The objective of this project is to develop a turning-milling machine tools which are easy usage for high accuracy and high efficiency. For this objective, the following technologies will be developed; (a) a technology to determine the optimum process plan and to generate the NC program, (b) a technology to accurately estimate cutting force based on servo information, (c) a technology to automatically make the optimum cutting condition by identifying cutting state based on process models.

The research results about routing, media access control, and attack defense which fill power saving, high reliability and high security are shown towards realization of IoT (Internet of Things).

In this group, carrier doping for device designs in organic transistors have been intensely studied by using both device simulation and experimental methods. The research and development toward international standardization on characterization techniques for organic transistors is also going on. This study was partly supported by the Joint R&D Project of International Standards funded by METI.

Energy consumption has been a critical issue for network virtualization environment (NVE). We focus on the data switching energy consumption on NVE, and study a dynamic virtual network resource allocation approach to reduce data switching energy consumption and moreover no impact on quality of service and end user experience.

This project develops microthermofluidic devices for life science research by the integration of microfluidic devices, which have been developed from the standpoint of bioengineering and bioMEMS, and micro-optical detection systems, which have been developed from the standpoint of thermal engineering and optical MEMS.

Regenerative medicine requires a novel cell cultivation technology. Our research group aims to develop such cell cultivation technology using ultrasonic vibration. We will introduce an effective cell collection method using resonance vibration of cultivation base, and enzyme free cell detachment method.

Our laboratory develops cell culture substrate using UV/ozone surface modification technique. We introduce the cell culture substrate that promote iPS cell adhesion and proliferation, and the substrate for evaluation of stem cell pluripotency.