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Evaluation of correlation functions and design of minimum mean squared error equaliser for a high-density magnetic recording channel with partial erasure effect

Evaluation of correlation functions and design of minimum mean squared error equaliser for a high-density magnetic recording channel with partial erasure effect

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  • Author(s): T.-S. Kao 1  and  H.-H. Ku 2
    • View affiliations
    • Affiliations: 1: Department of Electronic Engineering, Hwa-Hsia Institute of Technology, Taipei, Taiwan
      2: Department of Computer Science and Information Engineering, Hwa-Hsia Institute of Technology, Taipei, Taiwan
  • Source: Volume 6, Issue 6, August 2012, p. 600 – 607
    DOI:  10.1049/iet-spr.2010.0373 , Print ISSN 1751-9675, Online ISSN 1751-9683
© The Institution of Engineering and Technology
Published

In a high-density magnetic recording channel, non-linear effects such as transition shift and partial erasure arise, and these effects limit detector performance. The transition shift can be precompensated by using an appropriate write current; however, partial erasure still degrades detector performance. In this study, the authors obtained the correlation functions of the stored data in the presence of partial erasure under the assumption that the transition shift has been precompensated. The correlation functions are applied in designing a minimum mean squared error equaliser for both the linear partial response and the non-linear partial response, and the corresponding partial response maximum likelihood (PRML) sequence detector, realised by the Viterbi decoder, is also examined. Computer simulations indicate that the mean squared error of the proposed equaliser can be improved and the bit error rate of the PRML sequence detector is also reduced as compared with the conventional one in the presence of partial erasure.

Inspec keywords: maximum likelihood sequence estimation; equalisers; Viterbi decoding; mean square error methods; magnetic recording; maximum likelihood detection

Other keywords: limit detector performance; write current; transition shift; high-density magnetic recording channel; partial erasure effect; partial response maximum likelihood sequence detector; bit error rate; PRML sequence detector; Viterbi decoder; nonlinear partial response; nonlinear effects; correlation functions; minimum mean squared error equaliser

Subjects: Magnetic recording; Codes; Signal detection; Interpolation and function approximation (numerical analysis); Other topics in statistics; Communication channel equalisation and identification

References

    1. 1)
      • H. Meyr , M. Moeneclaey , S.A. Fechtel . (1997) Digital communication receivers: synchronization, channel estimation and signal processing. Wiley series in telecommunications and signal processing.
    2. 2)
      • Kao, T.S., Wang, Y.C., Chang, Y.C., Juan, C.J.: `On the S-curve of a magnetic recording channel in the presence of partial erasure and transition shift', Int. Conf. Signal Processing Systems, May 2009, p. 47–51.
    3. 3)
    4. 4)
    5. 5)
    6. 6)
      • R.W. Wood , D.A. Petersen . Viterbi detection of class IV partial response on a magnetic recording channel. IEEE Trans. Magn. , 454 - 461
    7. 7)
    8. 8)
    9. 9)
    10. 10)
    11. 11)
      • S.X. Wang , A.M. Taratorin . (1999) Introduction to magnetic information storage technology.
    12. 12)
    13. 13)
    14. 14)
    15. 15)
      • J.W.M. Bergmans . (1996) Digital baseband transmission and recording.
    16. 16)
    17. 17)
    18. 18)
      • Raphaeli, D., Zarai, Y.: `Combined turbo equalization and turbo decoding', Proc. IEEE Global Telecommunications Conf., November 1997, 2, p. 639–643.
    19. 19)
      • T.S. Kao , Y.C. Chang , S.Y. Hou , C.J. Juan . Effects of timing information for a magnetic recording channel in the presence of non-linearities. Int. Colloq. Signal Process. Appl. , 273 - 275
    20. 20)
    21. 21)
    22. 22)
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