1. |
T. Kamekawa, T. Kuroyama, T. Samejima, M. Miura, K. Nishimiya, Tips for Online Presentation. |

2. |
T. Samejima, Vibration analysis of a slapping electric bass guitar and its application to physical modeling sound synthesis. |

3. |
R. Kai and T. Samejima, Ocean sound propagation analysis using Green’s function parabolic equation method, Spring Meet. Acoust. Soc. Jpn.. |

4. |
T. Samejima, Vibration analysis of a bowed string involving a tremble of a violin bow, Spring Meet. Acoust. Soc. Jpn.. |

5. |
K. Kobayashi, S. Sekiguchi and T. Samejima, Transaural Sound Reproduction Using Acoustic Contrast. |

6. |
S. Sekiguchi and T. Samejima, Physical Modeling Sound Synthesis of Grand Piano Involving Damper. |

7. |
N. Watanabe, S. Sekiguchi and T. Samejima, Coupled vibration analysis of transverse and longitudinal vibrations in piano strings and bridges. |

8. |
H. Tsuzuki, T. Samejima and T. Fuchigami, Influence of the form of endpin-stoppers of cellos on radiated sound. |

9. |
H. Tsuzuki, T. Samejima and T. Fuchigami, Brass endpin-stopper for improving acoustical characteristics of cellos. |

10. |
K. Kawahara, M. Takada, A. Omoto, T. Kaburagi, T. Samejima, K. Yamauchi and K. Wakamiya, Acoustic related demonstrations on the open campus at school of design, kyushu university -case study on the year of 2019-, Autumn Meet. Acoust. Soc. Jpn.. |

11. |
R. Kai and T. Samejima, Ocean sound propagation analysis with obstacles by three-dimensiona parabolic equation method with spectral method, Autumn Meet. Acoust. Soc. Jpn.. |

12. |
A. Higashikawa and T. Samejima, Active control of acoustic energy in sound field with arbitrary boundary condition using an gain scheduling control, Autumn Meet. Acoust. Soc. Jpn.. |

13. |
T. Samejima, Nonlinear physical modeling sound synthesis of cymbals involving dynamics of a stick as a multi-degree-of-freedom system, Autumn Meet. Acoust. Soc. Jpn.. |

14. |
S. Sekiguchi and T. Samejima, Physical modeling sound synthesis of grand piano considering hammer aging, Autumn Meet. Acoust. Soc. Jpn.. |

15. |
R. Kai and T. Samejima, Sound propagation analysis in sea based on three-dimensional parabolic equation method with Chebyshev spectral method, Meet. Marine Acoust. Soc. Jpn.. |

16. |
S. Sekiguchi and T. Samejima, Physical modeling sound synthesis of a grand piano using numerical calculations. |

17. |
Y. Araki and T. Samejima, Design of musical instruments using physical modeling sound synthesis and interactive evolutionary computation. |

18. |
T. Samejima, Physical simulation of the vibration of a bowed string involving dynamics of a violin bow, Autumn Meet. Acoust. Soc. Jpn.. |

19. |
S. Sekiguchi and T. Samejima, Coupled vibration analysis of multiple strings and a bridge in grand piano and its application to physical modeling sound. |

20. |
K. Yamazaki and T. Samejima, Vibration analysis of an electric bass guitar using the finite element method and its application to physical modeling sound synthesis. |

21. |
R. Shimizu and T. Samejima, Nonlinear vibration analysis of a hammered cymbal under non-uniform physical parameters. |

22. |
H. Tsuzuki and T. Samejima, Vibration analysis of a violin body with a soundpost using the finite element method and its application to physical modeling sound synthesis. |

23. |
T. Samejima, Science of membranophones 2018(2). |

24. |
A. Higashikawa and T. Samejima, Active control of acoustic energy in a sound field by finite element method and gain scheduling control theory. |

25. |
T. Samejima, Science of membranophones 2018. |

26. |
T. Samejima, Physical simulation of the vibration of a bowed string involving dynamics of a violin bow, Autumn Meet. Acoust. Soc. Jpn.. |

27. |
T. Samejima and Y. Nishikawa, Nonlinear physical modeling sound synthesis of cymbals involving dynamics of washers and mallets, Autumn Meet. Acoust. Soc. Jpn.. |

28. |
S. Suzuki and T. Samejima, An Acoustic Metamaterial Plate with Variable-Elastic Piezoelectric Elements, Autumn Meet. Acoust. Soc. Jpn.. |

29. |
Y. Yamasaki and T. Samejima, Elastic Parabolic Equation Solution with Chebyshev Spectral Method for Seismo-Acoustic Propagation in Underwater Environments, Autumn Meet. Acoust. Soc. Jpn.. |

30. |
K. Yamazaki T. Samejima and Y. Araki , Vibration analysis of an electric bass guitar by FEM for identifying "Dead spot". |

31. |
T. Samejima and Y. Araki, Structural form creation of an Indian musical drum tabla through high-accuracy numerical analysis, Spring Meet. Acoust. Soc. Jpn.. |

32. |
A. Takahashi and T. Samejima, Non-linear vibration analysis of a membranophone for making pitch glide sounds, Spring Meet. Acoust. Soc. Jpn.. |

33. |
Y. Araki and T. Samejima, Mathematical optimization of a kettledrum using physical modeling and evolutionary computation, Spring Meet. Acoust. Soc. Jpn.. |

34. |
Y. Araki and T. Samejima, Physical modeling sound synthesis of membranophones using a spectral method, Autumn Meet. Acoust. Soc. Jpn.. |

35. |
Yozo Araki, Toshiya Samejima, Physics-based high-efficiency analysis of membranophones using a spectral method, 2017 International Symposium on Musical Acoustics (ISMA), 2017.06. |

36. |
K. Kita, D. Ueno, H. Ishikawa, T. Samejima and H. Shinonaga, Design method of bandpass delta sigma modulator using H∞ control theory, 2017 IEICE General Conference.. |

37. |
G. Shirouze and T. Samejima, Natural frequency distribution adjustment in room sound field using evolutionary structural optimization method, Spring Meet. Acoust. Soc. Jpn.. |

38. |
K. Tsutsui and T. Samejima, Influence of cello endpin on cello body's vibration and sound radiation characteristics, Spring Meet. Acoust. Soc. Jpn.. |

39. |
Y. Mukaihama and T. Samejima, Analysis of super-near-field head-related transfer functions using spherical sound source and multiple spherical obstacles model, Spring Meet. Acoust. Soc. Jpn.. |

40. |
Y. Kadowaki and T. Samejima, Neural network type feedback control for reducing nonlinear distortion on loudspeaker systems, Spring Meet. Acoust. Soc. Jpn.. |

41. |
Toshiya Samejima, Goki Shirouzu, Topological design of distributed mode loudspeakers based on evolutionary structural optimization, Youngnam Kyushu Joint Conference on Acoustics 2017, 2017.02. |

42. |
Yozo Araki, Toshiya Samejima, Acoustic design of timpani using vibro-acoustic numerical analysis, 5th Joint Meeting Acoustical Society of America and Acoustical Society of Japan, 2016.12. |

43. |
Goki Shirouzu, Toshiya Samejima, Design of distributed mode loudspeaker through evolutionary structural optimization, 5th Joint Meeting Acoustical Society of America and Acoustical Society of Japan, 2016.12. |

44. |
Kenji Kita, Toshiya Samejima, Stability improvement of delta-sigma modulator by sliding mode control theory, 2016 IEEE 5th Global Conference on Consumer Electronics (GCCE), 2016.10. |

45. |
Yusuke Kadowaki, Toshiya Samejima, Combined inverse filtering and feedback control for robust equalization and distortion reduction in loudspeaker systems, AES 141st Convention 2016, 2016.09. |

46. |
Y. Araki and T. Samejima, Fourier series expansion type of DtN spectral method for sound field analysis of axisymmetric unbounded domain, Autumn Meet. Acoust. Soc. Jpn.. |

47. |
G. Shirouzu and T. Samejima, Evolutionary structural optimization of diaphragm of distributed mode loudspeaker, Autumn Meet. Acoust. Soc. Jpn.. |

48. |
A. Takahashi and T. Samejima, Finite element analysis of cymbal vibration using axisymmetric thin shell element, Autumn Meet. Acoust. Soc. Jpn.. |

49. |
Y. Kadowaki and T. Samejima, Robust loudspeaker linearization using Model-Following control, Spring Meet. Acoust. Soc. Jpn.. |

50. |
G. Shirouzu and T. Samejima, Design of distributed mode loudspeaker through structural optimization method, Spring Meet. Acoust. Soc. Jpn.. |

51. |
H. Suganuma, Y. Araki and T. Samejima, Sound propagation analysis in sea based on parabolic equation method with Chebyshev spectral method, Spring Meet. Acoust. Soc. Jpn.. |

52. |
Y. Araki and T. Samejima, Fourier series expansion type of spectral method for sound field analysis of axisymmetric cavities, Spring Meet. Acoust. Soc. Jpn.. |

53. |
S. Abe, T. Samejima and Y. Araki, Numerical analysis of vibration field of cylindrical elastic body by spectral method, Spring Meet. Acoust. Soc. Jpn.. |

54. |
K. Kita and T. Samejima, Design approach of a Delta-Sigma Modulator with a switching hyperplane and a sliding mode controller, Spring Meet. Acoust. Soc. Jpn.. |

55. |
Y. Araki and T. Samejima, The role of spectral methods in numerical methods and application to vibro-acoustic analysis. |

56. |
Y Araki and T. Samejima, Fourier expansion type of spectral method for vibration analysis of cylindrical shells, Autumn Meet. Acoust. Soc. Jpn.. |

57. |
T. Samejima and S. Oka, Modal analysis parabolic equation method for calculation of outdoor sound propagation, Autumn Meet. Acoust. Soc. Jpn.. |

58. |
K. Oto, T. Samejima, Y. Araki and S. Abe, Vibro-acoustic analysis of membranophone using axisymmetric elements, Spring Meet. Acoust. Soc. Jpn.. |

59. |
S. Yogiashi and T. Samejima, Effects of shape of a violin bow on its vibration, Spring Meet. Acoust. Soc. Jpn.. |

60. |
K. Takayanagi, T. Samejima and K. Kawahara, Vibro-acoustic analysis of Distributed Mode Loudspeakers introducing viscoelasitc properties in its support condition, Spring Meet. Acoust. Soc. Jpn.. |

61. |
A. Tamaru and T. Samejima, Calculation of reverberation time in heterothermal sound fields based on free path length of sound particles, Spring Meet. Acoust. Soc. Jpn.. |

62. |
S. Abe and T. Samejima, Vibration analysis of three-dimensional axisymmetric elastic body by a spectral method, Spring Meet. Acoust. Soc. Jpn.. |

63. |
Y. Araki and T. Samejima, Spectral method for vibration analysis of axisymmetric membranes and plates, Spring Meet. Acoust. Soc. Jpn.. |

64. |
Toshiya Samejima, Risa Fukuda, Membrane vibration analysis of a membranophone with nonuniform density and tension by a spectral method, Kyushu Youngnam Joint Conference on Acoustics 2015, 2015.01. |

65. |
Kohei Oto, Toshiya Samejima, Yozo Araki, Satoshi Abe, Vibro-acoustic analysis of a membranophone involving two heads by the finite element method using axisymmetric elements, Kyushu Youngnam Joint Conference on Acoustics 2015, 2015.01. |

66. |
Yozo Araki, Toshiya Samejima, Spectral method for vibration analysis of axisymmetric membranes and plates, Kyushu Youngnam Joint Conference on Acoustics 2015, 2015.01. |

67. |
S. Abe and T. Samejima, Vibration analysis of stretched thin plates under non-uniform density and plate bending stiffness, Autumn Meet. Acoust. Soc. Jpn.. |

68. |
S. Abe and T. Samejima, Vibration analysis of stretched thin plates under non-uniform density and plate bending stiffness, Autumn Meet. Acoust. Soc. Jpn.. |

69. |
T. Samejima and S. Takahashi, Sound field analysis by a spectral method in generalized curvilinear coordinates with domain division, Autumn Meet. Acoust. Soc. Jpn.. |

70. |
T. Samejima, Fourier expansion-hybrid type of infinite element for finite element analysis of unbounded problems, Autumn Meet. Acoust. Soc. Jpn.. |

71. |
K. Oto and T. Samejima, Vibro-acoustic analysis of membranophone involving two membranes, Autumn Meet. Acoust. Soc. Jpn.. |

72. |
K. Kita and T. Samejima, Stability of a delta sigma modulator with a dither, Autumn Meet. Acoust. Soc. Jpn.. |

73. |
K. Mitsuyasu and T. Samejima, Multiple-point equalization based on system identification with singular value decomposition, Autumn Meet. Acoust. Soc. Jpn.. |

74. |
K. Takayanagi, T. Samejima and K. Kawahara, Vibro-acoustic analysis of Distributed Mode Loudspeaker, Autumn Meet. Acoust. Soc. Jpn.. |

75. |
T. Samejima and S. Takahashi, Sound field analysis by a spectral method in generalized curvilinear coordinates, Spring Meet. Acoust. Soc. Jpn.. |

76. |
K. Oto and T. Samejima, Vibro-acoustic analysis of membranophones involving bending stiffness of heads, Spring Meet. Acoust. Soc. Jpn.. |

77. |
T. Miyake, H. Inou, K. Mitsuyasu and T. Samejima, Transaural system based on inverse filters with weighted objective functions, Spring Meet. Acoust. Soc. Jpn.. |

78. |
Shang-Lin Lin, Toshiya Samejima, Vibro-acoustic analysis of a headphone by the finite element method and its active noise control, 6th International Symposiumu on Temporal Design (6th ISTD), 2013.11. |

79. |
Yoshitaka Kida, Toshiya Samejima, Calculation of acoustic scattering by a thin plate using spheroidal wave functions and least-squares method, 6th International Symposiumu on Temporal Design (6th ISTD), 2013.11. |

80. |
K. Takayanagi, T. Samejima and K. Kawahara, Methods for analyzing vibration characteristics of distributed mode loudspeakers. |

81. |
Kenji Kita, Toshiya Samejima, Delta-sigma modulator with μ-synthesis and switching loop filter based on the linear gain, 2013 IEEE 2nd Global Conference on Consumer Electronics (GCCE), 2013.10. |

82. |
K. Oto and T. Samejima, Coupled analysis of tensioned circle plate vibration and cylindrical shell vibration, Autumn Meet. Acoust. Soc. Jpn.. |

83. |
K. Mitsuyasu and T. Samejima, Transaural system with improved objective functions, Autumn Meet. Acoust. Soc. Jpn.. |

84. |
S. Lin and T. Samejima, Vibro-acoustic analysis of a headphone by the finite element method and equivalent circuit method, Autumn Meet. Acoust. Soc. Jpn.. |

85. |
Y. Noda and T. Samejima, Inverse filter design by model matching problem in the framework of gain scheduling control theory, Spring Meet. Acoust. Soc. Jpn.. |

86. |
K. Kita and T. Samejima, Design of delta sigma modulator by the switching loop filter based on the linear gain, Spring Meet. Acoust. Soc. Jpn.. |

87. |
S. Lin and T. Samejima, Vibro-acoustic analysis of a headphone by the finite element method and its active noise control, Spring Meet. Acoust. Soc. Jpn.. |

88. |
Y. Kida and T. Samejima, Analysis of acoustic scattering fields by a thin plate using least-squares method and spheroidal wave functions, Spring Meet. Acoust. Soc. Jpn.. |

89. |
Toshiya Samejima, Risa Fukuda, VIBRO-ACOUSTIC ANALYSIS OF MEMBRANOPHONES UNDER NONUNIFORM DENSITY AND TENSION BY A SPECTRAL METHOD AND BOUNDARY ELEMENT METHOD, Youngnam Kyushu Joint Conference on Acoustics 2013, 2013.01. |

90. |
K. Kita and T. Samejima, Design method of delta-sigma modulators based on sliding mode control theory using a linear filter, Autumn Meet. Acoust. Soc. Jpn.. |

91. |
Y. Noda and T. Samejima, Active control of acoustic energy in a sound field using gain scheduling control theory, Autumn Meet. Acoust. Soc. Jpn.. |

92. |
Y. Kida and T. Samejima, Analysis of acoustic scattered field by a thin plate using spheroidal wave functions, Autumn Meet. Acoust. Soc. Jpn.. |

93. |
R. Fukuda and T. Samejima, Vibro-acoustic analysis of Indian traditional percussions using a spectral method and boundary element method, Autumn Meet. Acoust. Soc. Jpn.. |

94. |
Toshiya Samejima, Shiori Ide, Yozo Araki, Vibro-acoustic analysis of wind instruments with membranes on resonance holes, ACOUSTICS 2012 HONG KONG Conference and Exhibition, 2012.05. |

95. |
R. Fukuda and T. Samejima, Vibro-acoustic analysis of membranophones under nonuniform density and tension using a spectral method and boundary element method, Spring Meet. Acoust. Soc. Jpn.. |

96. |
T. Samejima and R. Fukuda, Membrane vibration analysis of a membranophon with nonuniform density and tension by a spectral method, Spring Meet. Acoust. Soc. Jpn.. |

97. |
Y. Noda, H. Sakai and T. Samejima, Control of error signals on inverse filter design using least squares method, Spring Meet. Acoust. Soc. Jpn.. |

98. |
K. Kita and T. Samejima, Design method of delta-sigma modulators based on sliding mode control theory for improving their stability and high accuracy, Autumn Meet. Acoust. Soc. Jpn.. |

99. |
Y. Kida and T. Samejima, Semi-analytical approach by using spherical wave functions and Kirchhoff-Huygens formula for multiple acoustic scattering analysis, Autumn Meet. Acoust. Soc. Jpn.. |

100. |
S. Ide, T. Samejima, and Y. Araki, Numerical coupled analysis and measurement of wind instruments with membranes on resonance holes, Autumn Meet. Acoust. Soc. Jpn.. |

101. |
Y. Sasaki, T. Samejima, and K. Kawahara, Acoustic response analysis of distributed mode loudspeaker by vibro-acoustic analysis, Autumn Meet. Acoust. Soc. Jpn.. |

102. |
Y. Noda and T. Samejima, Prediction of nonminimum-phase zeros in head-related transfer functions, Autumn Meet. Acoust. Soc. Jpn.. |

103. |
M. Takeshita and T. Samejima, Transaural system adopting equalization filter using common AR coefficients and IIR filter, Spring Meet. Acoust. Soc. Jpn.. |

104. |
K. Kita, T. Fukumoto and T. Samejima, Design method of high-order delta-sigma modulators based on robust control theory for improving their stability, Spring Meet. Acoust. Soc. Jpn.. |

105. |
S. Ide and T. Samejima, Acousitc characteristics of wind instruments with membranes on resonance holes, Spring Meet. Acoust. Soc. Jpn.. |

106. |
Y. Araki, T. Samejima and Y. Yanahira, Design of membranophones based on vibro-acoustic analysis, Spring Meet. Acoust. Soc. Jpn.. |

107. |
T. Samejima and T. Fukumoto, Design method of high-order delta-sigma modulators based on H∞ control theory for improving their stability, Autumn Meet. Acoust. Soc. Jpn.. |

108. |
Y. Araki and T. Samejima, Vibro-acoustic analysis of membranophones involving bending stiffness of membrane, Autumn Meet. Acoust. Soc. Jpn.. |

109. |
T. Samejima, Y. Kida and K. Morikuni, Semi-analytical calculation methods for multiple acoustic scattering by arbitrary obstacles, Annual Conference of the Institute of Systems, Control and Information Engineers(ISCIE).. |

110. |
Y. Kida, T. Samejima and K. Morikuni, Semi-analytic method for multiple acoustic scattering field by multiple scatterers. |

111. |
Y. Kida, T. Samejima and K. Morikuni, Evaluation of semi-analytic method for multiple acoustic scattering field analysis, Spring Meet. Acoust. Soc. Jpn.. |

112. |
Y. Araki and T. Samejima, Vibro-acoustic analysis of membranophones involving vibration fields of membranes and shells, Autumn Meet. Acoust. Soc. Jpn.. |

113. |
Y. Sasaki and T. Samejima, A study of a multiple-input/output system identification of a sound field based on experimental modal analysis, Spring Meet. Acoust. Soc. Jpn.. |

114. |
K. Kawahara, T. Samejima and S. Iwamiya, Case study of acoustic education in “Acoustics and visual communication experiments for high school students”, Autumn Meet. Acoust. Soc. Jpn.. |

115. |
T. Samejima, Curriculum of department of acoustic design, Kyushu university: Part 2 Contents of acoustical experiment I and II, Autumn Meet. Acoust. Soc. Jpn.. |

116. |
T. Fukumoto and T. Samejima, Speaker compensation for control of enclosed sound fields using direct rate feedback, Autumn Meet. Acoust. Soc. Jpn.. |

117. |
M. Kashida and T. Samejima, Almost periodic noise reduction based on generalized harmonic analysis, Autumn Meet. Acoust. Soc. Jpn.. |

118. |
Y. Sasaki and T. Samejima, Sound reproduction system by hybrid control combined feedforward and feedback based on H∞ control theory, Autumn Meet. Acoust. Soc. Jpn.. |

119. |
K. Morikuni, T. Samejima and M. Kashida, Analysis of acoustic scattering from multiple obstacles with arbitrary boundary conditions, Autumn Meet. Acoust. Soc. Jpn.. |

120. |
K. Aoki and T. Samejima, Coupled analysis of membrane vibration and cylindrical shell vibration in axisymmetric problems, Autumn Meet. Acoust. Soc. Jpn.. |

121. |
K. Fujiwara, M. Kiyosumi, N. Ashikawa, T. Kaburagi, A. Omoto, T. Samejima and K. Kawahara, On the education unit of Hall-Management-Engineer, Spring Meet. Acoust. Soc. Jpn.. |

122. |
Y. Sasaki and T. Samejima, Active damping control of a sound field by FEM and sliding mode control theory, Spring Meet. Acoust. Soc. Jpn.. |

123. |
Y. Sasaki and T. Samejima, Active damping control of a sound field by sliding mode control theory. |

124. |
H. Komai, M. Kashida and T. Samejima, A method of vibro-acoustic coupled analysis of sound fields with cylindrical shells. |

125. |
Y. Sasaki and T. Samejima, Robustness to head misalignment of sound reproduction system using H∞ control theory, Autumn Meet. Acoust. Soc. Jpn.. |

126. |
K. Miyazaki and T. Samejima, Active modal control by constant gain output feedback using motiohal feedback loudspeaker. |

127. |
A. Yokomichi and T. Samejima, Possibility of avoidance of nonuniqueness on acoustic scattering analysis with quasi-theoretical methods, Autumn Meet. Acoust. Soc. Jpn.. |

128. |
H. Komai and T. Samejima, A method of vibro-acoustic coupled analysis of sound fields with cylindrical shells, Autumn Meet. Acoust. Soc. Jpn.. |

129. |
T. Samejima and K. Kita, Design of inverse filters by H∞ control theory, Autumn Meet. Acoust. Soc. Jpn.. |

130. |
N. Ugai and T. Samejima, H∞ sound reproduction system by using virtual microphone system, Autumn Meet. Acoust. Soc. Jpn.. |

131. |
T. Otsuru, T. Sakuma, S. Sakamoto, Y. Kawai, Y. Horinouchi, T. Samejima, T. Oshima, T. Okubo, K. Takahashi, M. Ikeda, R. Tomiku, Y. Yasuda, K. Kosaka, and T. Masumoto, Construction of AIJ benchmark platform of computational methods for architectural/environmental acoustics , Spring Meet. Acoust. Soc. Jpn.. |

132. |
K. Miyazaki and T. Samejima, Active modal control using constant gain output feedback, Spring Meet. Acoust. Soc. Jpn.. |

133. |
H. Saito, A. Yokomichi, and T. Samejima, Analytical approach to acoustic scattering by obstacles, Spring Meet. Acoust. Soc. Jpn.. |

134. |
Kimitoshi FUKUDOME, Kazuki TAKENOUCHI, Toshiya SAMEJIMA and Naoki ONO, Develpment of a Measurement System of Head Related Impulse Response for All Azimuthal Directions with Discrete Elevations and Resulting Measurement Accuracy, Proceedings of JSEM 2006 Annual Conference on Experimental Mechanics, No.6, pp.293-296 (2006).. |

135. |
H. Kitajima, I. Taniguchi, and T. Samejima, Sound field reproduction system based on H∞ control theory. |

136. |
H. Saito and T. Samejima, Acoustic scattering from a finite cylinder. |

137. |
T. Samejima and T. Mitsui, Active modal control in a sound field based on experimental modal analysis and H∞ control theory, Spring Meet. Acoust. Soc. Jpn.. |

138. |
T. Samejima, T. Mitsui, and D. Yamamoto, Active control of sound fields based on modal analysis and H∞ control theory. |

139. |
T. Samejima and D. Yamamoto, Active modal control in a sound field based on the finite element method and H∞ control theory, Autumn Meet. Acoust. Soc. Jpn.. |

140. |
T. Samejima and D. Yamamoto, Active minimization of sound fields through finite element modeling and H-infinity control theory, Proc. ACTIVE2002. |

141. |
K. Komatsu and T. Samejima, Adaptive feedback filter for broad-band acoustic impedance control using an MFB loudspeaker, Autumn Meet. Acoust. Soc. Jpn.. |

142. |
S. Miyashita and T. Samejima, Formulation of a membrane matrix based on modal analysis in acoustical FEM analysis, Autumn Meet. Acoust. Soc. Jpn.. |

143. |
D. Yamamoto and T. Samejima, Active modal control in a sound field based on the finite element method and H∞ control theory, Autumn Meet. Acoust. Soc. Jpn.. |

144. |
T. Samejima and D. Yamamoto, Active modal control in a sound field by H∞ control theory, 2001 Meet. Institute of Noise Control Engineering of Japan. |

145. |
D. Yamamoto and T. Samejima, Active suppression of reverberation in a sound field by H∞ control theory, Spring Meet. Acoust. Soc. Jpn.. |

146. |
K. Komatsu, T. Samejima, and D. Yamamoto, Active control of wide frequency range acoustic impedance with a state feedback electro-acoustic transducer, Spring Meet. Acoust. Soc. Jpn.. |

147. |
T. Samejima, D. Yamamoto, and K. Komatsu, Active control of a sound field with a state feedback electro-acoustic transducer. |

148. |
S. Miyashita, T. Samejima, and T. Sakuma, Wave acoustical control of a sound field using a membrane and its optimum design, Autumn Meet. Acoust. Soc. Jpn.. |

149. |
D. Yamamoto and T. Samejima, Active suppression of reverberation in a sound field with a state feedback electro-acoustic transducer, Autumn Meet. Acoust. Soc. Jpn.. |

150. |
D. Yamamoto and T. Samejima, Olson's "Electronic Sound Absorber" revisited, Spring Meet. Acoust. Soc. Jpn.. |

151. |
T. Samejima and D. Yamamoto, Active suppression of reverbration in a sound field with a state feedback electro-acoustic transducer, Spring Meet. Acoust. Soc. Jpn.. |

152. |
T. Samejima, System modeling of a sound field including mechanism of a loudspeaker and state feedback control of it, Spring Meet. Acoust. Soc. Jpn.. |

153. |
T. Samejima, Effect of high frequency modes on control characteristics in state feedback control of a sound field, Autumn Meet. Acoust. Soc. Jpn.. |

154. |
T. Samejima, State-space expression of a sound field based on numerical analysis or experimental mode analysis and its application. |

155. |
T. Samejima, Effect of perturbation of boundary condition on control characteristics in state feedback control of a sound field, Annual Meet. Arch. Inst. Jpn.. |