T Ledgeway, A T Smith. Vision Res 1995
Times Cited: 33
Times Cited: 33
Times Cited
Times Co-cited
Similarity
Drift-balanced random stimuli: a general basis for studying non-Fourier motion perception.
C Chubb, G Sperling. J Opt Soc Am A 1988
C Chubb, G Sperling. J Opt Soc Am A 1988
51
Evidence for separate motion-detecting mechanisms for first- and second-order motion in human vision.
T Ledgeway, A T Smith. Vision Res 1994
T Ledgeway, A T Smith. Vision Res 1994
48
A psychophysically motivated model for two-dimensional motion perception.
H R Wilson, V P Ferrera, C Yo. Vis Neurosci 1992
H R Wilson, V P Ferrera, C Yo. Vis Neurosci 1992
48
Spatiotemporal energy models for the perception of motion.
E H Adelson, J R Bergen. J Opt Soc Am A 1985
E H Adelson, J R Bergen. J Opt Soc Am A 1985
45
42
Direction identification thresholds for second-order motion in central and peripheral vision.
A T Smith, R F Hess, C L Baker. J Opt Soc Am A Opt Image Sci Vis 1994
A T Smith, R F Hess, C L Baker. J Opt Soc Am A Opt Image Sci Vis 1994
30
Perceived velocity of luminance, chromatic and non-fourier stimuli: influence of contrast and temporal frequency.
K R Gegenfurtner, M J Hawken. Vision Res 1996
K R Gegenfurtner, M J Hawken. Vision Res 1996
30
Discriminating the direction of second-order motion at short stimulus durations.
A M Derrington, D R Badcock, G B Henning. Vision Res 1993
A M Derrington, D R Badcock, G B Henning. Vision Res 1993
30
The dimensionality of texture-defined motion: a single channel theory.
P Werkhoven, G Sperling, C Chubb. Vision Res 1993
P Werkhoven, G Sperling, C Chubb. Vision Res 1993
27
A processing stream in mammalian visual cortex neurons for non-Fourier responses.
Y X Zhou, C L Baker. Science 1993
Y X Zhou, C L Baker. Science 1993
27
A computational model of the analysis of some first-order and second-order motion patterns by simple and complex cells.
A Johnston, P W McOwan, H Buxton. Proc Biol Sci 1992
A Johnston, P W McOwan, H Buxton. Proc Biol Sci 1992
27
Contrast dependence of colour and luminance motion mechanisms in human vision.
M J Hawken, K R Gegenfurtner, C Tang. Nature 1994
M J Hawken, K R Gegenfurtner, C Tang. Nature 1994
27
Separate detection of moving luminance and contrast modulations: fact or artifact?
A T Smith, T Ledgeway. Vision Res 1997
A T Smith, T Ledgeway. Vision Res 1997
24
The influence of spatial frequency and contrast on the perception of moving patterns.
F W Campbell, L Maffei. Vision Res 1981
F W Campbell, L Maffei. Vision Res 1981
24
Perceived motion of contrast-modulated gratings: predictions of the multi-channel gradient model and the role of full-wave rectification.
A Johnston, C W Clifford. Vision Res 1995
A Johnston, C W Clifford. Vision Res 1995
21
21
The effect of contrast upon perceived speed: a general phenomenon?
M R Blakemore, R J Snowden. Perception 1999
M R Blakemore, R J Snowden. Perception 1999
21
Full-wave and half-wave rectification in second-order motion perception.
J A Solomon, G Sperling. Vision Res 1994
J A Solomon, G Sperling. Vision Res 1994
18
Separate detectors for simple and complex grating patterns?
A M Derrington, D R Badcock. Vision Res 1985
A M Derrington, D R Badcock. Vision Res 1985
18
Adaptation to second-order motion results in a motion aftereffect for directionally-ambiguous test stimuli.
T Ledgeway. Vision Res 1994
T Ledgeway. Vision Res 1994
18
The influence of spatial frequency on perceived temporal frequency and perceived speed.
A T Smith, G K Edgar. Vision Res 1990
A T Smith, G K Edgar. Vision Res 1990
18
Speed estimates from grating patches are not contrast-normalized.
P Thompson, L S Stone, S Swash. Vision Res 1996
P Thompson, L S Stone, S Swash. Vision Res 1996
20
Perceived velocity as a function of reference mark density.
W C Gogel, P McNulty. Scand J Psychol 1983
W C Gogel, P McNulty. Scand J Psychol 1983
24
Perceived velocity of moving chromatic gratings.
P Cavanagh, C W Tyler, O E Favreau. J Opt Soc Am A 1984
P Cavanagh, C W Tyler, O E Favreau. J Opt Soc Am A 1984
18
Perceived direction of moving two-dimensional patterns depends on duration, contrast and eccentricity.
C Yo, H R Wilson. Vision Res 1992
C Yo, H R Wilson. Vision Res 1992
18
Correspondence-based and energy-based detection of second-order motion in human vision.
A T Smith. J Opt Soc Am A Opt Image Sci Vis 1994
A T Smith. J Opt Soc Am A Opt Image Sci Vis 1994
15
Motion defined exclusively by second-order characteristics does not evoke optokinetic nystagmus.
L R Harris, A T Smith. Vis Neurosci 1992
L R Harris, A T Smith. Vis Neurosci 1992
15
15
Global motion perception: no interaction between the first- and second-order motion pathways.
M Edwards, D R Badcock. Vision Res 1995
M Edwards, D R Badcock. Vision Res 1995
15
1st- and 2nd-order motion and texture resolution in central and peripheral vision.
J A Solomon, G Sperling. Vision Res 1995
J A Solomon, G Sperling. Vision Res 1995
16
On the mechanism that encodes the movement of contrast variations: velocity discrimination.
K Turano, A Pantle. Vision Res 1989
K Turano, A Pantle. Vision Res 1989
15
The spatial frequency effect on perceived velocity.
H C Diener, E R Wist, J Dichgans, T Brandt. Vision Res 1976
H C Diener, E R Wist, J Dichgans, T Brandt. Vision Res 1976
15
Precise velocity discrimination despite random variations in temporal frequency and contrast.
S P McKee, G H Silverman, K Nakayama. Vision Res 1986
S P McKee, G H Silverman, K Nakayama. Vision Res 1986
15
Detecting the displacements of spatial beats: no role for distortion products.
D R Badcock, A M Derrington. Vision Res 1989
D R Badcock, A M Derrington. Vision Res 1989
15
Motion of chromatic stimuli: first-order or second-order?
S J Cropper, A M Derrington. Vision Res 1994
S J Cropper, A M Derrington. Vision Res 1994
15
Dual multiple-scale processing for motion in the human visual system.
S Nishida, T Ledgeway, M Edwards. Vision Res 1997
S Nishida, T Ledgeway, M Edwards. Vision Res 1997
15
Position displacement, not velocity, is the cue to motion detection of second-order stimuli.
A E Seiffert, P Cavanagh. Vision Res 1998
A E Seiffert, P Cavanagh. Vision Res 1998
15
Low-level and high-level processes in apparent motion.
O J Braddick. Philos Trans R Soc Lond B Biol Sci 1980
O J Braddick. Philos Trans R Soc Lond B Biol Sci 1980
15
Co-cited is the co-citation frequency, indicating how many articles cite the article together with the query article. Similarity is the co-citation as percentage of the times cited of the query article or the article in the search results, whichever is the lowest. These numbers are calculated for the last 100 citations when articles are cited more than 100 times.