JP2589072B2 - Disk playback device - Google Patents

Description

The present invention relates to a device for optically reading information recorded on a disc, for example, a compact disc player (hereinafter referred to as a CD player).

(B) Conventional technology Conventionally, as a method for reading information from a CD player, a beam emitted from a semiconductor laser is divided using a diffraction grating, and the 0th-order diffracted light is used for information reproduction and focusing control, and the 1st-order diffracted light is tracked. So-called 3 used for control
A beam type disc reproducing apparatus is well known. In such a disk reproducing apparatus, the first-order diffracted light always precedes the zero-order diffracted light at the time of reproduction. Therefore, if a defect such as a scratch is present on the disk surface, the first-order diffracted light is first affected and the tracking is performed. The error signal is disturbed.

In a conventional three-beam type disk reproducing apparatus, there has been a method of detecting the disturbance of such a dragging error signal, determining the loss of the disk, and correcting the tracking error signal (see Japanese Patent Application Laid-Open No. 60-29944). However, in such a method, since the tracking error signal is already disturbed at the time of detection, there is a possibility that tracking control may not be performed when passing through a defective portion.

(C) Problems to be Solved by the Invention The present invention provides a method for reproducing a disc having a defective portion.
An object of the present invention is to solve the problem that tracking control or focusing control becomes difficult.

(D) Means for Solving the Problems In view of the above problems, the present invention provides a diffraction grating for splitting light emitted from a light source, an optical system for guiding the split light split by the diffraction grating to a disk surface, and Of the divided light guided by the optical system and transmitted or reflected by the disk, a photoelectric element that receives a divided light preceding the divided light for performing information reproduction, tracking control, and focusing control,
Loss determining means for determining a signal transmitted from the photoelectric element and transmitting an index signal indicating the loss of the disk.

(E) Function When a defect is present in the disc, the influence is exerted on the divided light preceding the divided light for information reproduction, tracking control, and focusing control, and transmitted from the photoelectric element that receives the divided light. The loss discriminating means discriminates the fluctuation and sends an index signal to perform correction such as tracking control. That is, these signals are corrected before the loss existing on the disc affects the information reproduction signal, the tracking error signal, and the focus error signal.

(F) Embodiment In FIG. 1, light emitted from a laser diode (1) passes through a diffraction grating (2), is divided into a plurality of diffracted lights, and is further parallelized by passing through a collimator lens (3). Lighted. The light path of the diffracted light thus converted into parallel light is changed by 90 ° by the beam splitter (4), and is focused on the disk (D) by the objective lens (5). The diffracted light focused on the disk (D) is reflected by the disk (D), passes through a beam splitter (4), passes through a converging lens (6) and a cylindrical lens (7), and becomes astigmatic light. The light is received by the light receiving element ( 8 ).

On the disk (D), the zero-order diffracted light (L ₀ ), the first-order diffracted light (L ₁ ) (L ₁ ′), and the second-order diffracted light (L ₂ ) (L ₂ ′) of the diffracted light are usually the second It is irradiated as shown in the figure. That is, the zero-order diffracted light (L ₀ ) is located substantially at the center of the track formed by the row of pits (9)..., And the two first-order diffracted lights (L ₁ ) (L ₁ ′) are partly substantially equal to each other. Hanging on a truck. The second-order diffracted light (L ₂₎ (L ₂ ') is 0-order diffracted light with located between two adjacent tracks (L ₀₎ and first-order diffracted light (L ₁₎ (L _1' and across the).

By the way, the light receiving element ( 8 ) described above is composed of a four-divided photo sensor (10) and four photo sensors (12a) (12b) (13).
a) (13b), and among the reflected lights of the respective diffracted lights on the disk surface, the 0th-order diffracted light (L ₀ ) is transmitted to the four-divided photosensor (10) by the first-order diffracted light (L ₁ ) (L ₁ ′) is applied to the photosensors (12a) and (12b) by the second-order diffracted light (L ₂ )
(L ₂ ′) is received by the photo sensors (13a) and (13b), respectively. In the four-segment photosensor (10), a focus error signal (F _E ) is formed by using astigmatism of incident light, and an information signal (R _F ) is formed by a sum component of each sensor. Publication reference No. 60-48949), by adding the photo sensor (12a) (12b) in the signal level adder output from each of the sensors (11), a tracking error signal (T _R) is formed.

FIG. 3 is a diagram showing a circuit for correcting a tracking error signal when a loss of a disk is detected.

Signals output from the photosensors (12a) and (12b) are calculated by an adder (11), and the calculated output is passed through a phase compensation circuit (14) and a switch (15) for determining the frequency specification of the servo system, and the pickup is driven. Applied to the circuit (16). Then, a signal output from the pickup drive circuit (16) is applied to the tracking coil (17) to perform tracking control. (18) is a low-frequency hold circuit that retains a low-frequency component of the tracking error signal (T _R ).

The signal output from the photosensor (13a) is binarized by a comparator (19), noise is removed by a low-pass filter (20), and applied to a set input terminal of a flip-flop (22) through an inverter (21). Is done. Similarly, the signal output from the photo sensor (13b) is binarized by a comparator (23), noise is removed by a low-pass filter (24), and further differentiated by a differentiating circuit (25). (2
2) Applied to the reset input terminal. The differentiation circuit (2
5) resets the flip-flop (22) by applying a trigger pulse only when the signal rises. The output terminal of the flip-flop (22) is connected to a switch (15), and the switch (15) is opened when an H level is applied.

Since the second-order diffracted light (L ₂ ) (L ₂ ′) is located between adjacent tracks as described above, these diffracted light (L ₂ )
(L ₂ ′) is always totally reflected by the disc (D) during normal reproduction, and a photo sensor (13
a) An H level signal is output from (13b). Therefore, an L-level signal is applied to the set input terminal of the flip-flop (22) via the inverter (21), the flip-flop (22) is not set, and an L-level signal is output from the output terminal. Has been output. Therefore, the switch (15) is closed and normal tracking control is performed.

Now, it is assumed that the reproduction position has reached the defective portion (26) of the disk as shown in FIG. Then, the second-order diffracted light (L ₂ ) that precedes the other diffracted lights at the reproduction position reaches the defect portion (26), and the second-order diffracted light (L ₂ ) is irregularly reflected by the defect portion. When the second-order diffracted light (L ₂ ) is irregularly reflected in this manner, a photo sensor (13) that receives the _second-order diffracted light (L ₂ )
The output level of a) decreases and the photo sensor (13a)
Outputs an L-level signal. Photo sensor (13
When the output signal from a) is inverted to L level, the output signal from the inverter (21) is inverted to H level in response thereto, and the flip-flop (22) is set in response to the rise of this signal, and the flip-flop (22) is set. The output from the loop (22) is inverted to the H level. Therefore, switch (15) is set to H
The level signal is applied, and the switch (15) is opened.

When the switch (15) is opened, the tracking error signal (T _R ) is no longer applied from the phase compensation circuit (14) to the pickup driving circuit (16), and the switch ( 15) A predetermined level signal which is a low-frequency component of the tracking error signal (T _R ) at the time of opening is applied. Therefore, a predetermined level voltage is applied to the tracking coil (17), and each of the above-mentioned diffracted lights is at a predetermined position,
That is, it is fixed at the position where it has reached the defective portion (26).

Further, following the _second-order diffracted light (L ₂ ), the first-order diffracted light (L ₁ ), the zero-order diffracted light (L ₀ ), and the first-order diffracted light (L ₁ ′) sequentially reach the defective portion (26). Since the light does not participate in the operation of the flip-flop (22), the switch (15) is kept open and each diffracted light is kept in the above position.

Further, following each of the above-described diffracted lights, the second-order diffracted light (L ₂ ′) reaches the defective portion (26), and the output signal from the photosensor (13b) is inverted to the L level. Since the inversion is to the L level, no trigger pulse is output from the differentiating circuit (25). Therefore the flip-flop (2
2) is not reset.

As described above, when each of the diffracted lights passes through the defective portion (26), the switch (15) is open, and each of the diffracted lights keeps the track position when reaching the defective portion.

Now, with the rotation of the disk, the second-order diffracted light (L ₂ ′)
However, when the light exits from the defective portion (26) following the preceding diffracted light (L ₂ ) (L ₁ ) (L ₀ ) (L ₁ ′), the second-order diffracted light (L ₂ ′) is totally scattered by the disc (D). Reflected by the photo sensor (13
The output of b) is inverted from L level to H level. Then, at the same time, a trigger pulse indicating the rising of the signal is applied to the flip-flop (22) from the differentiating circuit (25), and the flip-flop (22) is reset. When the flip-flop (22) is reset in this way, the output signal of the flip-flop inverts to L level, thereby causing the switch (15)
Is closed. The big drive circuit (1
The tracking error signal (T _R ) is applied to 6), and the control returns to the normal tracking control.

As described above, in the present embodiment, before the 0th-order diffracted light for information reading and focus control and the 1st-order diffracted light for tracking control reach the defective portion of the disk, the defect of the disk is detected by the second-order diffracted light and the tracking error signal is generated. Since the correction is performed, the tracking control is not disturbed by the loss of the disk. Further, the length of the defect can be determined by the second-order diffracted light, that is, the beginning of the defect is detected by the preceding diffracted light of the two second-order diffracted lights, and the end of the defect is detected by the other diffracted light. Therefore, the tracking error signal can be reliably corrected regardless of the size of the defect.

In the above embodiment, the tracking error signal is corrected when the loss is detected. However, it is needless to say that the tracking error signal can be used for correcting the focus error signal and the information signal. Further, the method of correcting the tracking error signal is not limited to the method of this embodiment, but may be a method of controlling the frequency characteristic of a servo system, for example.

Further, in this embodiment, the description has been given of the three-beam type disk reproducing apparatus. However, the present invention is not limited to this. For example, the present invention can be applied to a one-beam type disk reproducing apparatus which performs information reproduction, focusing control, and tracking control with one beam. . In this case, it is preferable to perform information reproduction, focus control, and tracking control using the 0th-order diffracted light, and perform defect detection using the 1st-order diffracted light.

(G) Effects of the Invention According to the present invention, before the light for performing information reproduction, tracking control, and focusing control reaches the defective portion of the disk, the defective portion is detected and the index signal is transmitted. By correcting information reproduction, tracking control, focusing control, and the like with the index signal, a malfunction can be prevented from occurring due to a defective portion, and a stable reproduction operation can be realized.

[Brief description of the drawings]

Each of the drawings shows an embodiment of the present invention. FIG. 1 is a diagram showing an optical system, FIG. 2 is a diagram showing a position of each diffracted light on a disk surface and a relationship with a photosensor which receives each diffracted light, and FIG. 3 is a diagram for correcting a defect. FIG. 3 is a diagram showing a circuit configuration of FIG. (1) laser diode (light source), (2) diffraction grating, ( 8 ) light receiving element (photoelectric element), (21), (2)
2), and (25) …… Inverters, flip-flops,
And a differentiating circuit (loss determining means).

Claims (1)

(57) [Claims] 1. A diffraction grating for splitting light emitted from a light source, an optical system for guiding zero-order, first-order, and second-order diffracted light split by the diffraction grating to a disk surface; Of the diffracted light transmitted or reflected from the disc, a first photoelectric element that receives the 0th-order diffracted light used for information reproduction and focusing control; and a first photoelectric element guided from the optical system and transmitted or reflected from the disc. Of the diffracted light, a second photoelectric element that precedes and follows the 0th-order diffracted light and receives the first-order diffracted light used for tracking control; and each guided by the optical system and transmitted or reflected from the disk. Of the diffracted light, two third photoelectric elements that receive the second-order diffracted light preceding and succeeding the first-order diffracted light, and based on a signal transmitted from the second photoelectric element. A phase compensating means for determining the frequency characteristic of the servo system, a pickup driving means for performing a tracking control of the pickup based on a signal output from the phase compensating means, and a path for guiding a signal from the phase compensating means to the pickup driving means. Switch means for passing and blocking a signal from the phase compensation means; and when the second-order diffracted light preceding the first-order diffracted light reaches a defective portion on the disk, the second-order diffracted light advances. The switching means is controlled based on a change in a signal from the third photoelectric element that receives the folded light, and blocks a signal guided from the transfer compensating means to the pickup driving means. After the second-order diffracted light passes through the defective portion on the disk, the signal from the third photoelectric element that receives the subsequent second-order diffracted light Disk playback apparatus controls the switching means based on the change, and having a defect detection control means for passing a signal derived from the transfer compensation means to the pickup driving means.