Publication List
Index
1 Impulse response measurement
2. Microphone-array
2.1 Adaptive microphone-array
2.2 Delay-and-sum array
2.3 Noise reduction based on spatial correlation
2.4 Sound source localization in a reverberant space
3. Acoustic Echo Canceller
3.1 Echo canceller system
3.2 Adaptive Algorithm for Acoustic Echo Canceller
3.2.1 Exponentially weighted step-size (ES) algorithms
3.2.2 Fast Projection algorithm and other
3.3 Stereo echo canceller
4. Inverse filtering of room acoustics and its applications
5. 3D sound reproduction.
6.Room acoustics
6.1 Room modeling using common acoustical poles
6.2
7. Modeling of HRTF (head-related transfer function)
8. Blind deconvolution
9. Active noise control
10. Noise reduction signal processing
11. Impulse response measurement
12. General
Yutaka Kaneda,
“Noise Reduction Performance of Various Signals for Impulse Response Measurement"
J. Audio Eng. Soc., vol. 63, no. 5, pp. 348-357 (2015 May).
Ryo Shinohara and Yutaka Kaneda,
Hirokazu Ochiai and Yutaka Kaneda,
“A recursive adaptive method of impulse response measurement
with constant SNR over target frequency band,”
J. Audio Eng. Soc., vol. 61,
no. 9, pp. 647-655 (2013 Sept).
Hirokazu Ochiai and Yutaka Kaneda,
Hirotoshi Takahashi and Yutaka Kaneda,
2. Microphone-array
2.1 Adaptive microphone-array
Y. Kaneda and J. Ohga: "Adaptive microphone-array system for noise reduction," Acoustical Society of America 108th Meeting, Suppl. 1, Vol. 76, LL-11 (1984.10).
Y. Kaneda and J. Ohga: "Adaptive microphone-array system for noise reduction," IEEE Trans. on Acoustics, Speech and Signal Processing, Vol. ASSP-34, No. 6, pp. 1391-1400 (1986.12).
Y. Kaneda: "Adaptive microphone-array system for noise reduction (AMNOR) and its performance studies," Proc. ISCAS'88 (IEEE Int. Symp. on Circuits and Systems) pp. 2395-2398 (1988.06).
Y. Kaneda: "Speech period detection using an adaptive microphone array," Proc. IEEE Workshop on Application of Signal Processing to Audio and Acoustics (1989.10).
A. Kataoka and Y. Ichinose: "A microphone-array configuration for AMNOR (Adaptive microphone-array system for noise reduction) ," J. Acoust. Soc. Jpn. (E), Vol. 11, No. 6, pp. 317-325 (1990.11).
Y. Kaneda: "Directivity characteristics of adaptive microphone-array for noise reduction (AMNOR)," J. Acoust. Soc. Jpn. (E), Vol. 12, No. 4, pp. 179-187 (1991.07).
2.2 Delay-and-sum array
H. Nomura, Y. Kaneda and J. Kojima; "Optimum gains of a delay-and-sum microphone array for near sound field," J. Acoust. Soc. Am., Vol. 100, No.4, Pt. 2, p.2697 (1996.10).
K. Kiyohara, Y. Kaneda, S. Takahashi, H. Nomura and J. Kojima: "A microphone array system for speech recognition," Proc. ICASSP'97, pp.215-218 (1997.4).
2.3. Noise reduction based on spatial correlation
Y. Kaneda and M. Tohyama: "Noise suppression signal processing using 2-Point received signals," Electronics and Communications in Japan Vol. 67-A, No. 12, pp.
19-28 (1984.04). pdf (2.8M)
2.4. Sound source localization in a reverberant space
Y. Kaneda: "Sound source localization for wide-band signals under a reverberant condition," J. Acoust. Soc. Jpn. (E), Vol. 14, No. 1, pp. 47-48 (1993.01).
M. Tanaka and Y. Kaneda: "Performance of sound source direction estimation methods under reverberant conditions," J. Acoust. Soc. Jpn. (E), Vol. 14, No. 4, pp. 291-292 (1993.07).
3. Acoustic echo canceller
3.1 Echo canceller system
3.2 Adaptive Algorithm for Acoustic Echo Canceller
3.2.1 Exponentially weighted step-size (ES) algorithms
S. Makino and Y. Kaneda: "Acoustic echo canceller algorithm based on the variation characteristics of a room impulse response," Proc. ICASSP'90, pp. 1133-1136 (1990.04)
S. Makino and Y. Kaneda: "Exponentially weighted step-size projection algorithm for acoustic echo cancellers," IEICE Trans. on Fundamentals of Electronics, Communications and Computer Sciences, Vol. E75-A, No. 11, pp. 1500-1508 (1992.11).
S. Makino, Y. Kaneda, and N. Koizumi: "Exponentially weighted step-size NLMS adaptive filter based on the statistics of a room impulse response," IEEE Trans. on Speech and Audio, Vol. 1, No. 1, pp. 101-108 (1993.01).
S. Makino and Y. Kaneda: "A new RLS algorithm based on the variation characteristics of a room impulse response," Proc. ICASSP'94, pp. III-373 - III-376 (1994.04).
3.2.2 Fast Projection algorithm and other
M. Tanaka, Y. Kaneda, S. Makino and J. Kojima: "A fast projection algorithm for adaptive filtering," IEICE Trans. on Fundamentals of Electronics, Communications and Computer Sciences, Vol. E78-A, No.10, pp.1355-1361 (1995.10) pdf
M. Tanaka, Y. Kaneda, S. Makino and J. Kojima: "Fast projection algorithm and its step size control," Proc. ICASSP'95, pp. 945-948 (1995.05).
M. Tanaka, Y. Kaneda, and J. Kojima:"A fast converging adaptive filter algorithm for filtered-x systems," J. Acoust. Soc. Jpn.(E), Vol.17, No.6,pp.311-321(1996).
3.3 Stereo echo canceller
4. Inverse filtering of room acoustics and its applications
M. Miyoshi and Y. Kaneda: "Inverse control of room acoustics using multiple loudspeakers and/or microphones," Proc. ICASSP'86, pp. 917-920 (1986.04).
M. Miyoshi and Y. Kaneda: "Inverse filtering of room acoustics," IEEE Trans. on Acoustics, Speech and Signal Processing, Vol. ASSP-36, No. 2, pp. 145-152 (1988.02).
N. Nakajima, Y. Takaki, M. Miyoshi and M. Tohyama: "Sound field control by indefinite MINT filters," Proc.
5. 3-D sound reproduction
6. Room acoustics
6.1 Room modeling using common acoustical poles
Y. Haneda, S. Makino, and Y. Kaneda: "Modeling of a room transfer function using common acoustical poles," Proc. ICASSP'92 (IEEE Int. Conf. on Acoustics, Speech, and Signal Processing), vol. 2, pp. 213-216 (1992.03)
Y. Haneda, S. Makino, and Y. Kaneda: "Common acoustical pole and zero modeling of room transfer functions," IEEE Trans. on Speech and Audio, Vol. 2, No. 2, pp. 320-328 (1994.04).
Y. Haneda, S. Makino, Y. Kaneda and N. Koizumi: "ARMA modeling of a room transfer function at low frequencies," J. Acoust. Soc. Jpn. (E), Vol. 15, No. 5, pp. 353-355 (1994.09).
Y. Haneda, S. Makino and Y. Kaneda: "Multiple-Point Equalization of Room Transfer Functions by using Common Acoustical Poles," IEEE Trans. Speech Audio Processing, Vol. 5, No. 4, pp. 325-333 (1997.07).
Y. Haneda and Y. Kaneda: "Interpolation and Extrapolation of Room Transfer Functions based on Common Acoustical Poles and their Residues," in Proc. IEEE Workshop Applications Signal Processing Audio Acoust., New Paltz, NY (1997.10).
6.2
7. Modeling of HRTF (head-related transfer function)
Y. Haneda, S. Makino and Y. Kaneda: "Common acoustical poles independent of sound directions and modeling of head-related transfer functions," J. Acoust. Soc. Jpn. (E), Vol. 15, No. 4, pp. 277-279 (1994.07). pdf (1M)
8. Blind deconvolution
K. Furuya and Y. Kaneda: "Blind deconvolution based on common zeros of the z-transforms of two observed signals," Proc.of ASA and ASJ Third Joint Meeting, pp.1245-1250 (1996).
K. Furuya and Y. Kaneda: "Two-channel blind deconvolution of nonminimum phase FIR systems, IEICE trans. on Fundamentals of Electronics, Communications and Computer Science, Vol.E80-A, No.5, pp.804-808 (1997).
K. Furuya and Y.Kaneda: "Two-channel blind deconvolution for nonminimum phase impulseresponses," Proc. ICASSP-97, pp.1315-1318 (1997)
9. Active noise control
M. Miyoshi and Y. Kaneda: "Active noise control in a reverberant three-dimensional sound-field," Proc. INTER-NOISE'88, pp. 983-986 (1988.08).
M. Miyoshi and Y. Kaneda: "Active control of broadband random noise in a reverberant three-dimensional space," Noise Control Engineering Journal, Vol. 36, No. 2, pp. 85-90 (1991.03).
Y. Kaneda, M. Tanaka and J. Kojima: "An adaptive algorithm with fast convergence for multi-input sound control," Proc. ACTIVE 95, pp. 993-1004 (1995.07).
pdf (1.54M)
10. Noise reduction signal processing
11. Impulse response measurement
Y. Kaneda: "A study of non-linear effect on acoustic impulse response measurement," J. Acoust. Soc. Jpn. (E), Vol. 16, No.3, pp.193-195 (1995.05). pdf (1M)
12. General
[Last updated 11-Nov-1997]
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