Neural encoding of behaviourally relevant visual-motion information in the fly

Egelhaaf, Martin; Kern, Roland; Krapp, Holger G.; Kretzberg, Jutta; Kurtz, Rafael; Warzecha, Anne Kathrin

doi:10.1016/s0166-2236(02)02063-5

Cited by 149 publications

(110 citation statements)

References 76 publications

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“…This aftereffect, the waterfall illusion, is not unique to humans: elegant behavioural work has shown that it is also experienced by flies (Götz & Wenking 1973;Srinivasan & Dvorak 1979), indicating that motion adaptation is also relevant to these animals (Clifford & Langley 1996). In flies, the physiological counterpart of this phenomenon can be found in motion-sensitive neurons in the third visual neuropile (lobula plate), most of which sum motion signals across large areas of visual space (Hausen 1984;Krapp & Hengstenberg 1996;Egelhaaf et al 2002). Similarly to macaque MT neurons (Kohn & Movshon 2003, these cells adapt their response characteristics to prolonged stimulation (Srinivasan & Dvorak 1979;Maddess & Laughlin 1985;de Ruyter van Steveninck et al 1986;Fairhall et al 2001).…”

Section: Introductionmentioning

confidence: 99%

Global versus local adaptation in fly motion-sensitive neurons

Neri

Laughlin

2005

Proc. R. Soc. B.

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Flies, like humans, experience a well-known consequence of adaptation to visual motion, the waterfall illusion. Direction-selective neurons in the fly lobula plate permit a detailed analysis of the mechanisms responsible for motion adaptation and their function. Most of these neurons are spatially non-opponent, they sum responses to motion in the preferred direction across their entire receptive field, and adaptation depresses responses by subtraction and by reducing contrast gain. When we adapted a small area of the receptive field to motion in its anti-preferred direction, we discovered that directional gain at unadapted regions was enhanced. This novel phenomenon shows that neuronal responses to the direction of stimulation in one area of the receptive field are dynamically adjusted to the history of stimulation both within and outside that area.

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Section: Introductionmentioning

confidence: 99%

Global versus local adaptation in fly motion-sensitive neurons

Neri

Laughlin

2005

Proc. R. Soc. B.

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“…We observed the same inseparabilities in the UV STRFs of L-neurons. This type of directional computation is distinct from that seen in fully opponent directionally selective cells, like lobula plate tangential cells in flies (Hausen, 1982a,b;Single et al, 1997;Borst and Haag, 2002;Egelhaaf et al, 2002) or complex cells in the mammalian visual cortex (Emerson et al, 1992) that encode directionality in the mean of the response.…”

Section: Discussionmentioning

confidence: 90%

Directional Selectivity in the Simple Eye of an Insect

Kleef¹,

Berry²,

Stange³

2008

J. Neurosci.

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Among other sensory modalities, flight stabilization in insects is performed with the aid of visual feedback from three simple eyes (ocelli). It is thought that each ocellus acts as a single wide-field sensor that detects changes in light intensity. We challenge this notion by providing evidence that, when light-adapted, the large retinal L-neurons in the median ocellus of the dragonfly respond in a directional way to upward moving bars and gratings. This ability is pronounced under UV illumination but weak or nonexistent in green light and is optimal at angular velocities of ϳ750°s Ϫ1 . Using a reverse-correlation technique, we analyze the functional organization of the receptive fields of the L-neurons. Our results reveal that L-neurons alter the structure of their linear spatiotemporal receptive fields with changes in the illuminating wavelength, becoming more inseparable and directional in UV light than in green. For moving bars and gratings, the strength of directionality predicted from the receptive fields is consistent with the measured values. Our results strongly suggest that, during the day, the retinal circuitry of the dragonfly median ocellus performs an early linear stage of motion processing. The likely advantage of this computation is to enhance pitch control.

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“…A matched filter is a concept in neuroethology and describes the spatial layout of some population of receptors that is matched to a certain aspect of the task (Wehner 1987). For example, preferred directions for arrays of elementary motion detectors seem to corre- spond to flow fields induced by particular movements of flies, e.g., by roll movements (Egelhaaf et al 2002;Krapp 2000;Franz and Krapp 2000;Franz et al 2004). Our matched filters have the typical structure of flow fields for pure translations in the horizontal plane: a focus of expansion, a focus of contraction, and nearly horizontal flow between them (Fig.…”

Section: Homing With Two Flow Templatesmentioning

confidence: 99%

Local visual homing by matched-filter descent in image distances

Möller

Vardy

2006

Biol Cybern

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In natural images, the distance measure between two images taken at different locations rises smoothly with increasing distance between the locations. This fact can be exploited for local visual homing where the task is to reach a goal location that is characterized by a snapshot image: descending in the image distance will lead the agent to the goal location. To compute an estimate of the spatial gradient in the distance measure, its value must be sampled at three noncollinear points. An animal or robot would have to insert exploratory movements into its home trajectory to collect these samples. Here we suggest a method based on the matched-filter concept that allows one to estimate the gradient without exploratory movements. Two matched filters -optical flow fields resulting from translatory movements in the horizontal plane -are used to predict two images in perpendicular directions from the current location. We investigate the relation to differential flow methods applied to the local homing problem and show that the matched-filter approach produces reliable homing behavior on image databases. Two alternative methods that only require a single matched filter are suggested. The matched-filter concept is also applied to derive a home-vector equation for a Fourier-based parameter method.

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Neural encoding of behaviourally relevant visual-motion information in the fly

Cited by 149 publications

References 76 publications

Global versus local adaptation in fly motion-sensitive neurons

Global versus local adaptation in fly motion-sensitive neurons

Directional Selectivity in the Simple Eye of an Insect

Local visual homing by matched-filter descent in image distances

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