NL1006255C2 - Optical pick-up device. - Google Patents

Description

Title: "Optical pick-up device"

Background of the invention

The present invention relates to an optical recording device, and more particularly to an optical recording device capable of using disc format recording media of different format compatible.

An optical recording device to be used in a digital video disc player (DVDP) capable of recording and displaying high density information must be capable of recording and reproducing on not only a digital video disc (DVD) but also a recording medium of the CD family such as a compact disk (CD), CD-R (recordable), CD-I, CD-G etc. to achieve compatibility.

However, while the standardized thickness of the existing CD family is 1.2 mm, the standardized thickness of the DVD is 0.6 mm due to an allowable disc inclination error, the numerical aperture of an objective lens, etc. Therefore, when an optical recorder for recording a DVD information recorded on a CD and reproducing it, spherical aberrations are generated due to a difference in thickness. A sufficient light intensity required for recording an information signal cannot be obtained because of the spherical aberrations, or a signal deterioration may occur during reproduction.

Also, optical sources for reproducing a DVD and a CD have different wavelengths, the wavelength of the existing optical reproducing source for a CD being about 780 nm and that for a DVD being about 650 nm.

A conventional compatible optical pickup device capable of recording and reproducing 1006255 2 information on disks of different formats as described above includes a single optical source for emitting short wavelength light of about 650 nm suitable for the DVD format, and has an improved structure that can compensate for differences in the thicknesses of the disks used, so that disks of different sizes can be used interchangeably in a device using such a compatible optical recording device.

In this case, a decrease in intensity of about 5% is generated compared to an optical pick-up device using an optical source for emitting light with a wavelength of 780 nm, but being within the allowable error range for 15 display, such a problem is not serious.

However, when the CD-R is used as one of the CD family, a difference in sensitivity is generated when an optical source for emitting light with a wavelength of 650 nm is used, compared to using an optical source for emitting light with a wavelength of 780 nm. That is, since the CD-R has an organic dye film recording layer, the difference in reflectivity is significantly dependent on the wavelength of the light, as shown in Fig. 1. Therefore, when light of wavelength of about 650 nm is used , the reflectivity decreases to less than 10%, making signal display impossible.

To overcome the above problem, as shown in Fig. 2, a conventional compatible optical pick-up device is designed with a first optical source 21 for emitting light with a wavelength of 635 nm and a second optical source 31 for emitting light with a wavelength of 780 nm. The first optical source 21 serves for a relatively thin disc 10a such as 1006255 3 the DVD and the second optical source 31 serves for a relatively thick disc 10b such as the CD.

Light emitted from the first optical source 21 is reflected by a polarization-5 beam splitter 23, passes through an interference filter 33, a λ / 4 delay plate 11 and a hologram 13, and is focused on a disk 10 by means of an objective lens 15 The interference filter 33 reflects light emitted from the second optical source 31 10 to the disk 10 and passes the light reflected from the disk 10.

Since the light emitted from the first optical source 21 has a larger diameter than the diffraction pattern formed at the center of the hologram 13, this light is not diffracted even after passing through the hologram 13, ie 0th-order diffracted light, and is focused on a relatively thin disc 10a. In contrast, the light emitted from the second optical source 31 is diffracted to 1st order light by a diffraction pattern as the light passes through the hologram 13 and is focused on the relatively thick disc 10b.

The compatible optical recording device can use the CD-R as a recording medium using two optical sources. However, the hologram on which the diffraction pattern is formed is contained such that assembly and optical arrangement are difficult. Since an optical detector is used, an accurate arrangement of the optical axes emitted from the two optical sources is also necessary.

Summary of the invention

To overcome the aforementioned problems, it is an object of the present invention to provide a compatible optical pickup device of simple construction capable of using discs of different sizes compatible.

1006255 4

To accomplish the aforementioned purposes, a compatible optical pickup device is provided, comprising: a first optical source for emitting light of a predetermined wavelength; a second optical source for emitting light with a wavelength different from that of the light emitted from the first optical source; an objective lens for focusing light emitted from the first and second optical sources, respectively, on a recording medium; means for changing a light path arranged in a light path between the first and second optical sources, and the objective lens for changing the incident path of the incident light; a first optical detector for receiving light emitted from the first optical source and incident through the recording medium and the light path changing means; and a second optical detector for receiving light emitted from the second optical source and incident through the recording medium and the means for changing the light path.

The light path changing means includes: a first beam splitter disposed in a light path between the first optical source and the objective lens for reflecting light emitted from the first optical source to the recording medium and passing light that is reflected by the recording medium to the first optical detector; a second beam splitter disposed in a light path between the first beam splitter and the objective lens for reflecting light emitted from the second optical source to the recording medium and passing light reflected by the recording medium; and a third beam splitter disposed in a light path between the first and second beam splitters to reflect light emitted from the second optical source, 1006255 is reflected by the recording medium and passes through the second beam splitter to the second optical detector.

According to another aspect of the present invention, the means for changing the light path include: a first beam splitter disposed in a light path between the first optical source and the objective lens for reflecting light emitted from the first optical source the recording medium and passing light reflected from the recording medium to the first optical detector; a second beam splitter disposed in a light path between the first beam splitter and the objective lens for reflecting light 15 emitted to the second optical source to the recording medium and passing light reflected by the recording medium; and a third beam splitter disposed in a light path between the objective lens and the second beam splitter for passing light emitted from the first and second optical sources to the recording medium, passing light emitted from the first optical source and is reflected by the recording medium, and reflecting light emitted from the optical source and reflected by the recording medium to the second optical detector.

According to yet another aspect of the present invention, the means for changing the light path include: a first beam splitter disposed in a light path between the first optical source and the objective lens for passing light emitted from the first optical source to the recording medium and reflecting light reflected from the recording medium to the first optical detector; a second beam splitter disposed in the light path between the second optical source 1006255 6 and the objective lens for reflecting light emitted from the second optical source and passing light reflected from the recording medium to the second optical detector; and a third beam splitter disposed in a light path between the first beam splitter and the objective lens for reflecting light emitted from the second optical source and reflected by the second beam splitter to the recording medium, and reflecting light which is reflected from the recording medium to the second beam splitter.

According to yet another aspect of the present invention, the first optical source and the first optical detector are arranged side by side to form a first module.

Brief description of the drawings

The above objects and advantages of the present invention will become apparent by describing in detail a preferred embodiment thereof with reference to the attached drawings, in which: FIG. 1 is a graph showing the reflectivity according to the wavelength of an optical source when a CD-R is used as the recording medium; Fig. 2 is a schematic diagram showing the optical arrangement of a conventional compatible optical pickup device; Fig. 3 is a schematic diagram showing the optical arrangement of a compatible optical pickup device according to a first embodiment of the present invention; Fig. 4 is a schematic diagram showing the optical arrangement of a compatible optical pickup device according to a second embodiment of the present invention; Fig. 5 is a schematic diagram showing the optical arrangement of a compatible optical recording device according to a third embodiment of the present invention; Fig. 6 is a schematic diagram showing the optical arrangement of a compatible optical pickup device according to a fourth embodiment of the present invention; and FIG. 7 is a schematic sectional view of an embodiment of a first module used in FIG. 6.

Detailed description of the invention

As shown in Fig. 3, a compatible optical pickup device according to a first embodiment of the present invention includes first and second optical sources 51 and 61 for generating and emitting laser light, first, second and third beam splitters 53, 63 and 65 as means for changing the light path and arranged in the light path for changing the incident path of the incident light, an objective lens 41 for focusing light 20 emitted from the optical sources 51 and 61 on a recording medium 10, and first and second optical detectors 57 and 69 for receiving light reflected from the recording medium 10 and detecting an information signal and an error signal.

The first optical source 51 generates and emits light of about 650 nm, which can record and display information on a relatively thin disc 10a such as a DVD, DVD-ROM, etc. The second optical source 61 generates and emits light from about 780 nm which can record and display information on a relatively thick disc 10b such as a disc of the CD family, in particular a CD-R.

The first and second optical sources 51 and 61 are arranged in different light paths, one of which is selectively driven according to the nature of the recording medium 10. Here, the driving mechanism 1006255 of the first and second optical sources 51 and 61 is a manual method, wherein a user selects an optical source suitable for the type of recording medium used 10 or an automatic method wherein an optical source is selected by a separate detector (not shown) for detecting the nature of the recording medium 10 in the player loaded. Since the above-described drive mechanisms are widely known, a detailed description thereof will be omitted.

The objective lens 41 focuses light emitted from the first and second optical sources 51 and 61 to form an optical spot on the recording medium 10. The objective lens 41 is driven by a driving device (not shown) which is driven depending on a focal point. error signal and a track error signal.

The first and second optical detectors 57 and 69 each receive light emitted from the first and second optical sources 51 and 61, respectively, and incident through the recording medium 10 and the first, second and third beam splitters 53, 63 and 65. The first and second second optical detectors 57 and 69 include at least two plates (not shown) for receiving incident light and generating electrical signals corresponding to the amount of light. The electrical signal outputs from the first and second optical detectors 57 and 69 are amplified differentially and / or summing and used to detect the information signal, the track error signal and the focus error signal.

The first beam splitter 53 is arranged in a light path between the first optical source 51 and the objective lens 41, reflecting light emitted from the first optical source 51 to the recording medium 10 and passing light reflected by the recording medium 10 to the first 100δ25 & 9 optical detector 57. The first beam splitter 53 passes part of the incident light at a predetermined ratio and reflects the rest. It is preferable that the first beam splitter 53 is flat, as shown in the drawing, but it may also have a cubic shape obtained by combining two triangles. Here, the arrangement of the first optical source and the first optical detector can be controlled according to the cubic type structure.

The second beam splitter 63 is arranged in a light path between the first beam splitter 53 and the objective lens 41, and reflects light emitted from the second optical source 61 onto the recording medium 10 and passes light reflected therethrough through the recording medium 10.

Also, the third beam splitter 65 is arranged in a light path between the first and second beam splitters 53 and 63 and changes the path of the light so that light passing through the second beam splitter 63 after it is emitted from the second optical source 61 and reflected by the recording medium 10, goes to the second optical detector 69. Each of the first, second and third beam splitters 53, 63 and 65 can be coated so that light in a predetermined wavelength range can selectively pass through or be reflected therefrom.

Here, the second and third beam splitters 63 and 65 can be flat or cubic. In case the second and third beam splitters 63 and 65 are flat, no astigmatism due to the inclination of the two beam splitters 63 and 65 should occur when light emitted from the first optical source 51 therethrough is going. Thus, as shown, the second and third beam splitters 63 and 65 make an angle in opposite directions to each other so that they can compensate for each other's astigmatism. Preferably, there is a difference of 90 ° 1006255 in inclination between the second and third beam splitters 63 and 65.

A collimation lens 45 may further be contained in a light path between the objective lens 41 and the second beam-5 splitter 63. Since the first optical source 51 is placed in the focus of the collimation lens 45, the light emitted from the first optical source and passes through the collimation lens 45 in parallel. In contrast, since the second optical source is disposed at a position different from the focal point of the collimation lens 45, that is, a shorter position than the focal length, light (A) is emitted from the second optical source 61 and passes through the collimation lens 45 diverged as light almost equal to the parallel light. As described above, the divergence of the light from the second optical source 61 by the collimation lens 45 serves to generate spherical aberrations according to a difference in thickness between the recording medium 10 and the wavelength of an optical source used when the oblation flange 41 is constructed to prevent a relatively thin disc 10a.

The light emitted from the first optical source 51 and passing through the collimation lens 45 and the objective lens 41 is focused on a relatively thin recording medium 10a. The light emitted from the second optical source 61 and passing through the collimation lens 45 and the objective lens 41 is focused on a relatively thick recording medium 10b.

Furthermore, a first sensor lens 55 may be included in a light path between the first beam splitter 53 and the first optical detector 57 so that the focus of the light incident on the first optical detector 57 can be controlled. The first sensor lens 55 allows the optical arrangement of the first optical detector 57. Also, the curvature of the first sensor lens 55 is controlled so that the horizontal focal position of 1006 255 11 light passing through the first sensor lens 55 may differ from its vertical focal position, causing astigmatism. Therefore, the first optical detector 57 can detect the focal error signal in an astigmatic manner.

The second sensor lens 67 may further be contained in a light path between the third beam splitter 65 and the second optical detector 69. The configuration and function of the second sensor lens 67 are essentially the same as that of the first sensor lens 55.

A compatible optical pickup device according to a second embodiment of the present invention is shown in Fig. 4. Here, the reference numerals indicate the same elements as in Fig. 3. With reference to Fig. 4, a second beam splitter 163 is present in a light path between the first beam splitter 53 and the objective lens 41 and reflects the light emitted from the second optical source 61 to the recording medium 10 and passes light incident 20 from the recording medium 10.

A third beam splitter 165 is arranged in a light path between the objective lens 41 and the second beam splitter 163 and passes light incident from the first and second optical sources 51 and 62 and reflects the light emitted from the second optical source 61 and reflected through the recording medium 10 to the second optical detector 69.

Here, it is preferred that the second and third beam splitters 163 and 165 be cubic as shown in Fig. 4 so that the shape of the light emitted from the second optical source 61 cannot be distorted by astigmatism.

A compatible optical pickup device according to a third embodiment of the present invention is shown in Fig. 5. Here, the same elements are represented by the same reference numerals. According to the 1006255 12 characteristics of the present embodiment, a third beam splitter 65 is arranged in a light path between the first beam splitter 53 and the objective lens 41 and reflects light emitted from the second second optical source 61 to the recording medium 10 and reflects light incident. from the recording medium 10.

The second beam splitter 63 is arranged in a light path between the second optical source 61 and the third beam splitter 65 and passes light incident from the third beam splitter 65 to the second optical detector 69.

It is preferred here that the first, second and third beam splitters 53, 63 and 65 be flat as shown in Fig. 5. Here, the inclination of the first beam splitter 53 is opposite to that of the third beam splitter 65. Also, the first optical source 51 arranged to align in a straight line with the first beam splitter 53, the third beam splitter 65, the objective lens 41 and the recording medium 10.

The first, second and third beam splitters 53, 63 and 65 can be cubic or flat, as already mentioned above.

As shown in Fig. 6, a compatible optical pickup device according to a fourth embodiment of the present invention includes first and second optical modules 70 and 80 for emitting light of different wavelengths and receiving light reflected from the recording medium simultaneously. , an objective lens 41 for focusing light emitted from the first and second optical modules 70 and 80 on the recording surface of the recording medium 10, and a light path changing means such as a beam splitter 47 arranged in a light path to change the incident path of the incident light. The same reference numerals as already mentioned 1006255 13 in the previous drawings represent the same elements.

According to the characteristics of the present embodiment, an optical source and an optical detector are assembled into an optical module. In this case, there is no need to install the first beam splitter 53 (see FIG. 3) and the third beam splitter 65. Therefore, since only one beam splitter 47 is included as a light path changing means, the configuration 10 of an optical system can be easily formed and the efficiency of light utilization can be increased.

The first optical module 70 or the second optical module 80 may consist of an optical source and an optical detector as described with reference to Figures 3-5.

The first optical module 70, which can be used when the beam splitter 47 has a cubic type structure, will be described with reference to Fig. 7. As shown in Fig. 7, the first optical module 70 includes a substrate 71, on which a first optical source 151 and a first optical detector 157 are provided, a housing 72 which covers the first optical source 151 and the first optical detector 157 and has an emission window 73, and a hologram 74 which is provided in the emission window 73.

When the optical source 151 is a round-emitting laser, the first optical source 151 is connected to the substrate 71 by means of a holder 75. Also, the first optical module includes a plurality of leads 76 passing through the substrate 71 are mounted to drive the first optical source 151 and the first optical detector 157.

The hologram 74 allows light to pass straight from the first optical source 151 to the recording medium 10 of FIG. 6 and to pass the light reflected from the recording medium 10 to the first optical detector 157 with diffraction.

1 0 0 6 2 55 14

The configuration of the second optical module 80 of Fig. 6 is the same as that of the first optical module 70 except that a second optical source (not shown) and a second optical detector each for emitting and detecting light of different wavelengths from the first optical source 151 and the first optical detector 157 are included.

When the beam splitter 47 is in the form of an angled flat plate, a hologram 74 of the first and second optical modules 70 and 80 is arranged obliquely across a light path so that its inclination is opposite to that of the beam splitter 47. Therefore, distortion of the light from the first optical source 51 incident on the recording medium 10 is prevented. A compatible optical pickup device according to the present invention includes first and second optical sources for emitting light of different wavelengths, and can use discs of different thickness in a compatible manner by selectively driving one of the optical sources of the nature of the recording medium used, and may prevent destruction of data recorded during playback of information recorded on a disc of the CD family, in particular a CD-R having an organic liquid recording layer thereon. Also, the selective use of two optical sources improves the life of the optical pickup device, and the use of two optical detectors facilitates the optical arrangement of each component part.

1006255

Claims (13)

A compatible optical pickup device comprising: a first optical source for emitting light of a first predetermined wavelength; a second optical source for emitting light 5 with a second predetermined wavelength different from that of the first predetermined wavelength; an objective lens for focusing light emitted from the respective first and second optical sources on disc-type first and second recording media, respectively; means for changing the light path arranged in light paths between the first and second optical sources and the objective lens for changing the path of the incident light emitted by the first and second optical sources; a first optical detector for receiving light emitted from the first optical source and incident through the first disc-shaped recording medium and the means for changing the light path; and a second optical detector for receiving light emitted from the second optical source and incident through the second disc-shaped recording medium and the means for changing the light path; characterized in that the means for changing the light path comprise first to third beam splitters arranged in the light paths between the first optical source and the objective lens and between the second optical source and the objective lens, in order to directing the first optical source and from the second optical source to the objective lens so that it is transmitted to a corresponding copy of the first and second disc-type recording media, and to transmit the light from the first optical source passing through the objective lens to the first optical detector and to direct the light from the 1 0 06255 second optical source passing through the objective lens to the second optical detector, and that at least two of the first through third beam splitters are arranged together at a linear path and at least one of those at least two beam splitters is turned away from the other of those at least two beam splitters in an opposite direction to a plane perpendicular to an optical axis of the objective lens to neutralize astigmatism between each other. Optical pickup device according to claim 1, characterized in that the first beam splitter is arranged in a first light path between the first optical source and the objective lens 15 for reflecting light emitted from the first optical source to the first recording medium of the disc type and transmitting the light from the first optical source reflected from the first disc type recording medium to the first optical detector; the second beam splitter is arranged in a second light path between the first beam splitter and the objective lens, for reflecting light emitted from the second optical source to the second disc-type recording medium and transmitting the light from the second optical source reflected from the second disc type recording medium, and the third beam splitter is arranged in a third light path between the first and second beam splitters to reflect light emitted from the second optical source, is reflected by the second disc-type recording medium, and passes through the second beam splitter to the second optical detector. Optical pick-up device according to claim 2, characterized in that a collimator lens is provided for changing diverging light incident on the light paths "0 06255; between the first and second optical sources, the objective lens is in parallel light or near parallel light. Optical pickup device according to claim 3, characterized in that the second optical source is located within the focal length of the collimator lens to diverge light emitted from the second optical source and passing through the collimator lens by a predetermined angle. Optical pickup device according to claim 2, characterized in that a first sensor lens is further provided for adjusting the focal point of light incident on a forward light path of at least the first or the second optical detector. An optical pickup device according to claim 1, characterized in that the first beam splitter is arranged in a light path between the first optical source and the objective lens for reflecting light emitted from the first optical source to the recording medium and transmitting it. 20 light from the first optical source reflected from the first disc-type recording medium to the first optical detector; the second beam splitter is arranged in a second light path between the first beam splitter and the objective lens, for reflecting light emitted from the second optical source to the second disc-type recording medium and transmitting light from the second optical source reflected from the second disc-type recording medium; and the third beam splitter is arranged in a third light path between the objective lens and the second beam splitter to pass light emitted from the first and second optical sources to the corresponding disc-type first and second recording media, and passing light emitted by the first optical source and reflected by the first </ -V · N - rrr, disc-type recording medium, and reflecting light emitted by the second optical source and reflected by the second disc-type recording medium to the second optical detector. Optical pick-up device according to claim 6, characterized in that a collimator lens is provided for changing diverging light incident on the light paths between the first and second optical sources and the objective lens into parallel light or light which is almost parallel. Optical pickup device according to claim 7, characterized in that the second optical source is located within the focal length of the collimator lens such that light emitted from the second optical source and passing through the collimator lens is divergent. Optical pickup device according to claim 6, characterized in that a first sensor lens is provided for adjusting the focus of the light incident on a forward light path of at least the first or the second optical detector. An optical pickup device according to claim 1, characterized in that the first beam splitter is arranged in a first light path between the first optical source and the objective lens 25 for passing light emitted from the first optical source to the first recording medium of the disc type and reflecting light from the first optical source reflected from the first disc type recording medium to the first optical detector; the second beam splitter is arranged in a second light path between the second optical source and the objective lens, for reflecting light emitted from the second optical source and passing light from the second optical source reflected by the second V ·. The disc-type recording medium to the second optical detector; and the third beam splitter is arranged in a third light path between the first beam splitter and the objective lens 5 to reflect light emitted from the second optical source and reflected by the second beam splitter to the second disc-type recording medium, and reflecting light from the second optical source reflected from the second disc-type recording medium to the second beam splitter. Optical pick-up device according to claim 10, characterized in that a collimator lens is provided for changing diverging light incident on the light paths between the first and second optical sources and the objective lens in parallel light or light which is almost parallel. 12. The optical pickup device according to claim 11, characterized in that the second optical source is within the focal length of the collimator lens so that light emitted from the second optical source and passing through the collimator lens is divergent. Optical pick-up device according to claim 10, characterized in that a first sensor lens is provided for adjusting the focal point of light incident on a forward light path of at least the first or the second optical detector. - <V · \. ·