Faculty Members / Research Areas
Professor
KOBAYASHI Tetsuya
Professor
Komaba Campus
Mathematics and Informatics for Understanding Living Systems
We aim to uncover the design principles of information processing and robustness in biological systems by integrating theoretical and informatics approaches to various biological quantitative data.
KOBAYASHI Tetsuya
Professor
Mathematics and Informatics for Understanding Living Systems
We aim to uncover the design principles of information processing and robustness in biological systems by integrating theoretical and informatics approaches to various biological quantitative data.
SUGIYAMA Masakazu
Professor
Komaba Campus
Materials / devices / systems to realize carbon neutrality.
Our interests spread from basic research on renewable energy to social implementation. The most exciting frontiers exist at the interfaces such as the ones between electricity and chemistry, research and society.
SUGIYAMA Masakazu
Professor
Materials / devices / systems to realize carbon neutrality.
Our interests spread from basic research on renewable energy to social implementation. The most exciting frontiers exist at the interfaces such as the ones between electricity and chemistry, research and society.
SEKINO Masaki
Professor
Hongo Campus
Electronics for imaging and stimulation of brain and living bodies
Our researches focus on biomedical devices and artificial intelligence covering highly sensitive sensor for detecting magnetic fields arising from neurons, stimulation of neurons using pulsed magnetic fields, and magnetic sensor for diagnosis of tumor metastasis.
SEKINO Masaki
Professor
Electronics for imaging and stimulation of brain and living bodies
Our researches focus on biomedical devices and artificial intelligence covering highly sensitive sensor for detecting magnetic fields arising from neurons, stimulation of neurons using pulsed magnetic fields, and magnetic sensor for diagnosis of tumor metastasis.
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.
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.
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.
Associate Professor
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 Masaharu
Associate Professor
Komaba Campus
Semiconductor transistor and memory device technologies for next generation computing
Hiramoto/Kobayashi Laboratory is pursuing ultimate integrated nanoelectronics by device innovation to solve the world's issues.
KOBAYASHI Masaharu
Associate Professor
Semiconductor transistor and memory device technologies for next generation computing
Hiramoto/Kobayashi Laboratory is pursuing ultimate integrated nanoelectronics by device innovation to solve the world's issues.
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.
TOPRASERTPONG KASIDIT
Associate Professor
Hongo Campus
Advanced electronic devices using semiconductors and functional materials
Our research focuses on the development of functional electronic devices based on semiconductor and ferroelectric materials. We explore various research areas such as material engineering, device physics, and new-concept computing by leveraging the unique properties of these materials and devices.
TOPRASERTPONG KASIDIT
Associate Professor
Advanced electronic devices using semiconductors and functional materials
Our research focuses on the development of functional electronic devices based on semiconductor and ferroelectric materials. We explore various research areas such as material engineering, device physics, and new-concept computing by leveraging the unique properties of these materials and devices.
MATSUI Hiroaki
Associate Professor
Hongo Campus
Development of biological and energy applications based on nano-optical technology
Using nano light technology, the creation of biomolecular information sensing, biological defense technology, and energy -saving technology
MATSUI Hiroaki
Associate Professor
Development of biological and energy applications based on nano-optical technology
Using nano light technology, the creation of biomolecular information sensing, biological defense technology, and energy -saving technology
MATSUHISA Naoji
Associate Professor
Komaba Campus
Soft and stretchable electronic mateterials and the devices to harmonize human-machine interactions
We are working on the development of electronic materials and devices that are soft and stretchable like a living body. Taking advantage of the softness, we aim to realize a healthcare sensor that integrates the skin and body and the next-generation human computer interface.
MATSUHISA Naoji
Associate Professor
Soft and stretchable electronic mateterials and the devices to harmonize human-machine interactions
We are working on the development of electronic materials and devices that are soft and stretchable like a living body. Taking advantage of the softness, we aim to realize a healthcare sensor that integrates the skin and body and the next-generation human computer interface.
LE DUC ANH
Associate Professor
Hongo Campus
Realization of semiconductor materials and devices that integrate "magnetism", "superconductivity" and "topology".
Our focus is to integrate "magnetism", "superconductivity" and "topology" to all-in-one semiconductor platforms, using nanoscale semiconductor/ferromagnet/superconductor hybrid structures. These integrated material platforms would pave new ways to fundamental technologies for ultra-low power-consumption electronics and fault-tolerant quantum information.
LE DUC ANH
Associate Professor
Realization of semiconductor materials and devices that integrate "magnetism", "superconductivity" and "topology".
Our focus is to integrate "magnetism", "superconductivity" and "topology" to all-in-one semiconductor platforms, using nanoscale semiconductor/ferromagnet/superconductor hybrid structures. These integrated material platforms would pave new ways to fundamental technologies for ultra-low power-consumption electronics and fault-tolerant quantum information.