Celestial compass sensor mimics the insect eye for navigation under cloudy and occluded skies

Evripidis Gkanias; Robert Mitchell; Jan Stankiewicz; Sadeque Khan; Srinjoy Mitra; Barbara Webb

doi:10.1038/s44172-023-00132-w

Celestial compass sensor mimics the insect eye for navigation under cloudy and occluded skies

Evripidis Gkanias^*, Robert Mitchell, Jan Stankiewicz, Sadeque Khan, Srinjoy Mitra, Barbara Webb

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

Abstract

Insects use the sun’s position (even when concealed) as a compass for navigation by filtering celestial light intensity and polarisation through their compound eyes. To replicate this functionality, we present a sensor that imitates essential aspects of insect eyes, particularly the fan-like arrangement of polarised light receptors in their dorsal rim area. Our sensor comprises a ring of eight pairs of photodiodes (evaluating two orthogonal orientations of polarised light) to analyse the skylight coming from different directions. Because the layout of our sensor aligns with the polarised light pattern in the sky, a circular-mean model that integrates information spatially across the analysers can estimate the solar azimuth. When using the same sensor design, our model achieves lower compass errors than alternative (and computationally more complex) algorithms, especially under cloudy and occluded skies. Thus, the morphology and processing of the insect celestial compass provide an efficient and robust directional input for navigation.

Original language	English
Article number	82
Pages (from-to)	1-12
Number of pages	12
Journal	Communications Engineering
Volume	2
Issue number	1
DOIs	https://doi.org/10.1038/s44172-023-00132-w
Publication status	Published - 15 Nov 2023

Keywords / Materials (for Non-textual outputs)

biomimetics
computational science
electrical and electronic engineering
electronics, photonics and device physics
information theory and computation

Access to Document

10.1038/s44172-023-00132-wLicence: Creative Commons: Attribution (CC-BY)

Celestial compass_GKANIAS_DOA30102023_VOR_CC BYFinal published version, 6.36 MBLicence: Creative Commons: Attribution (CC-BY)

https://www.nature.com/articles/s44172-023-00132-wLicence: Creative Commons: Attribution (CC-BY)

Insect-Brain inspired Neuromorphic Nanophotonics
Webb, B. (Principal Investigator)
Innovate UK
1/04/22 → 31/03/26
Project: Research
UltimateCOMPASS: Navigating the most challenging habitats on earth: unravelling the architecture of a universal compass system
Webb, B. (Principal Investigator)
EU government bodies
1/06/19 → 31/05/24
Project: Research
DTP 2018-19 University of Edinburgh
Maciocia, A. (Principal Investigator) & Lobaskin, I. (Student)
1/10/18 → 30/09/23
Project: Research

From skylight input to behavioural output: A computational model of the insect polarised light compass
Gkanias, E., Risse, B., Mangan, M. & Webb, B., 18 Jul 2019, In: PLoS Computational Biology. 15, 7, e1007123.
Research output: Contribution to journal › Article › peer-review

Open Access
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Cite this

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title = "Celestial compass sensor mimics the insect eye for navigation under cloudy and occluded skies",

abstract = "Insects use the sun{\textquoteright}s position (even when concealed) as a compass for navigation by filtering celestial light intensity and polarisation through their compound eyes. To replicate this functionality, we present a sensor that imitates essential aspects of insect eyes, particularly the fan-like arrangement of polarised light receptors in their dorsal rim area. Our sensor comprises a ring of eight pairs of photodiodes (evaluating two orthogonal orientations of polarised light) to analyse the skylight coming from different directions. Because the layout of our sensor aligns with the polarised light pattern in the sky, a circular-mean model that integrates information spatially across the analysers can estimate the solar azimuth. When using the same sensor design, our model achieves lower compass errors than alternative (and computationally more complex) algorithms, especially under cloudy and occluded skies. Thus, the morphology and processing of the insect celestial compass provide an efficient and robust directional input for navigation.",

keywords = "biomimetics, computational science, electrical and electronic engineering, electronics, photonics and device physics, information theory and computation",

author = "Evripidis Gkanias and Robert Mitchell and Jan Stankiewicz and Sadeque Khan and Srinjoy Mitra and Barbara Webb",

note = "This work was financially supported in part by the European Union, Horizon Europe, (Project 101046790, InsectNeuroNano), the European Research Council (817535, Ultimate-COMPASS), and the UKRI Engineering and Physical Sciences Research Council (Grant No. EP/R513209/1, EP/M008479/1, and Impact Acceleration Account PIV068). We thank Marie Dacke from Lund University for facilitating field testing by providing travel and access to the field sites used for data collection. Thanks to the members of the Insect Robotics Group from the University of Edinburgh for commenting on earlier versions of the manuscript. Also, thanks to the InsectNeuroNano team for comments on the results of this work.",

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AU - Webb, Barbara

N1 - This work was financially supported in part by the European Union, Horizon Europe, (Project 101046790, InsectNeuroNano), the European Research Council (817535, Ultimate-COMPASS), and the UKRI Engineering and Physical Sciences Research Council (Grant No. EP/R513209/1, EP/M008479/1, and Impact Acceleration Account PIV068). We thank Marie Dacke from Lund University for facilitating field testing by providing travel and access to the field sites used for data collection. Thanks to the members of the Insect Robotics Group from the University of Edinburgh for commenting on earlier versions of the manuscript. Also, thanks to the InsectNeuroNano team for comments on the results of this work.

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N2 - Insects use the sun’s position (even when concealed) as a compass for navigation by filtering celestial light intensity and polarisation through their compound eyes. To replicate this functionality, we present a sensor that imitates essential aspects of insect eyes, particularly the fan-like arrangement of polarised light receptors in their dorsal rim area. Our sensor comprises a ring of eight pairs of photodiodes (evaluating two orthogonal orientations of polarised light) to analyse the skylight coming from different directions. Because the layout of our sensor aligns with the polarised light pattern in the sky, a circular-mean model that integrates information spatially across the analysers can estimate the solar azimuth. When using the same sensor design, our model achieves lower compass errors than alternative (and computationally more complex) algorithms, especially under cloudy and occluded skies. Thus, the morphology and processing of the insect celestial compass provide an efficient and robust directional input for navigation.

AB - Insects use the sun’s position (even when concealed) as a compass for navigation by filtering celestial light intensity and polarisation through their compound eyes. To replicate this functionality, we present a sensor that imitates essential aspects of insect eyes, particularly the fan-like arrangement of polarised light receptors in their dorsal rim area. Our sensor comprises a ring of eight pairs of photodiodes (evaluating two orthogonal orientations of polarised light) to analyse the skylight coming from different directions. Because the layout of our sensor aligns with the polarised light pattern in the sky, a circular-mean model that integrates information spatially across the analysers can estimate the solar azimuth. When using the same sensor design, our model achieves lower compass errors than alternative (and computationally more complex) algorithms, especially under cloudy and occluded skies. Thus, the morphology and processing of the insect celestial compass provide an efficient and robust directional input for navigation.

KW - biomimetics

KW - computational science

KW - electrical and electronic engineering

KW - electronics, photonics and device physics

KW - information theory and computation

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JF - Communications Engineering

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ER -

Celestial compass sensor mimics the insect eye for navigation under cloudy and occluded skies

Abstract

Keywords / Materials (for Non-textual outputs)

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Projects

Insect-Brain inspired Neuromorphic Nanophotonics

UltimateCOMPASS: Navigating the most challenging habitats on earth: unravelling the architecture of a universal compass system

DTP 2018-19 University of Edinburgh

Research output

From skylight input to behavioural output: A computational model of the insect polarised light compass

Cite this