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261 results on '"Polarization vision"'

2. Light pollution and navigation in two nocturnal arthropod taxa

Author

Meah, Rochelle J. and Roberts, Nicholas

Subjects
light pollution, polarization vision, navigation, arthropod
Abstract

Artificial light at night is a major anthropogenic pollutant. The area of artificially lit land is increasing at approximately 2% per year globally, and almost 90% of Europe is now affected by increased night sky luminance. The intensity, spectral composition, and timing of light pollution all affect different aspects of the physiology and behaviour of individual organisms. Ultimately, these changes can alter community structures and the ecology of different ecosystems. Among nocturnal arthropods, research on the impacts of light pollution has largely focused on community-level effects or broader behavioural ecology. The effects of artificial light masking visual cues used in task-specific behaviours have received relatively little attention and there are indications that light pollution might obscure a major nocturnal cue, the skylight polarization pattern, but this has never been studied in any detail. Similarly, how light pollution might affect the timing of these behaviours is also under-studied. This PhD investigates how artificial light at night masks the skylight polarization pattern and how the loss of this cue, and the spectral composition and intensity of the artificial light, behaviourally impacts both nocturnal central-place foraging spiders of the genus Drassodes, and a long-distance migratory moth, Helicoverpa armigera. The major differences in the polarization pattern between dark and light-polluted skies across four moon phases and across a light pollution radiance gradient were established using imaging polarimetry. The ecological impact of the masking effect of light pollution to polarization-guided navigation was assessed using analysis of the tethered paths of animals exposed to polarized stimuli. Finally, the ecological impact of light pollution on the initiation and timing of nocturnal journeys was examined by observing patterns of activity under streetlights of different intensities and spectral compositions. The skylight polarization pattern is significantly affected by light pollution which not only affects the strength of the polarization pattern, but its spatial and temporal extent. These impacts can occur even at low levels of light pollution and are exacerbated by changes in moon luminance across the phases of the lunar cycle. This has the potential to disorientate both H. armigera and Drassodes in the wild, as well as inhibit or alter time-sensitive navigational behaviour essential for survival with broader implications for dispersal, individual fitness, community composition and agroecosystems. Tuning the intensity and spectral composition of light pollution may alleviate the magnitude of these impacts through reductions in radiance and shifting the spectral character of the light away from short wavelengths.

Published
2023

21. Vízirovarok polarizációérzékelése, poláros ökológiai csapdák.

Author

GYÖRGY, KRISKA

Abstract

The research presented in this review paper provided new data on the polarization vision of different aquatic insect taxa and its biological role. It has also demonstrated the effects of different artificial polarized light sources and their polarization patterns on aquatic insects. In the first part we summarize the light polarization vision-based behaviour of mayflies (Ephemeroptera), dragonflies (Odonata), non-biting midges (Chironomidae) and horseflies (Tabanidae) that play a crucial role in the survival of each taxon. Research presented in the second thematic unit has shown that polarotactic aquatic insects often prefer artificial surfaces that are totally unsuitable as habitat and reflect strongly and horizontally polarized light, rather than the water surface. The striking levels of insect mortality frequently observed near such artificial surfaces have played an important role in the scientific definition of the term ecological trap. A specific form of ecological traps is polarized light pollution, which is a threat to aquatic insects, and whose typical sources are oil lakes, asphalt roads, black plastic sheeting used in agriculture, glass surfaces of greenhouses and buildings, car bodies, black tombstones, solar panels and solar collectors. If a polarotactic aquatic insect has a choice between these horizontally polarizing surfaces and a water surface, it will not choose water because of the supernormal polarization signal of the former. The exploration of this phenomenon has led to the recognition and definition of a new type of ecological light pollution, polarized light pollution. [ABSTRACT FROM AUTHOR]

Published
2024
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22. Behavioral responses of free-flying Drosophila melanogaster to shiny, reflecting surfaces.

Author

Mathejczyk, Thomas F., Babo, Édouard J., Schönlein, Erik, Grinda, Nikolai V., Greiner, Andreas, Okrožnik, Nina, Belušič, Gregor, and Wernet, Mathias F.

Subjects
*DROSOPHILA melanogaster, *FRUIT flies, *GENETIC models, *LIGHT intensity, *ANIMAL locomotion
Abstract

Active locomotion plays an important role in the life of many animals, permitting them to explore the environment, find vital resources, and escape predators. Most insect species rely on a combination of visual cues such as celestial bodies, landmarks, or linearly polarized light to navigate or orient themselves in their surroundings. In nature, linearly polarized light can arise either from atmospheric scattering or from reflections off shiny non-metallic surfaces like water. Multiple reports have described different behavioral responses of various insects to such shiny surfaces. Our goal was to test whether free-flying Drosophila melanogaster, a molecular genetic model organism and behavioral generalist, also manifests specific behavioral responses when confronted with such polarized reflections. Fruit flies were placed in a custom-built arena with controlled environmental parameters (temperature, humidity, and light intensity). Flight detections and landings were quantified for three different stimuli: a diffusely reflecting matt plate, a small patch of shiny acetate film, and real water. We compared hydrated and dehydrated fly populations, since the state of hydration may change the motivation of flies to seek or avoid water. Our analysis reveals for the first time that flying fruit flies indeed use vision to avoid flying over shiny surfaces. [ABSTRACT FROM AUTHOR]

Published
2023
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23. Stable flies sense and behaviorally respond to the polarization of light.

Author

Blake, Adam J., Hung, Emmanuel, To, Stephanie, Ng, Geoffrey, Qian, James, and Gries, Gerhard

Subjects
*OPTICAL polarization, *BLOODSUCKING insects, *SPECTRAL sensitivity, *FLIES, *VISUAL accommodation
Abstract

Insects use their polarization-sensitive photoreceptors in a variety of ecological contexts including host-foraging. Here, we investigated the effect of polarized light on host foraging by the blood-feeding stable fly, Stomoxys calcitrans, a pest of livestock. Electroretinogram recordings with chromatic adaptation demonstrated that the spectral sensitivity of stable flies resembles that of other calyptrate flies. Histological studies of the flies' compound eye revealed differences in microvillar arrangement of ommatidial types, assumed to be pale and yellow, with the yellow R7 and pale R8 photoreceptors having the greatest polarization sensitivity. In behavioural experiments, stable flies preferred to alight on horizontally polarized stimuli with a high degree of linear polarization. This preferential response disappeared when either ultraviolet (UV) or human-visible wavelengths were omitted from light stimuli. Removing specific wavelength bands further revealed that the combination of UV (330–400 nm) and blue (400–525 nm) wavelength bands was sufficient to enable polarized light discrimination by flies. These findings enhance our understanding of polarization vision and foraging behavior among hematophagous insects and should inform future trap designs. [ABSTRACT FROM AUTHOR]

Published
2023
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24. Image Enhancement and Concealed Object Detection Technology Based on Polarization Vision

Author

Guo, Zhenhao, Wu, Xuesong, Fan, Chen, He, Xiaofeng, Zhang, Lilian, Zhou, Wenzhou, Huang, Jing, Hu, Xiaoping, Angrisani, Leopoldo, Series Editor, Arteaga, Marco, Series Editor, Panigrahi, Bijaya Ketan, Series Editor, Chakraborty, Samarjit, Series Editor, Chen, Jiming, Series Editor, Chen, Shanben, Series Editor, Chen, Tan Kay, Series Editor, Dillmann, Rüdiger, Series Editor, Duan, Haibin, Series Editor, Ferrari, Gianluigi, Series Editor, Ferre, Manuel, Series Editor, Hirche, Sandra, Series Editor, Jabbari, Faryar, Series Editor, Jia, Limin, Series Editor, Kacprzyk, Janusz, Series Editor, Khamis, Alaa, Series Editor, Kroeger, Torsten, Series Editor, Li, Yong, Series Editor, Liang, Qilian, Series Editor, Martín, Ferran, Series Editor, Ming, Tan Cher, Series Editor, Minker, Wolfgang, Series Editor, Misra, Pradeep, Series Editor, Möller, Sebastian, Series Editor, Mukhopadhyay, Subhas, Series Editor, Ning, Cun-Zheng, Series Editor, Nishida, Toyoaki, Series Editor, Oneto, Luca, Series Editor, Pascucci, Federica, Series Editor, Qin, Yong, Series Editor, Seng, Gan Woon, Series Editor, Speidel, Joachim, Series Editor, Veiga, Germano, Series Editor, Wu, Haitao, Series Editor, Zamboni, Walter, Series Editor, Zhang, Junjie James, Series Editor, Yan, Liang, editor, and Deng, Yimin, editor

Published
2023
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25. The sky compass network in the brain of the desert locust.

Author

Homberg, Uwe, Hensgen, Ronja, Jahn, Stefanie, Pegel, Uta, Takahashi, Naomi, Zittrell, Frederick, and Pfeiffer, Keram

Subjects
*DESERT locust, *SPATIAL orientation, *BRAIN anatomy, *ARTHROPODA, *PHOTORECEPTORS
Abstract

Many arthropods and vertebrates use celestial signals such as the position of the sun during the day or stars at night as compass cues for spatial orientation. The neural network underlying sky compass coding in the brain has been studied in great detail in the desert locust Schistocerca gregaria. These insects perform long-range migrations in Northern Africa and the Middle East following seasonal changes in rainfall. Highly specialized photoreceptors in a dorsal rim area of their compound eyes are sensitive to the polarization of the sky, generated by scattered sunlight. These signals are combined with direct information on the sun position in the optic lobe and anterior optic tubercle and converge from both eyes in a midline crossing brain structure, the central complex. Here, head direction coding is achieved by a compass-like arrangement of columns signaling solar azimuth through a 360° range of space by combining direct brightness cues from the sun with polarization cues matching the polarization pattern of the sky. Other directional cues derived from wind direction and internal self-rotation input are likely integrated. Signals are transmitted as coherent steering commands to descending neurons for directional control of locomotion and flight. [ABSTRACT FROM AUTHOR]

Published
2023
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26. Polarization Vision

Author

Heinze, Stanley, Migliore, Michele, Section editor, Linster, Christiane, Section editor, Cavarretta, Francesco, Section editor, Jaeger, Dieter, editor, and Jung, Ranu, editor

Published
2022
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27. Non-celestial polarization vision in arthropods.

Author

Wernet, Mathias F., Roberts, Nicholas W., and Belušič, Gregor

Subjects
*COMPARATIVE physiology, *ARTHROPODA, *VISION, *RETINA
Abstract

Most insects can detect the pattern of polarized light in the sky with the dorsal rim area in their compound eyes and use this visual information to navigate in their environment by means of 'celestial' polarization vision. 'Non-celestial polarization vision', in contrast, refers to the ability of arthropods to analyze polarized light by means of the 'main' retina, excluding the dorsal rim area. The ability of using the main retina for polarization vision has been attracting sporadic, but steady attention during the last decade. This special issue of the Journal of Comparative Physiology A presents recent developments with a collection of seven original research articles, addressing different aspects of non-celestial polarization vision in crustaceans and insects. The contributions cover different sources of linearly polarized light in nature, the underlying retinal and neural mechanisms of object detection using polarization vision and the behavioral responses of arthropods to polarized reflections from water. [ABSTRACT FROM AUTHOR]

Published
2023
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28. Performance of polarization-sensitive neurons of the locust central complex at different degrees of polarization.

Author

Hensgen, Ronja, Zittrell, Frederick, Pfeiffer, Keram, and Homberg, Uwe

Subjects
*LOCUSTS, *NEURONS, *LIGHT scattering, *RAYLEIGH scattering, *NAUTICAL astronomy
Abstract

The polarization pattern of the sky is exploited by many insects for spatial orientation and navigation. It derives from Rayleigh scattering in the atmosphere and depends directly on the position of the sun. In the insect brain, the central complex (CX) houses neurons tuned to the angle of polarization (AoP), that together constitute an internal compass for celestial navigation. Polarized light is not only characterized by the AoP, but also by the degree of polarization (DoP), which can be highly variable, depending on sky conditions. Under a clear sky, the DoP of polarized sky light may reach up to 0.75 but is usually much lower especially when light is scattered by clouds or haze. To investigate how the polarization-processing network of the CX copes with low DoPs, we recorded intracellularly from neurons of the locust CX at different stages of processing, while stimulating with light of different DoPs. Significant responses to polarized light occurred down to DoPs of 0.05 indicating reliable coding of the AoP even at unfavorable sky conditions. Moreover, we found that the activity of neurons at the CX input stage may be strongly influenced by nearly unpolarized light, while the activity of downstream neurons appears less affected. [ABSTRACT FROM AUTHOR]

Published
2022
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29. Identification for Recycling Polyethylene Terephthalate (PET) Plastic Bottles by Polarization Vision

Author

Zhiying Tan, Zhongwen Fei, Baolai Zhao, Jian Yang, Xiaobin Xu, and Zilong Wang

Subjects
Plastic recycling, polarization vision, refractive index, Electrical engineering. Electronics. Nuclear engineering, TK1-9971
Abstract

The recycling of disposed PET plastic bottles has significant meaning for environmental pollution control and resource recycling. The reuse value heavily depends on the purity of the recycled PET. In order to improve the purity of PET recycling, a new means of material identification of PET plastic bottle based on polarization vision is proposed. To identify PET plastic bottles on conveyor belt, an effective region segmentation method for plastic bottle location and feature extraction has been put forward. The polarization of the scattered light on the surface of the object contains the information of its material. To obtain robust material characteristics of the PET plastic bottle, an approximate refractive index calculation method based on the degree of polarization and phase angle is introduced. The mean, standard deviation and coefficient of variation of the approximate refractive index and intensity distribution are used to construct the feature vector. The support vector machine (SVM) algorithm was used for PET identification. The experimental results show that the mean accuracy of PET plastic bottles material identification of recycled bottles is up to 92.06%.

Published
2021
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30. Approach trajectory and solar position affect host plant attractiveness to the small white butterfly.

Author

Blake, Adam J., Couture, Samuel, Go, Matthew C., and Gries, Gerhard

Subjects
*POLARIMETRY, *VISION, *PLANT canopies, *LIGHT sources, *PLANT species, *RESEARCH, *ANIMAL experimentation, *RESEARCH methodology, *MEDICAL cooperation, *EVALUATION research, *COMPARATIVE studies, *LEAVES, *INSECTS, *PROMPTS (Psychology)
Abstract

While it is well documented that insects exploit polarized sky light for navigation, their use of reflected polarized light for object detection has been less well studied. Recently, we have shown that the small white butterfly, Pieris rapae, distinguishes between host and non-host plants based on the degree of linear polarization (DoLP) of light reflected from their leaves. To determine how polarized light cues affect host plant foraging by female P. rapae across their entire visual range including the ultraviolet (300-650 nm), we applied photo polarimetry demonstrating large differences in the DoLP of leaf-reflected light among plant species generally and between host and non-host plants specifically. As polarized light cues are directionally dependent, we also tested, and modelled, the effect of approach trajectory on the polarization of plant-reflected light and the resulting attractiveness to P. rapae. Using photo polarimetry measurements of plants under a range of light source and observer positions, we reveal several distinct effects when polarized reflections are examined on a whole-plant basis rather than at the scale of pixels or plant canopies. Most notably from our modeling, certain approach trajectories are optimal for foraging butterflies, or insects generally, to discriminate between plant species on the basis of the DoLP of leaf-reflected light. [ABSTRACT FROM AUTHOR]

Published
2021
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31. Polarizing Natural Nanostructures

Author

Järrendahl, Kenneth, Arwin, Hans, Ertl, Gerhard, Series Editor, Lüth, Hans, Series Editor, Car, Roberto, Series Editor, Rocca, Mario Agostino, Series Editor, FREUND, HANS-JOACHIM, Series Editor, Hinrichs, Karsten, editor, and Eichhorn, Klaus-Jochen, editor

Published
2018
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32. Spatial Contrast Sensitivity to Polarization and Luminance in Octopus

Author

Luis Nahmad-Rohen and Misha Vorobyev

Subjects
octopus vision, octopus behavior, polarization vision, contrast sensitivity, polarization sensitivity, chromatic vision, Physiology, QP1-981
Abstract

While color vision is achieved by comparison of signals of photoreceptors tuned to different parts of light spectra, polarization vision is achieved by comparison of signals of photoreceptors tuned to different orientations of the electric field component of visible light. Therefore, it has been suggested that polarization vision is similar to color vision. In most animals that have color vision, the shape of luminance contrast sensitivity curve differs from the shape of chromatic contrast sensitivity curve. While luminance contrast sensitivity typically decreases at low spatial frequency due to lateral inhibition, chromatic contrast sensitivity generally remains high at low spatial frequency. To find out if the processing of polarization signals is similar to the processing of chromatic signals, we measured the polarization and luminance contrast sensitivity dependence in a color-blind animal with well-developed polarization vision, Octopus tetricus. We demonstrate that, in Octopus tetricus, both luminance and polarization contrast sensitivity decrease at low spatial frequency and peak at the same spatial frequency (0.3 cpd). These results suggest that, in octopus, polarization and luminance signals are processed via similar pathways.

Published
2020
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33. Horsefly reactions to black surfaces: attractiveness to male and female tabanids versus surface tilt angle and temperature.

Author

Horváth, Gábor, Pereszlényi, Ádám, Egri, Ádám, Fritz, Benjamin, Guttmann, Markus, Lemmer, Uli, Gomard, Guillaume, and Kriska, György

Subjects
*HORSEFLIES, *AQUATIC insects, *SOLAR cells, *SURFACE reactions, *LIGHT pollution, *INSECT eggs
Abstract

Tabanid flies (Diptera: Tabanidae) are attracted to shiny black targets, prefer warmer hosts against colder ones and generally attack them in sunshine. Horizontally polarised light reflected from surfaces means water for water-seeking male and female tabanids. A shiny black target above the ground, reflecting light with high degrees and various directions of linear polarisation is recognised as a host animal by female tabanids seeking for blood. Since the body of host animals has differently oriented surface parts, the following question arises: How does the attractiveness of a tilted shiny black surface to male and female tabanids depend on the tilt angle δ? Another question relates to the reaction of horseflies to horizontal black test surfaces with respect to their surface temperature. Solar panels, for example, can induce horizontally polarised light and can reach temperatures above 55 °C. How long times would horseflies stay on such hot solar panels? The answer of these questions is important not only in tabanid control, but also in the reduction of polarised light pollution caused by solar panels. To study these questions, we performed field experiments in Hungary in the summer of 2019 with horseflies and black sticky and dry test surfaces. We found that the total number of trapped (male and female) tabanids is highest if the surface is horizontal (δ = 0°), and it is minimal at δ = 75°. The number of trapped males decreases monotonously to zero with increasing δ, while the female catch has a primary maximum and minimum at δ = 0° and δ = 75°, respectively, and a further secondary peak at δ = 90°. Both sexes are strongly attracted to nearly horizontal (0° ≤ δ ≤ 15°) surfaces, and the vertical surface is also very attractive but only for females. The numbers of touchdowns and landings of tabanids are practically independent of the surface temperature T. The time period of tabanids spent on the shiny black horizontal surface decreases with increasing T so that above 58 °C tabanids spent no longer than 1 s on the surface. The horizontally polarised light reflected from solar panels attracts aquatic insects. This attraction is adverse, if the lured insects lay their eggs onto the black surface and/or cannot escape from the polarised signal and perish due to dehydration. Using polarotactic horseflies as indicator insects in our field experiment, we determined the magnitude of polarised light pollution (being proportional to the visual attractiveness to tabanids) of smooth black oblique surfaces as functions of δ and T. [ABSTRACT FROM AUTHOR]

Published
2020
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34. Cellular and synaptic adaptations of neural circuits processing skylight polarization in the fly.

Author

Sancer, Gizem, Kind, Emil, Uhlhorn, Juliane, Volkmann, Julia, Hammacher, Johannes, Pham, Tuyen, Plazaola-Sasieta, Haritz, and Wernet, Mathias F.

Subjects
*NEUROPLASTICITY, *NEURAL circuitry, *DROSOPHILA melanogaster, *FLIES, *PHOTORECEPTORS
Abstract

Specialized ommatidia harboring polarization-sensitive photoreceptors exist in the 'dorsal rim area' (DRA) of virtually all insects. Although downstream elements have been described both anatomically and physiologically throughout the optic lobes and the central brain of different species, little is known about their cellular and synaptic adaptations and how these shape their functional role in polarization vision. We have previously shown that in the DRA of Drosophila melanogaster, two distinct types of modality-specific 'distal medulla' cell types (Dm-DRA1 and Dm-DRA2) are post-synaptic to long visual fiber photoreceptors R7 and R8, respectively. Here we describe additional neuronal elements in the medulla neuropil that manifest modality-specific differences in the DRA region, including DRA-specific neuronal morphology, as well as differences in the structure of pre- or post-synaptic membranes. Furthermore, we show that certain cell types (medulla tangential cells and octopaminergic neuromodulatory cells) specifically avoid contacts with polarization-sensitive photoreceptors. Finally, while certain transmedullary cells are specifically absent from DRA medulla columns, other subtypes show specific wiring differences while still connecting the DRA to the lobula complex, as has previously been described in larger insects. This hints towards a complex circuit architecture with more than one pathway connecting polarization-sensitive DRA photoreceptors with the central brain. [ABSTRACT FROM AUTHOR]

Published
2020
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35. Light pollution and navigation in two nocturnal arthropod taxa

Author

Meah, Rochelle J and Meah, Rochelle J

Abstract

Artificial light at night is a major anthropogenic pollutant. The area of artificially lit land is increasing at approximately 2% per year globally, and almost 90% of Europe is now affected by increased night sky luminance. The intensity, spectral composition, and timing of light pollution all affect different aspects of the physiology and behaviour of individual organisms. Ultimately, these changes can alter community structures and the ecology of different ecosystems. Among nocturnal arthropods, research on the impacts of light pollution has largely focused on community-level effects or broader behavioural ecology. The effects of artificial light masking visual cues used in task-specific behaviours have received relatively little attention and there are indications that light pollution might obscure a major nocturnal cue, the skylight polarization pattern, but this has never been studied in any detail. Similarly, how light pollution might affect the timing of these behaviours is also under-studied. This PhD investigates how artificial light at night masks the skylight polarization pattern and how the loss of this cue, and the spectral composition and intensity of the artificial light, behaviourally impacts both nocturnal central-place foraging spiders of the genus Drassodes, and a long-distance migratory moth, Helicoverpa armigera. The major differences in the polarization pattern between dark and light-polluted skies across four moon phases and across a light pollution radiance gradient were established using imaging polarimetry. The ecological impact of the masking effect of light pollution to polarization-guided navigation was assessed using analysis of the tethered paths of animals exposed to polarized stimuli. Finally, the ecological impact of light pollution on the initiation and timing of nocturnal journeys was examined by observing patterns of activity under streetlights of different intensities and spectral compositions. The skylight polarization

Published
2023

36. Attractiveness of thermally different, uniformly black targets to horseflies: Tabanus tergestinus prefers sunlit warm shiny dark targets

Author

Gábor Horváth, Ádám Pereszlényi, Tímea Tóth, Szabolcs Polgár, and Imre M. Jánosi

Subjects
horsefly, host choice, blood-seeking, thermoreception, polarization vision, parasite–host interaction, Science
Abstract

From a large distance tabanid flies may find their host animal by means of its shape, size, motion, odour, radiance and degree of polarization of host-reflected light. After alighting on the host, tabanids may use their mechano-, thermo-, hygro- and chemoreceptors to sense the substrate characteristics. Female tabanids prefer to attack sunlit against shady dark host animals, or dark against bright hosts for a blood meal, the exact reasons for which are unknown. Since sunlit darker surfaces are warmer than shady ones or sunlit/shady brighter surfaces, the differences in surface temperatures of dark and bright as well as sunlit and shady hosts may partly explain their different attractiveness to tabanids. We tested this observed warmth preference in field experiments, where we compared the attractiveness to tabanids (Tabanus tergestinus) of a warm and a cold shiny black barrel imitating dark hosts with the same optical characteristics. Using imaging polarimetry, thermography and Schlieren imaging, we measured the optical and thermal characteristics of both barrels and their small-scale models. We recorded the number of landings on these targets and measured the time periods spent on them. Our study revealed that T. tergestinus tabanid flies prefer sunlit warm shiny black targets against sunlit or shady cold ones with the same optical characteristics. These results support our new hypothesis that a blood-seeking female tabanid prefers elevated temperatures, partly because her wing muscles are more rapid and her nervous system functions better (due to faster conduction velocities and synaptic transmission of signals) in a warmer microclimate, and thus, she can avoid the parasite-repelling reactions of host animals by a prompt take-off.

Published
2019
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39. Polarization of foliar reflectance: novel host plant cue for insect herbivores.

Author

Blake, Adam J., Go, Matthew C., Hahn, Gina S., Grey, Hayley, Couture, Samuel, and Gries, Gerhard

Subjects
*CHEMICAL plants, *INSECT host plants, *REFLECTANCE, *HERBIVORES, *LINEAR polarization, *HOST plants, *BUTTERFLIES, *DIGITAL images
Abstract

Insect herbivores exploit plant cues to discern host and non-host plants. Studies of visual plant cues have focused on colour despite the inherent polarization sensitivity of insect photoreceptors and the information carried by polarization of foliar reflectance, most notably the degree of linear polarization (DoLP; 0–100%). The DoLP of foliar reflection was hypothesized to be a host plant cue for insects but was never experimentally tested. Here, we show that cabbage white butterflies, Pieris rapae (Pieridae), exploit the DoLP of foliar reflections to discriminate among plants. In experiments with paired digital plant images, P. rapae females preferred images of the host plant cabbage with a low DoLP (31%) characteristic of cabbage foliage over images of a non-host potato plant with a higher DoLP (50%). By reversing the DoLP of these images, we were able to shift the butterflies' preference for the cabbage host plant image to the potato non-host plant image, indicating that the DoLP had a greater effect on foraging decisions than the differential colour, intensity, or shape of the two plant images. Although previously not recognized, the DoLP of foliar reflection is an essential plant cue that may commonly be exploited by foraging insect herbivores. [ABSTRACT FROM AUTHOR]

Published
2019
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40. Horsefly object-directed polarotaxis is mediated by a stochastically distributed ommatidial subtype in the ventral retina.

Author

Meglič, Andrej, Ilić, Marko, Pirih, Primož, Škorjanc, Aleš, Wehling, Martin F., Kreft, Marko, and Belušič, Gregor

Subjects
*HORSEFLIES, *RETINA, *SPECTRAL sensitivity, *PHOTORECEPTORS, *DIVISION of labor
Abstract

The ventral compound eye of many insects contains polarization-sensitive photoreceptors, but little is known about how they are integrated into visual functions. In female horseflies, polarized reflections from animal fur are a key stimulus for host detection. To understand how polarization vision is mediated by the ventral compound eye, we investigated the band-eyed brown horsefly Tabanus bromius using anatomical, physiological, and behavioral approaches. Serial electron microscopic sectioning of the retina and single-cell recordings were used to determine the spectral and polarization sensitivity (PS) of photoreceptors. We found 2 stochastically distributed subtypes of ommatidia, analogous to pale and yellow of other flies. Importantly, the pale analog contains an orthogonal analyzer receptor pair with high PS, formed by an ultraviolet (UV)-sensitive R7 and a UV- and blue-sensitive R8, while the UV-sensitive R7 and green-sensitive R8 in the yellow analog always have low PS. We tested horsefly polarotaxis in the field, using lures with controlled spectral and polarization composition. Polarized reflections without UV and blue components rendered the lures unattractive, while reflections without the green component increased their attractiveness. This is consistent with polarotaxis being guided by a differential signal from polarization analyzers in the pale analogs, and with an inhibitory role of the yellow analogs. Our results reveal how stochastically distributed sensory units with modality-specific division of labor serve as separate and opposing input channels for visual guidance. [ABSTRACT FROM AUTHOR]

Published
2019
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41. How does the water springtail optically locate suitable habitats? Spectral sensitivity of phototaxis and polarotaxis in Podura aquatica.

Author

Egri, Ádám and Kriska, György

Subjects
*COLLEMBOLA, *POLARIZATION of photon beams, *PHOTOTAXIS, *POLAROGRAPHY, *ECOLOGY
Abstract

Optical detection of horizontally polarized light is widespread among aquatic insects. This process usually occurs in the UVor blue spectral ranges. Recently, it was demonstrated that at least one collembolan species, the water springtail (Podura aquatica) also possesses positive polarotaxis to horizontally polarized light. These hexapods are positively phototactic, live on the surface of calm waters and usually accumulate close to the riparian vegetation. In laboratory experiments, we measured the wavelength dependence of phototaxis and polarotaxis of P. aquatica in the 346-744 nm and 421-744 nm ranges, respectively. According to our results, the action spectrum of phototaxis is bimodal with two peaks in the blue (ë1=484 nm) and green-yellow (ë2=570 nm) ranges, while polarotaxis operates in the blue spectral range. For the first time, we show that collembolan polarotaxis functions in the same spectral range as the polarotaxis of many aquatic insects.We present our experiments and discuss the possible ecological significance of our findings. [ABSTRACT FROM AUTHOR]

Published
2019
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42. Two Compasses in the Central Complex of the Locust Brain.

Author

Pegel, Uta, Pfeiffer, Keram, Zittrell, Frederick, Scholtyssek, Christine, and Homberg, Uwe

Subjects
*DESERT locust, *LOCUSTS, *BLUE light, *BRAIN
Abstract

Many migratory insects rely on a celestial compass for spatial orientation. Several features of the daytime sky, all generated by the sun, can be exploited for navigation. Two of these are the position of the sun and the pattern of polarized skylight. Neurons of the central complex (CX), a group of neuropils in the central brain of insects, have been shown to encode sky compass cues. In desert locusts, the CX holds a topographic, compass-like representation of the plane of polarized light (E-vector) presented from dorsal direction. In addition, these neurons also encode the azimuth of an unpolarized light spot, likely representing the sun. Here, we investigate whether, in addition to E-vector orientation, the solar azimuth is represented topographically in the CX. We recorded intracellularly from eight types of CX neuron while stimulating animals of either sex with polarized blue light from zenithal direction and an unpolarized green light spot rotating around the animal's head at different elevations. CX neurons did not code for elevation of the unpolarized light spot. However, two types of columnar neuron showed a linear correlation between innervated slice in the CX and azimuth tuning to the unpolarized green light spot, consistent with an internal compass representation of solar azimuth. Columnar outputs of the CX also showed a topographic representation of zenithal E-vector orientation, but the two compasses were not linked to each other. Combined stimulation with unpolarized green and polarized blue light suggested that the two compasses interact in a nonlinear way. [ABSTRACT FROM AUTHOR]

Published
2019
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45. The Fly Sensitizing Pigment Enhances UV Spectral Sensitivity While Preventing Polarization-Induced Artifacts

Author

Marko Ilić, Andrej Meglič, Marko Kreft, and Gregor Belušič

Subjects
polarization vision, sensitizing pigment, Drosophila, microvilli, rhabdomere, polarimetry, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571
Abstract

Microvillar photoreceptors are intrinsically capable of detecting the orientation of e-vector of linearly polarized light. They provide most invertebrates with an additional sensory channel to detect important features of their visual environment. However, polarization sensitivity (PS) of photoreceptors may lead to the detection of polarization-induced false colors and intensity contrasts. Most insect photoreceptors are thus adapted to have minimal PS. Flies have twisted rhabdomeres with microvilli rotated along the length of the ommatidia to reduce PS. The additional UV-absorbing sensitizing pigment on their opsin minimizes PS in the ultraviolet. We recorded voltage from Drosophila photoreceptors R1–6 to measure the spectral dependence of PS and found that PS in the UV is invariably negligible but can be substantial above 400 nm. Using modeling, we demonstrate that in R1–6 without the sensitizing pigment, PS in the UV (PSUV) would exceed PS in the visible part of the spectrum (PSVIS) by a factor PSUV/PSVIS = 1.2–1.8, as lower absorption of Rh1 rhodopsin reduces self-screening. We use polarimetric imaging of objects relevant to fly polarization vision to show that their degree of polarization outdoors is highest in the short-wavelength part of the spectrum. Thus, under natural illumination, the sensitizing pigment in R1–6 renders even those cells with high PS in the visible part unsuitable for proper polarization vision. We assume that fly ventral polarization vision can be mediated by R7 alone, with R1–6 serving as an unpolarized reference channel.

Published
2018
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46. NThe Fly Sensitizing Pigment Enhances UV Spectral Sensitivity While Preventing Polarization-Induced Artifacts.

Author

Ilić, Marko, Meglič, Andrej, Kreft, Marko, and Belušič, Gregor

Subjects
PHOTORECEPTORS, DROSOPHILA, POLARIZATION (Electricity), POLARIMETRY, RHABDOM
Abstract

Microvillar photoreceptors are intrinsically capable of detecting the orientation of e-vector of linearly polarized light. They provide most invertebrates with an additional sensory channel to detect important features of their visual environment. However, polarization sensitivity (PS) of photoreceptors may lead to the detection of polarizationinduced false colors and intensity contrasts. Most insect photoreceptors are thus adapted to have minimal PS. Flies have twisted rhabdomeres with microvilli rotated along the length of the ommatidia to reduce PS. The additional UV-absorbing sensitizing pigment on their opsin minimizes PS in the ultraviolet. We recorded voltage from Drosophila photoreceptors R1-6 to measure the spectral dependence of PS and found that PS in the UV is invariably negligible but can be substantial above 400 nm. Using modeling, we demonstrate that in R1-6 without the sensitizing pigment, PS in the UV (PSV/S would exceed PS in the visible part of the spectrum (PSVIS) by a factor PSUV/PSVIS = 1.2-1.8, as lower absorption of Rh1 rhodopsin reduces self-screening. We use polarimetric imaging of objects relevant to fly polarization vision to show that their degree of polarization outdoors is highest in the short-wavelength part of the spectrum. Thus, under natural illumination, the sensitizing pigment in R1-6 renders even those cells with high PS in the visible part unsuitable for proper polarization vision. We assume that fly ventral polarization vision can be mediated by R7 alone, with R1-6 serving as an unpolarized reference channel. [ABSTRACT FROM AUTHOR]

Published
2018
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48. Circularly polarized light detection in stomatopod crustaceans: a comparison of photoreceptors and possible function in six species.

Author

Templin, Rachel M., How, Martin J., Roberts, Nicholas W., Tsyr-Huei Chiou, and Marshall, Justin

Subjects
*STOMATOPODA, *VISION, *PHOTODETECTORS, *PHOTORECEPTORS, *OPTICAL polarization, *PHYSIOLOGY
Abstract

A combination of behavioural and electrophysiological experiments have previously shown that two species of stomatopod, Odontodactylus scyllarus and Gonodactylaceus falcatus, can differentiate between left- and right-handed circularly polarized light (CPL), and between CPL and linearly polarized light (LPL). It remains unknown if these visual abilities are common across all stomatopod species, and if so, how circular polarization sensitivity may vary between and within species. A subsection of the midband, a specialized region of stomatopod eyes, contains distally placed photoreceptor cells, termed R8 (retinular cell number 8). These cells are specifically built with unidirectional microvilli and appear to be angled precisely to convert CPL into LPL. They are mostly quarter-wave retarders for human visible light (400-700 nm), as well as being ultraviolet-sensitive linear polarization detectors. The effectiveness of the R8 cells in this role is determined by their geometric and optical properties. In particular, the length and birefringence of the R8 cells are crucial for retardation efficiency. Here, our comparative studies show that most species investigated have the theoretical ability to convert CPL into LPL, such that the handedness of an incoming circular reflection or signal could be discriminated. One species, Haptosquilla trispinosa, shows less than quarter-wave retardance. Whilst some species are known to produce circularly polarized reflections (some Odontodactylus species and G. falcatus, for example), others do not, so a variety of functions for this ability are worth considering. [ABSTRACT FROM AUTHOR]

Published
2017
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49. Regional differences in the preferred e-vector orientation of honeybee ocellar photoreceptors.

Author

Yuri Ogawa, Ribi, Willi, Zeil, Jochen, and Hemmi, Jan M.

Subjects
*HONEYBEES, *PHOTORECEPTORS, *WORKER honeybees, *ELECTROPHYSIOLOGY, *CELL receptors
Abstract

In addition to compound eyes, honeybees (Apis mellifera) possess three single-lens eyes called ocelli located on the top of the head. Ocelli are involved in head-attitude control and in some insects have been shown to provide celestial compass information. Anatomical and early electrophysiological studies have suggested that UV and blue-green photoreceptors in ocelli are polarization sensitive. However, their retinal distribution and receptor characteristics have not been documented. Here, we used intracellular electrophysiology to determine the relationship between the spectral and polarization sensitivity of the photoreceptors and their position within the visual field of the ocelli. We first determined a photoreceptor's spectral response through a series of monochromatic flashes (340-600 nm). We found UV and green receptors, with peak sensitivities at 360 and 500 nm, respectively. We subsequently measured polarization sensitivity at the photoreceptor's peak sensitivity wavelength by rotating a polarizer with monochromatic flashes. Polarization sensitivity (PS) values were significantly higher in UV receptors (3.8± 1.5, N=61) than in green receptors (2.1±0.6, N=60). Interestingly, most receptors with receptive fields below 35 deg elevation were sensitive to vertically polarized light while the receptors with visual fields above 35 deg were sensitive to a wide range of polarization angles. These results agree well with anatomical measurements showing differences in rhabdom orientations between dorsal and ventral retinae. We discuss the functional significance of the distribution of polarization sensitivities across the visual field of ocelli by highlighting the information the ocelli are able to extract from the bee's visual environment. [ABSTRACT FROM AUTHOR]

Published
2017
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50. Bionic Orientation and Visual Enhancement With a Novel Polarization Camera.

Author

Wang, Yujie, Hu, Xiaoping, Lian, Junxiang, Zhang, Lilian, and He, Xiaofeng

Abstract

The remarkable polarization vision of animals provides a significant inspiration for robotic navigation and visual enhancement, as polarization pattern provides additional information besides spectral signatures. A novel bio-inspired polarization camera is proposed in this paper, which can realize real-time image-based polarization measurement. The composition of the system is described and the optimal estimation of the polarization state is derived based on the least square algorithm. This paper concentrates particularly on the camera orientation algorithms and visual enhancement methods with it. To estimate the camera’s heading angle with the skylight polarization pattern, the sun vector is established as an optimization problem of finding the minimum eigenvector. The solar meridian is also estimated from the degree of polarization pattern by detecting reflectional symmetry axes. The result shows that the measured polarization patterns are very close to the theory. The maximum orientation error of the proposed method based on angle of polarization is about 0.5°. The average error is 0.012° with standard deviation of 0.28°. Thus, the novel polarization camera could be used as sun compass. When observing scenes in distance, the polarization camera is used to decouple the airlight from the object radiance, which results in much better contrast. More importantly, the polarization information is helpful for scene identification and object detection. The result also shows that the polarization camera can reasonably cope with the semi-reflection problem. [ABSTRACT FROM PUBLISHER]

Published
2017
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