KR100438290B1 - Optical pickup - Google Patents

Abstract

The present invention relates to an optical pickup apparatus including a condenser lens for guiding and concentrating light from a light source to a monitor optical detector (MPD) in an optical pickup apparatus for recording and reproducing data on an optical recording medium using a laser. .

In particular, the present invention is a light collecting lens for focusing a part of the light emitted from the laser diode to enter the MPD, using a square BS (PBS), forming a part of the corner of the PBS as a reflective surface and mounting the MPD on the opposite surface An optical pickup apparatus includes a condenser lens in which a part of laser diode emitted light is reflected from the reflective surface to focus and form an image on an MPD.

In addition, the present invention forms a part of the corner of the square BS (PBS) as a reflective surface and by placing the MPD on the opposite surface to allow the MPD to receive some light that is not transmitted to the collimating lens system from the light emitted from the laser diode, Provided is an optical pickup device including a condenser lens that has a small dispersion of the amount of incident light of the MPD due to the emitted light and improves the light utilization efficiency, and is easy to assemble and light and short.

Description

Optical pickup device {OPTICAL PICKUP}

The present invention relates to an optical pickup apparatus including a condenser lens for guiding and concentrating light from a light source to a monitor optical detector (MPD) in an optical pickup apparatus for recording and reproducing data on an optical recording medium using a laser. .

In the case of CD-R / RW, which is one of the optical recording apparatuses, a method of monitoring the laser light output and adjusting the driving current so that the light output is constant is used. For this purpose, the monitor PD is used. Although the photodetector PD placed behind the laser diode is convenient to monitor the laser light output, the rear monitor PD is not used because the front output light output of the laser diode is nonlinear compared to the rear output light output. Has the disadvantage of poor accuracy. To overcome this, a front monitor PD is used that directly monitors the front exit light.

Fig. 1 shows the general configuration of the optical system for the front monitor PD in a pickup for a CD-R / RW using a high output hologram pickup module (HPM) for optical pickup.

The light output from the hologram pickup module (HPM) 101 is converted into a parallel beam through the collimating lens 102 and reflected by the reflector 104 through the beam splitter 103 and then to the objective lens 105. It is focused and focused at any point on the optical disc 106. In addition, the beam splitter 103 forms a part of the 0th order beam of the HOE by the MPD 107 so as to be used for adjusting the recording optical power.

The present invention provides an optical pickup apparatus including a condenser lens that can guide and focus light from the light source to the MPD in the optical pickup apparatus.

In particular, the present invention is a light collecting lens for focusing a part of the light emitted from the laser diode to enter the MPD, using a square BS (PBS), forming a part of the corner of the PBS as a reflective surface and mounting the MPD on the opposite surface A light pickup device including a condenser lens in which a part of laser diode emitted light is reflected by the reflecting surface to focus and form an image on an MPD.

In addition, the present invention forms a part of the corner of the square BS (PBS) as a reflective surface and by placing the MPD on the opposite surface to allow the MPD to receive some light that is not transmitted to the collimating lens system from the light emitted from the laser diode, Provided is an optical pickup device including a condenser lens that has a small dispersion of the amount of incident light of the MPD due to the emitted light and improves the light utilization efficiency, and is easy to assemble and light and short.

1 is a view showing the configuration of a conventional optical system for a front monitor PD;

2 is a view showing the configuration of the first embodiment of the optical pickup apparatus using the condenser lens of the present invention;

3 is a diagram showing the configuration of a second embodiment of the optical pickup apparatus using the condenser lens of the present invention;

4 is a diagram showing the configuration of the third embodiment of the optical pickup apparatus using the condenser lens of the present invention;

5 is a diagram showing the configuration of the fourth embodiment of the optical pickup apparatus using the condenser lens of the present invention;

Fig. 2 shows a first embodiment of an optical system structure of a pickup including a condenser lens using a square BS (PBS) of the present invention.

A laser diode 201 was used as a light source, and the BS 202 for the light distribution output from the laser diode 201 and an optical system using the main beam a of the laser light to make the main beam into a parallel beam. A collimator lens 203, a reflector 204 for reflecting light converted into a parallel beam by the collimator lens 203, an objective lens 205 for focusing the reflected parallel beam, and the objective It includes an optical disk 206 in which the beam focused by the lens 205 is focused at an arbitrary point to read or write data. In addition, a total reflection surface 207 is formed on a part of a corner of the BS 202 so that the light b emitted from the laser diode 201 without being incident to the main optical system is incident on the MPD 208. The MPD 208 is mounted on one surface of the BS 202 opposite to the total reflection surface 207. The focusing characteristic of a laser beam common in the optical device configured as described above will be briefly described. The emitted elliptical laser beam is incident on the collimator lens and passes through only the central area of the elliptical beam, and becomes a parallel beam. The parallel beam is incident on the objective lens and focused on the disk data surface to form an elliptic beam spot. In this case, the elliptical beam spot on the disk data plane has the same long axis direction as the short axis direction of the elliptical beam emitted from the laser diode.

The recordable optical pickup apparatus shown in FIG. 1 uses the BS 202 to have a large radiation angle of the laser diode 201 in a tangential direction when the radial OV (Radial Oval Spot) type is ROS. 207 cuts the edge surface of BS 202 into a sloped surface that satisfies the total reflection condition. The MPD 208 may be placed on top or bottom of the BS 202, and the light totally reflected by the total reflection surface 207 propagates through the BS 202 to the MPD 208.

By making an inclined plane (total reflection surface) in the form of a chamfer on the opposite edge portion of the MPD 208 as described above, the amount of light incident on the MPD 208 due to the radiation angle of the laser diode 202 or fabrication or assembly error Spreading can be reduced and assembly tolerances can also be increased, which can help improve assembly.

Of the light emitted from the laser diode 201 at a wide angle, the light b, which is not incident to the main optical system 203, 204, 205 and is discarded, is incident on the total reflection surface 207 of the BS 202 at a predetermined angle of incidence. Total reflection. The reflected light b propagates under total reflection conditions, and the light reaching the opposite exit surface is focused and formed on the MPD 208.

The main beam a output from the laser diode 201 is converted into a parallel beam by the collimating lens 203 via the BS 202 and then reflected by the reflecting mirror 204 to the optical disk through the objective lens 205. 206 is focused on to record or reproduce data.

3 is a view showing the optical system structure according to the second embodiment of the present invention, in which the total reflection surface 207a formed in the BS 202 is formed in the outer edge portion of the BS 202. That is, the total reflection surface 207a formed at the outer edge portion of the BS 202 totally reflects the emitted light b of the laser diode 201 to propagate light using air as a medium. It is a structure mounted at a predetermined position on the total reflection path.

4 is a view showing an optical system structure according to a third embodiment of the present invention, in which a total reflection surface 207b formed in the BS 202 is formed at the outer edge portion of the BS 202, and the MPD 208 is formed. It is a structure mounted on one surface of BS 202 of the position near the total reflection surface 207b. According to this structure, since the MPD 208 is mounted on the BS 202, it can occupy less space and contribute to light and thinner than the structure of FIG.

FIG. 5 is a view showing an optical structure according to a fourth embodiment of the present invention, in which a total reflection surface 207c is formed in an inclined shape at a corner portion of the PDIC 210 in a radial direction, and the opposite side thereof is opposite. The MPD 208 is mounted at a position where the MPD 208 is mounted, 202a is a PBS, 209 is a QWP (λ / 4 plate), and 210a is a focusing lens. The optical system shown in Fig. 5 is a structure in which both the optical system leading to the PDIC 210 and the optical system leading to the MPD 208 are realized in a square BS, and the total reflection surface 207c in which the monitor optical system for the MPD 208 is formed in the BS and Since the MPD 208 mounted on the opposite surface is made light and small, the laser monitor system can be configured efficiently and efficiently. FIG. 6 shows that the MPD is totally reflected by the inclined surface formed on the BS. In general, a critical angle at which total reflection occurs is determined by a known Snell's law according to the refractive index of each medium on which refraction is to occur, and a total reflection is generated by a laser beam incident at an angle larger than the threshold angle. As shown in FIG. 6, the central portion of the elliptical beam emitted from the laser diode passes through the collimator lens and is driven by the objective lens on the optical disk surface. Although ocusing, it is possible to detect the amount of incident light by creating a total reflection surface in the corner region of BS prism that passes the area larger than the outer diameter of the collimator lens, and placing the MPD at the opposite corner.The total reflection surface is the incident angle θ, 7A is a view showing the chamfered slope and the MPD formed in the BS of FIG. 2. FIG. 7B is a view showing the chamfered slope and the MPD formed in the BS of FIG. 5. The difference between FIGS. 7A and 7B is that the position of the total reflection surface and the position of the MPD are different depending on whether the long axis of the ellipse of the LD radiation beam is in the radial or tangential direction. As described above, in the optical pickup apparatus according to the present invention, Since the light for MPD uses light that is not used in the main beam optical system, the light utilization efficiency can be improved. In addition, since the light incident on the BS is totally reflected by the total reflection surface of the corner portion to form an MPD, the allowable range of the angle of incidence (critical angle) is large, and thus the assembly error of the MPD optical system is not a problem. Excellent and good dispersion.

In addition, since the total reflection surface for the monitor optical system and the MPD mounted on or close to the BS can be installed in the BS itself, it is also possible to configure the optical pickup device to be light and thin.

The optical pickup apparatus including the total reflection type condensing lens of the present invention has high light efficiency, excellent dispersion characteristics of the amount of MPD incident light according to the objective lens exit light, and can form a monitor optical system using a partial surface of a square BS corner. Therefore, the assembling error at the time of assembling the monitor optical system can be largely tolerated, resulting in excellent assemblability.

In addition, since a separate condenser lens for the monitor optical system (MPD) is not required, the light utilization efficiency can be further increased, thus enabling the use of a relatively low power laser diode.

Claims (6)

LD, which is a light source, a collimator lens converting the light source into parallel light, and a BS formed between the LD and the collimator lens and performing one or more refractions, passes, or reflections on the light emitted from the LD. In the optical system, A reflective surface is formed on one surface of the BS to reflect light that will not be transmitted to the collimator lens among the light output from the light source, and a contact or constant point with the BS is used to detect the light reflected by the reflective surface. MPD; optical pickup apparatus characterized in that the formed. The reflective surface of claim 1, wherein the propagation path by the reflection of light formed into the MPD passes through the BS and passes through an area larger than the outer diameter of the collimator lens, and the reflecting surface at the corner of the BS so that the light is formed into the MPD. Optical pickup device, characterized in that formed inclined. The optical pickup apparatus of claim 2, wherein the reflective surface formed on one surface of the BS is formed at a predetermined angle to totally reflect the light incident from the LD. The optical pickup apparatus of claim 1 or 2, wherein the MPD is formed in a direction opposite to or the same as a reflection surface formed in the BS. The optical pickup apparatus of claim 1, wherein the position of the reflection surface and the position of the MPD are differently formed depending on whether the long axis of the ellipse of the light emitted to the LD is in the radial direction or the tangential direction. 6. The optical pickup apparatus of claim 5, wherein the reflective surface is formed at the PDIC side edge in the radial direction from the BS and the MPD is located at a position opposite the reflective surface.