DE2846857A1 - Electronic flash for automatic camera - is coupled to transistor circuit to override camera exposure timing - Google Patents

Abstract

The electronic flash (FL) is used for a photographic camera with an exposure control circuit responsive to the selected exposure, the film sensitivity, the shutter diaphragm setting and the brightness of the subject. The flash tube is ignited by discharging a main capacitor and the flash is extinguished when the measured value of the reflected light from the subject reaches a preset level. A flash synchronisation exposure setting device comprises a circuit for setting the camera exposure time independent of the exposure information upon closure of a current switch (S1) for the electronic flash, so that the exposure time is determined by the flash duration.

Description

FLASH PHOTOGRAPHING DEVICE

Description The invention relates to a flash photography device, with which the exposure time of the camera changes automatically when taking a flash can be changed to a value that is suitable for such a flash exposure.

A device for controlling the exposure time is already known a camera by an electrical signal stored in a memory circuit (a known memory circuit, which is in an ordinary electrical locking circuit is provided), corresponding to an exposure time that is required for flash photography is suitable, for example 1/60 s, if a signal is supplied that indicates that the charging of a main capacitor for the storage of the flash light energy in the flash unit is completed, and also the exposure time according to the Controls the brightness of the subject to be photographed when the shutter is released before the full charge indicating signal supplied has been.

However, such a conventional device has the following shortcomings on. In the case of a flash unit with automatic flash quantity control, the in Main capacitor for flash photography stored energy to an amount consumed as it is needed for the recording, so that the capacitor still has one Contains residual energy that can be sufficient for one more flash exposure. if For example, half of the amount for object illumination when taking the first picture stored energy is consumed, the remaining half of the energy is sufficient to photograph the same object again. This fact is important when considering the recent popularity of motorized cameras. When taking flash photography with a camera having a motor drive, in which the photographing with faster exposure sequence runs when the motor drive is working, is the exposure time control, which in the conventional way on the delivery of the completion of the charge of the main capacitor is reached, is not able to to allow a quick sequence of pictures of the same object with the motor drive, while the flash exposure before the delivery of the completion of the charge Signal the risk of camera shake (a shaky picture) conceals.

The object of the present invention is therefore to provide a flash synchronization exposure time setting device to make them available for use in a flashlitht apparatus which on closing a power or current switch of the flash unit towards the exposure time controls to a value suitable for flash photography, thereby reducing flash photography of an object that is at a relatively short distance or relatively well is lit, can be made possible without having to complete the charge of the main capacitor has to wait when a sequence of recordings is possible, such as in the case of using a motor drive.

An additional task is to solve the named task Flash sync exposure time setting device to make available the additionally has a display circuit that shows whether the exposure time is on is controlled to a value suitable for flash photography, and the Indicates the charge status of the flash unit.

The solution to this problem is characterized in claim 1 and in the subclaims advantageously developed.

In the following, the invention is explained in more detail on the basis of embodiments explained. In the drawing show: Fig. 1 is a circuit diagram of a Flash device which can be used for the present invention; Fig. 2 shows a circuit diagram of an embodiment according to the invention; and Fig. 3-5 circuit diagrams further embodiments according to the invention.

Fig. 1 shows a circuit diagram of a flashlight device with automatic Flash quantity control. A main capacitor C1 is activated upon the closing of a power switch S1 charged out from an energy source El in order to generate electrical energy from flash to save. In addition, a quenching capacitor C2 is used at the same time Charged via resistors R1, R2 to store electrical energy that is in is used to terminate lightning in a manner explained below.

After the capacitors Cl, C2 have been fully charged, it will turn on Synchronization switch S2 closed, with a shutter release button of the Camera is connected, an ignition circuit 1 sends an ignition current to the primary coil P of an ignition transformer 2 supplied to its secondary coil S a high voltage to create. On closing the Synchronization switch S2 towards the ignition circuit 1 also gives a pulse to activate a controlled Silicon rectifier (SCR) D1. As a result, the main capacitor C1, from one Flash tube FT and formed by the SCR D1 a closed circuit, so that the flash tube FT flashes lightning due to the electrical energy supplied by the main capacitor C1 sends out. The flash emitted to illuminate the object to be photographed is partially reflected from this object and from a light receiving element D2 caught. An integrating circuit 3 integrates its output signal and is a pulse to activate a silicon controlled rectifier D3 when the time-integrated signal reaches a predetermined value. This will the controlled silicon rectifier (SCR) D3 conductive, so that the quenching capacitor C2 connected between the anode and cathode of the already conductive SCR D1 iwrd. Of the In this way reversely biased SCR D1 is therefore switched off, so that the Flash emission from the flash tube FT is terminated. This way it becomes an automatic Flash quantity control or automatic control of the quantity of the emitted flash light achieved according to the brightness of the light to be photographed.

Fig. 2 shows a circuit diagram of an embodiment according to the invention.

A flash unit FL can be removed from a camera CM.

In the flashlight unit FL there is an energy source El, whose positive Electrode through a current switch S1 and a resistor R10 with a terminal T1 and its negative electrode is connected to a connection T2.

A block 5, the closing of the power switch from the Energy source El receives electrical energy, comprises the flash light circuit arrangement shown in FIG with the exception of the energy source El, the current switch S1 and the synchronization switch S2. The block 5 is also connected to a connection T3 via which the block 5 is connected to the synchronization switch S2, which in this embodiment provided on the camera.

The camera CM contains an exposure time control circuit of the so-called. TTL direct light measurement method for automatic control of the exposure time Measure the object light from the shutter curtain and / or from the photographic Film is reflected after the shutter is released.

Connections T4, T5 and T6 are provided on the camera, which correspond to the Connections T1, T2 or T3 on the flash unit and with the base a transistor Q1-l, the negative pole of an energy source E2 and the emitter of the transistor Q1-1 and the synchronization switch S2 are connected. The collector of transistor Q1-1 is over a resistor R20 with the positive one Pole of the energy source E2 connected. If by attaching the flash unit on the camera the connections T1 to T3 with the respective one of the connections T4 to T6 are connected, the transistor i1-1 is in the OFF state when the power switch is open and in the ON state when the power switch Si is closed so that the base of the transistor Ql-l through the resistor R10 to the positive pole of Energy source El is connected. The camera function of the automatic exposure control and the camera function of flash photography become according to the ON and OFF states of transistor Q1-1 is selected.

A trigger switch S4 is in connection with the shutter release process opened and closed upon completion of the buckle cocking. This switch is connected in parallel with a capacitor C3. A photoelectric conversion element 10 forms a series circuit with the capacitor C3, that with a transistor Q2 is connected. A resistor R31 forms another with the capacitor C3 Series circuit connected to a transistor Q3. The connection point between the capacitor C3, the photoelectric conversion element 10 and the resistor R21 is also connected to an input terminal (-) of a comparator A1-1.

A variable resistor R22 is used to generate a first voltage, which corresponds to exposure information such as film speed or lens aperture. The first voltage is applied to the other via a field effect transistor (FET) Q4 Input terminal (+) of the comparator Al-l given. At the connection point between Resistors R23 and R24 will maintain a constant second voltage for a Exposure time generated for a flash exposure. This second tension becomes via an FET Q5 also to the other input terminal (+) of the comparator Al-l given.

The output signal of the comparator A1-1 controls a magnet MG, that holds the trailing shutter curtain. A transistor Q6 is also provided, which is controlled on-off by transistor Q1-1, in one of the transistor Q1-1 each reversed state.

m In the case of a picture taken with automatic exposure control at on the camera attached to the flash unit, the power switch S1 is kept open, to turn transistor Q1-1 off and thereby turn transistor Q6 on, whereby the transistor Q3 and the FET Q5 are both held in the OFF state. If the transistor Q1-1 is in the OFF state, on the other hand, are the transistor Q2 and the FET Q4 both in the ON state. As a result, the (+) input terminal of the Comparator Al-1 alone the first voltage. On the other hand, if the trigger switch S4 closed before the shutter was released is received by the comparator A1-1 at its (-) - input connection the positive voltage of the energy source E2, so that it emits an output signal of low value, whereby the magnet MG is energized to hold the trailing shutter curtain.

When the shutter is released, it starts running at the same time of the leading shutter curtain, the trigger switch S4 opened, so that by the capacitor C3 and the photoelectric conversion element 10 form an integrating circuit is formed, the resistance value of the photoelectric conversion element 10 is variable and depends on that object light that is from the leading shutter curtain and / or is reflected from the photographic film during exposure. Consequently becomes the charging time constant of the capacitor C3 as a function of the brightness of the object to be photographed. At the beginning of the charging of the capacitor C3 towards the (-) - input terminal of the comparator A1-1 receives an integrated voltage, which gradually decreases from the positive voltage of the energy source E2. If the The comparator A1-1 inputs voltages at the input terminals High level output signal to de-energize magnet MG. The trailing one The shutter curtain is released and begins to run. In this way becomes an automatic control of the exposure time by a TTL direct light measuring method accomplished. In this moment the synchronization switch S2 closed. However, the block 5 remains inoperative because the power switch St is open so that no flash is generated.

In the case of a flashlight pickup, the power switch is on the flashlight unit FL closed so that transistor Q1-1 is turned on. This will make the Transistors Q2, Q5 and FET Q4 are all turned OFF, as is the transistor Q6 is turned OFF so that FET Q5 and transistor Q3 are turned on will. When the trigger switch S4 is opened, the comparator A1 receives it at its (-) input terminal an integrated voltage from the capacitor C3 and the resistor R21 composite integrating circuit while working on his (-) input terminal has a constant voltage determined by resistors R23 and R24 receives. The exposure time from opening the trigger switch S4 to de-excitation of the magnet MG is kept constant, regardless of the object brightness, the film speed or the lens aperture. For this constant exposure time a value is selected with which the flash unit can be synchronized, for example 1/60 s.

When the synchronization switch S2 is closed, it radiates the Flash unit off a flash for illuminating the object, and the flash It stops when the amount of reflected light reaches a predetermined value achieved as previously explained. -Fig 3 shows a circuit diagram of another embodiment of the invention. In this, the camera includes a circuit for Control of the exposure time depending on the measurement of the object light, which has passed through the subject and is closed by means of a mirror a Pentagon prism has been reflected.

When the power switch S1 is closed, the started in the main capacitor contained in block 5.

A neon lamp L1 remains before this main capacitor completes charging extinguished and lights up after the completion of this charge. Before the full When the capacitor is charged, transistors Q10 and Q11 are thus in the state OFF or ON, whereby the voltage between the terminals T1 and T2 by a Diode D11 and the transistor Q11 is fixed so that a light emitting diode D12 cannot emit light.

On the other hand, closing the power switch S1 holds a transistor 01-2 is in the ON state even when the transistor QII is in the ON state. Through this become a transistor Q12 and a FET Q13 is turned off and becomes a FET Q14 switched on. Consequently, the (+) input terminal of a comparator is obtained A2-1 a constant voltage resulting from the supply of a current from a constant current source I1 to a diode D13 results, i. i.e., a voltage proportional to the logarithm of the current of the constant current source.

This voltage is used to control the exposure time on one for Flash photography is used.

If the trigger switch S4 is closed before the shutter release process, the (-) - input terminal of the comparator A2-1 receives a positive voltage of the Energy source E2, whereby the magnet MG remains in the excited state to the trailing To hold fastener curtain.

Upon completion of charging of the main capacitor at which the neon lamp L1 lights up, the transistors Q10 and Q11 are switched on or off, so that the light emitting diode D2 is lit to indicate the completion of charging of the main capacitor on the camera, for example in its viewfinder. In this case, the transistor Q1-2 remains in the ON state.

When the shutter is released after a complete display The trigger switch s4 is charged at the same time as the preceding one starts running Shutter curtain opened to over charge a capacitor C5 one Diode D14 to begin. The voltage to which this capacitor C5 is charged is is proportional to the logarithm of the charging time and is applied to the (-) input terminal of the comparator A2-1 given, which when the input voltages at its input terminals reach a predetermined relationship, the magnet MG de-energizes to stop draining to trigger the trailing shutter curtain. Between the expiry of the preceding The shutter curtain and the trailing shutter curtain become the synchronization switch S2 closed to a flash emission and an automatic flash light quantity control to reach. In the manner explained, the flash exposure is carried out with a for this purpose suitable exposure time carried out, for example at an exposure time from 1/60 s.

Turning off the power switch S1 turns the transistor Q1-2 in brought to the OFF state, and the light emitting diode D12 is turned off regardless of whether the neon lamp L1 is lit or not is extinguished, and thereby the transistor becomes Q12 and FET Q13 are both turned on, and FET Q14 is turned off. Consequently the exposure time is controlled to a value that corresponds to the voltage, to which a storage capacitor CM is charged and in a known manner a Sum corresponds to that of a voltage generated by a diode D15 and is proportional to the logarithm of a photocurrent flowing from one the object light receiving photosensitive element D15 is supplied, and from a voltage generated by a Resistor R30 as a function of exposure information, such as the film receptivity indl ility, the lens aperture usa generated, is formed. A Memory switch SM is opened in connection with the locking / loosening process, the voltage to which the storage capacitor CM is charged during the Maintain exposure control. When the power switch 5 is opened in this way an automatic control of the exposure time is dependent carried out by the brightness of the object to be photographed.

In this second embodiment, the light emitting one lights up Diode D12 only on when the charging of the main capacitor is complete while the current switch S1 is closed. It doesn't light up when the power switch is on 1 is open even if the main capacitor is already charged. Consequently shows the light-emitting diode D12 lights up to indicate that the Main capacitor is completed and that the power switch 1 is closed State is, d. That is, the exposure time is already at one for flash photography appropriate value is set. And also shows the light emitting diode D12 a state by its non-lighting in which the exposure time according to the exposure information including the object brightness, the Film speed, lens aperture, etc. is controlled. Fig. 4 shows a further embodiment according to the invention, in which separate displays for that the current switch si is closed, and that the charging of the main capacitor is completed, are provided.

The light-emitting devices connected between the connections T4 and T5 Diodes D20 and D21 have different lighting voltages. The luminous voltage of diode D20 can be made lower than that of diode D21 by For example, a light-emitting GaAsP diode for D20 and a light-emitting diode for D21 GaP diode used. When the power switch S1 is closed, charging is started of the main capacitor initiated simultaneously with the switching on of one Transistor Q1-3, which works in the same way as transistor Q1-1. As long as the Neon lamp S1 does not light up until fully charged, the transistors are Q20 and Q21 switched off or on. For this state it is assumed that the Forward voltage drop in the diodes D22 to D24 is greater than the luminous voltage the light emitting diode D20, however lower than that of the light emitting diode D21.

In this way, the light emitting diode D20 becomes luminous brought to indicate that the power switch is closed, namely that the Exposure time set to a value by turning on transistor Q1-3 suitable for flash photography.

Thereafter, after the completion of charging, the neon lamp L1 comes on Main capacitor lights up so that transistor Q20 is turned on and the transistor Q21 is turned off. This will make the light-emitting Diodes D20, D21 from a voltage clamp through the diodes D22 to D24 lind the Transistor Q21 frees and light up. This closes the power switch or the completion of charging is displayed. The transistor also remains in this state Q1-3 in the ON state.

In this embodiment, block 7 provides an exposure time control circuit similar to those shown in Figs.

Fig. 5 shows a further embodiment of the present invention, in which the closing of the power switch S1 and the completion of charging by a single light emitting diode can be displayed. A transistor Q30 is turned on, when the neon lamp L1 is on completion of charging of the main capacitor lights up, and it is switched off when this neon lamp L1 goes out.

A logic circuit G1 is activated on the transistor Q30 opened to receive pulses from a pulse generator OSC to a transistor Q31 to be transmitted, with the transistors Q30 and Q31 between the terminals T1 and T2 are connected to control the voltage between here. Also between the connections T4 and T5 a light emitting diode D32 is connected.

To the closing of the power switch S1 and the completion of charging the transistor Q30 is now switched on, so that the logic circuit G1 is opened. This causes transistor Q31 to take off due to the pulses from the pulse generator OSC periodically switches ON and OFF. Consequently, the light-emitting Diode D32 alternately lights up and extinguishes, indicating that that the current switch S1 is closed. The transistor remains in this state Q1-4 in the ON state.

If the charge is incomplete, the transistor Q30 is switched off, so that the logic circuit G1 is closed.

This turns off the transistor Q31, so that the light-emitting Diode D32 kept in a steady light state that indicates that the charge is incomplete. When the power switch 5 is in this state is opened, the light emitting diode D32 goes out regardless of whether the Charging is already completed or not.

In the previous embodiments shown in Figs can be the number of ports that the flash unit is connected to the camera will be reduced, since the information about the closing of the power switch S1 and about the completion of charging between two pairs of terminals T1, T4; T2, T5 can be transmitted.

It also shows the lighting up of a light emitting device provided on the camera Diode for the indication of the completion of the charge as well as that the exposure time is set to a value suitable for flash photography and that charging is complete.

As has been explained above, the present invention allows at which the exposure time of a camera when closing a power switch a value suitable for flash photography is set, repeated flash photography, without having to wait for a charge completion signal when the The voltage to which the main capacitor is charged is at a value sufficient for a flash exposure even if they after taking a flash exposure that follows a full charge. In addition, according to the present invention, it is made possible by an on the camera intended light emitting element such as a light emitting diode, both indicate that the power switch of the flash unit is closed and the exposure time the camera is set to a value suitable for flash photography than also indicate that charging in the flash unit is complete.

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Claims (3)

PATENT CLAIMS Flash photography device with a camera, an exposure time control circuit for automatically controlling the exposure time depending on exposure information, film speed, lens aperture and brightness of the object to be photographed, and with a Flash device that illuminates the object to be photographed with a flash, that of a discharge tube due to one stored in a main capacitor Energy is emitted, and which stops the flash when the reading of the reflected Light reaches a predetermined value, characterized by a flash sync exposure time setting device with a circuit, which the exposure time of the camera (CM) when closing a power switch (S1) of the flash unit (FL) independently of the exposure information on a for Flash photography adjusts suitable exposure time. 2. Apparatus according to claim 1, characterized in that the flash synchronization exposure time setting device a display circuit which indicates that the power switch (S1) of the flashlight device (FL) is closed. 3. Apparatus according to claim 2, characterized in that the display circuit to the closing of the power switch (S1) of the flashlight unit (FL) and upon completion of the charging of the main capacitor (C1) both closing of the power switch and the completion of charging of the main capacitor able.