Medical Engineering & Physics
Volume 28, Issue 9 , Pages 925-931 , November 2006

Fuzzy support vector machines for adaptive Morse code recognition

  • Cheng-Hong Yang

      Affiliations

    • Department of Electronic Engineering, National Kaohsiung University of Applied Sciences, Kaohsiung 807, Taiwan
    • Corresponding Author InformationCorresponding author.
    • ,
  • Li-Cheng Jin

      Affiliations

    • Department of Electronic Engineering, National Kaohsiung University of Applied Sciences, Kaohsiung 807, Taiwan
    • ,
  • Li-Yeh Chuang

      Affiliations

    • Department of Chemical Eng., I-Shou University, Kaohsiung 807, Taiwan

Received 4 August 2004 ,Revised 29 July 2005 ,Accepted 2 December 2005.

References 

  1. In:  Bower R, et al. editor. The trace resourcebook-assistive technology for communication, control, and computer access. Trace Research & Development Center/Universities of Wisconsin-Madison, Waisman Center; 1998;
  2. Levine SP, Gauger JRD, Bwera LD, Khan KJ. A comparison of mouth stick and Morse code text inputs. AAC Augmentative Alternative Commun. 1996;2(51):45–51
  3. Goble LN, Colle HA. High-speed Morse code training. In: Proceedings of the IEEE 1985 national aerospace and electronics conference. NAECON. 1985;p. 944–951
  4. Trace R, Center D. Two switch auto-repeat Morse code. Waisman Center, University of Wisconsin-Madison; 1984;
  5. Shannon DA, Satewen WS, Miller J, Cohen BS. Morse-code controlled computer aid for the non-vocal quadriplegic. Med Instrum. 1981;15:341–343
  6. Yang Cheng-Hong, Chuang L-Y, Luo C-H. Morse code application for wireless environmental control system for severely disabled individuals. IEEE Trans Neural Syst Rehabil Eng. 2003;11(December (4)):463–469
  7. Yang C-H. An interactive Morse code emulation management system. Comput Math Appl. 2003;46:479–492
  8. Yang C-H, Chuang L-Y, Luo C-H. Internet access for disabled persons using Morse code. Int J Comput Appl. 2004;26(1):10–16
  9. Lin C-F, Wang S-D. Fuzzy support vector machines. IEEE Trans Neural Networks. 2002;13(2):
  10. Huang H-P, Liu Y-H. Fuzzy support vector machine for pattern recognition and data mining. Int J Fuzzy Syst. 2002;4(3):826–835
  11. Khasawneh MA, Mayyas KA. A newly derived variable degree variable step size LMS algorithm. Int J Electron. 1995;79(3):255–264
  12. Vapnik VN. The nature of statistical learning theory. Springer Verlag; 1995;
  13. Ben-Hur A, Horn D, Siegelmann HT, Vapnik VN. A support vector clustering method. In: International conference on pattern recognition. 2000;
  14. Cortes C, Vapnik VN. Support vector network. Mach Learn. 1995;20:1–25
  15. Campbell C, Cristianini N, Shawe-Taylor J. Dynamically adapting kernels in support vector machines. Advances in neural information processing systems. vol. 11. MIT Press; 1999;pp. 204–210
  16. Campbell C, Cristianini N, Frieß Th. The Kernel-Adatron: a fast and simple learning procedure for support vector machines. In: Proceedings of the 15th international conference on machine learning. 1998;p. 188–196
  17. Luo C-H, Shih C-H. Adaptive Morse-coded single-switch communication system for the disabled. Int J Biomed Comput. 1996;41:99–106
  18. Shih C-H, Luo C-H. A Morse-coded recognition system with LMS and matching algorithms for persons with disabilities. Int J Med Inform. 1997;44:193–202
  19. Yang C-H. Morse code recognition using learning vector quantization for persons with physical disabilities. IEICE Trans Fundam Electron, Commun Comput Sci. 2001;E84-A(1):356–362
  20. Yang C-H. Adaptive Morse code recognition using variable degree variable step size LMS for persons with disabilities. Bio-Med Mater Eng. 1998;8:343–352
  21. Conver WJ. Practical nonparametric statistics. second ed.. New York: Wiley & Sons Inc.; 1986;
  22. King TW. Assistive technology: essential human factors. Boston: Allyn and Bacon; 2000;

PII: S1350-4533(05)00266-3

doi: 10.1016/j.medengphy.2005.12.007

Medical Engineering & Physics
Volume 28, Issue 9 , Pages 925-931 , November 2006

Article Tools

* Image Usage & Resolution