ライフサイエンスコーパス: depth perception

1 tions of higher areas to specific aspects of depth perception.

2 structures (clusters and columns) underlying depth perception.

3 n maturation of binocular cortical cells and depth perception.

4 ough it themselves, fail to develop accurate depth perception.

5 inocular disparity, a key component of human depth perception.

6 computations and possible new algorithms for depth perception.

7 risk of inattentional blindness and impaired depth perception.

8 ervention to improve near vision and enhance depth perception.

9 ons on disparity variations that can support depth perception.

10 n important, previously unrecognized role in depth perception.

11 study of the underlying neural mechanisms of depth perception.

12 flicker as well as motion parallax cues for depth perception.

13 the functional contributions of this area to depth perception.

14 rcepts are refined over time in stereoscopic depth perception.

15 disparity, the raw material of stereoscopic depth perception.

16 dicating that they play an important role in depth perception.

17 arantee that they contribute to stereoscopic depth perception.

18 lateral retinogeniculate projection and poor depth perception.

19 s) to the brain permits binocular vision and depth perception.

20 man visual cortex and functionally linked to depth perception.

21 ma suspects, showed significant reduction in depth perception.

22 two eyes, binocular disparities, to generate depth perception?

23 ough these neurons are probably essential to depth perception, a recent study has shown that they are

24 ations in vision, focusing difficulties, and depth perception; all P > .05) or ocular symptoms (photo

25 eral sensory inputs are essential for visual depth perception and accurate localization of sounds in

26 y form the neural substrate for stereoscopic depth perception and are found in several areas of prima

27 findings suggest a new neural substrate for depth perception and demonstrate a robust interaction of

28 wever, operating through a microscope limits depth perception and fixes the visual perspective, which

29 mputations performed by the brain, including depth perception and heading perception.

30 ols and to determine the association between depth perception and severity of glaucoma.

31 s the binocular retinotopic match needed for depth perception and the light-dark retinotopic mismatch

32 s the binocular retinotopic match needed for depth perception and the light-dark retinotopic mismatch

33 f eye movements is essential for stereopsis (depth perception) and to prevent double vision.

34 n partially restores the optomotor response, depth perception, and circadian photoentrainment, demons

35 ation of the arm indeed powerfully modulates depth perception, and that this internal calibration can

36 the adaptors that are effective in altering depth perception appear widely separated in depth from t

37 This limit on stereoscopic depth perception appears to be intrinsic to the visual s

38 mus and Frisby stereoacuity tests to measure depth perception as stereopsis threshold in seconds of a

39 onveyed the binocular information needed for depth perception based on binocular cues.

40 h previous studies that implicate area MT in depth perception based on binocular disparities, our res

41 The results indicate that depth perception could affect VWM, and the visual system

42 motion perception difficulties and abnormal depth perception despite 'normal' (20/20) vision.

43 They accomplish depth perception, despite their tiny brains, by using sp

44 with CVFDs should be counseled regarding how depth perception difficulties may affect daily living.

45 opic systems have been introduced to enhance depth perception during minimum-access surgery.

46 Depth perception emerges from the development of binocul

47 umping spiders (Salticidae) rely on accurate depth perception for predation and navigation.

48 eptor deficit in the central retina and poor depth perception from a decrease in ipsilaterally projec

49 tion of a visual scene and encoding relative depth perception from motion disparity.

50 movements, as predicted by human studies of depth perception from motion parallax.

51 rst causal links between neural activity and depth perception have been established.

52 the middle temporal (MT) area contributes to depth perception in addition to its well established rol

53 t MT plays an important role in stereoscopic depth perception in addition to its well known role in m

54 To evaluate depth perception in Primary open angle glaucoma (POAG),

55 This deficit is associated with reduced depth perception in the visual cliff test.

56 ation, has led to the proposition that human depth perception in these stimuli depends on a distinct

57 timulus localization in auditory systems and depth perception in vision, but the role of stereo olfac

58 Motion-in-depth perception is critical in enabling animals to avoi

59 The process of stereoscopic depth perception is thought to begin with the analysis o

60 aining visual function and perception (e.g., depth perception), minimizing need to take glaucoma drop

61 st revealed a significant abnormality in the depth perception of Rbfox2-deficient animals.

62 demonstrated mixed results of the effect of depth perception on VWM, with some showing a beneficial

63 f objects in the scene and make stereoscopic depth perception possible.

64 Stereoscopic depth perception relies on binocular disparities, or sma

65 c contributions of different visual areas to depth perception remain poorly understood.

66 Depth perception requires that image features on one ret

67 inocular neurons that are closely related to depth perception should respond selectively for stimuli

68 oosts the precision, but not the accuracy of depth perception, suggesting that the enhanced stereoacu

69 st using the Sheridan Gardiner chart and the depth perception test using the Langs stereoacuity test.

70 2 or less in the better eye or a fail in the depth perception test.

71 overlays also resulted in better subjective depth perception than always-on solid overlay (p=0.031 a

72 ted finding (a surgical clip) and subjective depth perception (using a Likert scale).

73 One example is depth perception via binocular stereopsis in the praying

74 As early as the 1830s, stereoscopic depth perception was shown to depend on horizontal dispa

75 nals with sufficient fidelity to account for depth perception, we have compared neuronal and psychoph

76 area (MT) has previously been implicated in depth perception, we tested whether MT neurons could sig

77 vements of their retinas-which could enhance depth perception-when crossing gaps, and impairing the p

78 Analogously, visual depth perception, which is based on interocular disparit

79 ng approach to harness wide-angle vision and depth perception while addressing limitations like low r

80 eyes on our hands, rather than on our faces: depth perception would be improved by the greater distan