JP2003281768A - Optical head device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an optical head device which can suppress an undesired radiation level by suppressing a deformation in reducing the superimposed level of a high frequency component superimposed to driving current for a laser beam source. <P>SOLUTION: The driving circuit 7 of the optical head device has a high frequency superimposed circuit 8 including a high frequency superimposed IC 80 superimposing the high frequency component to the driving current, a resistor R<SB>aadj</SB>for fixing a superimposed level which controls the operation of the high frequency superimposed IC 80, and a resistor R<SB>fadj</SB>for fixing a frequency which controls the operation of the high frequency superimposed IC 80. Moreover, in the high frequency superimposed circuit 8, a fixation by the resistor R<SB>aadj</SB>for fixing a superimposed level is left as it is, and a capacitor C<SB>2</SB>for reducing the superimposed level for the reduction of the superimposed level of the high frequency component is electrically connected between a power source line and a ground. <P>COPYRIGHT: (C)2004,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical head device having a high frequency superimposing circuit for suppressing the influence of optical noise on a laser light source.

[0002]

2. Description of the Related Art An optical head device generally comprises a laser light source, an optical system for guiding the light emitted from the laser light source to an optical recording medium, and a monitor light receiving device for monitoring the laser light emitted from the laser light source. The drive circuit includes an element and a drive circuit that supplies a drive current to the laser light source. The drive circuit uses an automatic power control circuit (Automatic Power Co) based on the monitor output from the light receiving element for monitoring.
control circuit) automatically controls the level of the drive current supplied to the laser light source.

Further, as shown in FIG. 6, the drive circuit 7 is
A high frequency superimposing circuit 8 is provided for superimposing a high frequency component of several hundred MHz on the drive current to prevent the influence of optical noise caused by the returning light to the laser light source 2.

The high-frequency superimposing circuit 8 controls the operation of the high-frequency superimposing IC 80 for superimposing a high-frequency component on the drive current, and sets the superimposing level of the high-frequency component which the high-frequency superimposing IC 80 intends to superimpose. In order to set the frequency of the high frequency component to be superimposed by the high frequency superposition IC 80 by controlling the operation of the high frequency superposition IC 80 and the superposition level setting resistor _Raadj electrically connected to the superposition level setting terminal A _adj. Frequency setting terminal F
a frequency setting resistor R _{fad j} electrically connected to _adj ,
And a bypass capacitor C ₁ .

The high-frequency component superimposing operation in the high-frequency superimposing circuit 8 is performed by sucking in and discharging the current from the high-frequency superimposing IC 80. Regarding the sucking amount and the discharging amount, the superposition level setting resistor R is used. _aadj
Adjust by changing the resistance value of. Thereby, in the high frequency superimposing circuit 8, the superimposing level of the high frequency component can be changed between several mAp and hundreds of tens of mAp.

A power supply line 70 connected to the IC drive power supply V _CC , a drive current supply line 71 from the current supply terminal LD to the laser light source 2, a ground line 72 connected to the ground terminal GND, a monitor light receiving element 3 to a monitor terminal. Ferrite beads NF ₁ , NF ₂ , NF ₃ , and NF ₄ for preventing unwanted radiation are attached to the output line 73 extending to PD.

In the optical head device configured as described above, the higher the superposition level of the high frequency component superposed on the drive current, the less susceptible it is to the influence of optical noise. Radiation levels tend to be high. Therefore, efforts have been made to prevent the influence of optical noise caused by the returning light from the viewpoint of improving the laser light source 2 or designing the optical system 5.

[0008]

However, in the case of preventing the influence of optical noise caused by the returning light from the improvement of the laser light source 2 or the design of the optical system 5, the high frequency component superposed on the drive current. However, _if the resistance value of the resistance R _aadj for setting the superposition level is increased and the current _absorption amount and the discharge amount in the high frequency superposition IC 80 are set to be small, the offset currents of the suction amount and the discharge amount are offset. Cannot be ignored.
As a result, the balance between the suction amount and the discharge amount is lost and waveform distortion occurs, and even if the superimposing level of the high frequency component is reduced, the waveform distortion occurs as shown by the solid line L12 in FIG. 4B and FIG. However, there is a problem in that the higher harmonic component due to becomes larger and the level of unnecessary radiation becomes larger.

In view of the above problems, the object of the present invention is to
An object of the present invention is to provide an optical head device capable of suppressing the distortion when the superimposing level of the high frequency component superimposed on the drive current for the laser light source is reduced, and suppressing the level of unnecessary radiation.

[0010]

In order to solve the above problems, according to the present invention, a laser light source, a drive circuit for supplying a drive current to the laser light source, and an optical recording medium for emitting light emitted from the laser light source. And an optical system for guiding the high-frequency component to the drive current to prevent the influence of optical noise caused by the return light to the laser light source. The high frequency superposition circuit includes a high frequency superposition IC that superimposes the high frequency component on the drive current,
The operation of the high frequency superposition IC is controlled to control the high frequency superposition IC.
In the optical head device including a superimposing level setting circuit element that sets a superimposing level of the high frequency component to be superposed, the high frequency superimposing circuit further electrically connects a line extending from the high frequency superimposing IC to the laser light source. And a capacitor for reducing the superimposed level of the high-frequency component that is connected to each other to reduce the superimposed level.

In the present invention, the superposition level reducing capacitor is electrically connected, for example, between the line and the ground.

In the optical head device, the higher the superposition level of the high frequency component superposed on the drive current, the less susceptible it is to optical noise, but the level of unwanted radiation emitted from the high frequency superposition circuit tends to increase. Therefore, it is desired to reduce the influence of optical noise from the improvement of the laser light source or the design of the optical system to suppress the superposition level of the superposed high frequency component. In carrying out such an approach, according to the present invention, the setting by the circuit element for setting the superimposing level is left as it is, and the superimposing level reducing capacitor is electrically connected to the line extending from the high frequency superimposing IC to the laser light source. The reduction capacitor reduces the superposition level of high frequency components. Therefore, since the current suction amount and the current discharge amount in the high frequency superposition IC may be set to be relatively large, the influence of the offset current on the current suction amount and the current discharge amount does not occur. Therefore, since the balance between the suction amount and the discharge amount is not disturbed and the waveform distortion does not occur, the increase of the harmonic component due to the waveform distortion and the increase of the unnecessary radiation level due to the high frequency component occur. do not do. Therefore, even if the superimposing level of the high frequency component superposed on the drive current for the laser light source is reduced, the level of unwanted radiation can be suppressed to a low level.

[0013]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An example of an optical head device to which the present invention is applied will be described with reference to the drawings. The optical head device described below has the same basic configuration as that described with reference to FIG. 6, and therefore parts having common functions are denoted by the same reference numerals.

FIG. 1 is a schematic configuration diagram showing a basic configuration of an optical system of an optical head device to which the present invention is applied. FIG. 2 is a circuit diagram showing a main part of a drive circuit mounted on this optical head device. FIG. 3 is a graph showing the relationship between the resistance value of the superposition level setting resistor and the superposition level of the high frequency component superposed by the high frequency superposition IC in the high frequency superposition circuit configured in the drive circuit of FIG. 4 (A), (B)
Are harmonics generated when a high frequency is superimposed on a laser light source in an optical head device to which the present invention is applied, and harmonics generated when a high frequency is superimposed on a laser light source in a conventional optical head device with respect to an optical waveform. It is explanatory drawing which shows the result measured by the frequency analysis. Figure 5
Is a harmonic level generated when a high frequency is superimposed on a laser light source in the optical head device to which the present invention is applied, and a harmonic level generated when a high frequency is superimposed on a laser light source in a conventional optical head device. It is the graph which plotted the result measured by the frequency analysis with respect to an optical waveform.

An optical head device 1 shown in FIG. 1 is for reproducing a DVD or CD / CD-R or recording a CD-R, and includes a laser light source 2 for emitting laser light in a predetermined wavelength band. The monitor light receiving element 3 receives the monitor light emitted from the laser light source 2, and the signal detecting light receiving element 4 detects the signal from the return light from the optical recording medium 6.

On the optical path from the laser light source 2 to the optical recording medium 6, for example, a half mirror 51 for reflecting the laser light emitted from the laser light source 2 toward the optical recording medium 6, and this half mirror 51. An optical system 5 including a collimator lens 52 for collimating the reflected laser light into parallel light, and an objective lens 53 for converging the laser light collimated through the collimator lens 52 onto the recording surface of the optical recording medium 6. Are arranged.

The optical head device 1 thus constructed further has a drive circuit 7 whose main part is shown in FIG. 2. In the drive circuit 7, based on the monitor output from the monitor light receiving element 3. An automatic output control circuit (not shown) automatically controls the level of the drive current supplied to the laser light source 2.

Here, when the light emitted from the laser light source 2 returns to the emission end face of the laser light source 2 again, optical noise due to such return light is generated. For this reason,
The drive circuit 7 is configured with a high frequency superposition circuit 8 for superposing a high frequency component of several hundred MHz on the drive current to prevent the influence of optical noise caused by the return light to the laser light source 2.

The high frequency superimposing circuit 8 controls the operation of the high frequency superimposing IC 80 and the high frequency superimposing IC 80 for superimposing the high frequency component on the drive current, and sets the superimposing level of the high frequency component to be superposed by the high frequency superimposing IC 80. And a superposition level setting resistor R _aadj connected to the superposition level setting terminal A _adj and a frequency setting for controlling the operation of the high frequency superposition IC 80 to set the frequency of the high frequency component to be superposed by the high frequency superposition IC 80. A frequency setting resistor R _fadj connected to the terminal F _adj and a bypass capacitor C ₁ are provided.

A power supply line 70 connected to the IC driving power supply V _CC , a drive current supply line 71 from the current supply terminal LD to the laser light source 2, a ground line 72 connected to the ground terminal GND, a monitor light receiving element 3 to a monitor terminal. Ferrite beads NF ₁ , NF ₂ , NF ₃ , and NF ₄ for preventing unwanted radiation are attached to the output line 73 extending to PD.

In the high-frequency superimposing circuit 8 thus configured, the high-frequency component superimposing operation is performed by sucking in and discharging the current from the high-frequency superimposing IC 80.
The suction amount and the discharge amount are adjusted by changing the resistance value of the superposition level setting resistor _Raadj .

That is, as shown in FIG. 3, as the resistance value of the superposition level setting resistor R _aadj is increased, the current suction amount and the current discharge amount in the high frequency superposition IC 80 are reduced and the superposition current level is increased. Becoming smaller,
If the resistance value of the superposition level setting resistor R _aadj is reduced,
The amount of current sucked in and the amount of current discharged from the high frequency superposition IC 80 increase, and the superposition current level increases. Thereby, in the high frequency superimposing circuit 8, the superimposing level of the high frequency component can be changed between several mAp and hundreds of tens of mAp.

In the optical head device 1 thus constructed, the high-frequency superimposing circuit 8 is less susceptible to optical noise as the superimposing level of the high-frequency component superposed on the drive current is higher, but it is emitted from the laser light source 2. The level of unwanted radiation tends to increase. Therefore, in the present embodiment, while improving the laser light source 2 or reducing the influence of optical noise from the design side of the optical system 5, the following configuration is adopted to suppress the superimposing level of the superposed high frequency component to a low level. is there.

That is, in this embodiment, the high-frequency superimposition IC is set while the setting by the superimposing level setting circuit element is left as it is.
The superimposing level reducing capacitor C ₂ is electrically connected between the drive current supply line 71 electrically connected to the superimposing line 75 extending from the laser light source 2 to the ground, and the superimposing level reducing capacitor C _2. By C ₂ ,
The superposition level of high frequency components is reduced. Here, since the superimposing level reducing capacitor C ₂ has a low impedance at high frequencies, it is possible to reduce the level of high frequency components, and it is possible to correct it to the required superimposing level by changing its capacitance value appropriately. .

Therefore, in the optical head device 1 of the present embodiment, the high frequency superimposing IC 80 can keep the current suction amount and the current discharge amount set relatively large.
The influence of the offset current on the suction amount and the discharge amount is not exerted.

Therefore, since the balance between the suction amount and the discharge amount is not disturbed and the waveform distortion does not occur, the harmonic component caused by the waveform distortion does not increase. That is, in the conventional optical head device, FIG.
As shown by the solid line L12, the level of harmonics generated when a high frequency is superposed on the laser light source 2 is considerably high,
In the optical head device of this embodiment, as shown by the solid line L11 in FIG. 4A and FIG. 5, the level of harmonics generated when a high frequency is superimposed on the laser light source 2 is considerably low.

Therefore, in the optical head device 1 of the present embodiment, even if the superimposing level of the high frequency component superposed on the drive current for the laser light source 2 is reduced, the level of the unnecessary radiation due to the harmonic component can be suppressed to a low level. it can.

[0028]

As described above, in the optical head device according to the present invention, the superimposing level reducing capacitor is electrically connected to the line extending from the high frequency superimposing IC to the laser light source while the setting by the superimposing level setting circuit element is left unchanged. The connection level is reduced, and the superposition level of the high frequency component is reduced by the superposition level reducing capacitor. Therefore, since the current suction amount and the current discharge amount in the high frequency superposition IC may be set to be relatively large, the influence of the offset current on the current suction amount and the current discharge amount does not occur. Therefore,
Since the balance between the suction amount and the discharge amount is not disturbed and the waveform distortion does not occur, the increase of the harmonic component due to the waveform distortion and the increase of the unnecessary radiation level due to the high frequency component do not occur. Therefore, even if the superimposing level of the high frequency component superposed on the drive current for the laser light source is reduced, the level of unwanted radiation can be suppressed to a low level.

[Brief description of drawings]

FIG. 1 is a schematic configuration diagram showing a basic configuration of an optical system of an optical head device to which the present invention is applied.

FIG. 2 is a circuit diagram showing a main part of a drive circuit mounted on an optical head device to which the present invention is applied.

3 is a graph showing a relationship between a resistance value of a resistance for setting a superposition level and a superposition level of a high frequency component superposed by a high frequency superposition IC in the high frequency superposition circuit configured in the drive circuit of FIG.

4A and 4B are harmonics generated when a high frequency is superposed on a laser light source in an optical head device to which the present invention is applied, and a high frequency is superposed on a laser light source in a conventional optical head device. It is explanatory drawing which shows the result of having measured the harmonic generated in the case of performing the frequency analysis with respect to an optical waveform.

FIG. 5 shows a harmonic level generated when a high frequency is superimposed on a laser light source in an optical head device to which the present invention is applied, and a harmonic level generated when a high frequency is superimposed on a laser light source in a conventional optical head device. It is the graph which plotted the result which measured the level by the frequency analysis with respect to an optical waveform.

FIG. 6 is a circuit diagram showing a main part of a drive circuit mounted on a conventional optical head device.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 Optical head device 2 Laser light source 3 Monitor light receiving element 4 Signal detecting light receiving element 5 Optical system 6 Optical recording medium 7 Drive circuit 8 High frequency superimposing circuit 71 Drive current supply line 75 Superimposing line 80 High frequency superimposing IC C ₁ Bypass capacitor C _{2 Superposed} level reduction capacitor R _{aadj Superposed} level setting resistor ( _Superposed level setting circuit element) R _fadj Frequency setting resistor

Claims (2)

[Claims] 1. A laser light source, a drive circuit that supplies a drive current to the laser light source, and an optical system that guides the light emitted from the laser light source to an optical recording medium. A high frequency superimposing circuit for superimposing a high frequency component on the current to prevent the influence of optical noise caused by the return light to the laser light source, the high frequency superimposing circuit for superimposing the high frequency component on the drive current An optical head device comprising: a superposition IC and a superposition level setting circuit element for controlling an operation of the high frequency superposition IC to set a superposition level of the high frequency component to be superposed by the high frequency superposition IC. The circuit is further electrically connected to a line extending from the high frequency superposition IC to the laser light source to reduce the superposition level of the high frequency component. An optical head device comprising a capacitor. 2. The optical head device according to claim 1, wherein the superposition level reducing capacitor is connected between the line and the ground.