Title :
Read/Write Channel Modeling and Two-Dimensional Neural Network Equalization for Two-Dimensional Magnetic Recording
Author :
Yamashita, Masaru ; Osawa, Hideya ; Okamoto, Yuji ; Nakamura, Yoshihiko ; Suzuki, Yuya ; Miura, Kiyotaka ; Muraoka, Hiroaki
Author_Institution :
Grad. Sch. of Sci. & Eng., Ehime Univ., Matsuyama, Japan
Abstract :
An accurate medium modeling method of discretized granular medium with non-magnetic grain boundaries using a discrete Voronoi diagram is proposed for two-dimensional magnetic recording. A simple closed-form representation of a double-shielded reader sensitivity function is also proposed for modeling the reading process. Moreover, a two-dimensional neural network equalizer (2D-NNE) is proposed to mitigate the influence of intertrack interference and jitter-like medium noise. The bit-error rate performance of partial response class-I maximum likelihood (PR1ML) system with the 2D-NNE is obtained by computer simulation based on the proposed read/write channel model. The performance is far superior to that of PR1ML system with a two-dimensional finite impulse response equalizer.
Keywords :
electronic engineering computing; error statistics; grain boundaries; magnetic recording; neural nets; bit-error rate; closed-form representation; discrete Voronoi diagram; discretized granular medium; double-shielded reader sensitivity function; intertrack interference; jitter-like medium noise; nonmagnetic grain boundaries; partial response class-I maximum likelihood system; read-write channel modeling; two-dimensional magnetic recording; two-dimensional neural network equalization; two-dimensional neural network equalizer; Bit error rate; Educational institutions; Equalizers; Grain boundaries; Magnetic recording; Neurons; Sensitivity; 2D-NNE; Channel modeling; TDMR; double-shielded reader sensitivity function; genetic algorithms;
Journal_Title :
Magnetics, IEEE Transactions on
DOI :
10.1109/TMAG.2011.2157808
