DE2463393C2 - - Google Patents

Description

The invention relates to an electronic control device for automatic setting of the exposure time and the Corresponding aperture value in a photographic recording camera the preamble of claim 1.

In a known program exposure control of this type (DE-OS 20 31 978) is determined by the program Relationship between the exposure time and the aperture value prepared for appropriate photographic results to achieve. It is therefore not the case with such cameras possible, a time delay or an aperture because the combination of exposure time and Aperture value are predetermined by the program. In particular, it is therefore not possible for example decide with a higher object brightness of the user can whether he is performing a recording a greater depth of field or a greater range of motion prefers. With programmed cameras of this type there is therefore no possibility as with others known non-programmed cameras, an exposure control with aperture or time priority (DE-OS 21 33 212). In other known programmed Cameras that have an electromechanical control device have with a differential, there is the difficulty that the required mechanical Elements a relatively complicated construction and result in a disadvantageously high space requirement (DE-PS 15 22 050).

It is therefore an object of the invention to use a camera a program exposure control of the aforementioned Kind to improve such that the exposure time or A stronger weight is given to the aperture setting.  

This task is done with an electronic Control device of the type mentioned in the introduction solved by the subject matter of claim 1. Advantageous embodiments of the invention are the subject of subclaims.  

The invention will be explained in more detail, for example, with reference to the drawing. Show it

Fig. 1A-1C is a block diagram of an embodiment of a control device according to the invention;

2A-2B is a flow chart for explaining the operation of the control device in Fig. 1.

3A-3B are flow charts for explaining the exposure calculation in connection with FIG. 2.

Fig. 4 is a graphical representation for explaining the exposure control during program photography;

Fig. 5 is a block diagram of a single lens reflex camera in which an automatic exposure control means is provided; and

Fig. 6 is a graphical representation to explain the operation of program photography of the system shown in Fig. 4.

In Fig. 1 is a block diagram of an embodiment of the automatic exposure control system for a single lens reflex camera is reproduced. By means of a conventional photometer circuit 40, the brightness of an object or object is measured, wherein at the output terminal of a photoelectric element 40 G, an amplifier 40 is connected A, a diode is connected 40 D with logarithmic Kenlinie between its output and input terminal. Furthermore, a device 41 for setting the photographic information is provided, which has the following devices: a device SV , which is connected to the focusing screen of the single-lens reflex camera, for setting the film sensitivity; means PSA connected to the aperture adjustment ring for adjusting the aperture value; means PSS connected to the exposure time setting disk for setting the exposure time; a setting device OPF for setting the fully open diaphragm on the lens; devices connected to markers AMN or AMX for setting the minimum or maximum aperture value; Devices SMN or SMX connected to further markings for setting a minimum or maximum exposure time; a device ST connected to a lever for setting the self-timer time; and an adjusting device α for setting a program constant α , for example by means of a digital switch etc.

Furthermore, a gate circuit 41 G is connected to the output terminal of the switch, while the output terminal of the gate circuit 41 G is connected to a computing device 42 , so that the state of each of the aforementioned devices or switches is transmitted to the computing device 42 depending on the output of a sequence control circuit 43 becomes. The state of each function in a camera is set by means of a function verification and setting circuit, for example the position in which a mirror is placed, or predetermined recording conditions, such as, for example, photography with priority exposure time or aperture value setting. The circuit 44 has the following switches: a switch SW 1 , which is switched on when the trigger is depressed; a switch SW 2 to store and keep the optically felt brightness of an object in a register; a switch SW 3 to choose either an automatic or a preset aperture; a switch SW 4 which is turned on when the mirror reaches its upper limit position; a switch SW 5 , which is switched through when a rear curtain reaches its rear end position; a switch SW 6 for selecting the priority exposure time setting; a switch SW 7 for setting the priority aperture value setting; a switch SW 8 to select a sensing process with the aperture fully open, and a switch SW 9 which is connected to the selector switch for selecting a fully automatic exposure. Here, the output terminals of the switch are each connected to the gate circuit G 44.

Furthermore, the output terminal of the gate circuit 44 G is connected to a gate circuit 45 , so that the gate circuit 44 G can optionally output the signal from each of the switches SW 1 - SW 9 to the gate circuit 45 corresponding to the output of the sequence control circuit 43 . The switch SW 1 is designed so that it is locked in the off position if the exposure time and the aperture value are not displayed on the display devices SSD and APD to be described below. The conventional gate circuit 45 has a number of input and output connections. A function verification or determination circuit consists of the aforementioned setting circuit 44 for function evaluation and the gate circuit 45 . The sequence control circuit consists of an SCC determination circuit 43 a for retrieving the address of a sequence control counter (which is referred to as SC counter below), which contains the address of the command conversion circuit (hereinafter referred to as the ROM circuit), and from the aforementioned SC counter 43 b and the ROM circuit 43 c. Instructions such as addition and subtraction instructions or designation instructions are also included in the ROM circuit to designate the address or the part to or from which addition or subtraction is to be performed. When the output of the ROM circuit 43 c are other than jump or branch instructions, calls the determination circuit 43 a, the next address in the SC-counter after 43 c commanded function of the circuit is completed; In contrast, when a jump or branch instruction is output from the circuit 43 c, the output is to the determination circuit 43 fed back to a and it is an address of the SC counter 43 b corresponding to the jump or branch instructions and called the output of the gate circuit.

The operating time of the sequence control circuit 43 is controlled by means of a conventional circuit for generating the reference time. Circuit 46 has an input terminal to which the output of a conventional clock pulse generator 47 is applied and a number of output terminals. A computing device 42 has a circuit 42 a for performing the calculation and an ACC circuit 42 b which stores digitally represented data. The arithmetic circuit 42 a has an addition and a subtraction circuit in order to add or add any register of the data storage device 48 , which is selected by means of the position or address identification command, or any photographic information to or from the content of the ACC circuit 42 b to subtract when the arithmetic command and the job designation command are issued from the sequencer circuit 43 . Furthermore, the computing circuit 42 has a known gate circuit for transmitting the data of the ACC circuit 42 b to any register of the data storage device 48 or to any of the display devices 49 ; in addition, the circuit 42 a has a circuit for adding or subtracting the theoretical value "1" to or from the content of the ACC circuit 42 b and a circuit for the values "1" or "0" (hereinafter Values "1" or "0" represent theoretical values) at any desired BIT of the ACC circuit 42 b .

The circuit 42 b comprises a register of, for example, 5 bits; in the following description the lowest BIT is denoted by p and each of the following BITS is denoted by q, r, s and t , respectively. Each register of the data storage device 48 has a register of 5 BITS in accordance with the circuit 42 b . The data storage device 48 containing the calculation result, the digital-to-analog converter 50 and the circuit 51 evaluating the calculation result are connected to the output connection of the calculation device 42 , while the setting device 41 for photographic information, the data storage device 48 and the sequence control circuit 43 are connected to input connections of the calculation device are connected. The data storage device has a number of registers, namely a register SSR for storing the exposure time, a register APR for storing the aperture value, a register BR for temporarily storing the calculation result and a register BV 0 for storing the brightness. A conventional comparator 52 has an analog-to-digital converter (hereinafter referred to as AD converter in such cases) which, together with the DA converter 50 and the computing device 42, converts the analog value of the photo-sensing circuit 40 into the digital value. A display device 49 has a display device SSD for the content of the register SSR, a display device APD for the content of the register APR and a display device EVD for displaying the number of error steps EV, as well as a gate circuit 49 G in order to in each case connect the display devices in accordance with the output of the sequence control circuit 43 Taxes. In a drive or control circuit 53 are an indicator lamp for excessive exposure, an indicator lamp LM 2 for insufficient exposure, a solenoid L 1 for automatically dimming the lens, a solenoid L 2 for raising a mirror, a solenoid L 3 for starting a front one Curtain, a solenoid L 4 for starting a rear curtain and a solenoid L 5 for folding down and flip-flops 1 to 7 are provided. The flip-flops 1 to 7 are connected to the input terminal of the circuit 53 ; At the same time, a gate circuit 53 G is provided, via which each of the flip-flops 1 to 7 is controlled with the output of the sequence control circuit 43 . The sequence of functions is stored in a circuit 54 storing the internal state. The contents of all registers and the flip-flops are cleared by means of a reset circuit 55 when the switch 38 assigned to the energy source is switched on. The computing device 42 , the data storage device 48 and the sequence control circuit 43 etc. can be combined into one unit.

The operation of the circuit of Fig. 1 will now be described; Further, 3 (a) and (b) as well as a reproduced below Table 1 for explanation of the code used in the Fig. 3 (a) and (b) to Fig. 2, reference is made.

Table 1

When the switch 38 is turned on, a reset signal is present at the output of the reset circuit 55 . As a result, all registers of the setting device 41 for the photographic information, the function verification and setting circuit 44 , the gate circuit, the computing device 42 , the control circuit 53 and the content of the flip-flops are deleted. After lapse of a certain period of time which is determined by the sequence control circuit of the computing device is gradually in the circuit 42 b, the value "1" registers 42, while being controlled by the gate circuit 45 and the sequence control circuit 43; the output corresponding to the digital value is converted into an analog variable by means of the DA converter 50 . The analog output of the photo sensing circuit 40 and the converted analog quantity are compared in the comparator 52 . The amount of light of an object is converted in the computing device 42 from an analog to a digital value; in this way the sensed amount of light BV is determined. When the Filmempfindlichkeit- information SV, which is set at the switch SV of the device 41 is transferred upon the application of the output of the sequence control circuit 43 via the gate circuit 41G to the computing device 42, then in the computing device 42 is an addition between the photo-sensing value BV and the film sensitivity information SV is performed and the exposure value EV is calculated (ie BV + SV) = EV; the exposure value EV is then transferred to the register BR of the data storage device 48 together with the time control, which is determined by the output of the sequence control circuit, and stored. The corresponding exposure time and the aperture value, as will be described below, are then determined on the basis of this exposure value EV .

The following are each of the four photography methods described, namely taking pictures with a priority Exposure time setting, with a priority aperture value setting,  photographing according to a program and by hand.

(1) Photograph with a priority exposure time setting, that is, when the exposure time is set beforehand and the aperture value is automatically controlled (referred to as the path SSLC in Figs. 2 and 3 (b)).

When the switch SW 6 for the exposure time selection is switched on and the switch SW 7 for the selection of the aperture value setting is switched off, a signal is given to the sequence control circuit 43 via the gate circuit 45 . The output of the circuit 45 transmits the content of the switch PSS, which sets the exposure time TV , to the computing device 42 . When the output of the sequence control circuit 43 is present, a subtraction between the exposure time TV and the exposure value EV is also carried out in the computing unit 42 and the aperture value AV is thereby calculated (ie (EV - TV) = AV). At the same time, the content of the computing unit 42 AV. The aperture value AV is transmitted to the circuit 51 evaluating the calculation result and compared with the minimum and maximum aperture values AMND and AMXD , which are the contents of the switches AMN and AMX of the setting device 41 , which have been transmitted via the computing device 42 . If the calculated aperture value AV lies between the minimum and maximum aperture value, it is stored in the register APR and at the same time transmitted via the computing device 42 to the aperture value display device APD , where it is displayed. In this case, the value of the exposure time, which is the content of the switch PSS, is transmitted to the display device SSD via the computing unit 42 and displayed there.

On the other hand, if the object is too dark or too light and the aperture value AV calculated by the arithmetic means 42 is compared by the circuit 51 judging the calculation result, and if the value AV is outside the range determined by the minimum and maximum aperture value, it does not turn on the display device APD of the register APR is transferred, instead the content of the switch AMN or the switch AMX is transferred from the computing device 42 to the register APR and stored there. This means that the content of the APR register becomes the previously set, marginal exposure value. Then, when the switch SW 9 for automatic operation is turned on, a signal is output through the gate circuit 45 to the sequence control circuit 43 . When the output of the circuit 43 is present, a subtraction is carried out between the content of the register BR and the content of the register APR, ie between the aperture value lying at the edge and the exposure value (EV - AMND) or (EV-AMXD) in the computing device 42 and in this way the exposure time is calculated. The calculated exposure time is then transmitted to the evaluation circuit 51 and compared with the minimum and maximum exposure values SMND and SMXD , which are the contents of the switches SMN and SMX of the setting device 41 , which have been transmitted via the computing device 42 . If the value lies between the minimum and maximum exposure value, ie within the limit values of the shutter, then the exposure value TV is stored in the register SSR and at the same time transmitted to the display device SSD , where it is displayed.

That is, if the switch SW 9 is turned on and the object brightness is too bright or too dark compared to the set exposure time, and if a corresponding exposure is not obtained even if the calculated aperture value is the value on the edge, then the previously set exposure time is automatically set. If the switch SW 9 is then switched off after one of the aperture values lying on the edge is set, the brightness of an object is sensed again and the exposure value EV ′ based on the sensed size is stored in the register BR . That is, the content of the register BR is replaced by the new exposure value, ie EV by EV '. Then the operations described above are repeated with the new exposure value EV ' .

(2) Photography will now be described with a priority aperture value setting, that is, if the aperture value is previously set and the exposure time is controlled automatically (in Fig. 2 and Fig. 3 (b), this possibility is called ASLC .

When the SW 6 selector for the exposure time is turned off and the SW 7 selector for the aperture value is turned on while the aperture value is preset on the switch PSA , a priority aperture value setting is photographed in the following manner.

By switching off the switch SW 6 and switching on the switch SW 7 , a signal is output to the sequence control circuit 43 via the gate circuit 45 . When the output is applied to the circuit 43 , the content of the switch PSA, which is set as the aperture value AV , is transmitted to the computing device 42 . Likewise, when the output of the circuit 43 is present, the subtraction between the aperture value AV and the exposure value EV is carried out in the computing unit and the exposure time TV is thereby calculated (ie (EV - AV) = TV). The content of the computing device 42 then becomes TV at the same time . This exposure value TV is transmitted to the evaluation circuit 51 and compared with the minimum and maximum exposure values SMXD or SMXD , which represent the contents of the switches SMN or SMX transmitted via the computing device 42 . If the calculated exposure value TV lies within the limit values SMND and SMXD , the exposure time TV is stored in the register SSR and at the same time transmitted via the computing device 42 to the display device SSD , where it is displayed. In this case, the aperture value, which is the content of the switch PSA, is transmitted to the display device APD via the computing device 42 and displayed there. On the other hand, if the subject brightness is too low or too high compared to the set aperture value, and if a suitable exposure is not obtained even if the exposure time is set to one of the boundary values, the preset aperture value is automatically set and then the operations such as performed with the priority exposure time setting.

(3) The so-called program photography will now be described, that is, the predetermined combination of the aperture value of a lens and the exposure time is set as a calculation result of the object brightness, and the film sensitivity is automatically controlled (this is designated in FIG. 3 (b) with the sequence PROG ).

The principle of exposure control during program photography will now be described with reference to FIG. 4. In FIG. 4, the abscissa (on the X axis), the exposure time and on the ordinate (on the Y axis), the aperture value. The well-known diagram of the exposure value (EV) characteristic data is made up of the exposure values EV 0 , EV 1 , EV 2 . . . EVn together. PRG 1 is a program curve and P 1 is a straight line with a slope α . The straight line P 1 can be expressed by:

Y = α X (1);

The above-mentioned straight line EV 1 of the exposure value characteristic data can be expressed by:

Y = - X + (EVy) (2).

If the quantities XY are calculated from equations (1) and (2), the following results:

that is, from equations (3) and (4) it can be seen that the exposure time can be obtained by dividing the output EVy of the photo-sensing circuit by the sum of the previously set constants α plus the constant 1, ie ( α + 1) is obtained while the aperture value Y is obtained as the product of the exposure time obtained and the constant α . It can be seen, therefore, that the values (X, Y) during program photography can be obtained by entering the constant α in the arithmetic unit 42 so that it can be multiplied and divided based on the exposure value EVy .

According to the invention, the calculation shown in equation (3) is carried out by the computing device 42 and the data storage device 48 ; after the calculation of the value X, ie the exposure time, the procedure is then continued as in the method with priority exposure time setting and the same calculation is then carried out as in the method mentioned under (1). The corresponding exposure value is then calculated in this way. That is, when both the switch SW for the exposure time selection as the switch SW 7 are opened for the aperture value selection also 6, the signal through the gate 45 to the sequence control circuit 43 and the output of the circuit 43 is delivered to the computing device 42nd As a result, the exposure value EV felt by means of the photo-sensing circuit 40 is then transmitted to the register APR via the computing device 42 , and the constant α , which represents the content of the switch α , is registered in the computing device 42 after the value “1” has been added there ; that is, at this time, the content of the computing device 42 becomes ( α + 1).

The exposure value EV stored in the register APR is then divided by the content ( α + 1) of the computing device 42 ; this division is carried out in a known manner by means of the register APR and the computing device 42 . As a result of this division, the exposure value TV is transmitted from the computing device 42 to the register SSR and stored there. Likewise, the aperture value AV is set in the computing device 42 , based on the exposure time TV, via the path as in the case of photography with a preferred exposure time setting; the aperture value AV is transmitted to the register APR and stored there, and at the same time the same aperture value AV and the exposure value TV are transmitted to the display devices APD and SPD , where they are each displayed.

Since three photographing methods are now described above, manual photography is now described as the fourth method (this is shown in FIG. 3 (b) under the flowchart MANL ).

If both the switch SW 6 and the switch SW 7 are switched on, the content of the switch PSS of the setting circuit 41 is transmitted via the computing device 42 to the register SSR and at the same time to the display device SSD . When the output of the sequence control circuit 43 is present , the exposure value and the content of the switch PSA are added in the computing device 42 . This means that the calculation PSS + PSA = PEV is carried out. The content of the register BR, ie the exposure value EV, and the preset exposure value PEV are compared with one another and the number of error steps above and below is calculated and displayed.

With the method described above, a suitable aperture value and the exposure time are calculated and stored in each of the registers APR and SSR .

If the switch SW 2 for automatic exposure measurement connected to the button 34 is not closed, the calculation of a corresponding exposure value in the above-described method is carried out at a certain time interval (in each case at a distance of a few 10 ms), which is determined by the sequence control circuit ; the contents of each register APR and SSR are renewed and saved again. Even if the switch SW 2 is closed, the corresponding exposure value is stored in each register APR and SSR immediately before the closing, but after the closing, even if the object brightness changes, the content of the registers is no longer renewed.

Then, when the shutter release switch SW 1 is next turned on, the mechanism of a camera is controlled with a sequence shown in FIG. 2 after CTRL .

First, the time of a self-timer set at the switch ST is transmitted to the computing device 42 and counted; after counting, the amount of light BV 1 is then sensed photoelectronically. The sensed value BV 1 is then stored in one of the registers (not shown in the drawing) in the data storage device 48 . If the switch SW 3 is switched on during the automatic dimming, the flip-flop FF 3 provided for this purpose is set and the automatic dimming begins. During the automatic dimming, the amount of light from an object that is still passing through the aperture is felt and further dimmed until the amount of light felt becomes BC 1 - APR . As stated above, when the sensed amount of light becomes BV 2 , ie BC 1 - APR = BV 2 , a reset signal is emitted by the sequence control circuit and the flip-flop FF 3 is reset; in this way the fade-out is ended.

Thereafter, if a preset aperture mechanism has been used as usual, the switch SW 3 is switched during the automatic dimming. This sets the aperture value according to the APR register. However, since it is possible that the preset aperture value is not set to an appropriate aperture value due to a mechanical failure of the automatic dimming mechanism, according to the invention, when the preset aperture value is finished, a photoelectric measurement is performed again based on this aperture value . The exposure time is then measured again at this point in time using the measured quantity of light BV 2 and the result of the calculation is stored in the register SSR . This means that if the aperture value is set by the preset, automatic dimming mechanism, the calculated exposure time is corrected accordingly.

When the above-described operation is finished, the sequence control circuit 43 outputs a mirror flip-up signal. This sets the flip-flop FF 4 and the solenoid L 2 is energized, whereupon the mirror flips up; then when the switch SW 4 is turned on after flipping up the mirror, the flip-flop FF 3 is set, the solenoid L 3 is energized and the front curtain is moved. Thereafter, the content of the register SSR is counted and then the flip-flop FF 6 is set by the output of the sequence control circuit 43 . This energizes the solenoid L 4 and then moves the rear curtain. When the rear curtain reaches its prescribed end position, the switch SW 5 is switched on and the flip-flop FF 7 is set. As a result, the solenoid L 5 is then excited and the mirror is folded down again; the recording is then ended.

If any particular numbers are not set due to the choice of a photographer for the fade number and the exposure time, the system operates in program mode. Although the photographing is selected by program to finally obtain an appropriate exposure by automatically selecting a predetermined combination of the aperture value and the exposure time for the lens due to the calculation of the object brightness and the film sensitivity, this calculation method is described below with reference to FIG. 6.

In FIG. 6, the abscissa represents the exposure time Tv and the ordinate represents the aperture value Av. Since the value Tv is equivalent to the vertex ranges of the numerical code from "000" to "240", the zero point of the abscissa in the numerical code is set to "000", ie to the vertex value "-8", in order to initiate the practical calculations. Likewise, the exposure value Ev is shown as a straight Ev line, so that the points at which the sum of the aperture value Av and the exposure time Tv in the numerical code become the same are connected to one another in the range from Ev 000₈ to Ev 370₈. The straight Ev line therefore has a position which is determined by the size of the exposure value Ev obtained from the photoelectric information. In the diagram, the straight lines P ₀ to P ₇ have an inclination from α ₀ to α ₇ and the straight line is defined in the numerical code by:

Av = α _n Tv (15)

Since also the relationship, which is expressed by the equation is

Tv = Ev - Av (16)

can be obtained from equation (14), the following Obtain reference equations from equations (15) and (16) will:

As a result, a predetermined combination of the aperture value Av and the exposure time Tv in comparison with the exposure value Ev, which results from the photoelectrically measured data, can be obtained by appropriate setting α _n . In this example, the angles of inclination α _n to α ₇ of the straight lines P ₀ to P ₇ are given by 0, 1/7, 1/3, 3/5, 1, 5/3, 3, 7 by the expression

equivalent value is selected by the input device PRCN as the program constant in whole numbers from 0 to 7; as a result, the choice can be made by a photographer to some extent even in a program operation by changing the combination of the aperture value Av and the exposure time Tv .

Then when the program constant is represented by PCN and inserted in the following equation:

the dimming number can be determined by the following calculation:

Although in the foregoing, whether or not the f-number Avs thus determined is set between a maximum and minimum aperture value AMX and AMN by a photographer, if the aperture value Av obtained by calculation exceeds the maximum aperture value AMX , the latter is shown in Equation (16) is inserted as the determined aperture value Av , while the minimum aperture value AMN is inserted into equation (16) if the calculated aperture value Av is smaller than the minimum aperture value AMN. In this way, the exposure time Tv for a correct exposure can then be obtained. Although the maximum and minimum values for the exposure time Tv are used, if the exposure time Tv obtained by calculation is not within the set maximum and minimum exposure time TMX or TMN , the recording cannot of course be carried out with the correct exposure. The aperture value Av and the exposure time Tv, which are required for a correct exposure, can therefore be finally determined by any of the above-described operating modes.

If a correct exposure is to be obtained without either the aperture value or the exposure time being set, ie the so-called program photography is to be initiated, then both the aperture ring 18 and the exposure time setting disk are brought into the "AUTO" position without special values are selected; the maximum and minimum exposure times TMX and TMN and the maximum and minimum aperture values AMX and AMN are set. Furthermore, a program constant PCN, which is an element for determining the combination of the aperture value Av and the exposure time Tv , and both values are calculated automatically.

Now only the maximum and minimum values should be set both for the aperture value Av and for the exposure time Tv . At this point the control flow then changes to the program flow and the calculations such as

then take place with the program constant PCN, which is entered with the setting device 32 , and with the exposure value Ev, which was previously obtained on the basis of the photoelectric measurement; the aperture value Av is then obtained in this way. The aperture value Av obtained in this way is then compared with the originally set minimum aperture value AMN , and if it is smaller than the value AMN, the minimum aperture value AMN is used as the aperture value. If it is larger than the minimum aperture value AMN, it is compared with the originally used maximum aperture value AMX and if it exceeds this, the maximum aperture value AMX is used as the aperture value. As stated above, the aperture value Av, which is calculated in accordance with the predetermined program constant PCN , then results within the range between the originally set maximum and minimum aperture value. The control flow then changes to the flow for priority aperture value setting and the exposure time Tv results from using the obtained aperture value Av as the set value. If the exposure time Tv obtained is not between the originally set maximum and minimum values, the control flow returns to the starting point, as explained above. If fully automatic operation is selected using the switch, the control flow changes to the flow for priority exposure time setting, in which case the set maximum or minimum value of the exposure time is used as the originally set exposure time.

In the event that the switch for fully automatic operation is selected, that the exposure time or the aperture value for a corresponding exposure cannot be obtained under the set conditions, and that under these circumstances the operating mode changes compared to the exposure value Ev obtained by the photoelectric measurement has resulted, the flip-flop is reversed and reset both in the data flow for priority aperture value setting and in that for priority exposure time setting; the control flow then returns to the starting point based on the judgment of the on / reset state of this flip-flop.

As stated above, if the aperture value Av and the exposure time Tv required for proper exposure cannot be obtained within the set conditions and the control flow returns to the starting point, an underflow or overflow display is made and the photographer can determine in the viewfinder field; as a result, he can either change the conditions used or switch to manual mode, which can then give an aperture value Av and an exposure time Tv , at which a recording can be initiated. If a corresponding exposure is made possible by changing the conditions in the conditions that have now been set, the aforementioned underflow or overflow display disappears.

Claims (3)

1. Electronic control device for automatically setting the exposure time and the aperture value in a photographic recording camera, combinations of exposure time and aperture value which correspond to the measured object brightness being adjustable with the aid of a program curve, characterized in that a program curve setting device for setting a program constant α , which corresponds to the inclination angle of a rectilinear program curve , it is provided that a device for generating an exposure value signal EVy is provided on the basis of the output signal of the exposure measuring circuit ( 40 ), and that a calculation circuit ( 42 ) for calculating a value serving as an exposure time control signal and one serving as the aperture value control signal is provided. 2. Electronic control device according to claim 1, characterized in that the program constant α can be input via a manually operable digital switch. 3. Electronic control device according to claim 1 or 2, characterized in that at least a minimum and / or maximum aperture value (AMN, AMX) and / or a minimum and / or maximum value of the exposure time (SMN, SMX) is adjustable.