KR950000894B1 - Focus error retesting method for optical disk driver - Google Patents

Abstract

The method for detecting a focus error of an optical disk driver detects the focus error by using a thin film having on but sides a reflecting film of high reflecting ratio in order to detect a concentrated focus state of an object lens concentrating on light spot. The method is arranged that incident beam is concetnrated into the object lens, this concentrated beam is reflected on the optical disk, and on its opposite side a light detecting apparatus is set, thereby a change of a beam incidence angle entering the thin film is separated into the reflected beam so that the focus error signal can be detected.

Description

Focus error detection method of optical disk driver

1 is a plan view of a focus error detection apparatus of a conventional optical disk driver.

2 is a plan view of focus error detection of the optical disk driver of the present invention.

3 is a reflectance characteristic curve of a thin film used in the present invention.

Figure 4 is an enlarged plan view showing the principle of the focus error detection device of the optical disk driver of the present invention.

5 is a plan view showing a thin film used in the present invention.

* Explanation of symbols for main parts of the drawings

1: laser 2: collimator

3: polarization prism 4: 1/4 wavelength plate

5: objective lens 6: optical disc

7: condenser lens 8: circular lens

9: thin film 9a, 9b: reflective film

9c: glass 10a, 10b: photodetector

: 차동증폭기 10 : 광검출장치

Differential Amplifier 10

11: 1/4 wavelength plate

The present invention provides a focal error of an optical disc driver in which a focus error can be detected by using a thin film having both sides of a high reflectivity reflective film in order to detect a confocal state of an objective lens focused to an optical spot in an optical disc driver. It relates to a detection method.

In the conventional optical disc driver, as shown in FIG. 1, the light error emitted from the laser 1 becomes parallel light through the collimator 2, and the parallel light is 1/1 with the polarization prism 3. After focusing on the objective lens 5 through the four-wavelength plate 4 to detect the track of the optical disk 6, the detected signal passes through the quarter-wave plate 4 again and is reflected by the polarization prism 3. do. The beam reflected in this way is focused by the condenser lens 7 and the cylindrical lens 8, and the focused beams appear to be in focus with each other in the orthogonal direction. This confocal beam is detected by a quadrant photodetector arranged on the focal plane. This detected focus error signal is supplied to the movable coil device to move the objective lens 5 in its axial direction.

This method of focus error detection requires a considerably long optical path to focus the light beam, and the photodetectors must be precisely positioned in two orthogonal directions perpendicular to the optical axis and the optical axis. Since the signal is obtained in a relatively narrow operating range, the focus error signal cannot be detected even if the disk is slightly displaced.

In order to solve the above problems, the beam reflected from the optical disk is reflected back from the polarization prism through the quarter wave plate, and the reflected beam is reflected by using a thin film having a high reflectivity reflective layer on both sides. The polarization direction is reversed through the / 4 wave plate, and then passed through the polarization prism to change the light distribution of the light flux or the amount of light flux and the transmitted light flux to detect the focus error signal with the photodetector. Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

와 광검출기(10a), (10b)로 구성된 광검출장치(10)를 설치하여 상기 박막(9)에서 반사된 광속이 다시 1/4파장판(11)을 통과하여 상기 편광프리즘(3)을 통하여 광검출장치(10)에 인가시켜 이 광검출장치(10)로 초점오차 신호를 검출하여 대물렌즈(5)의 초점을 맞추기 위한 대물렌즈 구동장치(도시되지 않음)를 구동할 수 있게 한 것으로 상기와 같이 구성하여서 된 본 발명의 작용효과를 설명하면 다음과 같다.As shown in FIGS. 2 to 4, parallel light passing through the laser 1 and the collimator 2 is transferred from the objective lens 5 through the polarizing prism 3 and the quarter wave plate 4. The focused beam is reflected on the optical disk 6 and then reflected through the quarter wave plate 4 and the polarizing prism 3 so that the reflected beam is again focused and arranged on the focal plane. In the optical disk driver focus error detection method to be detected by the optical disk driver, the optical disk 6 is reflected by the quarter wave plate and the polarization prism 3 and is reflected by the quarter wave plate 11. ) And then on both sides of the glass 9a with refractive index n ₀ = 1.52 and thickness d ₀ = 50.14 as shown in FIGS. 3 and 5, the refractive index n ₁ = 2.30, n ₂ = 1.35, thickness lambda / A thin film 9 having a reflectivity of 73% with four reflective films 9a and 9b as four layers has a left side of the polarizing prism 3 as shown in FIG. But installed on the right side of the thin film (9) is a polarization prism 3 is shifted by about 2.8 ° installed with respect to the optical axis (C) and the other side that is the polarizing prism 3 of the differential amplifier is

And a photodetector 10 composed of photodetectors 10a and 10b so that the luminous flux reflected from the thin film 9 passes through the quarter-wave plate 11 again to pass through the polarizing prism 3. It is applied to the photodetector 10 to detect the focus error signal with the photodetector 10 so as to drive an objective lens driving device (not shown) for focusing the objective lens 5. Referring to the effects of the present invention configured as described above are as follows.

The beam emitted from the laser 1 becomes parallel light through the collimator 2, and the parallel light is focused in the objective lens 5 through the polarizing prism 3 and the quarter wave plate 4. The focused beam is reflected by the optical disk 6 and again reflected by the polarization prism 3 through the quarter wave plate 4 to reach the thin film 9.

The beam thus reached is such that the beam incident angle A is smaller than the beam incident angle B as shown in FIG. In other words, the non-incidence angle A shows high reflectance and the non-incidence angle B shows good transmittance.

In other words, the reason why the non-incidence angle A has high reflectance is that, as shown in the characteristic diagram of FIG. Can be. On the other hand, the incident beam as described above detects the difference in the amount of light using the light beams reflected by the thin film 9 as the photodetectors 10a and 10b. As shown in Fig. 4, the reflection beam enters the thin film 9 when it is displayed in the IN FOCUS state (single dashed line), in the focus state (solid line), or in the out focus (OUT FOCUS) (dashed line). The angle to be viewed is in the order of dotted line> solid line> dotted line when viewed from the beam incidence angle (B), and in the order of the dotted line> solid line> dotted line in the non-incidence angle (A). Therefore, the light beam reflected by the thin film 9 is reversed in the polarization direction, and passes through the polarization prism 3 again in the quarter wave plate 11 and applied to the photodetectors 10a and 10b. (10b) detects the focus error signal through the differential amplifiers (COMP ₁ ) and (COMP ₂ ), and the detected focus error signal is supplied to the objective lens driving device to focus the objective lens 5. It is to be able to focus the objective lens (5).

As described above, in the present invention, a thin film having a high reflectance layer on both sides is provided at a corresponding position of the polarizing prism, so that the light distribution of the light flux reflected from the thin film, or the amount of light flux transmitted, is transmitted to the light detection device. This makes it possible to easily detect the focus error signal of the optical disc, and to precisely adjust the position of the objective lens and to simplify the structure of the optical system, thereby reducing the optical path, thereby providing a compact focus error detection device. It is.

Claims (3)

The beam emitted from the laser 1 is focused on the objective lens 5 through the collimator 2, the polarization prism 3, and the quarter wave plate 4, and the focused beam is reflected by the optical disk 6 And a thin film 9 having a high reflectivity reflective layer on both sides where the light is reflected by the polarization prism 3 through the quarter wave plate 4 and on the opposite side, the photodetectors 10a and 10b and the differential amplifier And a photodetector 10 composed of (COMP ₁ ) and (COMP ₂ ), so that when the incident light enters the thin film 9, a change in the beam incident angle is separated into a reflected beam to detect a focus error signal. The focus error detection method of the optical disk driver. The film 9 according to claim 1, wherein the thin film 9 has a refractive index n ₁ = 2.30, n ₂ = 1.35 thickness on both sides of the glass 9C having a refractive index n ₀ = 1.52 and a thickness d ₀ = 50.14.

A focus error detection method for an optical disc driver, comprising four layers of phosphor reflecting films (9a) and (9b). The method of claim 1, wherein the photodetector 10 is installed on the corresponding surface of the polarizing prism 3 by using the vertical reflection and the quarter wave plate 4 on the surface of the thin film 9 so that the optical path can be reduced. A focus error detection method for an optical disk driver, characterized in that the.

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