KR100346627B1 - Continuous flash device for camera and method for controlling the same - Google Patents

Abstract

PURPOSE: A continuous flash device for a camera and a method for controlling the same are provided to allow for continuous photographing operation through the use of a plurality of condensers for flash. CONSTITUTION: A continuous flash device comprises a release switch(S1) operating from the first stage of release to the second stage of release in accordance with the user selection and outputting an electrical signal; a luminance measuring unit(2) for measuring luminance of an object and outputting a signal; an automatic distance measuring unit(3) for measuring the distance from the object; a motor driving unit(4); an information display unit(5) for displaying operation state of the camera; a strobe unit(6) constituted by a plurality of capacitors, and which charges capacitors in accordance with the relay control signal and light emitting signal applied when the luminance of the object is low; a photographing operation control unit(1) for performing a flash photographing operation by operating the strobe unit in accordance with the operation of the release switch; and a reference voltage generator(7) for supplying operating voltage to each unit.

Description

Continuous flash light emitting device of the camera and its control method

The present invention relates to a continuous flash light emitting device of a camera and a method of controlling the same. More specifically, a plurality of flash light emitting capacitors are mounted to charge the plurality of capacitors as power is applied to the camera, and then the operation of the release switch is performed. Accordingly, the present invention relates to a continuous flash light emitting device of a camera capable of photographing a plurality of flash lights by discharging the capacitors, and a control method thereof.

In general, when shooting a subject, the shooting condition is determined by the illumination condition of the surrounding environment. Therefore, when taking pictures indoors or at night, the illuminance is very low, so that the flashes, which have almost the same characteristics as the sun light with a large amount of light and a high color temperature, are made for a very short time to improve the influence of ambient illumination when taking pictures.

Therefore, when the amount of ambient light is insufficient, the flash device, which is manually mounted by the photographer and judges itself, emits a momentary flash in conjunction with the operation of the shutter.

In addition, even in the case of an automatic camera with a built-in flash device, if the amount of light is insufficient by judging whether the flash device is driven according to the ambient lighting conditions, the flash light is automatically emitted in conjunction with the shutter operation to compensate for the insufficient amount of light. It is configured to do so.

The operation of the conventional flash circuit is as shown in FIG. 1 attached to the power supply unit 10, that is, the voltage of the battery is boosted by the electromagnetic induction action of the boosting unit 20 is charged in the charging capacitor 70.

The photographing control device of the camera (not shown) determines whether the flash is charged, and then outputs a driving signal to the trigger unit 50 when the photographing controller does not properly photograph the exposure due to low ambient light.

The trigger unit 50 is operated in response to the driving signal, and the charges charged in the charging capacitor 70 are discharged through the discharge tube 60, so that the flash light emits according to the ionization action of the discharge tube 60.

However, the conventional flash circuit is equipped with only one capacitor to charge the voltage according to the flash emission, the flash shooting operation is performed until the flash charging is completed again after the flash emission shooting is completed according to the user's release switch operation As a result, a disadvantage arises in that a missed photographic opportunity is missed.

Therefore, an object of the present invention is to solve the above-mentioned disadvantages, and is equipped with a plurality of flash emitting capacitors and charges the plurality of capacitors as power is supplied to the camera, and then the capacitors ( Hereinafter, to provide a continuous flash light emitting device of a camera capable of continuous shooting according to a plurality of flash light emission by discharging each of the capacitor) and its control method.

The configuration of the present invention for achieving the above object,

A release switch for varying an operating state from the release 1 stage to the release 2 stage according to a user's selection operation and outputting a corresponding electrical signal;

Luminance metering means for measuring a luminance amount of the subject and outputting a signal corresponding thereto;

A stroboscope comprising a plurality of charging capacitors for charging a charging capacitor according to a relay control signal and a light emitting signal applied when the luminance amount of the subject is low brightness;

When the power is applied, it activates and outputs a charging preference for boosting the voltage and a relay control signal for charging the plurality of charging capacitors, and then determines whether the charging capacitor is completed according to a signal applied from the strobe unit. When charging is completed, the relay control signal output is stopped, and the luminance metering means is driven in accordance with the release first stage operation of the release switch to measure the subject luminance amount, and when the measured subject luminance amount is low luminance, According to the number of two-stage operation of the release is composed of a relay control signal for discharging a plurality of charging capacitors, respectively, and a control means for outputting a light emitting signal for emitting a strobe part.

Another configuration of the present invention for achieving the above object,

In the continuous flash light emitting method of the camera comprising a strobe part having a plurality of charging capacitors ,

Initializing all the usage variables when the camera is powered on, and then activating and outputting a charging signal for boosting the voltage of the strobe unit and a relay control signal for forming a charging path of the plurality of charging capacitors;

Determining whether the charging is completed according to a signal applied from the strobe unit, stopping the relay control signal output when the charging is completed, and determining whether the release switch is operated to the first release stage ;

Measuring the subject distance and the luminance amount when the release switch is operated in the first release stage, and then determining whether the subject luminance amount is low luminance;

Determining whether the strobe part is completely charged again when the object luminance is low, and determining whether the second release of the release switch is operated when the charging is completed;

When the release switch is operated in the second stage of the release switch to activate and output a relay control signal for forming a discharge path of one of the plurality of charging capacitors of the stroboscope portion and the light emitting signal for emitting the strobe portion, to emit a flash Continuous flash emission control method of the camera, characterized in that consisting of.

When described with reference to the accompanying drawings the most preferred embodiment which can easily implement the present invention by the above configuration as follows.

2 is a block diagram of a continuous flash light emitting apparatus of a camera according to an embodiment of the present invention,

3 is a detailed circuit diagram of the stroboscopic part of the continuous flash light emitting apparatus of the camera according to the embodiment of the present invention,

4 is an operation flowchart of the continuous flash emission control apparatus of the camera according to the embodiment of the present invention.

As shown in FIG. 2, a continuous flash light emitting device of a camera according to an embodiment of the present invention includes a release switch S1 having a first stage and a second stage, and a luminance metering unit for metering a subject luminance. 2), an automatic ranging unit 3 for measuring the distance to the subject, a motor drive unit 4 for driving a motor for adjusting shutter driving and lens feeding, and an information display unit 5 for displaying an operating state of the camera 5 ), The strobe part 6, the photographing control part 1 which operates the strobe part 6 according to the operation of the release switch S1, and performs flash emission photographing, and the operations of the devices 1 to 6. It consists of a reference voltage generator 7 which supplies a voltage.

As shown in FIG. 3, the configuration of the strobe part 6 of the continuous flash light emitting device of the camera according to the embodiment of the present invention includes a boosting part 61 for boosting and outputting a DC voltage applied to a predetermined voltage, and The high voltage charging unit 66 connected to the output terminal of the boosting unit 61 to charge the boosted voltage applied thereto, and the high voltage charging unit 66 connected to the output terminal of the boosting unit 61 according to a signal applied from the photographing controller 1. ) it is connected to the output terminal of the charge detecting unit 62, the step-up unit 61 for outputting a signal corresponding to the charge trigger for outputting the flashing signal in response to a trigger signal applied from the recording control section (1) of And a light emitting unit 64 connected to an output terminal of the boosting unit 61 and outputting a flash light when the flash light emission signal is output, while emitting a constant flash while the voltage charged in the high voltage charging unit 66 is discharged. Shooting control unit ( It is connected to the output terminal of 1) consists of a relay unit 65 for controlling the charging and discharging operation of the high voltage charging section 66.

The booster 61 includes a capacitor C6 having one terminal connected to a power source and the other terminal grounded, a resistor R2 having one terminal connected to a power source, a collector terminal connected to a power source, and a base terminal connected to the power source. A transistor Q2 connected to the tee-side terminal of the transistor, a collector terminal connected to the other terminal of the resistor R2, a base terminal connected to the charge signal terminal OSC of the photographing controller 1, and an emitter terminal grounded Q3, a diode D2 having a cathode terminal connected to the power source, a transistor Q1 having an emitter terminal connected to the power source and a base terminal connected to the anode terminal of the diode D2, and one terminal having the resistor A resistor R1 connected to the other terminal of the R2, one terminal connected to the other terminal of the resistor R1, and the other terminal connected to the anode terminal of the diode D2, and one terminal of the primary coil L1. Of the diode D2 A transformer T1 is formed of a secondary coil L2 connected to the other terminal, and a coil L3 having one terminal connected to the collector terminal of the transistor Q1 and the other terminal grounded.

The charge state detecting unit 62 includes a diode D1 having an anode terminal connected to the other terminal of the secondary coil L2 of the transformer T1 of the boosting unit 61, and an anode terminal of the photographing control unit. The diode D3 connected to the charging signal terminal OSC of (1), the anode terminal is connected to the charging completion detection signal terminal NEC of the photographing control unit 1, and the cathode terminal is the cathode terminal of the diode D3. A resistor (D4) connected to the transistor (D4), a base terminal connected to the cathode terminals of the diodes (D3 and D4) and an emitter terminal grounded, and one terminal connected to the collector terminal of the transistor (Q5). R4, a resistor R3 having one terminal connected to the cathode terminal of the diode D1, a neon discharge tube NE having one terminal connected to the other terminal of the resistor R3, and an emitter terminal having the neon terminal Connected to the other terminal of the discharge tube (NE) and the base terminal A transistor Q4 connected to the other terminal of the resistor R4 and one terminal of the transistor Q4 connected to the collector terminal of the transistor Q4 and the other terminal of the transistor Q4 are grounded, and a collector of the transistor Q4. The terminal is connected to the charging state signal terminal NES of the photographing controller 1.

In the configuration of the trigger unit 63, a resistor R7 having one terminal connected to the trigger terminal TRIG of the photographing control unit 1, one terminal connected to the other terminal of the resistor R7, and the other terminal being A grounded resistor R6, a capacitor C4 having one terminal connected to the other terminal of the resistor R7 and the other terminal grounded, and one terminal of the diode D1 of the charge state detecting unit 62. A thyristor (SCRI) having a resistor (R5) connected to the cathode terminal, an anode terminal connected to the other terminal of the resistor (R5), a cathode terminal grounded, and a gate terminal connected to the other terminal of the resistor (R7), and one terminal A capacitor C3 connected to the other terminal of the resistor R5, one terminal connected to the other terminal of the capacitor C3 and the other terminal grounded, and the other terminal grounded 2 It consists of the transformer T2 which consists of the difference coil L5.

The light emitting unit 64 has one terminal connected to the cathode terminal of the diode D1 of the charge state detecting unit 62, the other terminal is grounded, and the gate terminal of the light emitting unit 64 of the transformer T2 of the trigger unit 63. It consists of a xenon discharge tube (XE) connected to the other terminal of the car coil (L5).

The relay unit 65 includes a transistor Q11 having a base terminal connected to the first relay control signal terminal RYC1 of the photographing controller 1 and an emitter terminal grounded, and one terminal of which is a collector of the transistor Q11. A first relay RRYC1 consisting of a coil L6 connected to a terminal and the other terminal connected to a power source, a first switch RSW1 connected to a cathode terminal of the charge state detecting unit 62, and a base terminal; Is connected to the second relay control signal terminal RYC2 of the photographing control unit 1 and the emitter terminal is grounded, one terminal is connected to the collector terminal of the transistor Q12, and the other terminal is connected to the power supply. The second relay RRYC2 including the coil L7 connected, the second switch RSW2 connected to the cathode terminal of the charge state detecting unit 62, and the base terminal are connected to the third of the photographing controller 1. Emmy connected to relay control signal terminal (RYC3) A transistor Q13 having a grounded terminal, a coil L8 having one terminal connected to a collector terminal of the transistor Q13 and the other terminal connected to a power source, and one terminal having a cathode terminal of the charge state detecting unit 62. And a third relay RRYC3 including a third switch RSW3 connected to the diodes, and diodes D5, D6, and D7 are connected to both ends of the coils L6, L7, and L8.

The high voltage charging unit 66 may include a capacitor C11 having one terminal connected to the other terminal of the first switch RSW1 of the relay unit 65 and the other terminal grounded, and one terminal connected to the relay unit ( A capacitor C12 connected to the other terminal of the second switch RSW2 of the terminal 65 and the other terminal is grounded, and one terminal thereof is connected to the other terminal of the third switch RSW3 of the relay unit 65 and the other terminal thereof. Is made of a grounded capacitor C13.

The operation of the continuous flash light emitting device of the camera according to the embodiment of the present invention by the above configuration is as follows.

When power is applied to the camera, the photographing control unit 1 initializes all the usage variables, and then activates the charging signal OSE to the stroboscopic unit 6 in order to boost the flash driving voltage to charge the voltage necessary for flash emission. Output (S110 ~ S120).

The transistor Q3 of the booster 61 of the strobe unit 6 is turned on by the high level charge signal OSC output from the photographing controller 1, and the transistor Q3 is turned on due to the turn-on operation of the transistor Q3. Q2 also turns on in sequence.

When the transistor Q2 is turned on so that a current flows through the primary coil L1 of the transformer T1 to the transistor Q3 and the potential of the base terminal of the transistor Q1 is changed to a low level, the transistor Q1 is turned on. Turn on.

When the transistor Q1 is turned on and the current flowing to the primary coil L1 of the transformer T1 is interrupted, a high high voltage is induced in the secondary coil L2 by mutual induction.

The high voltage generated by the induction action is converted into a direct current through the diode D1 and charged with the capacitor C3 of the trigger unit 63 and the capacitors C11, C12, and C13 of the high voltage charging unit 66.

At this time, the photographing control unit 1 activates the charging signal OSC and simultaneously activates the relay control signals RYC1 to RRY3 applied to the relay unit 65 to output the high level state (S130).

The transistors Q11, Q12, and Q13 are turned on by the high level relay control signals RYC1 to RYC3 output from the photographing control unit 1 so that current flows to the relays RY1, RY2, and RY3.

The first switch RSW1 as a current is applied to the relays RRYC1 to RRYC3. Since the second switch RSW2 and the third switch RSW3 are turned on, the high voltage rectified through the diode D1 is charged to the capacitors C1 to C3 of the high voltage charging unit 66.

While the charging operation of the strobe unit 6 is started and the predetermined voltage is charged, the charging photographing control unit 1 activates the charge completion detection signal NEC to a high level state to determine whether the charging of the strobe unit is completed. Output (S140).

The high level charge completion detection signal NEC output from the capturing controller 1 is applied to the base terminal of the transistor Q5 via the diode D4, so that the transistor Q5 is turned on and the transistor Q5 is turned on. Transistor Q4 is also sequentially turned on in conjunction with the turn-on operation.

At this time, when the charging of the capacitors C11, C12, C13 of the high voltage charging unit 66 is completed, the neon discharge tube NE is turned on according to the voltage applied through the resistor R3, and the current turns on the transistor Q4. It is charged to the capacitor (C5) through.

Accordingly, when the charging of the capacitor C5 is completed, an electrical signal corresponding thereto is applied to the charging state signal terminal NES of the photographing controller 1.

In the above, the photographing controller 1 detects the charging state preference NES and determines whether the charging of the strobe unit 6 is completed (S150).

When the charging of the capacitor C5 is completed and a high level signal is input to the charging state signal terminal NES, the photographing controller 1 determines that the charging of the straw is completed, and is charged in the high voltage charger 66. In order to prevent the discharge operation of the voltage, the relay control signals RIC1 to RRY3 of the relay unit 65 are deactivated and output in a low level state (S160).

As the photographing control unit 1 outputs the low level light emitting signals RYC1 to RCT3, the transistors Q11, Q12, and Q13 are turned off so that no current flows to the relays RRYC1 to RRYC3, so that the first switch RSW1 is turned on. ), The second switch RSW2 and the third switch RSW3 are turned off.

As the first switch RSW1, the second switch RSW2, and the third switch RSW3 are turned off, the discharge paths of the capacitors C11, C12, and C13 are blocked.

In the above, when the charging of the strobe unit 6 is not completed, the photographing controller 1 outputs a charging signal OSC to charge the capacitors C11, C12, and C13 of the high voltage charging unit 66 with the boosted voltage. Let's do it.

After the charging operation of the strobe unit 6 is completed in the above, the photographing controller 1 determines whether the user releases the switch S1 (S170), and when the release switch S1 is operated in the first release stage, the automatic side By driving the rejection 3, the distance from the subject is measured, and the luminance of the subject to be photographed is measured through the luminance metering unit 2, and then the luminance of the subject according to the measured distance is determined to be high or low luminance. (S180 ~ S190).

When the luminance amount according to the distance of the subject to be photographed is low luminance, the photographing controller 1 again determines whether the charging of the strobe part 6 is completed according to a signal input through the charging state signal terminal NES. It is determined whether the release two-stage operation of the release switch (S1) (S200 ~ S210).

When the release switch S1 is operated in the second release stage, the photographing controller 1 activates and outputs the first relay control signal RIC1, which is a relay driving signal, to the relay unit 65 (S220).

The first switch RSW1 is turned on as the high level first relay control signal RYC1 is output and the transistor Q11 is turned on.

At this time, the photographing controller 1 activates the trigger signal TRIG for emitting the flash to output the strobe unit 6 at a high level, and then operates the motor driver 4 to operate a shutter (not shown). Perform photography (S230 ~ S240).

The trigger signal TRIG output from the capturing controller 1 is turned on as the thyristor SCR1 gate terminal of the trigger unit 63 is input through the resistor R7 so that the charge charged in the capacitor C3 is stored in the thyristor. It discharges via (SCR1).

As the capacitor C3 discharges, the current of the primary coil L4 of the transformer T2 is interrupted, and an electromotive force placed on the secondary coil L5 is generated by mutual induction and is applied to the xenon discharge tube XE. .

According to the applied high voltage, the high voltage charged in the capacitor C11 of the high voltage charging unit 66 is discharged through the xenon discharge tube XE.

At this time, the voltage charged in the capacitors C12 and C13 of the high voltage charging unit 66 is not discharged because the discharge path is blocked by the second switch RSW2 and the third switch RSW3.

After the photographing operation is performed according to the flash light, the photographing controller 1 determines whether the release switch S1 is operated again (S250), and when the release switch S1 is operated to the first release stage by the user again. After measuring the subject distance and the luminance, if the subject luminance is again low, it is determined whether all of the charging capacitors C11, C12, and C13 mounted on the strobe unit 6 have been discharged (S260 to S280).

When the voltages charged in the charging capacitors C11, C12, and C13 of the strobe part 6 are not discharged, the flash is emitted according to the voltage charged to the capacitors that are not discharged when the release switch stage 2 is operated. In order to do so, the corresponding relay control signals RYC2 and RYC3 are activated (S290 to S300).

In other words, in the photographing steps S220 to S230, since the first relay control signal RIC1 is activated and the voltage charged in the capacitor C11 is discharged through the xenon discharge tube XE, the second relay control preference RRY2 is preferred. By activating the Xenon discharge tube (XE) to emit light by using the voltage charged in the capacitor (C12) (S300 ~ S310).

When all the charging capacitors C11, C12, and C13 mounted above are discharged, the stroboscopic part 5 is charged again to perform imaging.

As described above, in the embodiment of the present invention, a plurality of flash emitting capacitors are mounted to charge the plurality of capacitors as power is applied to the camera, and then the capacitors are discharged according to the operation of the release switch, respectively. Continuous shooting according to light emission is possible.

In addition, even after performing flash flash photography, the flash flash photography may provide a continuous flash light emitting apparatus of a camera having an effect of preventing a missed photographing opportunity due to non-flash charging.

1 is a block diagram of a strobe circuit of a conventional camera,

2 is a block diagram of a continuous flash light emitting apparatus of a camera according to an embodiment of the present invention,

3 is a detailed circuit diagram of the stroboscopic part of the continuous flash light emitting apparatus of the camera according to the embodiment of the present invention,

4 is an operation flowchart of the continuous flash emission control apparatus of the camera according to the embodiment of the present invention.

Claims (4)

A release switch for varying an operating state from the release 1 stage to the release 2 stage according to a user's selection operation and outputting a corresponding electrical signal; Luminance metering means for measuring a luminance amount of the subject and outputting a signal corresponding thereto; A stroboscope comprising a plurality of charging capacitors for charging a charging capacitor according to a relay control signal and a light emitting signal applied when the luminance amount of the subject is low brightness; When the power is applied, the charging signal for boosting the voltage and the relay control signal for charging the plurality of charging capacitors are activated and outputted. When charging is completed, the output of the relay control signal is stopped, and the luminance metering means is driven in accordance with the release first stage operation of the release switch to measure the subject luminance amount , and when the measured subject luminance amount is low luminance, Control means for outputting a relay control signal for discharging each of a plurality of charging capacitors and a light emission signal for emitting the strobe part according to the release two-stage operation number Continuous flash light emitting device of the camera, characterized in that consisting of The method of claim 1, wherein the control means After the flash is fired, the release switch is operated by the user to the first stage of release, and when the subject luminance measured by the luminance metering means is low, the plurality of charging capacitors mounted on the stroboscopic part are discharged. In response to determining that all of the installed charging capacitors are not discharged, the relay control signal and light emission for discharging one of the charging capacitors that are not discharged according to the release two-stage operation of the release switch. A continuous flash light emitting device of a camera, characterized by activating and outputting a signal to emit a flash, and activating and outputting a charging signal for charging the stroboscopic part again when all of a plurality of mounted capacitors are discharged. In the continuous flash light emitting method of the camera comprising a strobe part having a plurality of charging capacitors , Initializing all the usage variables when the camera is powered on, and then activating and outputting a charging signal for boosting the voltage of the strobe unit and a relay control signal for forming a charging path of the plurality of charging capacitors; Determining whether the charging is completed according to a signal applied from the strobe unit, stopping the relay control signal output when the charging is completed, and determining whether the release switch is operated to the first release stage ; Measuring the subject distance and the luminance amount when the release switch is operated in the first release stage, and then determining whether the subject luminance amount is low luminance; Determining whether the strobe part is completely charged again when the object luminance is low, and determining whether the second release of the release switch is operated when the charging is completed; When the release switch is operated in the second stage of the release switch to activate and output a relay control signal for forming a discharge path of one of the plurality of charging capacitors of the stroboscope portion and the light emitting signal for emitting the strobe portion, to emit a flash Continuous flash emission control method of the camera, characterized in that consisting of. The method of claim 3, Determining whether the plurality of charging capacitors mounted on the stroboscopic part are discharged when the amount of the luminance of the subject to be measured is measured by the user and then the release switch is operated in the second release stage again by the user; If all of the above-described charging capacitors are not discharged, when the release switch is operated in the second release stage, the relay control signal and the light emission signal for discharging one of the plurality of non-discharged charging capacitors are activated. Outputting the flash to emit light; And when the plurality of charging capacitors mounted above are discharged, activating and outputting a charging signal for charging the strobe unit again.