JPH06325395A - Optical disk device - Google Patents

Abstract

PURPOSE:To perform tracking control precisely by compounding the output of a differential amplifier according to the deviation in a phase between two photodetecting means in a three beams method and correcting a tracking error signal. CONSTITUTION:The output E of a photodetector 11 detecting the reflection beam of +1st order diffracted light and the output F of the photodetector 12 detecting the reflection beam of -1st diffracted light in the three beam' method are inputted to the differential amplifier 13. Then, the output of the differential amplifier 13 is inputted to a multiplier 19. On the other hand, the output E of the photodetector 11 is inputted to a 180 deg. phase shift circuit 14 phase shifting the phase of an input signal by 180 deg., and the output of the circuit 14 and the output F of the photodetector 12 are inputted to a phase comparator circuit 15 outputting the phase difference between the input signals. Then, the output of the phase comparator circuit 15 is inputted to a function generation circuit consisting of an A/D converter 16, a PROM 17 and a D/A converter 18, and the output of the D/A converter 18 is inputted to the multiplier 19. That is, the tracking error signal inputted to the multiplier 19 is corrected by the output of the D/A converter 18.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical disk device. More specifically, the present invention relates to an optical disk device that performs tracking control by applying the 3-beam method.
The invention is particularly applicable to, but not limited to, CD-ROM players.

[0002]

2. Description of the Related Art In an optical disk such as a CD-ROM, a large number of minute holes called pits are formed on a spirally arranged track so that a large amount of data can be recorded. ing. And
An optical pickup that emits laser light is used to reproduce the data thus recorded.

The optical pickup emits a laser beam and detects the reflected light. When reproducing data from an optical disc, the laser beam emitted from the optical pickup must accurately trace a spiral track. is necessary. Then, for that purpose, it is necessary to detect whether the laser light is not displaced from the track and adjust the position of the optical pickup, that is, so-called tracking control.

One of the methods for detecting the track deviation is 3
There is a beam method. FIG. 5 is a diagram illustrating tracking control by the 3-beam method. When the laser light 54 passes through the diffraction grating 53 provided in front of the objective lens 52 as shown in FIG. 7B, 0th order and ± 1st order diffracted lights are generated. These diffracted lights are condensed by the objective lens 52 and form three spots, G ₀ , G ₊ and G ₋ , on the recording surface 51 of the optical disc.

The spot G _{+ of the +} 1st-order diffracted light and the spot G ₋ of the −1st-order diffracted light are shifted in the left and right opposite directions with respect to the track direction, but the shift widths are the same. The attachment mechanism of the optical pickup has been adjusted. Then, the reflected lights are received by different photodetectors.

If the 0th-order diffracted light spot G ₀ is irradiated to the center of the track, the irradiation positions of the + 1st-order diffracted light spot G ₊ and the −1st-order diffracted light spot G ₋ are: Since they are offset from the pit 50 by the same amount, their reflected light is at the same level. That is, + 1-order diffracted light spot G ₊ and -1 order diffracted light spot G _- and to keep the reflected light at a constant, is the principle of tracking control by the three-beam method.

FIG. 1A is a block diagram for explaining a conventional tracking error detection circuit in the 3-beam method. Photodetector for detecting reflected light RG ₊ of ₊ 1st order diffracted light
41 and -1st order diffracted light of the reflected light RG _- optical detectors for detecting the
The output of 42 is input to the differential amplifier 43, and the tracking error signal is generated.

In such a configuration, if the spot G ₀ of the 0th-order diffracted light is applied to the center of the track, the outputs of the photodetector 41 and the photodetector 42 are at the same level, and the differential amplifier The output of 43, that is, the tracking error signal becomes zero. On the other hand, if the 0th-order diffracted light spot G ₀ is not irradiated to the center of the track, the outputs of the photodetector 41 and the photodetector 42 are at different levels, and the differential amplifier 43
Output, that is, the tracking error signal has a value corresponding to such track deviation.

In the conventional optical disk device, tracking control is performed by using the tracking error signal thus obtained. That is, in the conventional optical disc device, if the optical pickup is moved in the direction in which the tracking error signal becomes smaller,
Spot G ₀ of the zero-order diffracted light is set to, going by tracing the track center.

The irradiation positions of the ₊ 1st-order diffracted light spot G ₊ and the -1st-order diffracted light spot G ₋ are as described above.
The light detector 41 and the light detector 42, which detect the reflected light, are offset from each other in the opposite left and right directions with respect to the track direction.
The output phase difference between them is 180 degrees.

By the way, the reflected light RG of the 0th order diffracted light
₀ is received by the photodetectors 44a, 44b, 44c, 44d divided into four, and those photodetection signals are used for focusing each spot, reading data, and the like.

The light reception level of the reflected light RG ₊ of the ₊ 1st order diffracted light in the photodetector will be referred to as “photodetection signal E” or simply “E” below. Similarly, the received light level of the reflected light RG ₋ of the −1st order diffracted light in the photodetector will be referred to as “photodetection signal F” or simply “F” below.
Is written.

[0013]

In order to perform accurate tracking control in the optical disk device, it is necessary that the tracking error signal be accurately output according to the track shift of the optical pickup. However, in the optical disc device using the conventional tracking error detection circuit, the tracking error signal changes not only due to the track shift of the optical pickup but also due to other factors, and accurate tracking control cannot be performed. The inconvenience of being lost occurs.

When such a variation becomes large,
Tracking control becomes impossible and data cannot be reproduced at all.

A technical object of the present invention is to focus on such a problem and to make tracking control more accurate in an optical disk device.

[0016]

FIG. 1 is a block diagram for explaining the basic principle of the present invention. The optical disc device according to claims 1 and 2 detects the light detecting means 1 for detecting the reflected light RG ₊ of the ₊ 1st order diffracted light in the 3-beam method and the reflected light RG ₋ of the −1st order diffracted light in the 3-beam method. And a subtraction means 3 for calculating an output difference between the light detection means 1 and 2 and outputting a tracking error signal TR _ERR .

In such an arrangement, the optical disk device according to the first aspect of the invention has a phase shift detecting means 4 for detecting a phase shift of the output between the light detecting means 1, 2 and a phase detected by the phase shift detecting means 4. The output of the subtraction means 3 is compressed and expanded according to the deviation, and the tracking error signal TR _ERR
Gain compensation means 5a for correcting

In the optical disk device according to a second aspect of the present invention, in the above structure, the phase shift detecting means 4 for detecting the phase shift of the output between the light detecting means 1, 2 and the phase shift detecting means 4 detect the phase shift. The light detection means 1 according to the phase shift
Of the tracking error signal TR
_The gain compensating means 5b for correcting the _ERR and the light detecting means 2 according to the phase shift detected by the phase shift detecting means 4.
Of the tracking error signal TR
_It has a gain compensation means 5c for correcting _ERR .

[0019]

The unstable tracking control is directly caused by the fact that the tracking error signal fluctuates due to a factor other than the track deviation as described above. It has been found that this is because the phase difference between the signals E and F deviates from the theoretical phase difference of 180 degrees. It was also found that the fluctuation amount of the tracking error signal corresponds to the amount by which the phase difference between the light detection signals E and F deviates from the theoretical phase difference of 180 degrees.

According to the optical disk device of the first aspect, when a phase shift occurs between the light detection signals E and F, the output of the subtraction means 3 is compressed and expanded in accordance with the phase shift.
Correct the conventional tracking error signal. That is, since the fluctuation of the conventional tracking error signal due to the phase shift between the light detection signals E and F is removed, an accurate tracking error signal TR _ERR according to the track shift can be obtained.

Therefore, in the optical disk device according to claim 1,
The tracking error signal TR _ERRBut the light detection signal
It is accurate because it does not change due to the phase shift between E and F.
So the tracking control is accurate.

According to the optical disk device of the second aspect, when a phase shift occurs between the photodetection signals E and F, the optical detection signals E and F are compressed and expanded according to the phase shift,
Correct the conventional tracking error signal. That is, since the fluctuation of the conventional tracking error signal due to the phase shift between the light detection signals E and F is removed, an accurate tracking error signal TR _ERR according to the track shift can be obtained.

Therefore, in the optical disk device according to claim 2,
The tracking error signal TR _ERRBut the light detection signal
It is accurate because it does not change due to the phase shift between E and F.
So the tracking control is accurate.

[0024]

EXAMPLES Next, examples of how the optical disk device according to the present invention is actually embodied will be described.
FIG. 2 is a block diagram showing the first embodiment of the present invention.
In this example, the output of the photodetector 11 which detects the reflected light RG ₊ of the ₊ 1st-order diffracted light in the 3-beam method and the photodetector which detects the reflected light RG ₋ of the −1st-order diffracted light in the 3-beam method The output of 12 is input to the differential amplifier 13. Then, the output of the differential amplifier 13 is input to the multiplier 19.

On the other hand, the output of the photodetector 11 is input to a 180-degree phase shift circuit 14 for shifting the phase of the input signal by 180 degrees,
The output and the output of the photodetector 12 are input to the phase comparison circuit 15 that outputs the phase difference between the input signals. The output of the phase comparison circuit 15 is the A / D converter 16, the PROM 17,
Input to the function generation circuit composed of D / A converter 18,
The output of the D / A converter 18 is input to the multiplier 19.

The 180-degree phase shift circuit 14 and the phase comparison circuit 15
Is to detect a phase shift between the light detection signals E and F. With such a configuration, the output of the differential amplifier 13, that is, the conventional tracking error signal can be corrected by the signal input to the multiplier 19, that is, the output of the D / A converter 18. is there.

That is, since the output of the D / A converter 18 is determined by the data stored in the PROM 17 according to the phase shift between the light detection signals E and F, write an appropriate numerical value in the PROM 17. It is possible to cancel the fluctuation by the above, and it is possible to correct the conventional tracking error signal and obtain an accurate tracking error signal.

FIG. 3 is a graph for explaining a gain compensation value suitable for the present invention, that is, a numerical value written in the PROM 17. The amount of attenuation of the output difference between the light detection signals E and F, that is,
The attenuation amount of the tracking error signal before correction has a characteristic that the attenuation amount increases as the phase shift increases, as shown in FIG.

The output of the tracking error signal before correction in the state where there is no phase shift is A _MAX , and a certain phase shift ψ _S
A _S output before correction of the tracking error signal in
Then, the gain compensation value may be A _MAX / A _S. That is, A _MAX / A _S may be written in the address corresponding to the phase shift ψ _S of the PROM 17.

As a matter of course, if such a gain compensation value can be obtained by a combination of analog elements,
The A / D converter 16, PROM 17, and D / A converter 18 in FIG. 2 may be replaced with a combination of such analog elements. Alternatively, a digital multiplier may be used as the multiplier 17, and the D / A converter 18 may be connected to the output of the multiplier 17. Alternatively, the phase shift of 180 may be applied to the output of the photodetector 12.

As described above, according to this embodiment, it is possible to correct the fluctuation of the tracking error signal due to the phase shift between the photodetection signals E and F, so that the corrected tracking error signal is accurate. Corresponds to the track deviation, so that the tracking control is well stable and accurate.

In the above-mentioned embodiment, the tracking error signal is compensated in the latter stage of the differential amplifier, but it is also possible to compensate in the former stage as will be described below. Figure 4
FIG. 8 is a block diagram illustrating a second embodiment of the present invention.

In this example, the photodetector 11 and the photodetector 12 are
The outputs of and are input to the differential amplifier 22 via the multiplier 20 and the multiplier 21. On the other hand, also in this example, the photodetector
The output of 11 shifts the phase of the input signal by 180 degrees.
It is input to the 0-degree phase shift circuit 14, and its output and the output of the photodetector 12 are input to the phase comparison circuit 15 which outputs the phase difference between the input signals.

The output of the phase comparison circuit 15 is the A / D
It is input to the function generating circuit composed of the converter 16, the PROM 17, and the D / A converter 18, and the output of the D / A converter 18 is input to the multipliers 20 and 21.

The 180-degree phase shift circuit 14 and the phase comparison circuit 15
Is to detect a phase shift between the light detection signals E and F. With such a configuration, the output of the differential amplifier 22, that is, the conventional tracking error signal can be corrected by the signal input to the multipliers 20 and 21, that is, the output of the D / A converter 18. It is possible.

That is, since the output of the D / A converter 18 is determined by the data stored in the PROM 17 according to the phase shift between the light detection signals E and F, write an appropriate numerical value in the PROM 17. It is possible to cancel the fluctuation by the above, and it is possible to correct the conventional tracking error signal and obtain an accurate tracking error signal. Also in this example, the numerical value written in the PROM 17 can be obtained in the same manner as in the above-mentioned embodiment.

As a matter of course, also in this example, if the gain compensation value can be obtained by combining the analog elements, the A / D converter 16, the PROM 17, and the DROM in FIG.
The / A converter 18 may be replaced with a combination of such analog elements. Also, a digital multiplier is used for the multipliers 20 and 21, and the D / A converter 18 is connected to the multipliers 20 and 21.
It may be configured to be connected to the output of. Also, 18
The configuration may be such that 0 phase shift is performed on the output of the photodetector 12.

As described above, according to this embodiment, it is possible to correct the fluctuation of the tracking error signal due to the phase shift between the photodetection signals E and F, so that the corrected tracking error signal is accurate. Corresponds to the track deviation, so that the tracking control is well stable and accurate.

[0039]

As described above, the optical disc apparatus according to the first aspect of the invention detects the output difference between the light detection signals E and F as
The tracking error signal does not fluctuate due to the phase shift between the photodetection signals E and F, unlike the conventional case, because the difference calculation is performed after the difference calculation according to the phase shift between F and F. .

Since the tracking error signal does not fluctuate due to the phase shift between the photodetection signals E and F, the tracking error signal accurately corresponds to the track shift, and the tracking control is well stabilized. Became accurate.

As described above, the optical disc device according to a second aspect of the invention detects the output difference between the photodetection signals E and F as the photodetection signals E and F.
Since the configuration is such that the difference is corrected before the difference calculation, the tracking error signal does not fluctuate due to the phase shift between the photodetection signals E and F, unlike the conventional case.

Since the tracking error signal no longer fluctuates due to the phase shift between the photodetection signals E and F, the tracking error signal accurately corresponds to the track shift, and the tracking control is well stabilized. Became accurate.

[Brief description of drawings]

FIG. 1 is a block diagram showing the basic principle of the present invention.

FIG. 2 is a block diagram illustrating a first embodiment of the present invention.

FIG. 3 is a graph illustrating a gain compensation value suitable for the present invention.

FIG. 4 is a block diagram illustrating a second embodiment of the present invention.

FIG. 5 is a block diagram and a sketch illustrating a conventional tracking error detection circuit.

[Explanation of symbols]

1 Light Detection Means 2 Light Detection Means 3 Subtraction Means 4 Phase Shift Detection Means 5a Gain Compensation Means 5b Gain Compensation Means 5c Gain Compensation Means RG ₊ Reflected Light of ₊ 1st Order Diffracted Light RG ₋ Reflected Light of −1st Order Diffracted Light 11 Photodetector 12 Photodetector 13 Differential amplifier 14 180 degree phase shift circuit 15 Phase shift comparison circuit 16 A / D converter 17 PROM 18 D / A converter 19 Multiplier 20 Multiplier 21 Multiplier 22 Differential amplifier

Claims (2)

[Claims] 1. The antireflection of the + 1st order diffracted light in the three-beam method.
Emission (RG₊) Detecting means (1) and the reflected light of the -1st order diffracted light (RG_-)
The output difference between the light detecting means (2) for detecting and the light detecting means (1), (2) is calculated and
King error signal (TR _ERR) And subtraction means (3)
In an optical disc device having a
According to the phase shift detection means (4) and the phase shift detected by the phase shift detection means (4).
The output of the subtracting means (3) is compressed and expanded, and the tracker
Error signal (TR_ERR) Compensation means (5a)
An optical disk device comprising: 2. The antireflection of the + 1st order diffracted light in the three-beam method.
Emission (RG₊) Detecting means (1) and the reflected light of the -1st order diffracted light (RG_-)
The output difference between the light detecting means (2) for detecting and the light detecting means (1), (2) is calculated and
King error signal (TR _ERR) And subtraction means (3)
In an optical disc device having a
According to the phase shift detection means (4) and the phase shift detected by the phase shift detection means (4).
The output of the light detection means (1) is compressed and expanded to
Error signal (TR_ERRGain compensation means (5
b) and the phase shift detected by the phase shift detection means (4)
The output of the light detection means (2) is compressed and expanded to
Error signal (TR_ERRGain compensation means (5
c) An optical disk device comprising: