JP2600911B2 - Optical disk signal reproduction device - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to an information input / output device for recording and reproducing information using an optical signal.

(Prior Art) At present, in order to record and reproduce information by using light, an optical head of an apparatus for irradiating a plurality of light beams to different tracks of a recording medium for the purpose of increasing a transfer speed of a reproduction signal. Development is ongoing (for example, Yoshiwara, Katayama et al .; Parallel recording / reproduction of magneto-optical disks using a multi-beam optical head, see '88 Autumn Application 4p-ZD-2). FIG. 3 schematically shows the configuration of a conventional multi-beam head using an array laser as a light source. A plurality of light beams emitted from the semiconductor laser array 1, which can be driven independently, are applied to different tracks 14 on the recording medium surface as shown in FIG. At the time of recording, by modulating each light beam intensity independently,
Recording is performed independently for each track. At the time of reproduction, each reflected light from the recording medium surface 5 via the condenser lens 4 is split into beams by the beam splitter 3 and made incident on different photodetectors on the photodetector array 11. The output signal from each detector is input to the signal reproducing circuit 13. In an error detection system for tracking and focusing a plurality of light beams, each of the reflected light beams from the recording medium surface is separated by a beam splitter 6, and a light detector array for error signal detection is passed through a condenser lens 7. 8. Irradiate on top. The signal obtained by the photodetector array is used as an error signal processing circuit 9
Is input to This configuration enables independent reproduction of the information signal of each track, and independent detection of an error signal in tracking and focusing of each track.

(Problems to be Solved by the Invention) In the above-described configuration, in the information reproduction system, when a wraparound from an adjacent light beam occurs, the reproduction signal characteristics deteriorate. Furthermore, when performing high-density recording,
Not only sneaking from an adjacent light beam but also interference from an adjacent pit occurs, so that the reproduction signal characteristic is greatly deteriorated.

An object of the present invention is to eliminate such crosstalk between light beams and intersymbol interference from adjacent pits at the same time to improve the reproduction signal characteristics.

(Means for Solving the Problems) In the present invention, a light having a plurality of photodetectors for irradiating a plurality of light beams on different tracks on a recording medium and reproducing signals independently from light reflected from each track is provided. In an optical disk signal reproducing method using a head, reproduction signals from the plurality of photodetectors are input to a group of frequency characteristic converters each of which can independently vary a frequency characteristic, and a certain set of the frequency converters is defined. The frequency converter output thus synthesized and an output signal from a frequency converter group different from the predetermined frequency converter are synthesized.

(Operation) In the present invention, the outputs of a plurality of photodetectors including crosstalk and intersymbol interference are independently input to frequency converters having variable frequency characteristics, and a signal of an optical beam modulated by information to be reproduced is obtained. The output of the frequency converter connected to the photodetector to be detected is combined with the output signal of the frequency converter connected to another photodetector.

First, a frequency converter connected to a photodetector for detecting a signal (a desired signal) of a light beam modulated by information to be reproduced is mainly used for removing intersymbol interference from adjacent pits.

Crosstalk between light beams is caused by the fact that a light beam for reproducing a desired signal has a spread, so that a part of the beam reaches data written on a peripheral track. . This distortion can be completely described if the characteristics of the data and the light beam written on the track causing the crosstalk are known, and can be easily removed. In the present invention, a plurality of light beams are applied to different tracks, and signals from tracks around the track on which information to be reproduced is written are also reproduced. By using these reproduced signals (reproduced signals of peripheral tracks), a replica of crosstalk generated in a desired signal can be formed.

Actually, the replica of the crosstalk formed on the basis of the reproduction signal of the peripheral track is also distorted because it includes crosstalk and intersymbol interference. However, the distortion occurring in this replica is 2 to the desired signal.
Since it occurs as a distortion of the next order, it can be almost ignored. A frequency converter to which a reproduction signal of a peripheral track is input is used to construct a replica of crosstalk generated from an input signal to a desired signal.

When using three light beams as shown in FIG. 2, the frequency characteristics of these frequency characteristic converters can be obtained, for example, as follows. First, at the time of writing data, a predetermined preamble signal is also recorded on the medium in addition to the write data. When reproducing data, first, the preamble signal is reproduced, and the reproduction output r (k of the preamble signal including crosstalk and intersymbol interference, which is obtained by, for example, adding the outputs of the respective frequency characteristic converters, is obtained. ) And R (k) for a reference signal sequence equal to a predetermined preamble signal sequence, and updates the tap coefficient of each frequency characteristic converter according to the following equation. ₀ (k + 1) = ₀ (k) + β (R (k) −r (k))
₀ (k) (1) ₁ (k + 1) = ₁ (k) + β (R (k) -r (k))
₁ (k) (2) ₂ (k + 1) = ₂ (k) + β (R (k) -r (k))
₂ (k) (3) In the above equation, ₀ (k) is a tap coefficient vector at time k of the frequency characteristic converter that receives a signal obtained from the central light beam, and ₁ (k) and ₂ (k) are A tap coefficient vector at time k of each frequency characteristic converter to which a signal obtained from a surrounding light beam is input,
₀ (k), ₁ (k) and ₂ (k) are input signal vectors of each frequency characteristic converter, and β is a step size. According to this algorithm, when a preamble signal having a sufficient length is used, the tap coefficient of each frequency characteristic converter becomes R
It is set so that the square error between (k) and r (k) is minimized. At this time, if the correlation between the signal sequence (preamble sequence) of the track on which the desired signal is written and the signal sequence written on the peripheral tracks is small, each signal obtained from the peripheral light beam is used as an input. The characteristics of the frequency characteristic converter are set so as to independently suppress crosstalk from each track to a desired signal. For this reason, in this case, the reproduction output r (k) of the preamble signal is given by the sum of the outputs of the respective frequency converters. Is set so as to output a replica of the inverse characteristic of the crosstalk component from each track. The characteristics of the frequency characteristic converter that receives a signal from the central light beam as input are set so as to remove intersymbol interference from adjacent pits.

As described above, the characteristics of each frequency characteristic converter are set by using the preamble signal of the track on which the desired signal is written, and the signal is reproduced by using these frequency characteristic converters. Data other than signals can be reproduced without crosstalk and intersymbol interference.

(Embodiment) FIG. 1 shows an embodiment in which the principle of the present invention is applied to a case where a semiconductor laser array having three light sources is used. Second
The figure shows the positional relationship between the focused spot on the recording medium surface and the track. The center beam is for signal reproduction, and the beams at both ends are for detecting a crosstalk signal to the center beam. In FIG. 1, 100 is a photodetector for signal reproduction, 10
1,102 are photodetectors for detecting a crosstalk signal, 110 to 112
Is a frequency characteristic variable filter, 120 is an adder, 121
Is a reference signal generation circuit, 122 is an error signal detection circuit, 123 is a frequency characteristic variable filter control circuit, 124 is a timing control circuit, 125 is a decision unit, 126 is a switch, and 130 and 13
1, 132 is an input terminal, and 133 is an output terminal.

Next, the operation of this embodiment will be described. Input terminal
The optical signals input from 130 to 132 are respectively
0 to 102 is input. The output of the photodetector 101 for signal reproduction is
Input to the timing control circuit 124, the timing control circuit 124 detects the head of the preamble signal written in advance, and outputs a control signal to the reference signal generation circuit 121 and the switch 126. When the control signal is input, the reference signal generation circuit 121 outputs a sequence equal to the preamble signal to the switch 126. At this time, the switch 126 is set to output the input signal from the reference signal generation circuit 121 to the error signal detection circuit 122. When detecting the end of the preamble signal, the timing control circuit 124 detects the end of the preamble signal.
Then, the control signal is output to the switch 126, the reference signal generation circuit 121 terminates the output of the reference signal, and the switch 126 is set to output the output of the determiner 125 to the error signal detection circuit 122.

At time k, the photodetectors 100 to 102 output signals including crosstalk and intersymbol interference from adjacent pits.
To 112. Frequency characteristic variable filters 110 to 112
Performs filtering of each input signal, and outputs the result to the adder 120. At the same time, frequency characteristic variable filter 1
10 to ₁₁₂ are the respective tap number vectors ₁₁₀ (k) to ₁₁₂ (k) at time k and the input signal vector ₁₁₀
(K) to ₁₁₂ (k) are output to the frequency characteristic variable filter control circuit 123. The adder 120 adds the signals filtered by the frequency characteristic variable filters 110 to 112, and outputs an output signal r (k) at a time k to the determiner 125 and the error signal detection circuit 122. The determiner 125 makes a determination based on the input signal, and outputs a determination result to the output terminal 133 and the switch 126. The error signal detection circuit 122
Detects an error signal e (k) = R (k) -r (k) using an output signal of the adder 120 and an output signal of the switch 126 as inputs, and converts e (k) into a frequency characteristic variable filter control circuit.
Output to 123. Here, r (k) and R (k) are output signals of the adder 120 and the switch 126 at the time k, respectively. At time k, the frequency characteristic variable filter control circuit 123 outputs the tap coefficient vectors ₁₁₀ (k) to ₁₁₂ (k) input from the frequency characteristic variable filters ₁₁₀ to _112.
And input signal vectors ₁₁₀ (k) to ₁₁₂ (k) and error signal e (k), and tap coefficient vector ₁₁₀ (k) of frequency characteristic variable filters ₁₁₀ to ₁₁₂ at time k + 1.
+1) to ₁₁₂ (k + 1), ₁₁₀ (k + 1) = ₁₁₀ (k) + βe (k)
₁₁₀ (k) (4) ₁₁₁ (k + 1) = ₁₁₁ (k) + βe (k)
₁₁₁ (k) (5) ₁₁₂ (k + 1) = ₁₁₂ (k) + βe (k)
_By obtaining ₁₁₂ (k) (6) and outputting ₁₁₀ (k + 1) to ₁₁₂ (k + 1) to the frequency characteristic variable filters ₁₁₀ to ₁₁₂ , the frequency characteristics of the frequency characteristic variable filters ₁₁₀ to ₁₁₂ are controlled.
Here, β is a predetermined step size. Frequency characteristic variable filter 11 shown in equations (4) to (6)
By controlling the frequency characteristics from 0 to 112, the frequency characteristic variable filters 111 and 112 output replicas of crosstalk from each track with inverse characteristics, and the crosstalk can be removed by the adder 120. it can. Also, the outputs of the frequency characteristic variable filters 111 and 112 are set in opposite
When inputting to 0, by the control of the equations (4) to (6),
The frequency characteristic variable filters 111 and 112 output the replica of the crosstalk from each track as it is.

(Effects of the Invention) According to the present invention, in an information reproducing system of an optical head device in which a plurality of light beams are applied to different tracks on a recording medium surface, wraparound between adjacent light beams and inter-code interference from adjacent pits are suppressed. , And a good reproduction signal can be obtained.

[Brief description of the drawings]

FIG. 1 is a system diagram showing an embodiment to which the present invention is applied when a semiconductor laser array having three light sources is used, and FIG. 2 is a recording medium using a semiconductor laser array having three light sources. FIG. 3 is a diagram showing a positional relationship between a condensed spot on a surface and a track, FIG. 3 is a diagram showing a configuration example of a conventional multi-beam optical head, and FIG. 4 is a diagram showing the multi-beam optical head shown in FIG. FIG. 3 is a diagram showing a positional relationship between a light-converged spot on a recording medium surface and a track when used. In the figure, 1 ... semiconductor laser array, 2 ... collimating lens, 3 ...
Beam splitter, 4 ... condenser lens, 5 ... recording medium, 6
... Beam splitter, 7: Condensing lens, 8: Error detector photodetector array, 9: Error signal processing circuit, 10: Condenser lens, 11: Reproduction signal detecting photodetector array, 12, 12 '
... frequency characteristic converter, 13 ... signal processing circuit, 14 ... track, 15 ... condensing spot, 16 ... recording pit, 100 ... photodetector for signal reproduction, 101, 102 ... photodetector for crosstalk signal detection, 110-112 ... Frequency characteristic variable filter, 120 ... Adder, 121 ... Reference signal generation circuit, 122 ... Error signal detection circuit, 123 ... Frequency characteristic variable filter control circuit, 124 ...
Timing control circuit, 125 ... Judge, 126 ... Switch, 13
0 to 132 ... input terminals, 133 ... output terminals.

Claims (1)

(57) [Claims] An optical disk signal reproducing apparatus using an optical head having a plurality of photodetectors for irradiating a plurality of light beams on different tracks on a recording medium and reproducing signals independently from reflected light from each track. A frequency converter group that receives reproduced signals from the plurality of photodetectors, each of which is capable of independently changing a frequency characteristic of an input signal; and the frequency characteristic converter group. Synthesizing means for synthesizing an output of a predetermined frequency converter having a predetermined frequency converter and an output signal from a frequency converter group different from the predetermined frequency converter, and determining means for judging an output signal from the synthesizing means. Detecting means for detecting a preamble signal from an output of the determined frequency converter; and means for outputting a reference signal based on an output of the detecting means. An output of the reference signal output means, an output of the determination means, and an output of the detection means are input, and a reference signal is output when the output of the detection means indicates that the detection means is detecting a preamble signal. And a switch for outputting the output of the judging means when the output of the detecting means does not indicate that the detecting means is detecting the preamble signal, and an error between the output of the switch and the output of the synthesizing means. An optical disc signal reproducing apparatus, comprising: an error signal output unit that detects a signal; and a unit that controls characteristics of the plurality of frequency characteristic converter groups based on an output of the error signal output unit.