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2020 – today
- 2024
[c83]Hubert Kasprzak, Nina Niewinska, Tomasz Komendzinski, Mihoko Otake-Matsuura, Tomasz M. Rutkowski:
Olfactory Paradigm for Reactive Brain-Computer Interface: EEG Response Spatial Visualization and Clustering. IJCNN 2024: 1-8- 2023
- [c82]Tomasz M. Rutkowski
, Masato S. Abe, Hikaru Sugimoto, Mihoko Otake-Matsuura:
Mild Cognitive Impairment Detection with Machine Learning and Topological Data Analysis Applied to EEG Time-series in Facial Emotion Oddball Paradigm. EMBC 2023: 1-4 - 2022
- [c81]Tomasz M. Rutkowski, Masato S. Abe, Seiki Tokunaga, Tomasz Komendzinski, Mihoko Otake-Matsuura:
Dementia Digital Neuro-biomarker Study from Theta-band EEG Fluctuation Analysis in Facial and Emotional Identification Short-term Memory Oddball Paradigm. EMBC 2022: 4056-4059 - [c80]Krystian Derezinski, Krzysztof Tolpa, Lukasz Furman, Tomasz M. Rutkowski, Wlodzislaw Duch:
Time-frequency analysis combined with recurrence quantification for classification of onset of dementia using data from the oddball BCI paradigm. SCIS/ISIS 2022: 1-6 - [c79]Tomasz M. Rutkowski, Stanislaw Narebski, Piotr Bekier, Tomasz Komendzinski, Hikaru Sugimoto, Mihoko Otake-Matsuura:
Cross-cultural Evaluation of Dementia Passive BCI Neuro-biomarker Candidates. SCIS/ISIS 2022: 1-5 - [c78]Tomasz M. Rutkowski, Masato S. Abe, Seiki Tokunaga, Hikaru Sugimoto, Tomasz Komendzinski, Mihoko Otake-Matsuura:
Passive BCI Oddball Paradigm for Dementia Digital Neuro-biomarker Elucidation from Attended and Inhibited ERPs Utilizing Information Geometry Classification Approaches. SMC 2022: 2657-2662 - 2021
- [c77]Tomasz M. Rutkowski, Masato S. Abe, Tomasz Komendzinski, Mihoko Otake-Matsuura:
Older Adult Mild Cognitive Impairment Prediction from Multiscale Entropy EEG Patterns in Reminiscent Interior Image Working Memory Paradigm. EMBC 2021: 6345-6348 - [c76]Tomasz M. Rutkowski, Masato S. Abe, Mihoko Otake-Matsuura:
Neurotechnology and AI Approach for Early Dementia Onset Biomarker from EEG in Emotional Stimulus Evaluation Task. EMBC 2021: 6675-6678 - 2020
- [c75]Tomasz M. Rutkowski, Masato S. Abe, Marcin Koculak, Mihoko Otake-Matsuura:
Classifying Mild Cognitive Impairment from Behavioral Responses in Emotional Arousal and Valence Evaluation Task - AI Approach for Early Dementia Biomarker in Aging Societies -. EMBC 2020: 5537-5543
2010 – 2019
- 2019
- [c74]Tomasz M. Rutkowski, Marcin Koculak, Masato S. Abe, Mihoko Otake-Matsuura:
Brain Correlates of Task-Load and Dementia Elucidation with Tensor Machine Learning Using Oddball BCI Paradigm. ICASSP 2019: 8578-8582 - [i27]Tomasz M. Rutkowski, Marcin Koculak, Masato S. Abe, Mihoko Otake-Matsuura:
Brain correlates of task-load and dementia elucidation with tensor machine learning using oddball BCI paradigm. CoRR abs/1906.07899 (2019) - [i26]Tomasz M. Rutkowski, Masato S. Abe, Marcin Koculak, Mihoko Otake-Matsuura:
Cognitive Assessment Estimation from Behavioral Responses in Emotional Faces Evaluation Task - AI Regression Approach for Dementia Onset Prediction in Aging Societies. CoRR abs/1911.12135 (2019) - 2018
- [i25]Tomasz M. Rutkowski, Qibin Zhao, Masato S. Abe, Mihoko Otake:
AI Neurotechnology for Aging Societies - Task-load and Dementia EEG Digital Biomarker Development Using Information Geometry Machine Learning Methods. CoRR abs/1811.12642 (2018) - 2017
- [p3]Daiki Aminaka, Tomasz M. Rutkowski:
A Sixteen-Command and 40 Hz Carrier Frequency Code-Modulated Visual Evoked Potential BCI. Brain-Computer Interface Research (6) 2017: 97-104 - 2016
- [j12]Tomasz M. Rutkowski:
Robotic and Virtual Reality BCIs Using Spatial Tactile and Auditory Oddball Paradigms. Frontiers Neurorobotics 10: 20 (2016) - [j11]Tomasz M. Rutkowski:
Data-Driven Multimodal Sleep Apnea Events Detection - Synchrosquezing Transform Processing and Riemannian Geometry Classification Approaches. J. Medical Syst. 40(7): 162:1-162:7 (2016) - [j10]Hiroshi Higashi, Tomasz M. Rutkowski, Toshihisa Tanaka, Yuichi Tanaka:
Multilinear Discriminant Analysis With Subspace Constraints for Single-Trial Classification of Event-Related Potentials. IEEE J. Sel. Top. Signal Process. 10(7): 1295-1305 (2016) - [c73]Hiroshi Higashi, Tomasz M. Rutkowski, Toshihisa Tanaka, Yuichi Tanaka:
Smoothing of xDAWN spatial filters for robust extraction of event-related potentials. APSIPA 2016: 1-5 - [c72]Takumi Kodama, Shoji Makino, Tomasz M. Rutkowski:
Tactile brain-computer interface using classification of P300 responses evoked by full body spatial vibrotactile stimuli. APSIPA 2016: 1-8 - [c71]Tom Stewart, Kiyoshi Hoshino, Andrzej Cichocki, Tomasz M. Rutkowski:
Motor Priming as a Brain-Computer Interface. ICONIP (2) 2016: 538-545 - 2015
- [j9]Zhenyu Cai, Shoji Makino, Tomasz M. Rutkowski:
Brain Evoked Potential Latencies Optimization for Spatial Auditory Brain-Computer Interface. Cogn. Comput. 7(1): 34-43 (2015) - [j8]Shota Kono, Tomasz M. Rutkowski:
Tactile-force brain-computer interface paradigm - Somatosensory multimedia neurotechnology application. Multim. Tools Appl. 74(19): 8655-8667 (2015) - [c70]Hiroshi Higashi, Tomasz M. Rutkowski, Toshihisa Tanaka, Yuichi Tanaka:
Subspace-constrained multilinear discriminant analysis for ERP-based brain computer interface classification. APSIPA 2015: 934-940 - [c69]Aness Belhaouari, Nasreddine Berrached, Tomasz M. Rutkowski:
Classification improvement and analysis of P300 responses with various inter-stimulus intervals in application to spatial visual brain-computer interface. APSIPA 2015: 1054-1058 - [c68]Hiroki Yajima, Shoji Makino, Tomasz M. Rutkowski:
Fingertip stimulus cue-based tactile brain-computer interface. APSIPA 2015: 1059-1064 - [c67]Daiki Aminaka, Shoji Makino, Tomasz M. Rutkowski:
SVM classification study of code-modulated visual evoked potentials. APSIPA 2015: 1065-1070 - [c66]Chisaki Nakaizumi, Shoji Makino, Tomasz M. Rutkowski:
Variable sound elevation features for head-related impulse response spatial auditory BCI. APSIPA 2015: 1094-1099 - [c65]Daiki Aminaka, Shoji Makino, Tomasz M. Rutkowski:
Classification Accuracy Improvement of Chromatic and High-Frequency Code-Modulated Visual Evoked Potential-Based BCI. BIH 2015: 232-241 - [c64]Chisaki Nakaizumi, Shoji Makino, Tomasz M. Rutkowski:
Head-related impulse response cues for spatial auditory brain-computer interface. EMBC 2015: 1071-1074 - [c63]Daiki Aminaka, Shoji Makino, Tomasz M. Rutkowski:
Chromatic and high-frequency cVEP-based BCI paradigm. EMBC 2015: 1906-1909 - [c62]Kensuke Shimizu, Shoji Makino, Tomasz M. Rutkowski:
Inter-stimulus interval study for the tactile point-pressure brain-computer interface. EMBC 2015: 1910-1913 - [c61]Tomasz M. Rutkowski:
Student teaching and research laboratory focusing on brain-computer interface paradigms - A creative environment for computer science students -. EMBC 2015: 3667-3670 - [c60]Daiki Aminaka, Shoji Makino, Tomasz M. Rutkowski:
EEG Filtering Optimization for Code-Modulated Chromatic Visual Evoked Potential-Based Brain-Computer Interface. Symbiotic 2015: 1-6 - [c59]Tomasz M. Rutkowski, Kensuke Shimizu, Takumi Kodama, Peter Jurica, Andrzej Cichocki:
Brain-Robot Interfaces Using Spatial Tactile BCI Paradigms - Symbiotic Brain-Robot Applications. Symbiotic 2015: 132-137 - [p2]Katsuhiko Hamada, Hiromu Mori, Hiroyuki Shinoda, Tomasz M. Rutkowski:
Airborne Ultrasonic Tactile Display BCI. Brain-Computer Interface Research (4) 2015: 57-65 - [i24]Katsuhiko Hamada, Hiromu Mori, Hiroyuki Shinoda, Tomasz M. Rutkowski:
Airborne Ultrasonic Tactile Display BCI. CoRR abs/1501.01144 (2015) - [i23]Tomasz M. Rutkowski, Hiromu Mori, Takumi Kodama, Hiroyuki Shinoda:
Airborne Ultrasonic Tactile Display Brain-computer Interface - A Small Robotic Arm Online Control Study. CoRR abs/1502.07762 (2015) - [i22]Moonjeong Chang, Tomasz M. Rutkowski:
Two-step Input Spatial Auditory BCI for Japanese Kana Characters. CoRR abs/1503.02903 (2015) - [i21]Tomasz M. Rutkowski:
Student Teaching and Research Laboratory Focusing on Brain-computer Interface Paradigms - A Creative Environment for Computer Science Students -. CoRR abs/1506.04226 (2015) - [i20]Chisaki Nakaizumi, Shoji Makino, Tomasz M. Rutkowski:
Head-related Impulse Response Cues for Spatial Auditory Brain-computer Interface. CoRR abs/1506.04374 (2015) - [i19]Kensuke Shimizu, Shoji Makino, Tomasz M. Rutkowski:
Inter-stimulus Interval Study for the Tactile Point-pressure Brain-computer Interface. CoRR abs/1506.04458 (2015) - [i18]Daiki Aminaka, Shoji Makino, Tomasz M. Rutkowski:
Chromatic and High-frequency cVEP-based BCI Paradigm. CoRR abs/1506.04461 (2015) - 2014
- [c58]Trevor Alexander, Anthony Kuh, Katsuhiko Hamada, Hiromu Mori, Hiroyuki Shinoda, Tomasz M. Rutkowski:
Parallel memory-efficient processing of BCI data. APSIPA 2014: 1-9 - [c57]Daiki Aminaka, Shoji Makino, Tomasz M. Rutkowski:
Chromatic SSVEP BCI paradigm targeting the higher frequency EEG responses. APSIPA 2014: 1-7 - [c56]Hiromu Mori, Shoji Makino, Tomasz M. Rutkowski:
Tactile and bone-conduction auditory brain computer interface for vision and hearing impaired users - Stimulus pattern and BCI accuracy improvement. APSIPA 2014: 1-7 - [c55]Tomasz M. Rutkowski:
Multichannel EEG sonification with ambisonics spatial sound environment. APSIPA 2014: 1-4 - [c54]Hiroki Yajima, Shoji Makino, Tomasz M. Rutkowski:
P300 responses classification improvement in tactile BCI with touch-sense glove. APSIPA 2014: 1-7 - [c53]Reo Togashi, Yoshikazu Washizawa, Shota Kono, Tomasz M. Rutkowski:
Bayesian delay time estimation of brainwaves using N100 response in tactile-force Brain-Computer Interface. SCIS&ISIS 2014: 292-296 - [c52]Bertrand Hieronymus, Hiromu Mori, Tomasz M. Rutkowski:
Brain-computer interface using ambisonics-reproduced dynamic sound image effects. SCIS&ISIS 2014: 301-306 - [c51]Waldir Marin Neto, Kensuke Shimizu, Hiromu Mori, Tomasz M. Rutkowski:
Virtual reality feedback environment for brain computer interface paradigm using tactile and bone-conduction auditory modality paradigms. SCIS&ISIS 2014: 469-472 - [c50]Kensuke Shimizu, Hiromu Mori, Shoji Makino, Tomasz M. Rutkowski:
Tactile pressure brain-computer interface using point matrix pattern paradigm. SCIS&ISIS 2014: 473-477 - [p1]Tomasz M. Rutkowski, Hiromu Mori, Koichi Mori:
Multi-command Tactile and Bone-Conduction-Auditory Brain-Computer Interface. Brain-Computer Interface Research (3) 2014: 125-131 - [i17]Chisaki Nakaizumi, Toshie Matsui, Koichi Mori, Shoji Makino, Tomasz M. Rutkowski:
Head-related Impulse Response-based Spatial Auditory Brain-computer Interface. CoRR abs/1404.3958 (2014) - [i16]Katsuhiko Hamada, Hiromu Mori, Hiroyuki Shinoda, Tomasz M. Rutkowski:
Airborne Ultrasonic Tactile Display Brain-computer Interface Paradigm. CoRR abs/1404.4184 (2014) - [i15]Takumi Kodama, Shoji Makino, Tomasz M. Rutkowski:
Spatial Tactile Brain-Computer Interface Paradigm Applying Vibration Stimuli to Large Areas of User's Back. CoRR abs/1404.4226 (2014) - 2013
- [c49]Zhenyu Cai, Shoji Makino, Tomasz M. Rutkowski:
Spatial auditory BCI with ERP responses to front-back to the head stimuli distinction support. APSIPA 2013: 1-8 - [c48]Yohann Lelievre, Yoshikazu Washizawa, Tomasz M. Rutkowski:
Single trial BCI classification accuracy improvement for the novel virtual sound movement-based spatial auditory paradigm. APSIPA 2013: 1-6 - [c47]Yoshihiro Matsumoto, Shoji Makino, Koichi Mori, Tomasz M. Rutkowski:
Classifying P300 responses to vowel stimuli for auditory brain-computer interface. APSIPA 2013: 1-5 - [c46]Nozomu Nishikawa, Shoji Makino, Tomasz M. Rutkowski:
Spatial auditory BCI paradigm based on real and virtual sound image generation. APSIPA 2013: 1-5 - [c45]Hiromu Mori, Shoji Makino, Tomasz M. Rutkowski:
Multi-command Chest Tactile Brain Computer Interface for Small Vehicle Robot Navigation. Brain and Health Informatics 2013: 469-478 - [c44]Tomasz M. Rutkowski, Zbigniew R. Struzik, Danilo P. Mandic:
EEG epileptic seizures separation with multivariate empirical mode decomposition for diagnostic purposes. EMBC 2013: 7128-7131 - [c43]Hiromu Mori, Yoshihiro Matsumoto, Victor V. Kryssanov, Eric W. Cooper, Hitoshi Ogawa, Shoji Makino, Zbigniew R. Struzik, Tomasz M. Rutkowski:
Multi-command Tactile Brain Computer Interface: A Feasibility Study. HAID 2013: 50-59 - [c42]Md. Khademul Islam Molla, Toshihisa Tanaka, Tomasz M. Rutkowski, Kenji Tanaka:
Phase synchronization analysis of EEG channels using bivariate empirical mode decomposition. ICASSP 2013: 1182-1186 - [c41]Takayuki Hamano, Tomasz M. Rutkowski, Hiroko Terasawa, Kazuo Okanoya, Kiyoshi Furukawa:
Generating an Integrated Musical Expression with a Brain-Computer Interface. NIME 2013: 49-54 - [c40]Chisaki Nakaizumi, Koichi Mori, Toshie Matsui, Shoji Makino, Tomasz M. Rutkowski:
Auditory Brain-Computer Interface Paradigm with Head Related Impulse Response-Based Spatial Cues. SITIS 2013: 806-811 - [c39]Shota Kono, Daiki Aminaka, Shoji Makino, Tomasz M. Rutkowski:
EEG Signal Processing and Classification for the Novel Tactile-Force Brain-Computer Interface Paradigm. SITIS 2013: 812-817 - [c38]Daiki Aminaka, Koichi Mori, Toshie Matsui, Shoji Makino, Tomasz M. Rutkowski:
Bone-Conduction-Based Brain Computer Interface Paradigm - EEG Signal Processing, Feature Extraction and Classification. SITIS 2013: 818-824 - [i14]Hiromu Mori, Yoshihiro Matsumoto, Zbigniew R. Struzik, Koichi Mori, Shoji Makino, Danilo P. Mandic, Tomasz M. Rutkowski:
Multi-command Tactile and Auditory Brain Computer Interface based on Head Position Stimulation. CoRR abs/1301.6357 (2013) - [i13]Moonjeong Chang, Nozomu Nishikawa, Zbigniew R. Struzik, Koichi Mori, Shoji Makino, Danilo P. Mandic, Tomasz M. Rutkowski:
Comparison of P300 Responses in Auditory, Visual and Audiovisual Spatial Speller BCI Paradigms. CoRR abs/1301.6360 (2013) - [i12]Hiromu Mori, Yoshihiro Matsumoto, Victor V. Kryssanov, Eric W. Cooper, Hitoshi Ogawa, Shoji Makino, Zbigniew R. Struzik, Tomasz M. Rutkowski:
Multi-command Tactile Brain Computer Interface: A Feasibility Study. CoRR abs/1305.4319 (2013) - [i11]Hiromu Mori, Shoji Makino, Tomasz M. Rutkowski:
Multi-command Chest Tactile Brain Computer Interface for Small Vehicle Robot Navigation. CoRR abs/1307.7342 (2013) - [i10]Yohann Lelievre, Tomasz M. Rutkowski:
Novel Virtual Moving Sound-based Spatial Auditory Brain-Computer Interface Paradigm. CoRR abs/1308.2630 (2013) - [i9]Tomasz M. Rutkowski:
Beyond visual P300 based brain-computer interfacing paradigms. CoRR abs/1309.2055 (2013) - [i8]Shota Kono, Daiki Aminaka, Shoji Makino, Tomasz M. Rutkowski:
EEG Signal Processing and Classification for the Novel Tactile-Force Brain-Computer Interface Paradigm. CoRR abs/1310.1593 (2013) - [i7]Chisaki Nakaizumi, Koichi Mori, Toshie Matsui, Shoji Makino, Tomasz M. Rutkowski:
Auditory Brain-Computer Interface Paradigm with Head Related Impulse Response-based Spatial Cues. CoRR abs/1312.4106 (2013) - 2012
- [j7]Md. Khademul Islam Molla, Md. Rabiul Islam, Toshihisa Tanaka, Tomasz M. Rutkowski:
Artifact suppression from EEG signals using data adaptive time domain filtering. Neurocomputing 97: 297-308 (2012) - [c37]Zhenyu Cai, Shoji Makino, Takeshi Yamada, Tomasz M. Rutkowski:
Spatial auditory BCI paradigm utilizing N200 and P300 responses. APSIPA 2012: 1-7 - [c36]Teruaki Kaniwa, Hiroko Terasawa, Masaki Matsubara, Tomasz M. Rutkowski, Shoji Makino:
EEG steady state synchrony patterns sonification. APSIPA 2012: 1-6 - [c35]Yoshihiro Matsumoto, Nozomu Nishikawa, Shoji Makino, Takeshi Yamada, Tomasz M. Rutkowski:
Auditory steady-state response stimuli based BCI application - the optimization of the stimuli types and lengths. APSIPA 2012: 1-7 - [c34]Nozomu Nishikawa, Yoshihiro Matsumoto, Shoji Makino, Tomasz M. Rutkowski:
The spatial real and virtual sound stimuli optimization for the auditory BCI. APSIPA 2012: 1-9 - [c33]M. Khademul Islam Molla, Toshihisa Tanaka, Tomasz M. Rutkowski:
Multivariate EMD based approach to EOG artifacts separation from EEG. ICASSP 2012: 653-656 - [c32]Mosabber Uddin Ahmed, Naveed ur Rehman, David Looney, Tomasz M. Rutkowski, Preben Kidmose, Danilo P. Mandic:
Multivariate entropy analysis with data-driven scales. ICASSP 2012: 3901-3904 - [c31]Esteve Gallego-Jutglà, Tomasz M. Rutkowski, Andrzej Cichocki, Jordi Solé-Casals:
EEG Signal Analysis via a Cleaning Procedure based on Multivariate Empirical Mode Decomposition. IJCCI 2012: 670-676 - [c30]Hiromu Mori, Yoshihiro Matsumito, Shoji Makino, Victor V. Kryssanov, Tomasz M. Rutkowski:
Vibrotactile stimulus frequency optimization for the haptic BCI prototype. SCIS&ISIS 2012: 2150-2153 - [c29]Moonjeong Chang, Nozomu Nishikawa, Zhenyu Cai, Shoji Makino, Tomasz M. Rutkowski:
Psychophysical responses comparison in spatial visual, audiovisual, and auditory BCI-spelling paradigms. SCIS&ISIS 2012: 2154-2157 - [i6]Tomasz M. Rutkowski, Hiromu Mori, Yoshihiro Matsumoto, Zhenyu Cai, Moonjeong Chang, Nozomu Nishikawa, Shoji Makino, Koichi Mori:
Haptic BCI Paradigm based on Somatosensory Evoked Potential. CoRR abs/1207.5720 (2012) - [i5]Hiromu Mori, Yoshihiro Matsumito, Shoji Makino, Victor V. Kryssanov, Tomasz M. Rutkowski:
Vibrotactile Stimulus Frequency Optimization for the Haptic BCI Prototype. CoRR abs/1210.2942 (2012) - [i4]Yoshihiro Matsumoto, Nozomu Nishikawa, Takeshi Yamada, Shoji Makino, Tomasz M. Rutkowski:
Auditory Steady-State Response Stimuli based BCI Application - The Optimization of the Stimuli Types and Lengths. CoRR abs/1210.2943 (2012) - [i3]Zhenyu Cai, Shoji Makino, Takeshi Yamada, Tomasz M. Rutkowski:
Spatial Auditory BCI Paradigm Utilizing N200 and P300 Responses. CoRR abs/1210.2944 (2012) - [i2]Nozomu Nishikawa, Yoshihiro Matsumoto, Shoji Makino, Tomasz M. Rutkowski:
The Spatial Real and Virtual Sound Stimuli Optimization for the Auditory BCI. CoRR abs/1210.2945 (2012) - [i1]Moonjeong Chang, Nozomu Nishikawa, Zhenyu Cai, Shoji Makino, Tomasz M. Rutkowski:
Psychophysical Responses Comparison in Spatial Visual, Audiovisual, and Auditory BCI-Spelling Paradigms. CoRR abs/1210.2959 (2012) - 2011
- [j6]Tomasz M. Rutkowski, Andrzej Cichocki, Danilo P. Mandic, Toyoaki Nishida:
Emotional empathy transition patterns from human brain responses in interactive communication situations - Brain-computer and machine interactive interfacing approach. AI Soc. 26(3): 301-315 (2011) - [j5]Tomasz M. Rutkowski, Toshihisa Tanaka, Andrzej Cichocki, Donna Erickson, Jianting Cao, Danilo P. Mandic:
Interactive component extraction from fEEG, fNIRS and peripheral biosignals for affective brain-machine interfacing paradigms. Comput. Hum. Behav. 27(5): 1512-1518 (2011) - [c28]Hiroshi Higashi, Tomasz M. Rutkowski, Yoshikazu Washizawa, Andrzej Cichocki, Toshihisa Tanaka:
EEG auditory steady state responses classification for the novel BCI. EMBC 2011: 4576-4579 - [c27]Tomasz M. Rutkowski:
Auditory Brain-Computer/Machine-Interface Paradigms Design. HAID 2011: 110-119 - [c26]Esteve Gallego-Jutglà, Jordi Solé-Casals, Tomasz M. Rutkowski, Andrzej Cichocki:
Application of Multivariate Empirical Mode Decomposition for Cleaning Eye Blinks Artifacts from EEG Signals. IJCCI (NCTA) 2011: 455-460 - 2010
- [j4]Tomasz M. Rutkowski, Danilo P. Mandic, Andrzej Cichocki, Andrzej W. Przybyszewski:
Emd Approach to Multichannel EEG Data - the amplitude and Phase Components Clustering Analysis. J. Circuits Syst. Comput. 19(1): 215-229 (2010) - [c25]Md. Khademul Islam Molla, Toshihisa Tanaka, Tomasz M. Rutkowski, Andrzej Cichocki:
Separation of EOG artifacts from EEG signals using bivariate EMD. ICASSP 2010: 562-565 - [c24]Qi-Wei Shi, Wei Zhou, Jianting Cao, Danilo P. Mandic, Toshihisa Tanaka, Tomasz M. Rutkowski, Ru-Bin Wang:
An Auditory Oddball Based Brain-Computer Interface System Using Multivariate EMD. ICIC (2) 2010: 140-148 - [c23]Yoshikazu Washizawa, Hiroshi Higashi, Tomasz M. Rutkowski, Toshihisa Tanaka, Andrzej Cichocki:
Tensor Based Simultaneous Feature Extraction and Sample Weighting for EEG Classification. ICONIP (2) 2010: 26-33
2000 – 2009
- 2009
- [c22]Tomasz M. Rutkowski, Andrzej Cichocki, Toshihisa Tanaka, Danilo P. Mandic, Jianting Cao, Anca L. Ralescu:
Multichannel spectral pattern separation - An EEG processing application -. ICASSP 2009: 373-376 - [c21]David Looney, Naveed ur Rehman, Danilo P. Mandic, Tomasz M. Rutkowski, Alla Heidenreich, Dagmar Beyer:
Conditioning multimodal information for smart environments. ICDSC 2009: 1-8 - [c20]Qi-Wei Shi, Ju-Hong Yang, Jianting Cao, Toshihisa Tanaka, Tomasz M. Rutkowski, Ru-Bin Wang, Hui-Li Zhu:
EMD Based Power Spectral Pattern Analysis for Quasi-Brain-Death EEG. ICIC (2) 2009: 814-823 - 2008
- [j3]Andrzej Cichocki, Yoshikazu Washizawa, Tomasz M. Rutkowski, Hovagim Bakardjian, Anh Huy Phan, Seungjin Choi, Hyekyoung Lee, Qibin Zhao, Liqing Zhang, Yuanqing Li:
Noninvasive BCIs: Multiway Signal-Processing Array Decompositions. Computer 41(10): 34-42 (2008) - [c19]Justin Dauwels, Tomasz M. Rutkowski, François B. Vialatte, Andrzej Cichocki:
On the synchrony of empirical mode decompositions with application to electroencephalography. ICASSP 2008: 473-476 - [c18]Tomasz M. Rutkowski, Danilo P. Mandic, Andrzej Cichocki, Andrzej W. Przybyszewski:
EMD Approach to Multichannel EEG Data - The Amplitude and Phase Synchrony Analysis Technique. ICIC (1) 2008: 122-129 - [c17]Rafal Zdunek, Tomasz M. Rutkowski:
Nonnegative Tensor Factorization with Smoothness Constraints. ICIC (1) 2008: 300-307 - [c16]Tomasz M. Rutkowski, Andrzej Cichocki, Toshihisa Tanaka, Anca L. Ralescu, Danilo P. Mandic:
Clustering of Spectral Patterns Based on EMD Components of EEG Channels with Applications to Neurophysiological Signals Separation. ICONIP (1) 2008: 453-460 - 2007
- [j2]Tomasz M. Rutkowski, Danilo P. Mandic, Allan Kardec Barros:
A Multimodal Approach to Communicative Interactivity Classification. J. VLSI Signal Process. 49(2): 317-328 (2007) - [c15]Tomasz M. Rutkowski, Danilo P. Mandic:
Modelling the Communication Atmosphere: A Human Centered Multimedia Approach to Evaluate Communicative Situations. Artifical Intelligence for Human Computing 2007: 155-169 - [c14]Danilo P. Mandic, Phebe Vayanos, Christos Boukis, Beth Jelfs, Su Lee Goh, Temujin Gautama, Tomasz M. Rutkowski:
Collaborative Adaptive Learning using Hybrid Filters. ICASSP (3) 2007: 921-924 - [c13]David Looney, Danilo P. Mandic, Tomasz M. Rutkowski:
Regularised Adaptive Fir Filters for Image Denoising. DSP 2007: 55-58 - [c12]Justin Dauwels, François B. Vialatte, Tomasz M. Rutkowski, Andrzej Cichocki:
Measuring Neural Synchrony by Message Passing. NIPS 2007: 361-368 - 2006
- [c11]André Borges Cavalcante, Danilo P. Mandic, Tomasz M. Rutkowski, Allan Kardec Barros:
Speech Enhancement Based on the Response Features of Facilitated EI Neurons. ICA 2006: 585-592 - [c10]Zhe (Sage) Chen, Andrzej Cichocki, Tomasz M. Rutkowski:
Constrained non-Negative Matrix Factorization Method for EEG Analysis in Early Detection of Alzheimer Disease. ICASSP (5) 2006: 893-896 - [c9]Beth Jelfs, Phebe Vayanos, Mo Chen, Su Lee Goh, Christos Boukis, Temujin Gautama, Tomasz M. Rutkowski, Tony Kuh, Danilo P. Mandic:
An Online Method for Detecting Nonlinearity Within a Signal. KES (3) 2006: 1216-1223 - [c8]Tomasz M. Rutkowski, François B. Vialatte, Andrzej Cichocki, Danilo P. Mandic, Allan Kardec Barros:
Auditory Feedback for Brain Computer Interface Management - An EEG Data Sonification Approach. KES (3) 2006: 1232-1239 - 2005
- [c7]Tomasz M. Rutkowski, Danilo P. Mandic:
Communicative Interactivity - A Multimodal Communicative Situation Classification Approach. ICANN (2) 2005: 741-746 - 2004
- [c6]Tomasz M. Rutkowski, Yoko Yamakata, Koh Kakusho, Michihiko Minoh:
Smart Sensor Mesh: Intelligent Sensor Clusters Configuration and Location Discovery for Collaborative Information Processing. IMTCI 2004: 147-157 - [c5]Tomasz M. Rutkowski, Koh Kakusho, Victor V. Kryssanov, Michihiko Minoh:
Evaluation of the Communication Atmosphere. KES 2004: 364-370 - 2003
- [c4]Tomasz M. Rutkowski, Susumu Seki, Yoko Yamakata, Koh Kakusho, Michihiko Minoh:
Toward the Human Communication Efficiency Monitoring from Captured Audio and Video Media in Real Environments. KES 2003: 1093-1100 - 2002
- [j1]Allan Kardec Barros, Tomasz M. Rutkowski, Fumitada Itakura, Noboru Ohnishi:
Estimation of speech embedded in a reverberant and noisy environment by independent component analysis and wavelets. IEEE Trans. Neural Networks 13(4): 888-893 (2002) - [c3]Andrzej Cichocki, Tomasz M. Rutkowski, Krzysztof Siwek:
Blind signal extraction of signals with specified frequency band. NNSP 2002: 515-524 - 2001
- [c2]Allan Kardec Barros, Fumitada Itakura, Tomasz M. Rutkowski, Ali Mansour, Noboru Ohnishi:
Estimation of speech embedded in a reverberant environment with multiple sources of noise. ICASSP 2001: 629-632
1990 – 1999
- 1999
- [c1]Andrzej Cichocki, Liqing Zhang, Tomasz M. Rutkowski:
Blind separation and filtering using state space models. ISCAS (5) 1999: 78-81
Coauthor Index
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