KR0142293B1 - Prevent of overcurrent circuit for laser diode - Google Patents

Abstract

The present invention relates to an overcurrent protection circuit of a laser diode, and in particular, an I / V conversion means for converting an amount of current into a voltage when an overcurrent flows through the laser diode, and a switch for changing a current flowing through the laser diode to protect the laser diode. Means, and monitor means for informing a user that an overcurrent flows through the laser diode. Therefore, by detecting the instantaneous or continuous overcurrent flow of the laser diode to protect the laser diode, it has the effect of providing safety to all products using the laser diode.

Description

Overcurrent prevention circuit of laser diode

1 is a circuit diagram showing a current amount control device of a conventional laser diode;

2 is a circuit diagram showing an overcurrent prevention circuit of a laser diode according to the present invention.

* Explanation of symbols for main parts of the drawings

10: control unit 20: RF amplifier

25: APC part (Automatic Power Control) 30: LD drive part

40: switch part 50: I / V conversion part

60: monitor part

The present invention relates to an overcurrent protection circuit of a laser diode, and in particular, to prevent damage to the laser diode due to overcurrent and any other external shock situation of devices that read data from an optical disk using a laser diode. The present situation relates to an overcurrent protection circuit of a laser diode that can monitor the user that an overcurrent is flowing.

In general, all products of an optical disc use a laser diode (hereinafter referred to as LD) to inject a laser into a designated position of the disc, pick up the reflected light, and read the information on the disc. At this time, if the laser output fluctuates, there is a possibility that an error occurs when reading information. A conventional apparatus for obtaining a stable laser output is shown in FIG. 1 is a circuit diagram showing a current amount adjusting device of a conventional laser diode. The apparatus of FIG. 1 includes a controller 10 for generating a signal CTL _LD for driving a laser diode LD. The output terminal of the control unit 10 is connected to the RF amplifier 20 with the built-in APC unit 25 for constantly adjusting the laser output. The LD driver 30 is connected between the input terminal and the output terminal of the APC unit 25. In more detail, the LD driving unit 30 has a base B connected to the output terminal of the APC unit 25, a transistor driving power supply + V _CC is connected to the emitter E through the resistor R, A capacitor C ₁ is connected between the emitter E and the base B, and the collector C has a PNP transistor TR connected to the coil L. A diode D, a capacitor C ₂ , and a laser diode LD are connected in parallel between the collector C of the transistor TR and ground. In addition, the photodiode PD for monitoring the laser light generated from the laser diode LD is connected to an input terminal of the APC unit 25.

In FIG. 1, when the signal CTL _LD for driving the laser diode LD from the controller 10 is applied to the RF amplifier 20, the APC unit 25 embedded in the RF amplifier 20 is an LD driver. A signal of a predetermined level is applied to the base terminal so that the transistor TR of 30 is in an ON state. When the transistor TR of the LD driving unit 30 is turned on, the driving power + V _CC flows through the resistor R to the collector stage and through the noise removing coil L through the laser diode LD. ) Is entered. At this time, the laser diode LD emits laser light. The photodiode PD senses the amount of laser light emitted from the laser diode LD and applies a current amount corresponding to the detected amount of radiation to the APC unit 25. The APC unit 25 controls the current flowing through the transistor TR in response to the amount of current applied from the photodiode PD. Therefore, the amount of current flowing through the laser diode LD is adjusted. That is, if the current flowing through the laser diode LD is insufficient, the APC unit 25 adjusts the current flowing through the transistor TR so that a large amount of current flows through the laser diode LD. On the contrary, if a large amount of current flows through the laser diode LD, the amount of current is also reduced.

However, when there is insufficient current in the photodiode stage that detects the amount of divergence of the laser diode, when a large amount of current flows through the laser diode and exceeds the upper limit, that is, when an overcurrent flows, the laser diode itself becomes a fatal effect, which gradually changes the laser diode into a light emitting diode. In addition to the consequences, there is a problem in that the product cannot be operated by the electric damage and the pickup part must be replaced, and in the severe case, the entire deck must be replaced.

Accordingly, an object of the present invention is to detect such a situation in the early stage when overcurrent flows instantaneously or continuously in order to solve the above-mentioned problem, to protect the laser diode, and to recognize the situation to the user. The present invention provides an overcurrent preventing circuit of a laser diode that prevents electrical vapor loss.

An object of the present invention as described above is a circuit for preventing an overcurrent from flowing through a laser diode driving an optical disc, wherein a signal for driving the laser diode is applied to the APC means, and a voltage value applied from the I / V conversion section. APC for controlling the amount of current flowing through the laser diode in response to the control unit for determining the overcurrent flowing through the laser diode and generating a switch selection signal according to the laser diode driving signal and the amount of current applied from the switch unit. Means, a first switch connected to an output terminal of the APC means, and a second switch receiving a predetermined driving power are selectively connected to either of the two switches in response to a switch selection signal applied from the control unit. A third voltage applied to the input terminal of the APC means; And a fourth switch connected to the ground and the ground are selectively connected in response to the switch selection signal to selectively output a current applied from the LD driver, and flows through the laser diode according to the voltage applied from the switch. It is achieved by an LD driver which receives a current amount and generates a current amount corresponding to the laser light emitted from the laser diode, and an I / V converter that applies a voltage value corresponding to the current amount applied from the LD driver to the controller. .

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a circuit diagram showing an overcurrent prevention circuit of the laser diode according to the present invention. The apparatus of FIG. 2 has a signal CTL _LD for driving the laser diode LD, a switch selection signal SEL1 to SEL4, and a controller 10 for generating a monitoring signal. The output terminal of the control unit 10 is connected to the RF amplifier 20 incorporating the APC unit 25 for maintaining a constant output of the laser diode (LD). The other output terminals of the control unit 10 are connected to a switch unit 40 having a plurality of switches SW1 to SW4. The LD driver 30 is connected between the first and second switches SW1 and SW2 of the switch unit 40 and between the third and fourth switches SW3 and SW4. Detailed configuration description of the LD driving unit 30 is the same as in FIG. 1 and will be omitted. The negative input terminal of the operational amplifier OP-AMP is connected between the fourth switch SW4 of the switch unit 40 and the input terminal of the controller 10, and the predetermined reference voltage VR _EF is positive. An I / V converter 50 is connected to the positive input terminal and has a resistor R ₄ connected between the negative input terminal and the output terminal. Another output terminal of the controller 10 includes a monitor unit 60 to which a plurality of light emitting diodes LED1 and LED2 are connected.

In FIG. 2, when the signal CTL _LD for driving the laser diode LD is input from the control unit 10 to the RF amplifier 20, the APC unit 25 embedded in the RF amplifier 20 responds thereto. Thus, a voltage 0.5V lower than the emitter voltage of the transistor TR is applied to the base terminal in the LD driving unit 30 through the first switch SW1 of the switch unit 40. Then, the emitter current of the transistor TR flows to the collector stage. At this time, the second switch SW2 of the switch unit 40 is turned off. Transistor protection resistor (R ₂ ) is connected between emitter and driving power + V _CC input terminal, and PNP is connected between emitter and base to condenser (C ₁ ) to remove noise caused by instantaneous voltage application. When the type transistor TR is turned on, a current applied to the collector is applied to the laser diode LD through the coil L. At this time, the laser diode LD emits laser light. Here, the coil (L) is for low frequency noise removal, the diode (D) connected in parallel with the laser diode (LD) serves to block the flow of excitation power. The photodiode PD changes the reverse current according to the intensity of light emitted from the laser diode LD and applies the changed amount of current to the APC unit 25 through the third switch SW3, and at the same time, the I / V conversion unit. It is applied as negative input terminal of OP-AMP in (50). At this time, the fourth switch SW4 of the switch unit 40 is turned off. The APC unit 25 responds to the amount of current obtained from the photodiode PD and changes the base voltage of the transistor TR in the LD driving unit 30 to constantly adjust the current applied to the laser diode LD. On the other hand, the operational amplifier OP-AMP of the I / V converter 50 receives a predetermined reference voltage VR _EF as a positive (+) input terminal, and provides a resistance between the negative (-) input terminal and the output terminal. R ₄ ) is connected to convert the current into a voltage to output (V _O = -IR ₄ ). The output voltage V _O of the operational amplifier OP-AMP is input to an A / D converter (not shown) built in the control unit 10. The controller 10 may increase the analysis degree of the input signal according to the number of bits of the register in the A / D converter (not shown). That is, the more bits there are, the more accurate the measurement can be. For example, when the number of bits of the register is 8 bits (number of 256 cases), the controller 10 accepts about OV to 5V, so 5 [V] ÷ 256 = 0.0195 [V], the operational amplifier (OP-AMP). The controller 10 may detect a situation of a current flowing in the photodiode PD whenever the output voltage V ₀ of the output voltage V ₀ changes by about 0.02 [V]. If the voltage value applied from the operational amplifier OP-AMP is within a preset normal range, the controller 10 turns on the first light emitting diode LED1 of the monitor 60 to emit green light. To inform the user that the status is normal. However, when the voltage value applied from the operational amplifier OP-AMP is out of the normal range, that is, when overcurrent flows through the laser diode LD, the controller 10 may control the first and third switches SW1 of the switch unit 40. , The switch selection signals SEL1 to SEL4 are generated to turn SW3 off and to turn on the second and fourth switches SW2 and SW4. In addition, the second light emitting diode SEL2 of the monitor unit 60 is turned on to emit red light, thereby informing the user of an abnormal state. At this time, the LD driving unit 30 is not controlled by the APC unit 25 but instead is controlled by the driving power supply + V _CC and the resistance R ₁ . The driving power source + V _CC is sequentially applied to the base of the transistor TR by passing through the resistor R ₁ and the second switch SW2 to drive the transistor TR. In this case, the resistance R ₁ is adjusted so that the current flowing through the laser diode LD may flow in a normal case. In addition, in order to check the instantaneous abnormal state, the controller 10 turns on the first and third switches SW1 and SW3 of the switch unit 40 to operate in a normal APC loop to operate the operational amplifier ( Re-check the output voltage (V _O ) of OP-AMP) and continue the operation if it is normal. If it is determined that the abnormal state even at the time of rechecking, that is, if the overcurrent continuously flows through the laser diode LD, the fourth switch SW4 is turned on to flow the overcurrent through the resistor R ₃ . The control unit 10 also turns on the second light emitting diode LED2 of the monitor unit 60 to recognize an abnormal state by the user to stop driving the laser diode LD and to stop all operations. Such contents can be expressed as Table 1 below.

In this way, the overcurrent is prevented from continuously flowing through the laser diode, thereby preventing damage due to deterioration of the laser diode LD.

As described above, the present invention relates to an overcurrent protection circuit of a laser diode, which can prevent the situation of replacing the entire deck due to damage of the laser diode, which is the main cause of pickup failure in a practical screen, and also has a significant effect in terms of product protection. To provide.

Claims (5)

In a circuit for preventing an overcurrent from flowing through a laser diode driving an optical disc, a signal for driving the laser diode is applied to the APC means, and the overcurrent flows through the laser diode according to a voltage value applied from the I / V converter. A control unit for determining that the control unit generates the switch selection signal accordingly; APC means for controlling the amount of current flowing through the laser diode in response to the laser diode driving signal applied from the control portion and the amount of current applied from the switch portion; A first switch connected to an output terminal of the APC means and a second switch receiving a predetermined driving power are selectively connected to either of the two switches in response to a switch selection signal applied from the controller to apply a predetermined voltage to the LD driver. A switch unit configured to selectively output a current applied from the LD driver by any one of which is selectively connected to a third switch connected to an input terminal of the APC means and a fourth switch connected to ground in response to a switch selection signal; An LD driver for controlling the amount of current flowing through the laser diode according to the voltage applied from the switch unit and generating an amount of current corresponding to the laser light emitted from the laser diode; And an I / V converter for applying a voltage value corresponding to the amount of current applied from the LD driver to the controller. The overcurrent protection circuit of claim 1, further comprising a monitor configured to display whether or not the overcurrent flows from the laser diode determined by the controller. The overcurrent protection circuit of claim 1, wherein the LD driver comprises a photodiode for detecting a laser light emitted from the laser diode and generating a current corresponding thereto. According to claim 1, wherein the I / V converter is applied to the current input to the first input terminal, a predetermined reference voltage is applied to the second input terminal, is connected by connecting a resistor between the first input terminal and the output terminal An overcurrent prevention circuit of a laser diode, characterized in that the output amplifier is controlled by the output voltage according to the amount of current. The over-current protection circuit of a laser diode according to claim 2, wherein the monitor unit comprises a plurality of light emitting diodes emitting light of different colors.