KR920004331B1 - Laser lighting indicator - Google Patents

Abstract

The indicator includes a laser beam output control section (6) for generating laser beam output control signals. A laser diode (1) generates laser beams under the control of the laser beam output control section (6). A focusing lens (2) focuses the laser beams of the laser diode (1), and a scan driving control section (7) generates scan driving control signals. A scanning device (3) decides the scanning direction under the control of the scan driving control section (7), and a reflecting mirror (4) reflects the focused laser beams in accordance with the scanning direction. A window (5) provides a beam path for the reflected laser beams to indicate the target point.

Description

Laser injection indicator

1 is a block diagram of a laser scanning indicator of the present invention.

2 is a detailed circuit diagram of the first laser light output control unit.

3A and 3B are explanatory views of the operation principle of the scanning device of FIG.

4 is a detailed circuit diagram of the scan driving control unit of FIG. 1;

* Explanation of symbols for main parts of the drawings

1 laser diode 2 connection lens

3: scanning device 4: reflective mirror

5: window 6: laser light output control unit

7: scanning drive control unit IC ₄ : constant voltage device

8: battery

The present invention relates to an apparatus for indicating an object through a mirror means using a visible light semiconductor laser as a light source, and in particular, to make it suitable for indicating a specific point on a screen or a track board by a light exchanger or an OHP. It relates to the laser injection indicator.

The conventional on-screen instruction function is indicated by using an indicator rod or writing instrument when instructing contents on the screen by a light illuminator, a projector, or the like, or when instructing contents of a track or a situation board.

In other words, when the image on the screen is imaged on the screen by the illuminator and the projector, the contents of the screen are instructed by the necessity of explanation, etc., and the descriptor or the third person instructs the portion by using an indicator rod or writing tool. In addition, when explaining the contents of the track, the situation board, etc. described in the same manner as described by the indicator bar and writing utensils at a close distance.

However, when instructing the screens of the illuminator and the projector with the indicator rod or writing utensils, etc. according to the necessity of explanation etc., the light of the indicator body and the indicator means is blocked to cover part of the projected contents. There was a problem that the loss of, and in the case of instructing the track or the situation board, etc. with the indicator bar, part of the content is similarly covered, there was a problem that the descriptor must be close to the description object.

By the way, the laser light can focus high brightness light and send it to a long distance. In recent years, with the development of semiconductor technology, a laser diode which generates visible light and high efficiency laser light has been developed.

Accordingly, it is an object of the present invention to provide a laser scanning indicator for directing an indication object in the form of a dot or line without using an indicator rod or writing implement using the laser light as the light emitting source.

The present invention for achieving the above object is to focus through a lens system using a semiconductor laser diode of visible light as a light emitting source, and to rotate the reflection mirror at a left and right angle through a scanning device to scan the focused laser light It is characterized by guiding the scanning light to the object in the form of points or lines through the window, which will be described in detail with reference to the accompanying drawings.

1 is a configuration diagram of the laser scanning indicator of the present invention, as shown therein, a laser beam output control unit 6 that receives power from a battery 8 and generates a laser beam output control signal, and the laser beam output control unit ( A laser diode 1 for generating a constant laser light under the control of 6), a focusing lens 2 for focusing the laser light of the laser diode 1, and a power supply from the battery 8 for scanning driving. A scanning drive controller 7 for generating a control signal, a scanning device 3 for controlling the scanning direction under the control of the scanning drive controller 7, and an axis of the scanning device 3, and scanning A reflection mirror 4 for reflecting the laser light focused by the focusing lens 2 in a crystal direction, and a window 5 for providing a passage of the laser light reflected by the reflection mirror 4 to instruct the object; It consists of.

FIG. 2 is a detailed circuit diagram of the laser beam output control unit 6 of FIG. 1, and as shown therein, the power source Vcc of the battery 8 is connected via a resistor R ₂₁ to a capacitor C ₂₁ and a laser diode ( 1) is connected to the anode of the light emitting laser diode (LD ₁ ) and the cathode of the light receiving laser diode (1), and the connection point is connected to the capacitor (C ₂₂ ), zener diode (D) through the resistor (R ₂₂ ) ₂₁₎ and connected to the emitter of the transistor (Q _21), and by connecting the collector of the transistor (Q ₂₁₎ to the base of the capacitor (C ₂₃₎ and a transistor (Q _22), a laser diode for the light in his collector ( The cathode of LD ₁ ) is connected via a resistor R ₂₃ , the anode of the light-receiving laser diode LD ₂ is connected in series with the resistor R ₂₄ and the variable resistor VR ₂₁ , and the connection point thereof is connected. It is configured by connecting to the base of the transistor Q ₂₁ .

In the present invention configured as described above, the power source Vcc is supplied from the battery 8, and the power source Vcc is charged to the capacitor C ₂₁ through the resistor R ₂₁ , and the charging voltage is supplied to the laser diode 1. Is applied to the collector of the transistor Q ₂₂ through the light emitting laser diode LD ₁ and the resistor R ₂₃ , and at the same time, the charging voltage is applied to the capacitor C ₂₂ and the zener diode D ₂₁ through the resistor R ₂₂ . ) and is applied to the emitter of the transistor (Q _21), yiettara the transistor (the constant voltage is output to the collector of Q _21), a capacitor (C _23), and therefore applied to the base the transistor (Q ₂₂ of the transistor (Q ₂₂₎ ) Is turned on to generate laser light from the light emitting laser diode LD ₁ . The laser light generated in this way is incident on the light-receiving laser diode LD ₂ , and is output as a voltage at the connection point of the anode and the resistor R ₂₄ , and this output voltage is supplied to the base of the transistor Q ₂₂ , so that The collector output voltage of the transistor Q ₂₂ is kept constant, and thus the laser light generated by the light emitting laser diode LD ₁ is kept constant without being affected by variations in ambient temperature and voltage.

As described above, the laser light generated and emitted by the light emitting laser diode LD _{1 of the} laser diode ₁ is focused by the focusing lens 2 and then incident on the reflective mirror 4 as parallel light.

3A and 3B are explanatory views showing the operation principle of the first FIG. 3 scanning device 3, and as shown therein, two winding groups 3a and 3b having a pair of poles wound at an angle of 180 °. And a galvanometer scanner (GALVANOMETER SCANNER) made of a rotor 3c magnetized by an N and S poles.

As shown in FIG. 3A, the winding group 3a is magnetized to the magnets 3 and the rotor 3c is placed at a predetermined position, as shown in FIG. 3a. As shown in FIG. 3, if a smaller current is applied in the form of a triangular wave to the other winding group 3b based on the current flowing in the winding group 3a, the rotor 3c reciprocates left and right at a predetermined angle. do. That is, the left and right angles of the reciprocating motion are determined by the amplitude of the triangular wave flowing through the winding group 3b, and the period is determined by the frequency thereof, so that the reflective mirror 4 connected to the scanning device 3 is reciprocated in a certain period. As it is rotated by movement, the laser beam passing through the focusing lens 2 is reflected at a predetermined angle and then guided to the object through the window 5.

The fourth turning FIG. 1 as a detail an arc of the scan driving control unit 7, whereby the power (Vcc) of the battery (8) as shown by the resistance (R ₄₂₎ resistance (R _43), a capacitor (C ₄₂ ), The non-inverting input terminal of the operational amplifier IC ₁ and the inverting input terminal of the operational amplifier IC ₂ are connected in common, and the output terminal of the operational amplifier IC ₁ is inverted through the capacitor C ₄₁ . connected to the input terminal also the addition through a resistance (R ₄₄₎ is is via the operational amplifiers (IC ₂₎ outputs a resistance (R ₄₅₎ of the connection to the non-inverting input terminal, and the operational amplifiers (IC ₂₎ of The non-inverting input terminal thereof is connected to the inverting input terminal of the operational amplifier IC ₁ through a resistor R ₄₁ , and the output terminal of the operational amplifier IC ₁ is connected to a resistor R ₄₆ . Connected to the inverting input terminal of the operational amplifier (IC ₅ ), and through the resistor (R ₄₇ ) to its output terminal again, and the battery (8). ) Is connected to the non-inverting input terminal of the capacitor C ₄₃ and its operational amplifier IC ₅ via the variable resistor VR ₄₂ , and the output terminal thereof is connected to the resistor R ₄₈ and variable. After connecting the switch SW ₁ and the non-inverting input terminal of the operational amplifier IC ₃ through the resistor VR ₄₁ , the output terminal of the operational amplifier IC ₃ is connected to the base of the transistor Q ₄₁ . The emitter is connected to the resistor R ₄₉ and the inverting input terminal of the operational amplifier IC ₃ through the winding group 3b of the scanning device 3, so that the power source Vcc of the battery 8 is a capacitor ( C ₄₄ ) and connected to the input terminal VI of the constant voltage element IC ₄ , and its output terminal Vo is connected to the winding group 3a of the scanning device 3 through the variable resistor VR ₄₃ . To configure.

When the scan drive control unit 7 configured as described above is supplied with the power Vcc from the battery 8, the power Vcc is divided in the resistors R ₄₂ and R ₄₃ and then charged in the capacitor C ₄₂ . And is applied to the non-inverting input terminal of the operational amplifier IC ₁ and the non-inverting input terminal of the operational amplifier IC ₂ , and the output signal of the operational amplifier IC ₁ is connected to the operational amplifier (R ₄₄ ) through the resistor R ₄₄ . IC ₂ ) is applied to the non-inverting input terminal, and the output signal of the operational amplifier (IC ₂ ) is applied to the inverting input terminal of the capacitor (C ₄₁ ) and the operational amplifier (IC ₁ ) through the resistor (R ₄₁ ), Accordingly, the triangular wave waveform is output from the operational amplifier IC ₁ by the integration operation of the resistor R ₄₁ and the capacitor C ₄₁ .

At this time, the power supply Vcc is charged to the capacitor C ₄₃ through the variable resistor VR ₄₂ and applied to the non-inverting input terminal of the operational amplifier IC ₅ as a reference voltage, and the triangular wave output of the operational amplifier IC ₁ is applied. The resistor R ₄₆ is applied to the inverting input terminal of the operational amplifier IC ₅ and the feedback resistor R ₄₇ to be compared and amplified. The output signal of the operational amplifier IC _{5 is} connected to the resistor R ₄₈ and The output is attenuated through the variable resistor VR ₄₁ . That is, at this time, the attenuation ratio is determined by the adjustment of the variable resistor VR ₄₁ .

In this state, when the switch SW ₁ is opened, the triangular wave output attenuated through the variable resistor VR ₄₁ is applied to the non-inverting input terminal of the operational amplifier IC ₃ , and compared with the signal of the inverting input terminal. As the transistor Q ₄ is turned on by the output signal of the operational amplifier IC ₃ , the power supply Vcc is supplied to the inverting input terminal of the operational amplifier IC ₃ through the winding group 3b of the scanning device 3. At this time, the rotor 3c is rotated at a predetermined angle by the triangular wave current flowing through the winding group 3b, that is, the scan width is determined by the magnitude of the input voltage to scan the laser light.

When the switch SW ₁ is shorted, the input voltage applied to the non-inverting input terminal of the operational amplifier IC ₃ is cut off, that is, the ground potential is applied to the non-inverting input terminal to stop the scanning function. As the output Vo of the device IC ₄ drives the winding group 3a of the scanning device 3 through the variable resistor VR ₄₃ , the laser light is output in the form of a dot.

As described in detail above, the present invention can be indicated in the form of a point or a line anywhere on the instruction object by using a pointer rod or writing tool, so that the instruction object can be pointed at a long distance to provide convenience to the user. There is an effect that can provide a laser injection indicator.

Claims (3)

A laser light output control unit 6 for generating a laser light output control signal, a laser diode 1 for generating a constant laser light under the control of the laser light output control unit 6, and a laser of the laser diode 1 A focusing lens 2 for focusing light, a scan drive controller 7 for generating a scan drive control signal, a scan device 3 for controlling the scan direction under the control of the scan drive controller 7, and A reflection mirror 4 which is connected to the rotor shaft of the scanning device 3 and reflects the laser light focused by the focusing lens 2 in its scanning crystal direction, and a passage of the laser light reflected by the reflection mirror 4; A laser scanning indicator comprising: a window (5) provided and instructed to an object. The laser light output control part 6 is connected by a zener diode D ₂₁ so that a constant voltage is applied to the emitter of the transistor Q ₂₁ , and the collector thereof is connected to the capacitor C ₂₃ and the transistor ( After connecting to the base of Q ₂₂ ), the light emitting laser diode LD ₁ of the laser diode 1 is connected to the collector side thereof, and the laser light of the light emitting laser diode LD ₁ is received. ₂ ) The laser scanning indicator which is configured to be connected to be applied to the base of the transistor (Q ₂₁ ) after receiving the light detected by ₂ ). 2. The scan driving controller 7 compares the output signal of the operational amplifier IC ₁ to which the predetermined voltage is applied to the non-inverting input terminal in the operational amplifier IC ₂ to which the predetermined voltage is applied to the inverting input terminal. amplifier is connected and the operation to be fed back to the inverting input terminal side of the amplifier (IC _1), the operational amplifier (IC ₁₎ to be a triangular wave signal output from, and the triangular wave signal is calculated which is applied a predetermined voltage to the noninverting input terminal The amplifier IC ₅ is connected to the non-inverting input terminal of the switch SW ₁ and the operational amplifier IC ₃ through the variable resistor VR ₄₁ , and then outputs the output signal of the operational amplifier IC ₃ . By controlling the on / off of the transistor Q ₄₁ to control the driving of the winding group 3b of the scanning device 3, and the output Vo of the constant voltage element IC ₄ is a variable resistor VR _43. It is configured to control the driving of the winding group (3a) of the injection device 3 through the) Characterized by laser injection indicator.

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