A Read-While-Write (RWW) operation for tape and/or potentially disk applications is
needed in the following three cases: 1. High reliability; 2. Data servo systems; 3. Buried
servo systems. All these applications mean that the read (servo) head and write head are
operative simultaneously. Consequently, RWW operation will require work to suppress
the so-called crossfeed field radiation from the write head.
Traditionally, write-read crossfeed has been reduced in conventional magnetic recording
heads by a variety of screening methods, but the effectness of these methods is very limited.
On the other hand, the early theoretical investigations of the crossfeed problem concentrating
on the flux line pattern in front of a head structure based on a simplified model,
may not be comprehensive. Today a growing number of magnetic recording equipment
manufacturers employ thin-film technology to fabricate heads and thereby the size of the
modern head is much smaller than in the past. The increasing use of thin-film metallic
magnetic materials for heads, along with the appearance of other new technologies,
such as the MR reproductive mode and keepered media, has stimulated the need for an
increased understanding of the crossfeed problem by advanced analysis methods and a
satisfactory practical solution to achieve the RWW operation.
The work described in this thesis to suppress the crossfeed field involves both a novel reproductive
mode of a Dual Magnetoresistive (DMR) head, which was originally designed
to gain a large reproduce sensitivity at high linear recording densities exceeding 100 kFCI,
playing the key role in suppressing the crossfeed (the corresponding signal-noise ratio is
over 38 dB), and several other compensation schemes, giving further suppression. Advanced
analytical and numerical methods of estimating crossfeed in single and multi track
thin-film/MR heads under both DC and AC excitations can often help a head designer understand
how the crossfeed field spreads and therefore how to suppress the crossfeed field
from the standpoint of an overall head configuration. This work also assesses the scale of
the crossfeed problem by making measurements on current and improved heads, thereby
adapting the main contributors to crossfeed. The relevance of this work to the computer
industry is clear for achieving simultaneous operation of the read head and write head, especially
in a thin-film head assembly. This is because computer data rates must increase to
meet the demands of storing more and more information in less time as computer graphics
packages become more sophisticated.
Date of Award | 1999 |
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Original language | English |
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Awarding Institution | |
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Advanced Magnetic Thin-Film Heads Under Read-While-Write Operation
Wang, F. Z. (Author). 1999
Student thesis: PhD