Color constancy improves for real 3D objects

Hedrich, M., Bloj, M., Ruppertsberg, A. I.

January 2009

In this study human color constancy was tested for two-dimensional (2D) and three-dimensional (3D) setups with real objects and lights. Four different illuminant changes, a natural selection task and a wide choice of target colors were used. We found that color constancy was better when the target color was learned as a 3D object in a cue-rich 3D scene than in a 2D setup. This improvement was independent of the target color and the illuminant change. We were not able to find any evidence that frequently experienced illuminant changes are better compensated for than unusual ones. Normalizing individual color constancy hit rates by the corresponding color memory hit rates yields a color constancy index, which is indicative of observers' true ability to compensate for illuminant changes.

Adult

Color

Color Perception/*physiology

Color Vision/*physiology

Female

Humans

*Imaging, Three-Dimensional

Learning/physiology

Lighting

Male

Memory/physiology

Middle Aged

Photic Stimulation/*methods

Young Adult

REF 2014

Real and predicted influence of image manipulations on eye movements during scene recognition

Harding, G., Bloj, M.

January 2010

In this paper, we investigate how controlled changes to image properties and orientation affect eye movements for repeated viewings of images of natural scenes. We make changes to images by manipulating low-level image content (such as luminance or chromaticity) and/or inverting the image. We measure the effects of these manipulations on human scanpaths (the spatial and chronological path of fixations), additionally comparing these effects to those predicted by a widely used saliency model (L. Itti & C. Koch, 2000). Firstly we find that repeated viewing of a natural image does not significantly modify the previously known repeatability (S. A. Brandt & L. W. Stark, 1997; D. Noton & L. Stark, 1971) of scanpaths. Secondly we find that manipulating image features does not necessarily change the repeatability of scanpaths, but the removal of luminance information has a measurable effect. We also find that image inversion appears to affect scene perception and recognition and may alter fixation selection (although we only find an effect on scanpaths with the additional removal of luminance information). Additionally we confirm that visual saliency as defined by L. Itti and C. Koch's (2000) model is a poor predictor of real observer scanpaths and does not predict the small effects of our image manipulations on scanpaths.

Adolescent

Adult

Attention/*physiology

Color Perception/physiology

Eye Movements/*physiology

Female

Fixation, Ocular/*physiology

Humans

Lighting

Male

Models, Neurological

Orientation/*physiology

Pattern Recognition, Visual/*physiology

Photic Stimulation/methods

Predictive Value of Tests

Young Adult

REF 2014

Induced deficits in speed perception by transcranial magnetic stimulation of human cortical areas V5/MT+ and V3A

McKeefry, D. J., Burton, M. P., Vakrou, C., Barrett, B. T., Morland, A. B.

January 2008

In this report, we evaluate the role of visual areas responsive to motion in the human brain in the perception of stimulus speed. We first identified and localized V1, V3A, and V5/MT+ in individual participants on the basis of blood oxygenation level-dependent responses obtained in retinotopic mapping experiments and responses to moving gratings. Repetitive transcranial magnetic stimulation (rTMS) was then used to disrupt the normal functioning of the previously localized visual areas in each participant. During the rTMS application, participants were required to perform delayed discrimination of the speed of drifting or spatial frequency of static gratings. The application of rTMS to areas V5/MT and V3A induced a subjective slowing of visual stimuli and (often) caused increases in speed discrimination thresholds. Deficits in spatial frequency discrimination were not observed for applications of rTMS to V3A or V5/MT+. The induced deficits in speed perception were also specific to the cortical site of TMS delivery. The application of TMS to regions of the cortex adjacent to V5/MT and V3A, as well as to area V1, produced no deficits in speed perception. These results suggest that, in addition to area V5/MT+, V3A plays an important role in a cortical network that underpins the perception of stimulus speed in the human brain.

Adult

Brain Mapping/methods

Electromagnetic Fields/adverse effects

Humans

Male

Photic Stimulation/methods

Retina/physiology

Time Factors

REF 2014