JPS62120641A - Optical head device - Google Patents

Abstract

PURPOSE:To make exact writing/reading out of information to and from an information recording medium by providing a reflected light attenuating means to a diffraction grating and attenuating the incident reflected light on a semiconductor laser light source so that the semiconductor laser light source is used at the substantially low state of a noise level regardless of the variance in the quantity of the return light. CONSTITUTION:The reflected light attenuating means 10 is provided to the diffraction grating. More specifically, the reflected light attenuating means 10 is formed by vapor depositing and coating of a thin film 10a for attenuation of the quantity of light on the laser diode side surface of the diffraction grating 2. The thin film 10a is formed by using a vapor deposited metallic film such as, for example, aluminum and vapor deposited dielectric film, etc. The substantial reduction of the quantity of the reflected light to be fed back to the semiconductor laser light source down to the level at which the noise level is made approximately the tolerance limits or below is thereby made possible and as a result, the S/N ratio of the laser light outputted from the semiconductor laser light source is improved. The writing of the information to the information recording medium such as optical disk and reading out of the information therefrom are thus exactly executed.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to an optical head device, and particularly to an improvement in a device for writing/reading information to/from an information recording carrier using a laser beam.

[Prior Art] Conventionally, an optical head device is used for recording/recording of optical disc production.
It is widely used as a playback head, and is used, for example, to irradiate the information writing section of an optical disk with a semiconductor laser output from a light source using a condensing lens system to write or read information on the optical disk. There is.

FIG. 5 shows a general configuration of such an optical head device, in which a laser beam (100) outputted from a laser diode (1) is used to write/write information by a diffraction grating (2). The light beam is diffracted into a total of three light beams: a main light beam for reading and a pair of auxiliary light beams used as a tracking sensor. After passing through the beam splitter (3), each of these light beams is focused by a condensing lens system (4) onto a bit (6) of an optical disk (5) serving as an information recording carrier. At this time, the laser beam (
100) has three focused spots (200a) and (200
b), (200c).

The right frame in Figure 4 shows the laser beam (10
The irradiation position of 0) is shown enlarged, and a track (7) consisting of a bit string formed on an optical disk (5) is shown.
In contrast, the three light-condensing spora h (200a), (20
The line connecting 0b) and (200c) is irradiated with a slight inclination.

Here, the central focused spot (200b) is used for writing/reading signals, and the spora l'' (200b) on both sides
00a) and (200c) are used as racking sensors for the track (7) of the laser beam (100).

Then, the laser beam (10
0) enters the beam splitter (3) via the condenser lens system (4). Here, a part of this reflected light (100) is sent to the photodetector (8) by the beam splitter (3).
The remaining reflected light is directly transmitted to the laser diode (1) via this beam splitter (3).
The direction toward is incident again.

At the bottom right of FIG. 4, an enlarged view of the reflected light (100) incident on the photodetector (8) is shown.
0) is the three focused spots (200a), (
200b), (200c), there are also three condensing sporares (300a), (300C),
! l: ShiT is incident on the light detection 1 (8).

The photodetector (8) detects each of these focused spots (300a)
, <300b), (300c), respectively.
), and as is well known, the central light receiving section (9b) reads the information written on the optical disc (5), and the left and right light receiving sections (9a>, (9b) read the information written on the optical disc (5). The positional deviation between the center of the track (7) and the irradiation position of the laser beam (100) is detected.

[Problem 1 to be solved by the invention By the way, conventionally, in such optical head devices, a refractive index guide type laser diode (1) has often been used.

This is from the laser diode (1) to the optical disk (5)
This is because the focusing optical system for the laser beam (100) must operate with almost no aberration until the laser beam (100) reaches .

However, this refractive index guide type laser diode has smaller astigmatism and is suitable for better light focusing than the other type, the gain guide type laser diode. be.

However, this refractive index guided type laser diode (
1) has higher monochromaticity (coherency) of light than a gain guide type laser diode, so a part of the reflected light from the optical disk (5) is transmitted to the beam splitter (3).
), there is a problem in that a so-called return light inducing tube is generated when the light is fed back to the light emitting end face of the laser diode (1).

That is, as mentioned above, the laser beam (1, OO) reflected by the optical disc 5) passes through the condensing lens system (4), and a part of it is sent to the photodetector (8) by the beam splitter (5). While some of the light is reflected, the rest is returned as is to the light emitting end face of the laser diode (1) via the beam splitter (3) and the diffraction grating (2).

However, refractive index guided type laser diode (1)
In this case, even when there is a small amount of return light of about 0.1% of the irradiated laser light (100), return light induced noise occurs, and as a result, the noise from the laser diode (1) toward the optical disk (5) is generated. is the irradiated laser light (100)
The S/N ratio of the optical disc (5) has decreased, which has become a major problem in accurately reproducing information on the optical disc (5).

As a countermeasure against such problems, conventionally, the output laser beam (100) is attached to the end face of the laser diode (1).
An optical feedback method is known that actively returns several percent or more of light to reduce noise. According to this optical feedback method,
As the amount of returned light increases from 0%, the induced noise increases to o, 1
xPi! It exhibits good characteristics in that it once rises to a certain degree, but then falls again.

The present applicants have already proposed an optical head device using this principle (No. 59-71142).

However, when we examined the induced noise characteristics of the laser diode (1) in more detail, we found that even if the amount of returned light was increased, not all laser diodes necessarily exhibited good S/N characteristics. As shown, as the amount of returned light increases, a certain level of returned light Ma
The presence of a laser diode was confirmed as the noise level increased again and exceeded the allowable S/N ratio again.

Even with such a laser diode, if it is used in the return light amount region MA shown in FIG. 5, for example, the laser diode (1) can be used with the S/N ratio below the allowable limit.

However, the laser diodes that are generally put into practical use are
Variations in the spread angle of the output laser light (100),
Normally, the ratio of the amount of returned light varies by about 2 to 3 times due to variations in the transmittance of optical components, etc.
As mentioned above, in the commercially available optical head device, there is a problem in that it is extremely difficult to appropriately set the return claw in a region below the allowable noise level limit, such as the point Δ, for example.

The present invention has been made to solve this problem, and it is possible to use a semiconductor laser light source device at a sufficiently low noise level, regardless of the above-mentioned variation in the amount of returned light, and to apply it to an information recording carrier. An object of the present invention is to obtain an optical head device that can accurately write/read information.

Means for Solving Problem E] The optical head device according to the present invention irradiates a laser beam from a semiconductor laser light source device to an information recording carrier, and uses a condensing lens system to direct the laser beam toward the information recording carrier. Light is focused on the surface of the device and information is written/read out.

Here, a diffraction grating is provided between the semiconductor laser light source device and the condensing lens system, and the light beam condensed onto the surface of the information recording carrier by the condensing lens system is used to write/read information. The light is split into a focused spot for the camera and multiple spots for the tracking sensor.

By the way, in such an optical head device, as mentioned above, the laser beam focused on the information recording carrier is reflected and returned to the semiconductor laser light source device again via the condensing lens system and the diffraction grating, and the laser beam is Reduce S/N ratio.

A characteristic feature of the present invention is that, in order to prevent such a reduction in the S/N ratio of the laser beam, the diffraction grating is provided with a reflected light attenuation means to attenuate the reflected light incident on the semiconductor laser light source device. That's true.

[Function] With the above configuration, according to the present invention, the amount of reflected light returning to the semiconductor laser light source device is sufficiently attenuated by the reflected light attenuating means until the noise level becomes approximately below the allowable limit. As a result, the S/N ratio of the laser beam output from the semiconductor laser light source device is improved, and it becomes possible to accurately write and read information to and from an information recording carrier such as an optical disk.

[Example] Next, a preferred example of the present invention will be described based on the drawings. Incidentally, the same reference numerals are given to the members corresponding to the apparatus shown in FIGS. 4 and 5, and the explanation thereof will be omitted.

In this embodiment, the optical head device is formed almost in the same way as the conventional device, as shown in FIG. 4, and its characteristic feature is that the laser diode (1) is Reflected light attenuating means (1) for attenuating the returning reflected light
0) is provided on the diffraction grating (2).

FIG. 1 shows a preferred embodiment of such a reflected light attenuation means (10).

Generally, the diffraction grating (2) has a diffraction grating section (2a) formed on its condensing lens system side, and in this embodiment, the reflected light attenuation means (10) is a laser diode of this diffraction grating (2). The side surface is coated with an optical attenuation thin film (10a) by vapor deposition.

Such a thin film (10a) can be formed using a metal vapor deposited film such as G sialuminum, a dielectric vapor deposit film, or the like.

FIG. 2 shows another embodiment of the reflected light attenuation means (10), in which the thin film (10a
) is formed by coating the condenser lens system side.

FIG. 3 shows another embodiment of the reflected light attenuation means (10), which includes a diffraction grating (10).
2) It is formed using a bulk material that has a light attenuation function, such as N.
/D filter, colored glass material, etc. can be used.

In other words, the reflected light attenuating means (10) of the present invention may be of any type as long as it can attenuate the reflected light returning to the laser diode (1), and if necessary, a structure other than this may be adopted as appropriate. Needless to say, it is also possible to do so.

The optical head device of this embodiment has the above structure, and its operation will be explained next.

In this example, the transmittance of the reflected light attenuation means (10) is T (0<T<1), and the condenser lens system (4),
Assuming that the return light a of the reflected light reflected via the beam splitter (3) has a MB greater than the allowable noise level limit, as shown by 8 in FIG. In the optical head device, reflected light attenuation means (10
It is understood that the magnitude of the return light mm that is fed back to the laser diode (1) via ) is M x T, which is significantly smaller than MB.

Here, the reason why the return light ff1M is multiplied by d is because the laser light 100 output from the laser diode (1) passes through the reflected light attenuation means (10) twice in total, on the way there and on the way back. It is.

Therefore, the transmittance T of this reflected light attenuation means (10) is set to O~
For example, by arbitrarily selecting within the range of 1, the return light I
Even if M is too large and would normally greatly exceed the allowable limit of the S/N ratio, the present invention can significantly reduce this cluttered light ff1M. It is possible to always set the value as shown in the dot.

In order to further confirm the effects of the present invention, the applicants created a dielectric interference filter with a transmittance of T=0.6 on the surface of the diffraction grating (2) as shown in FIG. We conducted an experiment.

At this time, without the interference filter, the return light ff1M of the reflected light was about 8%, but when an interference filter was installed to reduce the return light ff1M to about 0.2%, the laser diode ( It was confirmed that the noise characteristics of 1) were significantly improved and the signal reproduction quality for the optical disc (5) was significantly improved.

Note that the method of controlling the return light amount M of the reflected light is also theoretically possible by adjusting the transmittance of the beam splitter (3). However, replacing the beam splitter (3) itself with one having a different transmittance requires the adjustment of the position of the photodetector (8) and other efforts, which is not practical.

On the other hand, according to the present invention, by simply replacing the diffraction grating (2), the return light f to the diode (1) is
It is possible to freely adjust aM, and as mentioned above, the handling is extremely simple compared to replacing the beam splitter (3) itself. That is understood.

Therefore, according to the present invention, if a plurality of diffraction gratings (2) provided with reflected light extinction means (10) having different transmittances T are prepared, even after the optical head device is assembled, By simply changing the diffraction grating (2), it becomes possible to easily set the return light ff1M to the laser diode (1) to an optimal value.

That is, if the return light ff1M to the optical head (1) is too large and the noise of the laser diode (1) is increasing, it can be easily fixed by replacing the diffraction grating (2) with a diffraction grating with a low transmittance T. Sea 11 diode (1)
The noise level can be reduced.

In this embodiment, for the sake of convenience, an optical head device for reading/loading information to/from an optical disc, such as a CD, on which data is recorded as information from pin 1 to 1 is explained as an example, but the present invention is not limited to this. Needless to say, the present invention is also effective for optical head devices for all types of optical disks, such as optical disks of other types, such as magneto-optical disks, phase change disks, etc.

[Effect of the Invention 1] As explained above, the present invention provides a reflection light attenuation means in the diffraction grating, and a semiconductor laser light source v through a condensing lens system.
By sufficiently suppressing the return light D of the laser light that is fed back to the device, the semiconductor laser light source device can be used with a sufficiently low noise level, and information can be written/read accurately on the information recording carrier. It becomes possible to do so.

[Brief explanation of drawings]

FIG. 1 is an explanatory diagram of the main parts of a preferred embodiment of the optical head device according to the present invention, FIGS. 2 and 3 are explanatory diagrams of the main parts of other embodiments of the present invention, and FIG. FIG. 5, an optical circuit diagram of the optical head device used in the example, is an explanatory diagram of the relationship between the return set and the noise level. In the figure, (1) is a laser diode, (2) is a diffraction grating, (4) is a condensing lens system, (5) is an optical disk, (
10) is a reflected light attenuation means, and (100) is a laser beam. In addition, the same members in each figure indicate the same or equivalent parts.

Claims (4)

[Claims] (1) A semiconductor laser light source device that outputs a laser beam for optically writing/reading information from an information recording carrier that optically holds information, and collecting the laser beam into an information section of the information recording carrier. A condensing lens system that emits light is provided between the semiconductor laser light source device and the condensing lens system, and the light beam condensed onto the information section by the condensing lens system is condensed for information writing/reading. In an optical head device that writes/reads information to/from an information recording carrier, the optical head device includes a spot and a diffraction grating that diffracts a laser beam to form a plurality of focused spots for a tracking sensor. An optical head device characterized in that the diffraction grating is provided with a reflected light attenuating means for attenuating the amount of returned reflected light that re-enters the semiconductor laser light source device via the condensing lens system. (2) The optical head device according to claim 1, wherein the reflected light attenuation means is formed using a light amount attenuation thin film coated on the light source side surface of the diffraction grating. (3) The optical head device is characterized in that the reflected light attenuating means is formed using a light amount attenuating thin film coated on a surface of the diffraction grating on the condensing lens system side. (4) The optical head device according to claim 1, wherein the reflected light attenuation means is formed by forming the diffraction grating itself using a bulk material having a light amount attenuation function.