此研究是利用128通道全腦式腦磁圖儀來探討人類大腦聽覺皮質反應，在本文中我們將討論在不同頻率的聲音刺激下，聽覺誘發的開端反應on-response N100m(on-N1m)的時間以及空間演化特性。

1. M.F. Bear et al., Neuroscience: exploring the brain. Third edition. Lippincott Williams & Wilkins.
2. M.A. Howard III et al., Auditory Cortex on the Human Posterior Superior Temporal Gyrus. THE JOURNAL OF COMPARATIVE NEUROLOGY, 416 (2000) 79–92.
3. C. Pantev et al., Tonotopic organization of the human auditory cortex revealed by transient auditory evoked magnetic fields. Electroencephalography and clinical Neurophysiology, 69 (1988) 160–170.
4. C. Pantev et al., Tonotopic organization of the sources of human auditory steady-state responses. Hearing Research, 101 (1996) 62–74.
5. C.Y. Jin et al., Dynamic movement of N100m current sources in auditory evoked fields: Comparison of ipsilateral versus contralateral responses in human auditory cortex. Neuroscience Research, 60 (2008) 397–405.
6. E. Kaukoranta et al., Mixed and sensory nerve stimulations activate different cytoarchitectonic areas in the human primary somatosensory cortex SI. Exp Brain Res, 63 (1986) 60–66.
7. I. Ozaki et al., Dynamic anterolateral movement of N100m dipoles in evoked magnetic field reflects activation of isofrequency bands through horizontal fibers in human auditory cortex. Neuroscience Letters, 329 (2002) 222–226.
8. I. Ozaki et al., Dynamic movement of N100m dipoles in evoked magnetic field reflects sequential activation of isofrequency bands in human auditory cortex. Clinical Neurophysiology, 114 (2003) 1681–1688.
9. T. Tuomisto et al., Studies of Auditory Evoked Magnetic and Electric Responses: Modality Specificity and Modelling. Il Nuovo Cimento D, 2 (1983) 471–483.
10. Kuen-Lin Chen, Hong-Chang Yang, Sung-Ying Tsai, Yu-Wei Liu, Shu-Hsien Liao, Herng-Er Horng, Yong-Ho Lee, and Hyukchan Kwon. The stability of source localization in a whole-head Magnetoencephalography system demonstrated by auditory evoked field measurements; J. Appl. Phys. 110, 074702 (2011).
5
11. 劉瑜偉(2011)。用128通道腦磁圖儀系統研究人類大腦聽覺誘發磁場。未出版之碩士論文，國立台灣師範大學光電科技研究所，台北。
12. I. Ozaki et al., Rapid change of tonotopic maps in the human auditory cortex during pitch discrimination. Clinical Neurophysiology, 115 (2004) 1592–1604.
13. Deniz Bilecen, Klaus Scheffler, Nena Schmid, Kurt Tschopp, Jaochim Seelig. Tonotopic organization of the human auditory cortex as detected by BOLD-FMRI. Hearing Rearch 126 (1998) 19-27.
14. C. Mark Wessinger, Micheal H. Buonocore, Clif L. Kussmaul, and Geroge R. Mangun. Tonotopy in Human Auditory Cortex Examined With Functional Magnetic Resonance Imaging. Human Brain Mapping 5:18-25(1997).
15. Christoph Kayser, Christopher I. Petkov, Nikos K. Logothetis. Multisensory interactions in primate auditory cortex: fMRI and electrophysiology. Hearing Research 258 (2009) 80-88.
16. Thomas M. Talavage, Patrick J. Ledden, Randall R. Benson, Bruce R. Rosen, Jennifer R. Melcher. Frequency-dependent responses exhibited by multiple regions in human auditory cortex. Hearing Reseach 150 (2000) 225-244.
17. Alan H. Lockwood, Richard J. Salvi, Mary Lou Coad, Sally A. Arnold, David S. Wack, B.W. Murphy and Robert F. Burkard. The Function Anatomy of the Normal Human Auditory System: Responses to 0.5 and 4.0 kHz Tones at Varied Intensities. Cerebral Cortex Jan/Feb 1999;9:65-76.
18. M.A. Howard III et al., A chronic microelectrode investigation of the tonotopic organization of human auditory cortex. Brain Research, 724 (1996) 260-264.