KR930002353Y1 - Autofocus controlling circuit for camera - Google Patents

Abstract

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Description

Camera auto focus control circuit

1 is a focus control circuit diagram of a conventional camera.

2 is an automatic focusing circuit diagram of the camera of the present invention.

* Explanation of symbols for main parts of the drawings

1: oscillator 2: charge control unit

3: focus signal generator 4: strobe

5: focus driving unit 6: focus detecting unit

7: comparison unit 8: focus control unit

The present invention relates to the automatic focus control of the camera, in particular, to measure the distance quickly in the continuous shooting of the subject, even when shooting a certain time after the lens cover is open completely the distance of the camera It relates to an automatic focus control circuit.

As shown in FIG. 1, the focusing control circuit of the conventional camera has a transformer T1 and a resistor for outputting an oscillation voltage by inputting the DC voltage of the battery BT by switching the switch SW1. Oscillator 1 consisting of R1 and the output voltage of the oscillator 1 are full-wave rectified to drive the neon lamp NE1, and output a direct current power supply diode (D1-D3), capacitor (C1) and resistor (2) a charge coil (2) consisting of (R2) and (R3), a trigger coil (T2) and a xenon lamp (3a) which charge the output voltage of the charge control unit (2) and irradiate light by switching the switch (SW1). And a trigger coil for charging the focus signal generator 3 of the condenser C2 and the output voltage of the charging control unit 2 and irradiating light by on-off control of the shutter switch SW2 when photographing a subject. (T3), xenon lamp (4a), Zener diode (ZD1) and the strobe part (4) consisting of the capacitor (C3) (C4) by switching between the switch (SW1) A focus driver 5 consisting of an SCR1, a resistor R5, an R6, and a capacitor C5, which is positioned and discharges the voltage charged in the focus signal generator 3, and a direct current of the battery BT. A focus detector comprising a capacitor C6, C7, a resistor R7, a variable resistor VR1, and a phototransistor PT1 for driving an optical signal to the optical signal of the focus signal generator 3 reflected from a subject. 6) and a comparator (7) comprising a comparator (CP1), a capacitor (C8) and a resistor (R8) and (R9) for comparing the output voltage of the focus detection unit 6 and outputting a control voltage according thereto; Transistor (TR1), condenser (C9) and (C10) for charging the battery BT and switching on / off according to the output signal of the comparator 7 to control the lens by switching the switch SW1. And a focus control unit 8 composed of a diode D4 and a solenoid SOL.

The operation of the focusing circuit of the conventional camera configured as described above and the problems thereof will be described as follows.

First, when the movable terminal a of the switch SW1 is switched to the fixed terminal b, the DC power source of the battery BT passes through the movable terminal a and the fixed terminal b of the switch SW1 and then the oscillating unit ( The oscillation voltage applied to the primary coil L1 of the transformer T1 configured in 1) causes the transformer T1 to oscillate, and the oscillation voltage induced by the secondary coil L2 of the transformer T1 is charged. After half-crystallization through the diode D1 of 2), the neon lamp NE1 is made to emit light through the resistor R2. In addition, the oscillation voltage induced in the transformer T1 of the oscillation unit 1 is half-wave rectified through the diode D2 of the charge control unit 20 and charged in the condenser C2 of the focus signal generation unit 3. Half-wave rectified through D3 is charged in the condenser C3 of the stroboscope 4. After the charging is completed and the movable driver a of the switch SW1 is switched to the fixed terminal c, the DC power supply of the battery BT is connected to the resistors R6 and R5 and the capacitor C5 of the focus driver 5. Is applied to the gate of the SCR1 through the SCR1 to turn on the SCR1 and is charged to the condenser C10 of the focus control unit 8, and the S of the focus drive unit 5 is applied to the gate of the SCR1. When the seed SCR1 is turned on, the voltage charged in the condenser C2 of the focus signal generator 3 is bypassed through the resistors R3 and SCR1, and the turns ratio of the trigger coil T2 The boosted voltage turns on the xenon lamp 3a, and at that moment, the voltage charged in the capacitor C2 causes the xenon lamp 3a to emit light instantaneously, so that the optical signal emits light to the subject. The optical signal transmitted from the xenon lamp 3a is incident on the phototransistor PT1 of the focus detection unit 6 which is reflected from the target body again. In this case, when the reflected optical signal is many, that is, in the near field, the phototransistor PT1 is Since the DC power of the battery BT is bypassed through the phototransistor PT1 and the condensate C7, the low resistance is applied to the variable resistor VR1, and the low potential is compared to the comparator. Since the comparator CP1 is applied to the non-inverting terminal (+) of the comparator CP1 configured in (7), the comparator CP1 is compared with the voltage applied to its inverting terminal (-) through the resistor R7 and the capacitor C8. The low potential is output through the output terminal and the resistor R9 to turn on the transistor TR1 of the focus controller 8. Therefore, the solenoid SOL adjusts the lens by driving the solenoid SOL through the turned-on transistor TR1 through the DC power supply of the battery BT and the voltage charged in the capacitor C10 through the switch SW1. Done.

However, in the conventional camera focus control circuit, a neon lamp for notifying the oscillation is used on the strobe part, the charging is completed after a certain period of time, the neon lamp is turned off. However, if you take a picture after the predetermined time is warned with the lens cover open, press the shutter release button halfway again, check the lighting of the neon lamp, and take the picture before recharging the capacitor to the focus signal generator. There is a problem that the autofocus function is deteriorated when shooting while forgetting this fact.

In view of the above problems, the present invention connects the condenser of the stroboscopic unit with the condenser of the focus signal generator with a resistor, and then, during continuous shooting of the subject, the voltage charged in the condenser of the stroboscopic unit flows through the condenser of the focus signal generator to the subject more accurately. In addition to measuring the distance and to measure the more accurate distance to devise, when described in detail based on the accompanying drawings of the present invention as follows.

2 is an automatic focus control circuit diagram of the present invention, as shown in the figure, a transformer (T1) and a resistor for outputting an oscillation voltage by inputting the DC voltage of the battery BT by switching of the release switch SW1. A diode D1-D3, a condensate C1, which drives the neon lamp NE1 by full-wave rectifying the oscillation section 1 of R1 and the output voltage of the oscillation section 1; The trigger coil T2 and xenon which charge the output voltage of the charge control unit 2 and the charge bearing unit 2 made of resistors R2 and R3 and irradiate light by switching the release switch SW1. The focus signal generator 3 comprising the lamp 3a, the condenser C2, and the resistor R4, and the output voltage of the charge control unit 2 are charged, and the shutter switch SW2 and the release switch when photographing a subject ( Trigger coil T3 and xenon ram which irradiate light and discharge the charging voltage to the focus signal generator 3 under the control of SW1). (4a), the strobe part 4 composed of the zener diode ZD1 and the condenser C4 and the switch switched by the release switch SW1 to invert the voltage charged in the focus signal generator 3; The focus driver 5 consisting of a seed SCR1, a resistor R6, a resistor R7, and a capacitor C5 and a focus signal generator 3 driven by a DC voltage of the battery BT and reflected from a subject are reflected. By comparing the output voltages of the focus detector 6, which is composed of a capacitor C6 (C7), a resistor R8, a variable resistor VR1, and a phototransistor PT1 for detecting an optical signal, The voltage of the battery BT is changed by comparing the comparator 7 including the comparator CP1, the capacitor C8, and the resistors R9 and R10 and the release switch SW1. In addition to charging, transistors TR1, capacitors C9, C10, diodes D4, and solenoids SOL are switched on and off according to the output signal of the comparator 7 to adjust the lens. It is configured as the focused focusing unit 8. Referring to the operation, effects of the present invention configured as described above are as follows.

First, when the movable terminal (a) of the release switch (SW1) is switched to the fixed terminal (b), the DC power of the battery (BT) through the release switch (SW1) of the transformer (T1) configured in the oscillation section (1) The transformer T1 is applied to the primary coil L1 to oscillate, and the oscillation voltage induced by the secondary coil L2 of the transformer T1 is transferred through the diode D1 of the charge controller 2. Half-wave rectified, half-wave rectified through the resistor R2, charged to the capacitor C2 of the focus signal generator 3, and half-wave rectified through the diode D3, and then the capacitor C4 of the stroboscopic portion 4 The capacitor C4 is charged. After the charging is completed and the movable terminal (a) of the release switch (SW1) is switched to the fixed terminal (c), the DC power supply of the battery BT is the capacitor (R7) (R6) of the resistor (R7) (R6) of the focus driver (5). C5) turns on the SCR1 and charges the capacitor C10 of the focus control unit 8, and turns on the SCR1 of the focus drive unit 5 at the turn-on. The voltage charged in the condenser C2 of the focus signal generator 3 is bypassed through the resistor R3 and the turned-on SCR1, and the boost voltage due to the turns ratio of the trigger coil T2 is xenon. The lamp 3a is turned on, and at that moment, the voltage charged in the capacitor C2 causes the xenon lamp 3a to emit light.

At this time, in the case of continuous autofocusing, the voltage charged in the capacitor C3 of the stroboscopic unit 4 instantaneously emits the xenon lamp 3a through the resistor R4 of the generating unit 3 again, ( R4 < R5) at the same time the optical signal is projected to the subject.

The optical signal transmitted from the xenon lamp 3a is reflected from the subject again and is incident on the phototransistor PT1 of the focus detection unit 6. Since the DC power of the battery BT is bypassed to ground through the phototransistor PT1 and the capacitor C7, the low potential through the variable resistor VR1 is configured in the comparator 7. It is applied to the non-inverting terminal (+) of the comparator CP1. Therefore, the comparator CP1 compares the voltage input from the inverting terminal (-) and outputs a low potential through its output terminal and the resistor R10 to turn on the transistor TR1 of the focus controller 8. Accordingly, the power of the battery B through the release switch SW1 and the voltage charged in the condenser line C10 drive the solenoid SOL through the turned-on transistor TR1 so that the solenoid ( SOL) continuously adjusts the lens accurately, and when the shutter switch SW2 is turned on, the voltage charged in the capacitor C4 of the stroboscope 4 is triggered by the resistor R5 and the capacitor C3. Since the coil T3 is excited and the trigger coil T3 turns on the fresh xenon lamp 4a, the voltage charged in the capacitor C4 causes the xenon lamp 4a to emit light.

As described in detail above, the present invention connects the condenser of the focus signal generator and the condenser of the strobe to emit a focus control xenon lamp with a voltage charged to the condenser of the strobe, so that the distance of the subject can be measured more quickly during continuous shooting. In addition, the lens cover is open, even if a certain time has passed after the shooting has the effect of accurate distance ranging.

Claims (1)

By switching the release switch SW ₁ , the oscillator 1 receives the DC power of the battery BT and outputs an oscillation voltage, and rectifies the output voltage of the oscillator ₁ to drive the neon lamp NE ₁ . In addition, the charge control unit 2 for outputting the DC power, and the focus signal for charging the output voltage of the charge control unit 2 in the capacitor (C ₂ ) and irradiating light by switching of the release switch (SW ₁ ) A generating unit 3, a strobe unit 4 which charges the output voltage of the charging control unit 2 to the condenser C ₃ and irradiates light under the control of the shutter switch SW ₂ , and the release switch ( A focus driver 5 for controlling the driving of the focus signal generator 3 by switching of SW ₁ ) and a focus for detecting an optical signal reflected from a subject by driving by the DC power supply of the battery BT. Comparing the output voltage of the detection unit 6 and the focus detection unit 6 and outputs a control signal accordingly. On / off according to the output signal of the comparing unit 7, and the release switch (SW ₁₎ by the switching and charging the DC power of the battery (BT) to the capacitor (C _10), the comparison unit 7 of the In the camera focus control circuit composed of a focus control unit (8) which is switched to adjust the lens, the charge (C) of the condenser (C ₃ ) of the stroboscopic unit (4) is the capacitor (C) of the focus signal generator (3) ₂ ) A resistor R ₄ is connected between the capacitors C ₃ and C ₂ so as to flow into the capacitor C, and the focus signal generator 3 is driven by the capacitor C ₂ during continuous shooting. Auto focusing circuit of the camera, characterized in that configured to.