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.
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.
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。
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.
Associate Professor
IIZUKA Tetsuya
Associate Professor
Hongo Campus
Design Science - Design and Optimization of Integrated Circuits and Systems
We have a wide variety of research topics mainly focusing on the analog/digital mixed-signal circuits and systems. Our research target is to realize high-performance integrated circuit systems for the applications of communication, IoT, AI, and so on. Based on the theory and analysis of the circuit behavior we develop systematic design guidelines for the optimum designs of integrated systems.
IIZUKA Tetsuya
Associate Professor
Design Science - Design and Optimization of Integrated Circuits and Systems
We have a wide variety of research topics mainly focusing on the analog/digital mixed-signal circuits and systems. Our research target is to realize high-performance integrated circuit systems for the applications of communication, IoT, AI, and so on. Based on the theory and analysis of the circuit behavior we develop systematic design guidelines for the optimum designs of integrated systems.
Project Associate Professor
NAKANE Ryosho
Project Associate Professor
Hongo Campus
Novel functional electronic devices and their applications to AI electronics
We are conducting research toward thechnological innovation in highly-efficient AI computing hardware. The research is promoted by both wheels: one is hardware research that creates novel functional electronic devices, and another is software research that includes proposal of physics-oriented computing system as well as information science on methodology and principle.
NAKANE Ryosho
Project Associate Professor
Novel functional electronic devices and their applications to AI electronics
We are conducting research toward thechnological innovation in highly-efficient AI computing hardware. The research is promoted by both wheels: one is hardware research that creates novel functional electronic devices, and another is software research that includes proposal of physics-oriented computing system as well as information science on methodology and principle.
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.