Contextual Effects of Scene on the Visual Perception of Object Orientation in Depth

We investigated the effect of background scene on the human visual perception of depth orientation (i.e., azimuth angle) of three-dimensional common objects. Participants evaluated the depth orientation of objects. The objects were surrounded by scenes with an apparent axis of the global reference frame, such as a sidewalk scene. When a scene axis was slightly misaligned with the gaze line, object orientation perception was biased, as if the gaze line had been assimilated into the scene axis (Experiment 1). When the scene axis was slightly misaligned with the object, evaluated object orientation was biased, as if it had been assimilated into the scene axis (Experiment 2). This assimilation may be due to confusion between the orientation of the scene and object axes (Experiment 3). Thus, the global reference frame may influence object orientation perception when its orientation is similar to that of the gaze-line or object.     

Grasping preparation enhances orientation change detection

Preparing a goal directed movement often requires detailed analysis of our environment. When picking up an object, its orientation, size and relative distance are relevant parameters when preparing a successful grasp. It would therefore be beneficial if the motor system is able to influence early perception such that information processing needs for action control are met at the earliest possible stage. However, only a few studies reported (indirect) evidence for action-induced visual perception improvements. We therefore aimed to provide direct evidence for a feature-specific perceptual modulation during the planning phase of a grasping action. Human subjects were instructed to either grasp or point to a bar while simultaneously performing an orientation discrimination task. The bar could slightly change its orientation during grasping preparation. By analyzing discrimination response probabilities, we found increased perceptual sensitivity to orientation changes when subjects were instructed to grasp the bar, rather than point to it. As a control experiment, the same experiment was repeated using bar luminance changes, a feature that is not relevant for either grasping or pointing. Here, no differences in visual sensitivity between grasping and pointing were found. The present results constitute first direct evidence for increased perceptual sensitivity to a visual feature that is relevant for a certain skeletomotor act during the movement preparation phase. We speculate that such action-induced perception improvements are controlled by neuronal feedback mechanisms from cortical motor planning areas to early visual cortex, similar to what was recently established for spatial perception improvements shortly before eye movements.     

Magnetic orientation in the semi-terrestrial amphipod, Orchestia cavimana, and its interrelationship with photo-orientation and water loss

ABSTRACT. Orchestia cavimana Heller (Amphipoda, Talitridae) were shown to orient to the geomagnetic field as well as to an anisotropic light field. When tested in an isotropic light field the orientation in the geomagnetic field was either in or opposite to the compass direction of the light vector of the anisotropic light field in which the animals had lived before the test, and this orientation was upset predictably by changing the magnetic field with Helmholtz coils. The polarity of the reaction in both magnetic orientation and photo-orientation was correlated with pre-experimental water loss. The magnetic orientation of O. cavimana is compared with that of Tenebrio molitor , and its biological significance discussed.     

Experiment Research on Binocular Perceptual Characteristics around Peripheral Vision for Development of Head Mounted Display with Wide View

The head mounted display （HMD） is widely used in virtual reality technology. In common HMD, however, the binocular disparity is set to an equal fixed value in the entire range of view. Such HMD systems have several shortcomings when used for wide views. In this study, in order to realize a natural stereo sensation of HMD with wide view, we measure the characteristics of binocular stereo perception and binocular light perception. Results show that both the stereoacuity and light sensitivity decrease as the retina＇s eccentricity increases from fovea to periphery. However, the decrease of the stereoacuity is more rapid than that of the light sensitivity. These results suggest that the binocular disparity at the peripheral field should be small, otherwise double images would be observed instead of a stereo view. Based on the results we develop a relative binocular stereoacuity model which can be applied for the design of HMD systems with wide view.     

An experimental analysis on the magnetic field sensitivity of the black-meadow ant Formica pratensis Retzius (Hymenoptera: Formicidae)

Ant responses were tested under both the natural geomagnetic and artificially induced Earth-strength electromagnetic field. Foragers were trained for a month to visit a food source at the north arm accessed through an orientation platform assembly. Under the natural geomagnetic field, when all other orientational cues were eliminated, results indicated significant heterogeneity of ant distribution with the majority seeking geomagnetic north in darkness. However, in light, foragers failed to discriminate geomagnetic north. Under shifted artificial electromagnetic field, orientation was predominantly on the artificial magnetic N/S axis with a significant preference for the artificial north in both light and dark conditions.     

A visual pathway links brain structures active during magnetic compass orientation in migratory birds

The magnetic compass of migratory birds has been suggested to be light-dependent. Retinal cryptochrome-expressing neurons and a forebrain region, "Cluster N", show high neuronal activity when night-migratory songbirds perform magnetic compass orientation. By combining neuronal tracing with behavioral experiments leading to sensory-driven gene expression of the neuronal activity marker ZENK during magnetic compass orientation, we demonstrate a functional neuronal connection between the retinal neurons and Cluster N via the visual thalamus. Thus, the two areas of the central nervous system being most active during magnetic compass orientation are part of an ascending visual processing stream, the thalamofugal pathway. Furthermore, Cluster N seems to be a specialized part of the visual wulst. These findings strongly support the hypothesis that migratory birds use their visual system to perceive the reference compass direction of the geomagnetic field and that migratory birds "see" the reference compass direction provided by the geomagnetic field.     

Orientation in pied flycatchers: the relative importance of magnetic and visual information at dusk

We investigated the orientation of juvenile pied flycatchers, Ficedula hypoleuca, during autumn migration in south Sweden using orientation cage experiments, to study the relative importance of visual and magnetic information at sunset. We performed cage tests under 12 experimental conditions that manipulated the geomagnetic and visual sunset cues available for orientation: natural clear skies in the local or a vertical magnetic field; simulated total overcast in the local or a vertical magnetic field; natural pattern of skylight polarization and directional information from stars screened off, with the sun's position as normal or shifted 120 degrees anticlockwise with mirrors; reduced polarization in the local or a vertical magnetic field; directions of polarization (e-vector) NE/SW and NW/SE, respectively, in the local or a vertical magnetic field. The pied flycatchers were significantly oriented towards slightly south of west when they could use a combination of skylight and geomagnetic cues. The mean orientation was significantly shifted along with the deflection of the sunset position by mirrors. Reduced polarization had no significant effect on orientation either in the local, or in a vertical, magnetic field. The birds tended to orient parallel with the axis of polarization, but only when the artificial e-vector was aligned NW/SE. The mean orientation under simulated total overcast in a vertical, and in the local, magnetic field was not significantly different from random. It is difficult to rank either cue as dominant over the other and we conclude that both visual and magnetic cues seem to be important for the birds' orientation when caught and tested during active migration. Copyright 1999 The Association for the Study of Animal Behaviour.     

The magnetic field sensitivity of the human visual system shows resonance and compass characteristic

Orientation in the geomagnetic field is essential for many animal species. As yet, the interaction mechanisms of this weak field with the organisms are understood only incompletely. One mechanism in question is the interaction with the photochemical reaction in the retina. We show that the visual sensitivity of man is influenced by periodic sinusoidal inversion of the vertical component of the geomagnetic field. This effect indicates visual fixation in north-south direction and shows a pronounced resonance at a period duration of 110 s. These findings should be helpful in identifying in detail the mechanisms which are influenced by the geomagnetic field.     

The Opioid System and Magnetic Field Perception

The impact of Opilong—a dermorphine analog and μ-receptor agonist—on male Wistar rats' sensitivity to a static magnetic field (MF) of 38 ± 2 μT was studied using an original behavioral model of spatial learning in a multiple alternative maze. The 90° maze rotation with respect to the geomagnetic force lines caused disorientation in 80% of well-trained rats preconditioned by the Opilong treatment (0.05 mg/kg), but not in the control rats. Analysis of the behavioral patterns of the opioid–induced rats implied that the rats' orientations in the maze were initially established by taking the geomagnetic force lines into account. The internal maze cues were dominant for control rats' orientations. We conclude that modulation of the opioid system caused increased MF sensitivity and allowed perception of MF parameters. This could serve as an information factor for orientation in the maze, while self-organizing complicated goal–directed behavior in opioid-induced rats.     

Testing Magnetic Orientation in a Solitary Subterranean Rodent Ctenomys talarum (Rodentia: Octodontidae)

To test for the hypothesis that Ctenomys talarum can use the earth's magnetic field for spatial orientation, we carried out field and laboratory experiments to analyse if C. talarum burrows present any geomagnetic orientation in their natural habitat, if C. talarum show any spontaneous directional preference when starting to excavate their burrows and if this subterranean rodent is capable to use the earth's magnetic field to orient towards a goal in a complex maze. No correlation between the burrowing direction and the earth's magnetic field was found. We could not find any evidence for any spontaneous directional preference when starting to excavate the burrows in C. talarum. The change of the horizontal vector of the geomagnetic field did not affect the ability of this rodent to orient towards a goal in an artificial labyrinth. Explanations for these results and other possible mechanisms of orientation that could be used by C. talarum are discussed.     

Power lines and the geomagnetic field

The metric of prime interest in power line epidemiological studies has been AC magnetic intensity. To consider also possible geomagnetic involvement, the orientation of a long straight power line is examined relative to a uniform geomagnetic field (GMF) with dip angle α. An expression is derived for the component of the total GMF that is parallel, at an elevation β, to the circuital magnetic field that surrounds the line. This component is a function of the angles α and β, the total geomagnetic intensity B_T, and the angle θ between the axis of the power line and magnetic north. Plotting these geomagnetic parameters for known leukemia residences allows one to test for possible ion cyclotron resonance or other GMF interactions. This approach, in principle, is an easy addition to existing or planned studies, because residential access is not required to obtain local values for α, β, θ, and B_T. We recommend including these parameters in the design of epidemiological studies examining power line fields and childhood leukemia. © 1995 Wiley-Liss, Inc.     

Shoreward orientation involving geomagnetic cues in the nudibranch mollusc Tritonia diomedea

The marine nudibranch mollusc Tritonia diotnedea orients to the geomagnetic field in the laboratory, and has identifiable brain cells (Pd5, 6) which respond electrically when the ambient magnetic field is rotated artificially. Field studies reported here seek to determine if and why Tritonia diomedea uses geomagnetic cues to orient in the field. Animals were collected in their natural habitat using SCUBA, and placed on lines with magnetic headings parallel to the shore, at different locations with respect to their site of origin. Observations made at two or more tidal cycles later indicate that most animals move from the line in a direction corresponding to the original shoreward direction, regardless of the actual shoreward direction at the site of release, suggesting guidance by geomagnetic cues. Tritonia diomedea are close to neutrally buoyant, and subject to transport over great distances when dislodged by tidal currents or during escape swimming behavior. Since the natural distribution of food and mates is along the shoreline, shoreward orientation using geomagnetic cues, particularly when other cues are weak or ambiguous, may have adaptive value.     

Shifted magnetic fields lead to deflected and axial orientation of migrating robins,Erithacus rubecula,at sunset

The migratory orientation of the robin was tested in shifted magnetic fields during the twilight period after sunset, under clear skies and under simulated total overcast. The horizontal direction of the geomagnetic field was shifted 90° to the right or left in relation to the local magnetic field, without changing either the intensity of the field or its angle of inclination. Experiments were conducted during both spring and autumn, with robins captured as passage migrants at the Falsterbo and Ottenby bird observatories in southern Sweden as test subjects. Generally, the orientation of robins was affected by magnetic shifts compared to controls tested in the natural geomagnetic field. Autumn birds from the two capture sites differed in their responses, probably because of different migratory dispositions and body conditions. The robins most often changed their orientation to maintain their typical axis of migration relative to the shifted magnetic fields. However, preferred directions in relation to the shifted magnetic fields were frequently reverse from normal, or axial rather than unimodal. These results disagree with suggested mechanisms for orientation by visual sunset cues and with the proposed basis of magnetic orientation. They do, however, demonstrate that the geomagnetic field is involved in the sunset orientation of robins, probably in combination with additional visual or non-visual cues that contribute to establish magnetic polarity.     

Contextual modulation outside of awareness

Contextual effects are ubiquitous in vision and reveal fundamental principles of sensory coding. Here, we demonstrate that an oriented surround grating can affect the perceived orientation of a central test grating even when backward masking of the surround prevents its orientation from being consciously perceived. The effect survives introduction of a gap between test and surround of over a degree even under masking, suggesting either that contextual information can effectively propagate across early visual cortex in the absence of awareness of the signaled context or that it can proceed undetected to higher processing levels at which such horizontal propagation may not be necessary. The effect under masking also shows partial interocular transfer, demonstrating processing of orientation by binocular neurons in visual cortex in the absence of conscious orientation perception. This pattern of results is consistent with the suggestion that simultaneous orientation contrast is mediated at multiple levels of the visual processing hierarchy, and it supports the view that propagation of signals to and, possibly, back from higher visual areas is necessary for conscious perception.     

Effects of local adaptation of receptive field on sensitivity of the cat visual cortex neurons to cruciform images

The responses to flashing single light bars of different orientation and to cruciform images (CI) were compared in 9 neurons of the cat striate cortex possessing high specific sensitivity to CI, during local adaptation of various receptive field (RF) zones. In most neurons, a two- to threefold reduction in the response to CI with a constantly present bar of optimum or orthogonal orientation, if compared with a response to the figure consisting of two flashing bars, was found. Responses to the CI including an adaptation bar were often increased, if compared with those observed at usual orientation tuning. The role of a cross-orientation inhibition in the formation of a selective sensitivity to CI in the neurons of the visual cortex is discussed.Neirofiziologiya/Neurophysiology, Vol. 27, No. 2, pp. 134–139, March–April, 1995.     

Bats Respond to Very Weak Magnetic Fields

How animals, including mammals, can respond to and utilize the direction and intensity of the Earth’s magnetic field for orientation and navigation is contentious. In this study, we experimentally tested whether the Chinese Noctule, Nyctalus plancyi (Vespertilionidae) can sense magnetic field strengths that were even lower than those of the present-day geomagnetic field. Such field strengths occurred during geomagnetic excursions or polarity reversals and thus may have played an important role in the evolution of a magnetic sense. We found that in a present-day local geomagnetic field, the bats showed a clear preference for positioning themselves at the magnetic north. As the field intensity decreased to only 1/5^th of the natural intensity (i.e., 10 μT; the lowest field strength tested here), the bats still responded by positioning themselves at the magnetic north. When the field polarity was artificially reversed, the bats still preferred the new magnetic north, even at the lowest field strength tested (10 μT), despite the fact that the artificial field orientation was opposite to the natural geomagnetic field (P<0.05). Hence, N. plancyi is able to detect the direction of a magnetic field even at 1/5th of the present-day field strength. This high sensitivity to magnetic fields may explain how magnetic orientation could have evolved in bats even as the Earth’s magnetic field strength varied and the polarity reversed tens of times over the past fifty million years.     

Discrimination of a Right Angle with Monocular and Cyclopic Perception

Psychophysical tests with monocular and cyclopic perception were carried out to evaluate the accuracy of discrimination of right, acute, and obtuse angles. Tests with monocular perception were carried out with stimuli made by light line segments, spots, or elements of the Oppel-Kundt and Muller-Lyer figures. In tests with cyclopic perception, pairs of V-shaped stimuli with an identical orientation in the visual field and equal length of the sides but different divergence angles were presented to the different eyes of subjects. The test data demonstrated features of the perception of a right angle, namely, a high accuracy of reproduction, periodicity of errors as a function of the general orientation of a stimulus, similar characteristics of the manifestation of geometric illusions in angle reproduction and length comparison, and the manifestation of Hering’s law in cyclopic perception. These results agree with the multilocal hypothesis, which explains the perception of right and other angles on the basis of the information about the coordinates of stimulus parts.__________Translated from Fiziologiya Cheloveka, Vol. 31, No. 4, 2005, pp. 14–26.Original Russian Text Copyright © 2005 by Bulatov, Bertulis, Bulatova.     

Orientation Cage and Release Experiments with Migratory Wheatears (Oenanthe oenanthe) in Scandinavia and Greenland: The Importance of Visual Cues

Migratory orientation of Scandinavian and Greenland wheatears was recorded during the autumn migration periods of 1988 and 1989. Orientation cage tests were conducted under clear sunset skies, to investigate the importance of different visible sky sections on orientation performance. In addition, wheatears were released under clear starry skies and under total overcast to examine the orientation of free-flying birds. The following results were obtained:

• 1 Wheatears tested with a restricted visible sky section (90° centered around zenith) in orientation cages, showed a mean orientation towards geographic W/geomagnetic NW (Greenland) and towards geographic and magnetic WNW-NW (Sweden). These mean directions are clearly inconsistent with the expected autumn migration directions, SW-SSW in Scandinavia and SE in Greenland, as revealed by ringing recoveries for the two populations.
• 2 When the birds were allowed a much more extensive view of the sky, almost down to the horizon (above 10° elevation), Scandinavian wheatears chose headings in agreement with ringing data. Greenland birds were not significantly oriented.
• 3 Release experiments under clear starry skies resulted in mean vanishing directions in good agreement with ringing data from both sites. Greenland wheatears released under total overcast showed a similar orientation as under clear skies, indicating that a view of the stars may not be of crucial importance for selecting a seasonally accurate migratory direction.

The results suggest that an unobstructed view of the sky, including visual cues low over the horizon, is important, possibly in combination with geomagnetic cues, for the orientation of migratory naive wheatears. Furthermore, the birds showed remarkably similar orientation responses in Greenland and Scandinavia, respectively, indicating that they use basically the same orientation system, despite considerable differences in visual and geomagnetic orientation premises at the two different geographic and magnetic latitudes.     

L'ipotesi dell'effetto del campo geomagnetico e la variabilità tra le ripetizioni in prove di germinazione ed accrescimento in Triticum

Abstract

The geomagnetic field effect hypothesis and the variability among replications in germination and growth tests in Triticum. – During previous eperiments on germination and growth of Triticum, we have often found many cases of heteroscedasticity and of statistically significant differences among contemporary replications (i.e. germinators). In such experiments all the caryopses were oriented in the same way inside the germinators, whilst the germinators were randomly set inside the thermostats: therefore the seeds of different germinators might result differently oriented. Some researchers report that seeds differently oriented according to the lines of force of the geomagnetic field, may respond with different germination, growth rates and growth directions of shoots and roots (magnetotropism). The present investigation was designed to ascertain if these effects might be responsible of the variability among the contemporary replications. The different caryopses orientation within laboratory geomagnetic field, does not give evidence of any effect on germination, growth rate and direction. The caryopses show no germination sensibility neither related to different age, light and temperature conditions, neither to different cultivars, neither to varying orientation from the geomagnetic North every 15° and to varying time of ? preorientation ? in dry conditions. Differences between the variability of randomly and North oriented subsamples are not observed. No statistically significant differences are observed among shoots and roots lenghts of seedlings from differently oriented caryopses neither in different environmental conditions, nor as function of the orientation (24 angles of 15°), nor after different preorientations, nor after repeating the test on 608 subsamples (12.000 seedlings). Therefore the variability among contemporary replications is not imputable to the geomagnetic field. The variability and the distributions structure analysis suggest that both the heteroscedasticity and the significant differences among the replications may be due to an interaction among the caryopses inside the germinators through the substrate. This is probably related to the cultivar characteristics. We emphasize that an accurate evaluation of the variability is particularly necessary in germination and growth tests.