DE2717763C2 - Automatic exposure control system and flash unit - Google Patents

Description

60

The invention relates to an automatic exposure control system according to the preamble of Anspiuchs ^b 1 and to a flashlight device according to the preamble of the claim. 5

An automatic exposure control system and a flash device of this type are described in DE-OS 25 20 449. With conventional lighting control systems of this type, there is a problem that during an exposure process, either in daylight or in the blink of an eye, an unintentional actuation of the lighting switch can occur, so that the photographic information is changed, which in particular leads to incorrect exposure in the case of a barking control system. in which the automatic switchover is made when the spectral condenser of the photographic device reaches a sufficient charge level 1 agesH> hiaulnahme is controlled while lile Belichlunps / eli or Blendenöllnung as / lichtaulnahme at a blit μι-controls Kerner exist some possibilities for cm accidental ignition of the blit / {tube during a daylight shot, wherein a _c slit exposure may result. A drop in the charge level of the Spelcher condenser below the sufficient value can also lead to an undesired switchover.

The invention is based on the object of an automatic Exposure control system according to the preamble de ;. Claim 1 and a flash device according to the Preamble de «claim 5 to develop in such a way that the type of exposure of a recording with which the recording started while recording is being maintained.

This object is achieved according to the invention with the in the characterizing part of claim 1 and the Claim 5 specified features solved.

In this way it is ensured that a switchover of the switch and thus a change in the type of exposure during the exposure is prevented, even if the state detected at the beginning of the recording should change in such a way that a switch to the other type of exposure would be justified.

The holding circuit is advantageously put out of operation by a signal from a control device, which at Termination of recording occurs. In the case of an intended flashlight pickup using a i Motor drive that is started before a sufficient charge level of the storage capacitor or the consists of more recordings than can be carried out with one charge of the storage capacitor, daylight recordings will be carried out if the storage capacitor is insufficiently charged, whereby it is then ensured that there is no incorrect exposure during the transition from daylight exposure to flash exposure can occur.

The invention is illustrated below with the aid of exemplary embodiments explained in more detail with reference to the drawing.

Flg. 1 and 2 together show a partial block representation The detailed schematic diagram of an embodiment of the automatic exposure control system for daylight and flashlight photography, with the "part of the circuit" built into a camera in FIG and in F1 g. 2 the part built into a flash unit is shown:

Flg. 3 shows an example of a modification of the circuit according to FIG. 2 by means of a normal / and voltage detector connected ignition device for a flash tube.

FIG. 4 shows another example of a modification of FIG

IO

15th

20th

Circuit according to Flg. 2 by adding a reset circuit for the normal ignition voltage detector to the circuit according to FIG. 3;

Flg. Figure 5 is a schematic diagram shown partially in block form Schematic of a further detail the automatic exposure control system;

Flg. 6 shows details of block II of the circuit according to Fig. 5;

Flg. 7 shows details of block I of the circuit according to Flg. 5;

Fl g. 8 shows details of block 302 of the circuit according to Fig. 6

1 and 2 showing an embodiment of the automatic turn signal control system: reference is first made to FIG. 1; According to this, the system has a sensor 21 with a light-sensitive element which generates a voltage proportional to the brightness of a scene, an exposure device 22. Setting .jfjsfeines film speed value, a closing time Hfwerts and the like, an arithmetic amplifier 23, which forms a common part of a first and a second computer for the generation of respective output signals f, the daylight and flash light exposure values Ifilbzw. in this case represent exposure aperture values, '% (and the daylight and flashlight recording format flames via a mechanical first operating mode selector switch 24 which has two switch positions α and b for the daylight mode and the flashlight mode {has a memory device 25, which can be constructed in the form of a capacitor, a magnetic core or an analog-digital converter for storing the output signal of the computing amplifier 23 in analog or digital form, an aperture control device for controlling the size of the aperture of the camera accordingly the output signal of the memory device 25 via an interconnection with a diaphragm interrogation potentiometer 26, a comparator 27 and a JBIendenverriegelungsmagneten 28, a first timing circuit from the series connection of a capacitor Cl and a variable resistor Λ6, which is assigned to a shutter dial, not shown, a second e timing circuit, which has the capacitor in common with the first timing circuit - and has a fixed resistor Rl , the resistance of which. staüiiswert corresponds to a flash exposure time of, for example '/ »» s, a trigger circuit 36. which can have the form of a Schmitt trigger circuit, which to control the duration of actuation of a shutter electromagnet 37 optionally to the output signal! the ^r '° first or the second timing circuit is responsive, and a second electronic Betri ^ bsartwählschalter 32 with a first and a second transistor TrX or 7>. 2 which are connected between the respective tenting resistors Rd and Rl and a common battery V _SAT ^S5 . The camera is equipped with four connections . T%: Tu · and Tf , which are arranged so that they are connected to respective connection terminals Τ _Λ . T _x . T ₁₁ and T _{1 of} the flash unit are associated when the flash unit is attached to the camera.

The Flg. 2 shows the circuit of the flash device with a battery 1, a storage capacitor 3 connected to the battery 1 via a voltage booster circuit 2, a flash tube 7 which is connected in parallel to the storage capacitor 3 in such a way that the voltage stored in the storage capacitor 3 is applied to the flash tube 7 occurs, a gas discharge control circuit 8 connected between the cathode of the flash tube 7 and the negative feed line or the negative pole of the storage capacitor 3, a trigger circuit 6 for both the flash tube 7 and the gas discharge control circuit 8, a photocell 9, which Is arranged to receive the light reflected by an object 59 photographed with flashlight and which is connected via a manually operated flashlight selector switch element 17 to an integrating circuit 10 for integrating the output signal of the photocell 9 via an integrating control element whose parameters depend on the preselected Flashing aperture value is adjustable, the output signal of the integrator circuit 10 being applied to the control circuit 8 to terminate the duration of the burning of the flash tube 7, and an arithmetic amplifier 14, which is part of the second computer according to FIG. 1 forms. A variable signal resistance value Ri is connected between the negative signal circuit and the inverting output connection of the computing amplifier 14, while a resistor RA with a resistance value is connected in the negative feedback branch of the computing amplifier 14, which depends on the blinking light value preset in the integrating circuit! 0. The non-inversion input terminal of the arithmetic amplifier 14 is connected to the output terminal of a voltage divider made of in series resistors Ra and Rb , which are connected via a manually operable switch element 16 between the negative bus and the connection terminal T ₁ and which are used to form part of a control device for serve to control the actuation of an actuator of the system which will be described in detail later. To select either automatic daylight exposure or automatic flash exposure by hand, the switch element 16 is assembled with a further switch element 15 which is connected between the negative terminal of the battery 1 and the negative bus. The switch element 17 is coupled to a further switch element 18, which is connected in a line between the negative feedback branch of the computing amplifier 14 and the negative bus line. Three resistors 40, 41 and 44 connected in series form a voltage divider 4 which is connected in parallel to the storage capacitor 3. A neon tube or lamp 51 and two resistors 54 and 55 are connected in series with one another and form a voltage detector circuit 5, which is used to determine whether the storage capacitor 3 is charged to a normal ignition voltage level for the flash tube 7 or not, to the resistors 41 and 44 is connected in parallel.

In Fig. I an automatically operated mode selection device of the system is shown, comprising: a reference voltage source 29, a variable voltage source Ri, Ra, Rb, 13,42,43 (see Fig. 2) for outputting either a high or a low voltage Depending on whether the voltage on the storage capacitor 3 is above or below the normal ignition level as determined by the voltage detector circuit 5, an arithmetic amplifier 30, its non-inversion input connection to the reference voltage source 29 and its inversion input connection both via the connection of the connection connections T _r and T _c is connected to the variable voltage source as well as to the Nlchtinversionseitsangsanschluss of the computing amplifier 23, a first level detector 31, which when detecting an output signal of the computing amplifier 30 with a high level or low level either the first transistor 7Vl

or the second transistor 7V2 of the second mode selector switch 32 'is made nonconductive while the other transistor is kept conducting, a second level detector 33 which switches the first mode selector switch 24 to position b or position a in accordance with the output signal of the computing amplifier, and a first and a second indicator lamp 34 and 35, respectively, which are arranged in the field of view of the viewfinder of the camera and which light up when the flashing aperture or the bitmap tent are selected. According to Flg.2, the variable voltage source includes a transistor 13 whose base is connected to a connection point between the resistors 54 and 55, whose emitter is connected to the negative bus and whose collector is connected to the switch element 16 via a resistor Ri , which has a much smaller resistance value as the voltage divider of the resistors Ra and Rb and which is connected in parallel to these, and an additional transistor 43, the base of which is connected via a resistor 42 to the collector of the transistor 13 and which is connected to its emitter and its collector to the resistor 44 of the voltage divider 4 is connected in parallel. The circuit consisting of the resistor 42 and the transistor 43 also serves as a holding circuit if a Kämera release is carried out before the voltage of the storage capacitor 3 has assumed the normal ignition level.

In the working of the system according to FIGS. I and 2, it is assumed that the flash unit via the connection of the connections T ₁ . T ". T \ and 7., with the connections T ₁ -. T, _y . T _v and T _r attached to the camera.

If an exposure is to be carried out in daylight mode, the main switch element 15 of the flash unit is set to its position "1", while at the same time the switch element 16 is set to its position "1", in which the variable voltage source is disconnected from the computing amplifier 30 . whereby the latter generates a low-level output voltage which is almost equal to the reference voltage source 29. Thereby, the first and the second level detectors 31 and 33 operate the respective mode selection switches 32 and 24 and effect the automatic selection of the daylight mode. As soon as the first mode selector switch 24 connects the sensor 21 and the exposure control parameter setting device 22 to the computing amplifier 23, the actual aperture size is queried by means of the potentiometer 26 and the query result is queried by means of the comparator 27 when the camera release is actuated to initiate the closing movement of the shutter compared with the output signal of the memory device 25 in order to lock the shutter by means of the electromagnet 25 when the match between the query result and the output signal occurs. Then a front shutter curtain (not shown) begins to run down into the position for the open exposure aperture, at which time a start switch 38 connected in parallel with the timing capacitor Π is opened. Since the first switching transistor TrI was previously made conductive by means of the first level detector 31, while the second switching transistor 7V2 remained in the non-conductive state. the charging of the timing capacitor CM begins via the changeable contradiction Λ6, which has previously been set to a value dependent on the preselected locking tent. In a tent interval the same as the shutter line, the voltage across the tenting capacitor C1 reaches a trigger level for the trigger circuit 36, so that the exposure is completed because the shutter electromagnet 37 is switched off and a third shutter curtain, not shown, is released from the locked position.

If an exposure is to be carried out with an automatic choice between daylight operation or flash operation, the coupled switch elements 17 and 18 are set to their position "2", in which the photocell 9 is connected to the integrating circuit 10 and the resistor RA with a resistance value that corresponds to an in the integrating circuit 10 corresponds to 1 predetermined aperture value, in which the counter-coupling branch of the computing amplifier 14 is switched on. Next, the main switch element 15 is switched from its position “1” to its position “2”, as a result of which the voltage of the battery 1 is applied to the storage capacitor 3 by means of the voltage booster circuit 2 after the increase.

Assuming that the camera release is actuated before the voltage stored in the storage capacitor reaches the normal ignition level for the flash tube 7, a voltage which continues to occur during the actuation of the camera release is due to the transistor 13 remaining in its non-conductive state the connections of the terminals T _c . and T _{c applied to} both the base of the blocking transistor 43 and the resistive voltage divider Ra, Rb via the resistors Ri and 42, whereby the hold transistor 43 is turned on, so that ignition of the neon tube 51 is impossible even if the voltage on the storage capacitor 3 reaches the normal ignition level, and as a result of which the computing amplifier 30 also generates a low level output signal which the first and second level detectors 31 and 33 for actuating the first and second mode selector switches 24 and 32, respectively, for automatically selecting the flash mode turns off. As a result, the exposure is carried out in daylight mode.

Alternatively, suppose that the camera release is operated after the neon tube 51 has been lit for display above it. that the voltage at the storage capacitor % the normal level! assumed, the holding transistor 43 is kept blocked because the transistor 13 is switched through and a relatively large current is passed from the inversion input terminal of the computing amplifier TA via the resistor Rl, since the resistance of the resistor Ri is smaller than that of the voltage divider Ra Rb . In this case, the output signal of the processing amplifier 30 exceeds the critical level for the level detectors 31 and 33. As a result, the first mode selector switch 24 is moved from its position α to its position b , in which the output signal of the processing amplifier 14 via the connection of the terminals T ₀ . and T. is applied to the arithmetic amplifier 23 so that the size of the aperture of the camera is set in accordance with the combined information from the variable Flimensensibilkelteinstell-resistor Ri and the diaphragm value setting resistor A4. Furthermore, the first switching transistor TrI is blocked while the second switching transistor TrI is turned on, whereby the second timing circuit Rl. Ci is selected, from which the exposure time of U s results. In synchronism with the sequence movement of the front shutter curtain is used to actuate the trigger circuit 6 and a thyristor of the loading control

Circuit 8 a synchronous switch 39 is closed, whereby the flash tube 7 is ignited. Using the Photocell 9 receives light from the object 59 under the «flash exposure conditions. If that Output signal of the integrating circuit has reached the predetermined value, is used to terminate the ignition period of the flash tube the aforementioned thyristor is switched off. It should be noted that the tenting interval, meanwhile the flash tube 7 is ignited, both of the preselected aperture value and of the Camera-object distance depends.

The amount of electrical energy stored once in the storage capacitor 3 is sufficient for the execution of few image exposures in flash mode; therefore it is possible that when using one of the The motor drive unit assigned to the camera is to perform successively image exposures, the The number is greater than the number of possible image exposures in flash mode after the last of these has been completed Image exposures the voltage on the storage capacitor 3 drops below the normal ignition level, whereby the Neon tube 51 is extinguished, which in turn causes the conduction of the hold transistor 43, so that all The following image exposures of this sequence of exposures are carried out in daylight despite the fact that that the storage capacitor 3 is sufficient again at a point in time during these subsequent image exposures is loaded.

If the operator wishes to carry out the entire uninterrupted sequence of flashing lights, he must stop the operation of the camera release immediately after the light of the neon tube 51 is extinguished. To facilitate this termination process, a reset switch 60 is preferably used, which is in a line between the connection terminal T ₁ ■ and the inverse input terminal of the arithmetic amplifier 30 and cooperates with the film advance mechanism in the manner that the reset switch 6 for each advance of the film by one frame () is opened. After a -> 0 number of opening and closing cycles of the reset switch 60, the voltage on the storage capacitor 3 can assume the normal ignition level, so that at this point in time a second succession of flashing lights is initiated. It should be noted that between the first and second successions of flash exposures, a number of exposures are made every day.

3 shows an example of a control circuit connected to the voltage detector circuit 5 in the form of an ignition circuit 61 for the trigger circuit 6. The ignition circuit 61 has a first transistor 62, the base of which is connected via a resistor 63 to a connection point between the neon tube 5! and the resistor 54 and its emitter is connected to the connection terminal T _x , a second transistor 66 whose base is connected via a resistor 67 to the collector of the first transistor 62, whose emitter is connected to a junction between a resistor 64 and a capacitor 65, which between the positive and negative bus lines are connected, and the collector of which is connected to the trigger circuit 6, as well as a resistor 63 which is connected between the emitter and the base of the second transistor 66.

If the synchronous switch 39 according to Flg. 1 closed is, the emitter of the first transistor 62 is with connected to the negative manifold. Assume now that the neon tube 51 lights up in front of this tent point has, then the first transistor 62 becomes conductive, at the same time the second transistor 66 because of the flow a base current of the second transistor 66 from the capacitor 65 is conductive, so that thereby the Trigger circuit 6 is operated.

Flg. 4 shows an example of a modification of the hold circuit according to FIGS. 2 and 3; the modification is carried out by an automatic reset circuit for the hold circuit. The modified hold circuit has a first transistor 74, the base of which has the Resistor 42 with a connection point between the collector of the mode selector switch translator 13 and the resistor Al, its emitter with the negative bus and its collector with the Cathode of the neon tube 51 is connected, and a second transistor 77, whose emitter is connected to the negative Bus and whose collector is connected to the collector of the first transistor 74.

The reset circuit has a first transistor 75, whose emitter is connected to the negative bus and whose collector is connected to the base of transistor 74, and a second transistor 79, whose collector is connected to the bases of transistors 75 and 77, and whose emitter is connected via a resistor 79 is connected to the collector of the transistor 13 and its base via series-connected diodes 71 and 72 to the connection terminal T _x . The synchronous switch 39 according to Fi g. 1 is used as an actuator for the reset circuit. A connection point between the diodes 71 and 72 is connected to the emitter of the transistor 62 of the ignition circuit 61.

When a continuous series of exposures with automatic flash mode selection 1st, the hold circuit and the reset circuit work according to Flg. 4 as follows: Assume that the voltage on the storage capacitor has not yet assumed the normal ignition level; when the camera is triggered to apply an actuation signal to the base of the first holding translator 74 is operated, the output stage of the neon tube 51 is short-circuited, so that the subsequent closing of the Synchronous switch 39 results in no actuation of the ignition circuit 61, while the Beiriebsariwähischaii-Tränsistor 13 Is held in the non-conductive state. If the synchronous switch closes at this point in time 39 occurs with the movement of the front shutter curtain, the first holding translator 74 is by means of of the first reset translator 75 into the non-conductive reset as the first and second reset transistor 75 and 78 are made conductive. Conducting the second reset transistor 78 does that too Conducting the second holding Translstors 77, so that when the voltage on the storage capacitor 3 den Normal ignition level at a tent point during the exposure sequence of any of the images in the continuous Successive exposure achieved, the flash tube 7 is not ignited and furthermore the actuating elements 30, 31 and 33 for the automatic exposure selector switch do not result in a selection of the flash mode be operated. When the synchronous switch 39 synchronizes with the initiation of the sequence movement of the rear shutter curtain is opened, the second holding translator 77 is in the non-conductive state reset, whereupon the output stage of the neon tube 51 is reset to the operating state in which the Betrlebsartwfihlschalt-Translstor 13 In the control state is set because the neon tube 51 has already lit up. As a result, the next recording will be with

Flash completed. It is better to note that weighed the connection of the base of the first hold transistor 74 to a delay element or a capacitor 76 the conduction of the transistor 74 does not lead to the conduction of the transistor 13.

In the Fl g. 5 through 8 there is shown another embodiment of the automatically operated mode selector used in a digital automatic exposure control system for daylight and flash photography. In Flg. 5, a dash-dotted block denotes that part of the system which is built into a camera, a block MD in solid lines denotes a motor drive unit, and a further block EF in solid lines denotes a flash device of the type shown in FIG Exclusion of the holding circuit 42, 43 can be.

In Flg. 6 is an analog directional control circuit including an aperture value display circuit, but excluding an aperture control circuit shown in conjunction with a coordinator control circuit for different parts of the system is explained with FIG. 7. The in a block Circuit elements enclosed by dash-dotted lines correspond to a block II according to FIG. 5 and can be arranged in the form of a large scale integrated circuit on a single semiconductor substrate. Electrical power is supplied via a connection P36, but none for the sake of clarity further conductors are shown.

Light from a scene to be recorded falls on a light-sensitive element or a Slllzl- J0 umfotodiode SPD and causes the generation of a voltage, the level of which depends on the brightness of the scene. The Ausgangsspannimg from the Sllizlumfotodlode SHD is supplied to an operational amplifier Arl, in which & üegenkopp- lung branch a logarithm compression diode D3 is connected. To compensate for the change in the parameters of the diode D3 with the temperature of a diode Dl, an operational amplifier ARX and a resistor Λ33 are provided, when the scene illuminating light source is flickering, the high frequency component of the output signal of the operational amplifier ARL n.ittels a variable resistor VR1 is a capacitor CA and an arithmetic amplifier ARi attenuated By means of an arithmetic amplifier - »5 ARS , the brightness information (Hv) from the arithmetic amplifier AR 3 is transmitted via a resistor« 2 ° to a common variable resistor Ι · Λ3 preset information about the sensitivity and the closure / elt combined in order to generate an output signal 7U which represents a difference \ ΛΑ \ between a suitable aperture value and a maximum aperture V \ AV \ available in the camera lens and which is connected to the aperture control circuit via a connection PU by means of a line not shown (see Fig. 7) and also by means of one in Flg. 5 is connected to a »Üunkel« warning circuit for low light levels. The maximum possible aperture is preset on a variable resistor VRA , so that after combining the output signals of the computing amplifier AR5 and a computing amplifier ARd by means of a computing amplifier ARl, the correct aperture value is displayed, for example by means of a measuring unit M in the field of view of the camera viewfinder. Two variable resistors VRS and VR6 for setting a long and a short shutter tent and a capacitor C5 form a first cell circuit for daylight photography. A second timing circuit for the flash photography with a shutter of 1/60 s, for example, comprises a resistor Λ 32 and the capacitor CS shared with the first timing circuit. In response to the output signals from the first or second tenting circuit, a comparator CPd energizes and de- energizes the solenoid of a shutter electromagnet Mg3 from a battery BAT , provided that a camera release electromagnet MgI is operated beforehand.

The automatically operating mode selection device of the system includes a reference voltage source 301 and an arithmetic amplifier AR9, the non-inversion input terminal of which is connected to the reference voltage source 30 and the inversion input terminal of which is connected via a connection / '34 and a circuit part according to FIG. 7 to a variable voltage source which is the same as the voltage source shown in Fig. 2 Rl, 13, etc. can be. When the storage capacitor 3 is sufficiently charged, the arithmetic logic amplifier AR9 generates a high level output voltage, which is then applied to a comparator CP4 to generate a low level output voltage. In response to this low level voltage, the arithmetic logic amplifier ARS selects the input signal from a terminal P35 which is connected to a flashing light signal information source which may be the same as that of the arithmetic logic amplifier 14 of FIG In details in Flg. 8 is shown. for the connection to the comparator CP6 the second signaling circuit R 32. CSwShIt

According to FI g. 8 The output signal of the comparator CPA is passed to the base of a first transistor 81 via a resistor 85. The emitter of the transistor 81 is grounded, while its collector is connected both via a resistor 86 to the base of a second transistor 82 and via a resistor 89 to the base of a third transistor 83. The collector of transistor 82 is connected to the first timing circuit via a terminal P31 , while the emitter of transistor 82 is connected to a positive bus to which the emitter of transistor 83 is also connected. The collector of transistor 83 is connected to the base of a fourth transistor 84, the collector of which is connected to the two-n timing circuit via a terminal /> 31. The emitter of the T: anslstors 84 is connected to the positive bus line. Resistors 87 and 88 are connected between the bases and emitters of transistors 82 and 83, respectively. A resistor 90 is connected between the base of transistor 84 and ground. When the output of comparator CPA is high, transistors 81, 82 and 83 conduct while transistor 84 is non-conductive; as a result, a voltage is applied to the terminal P31. When the output of the compare «is low. If the state is reversed and a voltage is applied to the terminal P31 .

In Fig. 7 are a power supply control circuit, a battery voltage test circuit, selection circuits for manual and automatic operating mode, a Operating mode display circuit, a display circuit for aperture area overriding, a self-timer circuit, a camera release drive circuit, an iris control circuit, and a disabling circuit and resetting the flashing mode as well as a

Coordinating control circuit shown for these circuits, the overall function of which is explained below. It is It should be noted here that the circuit elements included in a block with dotted lines are arranged in the form of a large scale integrated circuit (LSI) on a single semiconductor substrate can.

(1) If, assuming that the camera is in the cocked state, with a switch SWS in its position »N. C "is, a shutter release button is depressed to a first stop, a switch SWX is closed and causes a transistor TrX to conduct, while at the same time a battery voltage £ 1 with the binary level" 1 "to a switch-on; clear circuit 303 is applied, whereby a binary counter with twenty stages 401 to 420 is preset, since a NAND gate 109 responding to a momentary output signal with the binary level "0" from switch-on clear circuit 303 generates an output signal "1". This instantaneous output signal "0" from the switch-on clearing circuit 303 also causes a FÜ.pflops 305 to be preset to an initial state with the generation of a voltage £ 2 of level "1", which in turn causes a flip-flop 306 to react. The initial state is preset in which a span £ 3 with a level of "1" is generated. This in turn has the consequence that a flip-flop 307 is preset to an initial state in which a voltage £ 4 with the level "1" is generated.

If a switch SW6 is opened to select the automatic exposure control mode, an output signal of a NAND gate 121 is a binary counter with seven output stages in response to the arrival of the voltage £ 2 at an analog-digital converter 309, which forms part of an aperture control circuit A to G is preset and an arithmetic amplifier ARA is connected to ground to prevent energization of a shutter lock solenoid Λ / rI.

When the light value detected by the silicon photodiode SPD according to FIG. 6 is below a certain value, ie. when VAAl is smaller than a reference voltage VC . generate ', a comparator C Pl an output signal "1", which together with the signals El. QXi and Q \ 4 is applied to a NAND gate 115 in order to generate an output signal "0" / u times at which the signals QXi and QU of the binary counter 401 to 420 are simultaneously "1" when the binary counter 401 to 420 a clock pulse train CP is fed from an oscillator OSC at a frequency that depends on the parameters of a resistor Ri and a capacitor Ci : the output signal of the NAND element 115 intermittently excites a light-emitting diode LEDl , which can be observed, for example, in the field of view of the viewfinder can.

(2) When assuming that in accordance with the determination by means of a comparator CPL the voltage of the battery BAT of the shutter release button lsi equal to or higher than an adequate operating level, further from the first depressed to the second stop wire ^1, a switch SWl is closed, whereby an inverter 202 has an output signal! "1" is shown, which in turn brings a NAND element 107 to generate an output signal "0", by which the flip-flop 305 is switched over so that the voltage £ 2 becomes "0" and an inverter 203 generates an output signal "0" So that the transistor 7Vl is kept in the conductive state even when the switch SW \ is opened.

This conversion or conversion of the flip-flop 305 also causes a single-pulse circuit 304 to generate an output signal "1" during a very short delay interval dependent on inverters 205, 206 and 207, which resets the binary counter 401 to 420. The binary counter 401 to 420 then begins to count the pulses from the oscillator OSC. On the other hand, in accordance therewith, the analog-to-digital converter 309 starts counting pulses Q \ of the binary counter, and a shutter interrogation mechanism starts moving while changing the resistance VRX while the shutter lock solenoid Mal is energized. As the number of pulses counted by means of the binary counter A to G increases , the output becomes ^ ig. ·! -Ie =. ^ i ^ hen amplifier AR4 step by step until they match. . '"' N limit signal voltage 1 · AA V reduced, at which a comparator CPi is inverted to" 1 ", whereby the counting process of the binary / counters A to G is completed. The use of the output signal of a NAND gate 120 to control the function des Vergie r..i '' P * serves to switch off the influence of disturbances on the / ählvoigang. If the comparator CPi detects that the output signal of the variable aperture query contradiction VRi with the output signal of the arithmetic logic amplifier AR4 , the aperture lock Elektromagnei May entregi in order to effect the automatic adjustment of the aperture size according to the calculated exposure value.

If automatic is selected in Bellchtungssteuerbetriebsarl opening both of the switch SWd and a switch SWl, generates an inverter 208, the LSI connected to the switch SWl through a terminal PXi. an output signal »0«. which is applied to an inverter 209, via which an output signal "1" is generated. At the first point in time at which the output signals QH, Uf and QU) become "I" at the same time, a NAND element MJ and the flip-flop 306 are converted so that the voltage £ 3 becomes "0". This leads to the excitation of the camera release EIekliomagneten MkL, which lasts until the signals Q1 and Q9 / u "1", which are applied to a NAND gate 114. The output signal “0” of the NAND gate! 14 also causes the flip-flop 307 to convert from “1” to “0” at voltage £ 4. which results in resetting the binary counter 401-420.

(3) Assuming that the manual exposure control mode is selected when the switch SWh is closed, an inverter 212 generates an output signal "1" which is applied to a NAND gate 116 so that at times when the signals 013 and Q 14 become "1" at the same time, its light-emitting diode LEDX is energized intermittently. In this case, the analog-digital converter 309 is held in the preset position during the course of the exposure process.

(4) If, on the assumption that when the switch SW1 is closed, either the automatic or manual operating mode is effective, output signals Q18 and Q10 simultaneously become "1", which are applied to a NAND element 110, the output voltage £ 3 of the flip-flop 306 is converted from "1" to "0" by means of a NAND gate 112. At this point in time, the binary counter 401 to 420 is reset to the initial state. This resetting is immediately followed by the start of the counting process of the binary counter 401 to 420, which is then followed after a short time interval until the counting.

10

15th

20th

If the signals 08, _{Q9 t} and QU coincide, if "0" the camera release plate magnet Wj; 2 is excited.

After the exposure, the switch SWS is moved from its position NC to its position NU , in which the inverter 2 (11 generates the output signal "0" so that the auxiliary pulse 305 is converted to generate a voltage L1 with the level "1" When SW1 is open, the transistor 7/1 is therefore closed. When the voltage El / u becomes "1", the fill-flop 3116 is inverted to generate a voltage E 3 with the level "1", whereby the fill flop 307 is also inverted Generation of the voltage IA with the level "I."

Next, referring to FIG. 5 to 8 consider the effects of the automatically operating mode selection device of the system. If, assuming that the storage capacitor in the flash unit EF according to Fi g. 5 is not yet charged to the normal ignition voltage for the flash tube, the shutter release button is pressed to the first stop, an output signal with the binary level "1" from the connection B of the flash unit EF to a connection P9B to the block I In Fig. 5 or the block shown in dash-dotted lines in FIG. 7, so that a NAND gate 122 is blocked by the output signal of an inverter 215 connected to the terminal P9B. If the shutter release button is pressed further to the second stop, a flip-flop 308 for generating an output signal "0" cannot be implemented despite the fact that a very short pulse is sent to the WAND element 122 from a differential circuit with a resistor 34 and a capacitor is created. Therefore, no current is passed from a terminal P9A through the coil of a relay LX which controls the opening and closing of a switch SWS which is connected in series with a synchronous switch SW9. As a result, even if the synchronous switch SW9 is closed, the flash tube will not fire. Furthermore, a light-emitting diode LEDi serving as a display device. not aroused. Since the terminal P34 in FIG. 6 is connected to the terminal P9A , the comparator CV4 elr, generates a high level output signal, whereby the automatic selection of the daylight mode takes place.

With the alternative assumption that the voltage is on the storage capacitor the normal ignition peeler at a point in time during the course of an exposure process after the second pressure stroke of the shutter release button has reached, there is almost no way that this tent point is in agreement with the one occurs to which the actuation pulse is applied to the NAND gate 122, since the duration of this Pulse is set to a very short value

After the voltage on the storage capacitor has reached the normal ignition level, the operator has to press the shutter release button down to the full stop, whereby the NAND element 122 is switched through and the activation pulse passes to the flip flop 308, from which the excitation of the RaIaIs Ll and the light-emitting diode LEDA as well also the automatic selection of the flashing light mode (see Fig. 6) results.

The switch SWS is thereby closed. It should be noted that while conventional systems are usually designed so that the application of the control signal for the automatic selection of the flash mode is interrupted in synchronism with the initiation of the ignition of the flash tube, the system described is not affected by such a situation, so that the Occurrence of a change between the first and second tenting circuit is prevented, which occurs in conventional systems.

When the rear shutter curtain runs down at the end of the exposure, an output signal "0" is applied to a NAND gate 124 of the flip-flop 308 by an inverter 214 connected to the switch SWS via / Ί6, so that the flip-flop 308 is converted and the automatic Selection of the daylight operating mode is effected.

For manual selection of the automatic daylight mode with effective use of the flash unit EF , a switch SW10 is provided which, when open, allows the flash control signal to be applied from the terminal B to the terminal P9B without causing the flash mode to be selected.

In addition 7 sheets of drawings

Claims (6)

25 30 claims: 1. Automatic flashing control system for a camera and a flashlight device with a first ο computing device for determining the flashing value for daylight photography and a second computing device for determining the exposure value for flashing photography. with a bell direction control. with a changeover switch for the optional connection of the first or second computing device to the exposure control device depending on the type of exposure and with a detector circuit which detects a signal about the type of exposure and supplies the changeover switch with a corresponding type of exposure control signal, characterized in that a hold circuit (43; 74) is provided Is that is put into operation when the camera is triggered and prevents switching of the switch (24, 32) and thus a change of the favorite type of operation during the exposure time. . 2 System according to claim 1, characterized gekennzefch- f net that the detector circuit (5,13) the charge level of the capacitor (3) of the flash device is detected than the one exposure mode determining signal. 3. System according to claim 1 or 2, characterized in that the holding circuit (43; 74) through a signal of a control device (60; 39) is put out of operation, which at the end of the recording occurs. 4. System according to claim 3, characterized in that the synchronous switch (39) as a control device is provided. 5. Flash unit with flash tube. Storage condenser and a detector circuit that detects the charge level 'Gel detects the storage capacitor, Beiichtungssteuersystem for use with a camera having an automatic. having a first arithmetic means for determining the Belichlungswertes at Tageslichlfotografle and a second computing device for w determining the Belichlungsweries in flash photography, a Bellchtungssleuereinrkhtung and a switch for selectively connecting the first or second computing device with the Bellchtungssteuereinrichiung depending on the exposure mode, characterized by a hold circuit (43; 74), which is put into operation when the camera is triggered and keeps an output signal of the detector circuit (5, 13) unchanged during the exposure period, and through a connection (J ₁ ) for supplying the output signal of the detector circuit to the switch (24, 32) of the Camera. 6. Flash device according to claim 5, characterized by an actuating circuit (61) for the flash tube (7). depending on the output signal the detector circuit remains out of operation if the charge level of the storage capacitor (3) is insufficient for a flash light exposure