KR20040102763A - Strobe control appaparus wherein triger signal is effectively used - Google Patents

Abstract

PURPOSE: A strobe controller is provided to reduce a number of circuit elements by effectively using an external trigger signal with a light receiving element and to increase the control accuracy by accumulating electric energy from the light receiving element since a strobe lamp is turned on. CONSTITUTION: A voltage supply unit feeds driving voltage to a strobe lamp(XE). An output switch(IGBT) is connected between a cathode of the strobe lamp and a terminal of a ground voltage(GND). The output switch turns on the strobe lamp by turning on when an external trigger signal(TRIG) is a first logical status. The output switch turns off the strobe lamp by turning off when the external trigger signal is a second logical status in opposition to the first logical status. A light receiving element(P-TR) receives DC(Direct Current) voltage(VDD) and reduces a self resistance value by comparing to the brightness of light to be reflected from an object. A capacitor(C3) charges and discharges the electricity by connecting between the light receiving element and the terminal of the ground voltage. A switch(Q1) prevents the charging of the capacitor by connecting with the capacitor in a parallel and turning on when the external trigger signal is the second logical status. A final control circuit turns off the output switch when the charged voltage of the capacitor is over a reference voltage though the external trigger signal is the first logical status. Thereby, a number of circuit elements are reduced and the control accuracy is increased.

Description

Strobe control appaparus where triger signal is effectively used

The present invention relates to an apparatus for controlling a strobe of a camera, and more particularly, a strobe for illuminating a subject by turning on the strobe lamp of the camera and turning off the strobe lamp according to the amount of illumination to the subject. It relates to a control device.

Conventional strobe control device For example, according to the strobe control device of US Patent No. 6,535,692, since the electrical energy from the light-receiving element that operates before the strobe lamp is turned on and accumulates, the problem of inferior control accuracy have. In addition, since the operation of the strobe lamp is controlled due to the operation of only the light receiving element, there is a problem that many circuit elements are used.

The present invention was devised to solve the above problems, and by effectively using an external trigger signal together with the light receiving element, the number of circuit elements is reduced, and from the time when the strobe lamp is turned on from the light receiving element. It is to provide a strobe control device capable of accumulating electrical energy to increase the precision of control.

1 is a view showing the configuration of a strobe control device according to the present invention.

2 is a timing diagram illustrating operation of the apparatus of FIG. 1.

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

XE ... strobe lamp, GND ... ground voltage,

TRIG ... trigger signal, IGBT ... gate-isolated-bipolar-transistor,

P-TR ... photo-transistor, VBATT, VDD ... DC voltage,

OSC ... oscillation control signal, P-TR ... photo-transistor,

GEN ... oscillator, TRG ... trigger,

C1 to C4 ... capacitor, Q1 to Q3 ... transistor,

T1 ... transformer, COMP ... comparator.

The present invention for achieving the above object is a strobe control device for turning on the strobe lamp (XE) of the camera to irradiate the subject and to turn off the strobe lamp (XE) in accordance with the amount of illumination to the subject And a voltage supply unit, an output switch IGBT, a light receiving element P-TR, a capacitor C3, a switch Q1, and a final control circuit.

The voltage supply unit applies a driving voltage to the strobe lamp XE. The output switch IGBT is connected between the cathode of the strobe lamp XE and the terminal of the ground voltage GND, and is turned on when the external trigger signal TRIG is in a first logic state. When the strobe lamp XE is turned on and the external trigger signal TRIG is in a second logic state that is opposite to the first logic state, the strobe lamp XE is turned off to turn off the strobe lamp XE. Off. The light receiving element P-TR is applied with a DC voltage VDD at one end thereof, and has its resistance lower in proportion to the brightness of light reflected from the subject. The capacitor C3 is connected between the other end of the light receiving element P-TR and the terminal of the ground voltage GND to perform charging and discharging. The switch Q1 is connected in parallel with the capacitor C3 and is turned on when the external trigger signal TRIG is in the second logic state to prevent charging of the capacitor C3. The final control circuit turns off the output switch IGBT even if the external trigger signal TRIG is in the first logic state when the charging voltage of the capacitor C3 is equal to or greater than a reference voltage. Let's do it.

According to the strobe control device of the present invention, the external trigger signal (TRIG) is effectively used together with the light receiving element (P-TR) by being involved in the operation of the output switch (IGBT) and the switch (Q1), The number of circuit elements may be reduced, and electrical energy may be accumulated from the light receiving element P-TR from the time point at which the strobe lamp XE is turned on, thereby increasing control accuracy.

Hereinafter, preferred embodiments according to the present invention will be described in detail.

Referring to FIG. 1, the strobe control device according to an embodiment of the present invention turns on the strobe lamp XE of the camera to illuminate the subject and turns off the strobe lamp XE according to the amount of illumination to the subject. (Off), the voltage supply unit, the output switch (IGBT), the light receiving element (P-TR), the third capacitor (C3), the PNP type first bipolar transistor (Q1) as the switch, the trigger unit (TRG) , And final control circuitry.

The voltage supply unit applies a driving voltage to the strobe lamp XE. The output switch IGBT is connected between the negative pole of the strobe lamp XE and the terminal of the ground voltage GND, and is turned on when the external trigger signal TRIG is in a high logic state, and the strobe lamp XE is turned on. ) Is turned on and is turned off when the external trigger signal TRIG is in a low logic state to turn off the strobe lamp XE. The light receiving element P-TR is applied with a DC voltage VDD at one end thereof, and has its resistance lower in proportion to the brightness of light reflected from the subject. The third capacitor C3 is connected between the other end of the light receiving element P-TR and the terminal of the ground voltage GND to perform charging and discharging. The PNP type first bipolar transistor Q1 is connected in parallel with the third capacitor C3, and is turned on when the external trigger signal TRIG is in the second logic state to prevent charging of the third capacitor C3. . When the charging voltage of the third capacitor C3 is equal to or greater than the reference voltage, the final control circuit turns off the output switch IGBT even though the external trigger signal TRIG is in a high logic state.

Accordingly, the external trigger signal TRIG is effectively used together with the light receiving element P-TR through the operation of the output switch IGBT and the PNP type first bipolar transistor Q1, thereby reducing the number of circuit elements. When the strobe lamp XE is turned on, electrical energy from the light receiving element P-TR is accumulated, thereby increasing the accuracy of the control.

As the strobe lamp XE, xenon lamps are used. Pulses synchronized with each other are periodically applied to the anode, trigger electrode, and cathode of the xenon lamp XE. The voltage of the pulses applied to the anode of the xenon lamp XE is lower than the voltage of the pulses applied to the trigger electrode and higher than the voltage of the pulses applied to the cathode.

The voltage supply part includes an oscillator part GEN, a diode D1 as a half-wave rectifier, a first resistor R1, a booster part C1 and T1, and a second capacitor C2. The oscillator GEN, which operates only while the external oscillation control signal OSC is in a high logic state, converts a DC voltage VBATT of 2.4 to 6 volts (V), which is commonly used, into an alternating voltage, and then converts the voltage into 300 volts (V). Step up). The diode D1 has its output terminal connected to the anode of the xenon lamp XE, and half-wave rectifies the AC voltage from the oscillation section GEN to output the positive pulses. The first resistor R1 is connected between the output terminal of the diode D1 and the cathode of the xenon lamp XE to lower the voltage of the positive pulses from the diode D1 and apply it to the cathode of the xenon lamp XE. do. The boosting units C1 and T1 including the first capacitor C1 and the transformer T1 are connected between the negative electrode of the xenon lamp XE and the trigger electrode, so that the voltage of the positive pulses from the half-wave rectifier D1 can be obtained. It raises and applies to the trigger electrode of xenon lamp XE. One end of the first capacitor C1 of the boosting units C1 and T1 is connected to the first resistor R1 to accumulate electrical energy from the first resistor R1. The transformer T1 of the boosting units C1 and T1 is connected between the other end of the first capacitor C1 and the trigger electrode of the xenon lamp XE, so that the voltage from the first capacitor C1 is 3.5 kilo-volts. Raised to (KV) and applied to the trigger electrode of the xenon lamp (XE). The second capacitor C2 is connected between the anode of the xenon lamp XE and the terminal of the ground voltage GND to accumulate electrical energy and remove noise.

The trigger unit TRG increases the voltage of the high logic state of the external trigger signal TRIG such that the output switch IGBT is turned on by the voltage of the high logic state of the external trigger signal TRIG. .

As an output switch (IGBT), an NPN type gate-insulated-bipolar transistor is used. The collector of the NPN type gate-insulation-bipolar-transistor (IGBT) is connected to the cathode of the strobe lamp (XE). The emitter of the NPN type gate-insulation-bipolar-transistor (IGBT) is connected to the terminal of the ground voltage (GND). The gate of the NPN type gate-insulation-bipolar-transistor IGBT is connected to the trigger portion TRG and the output terminals of the final control circuit.

A photo-transistor is used as the light receiving element P-TR. The collector of this photo-transistor P-TR is connected to the terminal of the power supply voltage VDD. The third capacitor C3 is connected between the emitter of the photo-transistor P-TR and the terminal of the ground voltage GND. The amount of current generated at the base of the photo-transistor P-TR is proportional to the brightness of light reflected from the subject.

The final control circuit includes a comparator COMP, an NPN type second bipolar transistor Q2, and an NPN type third bipolar transistor Q3. The negative input terminal (-) of the comparator COMP is connected to the emitter of the photo-transistor P-TR. A reference voltage is applied to the positive polarity input terminal + of the comparator COMP. The output terminal of the comparator COMP is connected to the base of the NPN type second bipolar transistor Q2. The emitter of the NPN type second bipolar transistor Q2 is connected to the terminal of the ground voltage GND. The collector of the NPN type second bipolar transistor Q2 is connected to the base of the NPN type third bipolar transistor Q3. The emitter of the NPN type third bipolar transistor Q3 is connected to the terminal of the ground voltage GND. The collector of the NPN type third bipolar transistor Q3 is connected to the base of the NPN type gate-insulation-bipolar transistor IGBT and the output terminal of the trigger portion TRG.

The operation of the apparatus of FIG. 1 will be described with reference to FIGS. 1 and 2 as follows. In FIG. 2, reference numeral OSC denotes an oscillation control signal input to the oscillator GEN, V _C2 denotes a charging voltage of the second capacitor C2, and TRIG denotes an output switch IGBT and a PNP type first bipolar transistor Q1. The external trigger signal involved in the operation of V _C denotes the voltage at point c in FIG. 1, Va denotes the voltage at point a in FIG. 1, and V b denotes the voltage at point b in FIG. 1.

In the time t1 to t2 when the oscillation control signal OSC is in the state of the high logic voltage V _H1 , the oscillator GEN outputs a sine wave AC voltage of 300 volts (V), and the diode D1 is the oscillator GEN. A half-wave rectified AC voltage from) outputs positive pulses. Accordingly, the second capacitor C2 accumulates electrical energy from the diode D1, and a driving voltage is applied to each electrode of the xenon lamp XE. However, since the trigger signal TRIG is in the state of a low logic voltage of the ground voltage GND, a low logic voltage is output from the trigger section TRG through the eighth resistor R8, so that the NPN gate-insulation-bipolar- Transistor IGBT and xenon lamp XE are off.

On the other hand, at the times t1 to t3 and t7 to t10 when the trigger signal TRIG is in the state of the low logic voltage at which the ground voltage GND is, the PNP type first bipolar transistor Q1 is turned on. Electrical energy applied to point a by the operation of the transistor P-TR is bypassed through the PNP type first bipolar transistor Q1. Accordingly, since electrical energy is not accumulated in the third capacitor C3, electrical energy from the photo-transistor P-TR may be prevented from being accumulated before the strobe lamp XE is turned on. In addition, since a voltage lower than the reference voltage is applied to the negative input terminal of the comparator COMP, a high logic voltage is output from the comparator COMP so that the NPN type second bipolar transistor Q2 is turned on. The NPN type third bipolar transistor Q3 is turned off. However, since a low logic voltage is output from the trigger portion TRG through the eighth resistor R8, the NPN type gate-insulation-bipolar transistor IGBT and the xenon lamp XE are turned off.

In time t2-t3, the 2nd capacitor C2 is fully charged and a drive voltage is applied to the anode of xenon lamp XE.

Next, at the time t3 at which the trigger signal TRIG is switched to the state of the high logic voltage V _H3 , the PNP type first bipolar transistor Q1 is turned off, so that the photo-transistor P-TR is turned off. By operation, electric energy applied to point a begins to accumulate in the third capacitor C3. Here, since the charging voltage of the third capacitor C3 applied to the negative input terminal of the comparator COMP is lower than the reference voltage, a high logic voltage is output from the comparator COMP, so that the NPN type second bipolar transistor Q2 is output. Is turned on, and the NPN type third bipolar transistor Q3 is turned off. In addition, since a high logic voltage is output from the trigger portion TRG through the eighth resistor R8, the NPN type gate-insulation-bipolar-transistor IGBT and the xenon lamp XE are turned on.

Next, when the brightness of light reflected from the subject is high and the charging voltage Va of the third capacitor C3 becomes higher than the reference voltage V _REF at time t4, the logic voltage lower from the comparator COMP from time t4. (See Vb) is output, the NPN type second bipolar transistor Q2 is turned off, and the NPN type third bipolar transistor Q3 is turned on. As a result, the current flowing from the trigger unit TRG through the eighth resistor R8 is bypassed to the NPN type third bipolar transistor Q3, so that the trigger signal TRIG has a high logic voltage V _H3 . In spite of the state of, a low logic voltage is applied to the gate of the NPN type gate-insulation-bipolar-transistor (IGBT) (see Vc). Accordingly, since the NPN type gate-insulation-bipolar transistor IGBT is turned off, the xenon lamp XE is also turned off.

Accordingly, the time t3 to t4, t3 to t5, or t3 to t6 when the xenon lamp XE is turned off is inversely proportional to the brightness of the light reflected from the subject, that is, the amount of dimming to the subject.

The operation after the time point t7 when the trigger signal TRIG is switched to the state of the low logic voltage GND is as described above.

As described above, according to the strobe control device according to the present invention, the external trigger signal (TRIG) is involved in the operation of the gate-insulation-bipolar transistor (IGBT) and the first bipolar transistor (Q1) photo-transistor Used effectively with (P-TR). Accordingly, the number of circuit elements is reduced, and electrical energy from the photo-transistor P-TR is accumulated from the time point when the xenon lamp XE is on, so that the precision of the control can be increased.

The present invention is not limited to the above embodiments, but may be modified and improved by those skilled in the art within the spirit and scope of the invention as defined in the claims.

Claims (10)

In the strobe control device to turn on the strobe lamp (XE) of the camera to irradiate the subject and to turn off the strobe lamp (XE) in accordance with the amount of illumination to the subject, A voltage supply unit applying a driving voltage to the strobe lamp XE; It is connected between the cathode of the strobe lamp (XE) and the terminal of the ground voltage (GND), when the external trigger signal (TRIG) is a first logic state is turned on (turn on) to turn on the strobe lamp (XE) ( an output switch to turn off the strobe lamp XE when the external trigger signal TRIG is in a second logic state that is opposite to the first logic state. IGBT); A light receiving element (P-TR) having a DC voltage (VDD) applied to one end thereof and having a lower resistance value in proportion to the brightness of light reflected from the subject; A capacitor C3 connected between the other end of the light receiving element P-TR and a terminal of the ground voltage GND to perform charging and discharging; A switch (Q1) connected in parallel with the capacitor (C3) to turn on when the external trigger signal (TRIG) is in the second logic state to prevent charging of the capacitor (C3); And And a final control circuit for turning off the output switch IGBT even if the external trigger signal TRIG is in the first logic state when the charging voltage of the capacitor C3 is equal to or greater than a reference voltage. Strobe control device. The method of claim 1, The strobe lamp XE is a xenon lamp, Pulses synchronized with each other are periodically applied to the anode, trigger electrode, and cathode of the xenon lamp XE, The strobe control device having a voltage of the pulses applied to the anode of the xenon lamp (XE) is lower than the voltage of the pulses applied to the trigger electrode and higher than the voltage of the pulses applied to the cathode. The method of claim 2, wherein the voltage supply unit, An oscillation unit GEN for converting a DC voltage VBATT, which is commonly used, into an AC voltage and then boosting it; A half-wave rectifier (D1) whose output terminal is connected to the anode of the xenon lamp (XE), and half-wave rectifies the AC voltage from the oscillator (GEN) to output positive pulses; A resistor connected between the output terminal of the half-wave rectifier D1 and the cathode of the xenon lamp XE to lower the voltage of the positive pulses from the half-wave rectifier D1 to apply to the cathode of the xenon lamp XE. (R1); And And a booster connected between the negative electrode of the xenon lamp (XE) and the trigger electrode to increase the voltage of the positive pulses from the half-wave rectifier (D1) to apply to the trigger electrode of the xenon lamp (XE). The voltage boosting unit of claim 3, A capacitor C1, one end of which is connected to the resistor R1 to accumulate electrical energy from the resistor R1; And A transformer (T1) connected between the other end of the capacitor (C1) and the trigger electrode of the xenon lamp (XE) to increase the voltage from the capacitor (C1) and apply it to the trigger electrode of the xenon lamp (XE). Strobe control device. The method of claim 4, wherein the voltage supply unit, And a capacitor (C2) connected between the anode of the xenon lamp (XE) and the terminal of the ground voltage (GND) to accumulate electrical energy and remove noise. The method of claim 1, The strobe control device wherein the first logic state is a high logic state and the second logic state is a low logic state. The method of claim 6, Trigger unit TRG for increasing the voltage of the high logic state of the external trigger signal (TRIG) so that the output switch (IGBT) is turned on by the voltage of the high logic state of the external trigger signal (TRIG) Strobe control device further including). The method of claim 7, wherein The output switch (IGBT) is an NPN type gate-insulated-bipolar transistor. The collector of the NPN type gate-insulation-bipolar transistor (IGBT) is connected to the cathode of the strobe lamp (XE), An emitter of the NPN type gate-insulation-bipolar transistor (IGBT) is connected to a terminal of the ground voltage (GND), And a gate of the NPN type gate-insulation-bipolar transistor (IGBT) is connected to the trigger portion (TRG) and output terminals of the final control circuit. The method of claim 8, The light receiving element P-TR is a photo-transistor, The collector of the photo-transistor P-TR is connected to the terminal of the power supply voltage VDD, The capacitor C3 is connected between the emitter of the photo-transistor P-TR and the terminal of the ground voltage GND, The strobe control device in which the amount of current generated at the base of the photo-transistor (P-TR) is proportional to the brightness of light reflected from the subject. The method of claim 9, The final control circuit comprises a comparator (COMP) and two NPN type bipolar transistors (Q2, Q3), The negative input terminal (-) of the comparator COMP is connected to the emitter of the photo-transistor P-TR, A reference voltage is applied to the positive input terminal (+) of the comparator COMP, The output terminal of the comparator COMP is connected to the base of the NPN bipolar transistor Q2, An emitter of the NPN bipolar transistor Q2 is connected to a terminal of the ground voltage GND, The collector of the one NPN bipolar transistor Q2 is connected to the base of the another NPN bipolar transistor Q3, The emitter of the another NPN type bipolar transistor Q3 is connected to the terminal of the ground voltage GND, And a collector of the another NPN type bipolar transistor (Q3) is connected to the base of the NPN type gate-insulation-bipolar transistor (IGBT) and the output terminal of the trigger portion (TRG).