Publications

Face perception as a multisensory process. Face perception as a multisensory process. Date Published 01/2020, “Multisensory and Crossmodal Interactions” symposium, EI/HVEI: Burlingame, California. Retrieved from https://www.imaging.org/site/IST/Conferences/EI/EI_2020/

Face perception as a multisensory process. Face perception as a multisensory process. Date Published 2020, “Multisensory and Crossmodal Interactions” symposium, EI/HVEI: Burlingame, California. Retrieved from https://www.imaging.org/site/IST/Conferences/EI/EI_2020/Conference/C_HVEI.aspx

Face perception as a multisensory process. Face perception as a multisensory process. Date Published 01/30/2020, Multisensory and Crossmodal Interactions, at IS&T Human Vision and Electronic Imaging: Burlingame, California. Retrieved from https://www.imaging.org/site/IST/Conferences/EI/EI_2020/

Harnessing the power of visual art to drive brain plasticity to enhance learning and memory in STEM education, and in blindness rehab. Harnessing the power of visual art to drive brain plasticity to enhance learning and memory in STEM education, and in blindness rehab. Bay Area Science Fair (BASF).

Perception and Appreciation of Tactile Objects: The Role of Visual Experience and Texture Parameters. Perception and Appreciation of Tactile Objects: The Role of Visual Experience and Texture Parameters. Jpi Special Issue On Multisensory And Crossmodal Interactions. Editors: Likova, L.t., Jiang, F., Stilles, N., Tanguay, A.r.

Rapid training of supramodal spatial cognition and memory for improved navigation in low vision and blindness. Rapid training of supramodal spatial cognition and memory for improved navigation in low vision and blindness. Investigative Ophthalmology and Vision Science (iOVS). ARVO 2020. Retrieved from https://iovs.arvojournals.org/article.aspx?articleid=2766791

Magnetic Head, N 1164781, G 11 B 5/10, Moscow, Russia. (1985). Magnetic Head, N 1164781, G 11 B 5/10, Moscow, Russia.

Magnetic Head, N 30903, G 11 B 5/10, Sofia, Bulgaria. (1985). Magnetic Head, N 30903, G 11 B 5/10, Sofia, Bulgaria.

Magnetic Head, N 237417, G 11 B 5/10, Prague, Czech Republic. (1986). Magnetic Head, N 237417, G 11 B 5/10, Prague, Czech Republic.

Visual pattern recognition based on neural network models. (1988). Visual pattern recognition based on neural network models. Methodology of the Mathematical Modeling; 23: 97-102.

The discrimination of abrupt changes in speed and direction of visual motion. (2000). The discrimination of abrupt changes in speed and direction of visual motion. Vision Research, 40, 409–415. http://doi.org/https://doi.org/10.1016/S0042-6989(99)00185-6

EEG frequency dynamics during movements imagery. (2000). EEG frequency dynamics during movements imagery. Acta Physiologica Et Pharmacologica Bulgarica, 26, 115–118.

Failure of stereomotion capture in an object disappearance paradigm. (2003). Failure of stereomotion capture in an object disappearance paradigm. Is&T/Spie Electronic Imaging. Retrieved from http://doi.org/10.1117/12.485517

Peak localization of sparsely sampled luminance patterns is based on interpolated 3D surface representation. (2003). Peak localization of sparsely sampled luminance patterns is based on interpolated 3D surface representation. Vision Research, 43, 2649–2657. http://doi.org/org/10.1016/S0042-6989(02)00575-8

Spatiotemporal relationships in a dynamic scene: stereomotion induction and suppression. (2003). Spatiotemporal relationships in a dynamic scene: stereomotion induction and suppression. Journal Of Vision, 3. http://doi.org/10.1167/3.4.5

Is the hMT+/V5 complex in the human brain involved in stereomotion perception? An fMRI study. (2004). Is the hMT+/V5 complex in the human brain involved in stereomotion perception? An fMRI study. Electronic Imaging 2004. http://doi.org/10.1117/12.568026

Predominantly extra-retinotopic cortical response to pattern symmetry. (2004). Predominantly extra-retinotopic cortical response to pattern symmetry. Neuroimage, 24, 306–314. http://doi.org/doi.org/10.1016/j.neuroimage.2004.09.018

Extended concepts of occipital retinotopy. (2005). Extended concepts of occipital retinotopy. Current Medical Imaging Reviews, 1, 319–329. http://doi.org/http://dx.doi.org/10.2174/157340505774574772

Transient-based image segmentation: top-down surround suppression in human V1. (2005). Transient-based image segmentation: top-down surround suppression in human V1. Is&T/Spie Electronic Imaging. Retrieved from http://doi.org/10.1117/12.610865

The specificity of cortical region KO to depth structure. (2006). The specificity of cortical region KO to depth structure. Neuroimage, 30, 228–238. http://doi.org/doi.org/10.1016/j.neuroimage.2005.09.067

Crowding: A neuro-analytic approach. (2007). Crowding: A neuro-analytic approach. Journal Of Vision, Http:// Journalofvision.org/7/2/16/ , 7(2)(16). http://doi.org/10.1167/7.2.16

Instantaneous stimulus paradigm: cortical network and dynamics of figure-ground organization. (2007). Instantaneous stimulus paradigm: cortical network and dynamics of figure-ground organization. Is&T/Spie Electronic Imaging Xii, 64921E. Retrieved from http://doi.org/10.1117/12.707556

Stereomotion processing in the human occipital cortex. (2007). Stereomotion processing in the human occipital cortex. Neuroimage, 38, 293–305. http://doi.org/org/10.1016/j.neuroimage.2007.06.039

Occipital network for figure/ground organization. (2008). Occipital network for figure/ground organization. Experimental Brain Research, 189, 257–267. http://doi.org/ 10.1007/s00221-008-1417-6

An Algebra for the Analysis of Object Encoding. (2010). An Algebra for the Analysis of Object Encoding. Neuroimage, 50, 1243–1250. http://doi.org/doi.org/10.1016/j.neuroimage.2009.10.091