| 3-dimensional image processing |
Kawata, Yoshiki |
| A |
|
| activated carbon |
Horikawa, Toshihide |
| activation |
Horikawa, Toshihide |
| adaptive control |
Ikeda, Kenji |
| adaptive hypermedia |
Mitsuhara, Hiroyuki |
| adsorption |
Horikawa, Toshihide / Katoh, Masahiro |
| adsorption mechanism |
Horikawa, Toshihide |
| adsorption separation |
Horikawa, Toshihide |
| advanced motion control |
Yasuno, Takashi |
| Aerial image processing |
Karungaru, Stephen Githinji |
| after treatment |
Kidoguchi, Yoshiyuki |
| algorithm |
Hasunuma, Toru / Nakayama, Shin-ichi |
| AlN |
Nishino, Katsushi |
| Amagasaki canal |
Kozuki, Yasunori |
| anionic polymerization |
Hirano, Tomohiro |
| anisotropic superconductivity |
Kawasaki, Yu |
| architecture |
Sano, Masahiko |
| artificial intelligence |
KANG, XIN / Shishibori, Masami / Tanioka, Hiroki |
| Artificial Society |
Okushima, Masashi |
| asymmetric synthesis |
Arakawa, Yukihiro |
| asymptotic analysis |
Ohyama, Yousuke |
| Atomic vibration in crystal |
Murai, Kei-ichiro |
| Autonomous Distributed Control |
Kinoshita, Kazuhiko |
| axial flow fan |
Shigemitsu, Toru |
| B |
|
| Backward erosion piping |
Horikoshi, Kauzuki |
| Basin water management |
TAMURA, Takao |
| Bearing capacity |
Ueno, Katsutoshi |
| bicrystal |
Okada, Tatsuya |
| bifurcation |
Murakami, Kouichi / Ueta, Tetsushi |
| bioelectrics |
Shimomura, Naoyuki |
| biomass |
Horikawa, Toshihide |
| Biomechanics |
SATO, Katsuya |
| biosensor |
Mizuguchi, Hitoshi |
| blood flow |
Akutagawa, Masatake |
| boundary layer |
Ichimiya, Masashi |
| brain information processing |
Uwate, Yoko |
| broadleaf tree |
TAMURA, Takao |
| Bus System |
Okushima, Masashi |
| C |
|
| capacitance |
Ueno, Katsutoshi |
| carbon dioxide adsorption |
Horikawa, Toshihide |
| carbon nanotube |
Horikawa, Toshihide |
| Cathode and anode materials for Li ion rechargeable batteries |
Nakamura, Koichi |
| Causal Machine Learning |
KANG, XIN |
| cell |
SATO, Katsuya |
| cellular neural networks |
Nishio, Yoshifumi |
| centrifugal pump |
Shigemitsu, Toru |
| chaos |
Nishio, Yoshifumi / Ueta, Tetsushi / Uwate, Yoko |
| ≫ chaos control |
Ueta, Tetsushi |
| ≫ chaotic phenomena |
YANG, Haichuan |
| chaos control |
Ueta, Tetsushi |
| chaotic phenomena |
YANG, Haichuan |
| Character Recognition |
Karungaru, Stephen Githinji |
| characterisation |
Horikawa, Toshihide |
| chemical engineering |
Horikawa, Toshihide |
| circuit design (→ circuitry) |
| circuitry |
Nishio, Yoshifumi |
| coastal environment |
TAMURA, Takao / Yamanaka, Ryoichi |
| coding |
Song, Tian |
| Cognitive Dual Process Imitative Neuro-Symbolic AI |
KANG, XIN |
| cognitive psychology |
KANG, XIN |
| colloidal crystal |
Suzuki, Yoshihisa |
| combustion |
Kidoguchi, Yoshiyuki / Nada, Yuzuru |
| Comparison Principle |
Ohnuma, Masaki |
| competitiveness |
Uno, Takeshi |
| complex systems |
Nishio, Yoshifumi / YANG, Haichuan |
| computational complexity |
Nakayama, Shin-ichi |
| computational fluid dynamics |
Kidoguchi, Yoshiyuki |
| Computer administraion system |
Sano, Masahiko |
| Computer Supported Collaborative Learning |
Matsuura, Kenji |
| computer vision |
Ukida, Hiroyuki |
| concrete-block wall |
Kozuki, Yasunori |
| conductor |
|
| ≫ ionic conductor |
|
| ≫ superionic conductor |
Nakamura, Koichi |
| Congestion Pricing |
Okushima, Masashi |
| conifer |
TAMURA, Takao |
| control |
Miwa, Masafumi / Nakata, Narutoshi |
| ≫ chaos control |
Ueta, Tetsushi |
| ≫ control theory |
Kubo, Tomohiro |
| Control Engineering |
Takaiwa, Masahiro |
| control theory |
Kubo, Tomohiro |
| cooperation |
TAMURA, Takao |
| coupled oscillatory circuits |
Nishio, Yoshifumi |
| crystal growth |
Yanagiya, Shin-ichiro |
| crystal plasticity |
Okada, Tatsuya |
| crystallographic defect |
Okada, Tatsuya |
| cutting force |
Mizobuchi, Akira |
| D |
|
| data mining |
Tanioka, Hiroki |
| data processing |
YANG, Haichuan |
| decentralized control |
Ikeda, Kenji |
| deep learning |
KANG, XIN |
| delay |
Murakami, Kouichi |
| Depression Detection Assistant AI |
KANG, XIN |
| design automation |
Yotsuyanagi, Hiroyuki |
| development |
Watanabe, Minoru |
| dialogue understanding |
Tanioka, Hiroki |
| diamond |
Okada, Tatsuya |
| Dictionary Retrieval |
Fuketa, Masao / Morita, Kazuhiro |
| dielectric microsphere |
Haraguchi, Masanobu |
| diesel engine |
Kidoguchi, Yoshiyuki |
| differential equation |
|
| ≫ partial differential equations |
Ohnuma, Masaki / Tsurumi, Hiroyuki |
| diffusion |
|
| ≫ ionic diffusion |
Nakamura, Koichi |
| digital signal processing |
Fukumi, Minoru |
| Disaster Information |
Nakata, Narutoshi |
| Disaster prevention map |
TAMURA, Takao |
| Discrete equations |
Ohyama, Yousuke |
| distributed parameter systems |
Kubo, Tomohiro |
| district improvement plan for disaster mitigation |
WATANABE, Kojiro |
| E |
|
| e-learning |
Matsuura, Kenji / Mitsuhara, Hiroyuki |
| earthquake |
Jiang, Jing-Cai |
| ecosystem in coastal zone |
Kozuki, Yasunori |
| education for disaster prevention |
Kozuki, Yasunori |
| elastic wave |
Watanabe, Takeshi |
| electrical bioimpedance |
Akutagawa, Masatake |
| Electrical conductivity measurement |
Nakamura, Koichi |
| Electrode catalyst |
Mizuguchi, Hitoshi |
| electroencephalogram |
Ito, Shin-ichi |
| electrorheology |
Minagawa, Keiji |
| embedded system |
Sano, Masahiko |
| Emmission |
Kidoguchi, Yoshiyuki |
| Emotion Recognition |
KANG, XIN / Matsumoto, Kazuyuki |
| energy conversion |
YANG, Haichuan |
| energy saving |
TAMURA, Takao |
| English Composition Support |
Matsumoto, Kazuyuki |
| entertainment computing |
Mitsuhara, Hiroyuki |
| environment-considered urban planning |
WATANABE, Kojiro |
| environmental analytical chemistry |
Imai, Shoji |
| environmental biotechnology |
Hirata, Akira |
| environmental chemistry |
Imai, Shoji |
| Environmental education |
Kozuki, Yasunori |
| environmental protection |
TAMURA, Takao |
| environmental science |
Imai, Shoji |
| enzyme catalysis |
Hirata, Akira |
| epitaxial film |
Okada, Tatsuya |
| ER fluid |
Minagawa, Keiji |
| EST |
Makabe, Kazuhiro W. |
| Evacuation assistance map |
TAMURA, Takao |
| evaporation |
TAMURA, Takao |
| evolutionary algorithm |
Uno, Takeshi |
| evolutionary computation |
YANG, Haichuan |
| evolutionary image processing |
Ito, Momoyo |
| Evolutionary Systems |
Fukumi, Minoru |
| experimental psychology |
Ito, Shin-ichi |
| F |
|
| Face Detection, Recognition |
Karungaru, Stephen Githinji |
| facility location |
Uno, Takeshi |
| Fault tolerance |
Hasunuma, Toru |
| fault tolerant computing |
Yotsuyanagi, Hiroyuki |
| femtosecond laser processing/modification |
Tomita, Takuro |
| Field electron Emission |
Koinkar, Pankaj |
| financial engineering |
KANG, XIN |
| Fishery |
TAMURA, Takao |
| flavin |
Arakawa, Yukihiro |
| flood |
TAMURA, Takao |
| flow rate |
TAMURA, Takao |
| flow-induced vibration |
Noda, Minoru |
| fluid |
Tsurumi, Hiroyuki |
| forest |
TAMURA, Takao |
| forest devastation |
TAMURA, Takao |
| forest-river-sea |
TAMURA, Takao |
| FPGA |
Sano, Masahiko |
| functional analysis |
Tsurumi, Hiroyuki |
| functional polymer |
Arakawa, Yukihiro |
| functional space |
Tsurumi, Hiroyuki |
| fuzzy |
Uno, Takeshi |
| Fuzzy-Neuro Model |
Okushima, Masashi |
| G |
|
| GA |
Shimomura, Naoyuki |
| Genetic Algorithm |
Okushima, Masashi / Uno, Takeshi / YANG, Haichuan |
| Genetic Algorithms |
Karungaru, Stephen Githinji |
| genome |
Makabe, Kazuhiro W. |
| genome editing |
Watanabe, Minoru |
| geographic information system |
WATANABE, Kojiro |
| Geological features of landslide |
Nishiyama, Ken-ichi |
| geological structure |
Aoya, Mutsuki |
| geometric flows |
Kunikawa, Keita |
| geosensing |
Ueno, Katsutoshi |
| Geotechnical centrifuge |
Ueno, Katsutoshi |
| GIS |
Shimomura, Naoyuki |
| global warming |
TAMURA, Takao |
| graph |
Hasunuma, Toru |
| ≫ graph theory |
Nakayama, Shin-ichi |
| graph theory |
Nakayama, Shin-ichi |
| graphene |
Horikawa, Toshihide |
| graphite |
Horikawa, Toshihide |
| green chemistry |
Minagawa, Keiji |
| Green curtain |
TAMURA, Takao |
| H |
|
| H-Q curve |
TAMURA, Takao |
| H.264 |
Song, Tian |
| hazard map |
TAMURA, Takao |
| heat equation |
Kunikawa, Keita |
| heat island |
TAMURA, Takao |
| heat treatment |
Hisazawa, Hiromu |
| heavy rain |
TAMURA, Takao |
| heavy-fermion compound |
Kawasaki, Yu |
| heavy-fermion system |
Magishi, Ko-ichi |
| high pressure |
Okamura, Hidekazu |
| high temperature superconductor |
Magishi, Ko-ichi |
| human sensing |
Fukumi, Minoru |
| hydrogen |
Kidoguchi, Yoshiyuki / Shimoda, Naohiro |
| hydrogen production process |
Katoh, Masahiro |
| hyperbolicity |
Moriyasu, Kazumine |
| Hypoxia |
Kozuki, Yasunori |
| I |
|
| ICT in education |
Mizuguchi, Hitoshi |
| image processing |
Hisazawa, Hiromu / Terada, Kenji / Ukida, Hiroyuki |
| Image Understanding |
Fukumi, Minoru |
| impact-echo method |
Watanabe, Takeshi |
| Individual Characteristics |
Ito, Shin-ichi |
| information processing |
Tanioka, Hiroki |
| information retrieval |
Tanioka, Hiroki |
| information retrieval system |
Shishibori, Masami |
| information security |
Tanioka, Hiroki |
| Information Security Management System |
Ueta, Tetsushi |
| information sharing |
Mitsuhara, Hiroyuki / Tanioka, Hiroki |
| Information Technology for Engineering Applications |
Nakata, Narutoshi |
| Information Visualization |
Ito, Shin-ichi |
| infrared spectroscopy |
Katoh, Masahiro / Okamura, Hidekazu |
| Infrared thermography |
Ishikawa, Masashi |
| intelligent control |
Yasuno, Takashi |
| Intelligent Systems |
Fukumi, Minoru |
| Interconnection networks |
Hasunuma, Toru |
| intermittent cutting |
Mizobuchi, Akira |
| Internal erosion |
Horikoshi, Kauzuki |
| internal flow |
Shigemitsu, Toru |
| Internet |
Sano, Masahiko |
| ion |
|
| ≫ ionic conductor |
|
| ≫ superionic conductor |
Nakamura, Koichi |
| ≫ ionic diffusion |
Nakamura, Koichi |
| ionic conductor |
|
| ≫ superionic conductor |
Nakamura, Koichi |
| ionic diffusion |
Nakamura, Koichi |
| Iwasawa theory for algebraic number fields |
Sumida-Takahashi, Hiroki |
| J |
|
| jaw motion (→ jaw movement) |
| jaw movement |
Akutagawa, Masatake |
| jet |
Ichimiya, Masashi |
| K |
|
| Knowledge Acqisition |
Fukumi, Minoru |
| L |
|
| Large Language Models |
KANG, XIN |
| Laser ablation |
Koinkar, Pankaj |
| laser diode |
Nagamatsu, Kentaro |
| Latent Thermal Energy Storage |
Kusano, Koji |
| LED (→ light emitting diode) |
| Levee |
Horikoshi, Kauzuki |
| Li transition metal oxide |
Nakamura, Koichi |
| lifelong learning |
Matsuura, Kenji |
| light emitting diode |
Akutagawa, Masatake / Nagamatsu, Kentaro |
| light localization |
Haraguchi, Masanobu |
| Linear Quadratic Regulator |
Kubo, Tomohiro |
| linear system |
Kubo, Tomohiro |
| Liquid exfoliation |
Koinkar, Pankaj |
| Liquid-liquid Phase Separation of Protein Solutions |
Suzuki, Yoshihisa |
| Li+ ion conductor |
Nakamura, Koichi |
| Li+ ion diffusion |
Nakamura, Koichi |
| localized plasmon |
Haraguchi, Masanobu |
| low power design |
Song, Tian |
| M |
|
| Machine Learning |
Okushima, Masashi / Tanioka, Hiroki / YANG, Haichuan / Yasuno, Takashi |
| magnetic measurement |
Akutagawa, Masatake |
| maintenance |
Watanabe, Takeshi |
| mathematical modeling |
TAMURA, Takao |
| mechanical engineering |
SATO, Katsuya |
| Mechanical milling |
Nakamura, Koichi |
| Mechanotransduction |
SATO, Katsuya |
| mechatronics |
Miwa, Masafumi |
| medical imaging |
Ito, Momoyo / Kawata, Yoshiki |
| medical infomatics |
Tanioka, Hiroki |
| MEMS |
SATO, Katsuya |
| metal oxynitrides |
Moriga, Toshihiro |
| metal-insulator transition |
Magishi, Ko-ichi |
| metamorphic rocks |
Aoya, Mutsuki |
| methodology |
Miyoshi, Norikazu |
| Microgravity experiments |
Suzuki, Yoshihisa |
| micromachine |
Miwa, Masafumi |
| microscope |
Yanagiya, Shin-ichiro |
| microstructure control |
Hisazawa, Hiromu |
| minimal submanifolds |
Kunikawa, Keita |
| mitigation |
Kozuki, Yasunori / Yamanaka, Ryoichi |
| Mobile Network |
Kinoshita, Kazuhiko |
| moisture content |
Ueno, Katsutoshi |
| molecular sieving carbon |
Horikawa, Toshihide |
| Monitoring of brain chemicals |
Mizuguchi, Hitoshi |
| morphogenesis |
Watanabe, Minoru |
| motion control |
Takaiwa, Masahiro |
| MRI |
Akutagawa, Masatake |
| Multi-Agent Simulation |
Okushima, Masashi |
| multi-tiered forest |
TAMURA, Takao |
| multimedia |
Shishibori, Masami |
| Multimodal Machine Learning |
KANG, XIN |
| multiobjective programming |
Uno, Takeshi |
| Multiphase Flow |
Kusano, Koji |
| N |
|
| nano |
Yanagiya, Shin-ichiro |
| nanophotonics |
Haraguchi, Masanobu |
| nanosecond pulsed power |
Shimomura, Naoyuki |
| nanostructure |
Okamoto, Toshihiro / Takashima, Yuusuke |
| natural disaster |
TAMURA, Takao |
| natural environment |
Imai, Shoji |
| Natural Language Analysis |
Fuketa, Masao |
| natural language processing |
Morita, Kazuhiro |
| Na+ ion conductor |
Nakamura, Koichi |
| Na+ ion diffusion |
Nakamura, Koichi |
| network |
Hasunuma, Toru |
| network architecture |
Kinoshita, Kazuhiko |
| neural network |
Akutagawa, Masatake / Fukumi, Minoru / Katayama, Takafumi |
| Neural Networks |
Karungaru, Stephen Githinji |
| neurodynamics |
Nishio, Yoshifumi |
| neuron model |
YANG, Haichuan |
| new synthesis |
Miyoshi, Norikazu |
| Ni-based superalloys |
Hisazawa, Hiromu |
| nitride semiconductor |
Nagamatsu, Kentaro |
| ≫ nitride semiconductor films |
Kusaka, Kazuya |
| nitride semiconductor films |
Kusaka, Kazuya |
| nitrogen oxide: NOx |
Shimomura, Naoyuki |
| NMR (→ nuclear magnetic resonance) |
| non-destructive testing |
Ishikawa, Masashi / Watanabe, Takeshi |
| non-Fermi liquid |
Kawasaki, Yu |
| nonlinear |
Murakami, Kouichi |
| nonlinear circuits |
Nishio, Yoshifumi |
| nonlinear dynamical system |
Ueta, Tetsushi |
| nonlinear optics |
Haraguchi, Masanobu / Okamoto, Toshihiro |
| nonuniform hyperbolicity |
Moriyasu, Kazumine |
| nuclear magnetic resonance |
Hisada, Akihiko / Kawasaki, Yu / Magishi, Ko-ichi / Nakamura, Koichi / Saito, Takahito |
| Numerical Analysis |
Kusano, Koji |
| numerical analysis of algebraic fields |
Sumida-Takahashi, Hiroki |
| numerical computation |
Ueta, Tetsushi |
| Nutritive salt |
TAMURA, Takao |
| O |
|
| optical device |
Naoi, Yoshiki / Takashima, Yuusuke |
| optical mode |
Haraguchi, Masanobu |
| optical properties of solid |
Okamura, Hidekazu / Tomita, Takuro |
| optical property |
Haraguchi, Masanobu |
| optics |
Yanagiya, Shin-ichiro |
| optimization |
KANG, XIN / Shimomura, Naoyuki / Uno, Takeshi / YANG, Haichuan |
| organic chemistry |
Miyoshi, Norikazu |
| organocatalysts |
Arakawa, Yukihiro |
| Outcome Management |
Matsumoto, Kazuyuki |
| ozone |
Shimomura, Naoyuki |
| P |
|
| The Painleve equations |
Ohyama, Yousuke |
| partial differential equations |
Ohnuma, Masaki / Tsurumi, Hiroyuki |
| particle swarm optimization |
Uno, Takeshi / YANG, Haichuan |
| Pd membrane |
Katoh, Masahiro |
| permittivity |
Ueno, Katsutoshi |
| petrology |
Aoya, Mutsuki |
| phenomenon |
|
| ≫ chaotic phenomena |
YANG, Haichuan |
| Phosphors |
Moriga, Toshihiro |
| Photocatalysis |
Koinkar, Pankaj |
| photocatalyst |
Yonekura, Daisuke |
| photonic band |
Haraguchi, Masanobu |
| photonic crystal |
Haraguchi, Masanobu |
| photonic device (→ optical device) |
| photovoltaic generation system |
Hojo, Masahide / YANG, Haichuan |
| Physical Skill |
Matsuura, Kenji |
| pipe flow |
Ichimiya, Masashi |
| planning support system |
WATANABE, Kojiro |
| plasmonics |
Haraguchi, Masanobu |
| Pneumatic Driving System |
Takaiwa, Masahiro |
| pole assignment |
Kubo, Tomohiro |
| polymer materials |
Minagawa, Keiji |
| polymerization |
|
| ≫ anionic polymerization |
Hirano, Tomohiro |
| ≫ radical polymerization |
Hirano, Tomohiro |
| porous materials |
Horikawa, Toshihide |
| power quality |
Hojo, Masahide |
| power system protection |
Hojo, Masahide |
| prediction |
YANG, Haichuan |
| process |
Nagamatsu, Kentaro |
| Processes of rock weathering |
Nishiyama, Ken-ichi |
| programming |
Tanioka, Hiroki |
| protein |
Hirata, Akira |
| Protein crystallization |
Suzuki, Yoshihisa |
| pulsed power |
Shimomura, Naoyuki |
| Q |
|
| quantitative evaluation |
TAMURA, Takao |
| quantum spin system |
Magishi, Ko-ichi |
| Quaternary system in Southwest Japan |
Nishiyama, Ken-ichi |
| R |
|
| radical polymerization |
Hirano, Tomohiro |
| Rainwater |
TAMURA, Takao |
| reaction engineering |
Shimoda, Naohiro |
| recrystallization |
Okada, Tatsuya |
| Red tide |
TAMURA, Takao |
| reduction |
TAMURA, Takao |
| regional disaster management |
TAMURA, Takao |
| relaminarization |
Ichimiya, Masashi |
| residential environment |
TAMURA, Takao |
| residual stress |
Kusaka, Kazuya / Yonekura, Daisuke |
| RNA |
Hirata, Akira |
| RNAi |
Watanabe, Minoru |
| Robot System |
Takaiwa, Masahiro |
| robotics |
Yasuno, Takashi |
| Route Navigation |
Okushima, Masashi |
| Routing |
Kinoshita, Kazuhiko |
| Rule Generation |
Fukumi, Minoru |
| runoff analysis |
TAMURA, Takao |
| runoff model |
TAMURA, Takao |
| S |
|
| sawing |
Mizobuchi, Akira |
| Seismological Network |
Nakata, Narutoshi |
| self-organizing map |
Nishio, Yoshifumi |
| SEM/EBSD |
Okada, Tatsuya |
| semiconductor |
Kawakami, Retsuo |
| Sensor |
Koinkar, Pankaj |
| separation |
Horikawa, Toshihide |
| shape reconstruction |
Ukida, Hiroyuki |
| SiC |
Okada, Tatsuya |
| signal processing |
|
| ≫ digital signal processing |
Fukumi, Minoru |
| signal transduction |
Watanabe, Minoru |
| Simple analytical methods |
Mizuguchi, Hitoshi |
| simulation |
Takeuchi, Toshiki |
| single crystal |
Okada, Tatsuya |
| small or medium-sized rivers |
TAMURA, Takao |
| small-sized fluid machinery |
Shigemitsu, Toru |
| SNS |
Matsuura, Kenji |
| Solid/Liquid Phase Change Heat Transfer |
Kusano, Koji |
| solute runoff |
TAMURA, Takao |
| sonochemistry (→ green chemistry) |
| spectroscopy |
|
| ≫ X-ray spectroscopy |
Moriga, Toshihiro |
| sports |
Tanioka, Hiroki |
| sputtering |
Kusaka, Kazuya / Yonekura, Daisuke |
| Statistical Learning Algorithms |
Fukumi, Minoru |
| stereoregular polymer |
Hirano, Tomohiro |
| sterilization |
Akutagawa, Masatake |
| stochastic programming |
Uno, Takeshi |
| storage capacity |
TAMURA, Takao |
| strong comparison principle |
Ohnuma, Masaki |
| strong maximum principle |
Ohnuma, Masaki |
| strongly correlated electron systems |
Okamura, Hidekazu |
| Structural Analysis and Simulation |
Nakata, Narutoshi |
| superconductivity |
Hisada, Akihiko |
| superconductor |
Saito, Takahito |
| superionic conductor |
Nakamura, Koichi |
| superionic conductors |
Moriga, Toshihiro |
| surface |
Yanagiya, Shin-ichiro |
| surface plasmon polariton |
Haraguchi, Masanobu |
| surface roughness |
Mizobuchi, Akira |
| synchronization phenomena |
Nishio, Yoshifumi |
| synchrotron radiation |
Okamura, Hidekazu |
| Synchrotron X-ray Crystallography of Protein Crystals |
Suzuki, Yoshihisa |
| systems with time-delay |
Kubo, Tomohiro |
| T |
|
| tabu search |
Uno, Takeshi |
| tectonics |
Aoya, Mutsuki |
| tensioning method |
Mizobuchi, Akira |
| Test Technology |
Yotsuyanagi, Hiroyuki |
| text mining |
Tanioka, Hiroki |
| texture control |
Okada, Tatsuya |
| theory |
|
| ≫ control theory |
Kubo, Tomohiro |
| ≫ graph theory |
Nakayama, Shin-ichi |
| thin film |
Yonekura, Daisuke |
| Three-dimensional measurement |
Terada, Kenji |
| tipped saw |
Mizobuchi, Akira |
| Toll of Expressway |
Okushima, Masashi |
| tool life |
Mizobuchi, Akira |
| tool temperature |
Mizobuchi, Akira |
| tool wear |
Mizobuchi, Akira |
| town-watching |
TAMURA, Takao |
| Track-etched membrane filter |
Mizuguchi, Hitoshi |
| Traffic Control |
Okushima, Masashi |
| Traffic Flow |
Okushima, Masashi |
| Traffic Safety Measure |
Okushima, Masashi |
| transcription |
Hirata, Akira |
| transcription factor |
Watanabe, Minoru |
| Transcriptional Regulation |
Watanabe, Minoru |
| transfer performance |
Shigemitsu, Toru |
| transistor |
Nagamatsu, Kentaro |
| transition |
Ichimiya, Masashi |
| transmission electron microscopy |
Hisazawa, Hiromu / Okada, Tatsuya |
| transparent conducting oxide |
Moriga, Toshihiro / Yonekura, Daisuke |
| transparent conducting oxides (→ transparent conducting oxide) |
| transport planning |
Hyodo, Satoshi |
| transportation engineering |
Hyodo, Satoshi |
| Travel Behaviour Analisys |
Okushima, Masashi |
| tricrystal |
Okada, Tatsuya |
| Tridentiger obscurus |
Kozuki, Yasunori |
| turbulence |
Ichimiya, Masashi |
| turbulence effects |
Noda, Minoru |
| turbulent flow (→ turbulence) |
| U |
|
| ubiquitous computing |
Mitsuhara, Hiroyuki |
| ultra-precision cutting |
Mizobuchi, Akira |
| Ultrasonic method |
Nakamura, Koichi / Watanabe, Takeshi |
| ultrasound |
Yonekura, Daisuke |
| urban planning |
WATANABE, Kojiro |
| Urban Planning for Asian Developing Countries |
WATANABE, Kojiro |
| User administration |
Sano, Masahiko |
| V |
|
| Versatile Video Coding |
Katayama, Takafumi |
| viscosity solutions |
Ohnuma, Masaki |
| VLSI |
Song, Tian / Yotsuyanagi, Hiroyuki |
| W |
|
| Water quality control |
Mizuguchi, Hitoshi |
| Water resource |
TAMURA, Takao |
| water treatment |
Shimomura, Naoyuki |
| water vapor adsorption |
Horikawa, Toshihide |
| watershed |
TAMURA, Takao |
| web-based learning |
Mitsuhara, Hiroyuki |
| welding |
Yonekura, Daisuke |
| wide area measurement system for power system |
Hojo, Masahide |
| Wind Application |
Noda, Minoru |
| wind disaster |
Noda, Minoru |
| wind power generation system |
Hojo, Masahide / YANG, Haichuan |
| wind properties estimation |
Noda, Minoru |
| Wireless Multi-hop Network |
Kinoshita, Kazuhiko |
| workshop |
TAMURA, Takao |
| World Wide Web |
Sano, Masahiko |
| X |
|
| X-ray |
|
| ≫ X-ray spectroscopy |
Moriga, Toshihiro |
| X-ray absorption fine structure (XAFS) |
Murai, Kei-ichiro |
| X-ray crystallography |
Murai, Kei-ichiro |
| X-ray diffraction |
Kusaka, Kazuya |
| X-ray diffractometry |
Moriga, Toshihiro |
| X-ray spectroscopy |
Moriga, Toshihiro |
| XAFS |
Yamamoto, Takashi |
| Xenopus laevis |
Watanabe, Minoru |
| Y |
| Z |
|
| zeolite |
Katoh, Masahiro |