NL1007927C2 - Optical recording system for reading information signals stored on an optical disk. - Google Patents

Description

Title: Optical recording system for reading information signals stored on an optical disc.

The present invention relates to an optical recording system for reading information signals stored on an optical disc, the system comprising: means for generating a light beam; an optical beam splitter for partially transferring the light beam to the optical disc; means for focusing the transmitted light beam on the optical disc and for converging the light beam reflected from the optical disc on the optical beam splitter capable of partially reflecting an incident light beam; and means for detecting a light beam incident thereon.

Such a system is known from "Patent

Abstracts of Japan ", Vol. 14, No. 141 [P-1023] 1990 & JP02-006711.

Hereby a beam splitter is used which is provided with a pair of half mirrors and a reflection surface in between. The light beam reflected from a reflection plate must pass through one of the half mirrors in the beam splitter, which however decreases the total optical efficiency.

Furthermore, there is a need for a reduced size optical pick-up system with a relatively simple structure.

The invention overcomes the above drawback and now addresses this need. The optical recording system according to the invention is therefore characterized in that the optical recording system further comprises: an optical means for reflecting the light beam from the optical beam splitter to the detection member; wherein this optical member makes the incident 1007927 2 light beam astigmatic after reflection; and that the optical detecting member is disposed adjacent to the light beam generating means.

The invention will now be explained in more detail with reference to drawings 5 and the description hereinafter.

Fig. 1 is a schematic side view of a known optical head;

Fig. 2 shows a top view of the optical detection unit housed in the prior optical head shown in FIG. 1;

Fig. 3 shows a schematic side view of an optical recording system using an optical device according to the invention in a first preferred embodiment of the invention; and FIG. 4 shows a schematic side view of an optical pick-up system containing an optical device according to a second preferred embodiment of the invention.

One of the common problems in an optical information recording disc, for example a compact disc, is related to the occurrence of focusing errors and an astigmatic method has already been proposed to solve this problem.

In FIG. 1, a known optical pickup system 100 is shown using the astigmatic method described in U.S. Patent No. 4,023,033, entitled "Optical Focusing Device." The optical recording system 100 includes a light source 110, a beam splitter 130, an objective lens 140, an optical information recording disc 150, a cylindrical lens 160, and an optical detection unit 170. In the system 100, a light beam 112 emitted from the light source 110, for example, a laser diode, on a beam splitter 130 and is partially reflected by a reflecting surface 132 contained therein. The light beam, which is reflected by the reflection surface 132, is focused by the objective lens 140, which forms a focused light beam in a convergence point 154 on the recording surface 152 of the optical disc 150. The focused light beam 5, which is reflected by the optical disc 150 passes through the objective lens 140 and is partially transmitted by the beam splitter 130, rendered astigmatic by its passage through the cylindrical lens 160, and then falls on the optical detection unit 170.

Referring to Fig. 2, the optical detection unit 170 includes four photoelectric cells 171 to 174, a first and a second adder 176, 177 and a differential amplifier 178. For example, each of the photoelectric cells 171 generates an output in the form of 15 a light intensity measurement. Two outputs from two opposite corners of the photoelectric cells, for example 171, 174 are sent to the first adder 176, and two other outputs from the remaining two opposite corners of the photoelectric cells 172, 173 are sent to the second adder 177, respectively. from the first and second adder 176, 177 are then sent to the differential amplifier 178 which in turn will generate an associated focusing error by comparing the outputs from the first and second adder 176, 177, the focusing error simply being the difference of the two outputs from the pair is adders.

Since the image or shape 175 of the light beam falling on the photoelectric cells 171 to 174 is astigmatic, it changes with the relative position of the recording surface 152 of the optical disk 150 with respect to the convergence point 154 of the light beam. To detect the change in the image shape of the light beam, the cylindrical lens 160 is placed between the convergence point 154 and the optical detection unit 170 in such a way that the image shape of the light beam falling on the photoelectric cells 171 up to 174 becomes circular when the light beam is precisely focused (zero focusing error) on the recording surface 152, which exists as a "just focused" position 5 in the art. If the optical disc 150 is moved along an optical axis drawn between the properly focused position and the center of the objective lens 140, the focusing error signal becomes non-zero with a sign indicating the direction of movement of the recording surface 152 of the optical disk 150 indicates from the "just focused" position, thereby detecting the focusing error.

One of the major shortcomings of the optical recording system 100 described above lies in its large size, which is caused by the location of the optical detection unit 170. That is, the optical detection unit 170 is placed on a line formed by a center point of the reflection surface 132 and a focal point of the objective lens 140 at a distance between the center point of the reflection surface 132 and the center point of the light source 110, the line being perpendicular to the optical axis being formed by the center point of the light source 110 and the center point of the reflection surface 132, thereby making the overall dimensions of the optical pickup system 100 bulky.

Figures 3 and 4 show schematic side views of an optical pickup system 200 and 300 according to a first and second preferred embodiments of the invention, respectively.

Fig. 3 shows a schematic side view of an optical pick-up system 200 according to a first embodiment of the present invention, comprising a light source 210, for example a semiconductor laser or a laser diode for generating a light beam, a beam splitter 220 provided with a base 222 which is transparent to the light beam and a reflection surface 224 mounted on a top side of the base 222, an objective lens 230, an optical detection unit 260 and an optical member 250 provided with a reflection plate 252 and a cylindrical lens 254 attached to the top of the reflection plate 252, the cylindrical lens 254 comprising a convex and a flat surface.

The light source 210, the beam splitter 220 and the objective lens 230 are arranged such that the beam splitter 220 is located between the objective lens 230 and the light source 210, and a first optical axis representing a focal point of the objective lens 230 and the center of the light source passes through the center of the reflection surface 224 of the beam splitter 220 and also the reflection surface 224 of the beam splitter meets with a first predetermined angle, the first predetermined angle being preferably 45 degrees. The reflection plate 252 of the optical member 250 is arranged such that a second optical axis connecting the center of the reflection surface 224 and the center of the reflection plate 252 meets the reflection plate 252 at a second predetermined angle.

When the light beam emanating from the light source 210 falls on the beam splitter 220, the reflection surface 224 of the beam splitter 220 transmits part of the light beam towards the objective lens 230 and reflects the remaining part of the light beam, thereby remaining portion of the light beam 30 is rendered useless when reading information signals stored on a recording surface 242 of an optical disc 240, the light beam from the light source 210 being aligned along the first optical axis. The objective lens 230 focuses the portion of the light beam onto the recording surface 242 of the optical disk 240 after being transferred therethrough, the objective lens 1007927 being capable of being disposed between the beam splitter 220 and the optical disk 240.

Thereafter, the portion of the light beam reflected by the recording surface 242 of the optical disk 240 is first converged by the objective lens 230, then is reflected by the reflection surface 224 of the beam splitter 220 to the optical member 250. The light beam being reflected by the reflection surface 224 falls on the cylindrical lens 254, the cylindrical lens 254 making the light beam incident thereon astigmatic after being reflected therefrom, whereby the optical detecting unit 260 can detect a focusing error signal using the astigmatic method.

Since the reflection plate 252 is attached to the flat surface of the cylindrical lens 254, it is possible for the optical detection unit 260 to be located near the light source 210, which in turn will reduce the overall dimensions of the optical pickup system 200. The detection member may, for example, be placed in a focus of the focusing member.

The optical path of the light beam from the reflection surface 224 of the beam splitter 220 to the optical detection unit 260 becomes equal to the optical path 25 from the light source to the reflection surface 224 of the beam splitter 220. In the first preferred embodiment of the present invention it is preferable that the reflection plate 252 of the optical member 250 is designed so that there is an overall reflection of a light beam incident thereon, thereby increasing the optical efficiency of the optical pickup system 200.

In Fig. 4, the optical pick-up system 300 according to a second preferred embodiment of the invention comprises a light source 310, for example a semiconductor laser or laser diode for generating a 1007927 7 light beam comprising a P and an S polarized light component with a wavelength λ, a beam splitter 320 having a base 322 transparent to the light beam and a polarization layer 324 formed on the top of the base 322, a 330 λ wafer 330, an objective lens 340, an optical detection unit 370 and an optical member 360 including a graded index lens 362 and a reflection plate 364 attached to the graded index lens 362.

When in the system 300 an optical disk 350 is loaded onto a disk tray, the light beam emitted from the light source 310 enters the objective lens 340 after being transferred by a polarization layer 324 of the beam splitter 320, which is the P-polarized light component towards the plaat λ plate 330 transmits and reflects the S-polarized light component, rendering the S-polarized light component useless when reading information signals stored on a recording surface 20 352 of the optical disc 350, the light beam from the light source 310 is aligned along a first line connecting a central point of the light source 310 and a focal point of the objective lens 340, and the polarization layer 324 is inclined at a first preset angle 25 with respect to the first line. It is preferable that the predetermined angle is 45 degrees. The light source 310 is placed in a position opposite the optical disc 350 with respect to the objective lens 340. The P-polarized light component transmitted through the polarization layer 324 of the beam splitter 320 is focused on the recording surface 352 of the optical disc 350. via the ¾ λ plate 330 through the objective lens 340.

Thereafter, the P-polarized light beam reflected from the optical disk 350 is first converged by the objective lens 340, then 1007927 8 is transferred through the ¾ λ plate 330, and is thereafter converted into an S-polarized light beam. The S-polarized light beam converted from the P-polarized light beam will be reflected to the optical member 360 by the polarization layer 324 of the beam splitter 320. The converted S-polarized light beam enters the graded index lens 362 and then reflects the reflection plate 364. from the optical member 360, the converted S-polarized light beam 10 totally to the optical detecting unit 370 through the graded index lens 362, the graded index lens 362 making the light beam incident thereon astigmatic after being transmitted therethrough. The reflection plate 364 is placed opposite the beam splitter 320 with respect to the graded index lens 362. The graded index lens 362 is made of a light refractive material, the refractive index having a position dependent distribution to perform the same function as that of the cylindrical lens 254 shown in Fig. 3. It should be noted that the functions and structures of the optical detection unit 370 in the second embodiment of the invention are the same as those of the first embodiment of the invention.

Compared to the known optical recording system 100 shown in Figure 1, the optical recording systems 200, 300 of the invention have simpler structures. This is accomplished by accommodating an optical member 250 with a cylindrical lens 254 and a reflection plate 252 in the optical pick-up system 200 and an optical member 360 with a graduated index lens 362 and a reflection plate 364 in the optical pick-up system 300, the cylindrical lens 254 and the graded index lens 362 can make a light beam falling thereon astigmatic, and the reflection plates 252, 364 of the 35 optical pickups 250, 360 totally reflect the incident light beam to the optical detection units 1 007927 9 260, 370, respectively, resulting in the dimensions of the optical recording systems 200, 300 are reduced.

While the present invention has been described with respect to preferred embodiments, other modifications and variations are possible without exceeding the scope and scope of the invention set out in the following claims.

1007927

Claims (11)

An optical recording system for reading information signals stored on an optical disk, the system comprising: means for generating a light beam; 5 an optical beam splitter for partially transferring the light beam to the optical disc; means for focusing the transmitted light beam on the optical disk and for converging the light beam reflected from the optical disk on the optical beam splitter capable of partially reflecting an incident light beam; and means for detecting a light beam incident thereon; characterized in that the optical pick-up system 15 further comprises: an optical means for reflecting the light beam from the optical beam splitter to the detection member; wherein this optical member makes the incident light beam astigmatic after reflection; and in that the optical detection member is placed near the means for generating the light beam. 2. An optical pick-up system according to claim 1, characterized in that the optical reflecting member comprises a cylindrical lens for making the transmitted light beam astigmatic and a reflection plate for reflecting the light beam from the optical beam splitter to the detection member, wherein the cylindrical lens has a convex and flat surface. 3. Optical recording system according to claim 2, characterized in that the reflection plate is mounted on the flat surface of the cylindrical lens. Optical pick-up system according to any one of claims 1-3, characterized in that the optical beam splitter 1007927 is arranged to make an angle with a first predetermined angle with respect to a first optical axis formed by a central point of connecting the light beam generating means to a focus of the focusing member. Optical recording system according to claim 4, characterized in that the first predetermined angle is 45 degrees. 6. An optical pick-up system according to any one of claims 2-5, characterized in that the reflection plate of the optical reflecting member is arranged such that it forms an angle with a second predetermined angle with respect to a second optical axis formed by a center point of the reflection plate to a center point of the optical beam splitter. Optical pick-up system according to any one of claims 1-6, characterized in that the detection member is placed in a focus of the focusing member. Optical pick-up system according to any one of claims 1-7, characterized in that the distance of the optical path 20 between the central point of the light beam generating means and the central point of the optical beam splitter is equal to the distance of the optical path between the central point of the detector and the central point of the optical beam splitter. Optical recording system according to any one of claims 1 and 4-8, characterized in that the optical reflecting means comprises a graded index lens to make an incident light beam astigmatic and a reflection plate for reflecting an incident beam. Optical recording system according to any one of claims 1-9, characterized in that the optical recording system further comprises a Y λ plate for changing the polarization component of the continuous light beam, wherein λ is the wavelength of the light beam and wherein the Yi λ plate is placed between the focusing member and the optical beam splitter. 1007927 Optical recording system according to any one of claims 1-10, characterized in that the optical reflecting member comprises a reflecting surface for transmitting one of the polarization components of the light beam. 1007927