JPH0593066U - Laser modulation circuit - Google Patents

Abstract

(57) [Abstract] [Purpose] To provide a stable laser modulation circuit that does not require a timing signal generator for sample and hold, has a simple control system design. A photovoltage converter 2 for converting the light output from the laser diode 8 into a voltage, a peak / envelope detector 3 for envelope detecting the peak portion of the output voltage waveform from the photovoltage converter 2, and a photovoltage. A bottom envelope detector 4 that envelope-detects the bottom portion of the output voltage waveform from the converter 2, a first current source 5 that outputs a current based on the peak envelope detection output, and a current based on the bottom envelope detection output. A second current source 6 which is sucked from the first current source 5 and whose suction operation and stop of the operation are controlled based on the modulation data. The output current from the first current source 5 and the second current source 6 The combined current with the suction current is supplied to the laser diode 8.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to a laser modulation circuit for recording information on a magneto-optical disc and an optical disc.

[0002]

[Prior Art]

 In the laser modulation circuit, weak light emission and strong light emission are alternately switched based on the data, so that the conventional laser modulation circuit uses the photocurrent converter 1 composed of the light emission monitor diode as shown in FIG. The converted light-current conversion output is converted into a voltage by the current-voltage converter 2, and the sample-hold circuits 10 and 11 respectively perform sample-holding during strong light emission and weak light-emission, respectively. A signal for controlling the light emission output at the time of light emission is used, and the output currents from the current sources 51 and 61 are controlled to control the current flowing to the laser diode 8.

[0003]

[Problems to be solved by the device]

 However, the conventional laser modulation circuit described above requires the timing signal generator 9 for outputting timing signals for sampling and holding, which causes a problem that the number of parts increases. Furthermore, in the method of passing a current in addition to the current from the current source during weak light emission during strong light emission, the control voltage for monitoring the amount of light emission changes significantly during strong light emission and during weak light emission. Due to the characteristics of the laser diode, the amount of current supplied is less than the amount of current supplied during weak light emission, which makes the system unstable, making it difficult to design the control system.

An object of the present invention is to provide a stable laser modulation circuit that does not require a timing signal generator for sampling and holding, has a simple control system design.

[0005]

Means for Solving the Problems A laser modulation circuit according to the present invention includes an opto-voltage converter that receives light from a laser and converts it into a voltage, and an envelope detection of a peak portion of an output voltage waveform from the opto-voltage converter. Peak envelope detector, a bottom envelope detector that envelope-detects the bottom part of the output voltage waveform from the photovoltage converter, a first current source that outputs a current based on the peak envelope detection output, and a bottom envelope detector. A current based on the envelope detection output is absorbed from the first current source, and a second current source whose suction operation and stop of operation are controlled based on the modulation data is provided. It is characterized in that a combined current with a sink current from two current sources is supplied to the laser.

The laser is a laser diode, the first current source includes a maximum current limiting circuit, and the second current source makes the sinkable current larger than the limiting current by the maximum current limiting circuit of the first current source. Good.

[0007]

[Action]

 According to the laser modulation circuit of the present invention, the light emitted from the laser is converted into a voltage, the peak portion of the converted voltage waveform is envelope-detected by the peak envelope detector, and the bottom portion of the converted voltage waveform is detected. Is envelope-detected by the bottom envelope detector. A current based on the peak envelope detection output is output from the first current source, and a current based on the bottom envelope detection output is drawn from the second current source from the output current of the first current source. The suction operation and the stop of the operation are controlled based on the modulation data. A combined current of the output current from the first current source and the output current from the second current source is supplied to the laser, and the laser is controlled to emit strong light and weak light based on the modulation data.

In this case, since the output current of the second current source is selectively absorbed from the output current of the first current source based on the modulation data, it is unstable even if the ratio of strong light emission to weak light emission is large. And the design of the control system becomes easier.

[0009]

【Example】

 Hereinafter, the present invention will be described with reference to examples. FIG. 1 is a block diagram showing the configuration of an embodiment of the present invention.

The light emitted from the laser diode 8 is received by the photocurrent converter 1 composed of a high-speed type PIN diode as a light emission monitor diode, and converted into a current proportional to the amount of emitted light. The output current of the photocurrent converter 1 is supplied to the current-voltage converter 2 and converted into a voltage.

The output voltage from the current-voltage converter 2 is applied to the peak envelope detector 3 and the bottom envelope detector 4, and the peak envelope detector 3 outputs the output voltage from the current-voltage converter 2. The peak part of the envelope of the output voltage waveform is envelope-detected to detect the amount of light emitted from the laser diode 8, and the bottom envelope detector 4 uses the envelope of the bottom part of the envelope of the output voltage waveform from the current-voltage converter 2. The light is detected and the light amount of the laser diode 8 is detected.

The output signal from the peak envelope detector 3 is supplied to the current source 5, and the output current from the current source 5 is changed in inverse proportion to the output signal level from the peak envelope detector 3. The current flowing through the laser diode 8 is changed. The current source 5 is further provided with a current limiter so that the maximum supply current is limited to a predetermined value.

The output signal from the bottom envelope detector 4 is supplied to the current source 6, and the output current from the current source 5 is changed in direct proportion to the output signal level from the bottom envelope detector 3 to generate a current. The source 6 sinks the output current from the current source 5. Further, the modulation data is supplied to the current source 6, and the suction operation of the current source 6 is selectively performed based on the modulation data. That is, when the modulation data has a high potential, the suction operation is stopped, and when the modulation data has a low potential, the current suction operation is performed to perform the suction control. Here, strong and weak light emission are associated with each other based on the modulation data. In this example, when the modulation data has a high potential, it is associated with strong light emission, and when the modulation data has a low potential, it is associated with weak light emission.

Therefore, when the laser diode 8 emits weak light, the current from the current source 5 is absorbed into the current source 6 based on the output signal from the bottom envelope detector 4, and the current from the current source 5 is absorbed. The current flowing to the laser diode 8 is controlled to be sucked in to reduce the current to the laser diode 8. Here, the current sink capability of the current source 6 is set to be larger than the maximum supply current of the current source 5.

In the present embodiment configured as described above, light is emitted when a current flows through the laser diode 8, and this light emission is received by the photocurrent converter 1 and converted into a current based on the amount of emitted light. The output current from the converter 1 is converted into a voltage by the current-voltage converter 2, and the current-voltage converter 2 outputs a voltage proportional to the amount of light emitted from the laser diode 8.

The output voltage from the current-voltage converter 2 is applied to the peak envelope detector 3 and the bottom envelope detector 4. An output that follows the peak value of the output voltage waveform of the current-voltage converter 2 is sent from the peak envelope detector 3 to the current source 5 as a control signal, and the bottom envelope detector 4 outputs the current-voltage converter. An output that follows the bottom value of the output voltage waveform of 2 is sent to the current source 6 as a control signal.

On the other hand, the modulation data is applied to the current source 6. When the modulation data remains at a low potential, the laser diode 8 continues to emit light weakly, and the level of the output signal of the peak envelope detector 3 and the level of the output signal of the bottom envelope detector 4 are changed. Are equal to each other, the output current of the current source 5 is sucked into the current source 6, and the current source 5 continues to flow the maximum supply current I ₁ max until the output current limit is reached due to insufficient light intensity.

Since the current source 6 changes the current I ₂ that is absorbed in direct proportion to the output level of the bottom envelope detector 4, when the amount of light emitted from the laser diode 8 increases, the current I ₂ also increases and flows into the laser diode 8. The current (I ₁ max-I ₂ ) is reduced, and a feedback loop is formed that acts to reduce the amount of light emission.

When the modulated data remains at a high potential, the level of the output signal of the peak envelope detector 3 and the level of the output signal of the bottom envelope detector 4 become equal. However, since the suction operation of the current source 6 is stopped, the current flowing through the laser diode 8 is only the supply current I ₁ from the current source 5. As the amount of light emitted from the laser diode 8 increases, the level of the output signal of the peak envelope detector 3 rises.

Since the current source 5 is set so as to change the supply current I ₁ in inverse proportion to the output signal level from the peak envelope detector 3, when the laser diode 8 emits more light, the peak envelope is increased. The output signal level of the detector 3 rises, and the current I ₁ is reduced in accordance with this rise. For this reason, the current flowing in the laser diode 8 is reduced, and a feedback loop is formed so as to reduce the amount of light emission.

Therefore, the light emission of the laser diode 8 is controlled based on the modulation data. That is, when the modulated data has a high potential, the current is not absorbed by the current source 6, the output current I ₁ of the current source 5 is supplied to the laser diode 8, and the laser diode 8 emits strong light. As the amount of emitted light increases, the output level of the peak envelope detector 3 increases, so that the output current from the current source 5 decreases and the amount of emitted light decreases, and when the amount of emitted light decreases, the amount of emitted light increases. The light emission is controlled so that a predetermined amount of strong light is emitted.

When the modulation data has a low potential, the output current I of the current source 5 is applied to the laser diode 8. ₁ To the output current I of the current source 6₂The current (I₁-I₂) Is supplied, the laser diode 8 emits weak light. As the amount of emitted light increases, the output level of the bottom envelope detector 4 increases, so that the output current from the current source 6 increases and the amount of emitted light decreases, and when the amount of emitted light decreases, the bottom envelope is increased. The output level of the detector 4 is decreased, the output current from the current source 6 is decreased, and the light emission amount is controlled to be increased, so that weak light emission of a predetermined light amount is controlled.

Next, a specific circuit of the above-described embodiment will be described. FIG. 2 shows a concrete circuit diagram. The photodiode PD constitutes the photocurrent converter 1, and the transistor pair Q1 constituting the current mirror circuit having the resistor R1 as a load constitutes the current-voltage converter 2 for converting the current of the photodiode PD into a voltage. is there. A peak envelope detector 3 is constituted by the transistor Q6 and the transistor Q7 which receive the output of the current-voltage converter 2, and a bottom envelope detector 4 is constituted by the transistor Q2 and the transistor Q3 which receive the output of the current-voltage converter 2. Is configured.

The current source 5 that receives the detection output of the peak envelope detector 3 by the transistor Q9 is configured, and the current source 6 that receives the detection output of the peak envelope detector 3 and the modulation data is formed by the transistors Q4, Q5, and Q8. Configured.

A current source is supplied to the laser diode 8 via a slow starter circuit 12 for performing a re-slow start from the transistor Q10 and a laser lighting control circuit 13 for controlling lighting of the laser diode 8 by a low active signal LDON which is composed of a transistor Q11. It is configured so as to supply a combined current of the output current of 5 and the output current of the current source 6. This concrete circuit is obtained by adding a slow start circuit 12 and a laser lighting control circuit 13 to the block diagram shown in FIG. 1, and its operation is similar to that of the circuit shown in FIG.

Here, the ratio of the light output of the strong light emission and the light output of the weak light emission is about 10 to 1 as shown in the light output of the laser diode 8 and the forward current characteristic of FIG. Even if it is changed to 1, it will be about 10 to 1, and the voltage will change greatly, but since the current source has two configurations, the sending side and the suction side, there is no instability and the control system The design of is no longer difficult.

[0027]

[Effect of the device]

 As described above, according to the present invention, the light emitted from the laser is converted into a voltage, the peak part of the converted voltage waveform is envelope-detected, the bottom part of the converted voltage waveform is envelope-detected, and the peak is generated from the first current source.・ The current based on the envelope detection output is output, the current based on the bottom envelope detection output is absorbed from the output current of the first current source from the second current source, and this absorption operation and stop of operation are based on the modulation data. Control is performed by supplying the combined current of the output current from the first current source and the output current from the second current source to the laser, so that the laser controls strong emission and weak emission based on the modulation data. In, the output current of the second current source is selectively absorbed from the output current of the first current source based on the modulation data, and the ratio of strong light emission to weak light emission is Hear no operation may be unstable even if there is an effect that it becomes easy to further control system design.

Furthermore, there is an effect that a timing signal generator for sampling and holding, which is conventionally required, is not required, the number of parts is small, and the circuit configuration is simple.

[Brief description of drawings]

FIG. 1 is a block diagram showing the configuration of an embodiment of the present invention.

FIG. 2 is a specific circuit diagram showing the configuration of an embodiment of the present invention.

FIG. 3 is a characteristic diagram of a laser diode.

FIG. 4 is a block diagram showing a configuration of a conventional example.

[Explanation of symbols]

 1 Photocurrent Converter 2 Current-Current Converter 3 Peak Envelope Detector 4 Bottom Envelope Detector 5 and 6 Current Source 8 Laser Diode

Claims (3)

[Scope of utility model registration request] 1. A photovoltage converter for receiving light from a laser and converting it into a voltage, a peak / envelope detector for envelope detection of a peak portion of an output voltage waveform from the photovoltage converter, and a photovoltage converter. The bottom envelope detector that envelope-detects the bottom portion of the output voltage waveform from, the first current source that outputs the current based on the peak envelope detection output, and the current based on the bottom envelope detection output from the first current source. A second current source in which suction and suction operation and stop of operation are controlled based on the modulation data, and a combined current of the output current from the first current source and the suction current from the second current source is supplied to the laser. Laser modulation circuit characterized by supplying. 2. The laser modulation circuit according to claim 1, wherein the laser is a laser diode. 3. The first current source is a current source that includes a maximum current limiting circuit and outputs a current that is inversely proportional to the output of the peak envelope detector, and the second current source supplies a sinkable current to the first current source. The laser modulation circuit according to claim 1, wherein the current is set to be larger than the current limit by the maximum current limit circuit.