DE2020386A1 - Electronic shutter speed control device with data storage - Google Patents

Description

Electronic shutter speed control device with data storage The present invention relates to an electronic shutter speed control device with memory of the measured value in photographic cameras.

Circuit arrangements for controlling the shutter in photographic Cameras with an RC circuit with a photo resistor and ultimately one of this Circuit operated electromagnet that closes the previously opened shutter causes are known. It is also known that in cameras in which the photo resistor does not remain exposed to light during the exposure time and also with cameras with partial measurement the measured value must be saved because the photoresistor during the recording is either not exposed to light or on something that is not important for the image Object detail is directed.

This storage takes place in cameras with mechanical shutter speed control usually mechanically, e.g. by clamping a measuring device pointer. But it is on the hand that one strives for cameras with electronic shutter speed control is to also carry out this storage electronically.

For this purpose, it is known, for example, in the camera a Provide incandescent lamp that is in one of the exposure light during the exposure time exposed light-sensitive control circuit and used as a light source for the Photoresistor of a separate timing electronics is formed.

On the other hand, because of the large scope of measurement and adjustment but It has also already been suggested not to save a vert of the illuminance on the photoresistor (or the time to be formed) is linear-analog, but logeritcisch-analog is and it has already been pointed out in this context that the logarithmization and deogarithmization need not be absolutely exact if these two Operations are "mirror images", i.e.

if the voltage-object luminance function of the measuring circuit and the loading function of the RC element in the locking control circuit along a mirror image Relocate curves.

The present invention is based on the object of this Spielgulvildlichkeit Erakt to guarantee and to indicate means, which ensure that external ones Influences, especially temperature influences1, on the logarithmic process and the delogarithmic process affect in the same way.

This object is achieved according to the invention in that for the Logarithmizing and delogarithmizing the same approximately logarithmizing and in any case non-linear member both for input into the memory member and is used for output from it, which is used when storing the measured value in The negative feedback branch of an operational amplifier is located at the output Charging current of the closure actuation circuit supplies or controls.

In particular, it is proposed as such a logarithmic Link to use a transistor, which is connected downstream of an operational amplifier is, being between these.

Transistor and the op-amp if necessary an impedance converter with high Input resistance is arranged.

In a further embodiment of the invention, known per se Veise A measuring mechanism must be inserted into the circuit, so that the exposure time to be expected is displayed and sorbit is made recognizable for the user before the recording. This The measuring mechanism can at the same time take over the storage. Instead, a Motor potentiometer can be used, but a galvanometer amplifier can also be used be provided with a voltage divider from photoresistors or from magnetic controlled resistors interacts and has a pointer that shows the expected Closing time indicates.

In the drawing, the invention is shown in several examples shown. 1 shows the schematic circuit diagram of the inventive Locking time control device lit capacitive storage of the measured value in its Basic form.

Fig. 2 is a circuit diagram of the shutter speed control device Dit measuring mechanism and follower potentiometers as display and storage element, Fig. 3 is a circuit diagram of the Shutter time control device with a motor potentiometer as an additional measuring mechanism is used, which also serves as a memory, Fig. 4 is a circuit diagram of the shutter control device, in which a galvanometer amplifier with controlled resistors is used.

The circuit according to Fig. 1 includes an operational amplifier 1, the by two resistors 4 and 5 acting as voltage dividers with sineim non-inverting Input is connected to a potential 6. At its inverting input is a Photo resistor 3 connected. A storage capacitor 13 is attached to the OP amplifier 1 and an impedance converter 2 followed, with the output of which is the base of a transistor 7 is controlled. This transistor 7 works as an approximation logarithmic Element.

The actual shutter speed circuit consists in a known manner a time circuit capacitor 8 and a threshold switch 9 and an electromagnet 10. A changeover switch 11 is placed between the transistor 7 and the capacitor 8, which allows the collector current to be used as the charging current at the start of the shutter speed to feed the capacitor 8.

Furthermore, a measuring button 12 is provided which simultaneously has two switches actuated, namely once a switch 13a in the circuit from the collector of the transistor 7 to the photoresistor 3, and on the other hand a switch 13b in the connection between the OP amplifier 1 and storage capacitor 15 and the impedance converter 2 This arrangement works in the following way at the inverting input of OP amplifier 1 the same potential occurs as in point 6. Thus flows through the photo resistor 3 a current proportional to the voltage difference between the + pole of the power supply and the potential in point 6. This difference is constant. The current is further away but also vice versa proportional to the resistance value of the photo resistor 3 in the each occurring lighting and thus proportional to the illuminance, if its slope exponent is equal to 1. By the dashed line 14 in front the photoresistor 3 is indicated that through a filter or a diaphragm Exposure parameters, such as the film speed and / or the lens aperture value, can be entered. If the double-pole switch 13a, 13b is closed with With the help of button 12, the output voltage of the OP amplifier 1 is switched over the impedance converter 2 on the one working as a logarithmic term Transistor 7 given. The base voltage will therefore adjust itself so that the collector current of the transistor 7 is practically the photoresistive current. Just a very small one A fraction of the photoresistor current is required to control the OP amplifier.

The output voltage of the OP amplifier 1 is thus determined by the IC / UBE characteristic of the transistor 7 is determined. This characteristic curve is approximate within a wide range logarithmic or

exponentially. If necessary, the transistor can also have another Non-linear element, such as diode lines or a varistor or a fixed voltage divider upstream in order to be able to control the OP amplifier further or

to work with larger voltages across the storage capacitor 15 to be able to.

If the switch 13a, 13b is now opened again, the storage capacitor stops 15 the voltage at the input of the impedance converter 2. Its input resistance iei very high, which e.g.

achieved by using a field effect transistor in source connection can be. In this case, the field effect transistor could possibly simultaneously the Take on the role of the approximately logarithmic term.

With a leakage current of 1pA and a capacitance of 0.1 / uF results A voltage drop of 1 mV occurs within 100 s.

The collector current of the transistor 7 is thus practically constant continue to flow as long as the wiring of the collector circuit allows this.

This current flow is initially interrupted by opening the switches 13a, 13b. If the switch 11 is now switched over, the collector current charges the time circuit capacitor 8 on.

The switch 11 is used as a short-circuiter in cameras with electronic Shutter speed control already known. It is generally used when the Closure is also open, with which the respective short circuit of the time circuit capacitor will be annulled. The threshold switch 9 and the magnet 10 are also already known components. When a certain voltage value is reached across the capacitor 8, the threshold switch 9 switches the magnet on or off and thus causes it the closure of the shutter.

The basic circuit shown in FIG. 1 is particularly evident clearly the advantage of the arrangement according to the invention. Because only a non-linear The element used for logarithmizing and delogarithmizing1 is namely the transistor, all errors in these arithmetic operations are eliminated. In particular, the temperature dependency falls of the non-linear semiconductor element, it being possible to assume that between measurement and exposure the temperature of this term is negligible changes.

In order to display the expected exposure time, the circuit can be used Furthermore, a measuring mechanism can be inserted, e.g. as a voltmeter 16 at the output of the OP amplifier (shown in dashed lines).

Fig. 2 shows how this measuring mechanism is used at the same time as a memory can be so that the storage capacitor 13 and the impedance converter 2 are omitted. Instead, the measuring mechanism 16 works with a potentiometer 23, whose Tap is adjusted by the measuring mechanism, but in such a way that the tap is free Uber the resistance track plays as long as button 12 is pressed. The measuring mechanism 16 and the potentiow meter 23 are calibrated so that when you press the tap 24 on the resistance path of 23 the potentioieter the same tension outputs which is applied to the measuring mechanism 16.

The switch 13b is designed as a changeover switch that when pressed Button 12 the direct connection between the output of the OP amplifier 1 and the Transistor 7 is made. At the same time, the measuring mechanism lock is released, so that the tap arm of the potentiometer can move freely over the resistance track can. The measuring mechanism then adjusts itself to the starting position of the OP amplifier a. When the measuring button 12 is released, the measuring mechanism is locked and the tap 24 pressed on the resistance track of 23.

At the same time, the base of the transistor is activated by means of the switch 13b no longer controlled by the output of the OP amplifier, but by potentiometer tap 24. As already stated, the voltage at the tap 24 should be the same as before au output of the OP amplifier was present The electronic shown in this example Storage by means of a lockable measuring mechanism and sequence potentiometer has opposite the capacitive storage has the advantage that no self-discharge takes place and so can be stored for as long as desired, so that it is possible to take continuous shots without to perform a new exposure measurement.

In the embodiment of Figures 3 and 4, the measuring mechanism 16 and the pole potentiometer 23 in a manner known per se by an automatic compensation arrangement replaced.

Fig. 3 shows an arrangement with a motor potentiometer according to the Potentiometer recorder method, In this circuit, the output voltage of the Operational amplifier to one of the two inputs of a differential amplifier 17, the output voltage of which is applied to a motor 18.

The rotor 18 adjusts the tap of a potentiometer in a known manner 19, until the voltage tapped from the potential conductor equals the Output voltage of the Operational amplifier 1 will, since both voltages are at the two inputs of the differential amplifier 17. So is at the base of the transistor 7, which is exactly as in Fig. 1 and 2 here also as approximately logarithmic Element works, the output voltage of the op-amp.

A pointer 19a can be connected to the potentiometer tap indicates the expected shutter speed on a scale 19b. This scale is 19b The better the nonlinear term logarithmic, the better the linear division.

From this display, however, you will generally only get a crude one content expected for the resulting exposure time.

If the switch 13a, 13b is now opened, the motor 18 will open all cases currentless. However, the potentiometer 19 still supplies the same voltage, even if the supply voltage is switched off in between.

In Fig. 4, a galvanometer amplifier is used for simultaneous display and storage used. The galvanometer 20 controls two light-dependent or magnetically controllable Resistors 21 and 22 that form a voltage divider. In the figure this is through a permanent magnet 25 adjusted by the galvanometer is indicated. In this case elements 21 and 22 are to be designed as field plates or magnetic diodes.

Claims (7)

Claims 0 Electronic shutter speed control device with measuring mechanism memory for photographic cameras with a measuring circuit with RC element, with photo resistor, with a storage element and a shutter actuation circuit with electromagnets, at which the value to be saved is saved logarithmically and in delogarithmized form is supplied to the shutter actuation circuit, the logarithmization and the delogarithmization take place in mirror image, characterized in that for the logarithmization and the delogarithmization the same approximately logarithmization and in any case non-linear element both for input into the memory element (15) as is also used to output from it, which is when the measured value is stored in the negative feedback branch of an OP amplifier (1) and that at the output of the Charging current of the shutter actuation circuit supplies or controls. 2. Electronic shutter speed control device na oh claim 1, characterized in that the OP amplifier is a transistor as the logarithmizing member (7) connected downstream and, in the case of capacitive storage, between the storage capacitor (15) and the transistor, an impedance converter (2) with a high input resistance is arranged is. 3. Electronic shutter speed control device after spraying 1 and 2, characterized in that the transistor (7) is a further non-linear Element or a voltage divider is connected upstream. 4. Electronic shutter time control according to claims 1 to 3, characterized in that to display the expected exposure time the So holding is provided in a known manner with a measuring mechanism (16). 5. Electronic shutter speed control device according to claim 4, characterized characterized in that the measuring mechanism in connection with a following potentiometer (23) is used as memory and display at the same time. 6. Electronic shutter speed control device according to claim 4, characterized marked that nls measuring mechanism a motor potentiometer (18,19) is used, the at the same time serves as a memory and with the interposition of a differential amplifier (17) a output of the OP amplifier (1) is located. 7. Electronic shutter speed control device according to claim 4, characterized characterized in that a mechanically lockable galvanometer (20) is used as the measuring mechanism is that a voltage divider made up of light-dependent or magnetically controlled resistors (21,22) adjusted and has a pointer that shows the expected shutter speed.