default search action
Youichi Haneda
Yoichi Haneda
Person information
Refine list
refinements active!
zoomed in on ?? of ?? records
view refined list in
export refined list as
showing all ?? records
2020 – today
- 2024
- [c62]Kosuke Yokota, Yoichi Haneda:
Comparison of 3D speech directivity and loudspeaker directivities with different shapes. GCCE 2024: 423-424 - [c61]Kota Sawajiri, Yoichi Haneda:
Subjective Evaluation of Interactive 3D Space Virtual Sound Source with Hand Tracking. GCCE 2024: 425-426 - [c60]Nao Komuro, Yoichi Haneda:
Representation of Spreading Source Width in 3D Space using Higher-Order Ambisonics. GCCE 2024: 427-428 - 2023
- [c59]Miho Hirohashi, Yoichi Haneda:
Subjective Evaluation of a Focused Sound Source Reproducing at the positions of a Listener's Moving Hand. APSIPA ASC 2023: 2395-2401 - [c58]Natsuko Maeda, Yoichi Haneda:
Investigation of loudspeaker array layout for sound field reproduction by room-mode matching in rectangular rooms. GCCE 2023: 426-428 - 2022
- [j25]Israel Mendoza Velázquez
, Héctor M. Pérez Meana, Yoichi Haneda
Ensemble Learning Approach With Class Rotation for Three-Dimensional Classification on Direction-of-Arrival Estimation. IEEE Access 10: 108185-108193 (2022) - [c57]Kensuke Kubo, Yoichi Haneda:
Evaluation of moving sound image rendering by VBAP and HOA with distance gain control. GCCE 2022: 7-8 - [c56]Tianle Zhong, Israel Mendoza Velázquez, Yi Ren
Spherical Convolutional Recurrent Neural Network for Real-Time Sound Source Tracking. ICASSP 2022: 5063-5067 - 2021
- [c55]Israel Mendoza Velázquez, Yi Ren
A fusion method based on class rotations for DNN-DoA Estimation on Spherical Microphone Array. EUSIPCO 2021: 885-889 - [c54]Tianle Zhong, Israel Mendoza Velázquez, Yoichi Haneda:
Involution Based Speech Autoencoder: Investigating the Advanced Vision Operator Performance on Speech Feature Extraction. GCCE 2021: 179-180 - [c53]Israel Mendoza Velázquez, Yi Ren
DOA Estimation for Spherical Microphone Array using Spherical Convolutional Neural Networks. GCCE 2021: 510-511 - [c52]Yi Ren
2D Local Exterior Sound Field Reproduction Using an Addition Theorem Based on Circular Harmonic Expansion. WASPAA 2021: 271-275
2010 – 2019
- 2019
- [c51]Kimitaka Tsutsumi, Kenta Imaizumi, Atsushi Nakadaira, Yoichi Haneda:
Analytical Method to Convert Circular Harmonic Expansion Coefficients for Sound Field Synthesis by Using Multipole Loudspeaker Array. EUSIPCO 2019: 1-5 - [c50]Yuma Koizumi, Noboru Harada
Trainable Adaptive Window Switching for Speech Enhancement. ICASSP 2019: 616-620 - [c49]Kenta Imaizumi, Kimitaka Tsutsumi, Atsushi Nakadaira, Yoichi Haneda:
Analytical Method of 2.5d Exterior Sound Field Synthesis By Using Multipole Loudspeaker Array. WASPAA 2019: 388-392 - 2018
- [j24]Yuma Koizumi
DNN-Based Source Enhancement to Increase Objective Sound Quality Assessment Score. IEEE ACM Trans. Audio Speech Lang. Process. 26(10): 1780-1792 (2018) - [c48]Kimitaka Tsutsumi, Yoichi Haneda, Ken'ichi Noguchil, Hideaki Takada
Directivity Synthesis with Multipoles Comprising a Cluster of Focused Sources Using a Linear Loudspeaker Array. ICASSP 2018: 496-500 - [c47]Yuma Koizumi, Noboru Harada
End-to-End Sound Source Enhancement Using Deep Neural Network in the Modified Discrete Cosine Transform Domain. ICASSP 2018: 706-710 - [c46]Ryusuke Tanaka, Yoichi Haneda:
Music Algorithm Based on Temporal DRR and Rayleigh Quotient for Reverberant Environments. IWAENC 2018: 391-395 - [i2]Yuma Koizumi, Kenta Niwa, Yusuke Hioka, Kazunori Kobayashi, Yoichi Haneda:
DNN-based Source Enhancement to Increase Objective Sound Quality Assessment Score. CoRR abs/1810.09137 (2018) - [i1]Yuma Koizumi, Noboru Harada, Yoichi Haneda:
Trainable Adaptive Window Switching for Speech Enhancement. CoRR abs/1811.02438 (2018) - 2017
- [c45]Koya Sato, Yoichi Haneda:
3D directivity control of a finite cylindrical loudspeaker array with cylindrical harmonics. GCCE 2017: 1-2 - [c44]Yuhei Yamamoto, Yoichi Haneda:
L1-regularised MV beamformer in the spherical harmonic domain for spherical microphone array recording. GCCE 2017: 1-2 - [c43]Yuma Koizumi, Kenta Niwa, Yusuke Hioka
DNN-based source enhancement self-optimized by reinforcement learning using sound quality measurements. ICASSP 2017: 81-85 - 2016
- [j23]Masahiro Fukui, Suehiro Shimauchi, Yusuke Hioka
Acoustic echo and noise canceller for personal hands-free video IP phone. IEEE Trans. Consumer Electron. 62(4): 454-462 (2016) - [c42]Ryusuke Tanaka, Yoichi Haneda:
Direction-of-arrival estimation based on joint diagonalization of matrices in different direct-to-reverberation ratios. IWAENC 2016: 1-5 - [c41]Yuhei Yamamoto, Yoichi Haneda:
Spherical microphone array post-filtering for reverberation suppression using isotropic beamformings. IWAENC 2016: 1-5 - 2014
- [j22]Masahiro Fukui, Shigeaki Sasaki, Yusuke Hiwasaki, Kimitaka Tsutsumi, Sachiko Kurihara, Hitoshi Ohmuro, Yoichi Haneda:
Adaptive Spectral Masking of AVQ Coding and Sparseness Detection for ITU-T G.711.1 Annex D and G.722 Annex B Standards. IEICE Trans. Inf. Syst. 97-D(5): 1264-1272 (2014) - [j21]Shoichi Koyama
Real-Time Sound Field Transmission System by Using Wave Field Reconstruction Filter and Its Evaluation. IEICE Trans. Fundam. Electron. Commun. Comput. Sci. 97-A(9): 1840-1848 (2014) - [j20]Shoichi Koyama
Wave Field Reconstruction Filtering in Cylindrical Harmonic Domain for With-Height Recording and Reproduction. IEEE ACM Trans. Audio Speech Lang. Process. 22(10): 1546-1557 (2014) - [j19]Masahiro Fukui, Suehiro Shimauchi, Yusuke Hioka
Double-talk robust acoustic echo cancellation for CD-quality hands-free videoconferencing system. IEEE Trans. Consumer Electron. 60(3): 468-475 (2014) - [c40]Manabu Okamoto, Ken-ichi Noguchi, Yusuke Hiwasaki, Yoichi Haneda:
Development of wideband handset for high quality IP telephone service trial. GCCE 2014: 523-524 - [c39]Yoichi Haneda, Ken'ichi Furuya
Close-talking spherical microphone array using sound pressure interpolation based on spherical harmonic expansion. ICASSP 2014: 604-608 - 2013
- [j18]Kenta Niwa, Yusuke Hioka
An Estimation Method of Sound Source Orientation Using Eigenspace Variation of Spatial Correlation Matrix. IEICE Trans. Fundam. Electron. Commun. Comput. Sci. 96-A(9): 1831-1839 (2013) - [j17]Shoichi Koyama
Analytical Approach to Wave Field Reconstruction Filtering in Spatio-Temporal Frequency Domain. IEEE Trans. Speech Audio Process. 21(4): 685-696 (2013) - [j16]Yusuke Hioka
Underdetermined Sound Source Separation Using Power Spectrum Density Estimated by Combination of Directivity Gain. IEEE Trans. Speech Audio Process. 21(6): 1240-1250 (2013) - [j15]Kenta Niwa, Yusuke Hioka
Diffused Sensing for Sharp Directive Beamforming. IEEE Trans. Speech Audio Process. 21(11): 2346-2355 (2013) - [c38]Masahiro Fukui, Suehiro Shimauchi, Yusuke Hioka, Hitoshi Ohmuro, Yoichi Haneda:
Acoustic echo reduction robust against echo-path change with instant echo-power-level adjustment. EUSIPCO 2013: 1-5 - [c37]Kenta Niwa, Yusuke Hioka, Kazunori Kobayashi, Ken'ichi Furuya, Yoichi Haneda:
Evaluation of microphone array based on diffused sensing with various filter design methods. EUSIPCO 2013: 1-5 - [c36]Shoichi Koyama
Sound field reproduction using multiple linear arrays based on wave field reconstruction filtering in helicalwave spectrum domain. ICASSP 2013: 271-275 - [c35]Shoichi Koyama
Improvement using circular harmonics beamforming on reverberation problem of wave field reconstruction filtering. ICASSP 2013: 276-280 - [c34]Shoichi Koyama
Map estimation of driving signals of loudspeakers for sound field reproduction from pressure measurements. WASPAA 2013: 1-4 - 2012
- [j14]Shoichi Koyama
Reproducing Virtual Sound Sources in Front of a Loudspeaker Array Using Inverse Wave Propagator. IEEE Trans. Speech Audio Process. 20(6): 1746-1758 (2012) - [j13]Yusuke Hioka
Angular region-wise speech enhancement for hands-free speakerphone. IEEE Trans. Consumer Electron. 58(4): 1403-1410 (2012) - [c33]Hiroaki Itou, Ken'ichi Furuya
Localized sound reproduction using circular loudspeaker array based on acoustic evanescent wave. ICASSP 2012: 221-224 - [c32]Kenta Niwa, Sumitaka Sakauchi, Ken'ichi Furuya
Diffused sensing for sharp directivity microphone array. ICASSP 2012: 225-228 - [c31]Shoichi Koyama
Design of transform filter for reproducing arbitrarily shifted sound field using phase-shift of spatio-temporal frequency. ICASSP 2012: 381-384 - [c30]Kenta Niwa, Yusuke Hioka
Telescopic microphone array using reflector for segregating target source from noises in same direction. ICASSP 2012: 5457-5460 - [c29]Kenta Niwa, Sumitaka Sakauchi, Ken'ichi Furuya
Superdirective beamforming using microphone array and single reflector. ICCE 2012: 17-18 - [c28]SunYong Kim, Takayuki Nakachi, Tatsuya Fujii, Satoru Emura
Highly realistic collaboration system by using 4K multi JPEG2000 codecs and 6-channel acoustic echo canceller. ISPACS 2012: 452-457 - [c27]Satoru Emura, Shoichi Koyama, Ken'ichi Furuya, Yoichi Haneda:
Posterior Residual Echo Canceling and its Complexity Reduction in the Wave Domain. IWAENC 2012 - [c26]Masahiro Fukui, Akira Nakagawa, Suehiro Shimauchi, Yoichi Haneda, Akitoshi Kataoka:
Echo Reduction Using Wiener Gains Considering Short-Time Correlation Between Echo and Near-End Speech. IWAENC 2012 - [c25]Yusuke Hioka, Ken'ichi Furuya, Kenta Niwa, Yoichi Haneda:
Estimation of Direct-to-Reverberation Energy Ratio Based On Isotropic and Homogeneous Propagation Model. IWAENC 2012 - [c24]Suehiro Shimauchi, Yoichi Haneda:
Nonlinear Acoustic Echo Cancellation Based on Piecewise Linear Approximation with Amplitude Threshold Decomposition. IWAENC 2012 - 2011
- [j12]Yusuke Hioka
Improving Power Spectra Estimation in 2-Dimensional Areas Using Number of Active Sound Sources. IEICE Trans. Fundam. Electron. Commun. Comput. Sci. 94-A(1): 273-281 (2011) - [j11]Yusuke Hioka
Estimating Direct-to-Reverberant Energy Ratio Using D/R Spatial Correlation Matrix Model. IEEE ACM Trans. Audio Speech Lang. Process. 19(8): 2374-2384 (2011) - [c23]Shoichi Koyama, Yusuke Hiwasaki, Ken'ichi Furuya, Yoichi Haneda:
Inversewave propagation for reproducing virtual sources in front of loudspeaker array. EUSIPCO 2011: 1322-1326 - [c22]Yoichi Haneda, Ken'ichi Furuya
Design of multipole loudspeaker array based on spherical harmonic expansion. ICASSP 2011: 141-144 - [c21]Satoru Emura
A method for posterior frequency-domain multi-channel residual echo canceling. ICASSP 2011: 421-424 - [c20]Masahiro Fukui, Shigeaki Sasaki, Yusuke Hiwasaki, Sachiko Kurihara, Yoichi Haneda:
Dual-Mode AVQ Coding Based on Spectral Masking and Sparseness Detection for ITU-T G.711.1/G.722 Super-Wideband Extensions. INTERSPEECH 2011: 2525-2528 - [c19]Shoichi Koyama
Design of transform filter for sound field reproduction using microphone array and loudspeaker array. WASPAA 2011: 5-8 - [c18]Hiroaki Itou, Ken'ichi Furuya
Evanescentwave reproduction using linear array of loudspeakers. WASPAA 2011: 37-40 - 2010
- [c17]Kenta Niwa, Yusuke Hioka
Estimation of sound source orientation using eigenspace of spatial correlation matrix. ICASSP 2010: 129-132 - [c16]Yusuke Hioka
Estimating direct-to-reverberant energy ratio based on spatial correlation model segregating direct sound and reverberation. ICASSP 2010: 149-152
2000 – 2009
- 2009
- [c15]Yusuke Hioka, Ken'ichi Furuya, Youichi Haneda, Akitoshi Kataoka:
Speech enhancement in a 2-dimensional area based on power spectrum estimation of multiple areas with investigation of existence of active sources. INTERSPEECH 2009: 1323-1326 - [c14]Shoichiro Saito, Akira Nakagawa, Yoichi Haneda:
Dynamic impulse response model for nonlinear acoustic system and its application to acoustic echo canceller. WASPAA 2009: 201-204 - 2008
- [j10]Suehiro Shimauchi, Youichi Haneda, Akitoshi Kataoka:
Robust Frequency Domain Acoustic Echo Cancellation Filter Employing Normalized Residual Echo Enhancement. IEICE Trans. Fundam. Electron. Commun. Comput. Sci. 91-A(6): 1347-1356 (2008) - [j9]Kazunori Kobayashi, Yoichi Haneda, Ken'ichi Furuya
A Hands-Free Unit with Noise Reduction by Using Adaptive Beamformer. IEEE Trans. Consumer Electron. 54(1): 116-122 (2008) - [j8]Yusuke Hioka
A display-mounted high-quality stereo microphone array for high-definition videophone system. IEEE Trans. Consumer Electron. 54(2): 778-786 (2008) - [c13]Ken'ichi Furuya, Akitoshi Kataoka, Youichi Haneda:
Noise robust speech dereverberation using constrained inverse filter. INTERSPEECH 2008: 427-430 - 2007
- [j7]Suehiro Shimauchi, Youichi Haneda, Akitoshi Kataoka, Akinori Nishihara:
Gradient-Limited Affine Projection Algorithm for Double-Talk-Robust and Fast-Converging Acoustic Echo Cancellation. IEICE Trans. Fundam. Electron. Commun. Comput. Sci. 90-A(3): 633-641 (2007) - [j6]Kazunori Kobayashi, Ken'ichi Furuya
An Approach to Solve Local Minimum Problem in Sound Source and Microphone Localization. IEICE Trans. Fundam. Electron. Commun. Comput. Sci. 90-A(12): 2826-2834 (2007) - 2006
- [j5]Satoru Emura, Youichi Haneda, Akitoshi Kataoka, Shoji Makino:
Stereo echo cancellation algorithm using adaptive update on the basis of enhanced input-signal vector. Signal Process. 86(6): 1157-1167 (2006) - 2004
- [c12]Satoru Emura
A solution to echo path imbalance problem in stereo echo cancellation. ICASSP (4) 2004: 129-132 - 2003
- [c11]Satoru Emura
A method of coherence-based step-size control for robust stereo echo cancellation. ICASSP (5) 2003: 592-595 - 2002
- [c10]Yoichi Haneda:
Active noise control with a virtual microphone based on common-acoustical-pole and residue model. ICASSP 2002: 1877-1880 - [c9]Satoru Emura
Enhanced frequency-domain adaptive algorithm for stereo echo cancellation. ICASSP 2002: 1901-1904 - [c8]Akira Nakagawa, Yoichi Haneda:
A study of an adaptive algorithm for stereo signals with a power difference. ICASSP 2002: 1913-1916 - 2000
- [c7]Akira Nakagawa, Suehiro Shimauchi, Yoichi Haneda, Shigeaki Aoki, Shoji Makino:
Channel-number-compressed multi-channel acoustic echo canceller for high-presence teleconferencing system with large display. ICASSP 2000: 813-816
1990 – 1999
- 1999
- [j4]Yoichi Haneda, Shoji Makino
Common-acoustical-pole and zero modeling of head-related transfer functions. IEEE Trans. Speech Audio Process. 7(2): 188-196 (1999) - [j3]Yoichi Haneda, Yutaka Kaneda, Nobuhiko Kitawaki:
Common-acoustical-pole and residue model and its application to spatial interpolation and extrapolation of a room transfer function. IEEE Trans. Speech Audio Process. 7(6): 709-717 (1999) - [c6]Suehiro Shimauchi, Shoji Makino, Yoichi Haneda, Akira Nakagawa, Sumitaka Sakauchi:
A stereo echo canceller implemented using a stereo shaker and a duo-filter control system. ICASSP 1999: 857-860 - 1998
- [c5]Suehiro Shimauchi, Yoichi Haneda, Shoji Makino, Yutaka Kaneda:
New configuration for a stereo echo canceller with nonlinear pre-processing. ICASSP 1998: 3685-3688 - 1997
- [j2]Yoichi Haneda, Shoji Makino
Multiple-point equalization of room transfer functions by using common acoustical poles. IEEE Trans. Speech Audio Process. 5(4): 325-333 (1997) - [c4]Shoji Makino, Klaus Strauss, Suehiro Shimauchi, Yoichi Haneda, Akira Nakagawa:
Subband stereo echo canceller using the projection algorithm with fast convergence to the true echo path. ICASSP 1997: 299-302 - 1996
- [c3]Yoichi Haneda, Shoji Makino, Junji Kojima, Suehiro Shimauchi:
Implementation and evaluation of an acoustic echo canceller using duo-filter control system. EUSIPCO 1996: 1-4 - [c2]Shoji Makino, Josef Noebauer, Yoichi Haneda, Akira Nakagawa:
SSB subband echo canceller using low-order projection algorithm. ICASSP 1996: 945-948 - 1994
- [j1]Yoichi Haneda, Shoji Makino
Common acoustical pole and zero modeling of room transfer functions. IEEE Trans. Speech Audio Process. 2(2): 320-328 (1994) - 1992
- [c1]Yoichi Haneda, Shoji Makino, Yutaka Kaneda:
Modeling of a room transfer function using common acoustical poles. ICASSP 1992: 213-216
Coauthor Index
manage site settings
To protect your privacy, all features that rely on external API calls from your browser are turned off by default. You need to opt-in for them to become active. All settings here will be stored as cookies with your web browser. For more information see our F.A.Q.
Unpaywalled article links
Add open access links from to the list of external document links (if available).
Privacy notice: By enabling the option above, your browser will contact the API of unpaywall.org to load hyperlinks to open access articles. Although we do not have any reason to believe that your call will be tracked, we do not have any control over how the remote server uses your data. So please proceed with care and consider checking the Unpaywall privacy policy.
Archived links via Wayback Machine
For web page which are no longer available, try to retrieve content from the of the Internet Archive (if available).
Privacy notice: By enabling the option above, your browser will contact the API of archive.org to check for archived content of web pages that are no longer available. Although we do not have any reason to believe that your call will be tracked, we do not have any control over how the remote server uses your data. So please proceed with care and consider checking the Internet Archive privacy policy.
Reference lists
Add a list of references from ,
, and
to record detail pages.
load references from crossref.org and opencitations.net
Privacy notice: By enabling the option above, your browser will contact the APIs of crossref.org, opencitations.net, and semanticscholar.org to load article reference information. Although we do not have any reason to believe that your call will be tracked, we do not have any control over how the remote server uses your data. So please proceed with care and consider checking the Crossref privacy policy and the OpenCitations privacy policy, as well as the AI2 Privacy Policy covering Semantic Scholar.
Citation data
Add a list of citing articles from and
to record detail pages.
load citations from opencitations.net
Privacy notice: By enabling the option above, your browser will contact the API of opencitations.net and semanticscholar.org to load citation information. Although we do not have any reason to believe that your call will be tracked, we do not have any control over how the remote server uses your data. So please proceed with care and consider checking the OpenCitations privacy policy as well as the AI2 Privacy Policy covering Semantic Scholar.
OpenAlex data
Load additional information about publications from .
Privacy notice: By enabling the option above, your browser will contact the API of openalex.org to load additional information. Although we do not have any reason to believe that your call will be tracked, we do not have any control over how the remote server uses your data. So please proceed with care and consider checking the information given by OpenAlex.
last updated on 2024-12-13 19:11 CET by the dblp team
all metadata released as open data under CC0 1.0 license
see also: Terms of Use | Privacy Policy | Imprint
dblp was originally created in 1993 at:
since 2018, dblp has been operated and maintained by:
the dblp computer science bibliography is funded and supported by: