Publications
. (1993). Patterns of eye movement adaptation to foveal lesions in adult primates. In Walker, M. F., FitzGibbon, E. J., & Goldberg, M. E. (1994). Contemporary Oculomotor and Vestibular Research: A Tribute to David A Robinson.
. (1994). Evidence of a timing mechanism for predictive smooth pursuit in frontal cortex. In Contemporary Oculomotor and Vestibular Research: A Tribute to David A Robinson.
. (1992). Adaptation of saccades and fixation to bilateral foveal lesions in adult monkey. Vision Research, 32, 365–373.
. (2015). Allocation of attention during pursuit of large objects is no different than during fixation. Journal Of Vision, 15, 9–9.
. (2006). Anticipatory movement timing using prediction and external cues. The Journal Of Neuroscience, 26, 4519–4525.
. (1992). Cerebellar uvula involvement in visual motion processing and smooth pursuit control in monkey. Annals Of The New York Academy Of Sciences, 656, 775–782.
. (1991). Characteristics of nystagmus evoked by electrical stimulation of the uvular/nodular lobules of the cerebellum in monkey. Journal Of Vestibular Research: Equilibrium & Orientation, 2, 235–245.
. (2018). Choosing a foveal goal recruits the saccadic system during smooth pursuit. Journal Of Neurophysiology , 120(2), 489-496. http://doi.org/ 10.1152/jn.00418.2017
. (2019). A common mechanism modulates saccade timing during pursuit and fixation. Journal Of Neurophysiology .
. (2014). Contrasting the roles of the supplementary and frontal eye fields in ocular decision making. Journal Of Neurophysiology, 111, 2644–2655.
. (2021). A covered eye fails to follow an object moving in depth. Scientific Reports, 11. http://doi.org/https://doi.org/10.1038/s41598-021-90371-8
. (2010). The default allocation of attention is broadly ahead of smooth pursuit. Journal Of Vision, 10, 7.
. (2015). Different time scales of motion integration for anticipatory smooth pursuit and perceptual adaptation. Journal Of Vision, 15, 16.
. (2008). The effects of microstimulation of the dorsomedial frontal cortex on saccade latency. Journal Of Neurophysiology, 99, 1857–1870.
. (2001). Facilitation of smooth pursuit initiation by electrical stimulation in the supplementary eye fields. Journal Of Neurophysiology, 86, 2413–2425.
. (2011). Flexible interpretation of a decision rule by supplementary eye field neurons. Journal Of Neurophysiology, 106, 2992–3000.
. (2015). A foveal target increases catch-up saccade frequency during smooth pursuit. Journal Of Neurophysiology, jn–00774.
. (2018). Foveated convolutional neural networks for video summarization. Multimedia Tools And Applications, 77(22), 29245-29267. http://doi.org/https://doi.org/10.1007/s11042-018-5953-1
. (1996). The function of the cerebellar uvula in monkey during optokinetic and pursuit eye movements: single-unit responses and lesion effects. Experimental Brain Research, 110, 1–14.
. (1991). Generation of smooth-pursuit eye movements: neuronal mechanisms and pathways. Neuroscience Research, 11, 79–107.
. (2019). Human Eye Movements Reveal Video Frame Importance. Computer, 52(5), 48–57. http://doi.org/10.1109/MC.2019.2903246
. (2017). Illusory motion reveals velocity matching, not foveation, drives smooth pursuit of large objects. Journal Of Vision, 17(12).
. (2015). A mechanism for decision rule discrimination by supplementary eye field neurons. Experimental Brain Research, 233, 459–476.