JP2887277B2 - Laser diode control device and control method - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Table of Contents] Overview Industrial application field Conventional technology Problems to be solved by the invention Means for solving the problem (FIG. 1) Action Embodiment (FIGS. 2 to 5) EFFECT OF THE INVENTION [Overview] Regarding a laser diode control device and a control method, in controlling a laser diode used as a light source of an optical disk device or the like, when applying a high frequency superposition method, a high frequency superposition amount can be controlled to an optimum value. In a device that emits light by superimposing a high-frequency current on a drive current of a laser diode, a laser diode, a light emission amount monitoring unit, a laser diode driving unit, a high-frequency oscillator, an amplitude designation unit, -It is configured to provide an off switching unit.

In addition, the laser diode is driven in a state where the high frequency superimposition is stopped, the driving current is set so that the monitored amount reaches a predetermined level, and the laser diode is driven with a current value reduced by a predetermined value from the set value, and the high frequency superposition is performed. Is started and the amplitude of the high-frequency superimposition is adjusted up or down until the light emission amount returns to a predetermined value, so that the high-frequency superposition amount is optimally adjusted.

[Industrial applications]

The present invention relates to a laser diode control device and a control method, and more specifically, is used for controlling a laser diode such as a recording / reproducing light source in an optical disk device. The present invention relates to a laser diode control device and a control method capable of controlling a superimposition amount to an optimum value.

[Conventional technology]

Conventionally, a laser diode has been widely used, for example, as a recording / reproducing light source of an optical disk device.

It has also been known to control the output light of a laser diode on the optical disk to a predetermined level (for example, see Japanese Patent Application Laid-Open No. 63-133327).

In such a conventional laser diode, since noise is generated, the noise of the laser diode is reduced by applying a high frequency superposition method (for example, “Semiconductor laser and applied technology”, Kogakusha Published, pages 88-
See page 95).

[Problems to be solved by the invention]

The prior art as described above has the following disadvantages. That is, in the conventional optical disk device, the light amount is modulated in order to perform recording / reproduction, and when the high frequency superposition method is applied, if the superposition amount is too large, overpower occurs at the time of recording.

In such a case, the laser diode may be deteriorated due to the overpower.

Conversely, if the amount of superimposition is too small, the effect of the high frequency superposition method is lost.

The present invention solves such a conventional drawback, and enables the amount of high-frequency superposition to be controlled to an optimum value when a high-frequency superposition method is applied in controlling a laser diode used as a light source or the like of an optical disc device. The purpose is to:

[Means for solving the problem]

FIG. 1 is a diagram showing the principle of the present invention. Hereinafter, the principle of the present invention will be described with reference to FIG.

In the figure, 1 is a laser diode unit, 2 is a high-frequency oscillator, _CH is a capacitor (for blocking DC components), 9 is an amplitude designation section, 12 is a current-voltage conversion section, 13 is an on / off switching section, and 20 is a laser. A diode driving unit, 21 indicates an MPU (microprocessor), LD indicates a laser diode, and PD indicates a photodiode.

The laser diode unit 1 is a laser diode LD
And a photodiode PD for monitoring the amount of light emitted from the laser diode.

The current-voltage converter 12 converts the current from the photodiode PD into a voltage, sends the voltage to the MPU 21, monitors the amount of light emission, and sends the voltage to the laser diode driver 20.

The high-frequency oscillator 2 is for applying the high-frequency superposition method. When the laser diode LD is driven by the laser diode driving unit 20, the high-frequency current from the high-frequency oscillator 2 is applied to the current flowing through the laser diode LD. Superimpose.

The amplitude specifying section 9 specifies the amplitude of the output current of the high-frequency oscillator 2 based on the set value of the MPU 21.
The OFF switching unit 13 switches ON / OFF (switching between the oscillation state and the oscillation stop state) of the high-frequency oscillator 21 according to an instruction from the MPU 21.

When recording and reproducing data on the optical disk by driving the laser diode LD, the following is performed.

First, in response to an instruction from the MPU 21, the on / off switching unit 13
To turn off the high-frequency oscillator 2. In this state, the laser diode LD is driven by the laser diode driving unit 20.

In this case, while monitoring the amount of light emitted from the laser diode LD based on the current from the photodiode PD, the drive current of the laser diode LD is gradually increased so that the monitored amount becomes a predetermined value (for example, a reproduction level). Set the current flowing to LD (I _OFF ).

Next, a current lower than the set value (I _OFF ) by a predetermined value (for example, 3 mA) is set. At this time, although the monitored amount decreases, the high frequency oscillator 2 is turned on by the on / off switching unit 13 and the high frequency current is superimposed on the drive current of the laser diode LD.

This high frequency superimposition increases the high frequency superimposition amount so that the monitor amount again becomes a predetermined value (for example, a reproduction level).

[Action]

Since the present invention is configured as described above, the following operation is provided. That is, the present invention measures the laser diode drive current required to keep the light emission amount of the laser diode LD at a predetermined level in a state where the high-frequency superposition is stopped, and performs the laser operation with a current obtained by subtracting a predetermined value from the measured current value. In addition to driving the diode, the amplitude (current amplitude) of the high-frequency superposition is adjusted so that the light emission amount of the laser diode LD returns to a predetermined level when the high-frequency superposition is turned on.

This makes it possible to optimally adjust the amount of high-frequency superposition, and as a result, the laser diode LD does not deteriorate due to overpower, and noise can be reduced.

〔Example〕

 Hereinafter, embodiments of the present invention will be described with reference to the drawings.

FIG. 2 is a circuit diagram of an embodiment of the present invention, and the same reference numerals as those in FIG. 1 denote the same parts. In FIG, TR1～TR9 transistors, C _1, C _H a _{capacitor, R H, R 9 ~R 12} , R 58 ~
_{R 64, R 3 ~R 6,} R 15, R 69, R 70, R 1 is the resistance, SW switch, LD laser diode, PD photodiode, 3
1, 51, 61 are operational amplifiers, 53, 55 are analog switches,
L is a coil, 16 is an A / DC (analog / digital converter),
4, 7, 14, 18 are D / AC (digital / analog converter),
V _CC (12V), V _AA (10V), V _CT (5V), V _DD (5V), V _EE
(0V), V _CV is a power supply, 2 is a high frequency oscillator, 21 is an MPU (microprocessor).

1 is a laser diode unit, 9 is an amplitude designation unit, 13 is an on / off switching unit, 12 is a current-voltage conversion unit, 50 is a balance circuit, 5 is a read power level current adjustment unit, 3 is a read power level detector. , 6 denotes a write power level current adjustment unit, 8 denotes a write power level setting unit, 10 denotes a write power level current subtraction unit, 11 denotes a level shift unit, and 17 denotes a write power level current subtraction setting unit.

The laser diode unit 1 includes a laser diode LD and a photodiode PD for monitoring the amount of light emitted from the laser diode LD.

The read power level detector 3 includes an operational amplifier 31, a resistor
R _1, consists capacitor C _1, D / AC4, as the output power of the laser diode is a voltage of the photodiode illustrating a read power level, is set in advance from the MPU 21.

The read power level current adjuster 5 includes a transistor TR
1, a resistor R ₃ , a coil L and a laser diode LD
The drive current is adjusted so that the light emission at the read power level is performed. The coil L is for preventing interference between read and write, and is not always necessary.

Write power level current adjusting unit 6 is composed of two transistors TR2 and TR3, and resistor R ₄ Prefecture, adjusting the drive current to light emission of the light power level to be superimposed from the laser diode LD to the read power level is made . The transistors TR2 and TR3 are connected to perform a differential operation, and operate at high speed.

The D / AC 7 is set in advance from the MPU 21 so that the output power of the laser diode LD becomes the voltage of the photodiode PD indicating the write power level.

Write power level setting unit 8 is composed of a transistor TR4 resistor R ₅ Prefecture, so as to output a laser beam in response to the write power level is set to D / AC7, sets the write power level current setting section 6 .

Write power level current subtraction unit 10, two transistors TR6 connected in order to the high-speed operation and TR7, and a resistor R ₆ Prefecture, from the photodiode current superimposed write power level current to the read power level current Subtract the write power level current.

The level shift unit 11 adjusts the bias of the transistors TR2, TR3, TR6 and TR7 of the write power level current adjustment unit 6 and the write power level current subtraction unit 10 so that the write power level shifts according to the write data.

Current-to-voltage converter 12 includes a resistor R ₉ to R _13, the switch SW, is an operational amplifier 61 converts the current flowing through the photodiode PD into a voltage with a predetermined conversion ratio.

The D / AC 14 sets a value from the MPU 21 that determines the output value of the A / DC 16 to be a photodiode voltage value indicating the read power level.

Balancing circuit 50 comprises a resistor R ₅₈ to R ₆₁ and the operational amplifier 51.

Reference numeral 2 denotes a high-frequency oscillator for superimposing a high-frequency current on the laser diode LD, which is connected to the laser diode LD via a capacitor C _H (capacitor for blocking DC components).

The amplitude specifying unit 9 includes a transistor TR8 and a resistor _RH, and specifies an output amplitude of the high-frequency oscillator. In addition,
The off switching unit 13 is configured by a transistor TR9, and is controlled to be on / off by an instruction from the MPU 21. The above transistor TR8
Is controlled by the output of the D / AC 18 in accordance with an instruction from the MPU 21.

FIG. 3 shows the current of the laser diode due to the high frequency superposition.
FIG. 4 is a diagram showing optical output characteristics, and FIG. 4 is a diagram for explaining the operation of high-frequency superposition.

In each figure, the horizontal axis is the laser diode current (I).
The vertical axis indicates the optical output (P) of the laser diode.

I _OFF is a reproduction level current when the high frequency superimposition is stopped (off state), and I _ON is a reproduction level current when the high frequency superimposition (on state). When the amount of high-frequency superposition is increased while the high-frequency superposition is on, the optical output increases as shown by the curve, and when the amount of high-frequency superposition is reduced, the optical output decreases as shown by the curve.

FIGS. 5A and 5B are flowcharts of a laser diode control method according to an embodiment of the present invention, which will be described with reference to FIGS. 2 to 4. FIG.

First, the analog switch 53, when turned on by an instruction from the MPU 21 (SO), and the operational amplifier 31 and capacitor C ₁ is bypassed, the operational amplifier 31 becomes a voltage follower.

That is, the voltage applied to the non-inverting input terminal (+) of the operational amplifier 31 is directly applied to the transistor via the operational amplifier 31.
Apply to TR1.

Next, according to an instruction from the MPU 21, the analog switch 55
Turning off (S1), the output of the D / AC4 resistance network 57 (R ₆₂ ~
R ₆₄ ) is applied to the non-inverting input terminal of the operational amplifier 31 via the resistor R ₆₂ .

Subsequently, in response to an instruction from the MPU 21, the transistor TR9 is turned on (S2) to turn off the high-frequency superposition, and the data of the D / AC 4 is initialized (S3).

When DA / C4 applies the analog output voltage based on the read output data to the non-inverting input terminal of the operational amplifier 31 (S
4), the applied analog voltage is applied to the base of the transistor TR1.

Therefore, the transistor TR1 is driven by the analog output voltage from the D / AC 4, and the laser diode LD emits light at a power level corresponding to the analog output voltage.

The output light (P) of the laser diode LD is detected by the photodiode PD, and the detected value is converted into a digital amount by the A / DC 16 (S5) and given to the MPU 21.

The MPU 21 detects whether or not the detected value of the A / D-converted photodiode has reached the read power level (reproduction level) (S6).

If the detected value of the photodiode PD has not reached the read power level, the read data of D / AC4 is incremented by 1 (+
1) Then (S7), the above steps are repeated until the detected value of the photodiode reaches the read power level (repeated from S4).

When the detected value reaches the read power level (LD current
I _OFF ), DA / C18 is initialized (S8), and D / AC4 data is 3 mA
Set the LD current to I _ON with a considerable reduction (S9). Next, the transistor TR9 is turned off (S10), and the data of the DA / C18 is output and supplied to the transistor TR8.

As a result, a voltage is supplied to the high-frequency oscillator 2 from the emitter resistor _RH of the transistor TR8, and the high-frequency current from the high-frequency oscillator 2 is superimposed on the current of the laser diode LD (high-frequency superposition on).

The light emission amount of the laser diode LD in such a state is
In the same manner as described above, the voltage is detected by the photodiode PD, converted into a voltage by the current / voltage conversion unit 12, converted into digital data by the A / DC 16, and sent to the MPU 21.

The MPU 21 detects whether the detection data from the photodiode PD has reached a predetermined read power level (reproduction level) (S13), and if not, updates the data of the D / AC 18 (high-frequency output The amplitude is adjusted), and the above operation is repeated (repeated from S11).

When the data from the photodiode PD has reached the read power level (S13), the data of D / AC7 and D / AC14 are initialized (S14), and the write power level current adjustment unit 6
(S15). Output D / AC7 data (S1
6).

Thereafter, in the same manner as above, the read value of the photodiode PD is A / D converted (S17), and it is detected whether or not the detection data has reached the write power level (S18).

As a result, if the write power level has not been reached, D /
The data of AC7 is updated (S19), and the above operation is repeated (S1
Repeat from 6.)

When the read value from the photodiode PD reaches the write power level, the MPU 21 then subtracts the amount obtained by subtracting the superimposed write power level from the photodiode reading to D / AC
Update sequentially via 14.

The reading of the photodiode from which the write power level has been subtracted is converted to digital data by the A / DC 16, and the reading is repeated until the value returns to the read power level (S26).
~ S29).

In the repetition process, when the MPU 21 detects that the read power level has been reached (S28), the write power level current adjuster 6 is deactivated (S20).

The MPU 21 sets the output value of the D / AC4 to the read power level (S21), and drives the D / AC4. Further, the analog switch 55 is turned on (S22), and the non-inverting input terminal of the operational amplifier 31 is lowered to the _VCT level.

On the other hand, the analog switch 53 is turned off (S23), and the capacitor C1 connected in parallel with the operational amplifier 31 is enabled to automatically adjust the laser diode to the target read power.

〔The invention's effect〕

As described above, the present invention has the following effects. That is, when the high-frequency superposition method is applied to a laser diode used as a light source or the like of an optical disc device, the amount of high-frequency superposition can be adjusted optimally, and as a result, deterioration of the laser diode due to overpower is eliminated. .

Also, since the high frequency superposition method can be applied in an optimal state,
This has the effect of reducing the noise of the laser diode.

That is, since the control means monitors the light emission amount of the laser diode and adjusts the laser diode driving current so that the light emission amount of the laser diode is maintained at a predetermined level in a state where the high frequency superposition is stopped, the laser power At a predetermined level with high accuracy. Therefore, there is an effect that the deterioration of the laser diode due to overpower can be prevented and noise can be reduced.

[Brief description of the drawings]

FIG. 1 is a principle diagram of the present invention, FIG. 2 is a circuit diagram of an embodiment of the present invention, FIG. 3 is a diagram showing a current-light amount characteristic of a laser disk by high frequency superposition, and FIG. FIG. 5 is a view showing a flowchart of a laser disk control method in the embodiment of the present invention. 1 Laser diode unit LD Laser diode PD Photodiode 12 Current-voltage converter 20 Laser diode driver 2 High-frequency oscillator 9 Amplitude specifying unit 13 On / off switching unit 21 …… MPU (microprocessor)

Claims (2)

(57) [Claims] A laser diode driving unit that adjusts and drives a current flowing through the laser diode; and a high-frequency oscillator that superimposes a high-frequency current on the laser diode driving current. In a laser diode control device that superimposes a high-frequency current on a drive current and emits light, an amplitude specifying unit that adjusts an amplitude of a high-frequency superimposed current output from the high-frequency oscillator, and monitors a light emission amount of the laser diode, With the superimposition stopped, the laser diode drive current is adjusted so that the light emission amount of the laser diode is maintained at a predetermined level, and control is performed to drive the laser diode with a current obtained by subtracting a predetermined value from the adjusted current. When the high frequency superposition is turned on, the light emission amount of the laser diode is reduced to the predetermined level. Back to the laser diode control apparatus characterized in that a, and a control means for performing control for adjusting the amplitude of the high-frequency superposition of the amplitude designating unit. 2. A laser diode comprising: a laser diode; a laser diode driving unit for adjusting and driving a current flowing through the laser diode; and a high-frequency oscillator for superposing a high-frequency current on the laser diode driving current. In a laser diode control method of superimposing a high-frequency current on a drive current to emit light, the laser diode is driven in a state where the superposition of the high-frequency current is stopped, and the drive current of the laser diode is gradually increased while monitoring the light emission amount of the laser diode. The driving current is adjusted so that the monitored amount reaches a predetermined level, and the laser diode is driven with a current value reduced by a predetermined value from the adjusted driving current. In this state, the high frequency current is superimposed. Start until the light emission amount of the laser diode increases and returns to the predetermined level.
A laser diode control method characterized by adjusting the amplitude of high frequency superposition.