◆Information on Regular Admission▶Regular Admission
The faculty of Department of System Innovation by their priory area are as follows.
Name | Research priority area | Position | keyword |
---|---|---|---|
OKABE Yoji | Networking for Artifact |
|
Advanced composite materials, Structural health monitoring, Non-destructive inspection, Ultrasonic guided waves, Optical fiber sensors |
SHIBATA Kazuya | Networking for Artifact |
|
Fluid Simulation, Naval Architecture and Ocean Engineering, Disaster prevention and mitigation, explanation of phenomena, optimization |
WAN Yi | Networking for Artifact |
|
Material engineering, Experimental evaluation, Modeling analysis, Carbon fiber reinforced composites |
TAKAHASHI Jun | Networking for Artifact |
|
Carbon fiber reinforced thermoplastics, future transportation and logistics systems, innovative simulation, superfunctional materials |
KOSHIZUKA Seiichi | Networking for Artifact |
|
Computer simulation, Physics-based CG, Fluid dynamics, Solid dynamics, Venture |
KAWABATA Tomoya | Networking for Artifact |
|
Hydrogen society, Steel material, Fracture mechanics, Natural gas, Pipeline, Storage tank, Earthquake |
SUZUKI Katsuyuki | Networking for Artifact |
|
Computational mechanics, Optimal design, Structural mechanics, Ship structure |
YONEKURA Kazuo | Networking for Artifact |
|
Optimization, Machine Learning, Aerospace system |
SHIBANUMA Kazuki | Networking for Artifact |
|
Fracture mechanics, Structural integrity |
HOUTANI Hidetaka | Networking for Artifact |
|
Ocean Waves, Ocean Engineering, Seakeeping Performance of Ships, Tank Experiment, Hydroelasticity |
SUZUKI Hideyuki | Networking for Artifact |
|
ocean renewable energy, floating offshore wind turbine, resource and energy development, ocean space utilization, CO2 ocean storage |
Name | Research priority area | Position |
---|---|---|
keyword_en | ||
YONEKURA Kazuo | Networking for Artifact |
|
Optimization, Machine Learning, Aerospace system | ||
SUZUKI Hideyuki | Networking for Artifact |
|
ocean renewable energy, floating offshore wind turbine, resource and energy development, ocean space utilization, CO2 ocean storage | ||
SHIBANUMA Kazuki | Networking for Artifact |
|
Fracture mechanics, Structural integrity | ||
HOUTANI Hidetaka | Networking for Artifact |
|
Ocean Waves, Ocean Engineering, Seakeeping Performance of Ships, Tank Experiment, Hydroelasticity | ||
SUZUKI Katsuyuki | Networking for Artifact |
|
Computational mechanics, Optimal design, Structural mechanics, Ship structure | ||
OKABE Yoji | Networking for Artifact |
|
Advanced composite materials, Structural health monitoring, Non-destructive inspection, Ultrasonic guided waves, Optical fiber sensors | ||
WAN Yi | Networking for Artifact |
|
Material engineering, Experimental evaluation, Modeling analysis, Carbon fiber reinforced composites | ||
KOSHIZUKA Seiichi | Networking for Artifact |
|
Computer simulation, Physics-based CG, Fluid dynamics, Solid dynamics, Venture | ||
SHIBATA Kazuya | Networking for Artifact |
|
Fluid Simulation, Naval Architecture and Ocean Engineering, Disaster prevention and mitigation, explanation of phenomena, optimization | ||
TAKAHASHI Jun | Networking for Artifact |
|
Carbon fiber reinforced thermoplastics, future transportation and logistics systems, innovative simulation, superfunctional materials | ||
KAWABATA Tomoya | Networking for Artifact |
|
Hydrogen society, Steel material, Fracture mechanics, Natural gas, Pipeline, Storage tank, Earthquake |
Name | Research priority area | Position | keyword |
---|---|---|---|
KATO Yasuhiro | Global Circulation System |
|
mineral deposits, rare earths, precious metals, global environment, CO2 disposal |
TSUJI Takeshi | Global Circulation System |
|
Geophysical exploration, Space exploration, CCS, Geothermics, Earthquake, Volcano |
NAKAMURA Kentaro | Global Circulation System |
|
Submarine mineral resources, rare metals, resource exploration, earth dynamics, earth-life evolution |
GODA Takashi | Global Circulation System |
|
Uncertainty quantification, Decision making, Numerical analysis, Computational algorithms, Quasi-Monte Carlo methods |
MIYAMOTO Hideaki | Global Circulation System |
|
Planetary explorations, asteroids, Mars, Moon, Space resources |
DODBIBA Gjergj | Global Circulation System |
|
Physical and/or chemical processing of materials, Solid waste management, Resource recovery, Wastewater treatment, Environmental impact assessment |
Junichiro Ohta | Global Circulation System |
|
Mineral resources, global circulation system, global Environment, isotope geochemistry, chronology |
TAKAYA Yutaro | Global Circulation System |
|
Waste Management and Recycling,Wastewater Treatment,Deep-sea Mineral Resources, CCS/CCU |
TOKORO Chiharu | Global Circulation System |
|
Resources Recycling, Environmental Remediation, Separation, Simulation, Mineral Processing, |
FUKUI Katsunori | Global Circulation System |
|
Mining System, Geosystem, Seafloor Hydrothermal Deposits, Safe and Reliable Society |
KOBAYASHI Hajime | Global Circulation System |
|
Energy conversion, low carbon, environmental harmony, microbial engineering, symbiosis |
YASUKAWA Kazutaka | Global Circulation System |
|
Seafloor mineral resources, geochemical cycles, climate change, chemical analyses, multivariate analyses, simulations |
HASHIBA Kimihiro | Global Circulation System |
|
Resource development, Mining system, Time-dependence, Long-term behavior, Mechanical model |
Name | Research priority area | Position |
---|---|---|
keyword_en | ||
NAKAMURA Kentaro | Global Circulation System |
|
Submarine mineral resources, rare metals, resource exploration, earth dynamics, earth-life evolution | ||
GODA Takashi | Global Circulation System |
|
Uncertainty quantification, Decision making, Numerical analysis, Computational algorithms, Quasi-Monte Carlo methods | ||
TAKAYA Yutaro | Global Circulation System |
|
Waste Management and Recycling,Wastewater Treatment,Deep-sea Mineral Resources, CCS/CCU | ||
TOKORO Chiharu | Global Circulation System |
|
Resources Recycling, Environmental Remediation, Separation, Simulation, Mineral Processing, | ||
HASHIBA Kimihiro | Global Circulation System |
|
Resource development, Mining system, Time-dependence, Long-term behavior, Mechanical model | ||
KOBAYASHI Hajime | Global Circulation System |
|
Energy conversion, low carbon, environmental harmony, microbial engineering, symbiosis | ||
KATO Yasuhiro | Global Circulation System |
|
mineral deposits, rare earths, precious metals, global environment, CO2 disposal | ||
TSUJI Takeshi | Global Circulation System |
|
Geophysical exploration, Space exploration, CCS, Geothermics, Earthquake, Volcano | ||
YASUKAWA Kazutaka | Global Circulation System |
|
Seafloor mineral resources, geochemical cycles, climate change, chemical analyses, multivariate analyses, simulations | ||
Junichiro Ohta | Global Circulation System |
|
Mineral resources, global circulation system, global Environment, isotope geochemistry, chronology | ||
FUKUI Katsunori | Global Circulation System |
|
Mining System, Geosystem, Seafloor Hydrothermal Deposits, Safe and Reliable Society | ||
DODBIBA Gjergj | Global Circulation System |
|
Physical and/or chemical processing of materials, Solid waste management, Resource recovery, Wastewater treatment, Environmental impact assessment | ||
MIYAMOTO Hideaki | Global Circulation System |
|
Planetary explorations, asteroids, Mars, Moon, Space resources |
Name | Research priority area | Position | keyword |
---|---|---|---|
IZUMI Kiyoshi | Socioeconomic System |
|
Agent-based simulation; Data mining; Artificial market; Text mining; Economic simulation |
MURAKAMI Shinsuke | Socioeconomic System |
|
Industrial Ecology, Mineral Economics, Material Flow/Stock Analysis, Social System Evaluation, Sustainability Assessment |
SHIBASAKI Ryuichi | Socioeconomic System |
|
international logistics, maritime shipping, intermodal transport, network modeling, data mining and analysis |
AOYAMA Kazuhiro | Socioeconomic System |
|
System engineering, Design / production system, Knowledge management, Decision making, Project management |
FUJII Hideki | Socioeconomic System |
|
Social Simulation, Complex System, Human Modelling, High Performance Computing, Design Support |
SHIMADA Takashi | Socioeconomic System |
|
Statistical Physics Approach to Eco/Econo/Socio-Systems |
KANNO Taro | Socioeconomic System |
|
Team Cognition, Human Factors and Ergonomics, Service Systems Design, Human-Centered Resiliience Engineering. |
KAWASAKI Tomoya | Socioeconomic System |
|
Supply Chain Management (SCM), Value Chain Management (VCM), Logistics Systems Optimization, Graph Analysis, Big Data Analysis |
TANAKA Kenji | Socioeconomic System |
|
social system, demand forecasting, service design, Li-battery life |
TORIUMI Fujio | Socioeconomic System |
|
computational social sciences, artificial intelligence, data mining, agent-based simulation, social media, social data analysis, complex networks |
Name | Research priority area | Position |
---|---|---|
keyword_en | ||
IZUMI Kiyoshi | Socioeconomic System |
|
Agent-based simulation; Data mining; Artificial market; Text mining; Economic simulation | ||
AOYAMA Kazuhiro | Socioeconomic System |
|
System engineering, Design / production system, Knowledge management, Decision making, Project management | ||
KANNO Taro | Socioeconomic System |
|
Team Cognition, Human Factors and Ergonomics, Service Systems Design, Human-Centered Resiliience Engineering. | ||
TORIUMI Fujio | Socioeconomic System |
|
computational social sciences, artificial intelligence, data mining, agent-based simulation, social media, social data analysis, complex networks | ||
TANAKA Kenji | Socioeconomic System |
|
social system, demand forecasting, service design, Li-battery life | ||
FUJII Hideki | Socioeconomic System |
|
Social Simulation, Complex System, Human Modelling, High Performance Computing, Design Support | ||
KAWASAKI Tomoya | Socioeconomic System |
|
Supply Chain Management (SCM), Value Chain Management (VCM), Logistics Systems Optimization, Graph Analysis, Big Data Analysis | ||
SHIBASAKI Ryuichi | Socioeconomic System |
|
international logistics, maritime shipping, intermodal transport, network modeling, data mining and analysis | ||
SHIMADA Takashi | Socioeconomic System |
|
Statistical Physics Approach to Eco/Econo/Socio-Systems | ||
MURAKAMI Shinsuke | Socioeconomic System |
|
Industrial Ecology, Mineral Economics, Material Flow/Stock Analysis, Social System Evaluation, Sustainability Assessment |
Name | Research priority area | Position | keyword |
---|---|---|---|
KITAZAWA Daisuke | Design of Advanced Knowledge |
|
Marine hydrodynamics, Marine food production, Marine renewable energy, Hydrodynamic and ecosystem coupled model, Sustainable development |
HAYASHI Teruaki | Design of Advanced Knowledge |
|
Data design, Data ecosystem, Knowledge structuring, Cross-disciplinary data exchange and collaboration, Market of data, Creative communication |
WATANABE Masataka | Design of Advanced Knowledge |
|
consciousness, machine consciousness, spiking neural networks, brain-machine-interface, mind-uploading |
YAMADA Tomonori | Design of Advanced Knowledge |
|
High Performance Computing, Computational Mechanics, Machine Learning, Multiphysics Simulation |
OHSAWA Yukio | Design of Advanced Knowledge |
|
chance discovery, innovators marketplace on data jackets, visualization and valuation of data, design of data and its market, analysis of actions and communications |
NAKAO Akihiro | Design of Advanced Knowledge |
|
Next Generation Cyber Infrastructure, Beyond5G, 5G・Local5G, Super Intelligent Networks, Regional Revitalization |
Name | Research priority area | Position |
---|---|---|
keyword_en | ||
KITAZAWA Daisuke | Design of Advanced Knowledge |
|
Marine hydrodynamics, Marine food production, Marine renewable energy, Hydrodynamic and ecosystem coupled model, Sustainable development | ||
YAMADA Tomonori | Design of Advanced Knowledge |
|
High Performance Computing, Computational Mechanics, Machine Learning, Multiphysics Simulation | ||
WATANABE Masataka | Design of Advanced Knowledge |
|
consciousness, machine consciousness, spiking neural networks, brain-machine-interface, mind-uploading | ||
HAYASHI Teruaki | Design of Advanced Knowledge |
|
Data design, Data ecosystem, Knowledge structuring, Cross-disciplinary data exchange and collaboration, Market of data, Creative communication | ||
NAKAO Akihiro | Design of Advanced Knowledge |
|
Next Generation Cyber Infrastructure, Beyond5G, 5G・Local5G, Super Intelligent Networks, Regional Revitalization | ||
OHSAWA Yukio | Design of Advanced Knowledge |
|
chance discovery, innovators marketplace on data jackets, visualization and valuation of data, design of data and its market, analysis of actions and communications |
Name | Research priority area | Position | keyword |
---|---|---|---|
AOYAMA Kazuhiro | Socioeconomic System |
|
System engineering, Design / production system, Knowledge management, Decision making, Project management |
IZUMI Kiyoshi | Socioeconomic System |
|
Agent-based simulation; Data mining; Artificial market; Text mining; Economic simulation |
OHSAWA Yukio | Design of Advanced Knowledge |
|
chance discovery, innovators marketplace on data jackets, visualization and valuation of data, design of data and its market, analysis of actions and communications |
Junichiro Ohta | Global Circulation System |
|
Mineral resources, global circulation system, global Environment, isotope geochemistry, chronology |
OKABE Yoji | Networking for Artifact |
|
Advanced composite materials, Structural health monitoring, Non-destructive inspection, Ultrasonic guided waves, Optical fiber sensors |
KATO Yasuhiro | Global Circulation System |
|
mineral deposits, rare earths, precious metals, global environment, CO2 disposal |
KAWASAKI Tomoya | Socioeconomic System |
|
Supply Chain Management (SCM), Value Chain Management (VCM), Logistics Systems Optimization, Graph Analysis, Big Data Analysis |
KAWABATA Tomoya | Networking for Artifact |
|
Hydrogen society, Steel material, Fracture mechanics, Natural gas, Pipeline, Storage tank, Earthquake |
KANNO Taro | Socioeconomic System |
|
Team Cognition, Human Factors and Ergonomics, Service Systems Design, Human-Centered Resiliience Engineering. |
KITAZAWA Daisuke | Design of Advanced Knowledge |
|
Marine hydrodynamics, Marine food production, Marine renewable energy, Hydrodynamic and ecosystem coupled model, Sustainable development |
KOSHIZUKA Seiichi | Networking for Artifact |
|
Computer simulation, Physics-based CG, Fluid dynamics, Solid dynamics, Venture |
KOBAYASHI Hajime | Global Circulation System |
|
Energy conversion, low carbon, environmental harmony, microbial engineering, symbiosis |
GODA Takashi | Global Circulation System |
|
Uncertainty quantification, Decision making, Numerical analysis, Computational algorithms, Quasi-Monte Carlo methods |
SHIBASAKI Ryuichi | Socioeconomic System |
|
international logistics, maritime shipping, intermodal transport, network modeling, data mining and analysis |
SHIBATA Kazuya | Networking for Artifact |
|
Fluid Simulation, Naval Architecture and Ocean Engineering, Disaster prevention and mitigation, explanation of phenomena, optimization |
SHIBANUMA Kazuki | Networking for Artifact |
|
Fracture mechanics, Structural integrity |
SHIMADA Takashi | Socioeconomic System |
|
Statistical Physics Approach to Eco/Econo/Socio-Systems |
SUZUKI Katsuyuki | Networking for Artifact |
|
Computational mechanics, Optimal design, Structural mechanics, Ship structure |
SUZUKI Hideyuki | Networking for Artifact |
|
ocean renewable energy, floating offshore wind turbine, resource and energy development, ocean space utilization, CO2 ocean storage |
TAKAHASHI Jun | Networking for Artifact |
|
Carbon fiber reinforced thermoplastics, future transportation and logistics systems, innovative simulation, superfunctional materials |
TAKAYA Yutaro | Global Circulation System |
|
Waste Management and Recycling,Wastewater Treatment,Deep-sea Mineral Resources, CCS/CCU |
TANAKA Kenji | Socioeconomic System |
|
social system, demand forecasting, service design, Li-battery life |
TSUJI Takeshi | Global Circulation System |
|
Geophysical exploration, Space exploration, CCS, Geothermics, Earthquake, Volcano |
TOKORO Chiharu | Global Circulation System |
|
Resources Recycling, Environmental Remediation, Separation, Simulation, Mineral Processing, |
TORIUMI Fujio | Socioeconomic System |
|
computational social sciences, artificial intelligence, data mining, agent-based simulation, social media, social data analysis, complex networks |
DODBIBA Gjergj | Global Circulation System |
|
Physical and/or chemical processing of materials, Solid waste management, Resource recovery, Wastewater treatment, Environmental impact assessment |
NAKAO Akihiro | Design of Advanced Knowledge |
|
Next Generation Cyber Infrastructure, Beyond5G, 5G・Local5G, Super Intelligent Networks, Regional Revitalization |
NAKAMURA Kentaro | Global Circulation System |
|
Submarine mineral resources, rare metals, resource exploration, earth dynamics, earth-life evolution |
HASHIBA Kimihiro | Global Circulation System |
|
Resource development, Mining system, Time-dependence, Long-term behavior, Mechanical model |
HAYASHI Teruaki | Design of Advanced Knowledge |
|
Data design, Data ecosystem, Knowledge structuring, Cross-disciplinary data exchange and collaboration, Market of data, Creative communication |
FUKUI Katsunori | Global Circulation System |
|
Mining System, Geosystem, Seafloor Hydrothermal Deposits, Safe and Reliable Society |
FUJII Hideki | Socioeconomic System |
|
Social Simulation, Complex System, Human Modelling, High Performance Computing, Design Support |
HOUTANI Hidetaka | Networking for Artifact |
|
Ocean Waves, Ocean Engineering, Seakeeping Performance of Ships, Tank Experiment, Hydroelasticity |
MIYAMOTO Hideaki | Global Circulation System |
|
Planetary explorations, asteroids, Mars, Moon, Space resources |
MURAKAMI Shinsuke | Socioeconomic System |
|
Industrial Ecology, Mineral Economics, Material Flow/Stock Analysis, Social System Evaluation, Sustainability Assessment |
YASUKAWA Kazutaka | Global Circulation System |
|
Seafloor mineral resources, geochemical cycles, climate change, chemical analyses, multivariate analyses, simulations |
YAMADA Tomonori | Design of Advanced Knowledge |
|
High Performance Computing, Computational Mechanics, Machine Learning, Multiphysics Simulation |
YONEKURA Kazuo | Networking for Artifact |
|
Optimization, Machine Learning, Aerospace system |
WATANABE Masataka | Design of Advanced Knowledge |
|
consciousness, machine consciousness, spiking neural networks, brain-machine-interface, mind-uploading |
WAN Yi | Networking for Artifact |
|
Material engineering, Experimental evaluation, Modeling analysis, Carbon fiber reinforced composites |
Name | Research priority area | Position |
---|---|---|
keyword_en | ||
AOYAMA Kazuhiro | Socioeconomic System |
|
System engineering, Design / production system, Knowledge management, Decision making, Project management | ||
IZUMI Kiyoshi | Socioeconomic System |
|
Agent-based simulation; Data mining; Artificial market; Text mining; Economic simulation | ||
OHSAWA Yukio | Design of Advanced Knowledge |
|
chance discovery, innovators marketplace on data jackets, visualization and valuation of data, design of data and its market, analysis of actions and communications | ||
Junichiro Ohta | Global Circulation System |
|
Mineral resources, global circulation system, global Environment, isotope geochemistry, chronology | ||
OKABE Yoji | Networking for Artifact |
|
Advanced composite materials, Structural health monitoring, Non-destructive inspection, Ultrasonic guided waves, Optical fiber sensors | ||
KATO Yasuhiro | Global Circulation System |
|
mineral deposits, rare earths, precious metals, global environment, CO2 disposal | ||
KAWASAKI Tomoya | Socioeconomic System |
|
Supply Chain Management (SCM), Value Chain Management (VCM), Logistics Systems Optimization, Graph Analysis, Big Data Analysis | ||
KAWABATA Tomoya | Networking for Artifact |
|
Hydrogen society, Steel material, Fracture mechanics, Natural gas, Pipeline, Storage tank, Earthquake | ||
KANNO Taro | Socioeconomic System |
|
Team Cognition, Human Factors and Ergonomics, Service Systems Design, Human-Centered Resiliience Engineering. | ||
KITAZAWA Daisuke | Design of Advanced Knowledge |
|
Marine hydrodynamics, Marine food production, Marine renewable energy, Hydrodynamic and ecosystem coupled model, Sustainable development | ||
KOSHIZUKA Seiichi | Networking for Artifact |
|
Computer simulation, Physics-based CG, Fluid dynamics, Solid dynamics, Venture | ||
KOBAYASHI Hajime | Global Circulation System |
|
Energy conversion, low carbon, environmental harmony, microbial engineering, symbiosis | ||
GODA Takashi | Global Circulation System |
|
Uncertainty quantification, Decision making, Numerical analysis, Computational algorithms, Quasi-Monte Carlo methods | ||
SHIBASAKI Ryuichi | Socioeconomic System |
|
international logistics, maritime shipping, intermodal transport, network modeling, data mining and analysis | ||
SHIBATA Kazuya | Networking for Artifact |
|
Fluid Simulation, Naval Architecture and Ocean Engineering, Disaster prevention and mitigation, explanation of phenomena, optimization | ||
SHIBANUMA Kazuki | Networking for Artifact |
|
Fracture mechanics, Structural integrity | ||
SHIMADA Takashi | Socioeconomic System |
|
Statistical Physics Approach to Eco/Econo/Socio-Systems | ||
SUZUKI Katsuyuki | Networking for Artifact |
|
Computational mechanics, Optimal design, Structural mechanics, Ship structure | ||
SUZUKI Hideyuki | Networking for Artifact |
|
ocean renewable energy, floating offshore wind turbine, resource and energy development, ocean space utilization, CO2 ocean storage | ||
TAKAHASHI Jun | Networking for Artifact |
|
Carbon fiber reinforced thermoplastics, future transportation and logistics systems, innovative simulation, superfunctional materials | ||
TAKAYA Yutaro | Global Circulation System |
|
Waste Management and Recycling,Wastewater Treatment,Deep-sea Mineral Resources, CCS/CCU | ||
TANAKA Kenji | Socioeconomic System |
|
social system, demand forecasting, service design, Li-battery life | ||
TSUJI Takeshi | Global Circulation System |
|
Geophysical exploration, Space exploration, CCS, Geothermics, Earthquake, Volcano | ||
TOKORO Chiharu | Global Circulation System |
|
Resources Recycling, Environmental Remediation, Separation, Simulation, Mineral Processing, | ||
TORIUMI Fujio | Socioeconomic System |
|
computational social sciences, artificial intelligence, data mining, agent-based simulation, social media, social data analysis, complex networks | ||
DODBIBA Gjergj | Global Circulation System |
|
Physical and/or chemical processing of materials, Solid waste management, Resource recovery, Wastewater treatment, Environmental impact assessment | ||
NAKAO Akihiro | Design of Advanced Knowledge |
|
Next Generation Cyber Infrastructure, Beyond5G, 5G・Local5G, Super Intelligent Networks, Regional Revitalization | ||
NAKAMURA Kentaro | Global Circulation System |
|
Submarine mineral resources, rare metals, resource exploration, earth dynamics, earth-life evolution | ||
HASHIBA Kimihiro | Global Circulation System |
|
Resource development, Mining system, Time-dependence, Long-term behavior, Mechanical model | ||
HAYASHI Teruaki | Design of Advanced Knowledge |
|
Data design, Data ecosystem, Knowledge structuring, Cross-disciplinary data exchange and collaboration, Market of data, Creative communication | ||
FUKUI Katsunori | Global Circulation System |
|
Mining System, Geosystem, Seafloor Hydrothermal Deposits, Safe and Reliable Society | ||
FUJII Hideki | Socioeconomic System |
|
Social Simulation, Complex System, Human Modelling, High Performance Computing, Design Support | ||
HOUTANI Hidetaka | Networking for Artifact |
|
Ocean Waves, Ocean Engineering, Seakeeping Performance of Ships, Tank Experiment, Hydroelasticity | ||
MIYAMOTO Hideaki | Global Circulation System |
|
Planetary explorations, asteroids, Mars, Moon, Space resources | ||
MURAKAMI Shinsuke | Socioeconomic System |
|
Industrial Ecology, Mineral Economics, Material Flow/Stock Analysis, Social System Evaluation, Sustainability Assessment | ||
YASUKAWA Kazutaka | Global Circulation System |
|
Seafloor mineral resources, geochemical cycles, climate change, chemical analyses, multivariate analyses, simulations | ||
YAMADA Tomonori | Design of Advanced Knowledge |
|
High Performance Computing, Computational Mechanics, Machine Learning, Multiphysics Simulation | ||
YONEKURA Kazuo | Networking for Artifact |
|
Optimization, Machine Learning, Aerospace system | ||
WATANABE Masataka | Design of Advanced Knowledge |
|
consciousness, machine consciousness, spiking neural networks, brain-machine-interface, mind-uploading | ||
WAN Yi | Networking for Artifact |
|
Material engineering, Experimental evaluation, Modeling analysis, Carbon fiber reinforced composites |