KR200149625Y1 - Strobo apparatus - Google Patents

Abstract

The present invention relates to a stroboscopic device, which allows light emission capacity to be changed according to the luminance state of the surrounding environment, so that the light emission operation is performed in a state suitable for the surrounding luminance state of the photographed subject, thereby obtaining a high quality photograph. In order to increase the design freedom by reducing the number of terminals connected to the control device for controlling the light emission operation, a control signal is output to the corresponding control terminal (OSC) to operate the strobe device, and the sensing terminal (NES) is A control unit 10 for outputting a control signal for the light emitting operation to a corresponding control terminal TIG when the charging voltage for the light emitting operation sensed through reaches the set reference voltage; An oscillation unit 1 configured to control a charging operation by performing an oscillation operation according to a state of a control terminal OSC of the control unit 10; A rectifier D1 for rectifying the voltage output from the oscillator 1; A charging unit C3 charged with the voltage rectified by the rectifying unit D1; A charge detecting unit 20 for changing the state of the sensing terminal NES according to the charging state of the charging unit C3 so that the controller 10 can determine the charging voltage of the charging unit C3; A trigger unit (3) for changing the operation state according to the state of the control signal output from the control unit (10) to the corresponding terminal (TRIG) so that the flash of high voltage can emit light; A light emitting unit 4 in which electrical energy charged in the charging unit 3 is converted into light energy by the triggering operation of the trigger unit 3, and flashes are emitted; And a memory 200 in which a reference voltage compared with the charging voltage of the charging unit C3 is stored.

Description

Strobe device

The present invention relates to a strobe device, and more particularly, to a strobe device capable of varying the light emitting capacity of the strobe.

When using an image capturing apparatus such as a camera for photographing a subject, if the luminance state of the surrounding environment is not suitable for performing the photographing operation, the auxiliary apparatus is used to adjust the luminance state to meet the photographing conditions.

Therefore, when the luminance of the surrounding environment is insufficient for taking a picture, the photographer may attach a separate strobe device to the camera to compensate for the lack of brightness, or operate a separate lighting device or apply sunlight to the camera. To prevent poor photography due to lack of brightness.

In general, even in the case of the most prevalent auto cameras, since the strobe device is almost installed, when the state of the luminance of the surrounding environment is determined to be insufficient by the control operation of the control device built in the camera, the installed strobe device is installed. In time with the shooting operation.

Therefore, the camera user can operate the strobe device as needed without a separate strobe device to compensate for the lack of brightness state to obtain a high-quality picture, thereby improving the user's convenience.

Hereinafter, referring to FIGS. 1 and 2, an operation state of a conventional stroboscopic device in which an operation state is changed according to the luminance state of the surrounding environment as described above will be described.

1 is a circuit diagram of a conventional stroboscopic apparatus, and FIG. 2 is an operation timing diagram of a conventional stroboscopic apparatus.

Referring to Fig. 1, the structure of a conventional strobe apparatus is described. The state of the luminance determined by determining the state of the surrounding luminance by a control operation (not shown) connected to the power source B + and the power source B +. Control unit 10 for controlling the state of each control terminal (NES, OSC, NEC, TRIG) to the corresponding state in order to operate the strobe device when it is determined to be a low luminance state below the set luminance, and the power supply (B +) And a rectifier (D1) comprising an oscillation unit (1) connected to the control unit (10) and operating according to the state of the control terminal (OSC) of the control unit 10 to perform an oscillation operation, and a diode rectifying the voltage output from the oscillation unit (1). ), A charging unit C3 consisting of a capacitor charged with the voltage rectified by the rectifying unit D1, and a state of the control terminal NES according to the charging state of the charging unit C3, thereby changing the state of the control unit 100. To control the operation of the oscillator 1 The charge detection unit 2 for stopping the charging operation of the charging unit C3 by changing the state of the control signal output to the control terminal OSC, and from the control unit 100 to the corresponding terminal TIG. An operation state changes according to the state of the output control signal, and the trigger unit 3 enables the flash of high voltage to emit light, and the electricity charged in the charging unit 3 by the trigger operation of the trigger unit 3. It consists of a light emitting portion 4 in which energy is converted into light energy and light flashes.

The oscillator 1 has a transistor Q1 having an emitter terminal connected to a power source B + and a base terminal connected to a control terminal OSC of the controller 100, and one terminal connected to a power source B +. A capacitor (C1), a transistor (Q2) having a collector terminal connected to the other terminal of the capacitor (C1), and a base terminal and an emitter terminal connected to the collector terminal of the transistor (Q1); One terminal is connected to the emitter terminal of Q2 and the other terminal is grounded, and the emitter terminal is connected to the power supply B +, and the base terminal is connected to the other terminal of the capacitor C1. A transformer T1 connected to the transistor Q3 and a collector terminal of the transistor Q3, and a secondary coil L2 connected to the collector terminal of the transistor Q1. And, the transformer (T1) 2 is side cathode terminal connected to the coil (L2), and consists of a Zener diode (D2) in the anode terminal thereof is grounded.

The charge detecting unit 2 has a resistor R2 having one terminal connected to the power supply B + and the other terminal connected to the control terminal NES of the controller 100, and the other terminal of the resistor R2. A transistor (Q4) having a collector terminal connected thereto and an emitter terminal grounded thereon, a resistor (R3) having one terminal connected to a cathode terminal of the rectifying unit (D1), and the other terminal of the resistor (R3). An emitter terminal and a base connected to the neon discharge tube NE1 having one terminal connected to the resistor, a resistor R4 having one terminal connected to the other terminal of the neon discharge tube NE1, and the other terminal of the resistor R4. A transistor Q5 having a terminal connected thereto and a collector terminal connected to a base terminal of the transistor Q4, and a capacitor C2 having one terminal connected to the collector terminal of the transistor Q5 and the other terminal being grounded ) And the other side of the resistor R4 The collector terminal is connected to the terminal, and the base terminal is connected to the control terminal NEC of the controller 100 and the emitter terminal is grounded.

The operation of the conventional stroboscopic device configured as described above is as follows.

When the state of the ambient luminance is determined as the low luminance state below the set luminance through the control operation of the control unit 100 (not shown), the control unit 100 sets the state of the control terminal OSC as L as shown in FIG. Convert to state

Accordingly, since the transistor Q1 of the oscillation unit 1 is turned on according to the low state L of the control terminal OSC and the base current of the transistor Q1 flows, the turn-on operation of the transistor Q1 is performed. Transistor Q2 is also converted to the turned on state.

By the turn-on operation of the transistor Q2, the charging voltage of the capacitor C1, which has been charged by the power supply B +, is discharged through the turned-on transistor Q2, so that the transistor Q3 is also turned on. The current of the power source B + flows to the primary coil L1 of the transformer T1 by the turn-on operation of the transistor Q3.

Accordingly, in the transformer T1, an induced voltage corresponding to the current flowing through the primary coil L1 is generated in the secondary coil L2 according to the number of turns of the secondary coil L2 or the state of the winding. Through the rectifying unit D1, the charging unit C3 gradually charges the capacitor as shown in FIG.

During the charging operation of the capacitor C3, when the collector current of the transistor Q3 gradually increases by the turn-on operation of the transistor Q3, the transformer T1 is converted into a saturation state and the voltage of the transformer T1 is boosted. The phenomenon does not occur.

Since the voltage stored in the secondary coil L2 of the transformer T1 is discharged and applied to the emitter terminal of the transistor Q2, the voltage difference between the collector terminal and the emitter terminal of the transistor Q2 is no longer applied. Since it does not occur, the transistor Q2 is switched to the turn-off state.

Since the transistor Q3 is also converted to the turn-off state by the turn-off operation of the transistor Q2, the oscillation operation is stopped.

When all of the voltage discharged from the transformer T1 is released through the above operation, the transistors Q2 and Q3 are sequentially turned on again, and the oscillation operation is performed again, so that the charging operation of the charging unit C3 is performed. Make it happen.

When the oscillation operation is performed by the turn-on / off operation of the transistors Q2 and Q3 as described above, the transistor Q1 maintains the L state, which is the low level of the control terminal OSC by the operation of the control unit 100, and continues to turn on. Maintain state.

When charge is charged in the charging unit C3 by the operation of the oscillation unit 1 and the rectifying unit D1 as described above, the control unit 100 uses the charging state detecting unit 2 to determine the charging state of the charging unit C3. Detect.

Hereinafter, the operation of the charging state detector 2 will be described.

When the control unit 100 outputs a low level L state signal to the control terminal OSC for the oscillation operation, the control unit 100 outputs a high level H state signal to the control terminal NEC as shown in FIG.

Therefore, the transistor Q6 is turned on by the high level H signal output to the control terminal NEC, and the transistor Q5 is also turned on sequentially.

In the turn-on state of the transistors Q5 and Q6 as described above, when the state of charge of the charging unit C3 is not charged to the set voltage, the state of the neon discharge tube NE1 becomes a non-lit state.

Therefore, since the transistor Q4 maintains the turn-off state, the sensing terminal NES maintains the high level H state by the resistor R2 as in the initial state as shown in FIG.

However, when the state of charge of the charging section C3 is about 280 V, the neon discharge tube NE changes to a lit state and becomes a conducting state.

Accordingly, the current flows through the neon discharge tube NE1 and the resistors R3 and R4 to the transistor Q5 turned on by the control signal of the control terminal NEC, thereby charging the capacitor C2, so that the transistor Q4 is turned on. Is converted to.

Therefore, by the turn-on operation of the transistor Q4, the state of the sensing terminal NES is changed from the high level H to the low level L as shown in FIG. 2C, so that the controller 100 controls the state of charge of the charging unit 100. I can detect it.

When the charging state of the charging unit C3 progresses to the state where the neon discharge tube NE1 can be turned on as described above, the control unit 100 changes the state of the control terminal NEC to a low level L as shown in FIG. By switching, the operation of the charge detector 2 is stopped.

When the sensing terminal NES is converted to the low level L state by the operation of the charge detecting unit 2 as described above, the controller 100 outputs a trigger signal to the control terminal TRIG for the light emitting operation of the strobe. .

Therefore, the trigger unit 3 and the light emitting unit 4 operate by the trigger signal output from the control unit 100 to the trigger unit 3 through the control terminal TRIG, and the electric energy charged in the charging unit 3 is charged. Is converted into light energy, causing the flash to flash instantaneously.

Therefore, when shooting a subject, a glare occurs to compensate for the insufficient brightness, so that a good quality picture can be obtained.

However, when detecting a lack of brightness when shooting a subject through the above operation, and automatically generates a flash by operating the strobe device, when the flash is emitted when the neon light tube (NE1) is switched to the lighting state, that is, The charging voltage of the charging unit C3 is limited to about 280V.

Therefore, the light emitting state of the light emitting unit 4 is limited to a state corresponding to a charging voltage of about 280V, thereby maintaining a constant light emitting state at all times regardless of the state of the ambient luminance.

Therefore, the light emitted is too bright, rather, the subject is photographed in a high brightness state or the light emitted is insufficient, so that the photographing operation of the subject is performed in a dark luminance state, and thus a problem in that a high quality photograph cannot be obtained.

In addition, since a plurality of control terminals (OSC, NEC, TRIG) and a sensing terminal (NES) connected to the control unit 100 are required to operate the conventional stroboscopic device operating as described above, the product which is miniaturized is designed. In this case, a problem arises in that design freedom is reduced.

Therefore, the object of the present invention is to solve the above-mentioned problems, and the light emission operation can be made in a state suitable for the ambient luminance state of the subject to be photographed by changing the emission capacity emitted according to the luminance state of the surrounding environment. To provide a stroboscopic device to obtain a picture of the.

Another object of the present invention is to provide a stroboscopic device capable of increasing design freedom by reducing the number of terminals connected to a control device for controlling the light emission operation.

1 is a circuit diagram of a conventional stroboscopic apparatus,

2 is an operation waveform diagram of a conventional stroboscopic apparatus,

3 is a circuit diagram of a strobe device according to an embodiment of the present invention,

4 is an operational waveform diagram of a strobe device according to an embodiment of the present invention,

5 is an operation flowchart of a control unit according to an embodiment of the present invention.

The construction of this invention for achieving the above object is to output a control signal to the corresponding control terminal to operate the strobe device, the light emitting operation when the charging voltage for the light emitting operation sensed through the sensing terminal reaches the set reference voltage A control unit for outputting a control signal for the control terminal; An oscillation unit configured to control a charging operation by performing an oscillation operation according to a state of a control terminal of the controller; A rectifier for rectifying the voltage output from the oscillator; A charging unit in which the voltage rectified by the rectifying unit is charged; A charge detector configured to change a state of a sensing terminal according to a state of charge of the charger to allow the controller to determine a charge voltage of the charger; A trigger unit configured to change an operation state according to a state of a control signal output from the control unit to a corresponding terminal so that a flash of high voltage can emit light; A light emitting unit for converting electrical energy charged in the charging unit into light energy by a triggering operation of the trigger unit and emitting flash light; And a memory storing a reference voltage compared with the charging voltage of the charging unit.

Hereinafter, with reference to the accompanying drawings, the most preferred embodiment that can be easily implemented by those skilled in the art to which the present invention belongs.

An apparatus having the same configuration as the prior art and performing the same function is given the same reference numeral as in the prior art.

3 is a circuit diagram of a strobe device according to an embodiment of the present invention, FIG. 4 is an operation waveform diagram of the strobe device according to an embodiment of the present invention, and FIG. 5 is an operation flowchart of a control unit according to an embodiment of the present invention.

Referring to Fig. 3, the configuration of the present invention will be described. The luminance state determined by determining the state of the peripheral luminance by the control operation (not shown) connected to the power source B + and the power source B + is the set luminance. When it is determined as the following low luminance state, the control signal is output to the corresponding control terminal (OSC) to operate the strobe device, and when the charging voltage for the light emitting operation detected through the sensing terminal (NES) reaches the set reference voltage The control unit 10 for outputting a control signal for the light emission operation to the control terminal (TRIG) and the power source (B +) is connected to the oscillation operation is performed according to the state of the control terminal (OSC) of the control unit 10 The rectifier D1 includes a oscillator 1 for controlling a charging operation, a rectifier D1 consisting of a diode rectifying a voltage output from the oscillator 1, and a capacitor charged with the voltage rectified by the rectifier D1. Charge sensing that allows the control unit 10 to determine the charging voltage of the charging unit C3 by changing the state of the sensing terminal NES according to the charging unit C3 and the charging state of the charging unit C3. The trigger unit 3 and the trigger unit 3 to enable the flash of high voltage to be emitted by changing the operation state according to the state of the control signal output from the control unit 10 to the corresponding terminal (TRIG), and the trigger unit By the triggering operation of (3), the electrical energy charged in the charging section 3 is converted into light energy, and the light emitting section 4 which emits flash light is connected to the control section 10 and the charging section C3 The memory 200 stores a reference voltage compared with a charging voltage.

The oscillator 1 includes a transistor Q1 having an emitter terminal connected to a power source B + and a base terminal connected to a control terminal OSC of the controller 100, and one terminal connected to a power source B +. A capacitor (C1) connected to the transistor, a collector terminal connected to the other terminal of the capacitor (C1), and a transistor (Q2) having a base terminal and an emitter terminal connected to the collector terminal of the transistor (Q1); A resistor R1 having one terminal connected to the emitter terminal of the transistor Q2 and the other terminal being grounded, and an emitter terminal connected to the power supply B + and a base terminal connected to the other terminal of the capacitor C1. Is connected to the transistor Q3 and the collector terminal of the transistor Q3 is connected to the primary coil L1 and the transformer terminal of the transistor Q1 is connected to the secondary coil L2. ) And the transformer (T1) A cathode terminal is connected to the secondary coil (L2) of the anode and the anode terminal is made of a zener diode (D2) is grounded.

The charge detector 20 may include a resistor R21 having one terminal connected to a cathode terminal of the rectifying unit D1, and a neon discharge tube NE21 having one terminal connected to the other terminal of the resistor R21. ), A resistor R22 having one terminal connected to the other terminal of the neon discharge tube NE21, a transistor Q21 having an emitter terminal and a base terminal connected to the other terminal of the resistor R22, One terminal is connected to the collector terminal of the transistor Q21 and the other terminal is grounded, and the control terminal OSC is connected to the emitter terminal and the base terminal connected to the power supply B +. A transistor Q22 having a collector terminal grounded, a collector terminal connected to a base terminal of the transistor Q21, a base terminal connected to a collector terminal of the transistor Q22, and an emitter terminal grounded; Is made up of a transistor (Q23) and a resistor (R23) in said one terminal to the collector terminal is connected to the transistor (Q21) and the other terminal is grounded.

The operation of the present invention consisting of the above configuration is as follows.

Since the configuration and operation of the oscillator 1 are the same as in the prior art, when the low-level L-state signal is output from the controller 10 to the control terminal OSC from the controller 10 to the transistor Q1, as shown in FIG. Q2 and Q3 are sequentially turned on, and the voltage rectified through the rectifying unit D1 by the step-up operation of the transformer T1 is performed by the charging unit C3.

The transistor former T1 is converted into a saturation state by the collector current of the transistor Q3 which is increased by the turn-on operation, and a reverse current is applied to the emitter terminal of the transistor Q2 to turn off the transistor Q2. Turns off the transistor Q3.

As described above, when the collector current of the transistor Q3 decreases again due to the reverse current applied to the emitter terminal of the transistor Q2, the transistor Q2 is converted to the turn-on state again and the oscillation operation is resumed.

When the oscillation operation of the oscillation unit 1 is performed by the above operation, and the charging operation of the charging unit C3 is performed, the signal state of the sensing terminal NES, in which the terminal state is changed by the operation of the charging detection unit 20, is changed. Using the controller 10 determines the state of charge of the charging unit (C3).

The state of the initial sensing terminal NES is maintained at the low level by the resistor R23, which is a pull-down resistor.

In order to control the operation of the oscillation unit 1, since the state of the control terminal OSC is maintained at the low level, the transistor Q22 is turned on, and the transistor Q23 is turned on by the turn-on operation of the transistor Q22. Q21) is sequentially turned on.

As described above, when the state of charge of the charging unit C3 rises to about 280 V, which is the set voltage as shown in FIG. 4B, in the turn-on state of the transistor Q21, the neon light tube (by the voltage applied through the resistor R21) NE21) is switched to the lit state.

Therefore, since a current flows through the lit neon lighting tube NE21 and the transistor Q21, the voltage is charged in the capacitor C21.

In this case, since the sensing terminal NES is a terminal for converting an analog signal applied to the A / D terminal, that is, the sensing terminal NES into a digital signal, the magnitude of the voltage charged in the capacitor C21 is converted into a digital state. Since the controller 10 is applied to the controller 10, the controller 10 may determine the charging voltage of the capacitor C21.

Accordingly, the controller 10 reads the charging voltage applied to the sensing terminal NES by the control operation as shown in FIG. 5 (S11) and determines the magnitude of the charging voltage charged in the capacitor C21. (S12).

When the charging voltage of the capacitor C21 is determined, the controller 10 compares the charging voltage of the capacitor C21 that gradually increases as shown in FIG. 4C with respect to a reference voltage that is already set and stored in the memory 200. It is determined whether the reference voltage of about 300V has been reached (S13).

Therefore, when the charging voltage of the capacitor C21 reaches the reference voltage, the controller 10 outputs a trigger signal for generating the luminance necessary for the photographing operation to the control terminal TRIG, so that the trigger unit 3 and the light emitting unit ( 4) is operated so that about 300V charged in the capacitor C21 can be converted into light energy to emit light.

The memory 200 includes a memory such as an EEPROM, which is embedded in the controller 10 or separately mounted on the outside of the controller 10, and may change data by a user, so that the reference voltage is compared with the charging voltage of the capacitor C21. Can be changed arbitrarily.

Therefore, as described above, since the controller 10 may determine the state of the voltage charged in the capacitor C21, the trigger unit 3 may be operated at a desired charge voltage to execute the light emission operation in a state corresponding to the charge voltage. have.

Since the operation timing of the trigger unit 3 and the light emitting unit 4 may be arbitrarily controlled according to the operation of the controller 10, the light emitting state according to the charging state of the charging unit C3 may be arbitrarily selected.

Therefore, the effect of the present invention, which operates as described above, can change the light emission state according to the charging state of the charging unit according to the brightness degree when the ambient luminance state of the subject to be photographed is a low luminance state, High quality pictures can be obtained by maintaining accurate brightness.

In addition, since the number of terminals is reduced by using a terminal for sensing the charging state of the charging unit and a terminal for controlling the operation of the oscillator in common, the hardware configuration can be simplified to solve the spatial limitation in design.

Claims (6)

In the strobe light emitting circuit, a control signal is output to a corresponding control terminal (OSC) to operate a strobe device, and when the charging voltage for the light emitting operation detected through the sensing terminal (NES) reaches a set reference voltage, the light emitting operation is performed. A control unit 10 for outputting a control signal for the control terminal TRIG; An oscillation unit 1 configured to control a charging operation by performing an oscillation operation according to a state of a control terminal OSC of the control unit 10; A rectifier D1 for rectifying the voltage output from the oscillator 1; A charging unit C3 charged with the voltage rectified by the rectifying unit D1; A charge sensing unit 20 for changing the state of the sensing terminal NES according to the charging state of the charging unit C3 so that the controller 10 can determine the charging voltage of the charging unit C3; A trigger unit (3) for changing the operation state according to the state of the control signal output from the control unit (10) to the corresponding terminal (TRIG) so that the flash of high voltage can emit light; A light emitting unit 4 in which electrical energy charged in the charging unit 3 is converted into light energy by the triggering operation of the trigger unit 3, and flashes are emitted; A strobe device comprising a memory (200) storing a reference voltage compared with the charging voltage of the charging unit (C3). The method of claim 1, wherein the charge detection unit 20, Neon discharge tube (NE21) connected to the charging unit (C3); First switching means Q21 connected to said neon discharge tube NE21; A second switching means Q22 connected to a power source B +, the switching state of which is switched according to a state of a signal output from the control terminal OSC of the controller 10 to control an operation of the first switching means. and; A third switching means Q23 connected to the first and second switching means to switch the switching state according to the operating state of the second switching means Q22 to control the switching state of the first switching means Q21; ; And a capacitor (C21) connected to the first switching means (Q21) for charging a charging voltage applied by the turn-on operation of the first switching means. The strobe device according to claim 1, wherein the sensing terminal (NES) of the control unit (10) is connected with an A / D terminal for converting an analog signal applied to the terminal into a digital signal. The reference control method of claim 1, wherein the controller 10 determines a charging voltage of the charging unit C3 using a signal applied through the sensing terminal NES, and stores the determined charging voltage in the memory 200. Compared to the voltage, the strobe device characterized by outputting a control signal for operating the trigger section (3) to the control terminal (TRIG) when the charging voltage reaches the reference voltage. The strobe apparatus according to claim 1, wherein the memory (200) comprises an EEPROM capable of changing data stored as a user. A neon discharge tube NE21 which is turned on when a charging voltage for the light emission operation is applied and the charging voltage reaches the set voltage; First switching means Q21 connected to said neon discharge tube NE21; A second switching means Q22 connected to a power source B +, the switching state of which is switched according to a state of a signal output from the control terminal OSC of the controller 10 to control an operation of the first switching means. and; A third switching means Q23 connected to the first and second switching means to switch the switching state according to the operating state of the second switching means Q22 to control the switching state of the first switching means Q21; ; And a capacitor (C21) connected to the first switching means (Q21) to charge the charging voltage applied by the turn-on operation of the first switching means.