ライフサイエンスコーパス: color perception

1 ainment, and may contribute to luminance and color perception.

2 ematically measuring how attention modulates color perception.

3 ct of language-specific terminology on human color perception.

4 in V1 are needed for the full repertoire of color perception.

5 the neural basis of the influence of form on color perception.

6 Form has a strong influence on color perception.

7 d to determine whether hypnosis can modulate color perception.

8 und implications for the nature of shape and color perception.

9 les predicted from psychophysical studies of color perception.

10 ed on correlating single-unit responses with color perception.

11 was negatively related to abnormal red-green color perception.

12 o further illuminate the mechanisms of human color perception.

13 iple of diminishing returns applies to human color perception.

14 use nor the effect of variation in low-level color perception.

15 that extra integrative steps give conscious color perception a time course substantially slower than

16 a strategy for the generation and control of color perception along the blue-yellow axis in blind pat

17 dentify neurodiversity in the development of color perception and cognition and implications for clin

18 resent the current state of knowledge on how color perception and cognition develop.

19 ons of the research for understanding mature color perception and cognition, for identifying the prin

20 We discovered a novel property of color perception and constancy, involving how we experie

21 hat is known about individual differences in color perception and its determinants, particularly cons

22 ingly investigating other functions, such as color perception and object recognition.

23 ge analysis eliminated subjectivity in human color perception and permitted reliable detection of opi

24 d whether similar neural mechanisms underlie color perception and synesthetic colors using magnetoenc

25 er daylight conditions and are essential for color perception and vision with high temporal and spati

26 ypes in the retina set fundamental limits on color perception, and abnormal or missing types are resp

27 functional deficits in contrast sensitivity, color perception, and dark adaptation.

28 Many visual predators have keen color perception, and thus camouflage patterns should pr

29 reen dimension of human and nonhuman primate color perception arose relatively recently in the primat

30 Over days there was a shift in color perception, as measured by the wavelength of uniqu

31 n dark adaptation, contrast sensitivity, and color perception before any microvascular pathologies on

32 n dark adaptation, contrast sensitivity, and color perception before microvascular pathologies become

33 It follows that color perception can arise without prior color sensation

34 Visual acuity and color perception depend on the distribution of photorece

35 Thus, a neural normalization mechanism for color perception, determined by visual experience, opera

36 ected color or, in more familiar terms, that color perception follows from color sensation.

37 the color vision system creates diversity in color perception, from discrimination to color matching,

38 ned if the ontogenetic effect of UV-light on color perception generates a negative selection pressure

39 Studies of color perception have led to mechanistic models of how c

40 Shared mechanisms of color perception help explain consistent partitions of v

41 ation, and little is known about nonspectral color perception in animals with more than three types o

42 ested the feasibility of partially restoring color perception in blind RP patients, with the aim to p

43 d reduction in both contrast sensitivity and color perception in multiple sclerosis patients despite

44 ina might render the standard model of human color perception incomplete.

45 These data emphasize that color perception involves multiple areas across a hierar

46 vision are impaired, the impact of memory on color perception is greatest for face color, supporting

47 tebrates, this capacity for rich nonspectral color perception is likely widespread.

48 These results suggest that color perception is mediated by specialized neurons that

49 ic color space and indicate that nonspectral color perception is vital for signaling and foraging.

50 ic color experience resembles that of normal color perception, one would predict activation of parts

51 magnocellular-dominated) tasks than face- or color-perception (parvocellular-dominated) tasks, the au

52 s that background color and luminance affect color perception, previous measurements of tooth color d

53 those using a genetic approach to understand color perception, raise some important questions.

54 Color perception relies on comparisons between adjacent

55 computing new cone-derived input to achieve color perception.SIGNIFICANCE STATEMENT The possibility

56 = 20) are assigned to an in-group based on a color perception task, complete a group reinforcement st

57 misrepresentation of the state-of-the-art of color perception; the type of model required to move the

58 imulation frequency from 6 to 120 Hz shifted color perception toward blue/purple despite a significan

59 Static visual functions (visual acuity, color perception, visual field, and contrast sensitivity

60 Similar to human color perception, VO responds powerfully to all colors b

61 ness was controlled by amplitude tuning, and color perception was acquired using the Red, Yellow, Gre

62 stency over time and spatially matched multi-color perception was possible with simultaneous stimulat

63 nce, can lead to abnormalities in blue-green color perception which causes the color lexicon to adapt

64 cornerstones of this review, which examines color perception with context that varies over space or