Publikationen von M Watanabe
Alle Typen
Zeitschriftenartikel (30)
21.
Zeitschriftenartikel
91 (6), S. 396 - 407 (2004)
An explanation of contextual modulation by short-range isotropic connections and orientation map geometry in the primary visual cortex. Biological Cybernetics 22.
Zeitschriftenartikel
35 (12), S. 57 - 66 (2004)
Change of memory formation according to STDP in a continuous-time neural network model. Systems and Computers in Japan 23.
Zeitschriftenartikel
15 (5), S. 980 - 986 (2004)
A network of coincidence detector neurons with periodic and chaotic dynamics. IEEE Transactions on Neural Networks 24.
Zeitschriftenartikel
16 (3), S. 251 - 265 (2004)
Spatial Localization of Synapses Required for Supralinear Summation of Action Potentials and EPSPs. Journal of Computational Neuroscience 25.
Zeitschriftenartikel
71 (1-2), S. 213 - 220 (2003)
Forward propagating reinforcement learning: biologically plausible learning method for multi-layer networks. Biosystems 26.
Zeitschriftenartikel
14 (4-5), S. 395 - 406 (2001)
Solving the binding problem of the brain with bi-directional functional connectivity. Neural networks 27.
Zeitschriftenartikel
58 (1-3), S. 259 - 263 (2000)
Associative memory model with temporal spike coding and active dendrite. Biosystems 28.
Zeitschriftenartikel
10 (8), S. 1353 - 1359 (1997)
Chaos in Neural Networks Composed of Coincidence Detector Neurons. Neural networks 29.
Zeitschriftenartikel
78 (2), S. 87 - 93 (1997)
A dynamic neural network with temporal coding and functional connectivity. Biological Cybernetics 30.
Zeitschriftenartikel
79 (3), S. 87 - 93 (1996)
Automatic learning in chaotic neural networks. Electronics and Communications in Japan III: Fundamental Electronic Science Buch (1)
31.
Buch
From Biological to Artificial Consciousness: Neuroscientific Insights and Progress. Springer, Cham, Switzerland (2022), 172 S.
Buchkapitel (2)
32.
Buchkapitel
14, S. 2588 - 2592 (Hg. Binder, M.; Hirokawa, N.; Windhorst, U.). Springer, Berlin, Germany (2009)
Neural Networks and Architectures. In: Encyclopedia of Neuroscience, Bd. 33.
Buchkapitel
Cognitive User Modeling Computed by a Proposed Dialogue Strategy Based on an Inductive Game Theory. In: Machine Learning and Robot Perception, S. 325 - 351 (Hg. Apolloni, B.; Ghosh, A.; Alpaslan, F.; Jain, L.; Patnaik, S.). Springer, Berlin, Germany (2005)
Konferenzbeitrag (2)
34.
Konferenzbeitrag
Dynamic decision making: neuronal, computational, and cognitive underpinnings. In: 34th Annual Meeting of the Cognitive Science Society (CogSci 2012), S. 50 - 51 (Hg. Miyake, N.; Peebles, D.; Cooper, R.). 34th Annual Meeting of the Cognitive Science Society (CogSci 2012), Sapporo, Japan, 01. August 2012 - 04. August 2012. Cognitive Science Society, Austin, TX, USA (2012)
35.
Konferenzbeitrag
Self-organization dynamics in chaotic neural networks. In: Control and Chaos, S. 320 - 332 (Hg. Judd, K.; Mees, A.; Keo, K.; Vincent, T.). US Australia Workshop on Control and Chaos 1995, Honolulu, HI, USA, 29. Juni 1995 - 01. Juli 1995. Birkhäuser, Boston, MA, USA (1997)
Meeting Abstract (1)
36.
Meeting Abstract
A Turing Test for Visual Qualia: An Experimental Method to Test Various Hypotheses on Consciousness. In 20th Anniversary Conference Toward a Science of Consciousness (TSC 2014), S. 120. 20th Anniversary Conference Toward a Science of Consciousness (TSC 2014), Tucson, AZ, USA, 21. April 2014 - 26. April 2014. (2014)
Vortrag (6)
37.
Vortrag
Cracking neural consciousness by machine consciousness. Second Meeting of Consciousness Research Network (CoRN 2019), Okazaki, Japan (2019)
38.
Vortrag
Mouse primary visual cortex is not part of the reverberant neural circuitry critical for visual perception. 5th Mini-Symposium on Cognition, Decision-Making and Social Function: In Memory of Kang Cheng, Wakō, Japan (2017)
39.
Vortrag
Visual Backward Masking and Optogenetic V1 Suppression in Mice: Turing Test for Machine Consciousness and its Validation using Split-Brain Mice. Consciousness Club Tokyo, Tokyo, Japan (2016)
40.
Vortrag
A Turing Test for Visual Qualia and the Chaotic Spatiotemporal Fluctuation Hypothesis. Stanford University: Center for the Explanation of Consciousness, Stanford, CA, USA (2014)