Acquistion timing loop for read channel

Dynamic magnetic information storage or retrieval – General recording or reproducing – Specifics of equalizing

Reexamination Certificate

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C360S046000

Reexamination Certificate

active

06594098

ABSTRACT:

BACKGROUND OF THE INVENTION
1. Field of the Invention
This invention relates to magnetic storage systems and, more particularly, to data channels for processing signals read from a magnetic medium.
2. Description of the Related Art
During a write operation in a magnetic disk storage system, write current applied to a read-write head is modulated according to digital data to record a sequence of magnetic flux transitions in concentric tracks on a magnetic medium. In a subsequent read mode, the read-write head moving over the magnetic medium converts the magnetic transitions into an analog signal of alternating polarity. The analog signal is then detected and decoded in a read channel to reproduce the recorded digital data. While a simple peak detector may be used to detect the analog signal from the read-write head, discrete time sequence detectors that compensate for intersymbol interferences (ISI) are now employed to reduce susceptibility to noise and to increase storage capacity and reliability.
FIG. 1
illustrates a known detection and decoding arrangement using a discrete time sequence detector. In
FIG. 1
, there is a variable gain amplifier (VGA)
101
, an analog to digital converter (ADC)
105
, a finite impulse response (FIR) equalizer
110
, a timing and gain control
115
, a discrete time sequence detector
125
(e.g., a Viterbi detector), a decoder
128
and a host computer
130
. During a read operation, a signal output of the read-write head is amplified in VGA
101
and the output of VGA
101
is converted into a sequence of timed samples in ADC
105
. The sample sequence is equalized in FIR equalizer
110
and equalized sample sequence is supplied to the discrete time sequence detector
125
which provides time sequence detection. The detected sequence is then converted into digital data in the decoder
128
and the decoded digital data is supplied to the host computer
130
.
As is well known, the FIR filter equalizer
110
in
FIG. 1
employs a set of parameter signals to compensate for variations in magnetic and electrical characteristics over the magnetic disk, disk angle and environmental conditions. The output of the FIR equalizer
110
is also applied to the timing and gain control
115
which operates to provide signals for adjusting the timing of samples in the ADC
105
and the gain of the VGA
101
. During the equalization of user data, the timing and gain control
115
receives the sample sequence output of the FIR equalizer
110
and provides signals to maintain proper amplitude in VGA
101
and proper timing for sampling of signals in the ADC
105
. Prior to the user data reading, a preamble pattern is read to synchronize the sampling of the analog waveform in ADC
105
and to initially adjust the gain of the variable gain amplifier
101
using the FIR equalizer output.
FIG. 2
shows an exemplary FIR equalizer having an n tap delay that may be used in the circuit of FIG.
1
. As shown in
FIG. 2
, the FIR equalizer includes delays
201
-
0
through
201
-n+1, multipliers
205
-
0
through
205
-n+1 and an adder
207
. The output sample sequence from the ADC
105
in
FIG. 1
is supplied to the input of the delay
201
-
0
and is sent through the serially arranged delays
201
-
0
through
201
-n+1. The output of each delay is also applied to an associated one of multipliers
205
-
0
through
205
-n+1 which multipliers also have equalizer coefficient inputs C
0
through Cn+1, respectively, applied thereto. The values of the coefficients C
0
through Cn+1 are previously determined from least mean square estimation obtained by having the FIR equalizer provide predetermined targets for a range of waveforms read from the magnetic disk. Arrangements for generating the FIR equalizer coefficients for least mean square (LMS) adaptive FIR filters are disclosed in “Digital Baseband Transmission and Recording”, Jan W. M. Bergmans, Kluwer Academic Publishers (ISBN 0-7923-9775-4).
In order to perform accurate equalization of a large range of input waveforms, an FIR equalizer having a large number of taps (e.g., 10-20) is required and the delay through or latency in the FIR equalizer may be 10 to 20 cycles or more. The tracking of the timing and gain by the timing and gain control
115
during reading of user data is not usually affected by the latency since the bandwidth for timing and gain changes during the data reading is ordinarily relatively low. In the initial acquisition period during which a synchronization pattern is read, however, large changes in timing and gain can be expected. These large changes require a high bandwidth timing and gain control loop. In the initial synchronization period of the read channel, the large latency in the FIR equalizer
110
having 10 to 20 delay taps operates to slow down the timing and gain adjustments and may cause instability.
U.S. Pat. No. 5,585,975 issued to William G. Bliss Dec. 17, 1996 discloses an equalization scheme for sample value estimation and sequence detection in a sampled amplitude read channel in which a pair of serially connected programmable discrete time filters equalizes signal samples into desired equalization. The first equalizer estimates sample values and a second equalizer provides for sequence detection of digital data. The timing and gain control loop for the equalization scheme includes the first equalizer that operates during both the preamble and-user data segments of a sector signal so that long latency in the first equalizer adapted to equalize user data waveforms affects the timing and gain loop bandwidths during the preamble segment.
U.S. Pat. No. 5,903,857 issued to Richard T. Behrens et al. May 11, 1999 discloses an arrangement for calibrating an analog filter in a sampled amplitude read channel wherein an analog filter precedes an analog to digital converter in a series circuit having a discrete equalizer FIR filter. A timing recovery loop includes the FIR filter used for both preamble and user data so that the FIR filter latency affects the timing loop operation. Accordingly, there is a problem in providing rapid and stable synchronization in read channels having multi-tap FIR filter equalizers adapted to equalize a wide range of waveforms.
SUMMARY OF THE INVENTION
The invention is directed to a data channel for processing a signal from a storage medium in which a timed sample sequence is formed in response to the storage medium signal. A filtering unit equalizes the timed sample sequence in response to a set of parameter signals and a control unit controls the forming of the timed sample sequence in response to the equalized time sample sequence from the filtering unit.
According to the invention, a first filtering unit equalizes the timed sample sequence during a first signal segment in response to a first number of parameter signals and a first control unit controls forming of the timed sample sequence in the first signal segment. A second filtering unit equalizes the timed sample sequence during a second signal segment in response to a second number of parameter signals and a second control unit controls forming of the timed sample sequence in the second signal segment.
According to one aspect of the invention, the number of first parameter signals is smaller than the number of second parameter signals.
According to another aspect of the invention, each first parameter signal is a linear combination of at least some of the second parameter signals.
According to yet another aspect of the invention, the first filtering unit and the second filtering unit both provide substantially the same equalized timed sample sequence for the signal of the first signal segment.
According to yet another aspect of the invention, the number of first parameter signals is at least two.
According to yet another aspect of the invention, the second parameter signals includes a set of second FIR equalizer coefficient signals c
0
, c
1
, c
2
, . . . cn, cn+1 and the first parameter signals includes a set of first FIR equalizer coefficient signals K
0
=f(c
0
, c

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