CHUBU UNIVERSITY
  • Print only the body of the page. Set to print background colors and images.
  • Print the whole page. Set to print background colors and images.

HIRATA Yutaka

Homepage

Profile

Year of Birth 1967
Place of Birth Tokyo
Title Professor
Belong to Dept. of Robotic Science and Technology
Computer Science (graduate school)
Robotic Science and Technology (graduate school)
Graduated Toyohashi University of Technology, Graduate School of Engineering
Degree Dr. of Engineering, Toyohashi University of Technology
Academic Institutional Membership The Institute of Electronics, Information and Communication Engineers, Vision Society of Japan, The Institute of Electrical and Electronics Engineers, Society for Neuroscience
Field of Study Biomedical Engineering, Systems Neuroscience, Space Neuroscience
Research, Studies Physiological and computational studies on motor learning and memory in primates and fish, Studies on human papillary control system
Curriculum Specialized Digital Signal Processing, Systems Control Engineering, Biomedical Engineering, Advanced Biomedical Engineering

Books Published, Translation

A Next Generation Modeling Environment PLATO: Platform for Collaborative Brain System Modeling, In ICONIP 2009, Ed. C.S. Leung, M. Lee, and J.H. Chan, Part I, LNCS 5863, pp. 84-90, Springer-Verlag Berlin Heidelberg, 2009.

Localizing sites for plasticity in the vestibular system. System identification approach, In The Vestibular System, Springer Verlag, 2004

Plasticity in the vertical VOR: A system identification approach to localizing the adaptive sites (joint work), In Recent developments in cerebellar research. Ed. SM Highstein and T. Thach. New York Academy of Science, 2002

Analysis of the Discharge Pattern of Floccular Purkinje Cells in Relation to Vertical Head and Eye Movement in the Squirrel Monkey (joint work), In Progress in Brain Research, Cerebellar Modules: Molecules, Morphology and Function, Ed. N. Gerrits and C. DeZeeuw. Elsevier, 2000

Academic Papers, Critique

Cerebellar role in predictive eye velocity initiation and termination. Journal of Neuroscience, Vol.38, No.48, pp.10371-10383, 2018, Nov.

Realtime micro saccade detection with convolutional neural network. Trans. IEICE, Vol. J101-D, No.2, pp.456-467, 2018, Feb.

Computational theory underlying acute vestibulo-ocular reflex motor learning with cerebellar long-term depression and long-term potentiation. Cerebellum, Vol.16, No.4, pp.827-839, 2017, Aug.

Medaka and zebrafish contactin1 mutants as a model for understanding neural circuits for motor coordination. Genes to Cells, 22, pp.723-741, 2017, June

Computational theory underlying acute vestibulo-ocular reflex motor learning with cerebellar long-term depression and long-term potentiation. Cerebellum, doi:10.1007/s12311-017-0857-6, 2017

Evaluation of Teaching Signals for Motor Control in the Cerebellum during Real-World Robot Application, Brain Sciences (Special Issue: Motor Control and Brain Plasticity), 6(4), 62, pp.1-17, 2016, Dec.

Realistic bi-hemispherical model of the cerebellum uncovers the purpose of the abundant granular cells during robot control, Frontiers in Neural Circuits, Vol.9, pp.1-13, 2015, May.

Mechanisms behind asymmetrical motor adaptation using a realistic bi-hemispherical neural network of the cerebellum for robot control, Frontiers in Neural Circuits, Vol.8, pp.1-14, 2014, Nov.

Customisation of Wavelet Function for Pupil Fluctuation Analysis to Evaluate Levels of Sleepiness, Journal of Communication and Computer, Vol.10, pp.585-592, 2013

Influences of mouth guards on autonomic nervous system activities: a quantitative study of pupillary flash responses. Oral Science International, vol.9, 2012, pp.38-42.

Simulation Platform: A Cloud-Based Online Simulation Environment, Neural Networks, Vol.24, No.7, pp.693-698, 2011, Sept.

A model-based theory on the signal transformation for the micro saccade generation, Neural Networks, Vol.24, No.9, pp.990-997, 2011, Nov.

Detect the Imperceptible Drowsiness, SAE Int. J. Passeng. Cars – Electron. Electr. Syst. Vol.3, No.1, pp.98-108, 2010, Aug.

Computer Simulation of Vestibuloocular Reflex Motor Learning Using a Realistic Cerebellar Cortical Neuronal Network Model. Neural Information Processing, Vol. 4984, pp.902-912, 2008

Relationship between residual aberration and light-adapted pupil size in human subjects. Optometry and Vision Science, Vol. 84, No.6, pp. 517-521, 2007, Jun.

Identification of loci involved in the memory of chronic motor learning of the vertical vestibuloocular reflex in squirrel monkeys. Cerebellum, Vol.5, No.4, pp.296-297, 2006

Chronic Changes in inputs to dorsal Y neurons accompany VOR motor learning.Journal of Neurophysiology, Vol.95, No. 3, pp.1812-1825, 2006, Mar.

Evaluation of the inverse dynamic model in cerebellum dueing visual-vestibular interactions at different VOR gains in squirrel monkeys, Neurocomputing, Vol.65-66, pp.709-717, Jun. 2005

Memory retention of vestibuloocular reflex motor learing in squirrel monkeys, Neuroreport, Vol.15, No.6, 2004

The vestibulo-ocular reflex as a model system for motor learing: what is the role of the cerebellum? Cerebellum, Vol.3, No.3, 2004

Function of the pupil in vision and information capacity of retinal image. Systems and Computers in Japan, Vol.34, No.9, pp.48-57, 2003, Dec.

Comparative physiology of postnatal developments of cardiopulmonary reflex. Biol. Sci. Space., Vol.17, No.3, pp.265-266, 2003, Oct.

Cerebellar signatures of VOR motor learning, J. Neuroscience, Vol.23, No.30, 2003

A dynamic model for the vertical vestibuloocular reflex and optokinetic response in primate, Neurocomputing, Vol.52-54, No.1, 2003

Capacity of vertical VOR adaptation in squirrel monkey, J, Neuroscience, Vol.23, No.30, 2003

Capacity of vertical VOR adaptation in squirrel monkey, J. Neurophysiology, Vol.88, No.6, 2002

Acute adaptation of the vestibuloocular reflex: signal processing by floccular and ventral parafloccular Purkinji cells. J. Neurophysiology, Vol.85, No.5 2001

Improvement of the method for monitoring autonomic nervous activity by pupillary flash response. Systems and Computers in Japan, Vol.32, No.13, pp.23-30, 2001

A Method for Monitoring Autonomic Nervous Activity by Pupillary Flash Response. Systems and Computers in Japan, Vol.31, No.4, 2000

An Analysis of Carp Cerebellar EEG under the Micro Gravitational Environment. Systems and Computers in Japan, Vol.27, No.3, pp.71-83, 1996

Estimation of Autonomic Nervous Activity using the Inverse Dynamic Model of the Pupil Muscle Plant. Annals of Biomedical Engineering, Vol.23, No.4, 1995

Parabolic Flight Experiments on Physiological Data Acquisition and Processing Technologies using Small Jet Aircraft (MU300). Journal of Gravitational Physiology, Vol.1, No.1, pp.92-95, 1994

Lectures, Symposium, Presentation

International meeting Proceedings (reviewed)

Human States Reflected in Eye Movements. The 1st International Workshop on Affective Computing for Social Robotics ACSR 2016, at IEEE RO-MAN 2016, pp.1-3, 2016, Aug. (New York City)

Bihemispheric cerebellar spiking network model to simulate acute VOR motor learning. International Conference on Neural Information Processing, ICONIP2016, pp.252-258, Spt. 30, 2016

A portable stand-alone bi-hemispherical neuronal network model of the cerebellum for engineering applications. Proc. 2014 IEEE International Conference on Robotics and Biomimetics, pp.1148-1151, 2014, Dec. (Bali)

Evaluation of hypersonic effect on biological signals that reflect alertness. Proc. 25th Annual International Conference of the IEEE Engineering in Medicine and Biology Society. 2014, Aug. (Chicago)

Microsaccades generated during car driving. Proc. 34th Annual International Conference of the IEEE Engineering in Medicine and Biology Society, pp.2148-2151, 2013, Jul. (Osaka)

Maintenance of high arousal level by voluntary driving maneuver using sensory feedback. ESV2013, p.71, 2013, Jun. (Seoul)

Cerebellar-Inspired Bi-Hemispheric Neural Network for Adaptive Control of an Unstable Robot. IEEE 2013 ISSNIP Biosignals and Biorobotics Conference (BRC), pp. 250-254, 2013, Feb. (Rio de Janeiro)

Cerebellum-Machine Interface to Understand Cerebellar Roles in Motor Learning. Proc. The 6th International Conference on Soft Computing and Intelligent Systems, The 13th International Symposium on Advanced Intelligent Systems, 2012, Nov. (Kobe)

Customization of wavelet function for pupil fluctuation analysis to evaluate levels of sleepiness. Proc. 11th International Conference on Signal Processing, pp.115-120, 2012, Apr. (Saint Malo & Mont Saint-Michel, France)

Effect of gravity on learning and memory of prism adaptation. Proc. 33rd Annual International Conference of the IEEE Engineering in Medicine and Biology Society, pp.3568-3572, 2011, Sep. (Boston)

Adaptive control of 2-wheeled balancing robot by cerebellar neuronal network model. Proc. 32nd Annual International Conference of the IEEE Engineering in Medicine and Biology Society, pp.1589-1592, 2010, Sep. (Buenos Aires)

Detect the Imperceptible Drowsiness. Proc. Society of Automotive Engineers World Congress 2010, Apr. (Detroit)

Detection and Prediction of Drowsiness by Reflexive Eye Movements Proc. 31st Annual International Conference of the IEEE Engineering in Medicine and Biology Society, pp.4015-4018, 2009, Sep. (Minneapolis)

Characterization of iris pattern stretches and application to the measurement of roll axis eye movements. Proc. 30th Annual International Conference of the IEEE Engineering in Medicine and Biology Society, pp.4949-4952, 2008, Aug. (Vancouver)

Computer simulation of vestibuloocular reflex motor learning using a realistic cerebellar cortical neuronal network model. Proc. The 14th International Conference on Neural Information Processing, 2007,Nov. (Kitakyushu)

The pupil as a possible premonitor of drowsiness. Proc. 29th Annual International Conference of the IEEE Engineering in Medicine and Biology Society, pp.1586-1589, 2007, Aug. (Lyon)

A realistic model of VOR motor learning with spiking cerebellar cortical neuronal network. Proc. 2006 International Symposium on Intelligent Signal Processing and Communication Systems (Yonago), pp. 915-918, 2006, Dec.

Mechanism of frequency selectivity in VOR motor learning: frequency channel or waveform learning? Proc. 28th Annual International Conference of the IEEE Engineering in Medicine and Biology Society (NY City), pp.6217-6220, 2006, Aug.30~Sep.3.

Model of VOR motor learning with spiking cerebellar cortical neuronal network. Proc. the Annual Computational Neuroscience Meeting 2006 (Edinburgh), p.57, 2006, Jul.

Interpretation of the heat rate variability during linear acceleration stimuli with the electrical circuit model of human cardiovascular system. Proc. The 27th annual international gravitational physiology meeting (Osaka), 2006, Apr.

Capacity of the horizontal vestibuloocular reflex motor learning in goldfish. Proc. 26th Annual International Conference of the IEEE Engineering in Medicine and Biology Society (San Francisco), pp.478-481, 2004, Sep.

Evaluation of the inverse dynamic model in cerebellum during visual-vestibular interactions at different VOR gains in squirrel monkeys. Proc. the Annual Computational Neuroscience Meeting 2004 (Baltimore), pp., 2004, Jul.

Analysis of cerebellar flocculus Purkinje cell firing patterns during visual-vestibular interactions before and in the process of VOR motor learning. Proc. 24th Annual International Conference of the IEEE Engineering in Medicine and Biology Society (Houston), pp.238-239, 2002, Oct.

A dynamic model for the vertical vestibuloocular reflex and optokinetic response in primate. Proc. the Annual Computational Neuroscience Meeting 2002 (Chicago), 2002, Jul.

Modeling of Primate Optokinetic and Vestibulo-ocular Reflex Systems. Proc. The 21st Annual International Conference of the IEEE Engineering in Medicine and Biology Society (Atlanta), p.403, 1999, Oct.

Assessment of the Sympathetic and the Parasympathetic Nervous Activity during Parabolic Flight by Pupillary Light Reflex. 12th Man in Space Symposium (Washington DC), pp. 1997, Jun.

An Analysis of the Cardiovascular Response under Hyper- and Hypo-Gravity Environments using a Mathematical Model. 12th Man in Space Symposium (Washington DC), pp., 1997, Jun.

The Pupil as a Monitor of the Autonomic Nervous System. Proc. the 19th Annual International Conference of the IEEE Engineering in Medicine and Biology Society (Chicago), pp.2777-2781, 1997, Oct.

Assessment of Autonomic Nervous Activity during Parabolic Flight. 20th International Symposium on Space Technology (Gifu), pp., 1996, May.

An Analysis of Carp Cerebellar EEG during Adaptation to Weightlessness. Proc. the 16th Annual International Conference of the IEEE Engineering in Medicine and Biology Society (Baltimore), pp.239-240, 1994, Nov.

Estimation of the Autonomic Nervous Activity from Pupillary Response. Proc. the 16th Annual International Conference of the IEEE Engineering in Medicine and Biology Society (Baltimore), pp.1170-1171, 1994, Nov.

Real time adaptive motor control by the cerebellar neuronal network model 18th Annual Meeting of Neural Control of Movement, 2008, Apr., Naples, Florida

International meeting Abstract

Online simulation environment for computational neuroscience and data analysis. INCF Congress 2017, Aug. 20-21., Kuala Lunpur.

Development of oculo-feedback system: Manipulation of microsaccade generation. Society for Neuroscience, 2016, Nov., San Diego.

Role of the cerebellum in the initiation and termination of predictive optokinetic behavior in goldfish. Society for Neuroscience, 2016, Nov., San Diego.

Evaluation of roles of cerebellar Golgi and basket/stellate cells in the vestibuloocular reflex motor learning: a computational study. Society for Neuroscience, 2016, Nov., San Diego.

Real-time artificial cerebellum to study neuronal mechanisms of motor learning. The 3rd RIEC International Symposium on Brain Functions and Brain Computer, p.11, 2015, Feb., Tohoku Univ.

Visual attention and individual miniature saccadic eye movements generated during car driving. Society for Neuroscience, 2014. Nov., Washington DC.

Predictive eye movements acquired by repetitive periodic optokinetic visual stimulation in goldfish. Society for Neuroscience, 2014. Nov., Washington DC.

Cerebellar dependent motor learning of predictive eye movements associated with velocity storage in human and fish. Society for Neuroscience, 2015. Nov., Chicago.

Both brighter visual stimuli and hyper-gravity promote oculomotor neural integrator learning in goldfish. Society for Neuroscience, 2015. Nov., Chicago.

Effects of reward and penalty associated with driving performance on maintenance of car driver’s aleartness. Proc. the 37th Annual International Conference of the IEEE Engineering in Medicine and Biology Society, 2015, Aug. (Milan)

Development of an on-line simulation platform for neuroscience research. The 8th INCF Congress of Neuroinformatidcs, Abstract Book, p.82, 2015, Aug., Cairns

Different roles for ipsilateral positive feed back and commissural inhibitory networks in oculomotor velocity to position neural integration. 24th Annual Computational Neuroscience Meeting CNS*2015, 2015, Jul,. Prague. BMC Neurosci., 16(Supple 1): P100, 2015, Dec.

Real-time artificial cerebellum to study neuronal mechanisms of motor learning. The 3rd RIEC International Symposium on Brain Functions and Brain Computer, p.11, 2015, Feb., Tohoku Univ.

Visual attention and individual miniature saccadic eye movements generated during car driving. Society for Neuroscience, 2014. Nov., Washington DC.

Predictive eye movements acquired by repetitive periodic optokinetic visual stimulation in goldfish. Society for Neuroscience, 2014. Nov., Washington DC.

The number of granular cells in a cerebellar neuronal network model engaged during robot control increases with the complexity of the motor task. 23rd Annual Computational Neuroscience Meeting CNS*2014, 2014, Jul., Quebec. BMC Neuroscience, vol.15 (Suppl 1), p.143

Spontaneous firing activity in climbing fiber is critical for a realistic bi-hemispherical cerebellar neuronal network during robot control. 23rd Annual Computational Neuroscience Meeting CNS*2014, 2014, Jul., Quebec. BMC Neuroscience, vol.15 (Suppl 1), p.142

Relationship between driver’s attention and micro-saccadic eye movements. FISTA World Automotive Congress, 2014 Netherland

Simulation of oculomotor control and learning by a realistic spiking cerebellar neuronal network model. The 2nd RIEC International Symposium on Brain Functions and Brain Computer, p.10, 2014, Jan., Tohoku Univ.

Period tuning of the optokinetic response: A new cerebellar dependent predictive motor learning? The 2nd RIEC International Symposium on Brain Functions and Brain Computer, p.16, 2014, Jan., Tohoku Univ.

Oculomotor test bench for developing zebrafish larvae. 6th Asia Oceania Zebrafish Meetoing, Additional Abstracts p.5, 2014, Jan., Hong Kong

Frequency dependent VOR motor learning in normal and cerebellectomized goldfish. Society for Neuroscience, 2013. Nov., San Diego.

Active driving maneuver to maintain high arousal level. FAST-zero’13, p.31, 2013, Sep., Nagoya

Construction of a bi-hemispheric cerebellar neuronal network model with realistic climbing fiber input and its application to adaptive control of an unstable robot. The 1st RIEC International Symposium on Brain Functions and Brain Computer, 2012, Nov., Tohoku Univ.

Bi-hemispheric model of the cerebellum with realistic climbing fiber input Society for Neuroscience, 2012. Oct., New Orleans.

Unaware drowsiness deeply in the pupil. The 5th International Conference on Traffic and Transport Psychology, 2012, Aug., Groningen, The Netherlands

Improvement of Simulation Platform for providing reliable and easy use model simulation environment. INCF congress, Abstract Book, 2012, Sep., Munich

Adaptive control of 2-wheeled balancing robot by two hemispheric cerebellar neuronal network model. 21st Annual Computational Neuroscience Meeting CNS*2012, 2012, Jul. Atlanta. BMC Neuroscience, vol.13 (Suppl 1), pp.118-119

A cerebellum-machine interface enables changes in neuronal activity to be causally linked with behavioral adaptation. Global COE International Symposium –Electronic Devices Innovation (EDIS 2011), pp.1-2, 2011, Dec. (Osaka)

Monocular and binocular behavior of the oculomotor neural integrator in goldfish. Society for Neuroscience, 2011. Nov., Washington DC.

Direct causality between single Purkinje cell activities and motor learning revealed by a cerebellum-machine interface utilizing VOR adaptation paradigm. 4th International Symposium Society for Research on the Cerebellum. 2011, Sep.

Simulation Platform. INCF congress, Abstract Book, pp.318-319, 2011, Sep., Boston

Monocular eye position specificity in the oculomotor neural integrator

20th Annual Computational Neuroscience Meeting CNS*2011, 2011, Jul. Stockholm. BMC Neuroscience, vol.12, Suppl 1, pp.151-152, 2011

Simulation Platform: Cloud-computing meets computational neuroscience

20th Annual Computational Neuroscience Meeting CNS*2011, 2011, Jul. Stockholm. BMC Neuroscience, vol.12, Suppl 1, pp.346-347, 2011

Adaptive control of a robot arm by a single Purkinje cell using a vestibolo-ocular reflex motor learning paradigm. Program No. 786.6. 2010 Abstract Viewer/Itinerary Planner: Society for Neuroscience, 2010. Online. San Diego

Cerebellar Brain Machine Interface to evaluate roles of a single Purkinje cell in motor learning. Neuroscience Research 685, e328, 2010 (Neuro2010, Kobe)

Simulation Platform: Model simulation on the cloud. Frontiers in Neuroinformatics. Conference Abstract: INCF Neuroinformatics2010, 2010, Sep., Kobe.

Environment for an integrative model simulation: PLATO. INCF Neuroinformatics2010, 2010, Sep., Kobe, accepted.

A modeling study on the signal transformation for the microsaccade generation. 19th Annual Computational Neuroscience Meeting CNS*2010, 2010, Jul. Submitted

The origin of the frequency selectivity in VOR motor learning revealed by a realistic cerebellar spiking neuron network model. 19th Annual Computational Neuroscience Meeting CNS*2010, 2010, Jul.

Proposal of Inside-Out camera for measuring 3D gaze position in free space, CVPR2009 Video review, 2009

Position-specific training in the oculomotor neural integrator. the Second International Symposium of the Society for Research on the Cerebellum, 2009, Oct., Chicago

Is a cerebellar Purkinje cell capable of controlling a non-biological motor sysytem? the Second International Symposium of the Society for Research on the Cerebellum, 2009, Oct., Chicago

Platform for collaborative brain system modeling (PLATO). Program No. 290.21. 2009 Abstract Viewer/Itinerary Planner: Society for Neuroscience, 2009. Online., Chicago

Position-specific training in the oculomotor neural integrator. Program No. 356.1. 2009 Abstract Viewer/Itinerary Planner: Society for Neuroscience, 2009. Online., Chicago

Changes in cerebellar Purkinje cell firing modulation during frequency differential VOR motor learning in goldfish. Program No. 660.22. 2009 Abstract Viewer/Itinerary Planner: Society for Neuroscience, 2009. Online., Chicago

Simulation Platform: a test environment of computational models via web. Frontiers in Neuroinformatics. Conference Abstract: 2nd INCF Congress of Neuroinformatics, Pilsen, Czech Republic, 2009, Sep.

Adaptive DC motor control by a cerebellar Purkinje cell, the 7th edition of Progress in Motor Control, 2009, Jul., Marseille, France

Real time adaptive motor control by the cerebellar neuronal network model, 18th Annual Meeting of Neural Control of Movement, 2008, Apr., Naples, Florida

Comparison of vestibuloocular reflex motor learning induced by active and passive head motion in goldfish. Program No. 190.2. 2007 Abstract Viewer/Itinerary Planner: Society for Neuroscience, 2007. Online.

Cerebellar flocculus Purkinje cell complex spikes during VOR in the dark before and after VOR motor learning in squirrel monkeys. Program No. 190.3. 2007 Abstract Viewer/Itinerary Planner: Society for Neuroscience, 2007. Online.

The Cerebellar Neuroinformatics Platform: the structure and function. Program No. 190.6. 2007 Abstract Viewer/Itinerary Planner: Society for Neuroscience, 2007. Online.

Neuroinformatics Database for Pupil Research. 27th Pupil Colloquium, 2007, Oct., Hamamatsu

Evaluation of driver’s sleepiness by pupillary fluctuation and anti-saccade reaction time: 27th Pupil Colloquium, 2007, Oct., Hamamatsu

Origin of the frequency selectivity in acute VOR motor learning: Modifiable frequency channels or waveform transformation? Program No. 805.9. 2006 Abstract Viewer/Itinerary Planner: Society for Neuroscience, 2006. Online.

Flocculus Purkinje cell complex spikes during acute motor learning of the horizontal vestibuloocular reflex in squirrel monkeys. Program No. 805.6. 2006 Abstract Viewer/Itinerary Planner: Society for Neuroscience, 2006. Online.

Cerebellar cortical network model for vestibuloocular reflex motor learning. Program No. 392.17. 2005 Abstract Viewer/Itinerary Planner: Society for Neuroscience, 2005. Online.

Left-right asymmetrical and frequency selective motor learning and memory in goldfish vestibulo-ocular reflex. Program No. 989.15. 2004 Abstract Viewer/Itinerary Planner: Society for Neuroscience, 2004. Online.

The Y group revisited following VOR adaptation. Program No. 989.9. 2004 Abstract Viewer/Itinerary Planner: Society for Neuroscience, 2004. Online.

Cerebellar floccular role in up-down asymmetrical motor learning of the vestibulo-ocular reflex. Program No. 73.11. 2003 Abstract Viewer/Itinerary Planner: Society for Neuroscience, 2003. Online.

Changes in response of cerebellar Purkinje cells following chronic VOR adaptation. Program No. 703.4. 2003 Abstract Viewer/Itinerary Planner: Society for Neuroscience, 2003. Online.

Changes in vertical optokinetic responses following VOR adaptation in the squirrel monkey. Program No. 603.7. 2003 Abstract Viewer/Itinerary Planner: Society for Neuroscience, 2003. Online.

Quantification of the period of decay of novel VOR gains acutely acquired by visual-vestibular mismatch in squirrel monkeys. Program No. 766.16. 2002 Abstract Viewer/Itinerary Planner: Society for Neuroscience, 2002. Online.

Inverse dynamic representation of flocculus Purkinje cell firing patterns during vertical visual- vestibular interaction leading to VOR adaptation in squirrel monkey. Program No. 766.17. 2002 Abstract Viewer/Itinerary Planner: Society for Neuroscience, 2002. Online.

Influence of the eye refraction on the luminance-pupil diameter relationship. Fall vision meeting in cooperation with the optical society of America, Abstr., 2002, Oct.

A dynamical model for vertical VOR, optokinetic response and visual-vestibular interactions in primate. XXII Meeting of the Barany Society, Vestibular influences on Movement Abstr., 2002, Sep.

Effect of pupil size on the quality of retinal images. Annual Meeting of the Association for Research in Vision and Ophthalmology (ARVO), CD-ROM, 2002, May.

Evaluation of possible error signals used in vertical vestibuloocular reflex adaptation in squirrel monkeys. Program No. 403.16. 2001 Abstract Viewer/Itinerary Planner: Society for Neuroscience, 2001. Online.

Response of Floccular Purkinje cells following chronic adaptation of the vertical VOR. Program No. 403.12. 2001 Abstract Viewer/Itinerary Planner: Society for Neuroscience, 2001. Online.

Function of the pupil in vision and information capacity of retinal image. 24th Pupil Colloquium Abstr., 2001, Sep.

Capacity of vertical vestibulo ocular reflex adaptation in squirrel monkey. 30th Annual Meeting Society for Neuroscience, Abstr. 26, p.1714, 2000, Nov.

Analysis of Discharge Pattern of Cerebellar Purkinje Cells before and during Adaptation of the Vestibulo Ocular Reflex in the Squirrel Monkey. 29th Annual Meeting Society for Neuroscience, Abstr. 25, p.371, 1999, Nov.

Identification of the Site(s) of Vestibulo-ocular Reflex Motor Learning in Primate based on Single Unit Recording of Cerebellar Flocculus Purkinje Cell Activity. The IVth International Symposium on the Head/Neck System, p.32, 1999, Aug.

Multiple Linear Regression Analysis of Floccular Purkinje Cell Activity during Vertical Visual Following in Squirrel Monkeys. 28th Annual Meeting Society for Neuroscience Abstr. 24, p.1405, 1998, Nov.

Evaluation of the Autonomic Nervous System Activity in Hyper- and Hypo-Gravity using Pupillary Response to Comb-like Flash. 22nd Pupil Colloquium, 1997, Sep.

Subcellular Calcium Regulation in Microgravity. Abstracts of the 4th IBRO World Congress of Neuroscience, p.78, 1995, Jun.

Estimation of the Autonomic Nervous Input by the Inverse Dynamic Model for Human Pupillary Muscle Plant. 20th Pupil Colloquium, 1993, Sep.

Pupillary Light Response during a Parabolic Flight. 40th International Congress of Aviation and Space Medicine, p.141, 1992, Jun.

Nonlinear Dynamics Model for Human Pupillary Light Reflex System. 19th Pupil Colloquium, 1991, Sep.

Domestic meeting, symposium

Most in Japanese. University policy does not allow us to list information in Japanese here, thus omitted. Please go to Japanese page if interested in.

Invited Symposium, Seminar talk

The cerebellum is necessary but not sufficient for the acquisition of predictive motor control: in the case of optokinetic eye movement in zebrafish, medaka, carp, goldfish, and humans. Friday lunch seminar, 2017, Jun., CiNET

Adaptive control of reflexive eye movements in fish and humans: Goldfish BMI, Artificial cerebellum, and Sleepiness prediction. The Irago Conference 2016, 2016, Nov., Dentsu Univ.

Predictors of sleepiness in your eyes. Neuroscience Seminar, Washington University School of Medicine, Aug.25, 2016

Neural mechanisms of adaptive oculomotor control. from animal experiments, neuronal circuitry modeling, cerebellum-machine interface to robot control, sleepiness detection, and motor learning promotion. 2016, Jul. Okinawa Institute of Science and Technology.

Hyper-gravity accelerates motor learning in goldfish and humans as predicted in Dragon Ball. Neuroscience Seminar, Washington University School of Medicine, Sep., 2015

Cerebellar dependent adaptation of reflexive eye movements in fish and primates. The Blazquez Laboratory Seminar, Washington University School of Medicine, Aug.25, 2014

What we have learned from the comparison of eye movement performance and plasticity in fish and primates. The Jenks Vestibular Physiology Laboratory Seminar, Massachusetts Eye and Ear Infirmary, Aug.18, 2014

Understanding of reflexive eye movement control by neurophysiology, modeling-simulation, and brain-machine interface. Oculomotor group seminar, Univ. of Washington, Nov.15, 2013.

From fish VOR to human VOR. Neuroscience seminar, Putra Malaysia University, Mar.21, 2013

The pupil and the VOR. Neuroscience seminar. University of Munich Hospital, 2011, Mar.

Cerebellum-Machine Interface to understand the cerebellum as an adaptive motor controller. CoTeSys Seminar. Technische Universitat Munhen, Mar.2, 2011.

What can we learn from goldfish about cerebellar motor learning? Neuroscience seminar. Stanford University, Nov.19, 2010.

Gain-up & down motor learning in oculomotor control: inverse processes at the same site(s)? Cerebellar Colloquium, RIKEN BSI, Wako, 2006, Apr.

Field Work, Creative Works

TV, Newspaper coverage

All in Japanese. University policy does not allow us to list information in Japanese here, thus omitted. Please go to Japanese page if interested in.

Awards

IEICE Human Communication Award, December 17, 2014

IEICE best paper award, May 26, 2013

JNNS research award, December 16, 2011

Masao Ito Prize, September 18, 2011

Paper award from the institute of electronics, informaton and communication engineers, 1996

Inose award (best paper award) from the institute of electronics, informaton and communication engineers, 1996

Page Top