KR100474759B1 - Skew setting method of object lens for optical pickup - Google Patents

Abstract

The present invention relates to an objective lens skew adjustment method for optical pickup that facilitates skew adjustment in the R direction by artificially increasing the relative light amount of the primary ring in the R direction for adjusting the objective lens skew for the optical pickup. .

According to the present invention, in adjusting the objective lens skew of the optical pickup, the CCD data region for detecting the objective lens emission light is appropriately divided in the R / T direction and normalized to the maximum value in each divided region. The amount of primary ring light is increased relatively to facilitate simultaneous adjustment of R / T skew and R skew adjustment.

In addition, the present invention is to increase the CCD gain for sensing the objective light emitted by the saturation in the T direction and to increase the R direction accordingly, so that fine skew adjustment in the R direction can be made. In addition, the present invention allows fine skew adjustment in both the R / T directions by reducing the 0th order light and increasing the first order light by using the defocusing of the CCD sensing the objective lens exit light.

Description

Objective skew adjustment method for optical pickup {SKEW SETTING METHOD OF OBJECT LENS FOR OPTICAL PICKUP}

The present invention relates to a method of adjusting an objective lens skew of an optical pickup. In particular, the present invention relates to a method of adjusting the objective lens skew of the optical pickup to facilitate the skew adjustment in the R direction by artificially increasing the relative light amount of the primary ring in the R direction for adjusting the objective lens skew of the optical pickup. will be.

In general, an optical pickup device includes a laser light source (laser diode), a collimator lens for making a laser beam output from the laser light source into a parallel beam, a reflector for converting the parallel beam into an optical path in a disk direction, and the reflected laser beam. It consists of an objective lens or the like that focuses and joins to an arbitrary point on the disk. When assembling the pick-up base and the actuator in the optical pickup apparatus, skew in the radial (R) direction and the tracking (T) direction is adjusted. However, since the numerical aperture (NA) of the collimating lens is small, the primary ring in the R / T (Radial / Tracking) direction of the objective lens is difficult to read. In the case of recordable pick-up, the numerical aperture of the collimating lens is relatively large and there is almost no primary ring. Therefore, in this case, it is very difficult to adjust the skew in the R direction because the signal of the primary ring used to detect the skew change of the objective lens, in particular, the primary ring signal in the R direction is small. For this reason, the skew in the R direction is conventionally adjusted depending on the experience of the skew adjuster by looking at the shape of the beam in the T direction. As such, depending on the experience of the coordinator, each coordinator has individual deviations and difficult to adjust precisely, which impedes the implementation of high quality pickup.

1 shows a typical light distribution and shape of the optical pickup objective light, and FIG. 2 shows a relative distribution of the primary ring light quantity of the objective lens exit light.

As shown in Fig. 1 and Fig. 2, the skew in the R direction and the T direction is adjusted using the objective lens skew adjusting device. The skew in the T direction is R due to the asymmetry of the laser diode radiation angle. It is relatively much richer than the amount of light in the primary ring in the direction, which makes it difficult to visualize the detection in the R direction. As a result, the skew in the T direction can be easily recognized, but the skew in the R direction cannot be easily obtained.

The light distribution characteristic can be obtained by capturing and displaying the objective lens exit light with a CCD camera. In the light distribution of the objective lens output light acquired by the CCD camera, the signal intensity of the primary ring is large in the light distribution in the T direction, but the signal strength of the primary ring in the R direction is small. You will find it very difficult to adjust the skew. Moreover, even if the R skew is adjusted within a narrow width in the R direction, it is difficult to discern how much the adjustment has been made, and the degree and precision of the adjustment are also considerably inferior to the T direction.

This results in deterioration of the reliability and quality of the optical pickup apparatus, and further, the instability of the servo control and the lowering of the reliability of data, resulting in deterioration of the quality of the optical disc recording / reproducing apparatus.

The present invention provides a method of adjusting the objective lens skew of the optical pickup to adjust the objective lens skew of the optical pickup by forcibly increasing the primary ring in the R direction, thereby making it easier to perform the skew adjustment in the R direction. Suggest.

According to the present invention, in adjusting the objective lens skew of the optical pickup, the CCD (Charge Coupled Device) data area for detecting the objective lens emission light is appropriately divided in the R / T direction and normalized to the maximum value in each divided area. By increasing the amount of primary ring light in the R direction, the objective lens skew adjustment method for optical pickup can be facilitated for simultaneous adjustment of R / T skew and R skew adjustment.

In the present invention, in adjusting the objective lens skew of the optical pickup, the CCD gain for detecting the objective lens output light is increased so that the T direction is saturated and the R direction is increased accordingly, so that fine skew adjustment in the R direction can be performed. We propose an optical lens skew adjustment method for an optical pickup.

In the present invention, in adjusting the objective lens skew of the optical pickup, by using the defocusing of the CCD for detecting the objective lens output light, the zero-order light is minimized and the first-order light is increased to fine tune the skew in both the R / T directions. An object lens skew adjustment method of an optical pickup is proposed.

The objective lens skew adjustment method of the optical pickup of the present invention increases the size of the primary ring in the R direction by detecting the objective lens exit light and obtaining the light quantity distribution in the R / T direction. The skew in the R direction is adjusted using the R direction primary ring distribution information.

Referring to the objective lens skew adjustment method of the optical pickup of the present invention described above in detail with reference to the accompanying drawings as follows.

FIG. 3 is a diagram showing the division of the CCD data region for explaining the first embodiment of the present invention, and FIG. 4 is a diagram showing the relative distribution of the primary ring light amount of the objective lens exit light.

In the first embodiment of the present invention, the data area of the CCD for detecting the objective lens exit light is divided into four in the R / T direction, and the output value and the detected value (data) are normalized to the maximum value in the region divided in the R direction, and R is By artificially increasing the sensitivity to the direction, it is a technique to increase the relative distribution of the amount of primary ring light in the R direction to facilitate the R skew adjustment.

That is, the sensing data area of the objective lens exit light detected by the CCD of the skew adjuster is divided into four areas Rt, Rb, Tr, and Tl in the R and T directions. The area segmentation is divided so as to have a width and a direction that sufficiently ensures the orientations in the R and T directions. Preferably, the area segmentation is performed by dividing the R and T axes in the center of the region.

Here, the data area may be virtually divided by software rather than physical partition, and two areas having the largest directionality in the R direction among the four divided areas, that is, the data of Rt and Rb in FIG. Normalization is performed to the maximum value in.

Then, as shown in FIG. 4, the relative distribution of the primary ring light amount of the objective lens exit light will appear. In other words, while the T direction maintains its existing shape, the R direction increases sensitivity differently. Therefore, the T direction and the R direction can be processed independently, so that the T skew and the R skew can be adjusted at the same time, and the R skew adjustment can be made more finely than in the conventional FIGS. 1 and 2.

That is, when adjusting the skew in the T direction, as described above, the amount of light in the primary ring in the T direction is abundant, so that it is easy to adjust the skew in the T direction.

However, when adjusting the skew in the R direction, the amount of light in the primary ring in the R direction is relatively insufficient as in FIG. 1, and thus it is not easy to adjust the skew in the R direction. Therefore, in the present invention, for adjusting the skew in the R direction, as shown in Fig. 3, the normalization process of dividing the CCD data area and artificially increasing the primary ring in the R direction, among others, is performed. In this artificially increased form, the primary light amount in the R direction is relatively abundantly detected.

Therefore, as shown in Fig. 4, when the relative amount of light in the R direction increases, the sensitivity of the skew in the R direction increases, so that the skew in the R direction can be finely adjusted by FIG.

On the other hand, as shown in Fig. 3, the effect of dividing the CCD data region into regions having the R / T directionality can also be ensured by a method of weighting the components in a specific direction to perform data processing.

In other words, if the CCD data is amplified in a manner that gives a greater weight to the R direction with respect to the component in the R direction with respect to the CCD data, the result of artificially increasing the sensitivity in the R direction as shown in FIG. 4 can be obtained. It is.

5 is a view showing the light distribution and shape (CCD Saturation) of the objective lens output light for explaining the second embodiment of the present invention, Figure 6 is a primary ring light amount of the objective lens output light according to the second embodiment of the present invention Shows the relative distribution of.

In the second embodiment of the present invention, in order to artificially increase the primary ring in the R direction, the gain of the CCD is increased to saturate in the T direction, and the amount of light in the primary ring in accordance with the saturation in the T direction in the R direction. This is a technique to increase.

That is, as shown in Fig. 5, the gain of the CCD is increased. Then, since the beam of the primary ring in the T direction has a larger amount of light than the beam of the primary ring in the R direction, the CCD cell in the T direction will first reach a saturation state. However, even when the T direction is saturated, the beam light amount of the primary ring in the R direction increases from a small value, so that the CCD cell in the R direction does not yet reach the saturation state.

Therefore, as shown in Fig. 5, the light amount in the T direction is saturated, and the light amount in the R direction is not saturated, but the light amount in the primary ring is artificially increased. Therefore, the output difference of the CCD cells in the R direction and the T direction is reduced, and the amount of light in the R direction is relatively increased, and thus the relative distribution characteristics of the primary ring light amount as shown in FIG. 6 are obtained. In this way, when the relative amount of light in the R direction is increased, the sensitivity to the skew in the R direction is increased, thereby ensuring an environment in which the skew in the R direction can be finely adjusted.

Fig. 7 shows the configuration of a skew adjuster for explaining the third embodiment of the present invention. The pickup 702 is mounted on the T / T skew adjustment table 701, and the actuator 703 is supported by the support portion 704. The outgoing light of the pick-up objective lens is detected by the sensor 705 (CCD), and the detected signals A, B, C, and D are respectively driven by the T driver 708 and the R driver 709 through the calculators 706 and 707. The skew adjuster is inputted as a driving control signal, and the R / T skew adjusting table 701 is driven by the T driving unit 708 and the R driving unit 709.

FIG. 8 is a view showing a light distribution according to a third embodiment of the present invention. Defocusing the CCD 705 to minimize zero-order light and increase primary light to measure light at four points. T / R skew is adjusted using the information A, C, B, and D.

That is, the T skew is adjusted by driving the R / T skew adjustment table 701 through the T driver 708 to the value obtained by calculating the difference between the sensing signal A in the T direction and the sensing signal C in the calculator 706. The R skew is adjusted by driving the R / T skew adjustment table 701 through the R driving unit 709 to the value obtained by calculating the difference between the sensing signal B in the R direction and the sensing signal D in the calculator 707. It is.

As described above, by artificially increasing the primary light by using defocusing, it is possible to easily adjust the skew in the R direction and the T direction.

Meanwhile, when adjusting the R / T skew in the skew adjuster of FIG. 7, the base may be fixed and the actuator may be adjusted by moving the actuator in the R / T direction, or the actuator may be released by moving the base in the R / T direction. Can also be used. After adjusting the skew, the actuator is soldered and fixed.

The present invention facilitates the R skew adjustment of the objective lens by making the amount of primary ring light in the R direction relatively rich in order to adjust the skew of the optical pickup objective lens.

In the present invention, the CCD data region is divided to artificially increase the sensitivity in the R direction, or the CCD gain is increased to saturate the T direction and to artificially increase the sensitivity in accordance with the T direction saturation, or to defocus the technique. By minimizing the amount of zeroth order light and increasing the amount of first order light, it is possible to fine tune the R skew by increasing sensitivity in the R direction.

Therefore, according to the present invention, the skew adjustment is facilitated at the time of assembling the optical pickup base and the actuator, and the precise adjustment is possible.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a view for explaining a typical light distribution and shape of an objective lens exit light of an optical pickup;

FIG. 2 is a diagram for explaining the relative distribution of the amount of primary ring light of the objective lens exit light of the optical pickup; FIG.

FIG. 3 is a view showing an example of dividing a CCD data region into four in order to amplify an objective lens outgoing light detection signal as a first embodiment of the present invention.

Fig. 4 is a diagram showing the relative distribution of the amount of primary ring light of the objective lens exit light according to the first embodiment of the present invention.

5 is a view showing the light distribution and shape (CCD Saturation) of the objective lens exit light as a second embodiment of the present invention

Fig. 6 is a view showing the relative distribution of the amount of primary ring light of the objective lens exit light according to the second embodiment of the present invention.

7 is a diagram showing the configuration of a skew adjuster according to a third embodiment of the present invention;

8 is a view showing the light distribution of the objective lens exit light according to the third embodiment of the present invention;

Claims (6)

Detecting objective lens outgoing light for adjusting the objective lens skew of the optical pickup; dividing the data reflecting the directional directions of the radial (R) direction and the tangential (T) direction with respect to the objective lens outgoing light detection information; And normalizing the data of the divided radial (R) direction region to increase the relative distribution of the primary ring light quantity in the radial (R) direction so that skew adjustment is performed. How to adjust skew. 2. The method of claim 1, wherein the normalization is performed to a maximum value within the region. The objective lens skew adjustment method of claim 1, wherein the primary ring light amount in the radial (R) direction is increased by weighting the component in the R direction with respect to the objective lens output light detection data. . Detecting an objective lens outgoing light for adjusting the objective lens skew of the optical pickup, amplifying the objective lens outgoing light detection information so that the tangent T direction is saturated, and the tangent T direction is saturated And performing a skew adjustment using the primary ring light quantity distribution in the radial (R) direction increased together with the amplification when the signal is reached. Defocusing a CCD (Charge Couped Device) for detecting objective lens exit light in the direction of minimizing the 0th order beam and increasing the primary ring for adjusting the objective lens skew of the optical pickup, obtained from the defocused result And performing skew adjustment using a primary ring light quantity distribution in a radial / tangential (R / T) direction. The method according to claim 5, wherein the tangent (T) skew is obtained by using the difference between the primary ring detection signal in the tangential (T) direction and the primary ring detection signal in the radial (R) direction obtained by the defocusing. And a radial (R) skew adjustment method.