The contrast sensitivity of human colour vision to red‐green and blue‐yellow chromatic gratings.

Mullen, Kathy T.

doi:10.1113/jphysiol.1985.sp015591

Cited by 879 publications

(561 citation statements)

References 26 publications

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“…The extent of the difference will depend on the relative degree of summation in colour receptive fields, and in the input stages of motion-detecting sub-units. Since both the spatial (Mullen, 1985) and the temporal (de Lange, 1958) sensitivity of colour detection mechanisms are low-pass we might expect a substantial degree of summation, and so a substantial enhancement in sensitivity for detection tasks over direction discrimination.…”

Section: Discussionmentioning

confidence: 99%

Detecting and discriminating the direction of motion of luminance and colour gratings

Derrington¹,

Henning

1993

Vision Research

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Human observers were required to discriminate the direction of motion of vertically moving, 1 c/deg luminance and colour gratings. The gratings had different contrasts and moved at temporal frequencies between 0.5 and 32 Hz. Sensitivity [the reciprocal of the contrast at which performance reached 75% correct in a temporal two-alternative forced-choice (2 AFC) discrimination task] was a band-pass function of temporal frequency for luminance gratings, and a low-pass function of temporal frequency for colour gratings. Further, when colour contrast was expressed in terms of the modulation in cone excitation produced by the stimulus, sensitivity to colour gratings was greater than sensitivity to luminance gratings at frequencies below 2 Hz. On the other hand, at temporal frequencies above 4 Hz, sensitivity to colour gratings was comparable with sensitivity to luminance gratings of double the temporal frequency. Research, 30, 1751-17611 who used a smaller stimulus seen in a parafoveal region and found that motion discrimination thresholds were higher than detection threshold for colour gratings. We repeated our threshold measurements using parafoveal viewing conditions similar to those used by Lindsey and Teller (1990). We found that, although for luminance gratings detection thresholds were very close to direction-discrimination thresholds, for colour gratings, they were lower. The result is in qualitative agreement with Lindsey and Teller (1990). Our results suggest that low-level, or "first-order" motion mechanisms are not as sensitive to chromatic gratings as are colour-detection mechanisms.

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Section: Discussionmentioning

confidence: 99%

Detecting and discriminating the direction of motion of luminance and colour gratings

Derrington¹,

Henning

1993

Vision Research

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“…Therefore, this form of stimulus should work with subjects who have impaired color vision. However, color may affect results with different SSVEP displays (Mullen, 1985;Regan, 1989;Arakawa et al, 1999).…”

Section: 1: Display Type and Gaze Shiftingmentioning

confidence: 99%

Towards an independent brain–computer interface using steady state visual evoked potentials

Allison

McFarland

Schalk

et al. 2008

Clinical Neurophysiology

285

183

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Objective-Brain -computer interface (BCI) systems using steady state visual evoked potentials (SSVEPs) have allowed healthy subjects to communicate. However, these systems may not work in severely disabled users because they may depend on gaze shifting. This study evaluates the hypothesis that overlapping stimuli can evoke changes in SSVEP activity sufficient to control a BCI. This would provide evidence that SSVEP BCIs could be used without shifting gaze.Methods-Subjects viewed a display containing two images that each oscillated at a different frequency. Different conditions used overlapping or non-overlapping images to explore dependence on gaze function. Subjects were asked to direct attention to one or the other of these images during each of twelve one-minute runs.Results-Half of the subjects produced differences in SSVEP activity elicited by overlapping stimuli that could support BCI control. In all remaining users, differences did exist at corresponding frequencies but were not strong enough to allow effective control.Conclusions-The data demonstrate that SSVEP differences sufficient for BCI control may be elicited by selective attention to one of two overlapping stimuli. Thus, some SSVEP-based BCI approaches may not depend on gaze control. The nature and extent of any BCI's dependence on muscle activity is a function of many factors, including the display, task, environment, and user.Significance-SSVEP BCIs might function in severely disabled users unable to reliably control gaze. Further research with these users is necessary to explore the optimal parameters of such a system and validate online performance in a home environment.

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“…Even if it has been observed that pictures of natural scenes do have color information represented in medium to high spatial frequencies (Parraga et al, 1998), the visual system tends to perceive chromatic information at coarser scales better than luminance information (Mullen, 1985). 7 The reported effects of color should therefore arise from the spatial layout of crude color information.…”

Section: Figmentioning

confidence: 99%

Diagnostic Colors Mediate Scene Recognition

Oliva

Schyns

2000

Cognitive Psychology

372

277

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The contrast sensitivity of human colour vision to red‐green and blue‐yellow chromatic gratings.

Cited by 879 publications

References 26 publications

Detecting and discriminating the direction of motion of luminance and colour gratings

Detecting and discriminating the direction of motion of luminance and colour gratings

Towards an independent brain–computer interface using steady state visual evoked potentials

Diagnostic Colors Mediate Scene Recognition

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