DE3443244A1 - CAMERA WITH ELECTRONIC SHUTTER CONTROL - Google Patents

Description

Hans-Jürgen Müller Gerhard D. Schupfner

Telegram / cable: Lucile-Grahn-Straße 38 European Patent Attorneys

Zetapatent® Munich D-8000 Munich 80 mandataires en brevets europeens

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Camera with electronic shutter control description

The invention relates to an electrically controlled camera, in particular the automatic exposure control according to Determination of the detected ambient light.

Eastman-Kodak recently launched a new form of 35mm film cassette (trade name "DX") which Has means by which the film speed is coded on the outside of the cassette by a five-digit Pattern of dark dielectric and light conductor areas is indicated. The non-conductor or insulating areas are open applied a common conductive area on the cassette so that the exposed areas code scanning areas will. So five possible conductive scan areas are used to provide a representation of the film speed accordingly the arrangement of non-conductor areas.

It is the purpose of this film coding system to control the To enable exposure for a given ambient light condition, which is detected by a photo sensor in the camera, so that thereby the correct values for aperture and shutter speed or both according to the pattern of dielectric markings film speed specific to the cassette can be set. There were already experimental systems demonstrated, in which an electrical contact with the

The pattern representing film sensitivity is produced by electrical scanning electrodes that are in pressure contact with these scanning areas are brought, the scanning results are in turn fed to a microprocessor, the a table search program is used to generate an exposure control signal in accordance with the exact film speed.

The object of the present invention is to provide a camera which performs the same function on the basis of such scans is made possible without the need for a microprocessor, thereby reducing the cost of the camera. Furthermore should a satisfactory exposure control can be achieved by scanning less than all five coded scanning areas, in order to further reduce the circuit complexity.

In the preferred embodiment of the invention, an electronic shutter timer is controlled so that the open Shutter is closed at a point in time determined by the film sensitivity according to the scanning conditions of the coded scanning areas of the film cassette and is determined by the ambient light detected by a photo sensor. this will achieved by a comparator circuit closing the shutter, one input of which is set to a time-immutable constant reference voltage (threshold voltage) is set and its other input is a voltage that can be changed over time is supplied, which rises to this voltage value, the rate of rise of this time-variable voltage is determined by the ambient light level detected at the photo sensor. So high brightness leads to a faster rise time the voltage that can be changed over time. The shutter is closed when the rising voltage reaches the level of Reference voltage reached; thus a higher captured Ambient light level in a reduced shutter open time.

According to the invention, this open time is also coded in accordance with the scanning results of the film speed code Cassette by means of scanning electrodes for correction of the

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length of time regulated in relation to film speed. According to a particular preferred embodiment of the invention provided that the rise time of the time-variable voltage by both the detected ambient light level and the scanned film speed is determined what also for the Size of the fixed reference voltage applies. The time-changeable signal can be controlled by a capacitor with more effective Size can be derived, its size by the detected film sensitivities is determined and the one with an ambient light dependent Speed charged by the Lighting status of the photo sensor is regulated. Furthermore, the constant reference voltage is derived from an attenuator, regulated by the recorded film speed becomes that it assumes appropriate values. The outputs of the various scanning electrodes of the camera are used to the capacitor and / or the attenuator resistance values of the circuits that the two inputs of the comparator circuit dine, control.

Another special aspect of the invention is based on the discovery that the coding system of said Kodak DX cassette, on which the film speed is indicated in coded form, shows that the information contained in only three of the named five scanning areas is sufficient to produce a film speed value get within 30 % of the actual value. The eighteen standard film speed values between ISO 25 and ISO 1250 can be approximated by the six average film speed ranges 32, 64, 125, 250, 500 and 1000. This is because the Kodak code corresponds to the film speed code bits in the scanning areas NJr. 2, 3 and 4 are assigned an identical but distinguishable coding pattern (see Tables I and II) for all industrial standard film speeds in the respective ranges of ISO 25-40, 50-80, 100-320, 400- 640 and 800-1250. Thus, the first coding pattern can be regarded as indicative of the medium value ISO 32, the second as denoting the medium value ISO 64, and so on, and these

mean values represent a continuum of contiguous Standard film speed groupings that span a full range between ISO 25 and ISO 1250.

Based on this knowledge, it is provided according to a further aspect of the invention that for exposure control less than the total number of scan areas (only three in the case of the special Kodak DX code) must be scanned.

In this way, an inexpensive timing circuit can be built with the required accuracy that only three Scanning electrodes for the film cassette and neither complex logic elements nor an expensive microprocessor for the Correction of the shutter speed in relation to film speed needed.

The invention is explained in more detail, for example, with the aid of the drawing explained. Show it:

Fig. 1 is a side view of a film cassette DX (TM from Eastman-Kodak) bearing markings showing, among other things. the sensitivity of the film it contains describe;

FIG. 2 shows a view of the cassette from FIG. 1, wherein the electrical conductivity is also symbolically recorded Scanning electrodes in contact with the areas indicating the film sensitivity (scanning areas) on the cartridge, the area scanning information to an exposure control circuit supply associated with a photo sensor for ambient light detection;

3 is a schematic circuit diagram of a shutter timing circuit; show the film speed samples from only three of the sample areas of FIG Control of the duration of the shutter cycle in accordance with the detected ambient light is used.

1 shows an exemplary film cassette DX (TM from Eastman-Kodak) with a single overall conductor surface carrying the aforesaid sensing areas A2-A6, the sensing areas A2, A4 and A6 in the particular cassette shown being covered by an insulating film. The selection of the areas covered with insulating film indicates a representation of the sensitivity of the film contained in the cassette. A sensing area A1, which is never isolated, is the exposed portion of this conductive surface. Additional information such as B. the number of images (12, 24, 36) is represented by further scanning areas A ¹ encoded in the same way.

Fig. 2 shows the cassette 10 of Fig. 1 in the position for the detection of the film speed by means of scanning electrodes P1-P6, which here symbolically contact scanning areas A1-A6 and with separate inputs of a general exposure control circuit 12 are coupled, the shutter speed, the aperture or both of an electric camera with a Ambient light photo sensor 13 controls.

Regarding the decoding of the film speed from the State of the scanning areas A2-A6, which is caused by electrical contact between the areas contacting the common area A1 When scanning electrode P1 and scanning electrodes P2-P6 are detected, Table I shows the arrangement of marks accordingly any film speed. It is understood that a film speed of 25 by the presence of insulating films on the scanning areas A2, A3, A4 and A6 and one bare metallic conductive scanning area A5 is displayed, so that a conductive state detection between the area A5 contacting scanning electrode P5 and the scanning electrode P1 scanning the area A1. In the same way a film speed of 50 results from the presence of conductive scanning areas A2 and A5 and non-conductive ones Scanning areas A3, A4 and A6.

3U3244

Since a large number of films on the market today have significant exposure latitudes, there is an exposure error of 30% normally not critical. Thus it can be seen that the five-range coding scheme of Table I works for many photographic purposes is overly refined. A shutter speed control system, which is only set correctly for ISO film speeds 32, 64, 125, 250, 500 and 1000, results with an error of at most 30% for all standard film speeds between these values. These Grouping is particularly advantageous because these five film speeds, as can be seen from Table I, on common groupings of codes are aligned which include only the scan areas A2, A3 and A4. This is in the Table II, from which, with reference to Table I, it can be seen that the entire "32 group" i.e. H. ISO sensitivity 25-40, which has the common property that A2, A3 and A4 are non-conductive at all three sensitivity values are. Likewise, the "64 group", which includes sensitivities 50-80, is in the range due to a conductive state A2 and non-conductive states are marked in areas A3 and A4. Similar considerations apply to the rest Sensitivity groups based on the mean values ISO 125, 250, 500 and 1000 are aligned. Thus, satisfactory control of the shutter speed can be achieved by appropriately designed timing circuit that only scans areas A2, A3 and A4. One such triple scan control is given by the circuit of Fig. 3, which will be described below.

The circuit of Fig. 3 activates a shutter release solenoid SOL by means of an amplitude comparator AC upon actuation of a locking switch SS, which is normally is closed and is controlled by releasing the shutter in the open state. A time-changing one Signal curve is sent to input A of the amplitude comparator AC is applied, and a reference constant voltage with a certain value is fed to input B. When opening the

Locking switch SS a charging process takes place, with a capacitor C2 (or alternatively a capacitor C1, which is switchable can be connected in parallel with the capacitor C2) is charged by a battery B via a photoresistor PC, so that the voltage at input A of the amplitude comparator AC increases. If this voltage changes from zero to the voltage at input B If the set invariable reference value increases, the amplitude comparator is activated so that the magnetic coil is the Shutter operated in a closed state. As will be explained, the rate of increase is that at input A of the amplitude comparator applied voltage also by scanning the scanning area A2 by means of the scanning electrode P2 controllable, and the reference voltage at input B can be regulated one of three different values corresponding to the scanning of the areas A3 and A4 by the scanning electrodes P3 and P4 set.

The locking system can be one of many; a representative Implementation with which the circuit according to FIG. 3 can be used directly is in our own US patent application Serial no. 477 248 of March 21, 1983. When a mechanical lock is triggered, a pair of shutter blades is activated Immediately pulled into an open position, whereby a lock switch opens immediately. The lock returns to a Closed position back after termination of a current which is fed to a closure solenoid. Such a system can can be used directly in connection with the circuit of FIG.

The aforementioned application also shows an associated timing circuit in which the environment is visible to a photocell controls the charging speed of a capacitor when the shutter is released. The capacitor voltage is the input fed to an amplitude comparator. The shutter is closed by pushing the comparator when the Capacitor voltage exceeds an invariable reference voltage that is generated internally in the comparator (not shown).

This circuit offers no possibility of detecting the film speed, so an appropriate exposure correction could be made while the present invention both the rate of rise of voltage as also controls the reference voltage across the film cassette samples.

The locking system specified in the aforementioned US patent application is of the "programmed" type in which a shutter is arranged to serve as a diaphragm stop, and the Lamellae are designed so that the shutter opening is open throughout the duration of the initial part of the exposure cycle is getting bigger and bigger. If the comparator is triggered, then the shutter closes immediately within a comparative negligible time. It is known that in this way using suitably shaped shutter blades a Doubling the shutter opening time quadrupling the actual exposure causes. As a result, a relatively minor change in the time interval may be required is until the capacitor reaches the reference voltage, cause a significantly larger change in the actual film exposure. In the following description of the circuit are the Circuit components are chosen so that the shutter opening times are reduced by approx. 30% in order to increase the film speed to offset by a factor of 2; however, it will be apparent to those skilled in the art that the system to be explained is not is limited to such limitations and the principles of the invention apply directly to non-programmed locks as well are valid.

In detail, FIG. 3 shows the comparator circuit, with fi lm sensitivity samples are derived from four scanning electrodes P1-P4 corresponding to scanning areas A1-A4, respectively 1 and 2 contact. It should be noted that the continuously conductive scanning area A1 from the scanning electrode Pi is scanned, this conductive area being led to system earth as shown in FIG. The contacting of a scanning

Any of the sensing electrodes P2-P4 results in the associated circuit elements being closed to ground and is denoted by an "ON" entry with respect to Table II, indicating that the associated, to earth leading switch is in an "ON" state. When the shutter switch SS is closed, the input A is the Amplitude comparator AC grounded, and the capacitor C2 is kept in the discharged state. When the shutter is released, which results in an immediate opening of the shutter switch SS, the capacitor C2 begins immediately through the resistor of the photoresistive element PC, which is coupled to the positive terminal of the battery B, to be charged. If no Charging takes place through the second branch, which is formed from the capacitor C1 in series with a switching transistor T to ground is, the rise time of the voltage at input A is determined by the value of the capacitor C2 and the resistance of the photo resistor PC adjusted according to the ambient light. Higher levels of lighting have a decrease in resistance of the photoresistor, which leads to a faster rise in the voltage curve and an earlier triggering of the amplitude comparator caused to excite the solenoid SOL and thus to close the shutter.

It should be noted, however, with reference to Table II that when the film speed is 32, the switching state is the Scanning electrode P2 is open or "OFF" so that the base of the transistor T due to the biasing effect of the resistor R1, which connects the base of the transistor to the positive terminal of the battery B, is driven in the forward direction. In In this case, the transistor T is kept live during the entire charging process, and both capacitors C1 and C2 need to be charged. If the capacitor C1 has a nominal value of 0.2 mF and the capacitor C2 the value of 0.5 mF is due to grounding of the scanning electrode P2 through a guide state scan, which is the case with film speeds of 64, 250 or 1000 is absolutely the case, the forward bias voltage between the base and emitter of the transistor T is

lifted so that the "ON" state of the transistor ended, the The charging process of the capacitor C1 is interrupted and the rise time at input A is reduced by approx. 30%. With it causes closing the switching state at the scanning electrode P2 to the "ON" state reducing the exposure time by a factor of 30% for any given reference voltage am Input B of the amplitude comparator AC. When using a With the programmable shutter, the film exposure time is reduced by a factor of 2.

A diode D can optionally be connected between the emitter and the collector of the transistor T to ensure that the capacitor C1 is fully discharged before the switch SS is opened. In order to have a conductive state The transistor is responsible for achieving the smallest possible voltage drop T prefers a germanium component.

Before the setting of the reference potential by means of the film speed scanning results is explained below it should be noted that Table II shows that the samples of sample areas A2, A3 and A4 show two patterns. First for the pairs of film speed groupings 32 and 64, 125 and 250, and 500 and 1000 are the A3-A4 samples identical for each of these pairs, whereas they are different from pair to pair. Within each of these pairs is also to note that a conductive state detection at the scanning area A2 (corresponding to a grounding of the scanning electrode P2) always the higher film speed of the couple. When considering the setting of the reference voltage from the scanning states of the scanning areas A3 and A4 it can be seen that the A3-A4 scanning values serve to establish the shutter open time for a given pair of film speeds to determine, and that the scan of A2 that the selective connection of the capacitor C1 in the charging circuit is determined, as already described, serves to the capacitor Decoupling C1 in order to achieve the shorter exposure time corresponding to the higher film speed value of the couple.

Thus, referring to Table II and Figure 3, it can be seen that the longest shutter open time of any film speed 32 should correspond. Since this is the longest shutter-close delay time in the system, it will be shown below referred to as the "base" exposure time.

With regard to the sensitivity pair 32 and 64, it is on the reference voltage applied to input B of the comparator is set to the maximum value of the various values that can be supplied, see above that the longest time is required for the charging of the parallel-connected capacitors C1 and C2 to the ignition value. As already mentioned, the capacitor C1 is separated from the charging circuit by a coded film sensitivity 64, which is a Reduction of the trigger time interval by approx. 30%.

When looking at the reference voltage source it can be seen that the reference input B of the amplitude comparator AC receives a damped battery voltage from the connection point of the resistors R2 and R3, the nominal values of 4 kΩ resp. 8 kJX- have. For ISO sensitivities 32 and 64, those are Resistance values of R2 and R3 selected so that the correct trip reference potential at input B of the amplitude comparator is applied so that the charging of the capacitor C2 or the capacitors C1 and C2 the corresponding correct exposure times results.

The two resistors R4 (nominal value 1 k £ L.) And R5 (nominal value 3 k-Ω.), Which are coupled to the scanning electrodes P4 and P3, respectively gind, cause a selective shunting of the connection point of the pair of damping resistors R2-R3 to ground, whereby the reference voltage applied to input B of the comparator AC can be set. The film speed pair 32-64 is closed note that both scan areas A3 and A4 are non-conductive so that neither resistor R4 and R5 is in parallel with the resistor R3 is switched into the circuit. As a result, with a nominal value of 3 V for battery B, the one at the input

B of the amplitude comparator AC applied reference voltage 2.0 V. Regarding the next pair of film speeds, 125-250 Note that scanning area A3 is conductive and scanning area A4 is non-conductive. This means that the resistor R5 is im Shunt connected in parallel to resistor R3 in the circuit, whereby the amplitude comparator supplied Reference voltage is reduced to approx. 1.05 V. Since the reference voltage has been reduced by a factor of 2, the one for the Applying the capacitor voltage to input A of the amplitude comparator AC required by one accordingly Factor reduced by approx. 2. Since with a programmed shutter, the shutter open time is reduced by one Factor 2 causes the actual exposure time to be reduced by a factor of 4, so it can be seen that with a grounded Scan electrode P3 the shutter now on a film speed 125 is set, the required reduction by a factor of 2 to adapt to a film speed 250, as already stated, is achieved by grounding the scanning electrode P2 so that the capacitor C1 is off is decoupled from the charging circuit.

Finally, it is with regard to the film speed pair 500-1000 it should be noted that here the scanning electrode P4 is grounded due to the conductive state of the scanning area A4 and the scanning area A3 is non-conductive, so that resistor R5 is disconnected from the circuit. If now the resistor R4 is selective is switched on parallel to resistor R3, it can be seen that the applied to input B of the amplitude comparator Reference voltage is approx. 0.54 V, which is a further reduction by a factor of 2 compared to the reduction for the previous pair (125-250) and from the further Halving of the shutter open time results; accordingly, the actual exposure time is reduced by a factor of 4 and corresponds to the film speeds in this end range.

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It should also be noted here that the resistance value of a linear photo sensor is reduced by half when doubles the brightness, and thus would reduce the charging time by a factor of 2, so that with one programmable shutter would reduce the actual film exposure by a factor of four. To this To overcome the problem, the non-linear type photo sensor used in conjunction with a programmable shutter must be used be, preferably a cadmium sulfide cell with a rate of resistance change of approx. 1.4 for each doubling of the brightness.

It has thus been shown that a simple scanning of three relevant coding areas of the film cassette by scanning electrodes is applicable to the rate of change of a timing waveform and the magnitude of the reference comparison voltage so to regulate that a satisfactory shutter control circuit for controlling the exposure within an error range of 30% is provided. Any iS decoders or microprocessors are not required, and it can be seen that the circuit of FIG. 3 can be implemented with very little cost can be produced. For those skilled in the art it is equally evident that other sensing elements can also be used instead of the conductivity sensors can be used. For example, means for detecting the reflectivity of light may be of various types used by magnetic scanning means; however, allows use for the reasons listed below of conductivity sensing electrodes directly connected to the relevant circuit elements are coupled, certain circuit simplifications to achieve a satisfactory Shutter speed control.

Furthermore, the concept of the invention is by no means programmable Locks limited; however, if low battery voltages are to be used, then this is the present one The invention is particularly suitable for this because of the ability to use the exposure time within wide limits relatively small changes in the reference voltage to control and

at the same time within the operating limits of the amplitude comparator to stay. It should be noted, however, that the basic idea disclosed here, which is based on the recognition of certain common patterns within the Kodak DX system's cassette scan codes, a direct extension of the Invention also allowed for non-programmable closures by techniques known to those skilled in the art.

It will be apparent to those skilled in the art that a variety of logical decoders can be used to obtain the sample results from the To decode scanning electrodes and to assign suitable reference potentials, capacitor ignition signals and associated control functions produce; However, such systems have the disadvantage that for the installation of such logic switching elements in the system high cost is required; furthermore, there is the disadvantage that such elements generate output control voltages which neither ground potential nor the positive system bus voltage of z. B. 3 V in the present circuit. Thus can Although such decoders are used in one form or another to perform the functions described, but the The invention offers the significant advantage that, with regard to film speeds from 32 to 1250, a simple grounding of Shunt dampers and a transistor charging switch, which does not require the interposition of logic control elements, can be used to control exposure which is completely sufficient for normal photographic purposes. Furthermore, the present system does not require any Complex correction for displacement voltages (and their normal propagation) that occur when designing gated logical decoding systems in connection with exposure control somehow have to be taken into account. Obviously, the invention offers a significant improvement over this such systems in terms of cost.

S. TABLE I. A2 SCAN CONDITION A4 C. A5 - ■ A6 SCAN AREA AND (c = conductive) C. C. NS. A3 C. C. (ISO) C. C. C. 25th C. C. C. 32 . C. C. C. 40 C. C. C. 50 C. 64 C. 80 C. C. C. 100 C. C. C. 125 C. C. C. 160 C. C. C. C. 200 C. C. '250 C. C. 320 C. C. 400 C. C. 500 C. C. 640 C. C. C. 800 1000 1250

TABLE II

AVERAGE SCANNER AND C. C. SAMPLING EXPOSURE NS. SENSOR STATUS C C C C (ON OR OFF) TIME (ISO) A2 A3 A4 P2 P3 P4 BASIC TIME 32 OFF OFF OFF 0.7 of BASE TIME 64 C. ON OFF OFF 0.5 of BASE TIME 125 OFF ON OFF 0.35 from GRUNDZEIT 250 ON ON OFF 0.25 from GRUNDZEIT 500 OFF OFF ON 0.18 from GRUNDZEIT 1000 ON OFF ON

Please note: c = electrically conductive

Claims (21)

Claims 1. Still camera in which a film cassette can be inserted and which is fed by an electrical power supply and comprises: an electrically controlled shutter, an ambient light sensor which generates an ambient light-related signal, indicating the ambient light level, the shutter control being coupled to the ambient light signal transmitter to control the shutter open time or exposure time in accordance with the ambient light level and has means for Adjustment of the exposure time according to the respective film speed, whereby the film speed by a on the outside of the cassette code is given in the form of a plurality of specific areas, each of which is indicated by a first or a second, indicating the film speed State is characterized, the states of the plurality of specific areas jointly essentially one represent accurately coded representation of the film speed, and with the shutter control scanning electrodes for scanning the film speed state of a number of these areas as a measure of the film speed and for controlling the exposure time so that the exposure time at least approximately in accordance with the film speed indicated on the cassette is correctable, characterized in that the shutter control has: a time control element which, when the shutter is opened, generates a time-adjustable electrical signal necessary to achieve of a predetermined threshold value requires a certain time interval after the opening of the shutter, the The time interval can be changed according to the ambient light-related signal status, a threshold value setting unit, which is a time-immutable generates an electrical signal with a given threshold value, and a comparator (AC), which compares the time-changeable and the time-unchangeable signal with each other and at Equality between the two actuates the shutter in a closed position, the timing member being time interval changing members which controllably respond to the scanning electrodes (P1-P4) and the time interval for each value of the Ambient light-related signal state to at least two different values in accordance with the scanning values of the scanning electrodes Adjust (P1-P4). 2. Camera according to claim 1,
characterized in that the time interval changing elements have means for adjusting the rate of change of the signal which can be changed over time on the basis of the scanning state of at least one of the scanning areas (A2-A6). 3. Camera according to claim 1,
characterized in that the threshold value setting unit has means which respond in a controllable manner to the sampled values of at least one of the sampled areas for generating at least two different, temporally unchangeable signal levels based on the sampled values. 4. Camera according to claim 2,
characterized in that the threshold value setting unit has means which respond in a controllable manner to the sampled values of at least one further of the sampled areas while generating at least two different, temporally unchangeable signal levels based on the sampled values. 5. Camera according to claim 1,
characterized in that the time interval changing unit has capacitors (C1, C2) coupled to the photo sensor (PC) which can be charged at a speed determined by the magnitude of the ambient light-related signal, so that the time interval is determined by the magnitudes of the capacitors and the ambient light level is. 6. camera according to claim 5,
characterized in that the time interval changing unit has means for changing the size of the capacitors (C1, C2) in accordance with the scanning state of at least one of the scanning areas. 7. camera according to claim 6,
characterized in that the sampling state of only one of the sampling areas (A2-A6) is used to regulate the size of the capacitor between only two values of the same. 8. Camera according to claim 7,
characterized in that the two values are chosen so that the time interval can be changed in such a way that the exposure time can be changed by a factor of approx. 9. Camera according to claim 3,
characterized in that three different, time-immutable signal levels are generated by the threshold value setting unit on the basis of the scanning states of two of the remaining scanning areas. 10. Camera according to claim 1 or 9,
characterized in that the time-unchangeable signal levels can be derived from controllable attenuators (R2, R3) which are fed by the voltage supply (B) and activated on the basis of the scanning states to form the various time-unchangeable signal levels. 11. Camera according to claim 1,
characterized in that the coding of the plurality of specific areas (A1-A6) is designed in such a way that the code patterns given by a specific smaller plurality of these areas designate film sensitivities which fall within a series of contiguous regions and span a considerable variation in film sensitivities, so that each code pattern corresponds to at least an approximate value of the film speed. 12. Camera according to claim 11,
characterized in that the given smaller majority consists of three specific areas (A2-A4), the different codes of these three areas jointly designating the film speed in increments of not more than a factor of 2 and a variation in film speed of approx. 30: 1 span. 13. Camera according to claim 12,
characterized in that the time interval changing unit has means for adjusting the rate of change of the signal which can be changed over time on the basis of the scanning state of one of the three scanning areas (A2-A4). 14. Camera according to claim 13,
characterized in that the threshold value setting unit has means which respond in a controllable manner to the scanning conditions of the two remaining scanning areas while generating three different, time-immutable signal levels based on the scanning conditions. 15. Camera according to claim 14,
characterized in that the time interval changing unit has capacitors (C1, C2) which are coupled to the photo sensor (PC) and can be charged at a rate determined by the size of the ambient light-related signal, so that the time interval is determined by the sizes of the capacitors and the Ambient light level is determined. 16. Camera according to claim 14,
characterized in that the time interval changing unit has means for changing the size of the capacitors on the basis of the scanning state of the one of the three scanning areas (A2-A4) for regulating the capacitor size between two values. 17. Camera according to claim 16,
characterized in that the two values are chosen so that the time interval can be changed in such a way that the exposure time can be changed by a factor of approx. 18. Camera according to claim 14,
characterized in that three different signal levels which cannot be changed over time are provided by the threshold value setting unit on the basis of the scanning states of the two further scanning areas. 19. Camera according to claim 18,
characterized in that the temporally unchangeable signal levels can be derived from controllable attenuators (R2, R3) fed by a voltage source (B) which can be activated on the basis of the sampled values to form the various temporally unchangeable signal levels. 20. Camera according to claim 1, 11 and 12, characterized in that an electrically conductive layer is provided on the film cassette and that the code pattern over this conductive layer by the presence of each increases the film speed The insulating layer covering the indicative area or the absence of such an insulating layer is formed and that the sensing elements a plurality of electrically conductive sensing electrodes (P2-P4) for physical contact with a plurality of the areas; and one common electrically conductive scanning electrode (P1) for the electrical Contact with the conductive layer so that the sensing states of each area are open and shorted, respectively between each of the plurality of scanning electrodes (P2-P4) and the common scanning electrode (P1). 21. The camera of claim 1, 11 or 12 in combination with the Film cassette, characterized in that an electrically conductive layer is provided on the cassette and that the code pattern over this conductive layer by the presence of each indicative of the film speed Area covering insulating layer or the absence one such is formed and that the scanning elements a plurality of electrically conductive scanning electrodes (P2-P4) for the physical Contact with several of the areas (A2-A4) as well as a common electrically conductive scanning electrode (P1) for electrical Contact with the conductive layer so that the samples for each area have an open or short circuit condition between each of the plurality of scanning electrodes and the common scanning electrode.