Faculty Members / Research Areas
Professor
IKEDA Makoto
Professor
Hongo Campus
Intelligent Information Processing, Sensing, and Hardware Security
Hardware is an root of intelligent information processing in cyber space, and seeking more intelligent, faster, lower power and more safer operations. Sensing is a gateway into cyber space from physical world, and authenticity and confidentiality of acquired information is a key for safety in cyber space. We are working on intelligent information processing, sensing and hardware security to fulfilling ever increasing requirements.
IKEDA Makoto
Professor
Intelligent Information Processing, Sensing, and Hardware Security
Hardware is an root of intelligent information processing in cyber space, and seeking more intelligent, faster, lower power and more safer operations. Sensing is a gateway into cyber space from physical world, and authenticity and confidentiality of acquired information is a key for safety in cyber space. We are working on intelligent information processing, sensing and hardware security to fulfilling ever increasing requirements.
OHSAKI Hiroyuki
Professor
Kashiwa Campus
Superconducting technology for next-generation energy equipment
We are conducting research on electrical energy equipment and systems with excellent characteristics, utilizing advanced materials such as superconductors and high-performance permanent magnets, with the aim of efficient use of electric energy and the realization of advanced electromagnetic applied systems.
OHSAKI Hiroyuki
Professor
Superconducting technology for next-generation energy equipment
We are conducting research on electrical energy equipment and systems with excellent characteristics, utilizing advanced materials such as superconductors and high-performance permanent magnets, with the aim of efficient use of electric energy and the realization of advanced electromagnetic applied systems.
KAWAHARA Yoshihiro
Professor
Hongo Campus
Digital fabrication and wireless power transfer for Internet of Things
Looking ahead to the next era of the Internet of Things, we are working on AI-based digital fabrication technology, wireless power transfer technology, robotics, and sensing technology with the aim of realizing a world in which sensor and actuator functions are naturally integrated everywhere.
KAWAHARA Yoshihiro
Professor
Digital fabrication and wireless power transfer for Internet of Things
Looking ahead to the next era of the Internet of Things, we are working on AI-based digital fabrication technology, wireless power transfer technology, robotics, and sensing technology with the aim of realizing a world in which sensor and actuator functions are naturally integrated everywhere.
KURODA Tadahiro
Professor
Hongo Campus
3D integrated circuit
Study AI chips, 3D memory, and silicon compilers to foster human resources who can design a green system in agile.
KURODA Tadahiro
Professor
3D integrated circuit
Study AI chips, 3D memory, and silicon compilers to foster human resources who can design a green system in agile.
TAKAMIYA Makoto
Professor
Komaba Campus
Small Chip Intelligently Managing Large Power
To achieve a carbon-free world by 2050, we are conducting research on integrated power management, in which a small IC chip can intelligently handle large amounts of power, with the goal of making power electronics systems more energy-efficient.
TAKAMIYA Makoto
Professor
Small Chip Intelligently Managing Large Power
To achieve a carbon-free world by 2050, we are conducting research on integrated power management, in which a small IC chip can intelligently handle large amounts of power, with the goal of making power electronics systems more energy-efficient.
TAKEUCHI Ken
Professor
Hongo Campus
Data Centric Computing (AI / Computation in Memory / Quantum Computer)
Takeuchi Lab is extensively studying brain-like data-centric computing and Computation in memory (CiM) that combines data processing and memory. We foster students who understand application and social implementation and then co-design different fields from LSI hardware, software, and machine learning for AI era.
TAKEUCHI Ken
Professor
Data Centric Computing (AI / Computation in Memory / Quantum Computer)
Takeuchi Lab is extensively studying brain-like data-centric computing and Computation in memory (CiM) that combines data processing and memory. We foster students who understand application and social implementation and then co-design different fields from LSI hardware, software, and machine learning for AI era.
TAKENAKA Mitsuru
Professor
Hongo Campus
Si photonics for next-generation AI/IoT deviecs
We are conducting research on silicon photonics for electronic-photonic integrarted circuits By combining silicon photonics with III-V compound semiconductors, germanium, 2D materials and so on, we investigate programmable photonic integrated circuits for deep learning, optical interconnect LSI, and mid-infrared integrated circuits. Our goal is to achieve innovative computing that does not rely on Moore's Law.
TAKENAKA Mitsuru
Professor
Si photonics for next-generation AI/IoT deviecs
We are conducting research on silicon photonics for electronic-photonic integrarted circuits By combining silicon photonics with III-V compound semiconductors, germanium, 2D materials and so on, we investigate programmable photonic integrated circuits for deep learning, optical interconnect LSI, and mid-infrared integrated circuits. Our goal is to achieve innovative computing that does not rely on Moore's Law.
TABATA Hitoshi
Professor
Hongo Campus
Brain-mimicking Beyond AI devices using spin waves and fluctuations and quantum technology for information processing and medical engineering applications
Research on brain-mimetic devices utilizing spin fluctuation, focusing on the spinciple that signal processing in neurons is equivalent to the Hamiltonian of a physical property called spin glass. Also, research is being conducted on applying spin wave quantum interference, resonance tunneling phenomena, and stochastic resonance principles, which can be operated at room temperature, to information processing devices to achieve low power consumption, and on ultra-sensitive measurement of bio-related information such as magnetoencephalography, magnetocardiography, and body gases.
TABATA Hitoshi
Professor
Brain-mimicking Beyond AI devices using spin waves and fluctuations and quantum technology for information processing and medical engineering applications
Research on brain-mimetic devices utilizing spin fluctuation, focusing on the spinciple that signal processing in neurons is equivalent to the Hamiltonian of a physical property called spin glass. Also, research is being conducted on applying spin wave quantum interference, resonance tunneling phenomena, and stochastic resonance principles, which can be operated at room temperature, to information processing devices to achieve low power consumption, and on ultra-sensitive measurement of bio-related information such as magnetoencephalography, magnetocardiography, and body gases.
TOSHIYOSHI Hiroshi
Professor
Komaba Campus
MEMS/NEMS, Micro/Nano mechatronics
MEMS (microelectromechanical systems) technology is a composite field of electrical engineering, mechanics, chemistry, material science, fluidics, optics and else. Using semiconductor microfabrication technology, we develop various MEMS applications such as optic communication, image display, medical diagnosis, IoT sensors, and energy harvesters.
TOSHIYOSHI Hiroshi
Professor
MEMS/NEMS, Micro/Nano mechatronics
MEMS (microelectromechanical systems) technology is a composite field of electrical engineering, mechanics, chemistry, material science, fluidics, optics and else. Using semiconductor microfabrication technology, we develop various MEMS applications such as optic communication, image display, medical diagnosis, IoT sensors, and energy harvesters.
NAKAJIMA Kengo
Professor
Hongo Campus
ポストムーア時代のアプリケーション・アルゴリズムへ向けて
スパコンを駆使した大規模シミュレーションによる計算科学は理論・実験に続く「第3の科学」と呼ばれています。当研究室では、スパコン上での大規模シミュレーションを支える数理的基盤の研究開発をScience-Modeling-Algorithm-Software-Hardware(SMASH)の幅広い観点から実施し、「第3の科学」の発展に貢献します。
NAKAJIMA Kengo
Professor
ポストムーア時代のアプリケーション・アルゴリズムへ向けて
スパコンを駆使した大規模シミュレーションによる計算科学は理論・実験に続く「第3の科学」と呼ばれています。当研究室では、スパコン上での大規模シミュレーションを支える数理的基盤の研究開発をScience-Modeling-Algorithm-Software-Hardware(SMASH)の幅広い観点から実施し、「第3の科学」の発展に貢献します。
HANAWA Toshihiro
Professor
Kashiwa Campus
Paving the Way to Next-Generation Supercomputers
The supercomputer is also attracting attention as a platform that realizes large -scale machine learning in addition to conventional simulations. By coordinating these, you can achieve more advanced applications. To do so, we need to optimize all kinds of processing, such as communication and file input and output, and aim to develop next -generation supercomputer fundamental technology through these more advanced fusion and cooperation.
HANAWA Toshihiro
Professor
Paving the Way to Next-Generation Supercomputers
The supercomputer is also attracting attention as a platform that realizes large -scale machine learning in addition to conventional simulations. By coordinating these, you can achieve more advanced applications. To do so, we need to optimize all kinds of processing, such as communication and file input and output, and aim to develop next -generation supercomputer fundamental technology through these more advanced fusion and cooperation.
BABA Jumpei
Professor
Hongo Campus
Create electricity using electricity -control of devices for smart grid-
We apply new technologies such as power electronics, energy storage technology, and ICT to the electric power field, and we are conducting research that contributes to the construction of better electric energy systems. We are conducting research close to hardware, such as actually going to remote islands and experiments.
BABA Jumpei
Professor
Create electricity using electricity -control of devices for smart grid-
We apply new technologies such as power electronics, energy storage technology, and ICT to the electric power field, and we are conducting research that contributes to the construction of better electric energy systems. We are conducting research close to hardware, such as actually going to remote islands and experiments.
HIROSE Akira
Professor
Hongo Campus
Neural Networks and Wireless Networks: See/feel/speak with radio-wave sensitive eyes and artificial intelligence (AI)
*Investigation of information processing principles in the brain from an electronic information engineering perspective, *Research on new information and signal processing technology by combining symbol processing and pattern processing, *Development of flexible electromagnetic/light measurement techniques, imaging and communication methods, and *Realization of useful systems and devices.
HIROSE Akira
Professor
Neural Networks and Wireless Networks: See/feel/speak with radio-wave sensitive eyes and artificial intelligence (AI)
*Investigation of information processing principles in the brain from an electronic information engineering perspective, *Research on new information and signal processing technology by combining symbol processing and pattern processing, *Development of flexible electromagnetic/light measurement techniques, imaging and communication methods, and *Realization of useful systems and devices.
FUKUDA Seisuke
Professor
Sagamihara Campus
Spacecraft/satellite systems and sensor signal processing
We are conducting a wide range of research, from very close to actual projects to future elemental technologies, regarding technology related to satellite and spacecraft systems with background in electronic engineering, and signal processing technology for radar and image sensing.
FUKUDA Seisuke
Professor
Spacecraft/satellite systems and sensor signal processing
We are conducting a wide range of research, from very close to actual projects to future elemental technologies, regarding technology related to satellite and spacecraft systems with background in electronic engineering, and signal processing technology for radar and image sensing.
MATSUHASHI Ryuji
Professor
Hongo Campus
Research on energy systems analysis and carbon-neutral societies
Matsuhashi Lab has conducted researches on energy systems and measures to mitigate global warming, and various researches related to energy policies. Currently, we are developing models of power systems that takes into account the large scale introduction of renewable energies, and the construction of novel energy economic models in consideration of bounded rationality, and integrating them.
MATSUHASHI Ryuji
Professor
Research on energy systems analysis and carbon-neutral societies
Matsuhashi Lab has conducted researches on energy systems and measures to mitigate global warming, and various researches related to energy policies. Currently, we are developing models of power systems that takes into account the large scale introduction of renewable energies, and the construction of novel energy economic models in consideration of bounded rationality, and integrating them.
MITA Yoshio
Professor
Hongo Campus
自然の機能に学ぶ先端集積化マイクロシステムの展開
山手線内で最も清浄な部屋「スーパークリーンルーム」で、世の中が見たこともないような「世界初」「世界最高」の賢いマイクロマシンを学生諸君と一緒に創造しています。
MITA Yoshio
Professor
自然の機能に学ぶ先端集積化マイクロシステムの展開
山手線内で最も清浄な部屋「スーパークリーンルーム」で、世の中が見たこともないような「世界初」「世界最高」の賢いマイクロマシンを学生諸君と一緒に創造しています。
MINEMATSU Nobuaki
Professor
Hongo Campus
Assistive technology for speech communication using computers that can talk with, listen to, and support users
Speech-to-text (speech recognition) and text-to-speech (speech synthesis) are working well even on smartphones. In our laboratory, using these speech technologies, we are developing frameworks that can aid humans to realize high-quality speech communication with other humans or with machines. By acquiring various kinds of knowlege such as acoustic phonetics, cognitive science, linguistics, and brain sciences as well as speech technologies, we are trying to improve the QoL of individuals who are communicating orally with others.
MINEMATSU Nobuaki
Professor
Assistive technology for speech communication using computers that can talk with, listen to, and support users
Speech-to-text (speech recognition) and text-to-speech (speech synthesis) are working well even on smartphones. In our laboratory, using these speech technologies, we are developing frameworks that can aid humans to realize high-quality speech communication with other humans or with machines. By acquiring various kinds of knowlege such as acoustic phonetics, cognitive science, linguistics, and brain sciences as well as speech technologies, we are trying to improve the QoL of individuals who are communicating orally with others.
MORIKAWA Hiroyuki
Professor
Hongo Campus
Digital Innovation: Transforming Society, Industry, Economy, and Local Communities
As digital technology revolutionizes society, we are researching 5G/Beyond 5G/6G, the Internet of Things (IoT), cloud robotics, wireless communication & power supply, and information society design. We invite you to collaborate with us and explore these exciting new frontiers with fresh ideas.
MORIKAWA Hiroyuki
Professor
Digital Innovation: Transforming Society, Industry, Economy, and Local Communities
As digital technology revolutionizes society, we are researching 5G/Beyond 5G/6G, the Internet of Things (IoT), cloud robotics, wireless communication & power supply, and information society design. We invite you to collaborate with us and explore these exciting new frontiers with fresh ideas.
Project Professor
HAMADA Mototsugu
Project Professor
Hongo Campus
Lowpower Integrated Circuits and Systems
We are researching low -powered processors and communication systems, which are responsible for information technology in the IoT/AI era.
HAMADA Mototsugu
Project Professor
Lowpower Integrated Circuits and Systems
We are researching low -powered processors and communication systems, which are responsible for information technology in the IoT/AI era.
FUJII Takashi
Project Professor
Hongo Campus
革新的レーザ計測技術の開発と高電圧研究への適用
直流グリッドが共存した次世代電力システムの実現に向け、光を用いた電界計測やレーザプラズマを用いた設備診断技術など、レーザの特長を生かした様々な応用研究や、レーザ特有の非線形現象の解明を行っています。
FUJII Takashi
Project Professor
革新的レーザ計測技術の開発と高電圧研究への適用
直流グリッドが共存した次世代電力システムの実現に向け、光を用いた電界計測やレーザプラズマを用いた設備診断技術など、レーザの特長を生かした様々な応用研究や、レーザ特有の非線形現象の解明を行っています。
Associate Professor
OISHI Takeshi
Associate Professor
Komaba Campus
Spatiotemporal modeling and representation of real world
We are developing technologies for 3D modeling, recognition, and analysis of the real world using optical sensor devices such as LiDAR and cameras to realize autonomous mobility for robots and self-driving vehicles.
OISHI Takeshi
Associate Professor
Spatiotemporal modeling and representation of real world
We are developing technologies for 3D modeling, recognition, and analysis of the real world using optical sensor devices such as LiDAR and cameras to realize autonomous mobility for robots and self-driving vehicles.
OHNISHI Wataru
Associate Professor
Hongo Campus
Toward Next Generation Mechatronics and Control
My team and I aim to achieve control performance that pushes the physical limits through innovations in control theory driven by the requirements of cutting-edge industrial and scientific applications. We pursue both performance and robustness through integrated optimization of the entire mechatronic system and controller design, including system identification and learning control. Our application includes precision mechatronics, electrical motors, power electronics, plasma, thermal systems, and pneumatic systems. Through domestic and international industry-academia collaboration, we propose and implement control theory and control system design methods for world-class control targets such as semiconductor manufacturing equipment, railroad systems, and power system equipments to support a sustainable and prosperous society.
OHNISHI Wataru
Associate Professor
Toward Next Generation Mechatronics and Control
My team and I aim to achieve control performance that pushes the physical limits through innovations in control theory driven by the requirements of cutting-edge industrial and scientific applications. We pursue both performance and robustness through integrated optimization of the entire mechatronic system and controller design, including system identification and learning control. Our application includes precision mechatronics, electrical motors, power electronics, plasma, thermal systems, and pneumatic systems. Through domestic and international industry-academia collaboration, we propose and implement control theory and control system design methods for world-class control targets such as semiconductor manufacturing equipment, railroad systems, and power system equipments to support a sustainable and prosperous society.
OGAWA Takefumi
Associate Professor
Kashiwa Campus
Interaction of Humans, Things, and Events
We are involved in various research projects aimed at enriching people's daily lives by utilizing augmented reality and virtual reality technologies. Our research themes share a common keyword - "connect". We are working on developing "communication support" and "groupware" to facilitate connections between people, "interfaces" to bridge the gap between people and computers, and "interaction technologies" to enable connections between people and data. Our goal is to create mechanisms that facilitate new experiences by enabling humans, objects, and events to interact with each other.
OGAWA Takefumi
Associate Professor
Interaction of Humans, Things, and Events
We are involved in various research projects aimed at enriching people's daily lives by utilizing augmented reality and virtual reality technologies. Our research themes share a common keyword - "connect". We are working on developing "communication support" and "groupware" to facilitate connections between people, "interfaces" to bridge the gap between people and computers, and "interaction technologies" to enable connections between people and data. Our goal is to create mechanisms that facilitate new experiences by enabling humans, objects, and events to interact with each other.
KOBAYASHI Daisuke
Associate Professor
Sagamihara Campus
Startled Computers: Space makes semiconductors surprised
In Sci-Fi movies, androids are often depicted as having cold and emotionless character. We may have such impression because most of computers rely on digital processing in which everything is flatly divided into "1" or "0", but—would you believe it?—they are easily surprised and often get upset. It is caused by a strike of tiny invisible particles, fragments of exploding stars a.k.a cosmic rays, but the shock is significant. The shock makes a computer chip surprised and lose its memory, control, and even its fundamental ability to boot up. So, what will you do next?
KOBAYASHI Daisuke
Associate Professor
Startled Computers: Space makes semiconductors surprised
In Sci-Fi movies, androids are often depicted as having cold and emotionless character. We may have such impression because most of computers rely on digital processing in which everything is flatly divided into "1" or "0", but—would you believe it?—they are easily surprised and often get upset. It is caused by a strike of tiny invisible particles, fragments of exploding stars a.k.a cosmic rays, but the shock is significant. The shock makes a computer chip surprised and lose its memory, control, and even its fundamental ability to boot up. So, what will you do next?
SAITO Daisuke
Associate Professor
Hongo Campus
Real-data-oriented Speech Information Processing and Media Information Processing
Saito Laboratory is studying and developing speech information processing, and conducting research on multimedia information processing based on the developed techniques. In particular, in recent years, we have been working on research on complex phenomena such as multiple singing, and analysis about the relationship between appearance of robots and their voice. As a research stance, we aim to create new technologies based on mathematical backgrounds and handle a wide range of media.
SAITO Daisuke
Associate Professor
Real-data-oriented Speech Information Processing and Media Information Processing
Saito Laboratory is studying and developing speech information processing, and conducting research on multimedia information processing based on the developed techniques. In particular, in recent years, we have been working on research on complex phenomena such as multiple singing, and analysis about the relationship between appearance of robots and their voice. As a research stance, we aim to create new technologies based on mathematical backgrounds and handle a wide range of media.
SATO Hiroyuki
Associate Professor
Kashiwa Campus
Security and Trust Science
Research on authentication infrastructure, research of optimization compiler with verification, We are conducting comprehensive research on security and trust through research on trasts in distributed environments.
SATO Hiroyuki
Associate Professor
Security and Trust Science
Research on authentication infrastructure, research of optimization compiler with verification, We are conducting comprehensive research on security and trust through research on trasts in distributed environments.
SATO Masahiro
Associate Professor
Hongo Campus
Phyisics and smart AI-aided electrical and electronic materials design
To achieve carbon neutrality in a materials limited world, we are designing new electrical and electronic materials with the aid of the laws of nature and artificial intelligence. By understanding the underlying phyisics of high electric field phenomena, we propose novel approaches for tailoring the material properties.
SATO Masahiro
Associate Professor
Phyisics and smart AI-aided electrical and electronic materials design
To achieve carbon neutrality in a materials limited world, we are designing new electrical and electronic materials with the aid of the laws of nature and artificial intelligence. By understanding the underlying phyisics of high electric field phenomena, we propose novel approaches for tailoring the material properties.
SHIMOKAWABE Takashi
Associate Professor
Hongo, Kashiwa Campus
Large-scale simulation on supercomputers
Physical simulations are used in various fields of computational science and computational engineering, such as meteorology, space, and manufacturing. Research and development of computational methods, algorithms, and software technologies are necessary to realize large-scale simulations using next-generation supercomputers. Our research interests include fluid computation, GPU computation, AMR, acceleration methods, machine learning, and dynamic load balancing.
SHIMOKAWABE Takashi
Associate Professor
Large-scale simulation on supercomputers
Physical simulations are used in various fields of computational science and computational engineering, such as meteorology, space, and manufacturing. Research and development of computational methods, algorithms, and software technologies are necessary to realize large-scale simulations using next-generation supercomputers. Our research interests include fluid computation, GPU computation, AMR, acceleration methods, machine learning, and dynamic load balancing.
NAKAYAMA Masaya
Associate Professor
Kashiwa Campus
Wide -area distributed processing
In our laboratory, we deal with research issues about network infrastructure technology and also including applied technology for collecting, processing, and utilizing information from connected devices.
NAKAYAMA Masaya
Associate Professor
Wide -area distributed processing
In our laboratory, we deal with research issues about network infrastructure technology and also including applied technology for collecting, processing, and utilizing information from connected devices.
NATSUAKI Ryo
Associate Professor
Hongo Campus
Measure the world with active sensing
"Observation using microwaves" is our research topic. We can observe the target from distant in any time and weather condition. We are studying the dynamic deformation of the Earth using satellite borne radar system.
NATSUAKI Ryo
Associate Professor
Measure the world with active sensing
"Observation using microwaves" is our research topic. We can observe the target from distant in any time and weather condition. We are studying the dynamic deformation of the Earth using satellite borne radar system.
NARUSUE Yoshiaki
Associate Professor
Hongo Campus
Exploring Wireless Technologies Empowering the Future
We are researching and developing next-generation wireless technologies and field-oriented computing to realize "Zero-Configuration CPS," which aims to design, build, and operate cyber-physical systems (CPS) with minimal human costs.
NARUSUE Yoshiaki
Associate Professor
Exploring Wireless Technologies Empowering the Future
We are researching and developing next-generation wireless technologies and field-oriented computing to realize "Zero-Configuration CPS," which aims to design, build, and operate cyber-physical systems (CPS) with minimal human costs.
YATANI Koji
Associate Professor
Hongo Campus
Reshaping User Experience with Novel Interactive Systems
Our research focuses on user interfaces, particularly the development of novel applications enabled by information technology. We also investigate how interactive systems influence people's activities and decision-making.
YATANI Koji
Associate Professor
Reshaping User Experience with Novel Interactive Systems
Our research focuses on user interfaces, particularly the development of novel applications enabled by information technology. We also investigate how interactive systems influence people's activities and decision-making.
Lecturer
KOSUGE Atsutake
Lecturer
Hongo Campus
Energy-efficient high-performance VLSI systems for next-generation large AI models
We study energy-efficient high-performance VLSI systems including (1) energy-efficient domain specific processors and (2) 2.5D/3D chip stacking technology.
KOSUGE Atsutake
Lecturer
Energy-efficient high-performance VLSI systems for next-generation large AI models
We study energy-efficient high-performance VLSI systems including (1) energy-efficient domain specific processors and (2) 2.5D/3D chip stacking technology.
Project Lecturer
HIGO Akio
Project Lecturer
Hongo Campus
Photonic NEMS/MEMS by using High-throughput and High-precision Electron Beam Lithography
In the optical information society, devices are becoming larger and larger. Usually, nanostructures are drawn in a small area by electron beam lithography. This research aims to realize photonic NEMS/MEMS devices using the character projection method, which draws high-throughput and high-resolution.
HIGO Akio
Project Lecturer
Photonic NEMS/MEMS by using High-throughput and High-precision Electron Beam Lithography
In the optical information society, devices are becoming larger and larger. Usually, nanostructures are drawn in a small area by electron beam lithography. This research aims to realize photonic NEMS/MEMS devices using the character projection method, which draws high-throughput and high-resolution.