A |
|
adaptive control |
Ikeda, Kenji |
adaptive hypermedia |
Mitsuhara, Hiroyuki |
Aerial image processing |
Karungaru, Stephen Githinji |
artificial intelligence |
KANG, XIN / Shishibori, Masami |
Autonomous Distributed Control |
Kinoshita, Kazuhiko |
B |
C |
|
Causal Machine Learning |
KANG, XIN |
chaos |
|
≫ chaotic phenomena |
YANG, Haichuan |
chaotic phenomena |
YANG, Haichuan |
Character Recognition |
Karungaru, Stephen Githinji |
Cognitive Dual Process Imitative Neuro-Symbolic AI |
KANG, XIN |
cognitive psychology |
KANG, XIN |
complex systems |
YANG, Haichuan |
D |
|
data processing |
YANG, Haichuan |
decentralized control |
Ikeda, Kenji |
deep learning |
KANG, XIN |
Depression Detection Assistant AI |
KANG, XIN |
Dictionary Retrieval |
Fuketa, Masao / Morita, Kazuhiro |
digital signal processing |
Fukumi, Minoru |
E |
|
e-learning |
Mitsuhara, Hiroyuki |
electroencephalogram |
Ito, Shin-ichi |
Emotion Recognition |
KANG, XIN / Matsumoto, Kazuyuki |
energy conversion |
YANG, Haichuan |
English Composition Support |
Matsumoto, Kazuyuki |
entertainment computing |
Mitsuhara, Hiroyuki |
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 |
financial engineering |
KANG, XIN |
G |
|
genetic algorithm |
YANG, Haichuan |
Genetic Algorithms |
Karungaru, Stephen Githinji |
H |
|
human interface |
Nishimura, Ryota |
human sensing |
Fukumi, Minoru |
I |
|
image processing |
Terada, Kenji |
Image Understanding |
Fukumi, Minoru |
Individual Characteristics |
Ito, Shin-ichi |
information retrieval system |
Shishibori, Masami |
information sharing |
Mitsuhara, Hiroyuki |
Information Visualization |
Ito, Shin-ichi |
Intelligent Systems |
Fukumi, Minoru |
interactive interface |
Nishimura, Ryota |
J |
K |
|
Knowledge Acqisition |
Fukumi, Minoru |
L |
|
Large Language Models |
KANG, XIN |
M |
|
machine learning |
YANG, Haichuan |
medical imaging |
Ito, Momoyo |
Mobile Network |
Kinoshita, Kazuhiko |
multimedia |
Shishibori, Masami |
multimodal interaction |
Nishimura, Ryota |
Multimodal Machine Learning |
KANG, XIN |
N |
|
Natural Language Analysis |
Fuketa, Masao |
natural language processing |
Morita, Kazuhiro |
network architecture |
Kinoshita, Kazuhiko |
neural network |
Fukumi, Minoru |
Neural Networks |
Karungaru, Stephen Githinji |
neuron model |
YANG, Haichuan |
O |
|
optimization |
KANG, XIN / YANG, Haichuan |
Outcome Management |
Matsumoto, Kazuyuki |
P |
|
particle swarm optimization |
YANG, Haichuan |
phenomenon |
|
≫ chaotic phenomena |
YANG, Haichuan |
photovoltaic generation system |
YANG, Haichuan |
prediction |
YANG, Haichuan |
Q |
R |
|
Routing |
Kinoshita, Kazuhiko |
Rule Generation |
Fukumi, Minoru |
S |
|
signal processing |
|
≫ digital signal processing |
Fukumi, Minoru |
speech recognition |
Nishimura, Ryota |
spoken dialog system |
Nishimura, Ryota |
Statistical Learning Algorithms |
Fukumi, Minoru |
T |
|
Three-dimensional measurement |
Terada, Kenji |
U |
|
ubiquitous computing |
Mitsuhara, Hiroyuki |
V |
W |
|
web-based learning |
Mitsuhara, Hiroyuki |
wind power generation system |
YANG, Haichuan |
Wireless Multi-hop Network |
Kinoshita, Kazuhiko |
XYZ |