KR101017976B1 - Apparatus and method for adjusting power of laser diode in Visual Fault Locator - Google Patents

Abstract

An apparatus and method for controlling a laser diode output for a visible light detector for controlling the output of a laser diode by adjusting the duty ratio of the laser diode while maintaining the maximum output of the laser diode are provided. The present laser diode output control apparatus for a visible light detector includes an input unit for receiving an output setting value of a laser diode; And calculating the duty ratio based on the output setting value, calculating the normal mode driving time and the normal mode driving period of the laser diode according to the duty ratio, and calculating the laser diode based on the calculated normal mode driving time and the normal mode driving period. And a control unit for generating a control signal for driving. According to the present invention, the laser diode output control device and method for visible light detector by controlling the output ratio of the laser diode by controlling the duty ratio of the laser diode in a state in which a constant current is supplied and the laser diode is fixed at the maximum output It is possible to freely adjust the output adjustment range of the laser diode.

Laser diodes, LD, VFL, visible light detector, duty ratio

Description

Apparatus and method for adjusting power of laser diode in Visual Fault Locator}

The present invention relates to an apparatus and method for controlling a laser diode output for a visible light detector, and more particularly, for a visible light detector for controlling light output of a laser diode used in a visible light visual identifier for detecting an abnormal point of an optical cable. A laser diode output control apparatus and method.

In general, a visual visual fault locator (VFL) applies an optical signal (for example, visible light) generated from a laser diode to a target optical cable to measure an abnormal point of the optical cable (for example, It is a measuring device that makes it possible to identify light leaked from disconnection, bending, etc.) with the naked eye of an operator so that an abnormal point (for example, disconnection, bending, etc.) of an optical cable can be detected.

Since the optical signal (for example, visible light) applied to the cable from the visible light visual identifier is attenuated at a constant rate in the optical cable, the length of the optical cable that can be measured as the output of the optical signal (for example, visible light) generated from the laser diode is larger Increases.

However, since the visible light visual identifier of the related art is configured to operate in the infrared region of a glass optical fiber manufactured for optical communication, in the case of the visible light, a constant light is emitted even if the cable is normal. Then, when a high-power light source is applied to the cable, since the light flowing out from the short distance of the normal cable increases, it is difficult to identify an abnormal point (for example, disconnection, bending, etc.) of the cable. Incidentally, when a strong laser is directly exposed to the eyes of the user, there is a problem that a safety accident occurs that causes damage to the eye.

In addition, in the conventional visible light visual identifier, as the current applied to the laser diode used as the light source increases, power consumption increases, and durability of the laser diode due to heat generation decreases.

In order to solve the problem of the visible light visual identifier, a method of controlling an output of an optical signal (eg, visible light) by controlling a current applied to a laser diode according to a user input, and an optical signal (eg, visible) A method of controlling the final light output by applying an optical attenuator while keeping the output of the light beam constant.

However, the method of controlling the output of an optical signal (for example, visible light) by controlling the current applied to the laser diode, the light output (ie The minimum value of the visible light output) is determined by the specification of the laser diode used, and the value is also about 10% of the maximum output, and thus the output adjustment range is limited. There is this difficult problem.

The method of controlling the output of an optical signal (for example, visible light) using an optical attenuator requires high accuracy of the optical attenuator, thereby using a costly and bulky optical attenuator. There is a problem that it is difficult to miniaturize the visible light visual identifier.

In addition, the method of controlling the output of an optical signal (for example, visible light) through the optical attenuator, the laser diode is driven at the maximum output to increase the power consumed by the laser diode, and the durability of the laser diode due to heat generation There is a problem.

SUMMARY OF THE INVENTION The present invention has been proposed in view of the above-described conventional situation, and the laser diode output control for the visible light detector for controlling the output of the laser diode by controlling the duty ratio of the laser diode while maintaining the maximum output of the laser diode It is an object to provide an apparatus and method.

In order to achieve the above object, the laser diode output control device for a visible light detector according to a preferred embodiment of the present invention, the laser diode output control for a visible light detector for controlling the light output of the laser diode in the visible light detector An apparatus comprising: an input unit for receiving an output setting value of a laser diode; And calculating the duty ratio based on the output setting value inputted to the input unit, calculating the normal mode driving time and the normal mode driving period of the laser diode according to the duty ratio, and based on the calculated normal mode driving time and the normal mode driving period. To generate a control signal for driving the laser diode.

The controller determines the driving mode of the laser diode by comparing the calculated duty ratio and the mode setting reference duty ratio.

The controller determines the blink mode driving mode when the calculated duty ratio exceeds the mode setting reference duty ratio.

When the controller determines the blink driving mode, the controller generates a control signal for driving the laser diode according to the duty ratio calculated during the blink mode driving time for every blink mode driving cycle.

The driving period is a period in which the afterimage effect occurs when visually observed.

In order to achieve the above object, the laser diode output control method for a visible light detector according to a preferred embodiment of the present invention, in the method for controlling the light output of the laser diode in the visible light detector, the control unit, A duty ratio calculating step of calculating a duty ratio based on an output set value of the laser diode; A general mode driving information calculating step of the control unit calculating a normal mode driving time and a normal mode driving period according to the duty ratio calculated in the duty ratio calculating step; And a control step of the control unit generating a control signal for driving the laser diode based on the normal mode driving time and the normal mode driving period calculated in the normal mode driving information calculating step.

The controller may further include a driving mode determination step of determining the driving mode of the laser diode by comparing the calculated duty ratio and the mode setting reference duty ratio.

In the driving mode determination step, when the calculated duty ratio exceeds the mode setting reference duty ratio, the controller determines the blink mode driving mode.

In the control step, when the controller determines that the blink driving mode, the control signal for driving the laser diode according to the duty ratio calculated during the blink mode driving time is generated for every blink mode driving cycle.

The driving period is a period in which the afterimage effect occurs when visually observed.

According to the present invention, the laser diode output control device and method for the visible light detector is a constant current is supplied to solve the limitation of the output control range due to the threshold current in the conventional laser diode is fixed to the laser diode maximum output By controlling the duty ratio of the laser diode by adjusting the duty ratio, it is possible to output less than 10% of the maximum output power, and it is possible to freely adjust the output adjustment range of the laser diode and precisely adjust the output of the laser diode. Do.

In addition, the laser diode output control apparatus and method for the visible light detector detects the cost of producing the visible light visual identifier by controlling the output of the laser diode by adjusting the duty ratio without using an expensive and bulky optical attenuator. It is possible to minimize and miniaturize the visible light visual identifier.

In addition, the laser diode output control apparatus and method for the visible light detector to control the driving time of the laser diode based on the duty ratio, thereby minimizing the power consumed by the laser diode and to minimize the reduction of durability of the laser diode due to heat generation. Can be.

In addition, the laser diode output control apparatus and method for the visible light detector is controlled to operate in the blink mode when the duty ratio causing the heating problem of the laser diode is set, it is possible to minimize the damage caused by the heating of the laser diode.

Hereinafter, the most preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the technical idea of the present invention. . First, in adding reference numerals to components of each drawing, the same components have the same reference numerals as much as possible even though they are shown in different drawings. In addition, in describing the present invention, if it is determined that the detailed description of the related well-known configuration or function may obscure the gist of the present invention, the detailed description will be omitted.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings in order to help understanding of the present invention. The following examples are provided to more easily understand the present invention, and the present invention is not limited to these examples.

1 is a block diagram illustrating a laser diode output control device for a visible light detector according to an embodiment of the present invention, Figure 2 illustrates a laser diode output control device for a visible light detector according to an embodiment of the present invention. It is a figure for following.

As shown in FIG. 1, the laser diode output control apparatus for the visible light detector includes an input unit 100, a control unit 200, a laser diode driver 300, and a laser diode 400.

The input unit 100 receives an output setting value of the laser diode 400. That is, the input unit 100 receives the output setting value of the laser diode 400 which is the basis for setting the duty ratio of the laser diode 400. Here, the input unit 100 may receive a duty ratio or may receive a driving time and a driving cycle of the laser diode 400 based on setting the duty ratio, but for the convenience of the user, the output of the laser diode 400 It is desirable to receive a setting value.

The controller 200 calculates the duty ratio of the laser diode 400 based on the output setting value from the input unit 100. That is, the controller 200 calculates the duty ratio D ₁ of the laser diode 400 by substituting the maximum output value of the laser diode 400 and the output setting value from the input unit 100 into Equation 1 below. Here, the duty ratio D ₁ refers to a ratio of the driving time T _ON1 and the driving period T _P1 of the laser diode 400.

P _EFF : Output setting value from the input unit 100

P _LD : Maximum output value of the laser diode 400

T _P1 : Normal Mode Driving Cycle

T _ON1 : Normal mode operation time

D ₁ : Duty ratio

The controller 200 determines the driving mode of the laser diode 400 based on the calculated duty ratio D ₁ and the preset mode setting reference duty ratio. That is, the control unit 200 groups the duty ratio (D _1), the mode setting reference by comparing the duty ratio of the duty ratio (D _1), the mode set based on the duty ratio is less than if it is determined in the normal mode, the duty ratio (D ₁ calculated ) Exceeds the mode setting reference duty ratio, it is determined as a blink mode. At this time, the mode setting reference duty ratio is set differently according to the laser diode 400 used in the visible light visual identifier, and is set to about 30% to 50%, which is a duty ratio in which heat generation or damage of the laser diode 400 occurs. do. Here, the mode setting reference duty ratio may be set to a value outside about 30% to 50% according to the characteristics of the laser diode 400 used in the visible light visual identifier. That is, the controller 200 increases the driving time as the duty ratio increases, and as the driving time increases, the calorific value of the laser diode 400 also increases, resulting in damage to the laser diode 400. When the duty ratio of the diode 400 exceeds the mode setting reference duty ratio (for example, about 30% to 50%) at which heat generation of the laser diode 400 occurs, the laser diode 400 is generated by driving in the blink mode. Increase time to release heat

When the controller 200 determines that the normal mode driving of the laser diode 400 is performed, the general mode driving time T _ON1 and the normal mode driving period T according to the general mode of the laser diode 400 using Equation 1 described above. _P1 ) is calculated and a control signal for driving the laser diode 400 in accordance with the normal mode driving time T _ON1 and the normal mode driving period T _P1 calculated in advance is generated. That is, as shown in FIG. 2, the controller 200 generates a control signal for driving the laser diode 400 according to the calculated normal mode driving time T _ON1 and the normal mode driving period T _P1 . do.

If the controller 200 determines that the blink mode of the laser diode 400 is driven, the controller 200 calculates the blink mode driving time T _ON2 and the blink mode driving period T _{P2 of} the laser diode 400 by using Equation 2 below. Then, a control signal for driving the laser diode 400 according to the calculated blink mode driving time T _ON2 and the blink mode driving period T _P2 is generated. That is, as shown in FIG. 3, the controller 200 controls the laser diode 400 to _operate according to the duty ratio D ₁ calculated during the blink mode driving time T _ON2 when it is determined as the blink driving mode. The signal is generated every blink mode driving period T _P2 . Here, D ₁ is a variable for adjusting the light output intensity of the laser diode 400, D ₂ is a variable for adjusting the average output of the laser diode 400. As such, the laser diode output control apparatus and method for the visible light detector detects the duty ratio causing the heating problem of the laser diode 400 to be driven in the blink mode, thereby minimizing damage caused by the heating of the laser diode 400. It is possible.

P _EFF : Output setting value from the input unit 100

P _LD : Maximum output value of the laser diode 400

T _P1 : Normal Mode Driving Cycle

T _ON1 : Normal mode operation time

T _P2 : Blink Mode Drive Cycle

T _ON2 : Blink Mode _Run Time

D ₁ : Normal mode duty ratio

D ₂ : Blink mode duty ratio

The controller 200 sets the driving time of the laser diode 400 to a fixed value and calculates the driving period using the above Equations 1 and 2, or sets the driving period to a fixed value based on the duty ratio. Calculate the drive time. The controller 200 may calculate the driving period and the driving time proportionally based on the duty ratio. At this time, the control unit 200 calculates a drive cycle of 60 s or more that the user can recognize that the movement is continuous by the afterimage effect when the user observes with the naked eye. Here, the driving time of the laser diode 400 refers to the time for the laser diode 400 to emit light in an ON state.

The laser diode driver 300 turns the laser diode 400 on or off based on a control signal from the controller 200. That is, the laser diode 400 turns on or off the laser diode 400 by applying or blocking a current to the laser diode 400 based on a control signal from the controller 200. Here, the details of turning on / off the laser diode 400 by applying or blocking a current are easily understood by those skilled in the same industry, and thus detailed description thereof will be omitted.

The laser diode 400 is driven by the laser diode driver 300 to generate light, and the light generated from the laser diode 400 is applied to the optical cable 600 to be inspected through the connector 500.

4 is a flowchart illustrating a laser diode output control method for the visible light detector according to an embodiment of the present invention, Figure 5 is a laser diode output control method for the visible light detector according to an embodiment of the present invention It is for the drawing.

First, the user connects the optical cable 600 to be inspected through the connector of the visible light visual identifier having the mode setting reference duty ratio of the laser diode 400 set to approximately 30% to 50%. When the connection with the optical cable 600 is completed, the user manipulates the input unit 100 to input an output setting value of the laser diode 400 (S100). That is, the user manipulates the input unit 100 to input an output setting value of the laser diode 400 to be applied to the optical cable 600. Here, the user may directly input the duty ratio by manipulating the input unit 100 or input a driving time and a driving period of the laser diode 400 based on setting the duty ratio. In this case, step S200 described later is omitted.

The controller 200 calculates a duty ratio based on the output setting value of the laser diode 400 from the input unit 100 (S200). That is, the controller 200 sets the duty ratio of the laser diode 400 by substituting the maximum output value of the laser diode 400 and the output setting value from the input unit 100 in Equation 1 described above. For example, when the maximum output value of the laser diode 400 is 50 Hz and the output setting value from the input unit 100 is 3 Hz, the control unit 200 calculates 6 calculated by substituting the respective values into Equation 1 described above. Let% (eg 0.06) be the duty ratio of the laser diode 400.

The controller 200 determines the driving mode of the laser diode 400 based on the calculated duty ratio and the preset mode setting reference duty ratio (S300). Here, the controller 200 determines the normal mode when the duty ratio is less than the mode setting reference duty ratio, and determines the blink mode when the duty ratio exceeds the mode setting reference duty ratio. At this time, the mode setting reference duty ratio is set differently according to the laser diode 400 used for the visible light visual identifier, and about 30% to 50% of the duty ratio at which heat generation or damage of the laser diode 400 occurs is performed. Is set. Here, the mode setting reference duty ratio may be set to a value outside 30% to 50% depending on the characteristics of the laser diode 400 used for the visible light visual identifier.

If it is determined in the normal mode (S300; YES), the control unit 200 calculates the driving time and driving period of the laser diode 400 according to the normal mode (S400). That is, when the controller 200 determines that the normal mode driving of the laser diode 400 is performed, the control unit 200 determines the normal mode driving time T _ON1 and the normal mode driving period T _{P1 of} the laser diode 400 by using Equation 1 described above. Calculate. Here, the controller 200 sets the normal mode driving time T _ON1 of the laser diode 400 to a fixed value based on the duty ratio D ₁ and calculates the normal mode driving period T _P1 , or calculates the duty ratio. Based on (D ₁ ), the normal mode driving period T _P1 is set to a fixed value and the normal mode driving time T _ON1 is calculated. At this time, the control unit 200 calculates a general mode driving period T _{P1 of} 60 ms or more, which can be recognized as a continuous movement by the afterimage effect when the user observes with the naked eye. The control unit 200 proportionally calculates a plurality of normal mode driving times T _ON1 and a normal mode driving cycle T _P1 , and generates a general mode driving cycle T of 60 ms or more in the calculated plurality of driving times and driving cycles. _The general mode driving time T _ON1 and the normal mode driving period T _{P1 including P1} ) may be calculated. For example, when the duty ratio D ₁ of the calculated laser diode 400 is 10% and the normal mode driving time T _ON1 is set to 6 ms, which is a fixed value, the controller 200 controls the duty ratio D. ₁ ) and 60 Hz, which is a result of the calculation using the normal mode driving time T _ON1 , are calculated as the normal mode driving period T _P1 of the laser diode 400.

In operation S300, the controller 200 calculates the blink mode driving time T _ON2 and the blink mode driving period T _P2 of the laser diode 400 (S500). That is, when the control unit 200 determines that the blink mode of the laser diode 400 is driven, the blink mode driving time T _ON2 corresponding to the blink mode of the laser diode 400 and the blink mode driving cycle ( T _P2 ) is calculated. Here, the controller 200 determines the blink mode driving time T _ON2 and the blink mode driving period T _P2 according to the blink mode for an integer multiple of the driving period T _P1 of the normal mode for convenience, and the duty ratio of the normal mode. The intensity of light perceived by the real user's naked eye is adjusted using (D ₁ ), and the average power of the laser diode 400 is adjusted using the duty ratio (D ₂ ) of the blink mode. As such, the laser diode output control apparatus and method for the visible light detector control the driving time of the laser diode 400 based on the duty ratio, thereby minimizing the power consumed by the laser diode 400, the laser diode due to heat generation The reduction in durability of 400 can be minimized.

The controller 200 generates a control signal for controlling the laser diode 400 to emit light according to the driving time and driving cycle of the previously calculated laser diode 400 (S600). For example, when the calculated laser diode 400 has a maximum output of 50 ms in the normal mode driving, the driving time is 6 ms, and the driving period is 60 ms, the control unit 200 calculates the calculated laser diode 400. As shown in FIG. 5, a control signal for driving the laser diode 400 is generated according to the driving time and the driving period of the laser diode 400.

The laser diode driver 300 applies or blocks a current applied to the laser diode 400 based on a control signal from the controller 200 (S700). When a current is applied from the laser diode driver 300, the laser diode 400 applies light corresponding to the maximum output to the optical cable 600 through the connector 500, and stops driving when the current is cut off. Here, the current applied to the laser diode 400 is a current value applied at the maximum output of the laser diode 400, and different currents are applied according to the characteristics of the laser diode 400 used. As such, the laser diode output control apparatus and method for the visible light detector is a constant current is supplied in order to solve the limitation of the output control range due to the threshold current in the conventional laser diode 400, so that the laser diode 400 to the maximum output By controlling the duty ratio in the fixed state to control the output of the laser diode 400, the output of 10% or less of the maximum output is possible, thereby freely adjusting the output adjustment range of the laser diode 400, It is possible to precisely adjust the output of 400).

As described above, the laser diode output control apparatus and method for the visible light detector by controlling the output ratio of the laser diode 400 by controlling the duty ratio of the laser diode 400 without using an expensive and bulky optical attenuator In addition, it is possible to minimize the cost of producing the visible light visual identifier and to miniaturize the visible light visual identifier.

Although a preferred embodiment according to the present invention has been described above, modifications can be made in various forms, and those skilled in the art may make various modifications and modifications without departing from the claims of the present invention. It is understood that it may be practiced.

1 is a block diagram illustrating a laser diode output control apparatus for a visible light naked eye detector according to an embodiment of the present invention.

2 and 3 are diagrams for explaining a control signal for controlling a laser diode.

Figure 4 is a flow chart for explaining a laser diode output control method for a visible light naked eye detector according to an embodiment of the present invention.

5 is a view for explaining a laser diode output control method for a visible light naked eye detector according to an embodiment of the present invention.

<Description of the symbols for the main parts of the drawings>

100: input unit 200: control unit

300: laser diode driver 400: laser diode

500: connector 600: optical cable

Claims (10)

A laser diode output control apparatus for a visible light detector for controlling a light output of a laser diode in a visible light detector, An input unit configured to receive an output setting value of the laser diode; And A duty ratio is calculated based on the output setting value input to the input unit, a normal mode driving time and a normal mode driving period of the laser diode according to the duty ratio are calculated, and the calculated normal mode driving time and normal mode driving are calculated. A control unit for generating a control signal for driving the laser diode based on the cycle, The control unit controls the laser diode to drive in a blink mode that outputs aperiodically when the calculated duty ratio exceeds a mode setting reference duty ratio. Calculate a blink mode driving time and a blink mode driving period of the laser diode based on the duty ratio, the normal mode driving time, and the normal mode driving period, and output light only during the blink mode driving time in each blink mode driving period. And controlling the laser diode to output light according to the calculated normal mode driving time and normal mode driving period during the blink mode driving time. delete delete delete The method according to claim 1, The driving period is a laser diode output control device for a visible light detector, characterized in that the period of the afterimage effect occurs when observed with the naked eye. In the visible light detector to control the light output of the laser diode, A duty ratio calculating step of the control unit calculating a duty ratio based on an input output setting value of the laser diode; A normal mode driving information calculating step of the control unit calculating a normal mode driving time and a normal mode driving period according to the duty ratio calculated in the duty ratio calculating step; And The control unit includes a control step of generating a control signal for driving the laser diode based on the normal mode driving time and the normal mode driving period calculated in the normal mode driving information calculation step, In the control step, In order to control the laser diode to drive in a blink mode that outputs aperiodically when the duty ratio calculated in the duty ratio calculating step by the controller exceeds a mode setting reference duty ratio, Calculate a blink mode driving time and a blink mode driving period of the laser diode based on the duty ratio, the normal mode driving time, and the normal mode driving period, and output light only during the blink mode driving time in each blink mode driving period. And controlling the laser diode to output light according to the calculated normal mode driving time and normal mode driving period during the blink mode driving time. delete delete delete The method according to claim 6, The driving cycle is a laser diode output control method for a visible light detector, characterized in that the after-image effect occurs when observed with the naked eye.

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