Null point of discrimination in crustacean polarisation vision

How, Martin J.; Christy, John H.; Roberts, Nicholas W.; Marshall, N. Justin

doi:10.1242/jeb.103457

Cited by 24 publications

(24 citation statements)

References 46 publications

(62 reference statements)

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“…Stimulus detection was strongly impaired when the e-vectors of stimulus and background were at +45 deg and −45 deg to the horizon, respectively, which agrees with an expected null point of discrimination of a horizontal/vertical 2D system (Bernard and Wehner, 1977; How et al, 2014). The stomatopods also tested in that study for comparison (How et al, 2014) did not exhibit a null point, which is not unexpected considering their various separate and differently oriented 2D systems (Box 1). Alternatively, they could have used a successive approach based on eye stalk rotation (Daly et al, 2016; Land et al, 1990).…”

Section: Searching For Evidence Of E-vector Perceptionsupporting

confidence: 75%

“…But most behavioral observations can be explained by the mere presence of polarization-sensitive photoreceptors without opponent signal interactions (Fig. 4C), at least qualitatively (crabs: How et al, 2012, 2014; cephalopods: Moody and Parriss, 1961; Pignatelli et al, 2011; Shashar and Cronin, 1996; Shashar et al, 1996; Temple et al, 2012). This is because even 1D polarization vision with a retina containing just one polarization-sensitive e-vector type of photoreceptor (e.g.…”

Section: Taking Stock Of Invertebrate Polarization Visionmentioning

confidence: 99%

“…Like cuttlefish, fiddler crabs respond to looming polarized stimuli with e-vector contrasts of just 3.2 deg to the background, in the absence of luminance contrast (How et al, 2012). Looming polarized stimuli were also used to test whether the responses of fiddler crabs were compatible with a 2D system of polarization vision (How et al, 2014). In that study, stimulus and background had the same e-vector but differed in degree.…”

Section: Searching For Evidence Of E-vector Perceptionmentioning

confidence: 99%

“…The general occurrence of 2D input stages suggests that true polarization vision may be quite frequent in object-based polarization vision. However, it cannot be excluded that polarization and luminance images are combined at some level in the brain (How et al, 2014), confounding true polarization vision again.…”

Section: Taking Stock Of Invertebrate Polarization Visionmentioning

confidence: 99%

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Can invertebrates see the e-vector of polarization as a separate modality of light?

Labhart

2016

Journal of Experimental Biology

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The visual world is rich in linearly polarized light stimuli, which are hidden from the human eye. But many invertebrate species make use of polarized light as a source of valuable visual information. However, exploiting light polarization does not necessarily imply that the electric (e)-vector orientation of polarized light can be perceived as a separate modality of light. In this Review, I address the question of whether invertebrates can detect specific e-vector orientations in a manner similar to that of humans perceiving spectral stimuli as specific hues. To analyze e-vector orientation, the signals of at least three polarization-sensitive sensors (analyzer channels) with different e-vector tuning axes must be compared. The object-based, imaging polarization vision systems of cephalopods and crustaceans, as well as the water-surface detectors of flying backswimmers, use just two analyzer channels. Although this excludes the perception of specific e-vector orientations, a two-channel system does provide a coarse, categoric analysis of polarized light stimuli, comparable to the limited color sense of dichromatic, ‘color-blind’ humans. The celestial compass of insects employs three or more analyzer channels. However, that compass is multimodal, i.e. e-vector information merges with directional information from other celestial cues, such as the solar azimuth and the spectral gradient in the sky, masking e-vector information. It seems that invertebrate organisms take no interest in the polarization details of visual stimuli, but polarization vision grants more practical benefits, such as improved object detection and visual communication for cephalopods and crustaceans, compass readings to traveling insects, or the alert ‘water below!’ to water-seeking bugs.

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Section: Searching For Evidence Of E-vector Perceptionsupporting

confidence: 75%

Section: Taking Stock Of Invertebrate Polarization Visionmentioning

confidence: 99%

Section: Searching For Evidence Of E-vector Perceptionmentioning

confidence: 99%

Section: Taking Stock Of Invertebrate Polarization Visionmentioning

confidence: 99%

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Can invertebrates see the e-vector of polarization as a separate modality of light?

Labhart

2016

Journal of Experimental Biology

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“…Behavioural studies carried out by How et al (2014aHow et al ( , 2014b on the stomatopods ability to discriminate different angles of polarised light indicate that their polarization vision may also function on similar simplified principles.…”

Section: Chapter 7 Summary and Future Directionsmentioning

confidence: 99%

Colour vision in mantis shrimps: understanding one of the most complex visual systems in the world

Thoen¹

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Stomatopods (commonly known as mantis shrimps) have one of the most complex visual systems in the animal kingdom with up to 20 different photoreceptor types and the ability to see both linear and circular polarized light. The eye of a stomatopod is divided into three different parts; a dorsal and a ventral hemisphere divided up by 6 distinct rows of specialised ommatidia (visual units) termed the midband. The midband contains a complex array of up to 12 spectral receptors with maximum sensitivities ranging from the ultraviolet (UV) to the far-red (300-700 nm), in addition to achromatic receptors of which several are sensitive to different forms of polarized light. The abundance of spectral receptors has puzzled researchers, as it seemed excessive even for an animal living in a spectrally rich environment such as the coral reef. Furthermore, theoretical analyses suggest that there is really no need to have more than 4-7 receptors to have satisfactory colour vision in the 300-400 nm spectral range. Our increasing knowledge of polarization sensitivity is rapidly expanding the theme of photoreceptor proliferation with up to six channels of polarization information from a combination of midband and hemisphere receptors.The aim of this thesis was to investigate how stomatopods process and analyse chromatic and polarization information using a complementary approach of behavioural, electrophysiological and neuroanatomical techniques. A comparison of spectral sensitivities across species in the superfamily Gonodactyloidea was carried out in Chapter 2. This study showed that their spectral sensitivities remain very similar between species, with narrow, steeply shaped sensitivity curves spread evenly throughout the spectrum, suggesting there is a benefit of having uniform sampling of all wavelengths. Behavioural experiments were performed to test stomatopod spectral discrimination in Chapter 3, and this was found to be surprisingly poor, both compared to other animals and to theoretical modelling. To investigate if the poor discrimination was due to the spectral shape of the stimuli, more natural-shaped stimuli (with step-shaped spectra instead of the conventional peakshaped spectra) were tested in similar experiments (Chapter 4). However, these experiments yielded similar results to the ones obtained in Chapter 3. The electrophysiological and behavioural results suggest that the stomatopod visual system may use a simpler, serial processing system unlike the "conventional" opponency system known from other animals and may be the reason for why the spectral and polarization space must be covered by several channels.While such as system may appear exceptional, there are similarities between this system and they way primates process colour, only at different steps in the processing pathway (Chapter 5). Using an interval-decoding scheme coupled with the narrow, binned spectral sensitivities of stomatopods could allow quick and precise colour judgements but at the cost of very fine discrimination. 3As very little wa...

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Polarisation vision: overcoming challenges of working with a property of light we barely see

Foster

Temple

How

et al. 2018

Sci Nat

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In recent years, the study of polarisation vision in animals has seen numerous breakthroughs, not just in terms of what is known about the function of this sensory ability, but also in the experimental methods by which polarisation can be controlled, presented and measured. Once thought to be limited to only a few animal species, polarisation sensitivity is now known to be widespread across many taxonomic groups, and advances in experimental techniques are, in part, responsible for these discoveries. Nevertheless, its study remains challenging, perhaps because of our own poor sensitivity to the polarisation of light, but equally as a result of the slow spread of new practices and methodological innovations within the field. In this review, we introduce the most important steps in designing and calibrating polarised stimuli, within the broader context of areas of current research and the applications of new techniques to key questions. Our aim is to provide a constructive guide to help researchers, particularly those with no background in the physics of polarisation, to design robust experiments that are free from confounding factors.

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Null point of discrimination in crustacean polarisation vision

Cited by 24 publications

References 46 publications

Can invertebrates see the e-vector of polarization as a separate modality of light?

Can invertebrates see the e-vector of polarization as a separate modality of light?

Colour vision in mantis shrimps: understanding one of the most complex visual systems in the world

Polarisation vision: overcoming challenges of working with a property of light we barely see

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