TY - JOUR
T1 - Exploration-exploitation model of moth-inspired olfactory navigation
AU - Lazebnik, Teddy
AU - Golov, Yiftach
AU - Gurka, Roi
AU - Harari, Ally
AU - Liberzon, Alex
N1 - Publisher Copyright:
© 2024 The Authors.
PY - 2024/7/17
Y1 - 2024/7/17
N2 - Navigation of male moths towards females during the mating search offers a unique perspective on the exploration-exploitation (EE) model in decision-making. This study uses the EE model to explain male moth pheromone-driven flight paths. Wind tunnel measurements and three-dimensional tracking using infrared cameras have been leveraged to gain insights into male moth behaviour. During the experiments in the wind tunnel, disturbance to the airflow has been added and the effect of increased fluctuations on moth flights has been analysed, in the context of the proposed EE model. The exploration and exploitation phases are separated using a genetic algorithm to the experimentally obtained dataset of moth three-dimensional trajectories. First, the exploration-to-exploitation rate (EER) increases with distance from the source of the female pheromone is demonstrated, which can be explained in the context of the EE model. Furthermore, our findings reveal a compelling relationship between EER and increased flow fluctuations near the pheromone source. Using an olfactory navigation simulation and our moth-inspired navigation model, the phenomenon where male moths exhibit an enhanced EER as turbulence levels increase is explained. This research extends our understanding of optimal navigation strategies based on general biological EE models and supports the development of bioinspired navigation algorithms.
AB - Navigation of male moths towards females during the mating search offers a unique perspective on the exploration-exploitation (EE) model in decision-making. This study uses the EE model to explain male moth pheromone-driven flight paths. Wind tunnel measurements and three-dimensional tracking using infrared cameras have been leveraged to gain insights into male moth behaviour. During the experiments in the wind tunnel, disturbance to the airflow has been added and the effect of increased fluctuations on moth flights has been analysed, in the context of the proposed EE model. The exploration and exploitation phases are separated using a genetic algorithm to the experimentally obtained dataset of moth three-dimensional trajectories. First, the exploration-to-exploitation rate (EER) increases with distance from the source of the female pheromone is demonstrated, which can be explained in the context of the EE model. Furthermore, our findings reveal a compelling relationship between EER and increased flow fluctuations near the pheromone source. Using an olfactory navigation simulation and our moth-inspired navigation model, the phenomenon where male moths exhibit an enhanced EER as turbulence levels increase is explained. This research extends our understanding of optimal navigation strategies based on general biological EE models and supports the development of bioinspired navigation algorithms.
KW - bioinspired algorithm
KW - biological signal processing
KW - navigation performance
KW - physical simulation
UR - http://www.scopus.com/inward/record.url?scp=85199014391&partnerID=8YFLogxK
U2 - 10.1098/rsif.2023.0746
DO - 10.1098/rsif.2023.0746
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C2 - 39013419
AN - SCOPUS:85199014391
SN - 1742-5689
VL - 21
JO - Journal of the Royal Society Interface
JF - Journal of the Royal Society Interface
IS - 216
M1 - 20230746
ER -