DE1169154B - Device for the control of light measuring devices with self-adjustment, especially for a camera with automatic shutter - Google Patents

Description

Device for regulating light meters with self-alignment, in particular for a camera with automatic shutter The invention relates to a device for Regulation of light meters with self-alignment, especially for a camera Shutter priority. In a bridge circuit operated with DC or AC voltage there is a photoresistor to which an automatically controllable light attenuation device is located is upstream. Such devices are known. The disadvantage here is that the sensitivity of the bridge circuit in the area of the input values is only approximate can be kept constant if all bridge resistances are dependent on. the Input values can be changed. This represents an avoidable additional effort; further this makes operation more difficult and increases the susceptibility to failure.

The invention assumes essentially only a single bridge resistor to use for entering exposure factors. If you were to resist the Provide bridge branch that does not contain the photoresistor, so the Sensitivity of the circuit depending on the input values strong fluctuations be subject to. In addition, the sensitivity of the circuit would be considerable Dimensions depend on the manufacturing tolerances of the photoresistors, as the sensitivity the circuit for the stability of the control process and for avoiding one Commuting is decisive. As is well known, it depends on the sensitivity of the circuit essentially depends on whether the control process is stable and oscillation is avoided will. Due to the occurrence of very large tolerance values for the photoresistors, the There is a risk that an inherently stable control process by extending its maximum sensitivity is laid in areas where stability is no longer guaranteed. Even Due to the manufacturing tolerances, aging of the photoresistors may result change the sensitivity of the circuit in an unfavorable sense.

According to the present invention, it is proposed to use essentially only the bridge resistor R, which is in series with the photoresistor R, for the input of exposure factors, in particular the sensitivity. For this purpose, R , is made controllable continuously or in steps, the resistance values corresponding to the individual control positions or steps being proportionally matched to the resistance values of the photoresistor corresponding to the input values. This is to be understood as follows: The automatic control system to which the invention relates has the property of generating a diaphragm-independent illuminance on the photoresistor, regardless of the brightness of the object. The size of this illuminance still depends on the input values, in particular the sensitivity of the film sensitivity to be set on R. or on the exposure factors to be taken into account. These different values of the illuminance correspond to different resistance values of the photoresistor RV. According to the invention, R, is measured such that the ratio u = RI / R2 is constant for all input values after the automatic control has responded. This means that the resistances RI, and R must also be dimensioned for the same resistance-4 ratio, since, as is well known, the ratio equation Ri: R2 # R 3: R4 must be fulfilled when balancing the bridge. Furthermore, according to the invention, the resistance ratio is to be set to such a value that the relay located in the diagonal circle of the bridge for actuating the automatic aperture control reaches its greatest response sensitivity at the lowest, electrically considered film sensitivity or the highest exposure factor, which also occurs when the photoresistive values deviate up to Factor 3 or a third of the target value, e.g. B. as a result of the manufacturing process, is exceeded neither for more sensitive nor for less sensitive photoresistors.

On the one hand, a high level of setting accuracy is required of an automatic aperture control, on the other hand, good stability of the control process. To meet these conditions the control circuit must have a high sensitivity, but it must not in the event of unfavorable operating conditions or as a result of the manufacturing requirements Tolerances of the electrical switching elements, especially the photoresistors, unstable and start to commute. The tendency to instability is greatest when with low film speed, i.e. with a lot of light, and with a photoresistor high sensitivity is used.

If the bridge is designed in such a way that predominantly the resistor R2 (Fig. 1), which is in series with the photoresistor R, is used to input the film speed, the circuit has the property that it delivers the greatest control current for the lowest film speed A quantity referred to here as interval current -4 i is suitable for the measure of the control current. This is the control current that flows through the control relay when the illuminance of the photoresistor changes by an interval after the bridge has been adjusted . H. changes by a factor of 2 or 0.5 .

F i g. 2 reveals how this interval current changes in the proposed circuit as a function of the input DIN number. For curve a, which relates to a photoresistor of average sensitivity, the interval current drops continuously from 12 to 27 'DIN, for example from 0.3 to 0.25 niA. For more sensitive (curve b) and less sensitive photoresistors (curve e) the drop is smaller or larger. F i g. 2 shows, however, that the circuit can be dimensioned in such a way that the interval current does not rise above the value 0.3 mA given, for example, for any input value and especially when using more sensitive or less sensitive photoresistors. In the example chosen, this current of 0.3 mA corresponds to the desired operating current of the automatic shutter control, with which, on the one hand, a high level of setting accuracy is achieved and, on the other hand, an instability of the control process is reliably avoided. Another advantage of the proposed circuit is that photoresistors can be used with any resistance (R) illuminance (E) characteristic curve, in particular with a resistance (R) illuminance (E) characteristic curve that runs in a double logarithmic representation, since it is because of the proportional replication of the value range of R, by R 2 it is possible to electrically take into account anomalies of the photoresist characteristic. The present invention goes beyond an older proposal in that a circuit for photoresistors with a linear log R = log E characteristic is dealt with.

Attention should also be paid to the practical advantage which results from the fact that the circuit has its greatest response sensitivity at the lowest film speed. Since highly sensitive films can be produced with a greater exposure latitude than less sensitive films, the course of the sensitivity characteristic is shown in FIG. 2 contrary to the practical requirements.

According to the invention, the size of this interval current is influenced by the two fixed resistors RI and R4 of the second bridge branch in a specific manner, which will be explained in more detail below. Depending on the adjustment ratio, i. H. Depending on the size of the relay resistor R, compared to the other bridge resistors, fixed resistors R3 and R 4e of different sizes are required for a certain control current, and the rule is that the bridge becomes more sensitive with decreasing resistance R, + R4. With the help of R and R4, the sensitivity can be adjusted to a permissible optimum value. The aim is to ensure that this optimum value is not exceeded when using photoresistors of different sensitivity, but is also fallen below as little as possible. An investigation has shown that this property can be significantly influenced by a suitable choice of the resistance ratio u = R, IR for balancing the bridge.

According to the invention, one of the two resistors R3 and R4, preferably R ″, is set to a constant value within a production series, while the other resistor, preferably R4, is made variable or interchangeable for the purpose of balancing the circuit and compensating for the specimen variance of the photoresistors If R. is determined as a constant resistance, one has the advantage over the choice of R4 that the less sensitive photoresistor, which has a higher resistance Ri than the average photoresistor under given lighting, has a smaller value of R41 and therefore also a smaller value of the maximum R, + R4, which determines the sensitivity. The loss of sensitivity due to the use of a less sensitive photoresistor is thus partly compensated for in this case by an increase in the sensitivity of the circuit.

If it becomes necessary to add correction values to the To enter the circuit, it may be useful to use the one in a production series initially constant set resistance R, also exchangeable or in certain To make boundaries changeable. It turns out to be for this subsequent change it is advantageous that R, set constant for all copies of a production series is because the change is then the same for all copies of a production series Way can be made.

To explain the assertion that the proposed circuit can be made immune to specimen deviations of the photoresistors by a suitable choice of the resistance ratio u for the bridge adjustment, refer to FIG. 3 referenced. This figure shows a diagram of the so-called interval voltage 1 U as a function of the resistance ratio u = R, IR. = R, IR, the bridge. Here, the interval voltage is to be understood as the terminal voltage that occurs at the consumer, the relay, with the resistor RO in the diagonal branch of the bridge when the illuminance of the photoresistor changes by a jump by a factor of 2 or 0.5, i.e. after adjusting the bridge. H. changes by an exposure interval. When the automatic control responds, this voltage becomes zero again, so it is only effective for the first moment before the automatic control responds and represents a measure of the sensitivity of the bridge arrangement.

The selected parameter is v = (R, + R3) / RO. The curve vo represents the no-load voltage, the curves for v 1, 3, 10 correspond to increasing loads on the bridge with decreasing consumer resistance R .. The curves have a maximum which, starting at u = 1 , increases more and more towards higher u -Values shifts. According to the invention, the resistance ratio u is chosen so that the operating point of the circuit is at the lowest film speed entered by means of R, i.e. H. at the smallest value R ", i", of the average photoresistance, is located approximately at the maximum of the associated v-curve. In this regard, it should be noted that R, i, is usually small compared to R ', so that the useful voltage even with a different resistance value of the photoresistor, i.e. H. with photoresistors of different sensitivity essentially the selected v-curve, z. B. v = 1 follows. The selected setting ensures that photoresistors with double or half sensitivity deliver a useful voltage only about 11 1 / o lower than the average photoresistor. The condition can also be defined in such a way that the resistance ratio u for the average photoresistance is set to a value u > 1 or, more precisely, to the value should be set. By the condition is namely the locus a of the maxima in FIG . 3 marked.

A further aim is to ensure that the power of the bridge is matched to the relay resistance at the highest film speed to be taken into account, at which the resistance of the average photoresistor reaches its maximum value Ri max. This adaptation is achieved at half the open circuit voltage (curve b in FIG. 3). It satisfies the condition v = 1 # - u, so that approximately (R, max + R3) IR,) = 1 + u must be chosen. The two curves a and b in FIG. 3 intersect at the point u = 2, v = 3, which corresponds to the optimal power adjustment of the consumer R for given values Rl, R. The bridge is expediently set to this operating point if only relatively few exposure values or, in the limit case, only a single exposure value is to be entered electrically into the bridge. These working conditions are particularly present when the film speed and other exposure values are in part also entered optically by a light attenuation device in front of the photoresistor. In Fig. Finally, a locus curve c is drawn in 3 , which corresponds to a 90 % power adjustment. In order to achieve a performance adjustment of at least 90%, the variables u and v, as can be seen from FIG . 3 results, move within the tolerances 1.2 < u < 3.2 and 1.5 < v <7.

F i g. 1 and the corresponding explanations initially relate to a bridge operated with direct current. However, the considerations remain valid even if the bridge is operated with alternating current. F i g. 4 shows an embodiment. In addition to the four bridge resistors, two rectifiers G 1 and G 2, a smoothing capacitor C and a transformer Tr are provided for introducing a constant auxiliary AC voltage into the diagonal circuit. The purpose of the auxiliary voltage is to control the rectifier in the linear part of its rectifier characteristic. This measure ensures that the generally curved characteristic of the rectifier does not reduce the sensitivity of the circuit. As with direct current, the relay is designed as a polarized control relay. To increase the sensitivity, a so-called zero-current amplifier can be switched on between the diagonal circle of the bridge and the rectifiers.

F i g. 5 shows an example in which a transformer-coupled amplifier stage with transistor T is used for amplification and a ring demodulator consisting of four rectifiers G1 to G4 is used for rectification. The control relay is designated with RO, Tr, and Tr2 are the input and output transformers of the transistor amplifier, which is supplied with direct current via the rectifier G ″ and the capacitor C. The ring modulator is also supplied with a constant auxiliary alternating voltage via the potentiometer R If a battery-powered resonant circuit with transistor is used as the alternating current source, the circuit is suitable for portable devices with high sensitivity, since the amplifier stage increases the sensitivity of the bridge circuit considerably The output voltage should not be fed to a control relay, but directly to a servomotor for the automatic shutter.

In the following, measures to correct slope deviations are described of the used photoresistors from the 1j average value treated.

F i g. 6 shows the curve of the resistance (R) illuminance (E) -Ken "e for the average photoresistance R, in a double-logarithmic representation, as well as the settings of the DIN number controller R that are proportionally reproduced to this characteristic curve. The operating points for the DIN sensitivities 12 are also entered 15 etc. to 27 'DIN. As is well known, the control diaphragm works in such a way that the photoresistor, after entering the resistance R corresponding to the DIN sensitivity, is set to the resistance value R that corresponds to the illuminance associated with the input value Fig. 6 shows the same abscissas.

It has already been stated that sample tolerances of the photoresistors can be compensated for by a suitable choice of the bridge resistors R 3 and R4. The adjustment is useful for a medium DIN sensitivity, e.g. B. for 0.5 (12 + 27) = 19.51 DIN . As indicated in FIG. 1.0 , however, especially in the end points of the characteristic curve, e.g. B. at 12 and 271 DIN, residual errors occur as a result of a different slope B = -A log RIA log E of the photoresistor characteristic from the average value. To eliminate these residual errors, the following procedure can be used: Firstly, with a continuous DIN number controller, the sensitivity scale can be made dependent on the steepness of the photoresistors. The rule here is that the distance between the graduation lines must be approximately proportional to the steepness of the photoresistors.

Second, changes in slope can be corrected by not setting the bridge to a completely constant resistance ratio. The resistance ratio, as shown in FIG. 7, is expediently made variable within certain, relatively narrow limits by inserting a potentiometer R coupled to the DIN number regulator R. Depending on whether the connections aa ', bb' or a'b, ab ' are connected to one another, steepnesses that are too small or too great can be corrected.

Thirdly, it is possible to change the setting values of the bridge by simultaneously using a series and a parallel resistor either to the photoresistor according to FIG . 8 or to the DIN number regulator according to fig . 9 to change.

10 shows the effect of the additional resistors R 11 and R2 'according to FIG. 8. The series resistance R acts like an increase in resistance of Ri with low DIN sensitivity, the parallel resistance R like a decrease in resistance of Ri with high DIN sensitivity. As a result of the interaction of the three resistors Rj, R and R2 ', the curve Ri of the photoresistor results in the curve Rl corr-Fig. 11 shows the effect of the circuit according to FIG. 9, which is to be used for photoresistors with too low a characteristic curve slope. In this case, the additional resistors R, 'and R, "ensure that the characteristic2 ?, of the DIN number controller, changes over to the characteristic R, -k", -, which is adapted to the photoresist characteristic R, with too little steepness.

Claims (2)

Claims-1. Bridge circuit operated with direct or alternating voltage and having a photoresistor, which is preceded by an automatically controllable light attenuation device for controlling light measuring devices, in particular for a camera with automatic diaphragm. characterized in that for the input of exposure factors, in particular the film speed, essentially the bridge resistor R lying in series with the photoresistor R1, continuously or in steps, can be varied in such a way and proportionally adjusted to the values of the photoresistor R corresponding to the input values, in particular the film sensitivity, that the Resistance ratio u = R1IR2 = R "IR present in the bridge adjustment is set to a constant value such that the relay located in the diagonal circle of the bridge for actuating the automatic aperture control reaches its greatest sensitivity at the lowest electrically considered film sensitivity or the highest exposure factor even if the photoresistor values deviate by a factor of 3 or a third from the nominal value, e.g. as a result of the manufacturing process, is not exceeded for either more sensitive or less sensitive photoresistors. 2. Bridge circuit according to claim 1, characterized in that of the two other bridge resistors R, and R 4 of a resistor RY preferably independent of the deviation of the photoresistors from its target value such a constant value is obtained, that in the smallest value of the Film sensitivity and use of a photoresistor with average light sensitivity, the permissible value of the control tolerance of the automatic shutter is reached, but not exceeded, while the other resistor, preferably R41, can be changed or exchanged to compensate for the variance of the photoresistors. 3. Bridge circuit according to claim 2, characterized in that the bridge resistance to be addressed as constant within a production series, preferably R., can be changed for subsequent input of correction values within certain narrow limits, expediently by exchanging fixed resistors. 4. Bridge circuit according to claims 1 to 3, characterized in that the resistance ratio u = R, IR, for a photoresistor of average sensitivity to a value u > 1 or approximately to the value 1 - # L (R, min + R3) R. is set when R "ni, the smallest resistance value that the average photoresistor assumes, while RI, the unipolar bridge resistance connected to the photoresistor and R, the resistance in the diagonal branch of the bridge with the relay. 5. Bridge circuit according to the claims 1 to 4, characterized in that the bridge resistance R 3 and the resistance R, of the diagonal circle are chosen so that at the greatest resistance value Ri.ax assumed by the average photoresistance, there is a power adjustment between the bridge and the consumer with the resistance R, . e. that the resistance values R, and RO approximately the relation (R, 11j (1 + R. satisfying i) IRO # 1 + U. 6. bridge circuit according to claims 1 to 5, characterized in that in addition to the possibility of entering the film speed and exposure factors into the circuit via the bridge resistor R 2, a second input possibility by means of a light attenuating device is provided in front of the photoresistor. 7. Bridge circuit according to claims 1 to 6, characterized in that with only a few or in the borderline case a single electrical input value, the circuit is dimensioned so that the relationship between the value R, the average photoresistance and the other bridge resistances is: L2 < u = RIIR #, = R3IR, <3.2 and 1.5 < (R, + R3) IRO < 6. 8. A circuit according to claims 1 to 7, characterized in that in AC operation the current occurring in the diagonal branch of the bridge, optionally below Interposition of a zero-current amplifier after rectification is fed to a polarized control relay for the automatic shutter, a controlled rectifier or ring demodulator preferably being used for rectification. 9. Bridge circuit according to claims 1 to 8, characterized in that the DIN number controller R2 carries a sensitivity scale in which the distance between the graduation marks is proportional to the steepness of the photoresistors used. 10. Bridge circuit according to claims 1 to 8, characterized in that the resistance ratio for bridge balance in dependence on the position of the DIN-speed regulator R 2 is so changeable that different slopes of the photoresists can be compensated by preferably between the bridge abutment stand, and R4 a potentiometer is interposed whose slider, which is coupled to the DIN number controller, is connected to the relay in the diagonal branch of the bridge. 11. Bridge circuit according to claims 1 to 8, characterized in that a too large or too small a compensating slope of the photoresistor by simultaneously inserting a series and parallel resistance of photoresistor Ri or to DIN-speed regulator R2. Publications considered: German patent application L8381Xa / 57a (made known on January 22, 1953).