[1] A. Anglade, M. Tiemann, and F. Vignoli, “Virtual Communities for Creating Shared Music Channels,” in Proceedings of International Conference on Music Information Retrieval, pp. 95–100, 2007.
[2] J. P. Bello, L. Daudet, S. Abdallah, C. Duxbury, M. Davies, and M. B. Sandler, “A Tutorial on Onset Detection in Music Signals,” IEEE Transactions on Speech and Audio Processing, Vol. 13, No. 5, pp. 1035-1047, 2005.
[3] S. J. Cunningham, D. Bainbridge, and D. McKay, “Finding New Music: A Diary Study of Everyday Encounters with Novel Songs,” in Proceedings of International Conference on Music Information Retrieval, pp. 83-88, 2007.
[4] S. Dixon, “Onset Detection Revisited,” in Proceedings of International Conference on Digital Audio Effects, pp. 133-137, 2006.
[5] S. Dixon, “Simple Spectrum-Based Onset Detection,” in Proceedings of Music Information Retrieval Evaluation eXchange, pp. 62-66, 2006.
[6] S. Dixon, “Learning to Detect Onsets of Acoustic Piano Tones,” Journal of New Music Research, Vol. 30, No. 1, pp. 39-58, 2001.
[7] C. Duxbury, J. P. Bello, M. Davies, and M. Sandler, “Complex Domain Onset Detection for Musical Signals,” in Proceedings of International Conference on Digital Audio Effects, pp. 1-4, 2003.
[8] S. Essid, G. Richard, and B. David, “Instrument Recognition in Polyphonic Music Based on Automatic Taxonomies,” IEEE Transactions on Audio, Speech and Language Processing, Vol. 14, Issue 1, pp. 68–80, 2006.
[9] M. Goto, and Y. Muraoka, “Beat Tracking based on Multiple-agent Architecture A Real-time Beat Tracking System for Audio Signals,” in Proceedings of International Conference on Multiagent Systems, pp. 159-171, 1996.
[10] M. Goto, and Y. Muraoka, “Sound Onset Detection by Applying Psychoacoustic Knowledge,” IEEE International Conference on Acoustics, Speech and Signal Processing, Vol. 6, pp. 115-118, 1999.
[11] M. Goto, “A Chorus-section Detection Method for Musical Audio Signals,” IEEE Transactions on Audio, Speech and Language Processing, Vol. 14, No. 5, pp.
437-440, 2003.
[12] M. Goto, and Y. Muraoka, “A Beat Tracking System for Acoustic Signals of Music,”
in Proceedings of the ACM International Conference on Multimedia, pp. 365-372, 1993.
39
[13] M. Goto, and Y. Muraoka, “A Real-time Beat Tracking System for Audio Signals,” in Proceedings of International Computer Music Conference, pp. 171-174, 1995.
[14] M. Goto, “A Predominant-F0 Estimation Method for Polyphonic Musical Audio Signals,” in Proceedings of Music Information Retrieval Evaluation eXchange, pp.
1085-1088, 2004.
[15] M. Goto, “A Real-time Music-scene-description System: Predominant-F0 Estimation for Detecting Melody and Bass Lines in Real-world Audio Signals,” Speech Communication, Vol. 43, No. 4, pp. 311–329, 2004.
[16] C. Duxbury, J. P. Bello, M. Davies, and M. Sandler, “Complex Domain Onset Detection for Musical Signals,” in Proceedings of International Conference on Digital Audio Effects, pp. 8-11, 2003.
[17] H. Helge, I. Mierswa, B. Möller, K. Morik, and M. Wurst. “A Benchmark Dataset for Audio Classification and Clustering,” in Proceedings of International Conference on Music Information Retrieval, pp. 528-531, 2005.
[18] R. Jeremy, and C.H. Lee, “A Study on Music Genre Classification Based on Universal Acoustic Models,” in Proceedings of International Conference on Music Information Retrieval, pp. 89-94, 2006.
[19] I. Karpov, “Hidden Markov Classification for Musical Genres,” Technical Report, Rice University, 2002.
[20] I. Karpov, “Learning Musical Instruments from Mixtures of Audio with Weak Labels,”
in Proceedings of International Conference on Music Information Retrieval, pp.
128-132, 2008.
[21] A. P. Klapuri, A. J. Eronen, and J. T. Astola, “Analysis of the Meter of Acoustic Musical Signals,” IEEE Transactions and Audio, Speech, and Language Processing, Vol. 14, No. 1, pp. 411-440, 2006.
[22] T. Kitahara, M. Goto, K. Komatani, T. Ogata, and HG. Okuno, “Instrument Identification in Polyphonic Music: Feature Weighting to Minimize Influence of Sound Overlaps,” European Association for Signal Processing Journal on Advances in Signal Processing, Vol. 2007, 2007.
[23] M. Li, and R. Sleep, “Genre Classification Via an LZ78 Based String Kernel,” in Proceedings of International Conference on Music Information Retrieval, pp. 252-259, 2005.
[24] J.C.R. Licklider, “A Duplex Theory of Pitch Perception,” Experiantia, No. 7, pp.
128-134, 1951.
40
[25] R. F. Lyon, “A Computational Model of Filtering, Detection, and Compression in the Cochlea,” IEEE International Conference on Acoustics, Speech, and Signal Processing, Vol. 7, pp. 1282-1285, 1982.
[26] C. McKay, and I. Fujinaga, “Musical Genre Classification: Is It Worth Pursuing and How Can it be Improved?,” in Proceedings of International Conference on Music Information Retrieval, pp. 101-107, 2006.
[27] A. Meng, and J. S. Taylor, “An Investigation of Feature Models for Music Genre Classification Using the Support Vector Classifier,” in Proceedings of International Conference on Music Information Retrieval, pp. 604-609, 2005.
[28] F. Pachet, and D. Cazaly, “A Taxonomy of Musical Genres,” in Proceedings Content-Based Multimedia Information Access, Vol. 2, pp.1238-1245, 2000.
[29] E. Pampalk, and M. Goto, “Musicsun: A New Approach to Artist Recommendation,”
in Proceedings of International Conference on Music Information Retrieval, pp.
249-272, 2007.
[30] D. Pan, “A Tutorial on MPEG/Audio Compression,” IEEE Multimedia, Vol. 2, Issue 2, pp. 60-74, 1995.
[31] M. Slaney, “Lyon's Cochlear Model,” Technical Report # 13, Apple Computer Inc., 1988.
[32] M. Slaney, “Auditory Toolbox,” Version 2, Technical Report No: 1998-010, Internal Research Corporation, 1988.
[33] M. Slaney, and R.F. Lyon, “A Perceptual Pitch Detector,” IEEE International Conference on Acoustics, Speech, and Signal Processing, Vol. 1, pp. 357-360, 1990.
[34] C. C. Todd, G. A. Davidson, M. F. Davis ,L. D. Fielder, B. D. Link, and S. Vernon,
“AC-3: Flexible Perceptual Coding for Audio Transmission and Storage,” in Proceedings Convention Audio Engineering Society, pp. 89-102, 1994.
[35] T. Tolonen, “A Computationally Efficient Multipitch Analysis Model,” IEEE Transactions on Speech and Audio Processing, Vol. 8, No. 6, pp. 708-716, 2000.
[36] G. Tzanetakis, and P. Cook, “Music Genres Classification of Audio Signals,” IEEE Transactions on Speech and Audio Processing, Vol. 10, No. 5, pp. 293-302, 2002.
[37] K. West, and S. Cox, “Finding an Optimal Segmentation for Audio Genre Classification,” in Proceedings of International Conference on Pattern Recognition, pp.
680-685, 2006.
[38] K. West, and S. Cox, “Features and Classifiers for the Automatic Classification of Musical Audio Signals,” in Proceedings of International Conference on Music Information Retrieval, pp. 531-536, 2004.
41
[39] Y. Yaslan, and Z. Cataltepe, “Audio Music Genre Classification Using Different Classifiers and Feature Selection Methods,” in Proceedings of International Conference on Pattern Recognition, Vol. 2, pp. 573-576, 2006.
[40] 尹璐,“許守誠訂譜的潮州箏曲研究,”武漢音樂學院碩士論文,2007.
[41] 李軍,“古箏演奏與心理音色,”中國戲曲學院學報,第1 期,頁 99-102,2007.
[42] 杜亚雄,“中國傳統箏樂在音色運用方面的特徵,”浙江藝術聯應學院學報,第 1 期,第一卷,頁55-58,2003.
[43] 余虹,“聲樂藝術的重要環節,”華南師範大學學報,第5 期,頁 129-133,2001.
[44] 何育齋,“何育齋箏譜遺稿,”人民音樂出版社,2008.
[45] 林莉萍,“潮州箏曲《寒鴉戲水》四種不同演奏版本比較研究,”武漢音樂學院碩 士論文,2005.
[46] 林雅琇,“潮州箏樂素材在當代箏樂創作中之運用,”演奏與詮釋研究生學術研討 會論文集,第二屆,2008.
[47] 林雅琇,“潮州箏曲《寒鴉戲水》之版本研究,”演奏與詮釋研究生學術研討會論 文集,第一屆,頁131-160,2007.
[48] 林東河、黃好吟,“箏曲彈奏集(第一冊),”學藝出版社,1990.
[49] 許守誠、許菱子,“談箏的左手揉按,”樂府新聲-瀋陽音樂學院學報,第3 期,頁 62-64,1989.
[50] 許冰,“唐箏探析,”析北京師範大學音樂學碩士學位論文,2006.
[51] 莊國年,“古箏初級教程,”生韻出版社,2007.
[52] 張曉清,“音色的采借,”中國音樂學,第2 期,頁 112-114,2008.
[53] 許媛淇,“音樂轉譯為演出之探討─以古箏曲《風月之名》為例,”演奏與詮釋研究 生學術研討會論文集,第二屆,2008.
[54] 莫軍梅,“古箏學習差的慢練,”皖西學院學報,第6 期,頁 153-154,2005.
[55] 張儷瓊,“現代古箏演奏技法符號之探討,”藝術學報,第69 期,頁 39-52,2001.
[56] 張儷瓊,“客家箏曲《出水蓮》乙凡音之按顫手法模式分析一個時距定量的測音方 法與附加頻率落點分析之應用研究,”藝術學報,第80 期,頁 175-194,2007.
[57] 張儷瓊,“河南箏樂大顫音之音頻樣態研究,”藝術學報,第85 期,頁 55-75,2005.
[58] 張儷瓊,“箜篌與豎琴聲學特性之比較研究,”藝術學報,第60 期,頁 123-148,
1998.
[59] 張儷瓊,“論【鮮花調】在地方箏派音樂中之存見與流變,”藝術學報,第77 期,
頁 87-114,2005.