Boris M. Sheliga
Affiliations: | National Eye Institute, Bethesda, Maryland |
Area:
Eye movements, visionGoogle:
"Boris Sheliga"Mean distance: 14.38 (cluster 17) | S | N | B | C | P |
Parents
Sign in to add mentorBernard Cohen | post-doc | 1996-1998 | Mount Sinai |
Frederick A. Miles | research scientist | NEI |
BETA: Related publications
See more...
Publications
You can help our author matching system! If you notice any publications incorrectly attributed to this author, please sign in and mark matches as correct or incorrect. |
Sheliga BM, FitzGibbon EJ. (2024) Weighted power summation and contrast normalization mechanisms account for short-latency eye movements to motion and disparity of sine-wave gratings and broadband visual stimuli in humans. Journal of Vision. 24: 14 |
Sheliga BM, FitzGibbon EJ. (2023) Manipulating the Fourier spectra of stimuli comprising a two-frame kinematogram to study early visual motion-detecting mechanisms: Perception versus short latency ocular-following responses. Journal of Vision. 23: 11 |
Sheliga BM, Quaia C, FitzGibbon EJ, et al. (2022) Weighted summation and contrast normalization account for short-latency disparity vergence responses to white noise stimuli in humans. Journal of Vision. 22: 17 |
Sheliga BM, Quaia C, FitzGibbon EJ, et al. (2021) Short-latency ocular following responses to motion stimuli are strongly affected by temporal modulations of the visual content during the initial fixation period. Journal of Vision. 21: 8 |
Sheliga BM, Quaia C, FitzGibbon EJ, et al. (2020) Short-latency ocular-following responses: Weighted nonlinear summation predicts the outcome of a competition between two sine wave gratings moving in opposite directions. Journal of Vision. 20: 1 |
Sheliga B, Quaia C, FitzGibbon E, et al. (2018) Short-latency ocular-following responses to motion stimuli are strongly affected by temporal modulations of the visual content during the initial fixation period. Journal of Vision. 18: 351 |
Sheliga BM, Quaia C, FitzGibbon EJ, et al. (2017) Human short-latency ocular vergence responses produced by interocular velocity differences. Journal of Vision. 16: 11 |
Sheliga BM, Quaia C, FitzGibbon EJ, et al. (2016) Ocular-following responses to white noise stimuli in humans reveal a novel nonlinearity that results from temporal sampling. Journal of Vision. 16: 8 |
Sheliga B, Quaia C, FitzGibbon E, et al. (2016) Human short-latency ocular vergence responses in the absence of the binocular disparity signal. Journal of Vision. 16: 426 |
Sheliga B, Quaia C, FitzGibbon E, et al. (2015) Human contrast normalization process operates on a local scale. Journal of Vision. 15: 287 |