HTML5 Webook

42/112

参考文献】【1Ban, H., Preston, T.J., Meeson, A., and Welchman, A.E., “The integra-tion of motion and disparity cues to depth in the dorsal visual cortexm,” Nature Neuroscience, vol.15, no.4, pp.636–643, 2012.2Dekker, T., Ban, H., van der Velde, B., Sereno, M.I., Welchman, A.E., and Narandini, M., “Late development of cue integration is linked to sensory fusion in cortex,” Current Biology, vol.25, no.21, pp.2856–2861, 2015.3Dovencioglu, D., Ban, H., Schofield, A.J., and Welchman, A.E., “Per-ceptual Integration for Qualitatively Different 3-D Cues in the Human Brain”. Journal of Cognitive Neuroscience, vol.25, no.9, pp.1527–1541, 2013.4Murphy, A., Ban, H., and Welchman, A.E., “Integration of texture and disparity cues to surface slant in dorsal visual cortex,” Journal of Neu-rophysiology, vol.110, Issue 1, pp.190–203, 2013.5Nadler, J. W., Barbash, D., Kim, H. R., Shimpi, S., Angelaki, D. E., and DeAngelis, G. C., “Joint representation of depth from motion parallax and binocular disparity cues in macaque area MT,” Journal of Neurosci-ence, vol.33, no.35, pp.14061–14074, 2013.6Armendariz, M., Ban, H., Welchman, A. E., and Vanduffel, W., “Areal differences in depth cue integration between monkey and human,” PLoS biology, vol.17, no.3, e2006405, 2019.7Ban, H. and Welchman, A.E. “fMRI Analysis-by-Synthesis Reveals a Dorsal Hierarchy That Extracts Surface Slant,” Journal of Neuroscience. vol.35, no.27, pp.9823–9835, 2015.8Goncalves, N. R., Ban, H., Sánchez-Panchuelo, R. M., Francis, S. T., Schluppeck, D., and Welchman, A. E., “7 tesla FMRI reveals system-atic functional organization for binocular disparity in dorsal visual cor-tex,” Journal of Neuroscience, vol.35, no.7, pp.3056–3072 ,2015.9Watt, S. J. and Bradshaw, M. F. “Binocular information in the control of prehensile movements in multiple-object scenes,” Spatial Vision, vol.15, pp.141–155, 2002.10Julesz, B., “Foundations of cyclopean perception,” Cambridge, MA: MIT Press, 1971.11Blake, A. and Bülthoff, H. “Does the brain know the physics of specu-lar reflection?,” Nature, vol.343, pp.165–168, 1990.12Norman, J. F., Todd, J. T., and Orban, G. A., “Perception of three-di-mensional shape from specular highlights, deformations of shading, and other types of visual information,” Psychological Science, vol.15, no.8, pp.565–570, 2004.13Tittle, J. S., Todd, J. T., Perotti, V. J., and Norman, J. F. “Systematic distortion of perceived three-dimensional structure from motion and binocular stereopsis,” Journal of Experimental Psychology: Human Perception and Performance, vol. 21, no.3, pp.663–678, 1995.14Welchman, A. E., “The human brain in depth: How we see in 3D,” Annual Review of Vision Science, vol.2, pp.345–376, 2016.15Preston, T. J., Li, S., Kourtzi, Z., and Welchman, A. E., “Multivoxel pattern selectivity for perceptually relevant binocular disparities in the human brain,” Journal of Neuroscience, vol.28, no.44, pp.11315–11327, 2008.16Uka, T., Tanabe, S., Watanabe, M., and Fujita, I., “Neural correlates of fine depth discrimination in monkey inferior temporal cortex,” Journal of Neuroscience, vol.25, pp.10796–10802, 2005.17Tsao, D. Y., Vanduffel, W., Sasaki, Y., Fize, D., Knutsen, T. A., Mandev-ille, J. B., et al. “Stereopsis activates V3A and caudal intraparietal areas in macaques and humans,” Neuron, vol.39, Issue 3, pp.555–568, 2003.18Hansen, T., Olkkonen, M., Walter, S., Gegenfurtner, K. R. “Memory modulates color appearance,” Nature Neuroscience, vol.9, no.11, pp.1367–1368, 2006.19Murray, S. O., Kersten, D., Olshausen, B. A., Schrater, P., and Woods, D. L., “Shape perception reduces activity in human primary visual cortex,” Proceedings of the National Academy of Sciences, U.S.A., vol.99, pp.15164–15169, 2002.20Wong, N. H., Ban, H., and Chang, D. H. “Human depth sensitivity is affected by object plausibility,” Journal of Cognitive Neuroscience, vol.32, no.2, pp.338–352, 2020.21Chou, I. W., Ban, H., and Chang, D. H., “Modulations of depth re-sponses in the human brain by object context: Does biological rele-vance matter?”, eNeuro, vol.8, no.4, 2021.番 浩志 （ばん ひろし）未来ICT研究所脳情報通信融合研究センター脳情報通信融合研究室主任研究員博士（人間・環境学）視覚情報処理、心理学、神経科学【受賞歴】2020年 HKU Social Sciences Outstanding Research Output Award (Basic Research) (香港)2018年 Poster Presentation Award, Social and Affective Neuroscience Society (US)2017年 Best Presentation Award, ヒト脳機能イメージング研究会相原 孝次 （あいはら たかつぐ）未来ICT研究所脳情報通信融合研究センター脳情報通信融合研究室研究員博士（身体教育学）視覚情報処理、心理学、神経科学Bayu Gautama Wundari （ウンダリ バユ ゴータマ）未来ICT研究所脳情報通信融合研究センター脳情報通信融合研究室研究員博士（工学）視覚情報処理、心理学、神経科学38　　　情報通信研究機構研究報告 Vol.68 No.1 （2022）3　ICTの最適化のための脳情報通信技術