biotelemetry systems provides a unique perspective on the interactions between aerial insectivores and their prey, contributing to a comprehensive understanding of optimal foraging strategies in diverse environments.
title Combining radio-telemetry and radar measurements to test optimal foraging in an aerial insectivore bird.
topic Animals
Radar
Telemetry
Feeding Behavior
Birds
Flight, Animal
Israel
Predatory Behavior
url https://pubmed.ncbi.nlm.nih.gov/39869495/