DE2211493B2 - Discriminator circuit for illumination control in photography - gives indication of stepwise varying parameter using two indicator lamps with feedback amplifier-transistor circuit - Google Patents

Abstract

The discriminator circuit is for e.g illimination control in photographic application, where brightness is converted into an electrical signal used to determine the correct exposure time. The circuit is used with a transducer to convert a stepwise varying physical parameter into a signal indicated solely by the illumination state of two lamps. The voltage at the input of an amplifier (A) drives one of two transistors (T1,T2) so long as the potential at the junction (a) of the transducer impedance (R1) and a series resistor (R2) exceeds a threshold level. Each transistor drives a lamp (L1,L2). The directly driven transistor (T1) also drives the amplifier via a resistor (Rf). The other transistor (T2) output drives the amplifier input via a capacitor (c). This enables selective operation of the indicator lamps for different transducer voltage levels.

Description

65

The invention relates to a discriminator circuit with a transducer for converting one of the measuring transducer recorded, they Ί gradually changing physical quantity into an electrical quantity one output terminal of the transducer is connected to the input of an amplifier having a threshold value, in which the output of the Amplifier alternately two switching transistors can be controlled, each with an output signal one of the two switching transistors a display device can be actuated, and between the Output of the first hold transistor and the input of the amplifier a resistor and between the Output of the second switching transistor and the input of the amplifier a capacitor switched * are.

Discriminator circuits of this type are suitable for example for photographic exposure controls, the light intensity or the brightness of an object is converted into an electrical quantity and this is used to determine the correct exposure time can be used depending on the brightness of the object.

There are already a number of discriminator circuits that are used to determine the exposure time let use. For example, with the arrangement according to JP-GM 24858/1968, the brightness of the object to be recorded is divided into four areas divided by an indicator light by four States are displayed, namely continuous lighting, flashing, brief lighting and non-lighting.

With such an arrangement, however, a number of shortcomings are noted, because the The displayed state must be distinguished from the others, so that the corresponding exposure time can be estimated. If a camera is equipped with such a discriminator circuit, then Disturbances and impairments of the images made with it cannot be avoided. In addition, the Heat capacity of the indicator lamp is a factor that determines the blinking cycle, so that a strict Quality control in the manufacture of the discriminator circuit for use in light meters is required and the possibilities in the Design of the arrangement are restricted

The object of the invention is therefore to provide a discriminator circuit with a transducer for converting one detected by the transducer to indicate gradually changing physical quantity in an electrical quantity, with the help of which various predetermined values of the physical quantity can be easily indicated by the light status of two indicator lamps.

According to the invention, this object is achieved in that the signal applied to the input of the amplifier electrical variable applied to either the first or the second switching transistor as soon as the The voltage drop across the series resistors exceeds a threshold value and that the output of the first switching transistor via the resistor and the output of the second switching transistor via the Capacitor fed back to the input of the amplifier to selectively operate the first and second indicators.

In a further development of the discriminations according to the invention gate circuit, the two switching transistors are connected in cascade and serve as display devices Indicator lamps and one indicator lamp each is connected to a collector of the switching transistors.

According to further features of the invention The transmitter has a discriminator circuit

photoelectric element or thermistor, a variable resistor and another resistor on, the photoelectric element or the thermistor is connected in series with the variable resistor and the further resistance is between the connection point between the photoelectric element or the thermistor and the variable resistor and the output of the transmitter or the input of the amplifier provided.

The discriminator circuit according to the invention is suitable is a reliable way of converting a physical quantity into an electrical quantity, whereby it is, for example, the gradually changing physical quantities detected by the measuring transducer to the light intensity or the brightness of an object, the temperature of an object or the like. can act.

The invention is explained below with reference to the description of an exemplary embodiment and below With reference to the drawing explained in more detail, where! Edigüch, for example, of a discriminator circuit to determine the correct exposure time is being discussed without the discriminator circuit on this application is limited The drawing shows in

Fig. 1 is a circuit diagram of the discriminator circuit according to the invention,

F i g. 2a and 2b equivalent circuit diagrams to explain the

Operation of the discriminator circuit according to FIG. 1, FIG. 3 are schematic representations for explanation

the signal curves in the discriminator circuit according to FIG. 1, and in

4 shows a graphic representation for explanation the operating characteristics of the discriminator circuit according to FIG. 1.

In the case of the discriminator circuit according to FIG. 1, a photoelectric element R 1 is used to determine the exposure time, the resistance value of which changes depending on changes in the brightness of the object to be recorded, while a variable resistor R 2 is used to set the resistance value according to the sensitivity of the film used. For the sake of simplicity, it is assumed that the variable resistor R 2 has a fixed value

There is also a resistor A3 Kii ». A fixed value and an amplifier A with a high input impedance are provided, the latter emitting an output signal when the input signal exceeds a threshold value Vp. A first switching transistor Jr TI has its base connected to the output of the amplifier A and its collector connected to the base of the second switching transistor T2.

The discriminator circuit also contains a voltage source E, an indicator lamp Ll connected between the collector of the first switching transistor Tl and the positive pole of the voltage source £, a second indicator lamp L 2 connected between the collector of the second switching transistor T2 and the voltage source E, a capacitor C between the Collector of the second switching transistor Tl and the input of the amplifier A for positive feedback of the collector potential of the second switching transistor Γ2 to the input b and a resistor Rf between the collector of the first switching transistor T 1 or the base of the second switching transistor 7 "2 and the input b of the Ve amplifier A for feedback of the collector potential of the first switching transistor T \ to the input B. For the sake of simplicity it is assumed that the photoelectric element R 1 and the resistor Λ 2 each have a smaller resistance than the resistor A3 and that the variable resistor R 2 has a fixed value

In such a discriminator circuit shown in FIG. 1, the intensity of the photoelectric flows Element J? 1 falling light corresponding

ίο Current in the circuit formed by the voltage source E, the photoelectric element R 1, the variable resistor R 2 and, in turn, the voltage source E. This current causes a voltage drop Va at point a, which can be described by the following expression :

Va = R2- 1 / (Ri + R2).

The voltage drop Va changes as a function of changes in the intensity of the light falling on the photoelectric element R 1 * Due to the changes in the voltage drop Va at point a, the following states can occur with the two indicator lamps L1 and L 2 :

1. The indicator lamp LX goes out and the indicator lamp L 2 lights up;

2. The indicator lamps Ll and L 2 switch on and off alternately;

3. The indicator lamp Ll lights up and the Indicator lamp L 2 goes out

If the voltage drop Va increases in steps, the discriminator circuit operates as follows: If the voltage drop Va is low, the potential Vb at the input b of the amplifier A is correspondingly low. In order to keep the potential Vb at the input b of the amplifier A below the threshold value Vp of the amplifier A , the latter must not deliver an output signal. Under these conditions, the first switching transistor Tl, whose base is at the output of the Ve amplifier A , blocks, while the second switching transistor T2, whose base is connected to the collector of the first switching transistor Tl, is turned on is connected to the collector of the second switching transistor T2.

This circuit state corresponds to the equivalent circuit diagram according to FIG. 2a, in which the capacitor C is connected between the input b of the amplifier A and ground and the resistor Rf between the input b and the voltage source £. Assuming that the amplifier A with a high input impedance has no influence on the discriminator circuit, the potential Vb at the input b of the amplifier A is determined in this discriminator circuit according to the following equation:

Vb = Va + (E- Va) RZI (RZ + Rf)

The area in which only the indicator lamp L 2 lights up, the potential Va at the junction point a between the variable resistor R 2 and the photoelectric element R 1 having a value at which the potential V £> at the input of the amplifier A is below the threshold value In of amplifier A drops is determined by the following equation:

Vp> Vh = Va + (F- Va) RM (RZ + Rf).

22 Π 493

So that applies

Va <Vp- (E- Vp) RyRf

(2)

If the potential Va at point a increases, that is, if the intensity of the light falling on the photoelectric element R 1 increases, the potential Vb at the input b increases in accordance with the potential Va at point a and finally exceeds the threshold value Vp of the amplifier A. As a result, a voltage that almost corresponds to the supply voltage of the voltage source E appears at the output of the amplifier A. which receives the potential Vb as an input signal.

At the same time, the output signal of the first switching transistor Ti occurs at time / 1 according to FIG. 3b

._ "._ Va-Rf . Λ-. "_ Va-Rf \" _ ..

Rf + R3

Rf

τ = C- Rf- R3 (Rj + R3).

on; the base of this switching transistor Ti is connected to the output of the amplifier A. In addition, the output of the second switching transistor 7 "2 switches off at time 12 according to FIG. 3c. Under these conditions, the capacitor C is connected between the input b and the voltage source and the resistor Rf is connected between the input ft and ground, as can be seen from the equivalent circuit diagram can be seen in FIG. 2b.

As a result, input b receives at time rt according to FIG. 3a instantaneously through the capacitor Γ a potential (E + Vp). and this potential gradually decreases during the time between the two points in time / 1 and 12. as can be seen from FIG. 3a can be seen. The potential drop at input b can be described ¹ 'by the following equation:

If the potential Vb at the input b decreases during the period ti'-ti (see FIG. 1 fig. 3a) and becomes equal to the potential of the threshold value Vp , the output signal of the amplifier A quickly falls to zero. As a result, the first switching transistor T \ blocks at time t2 (cf. FIG. 3b) and the second switching transistor 72 switches through at time / 2 (cf. FIG. 3c). Under these conditions, the capacitor C and the resistor Rl 'are in the one shown in FIG. 2 shown equivalent circuit. The input b therefore immediately reaches the potential - (E-Vp) via the capacitor C at the point in time f2 (cf. $ ■ fg. 3a). The potential Vb at input b then increases during the period 12 ' - f 2 (cf.Fig.3a) according to the following equation:

Γ = - ■

R3 + "Rf

CJRf-R3 R3 + RJ

- [E-Vp +

R3 + Rf

When the potential Vb at the entrance b of the amplifier A during the time interval 1 2 '- (.. Cf. Figure 3a) ί 3 increases according to the equation (4) and reaches the threshold value Vp, the amplifier A in the same way, operated as described above. As a result, the first switching transistor Ti turns on and the second switching transistor T2 blocks. As a result, a flip-flop switching behavior occurs • exp - (/ - t2 ') τ

in the circuit, so that the indicator lamp L i connected to the output of the first switching transistor Ti and the indicator lamp L 2 connected to the output of the second switching transistor T2 light up alternately. The cycle or the period of this flip-flop switching function can be determined by the following equation:

T = τ

E + Vp -

In-

Va-Rf Rf + R3

E-Vp

Vp-

Va Rf Rf + R3

+ In

ER3 + Va Rf Rf + Ri

E Rl + Va Rf Rf + R3

T = C-Rf- R3 / (R3 + Rf) .

From equations (3) and (4) it can be seen that the potential Va at point a, at which the flip-flop switching function for alternately acting on the indicator lamps Li and L 2 occurs, lies in the range determined by the following expression :

Vp - (E- Vp) R3 / Rf < Va <Vp (I + R3IRI)

(6)

ω The expression Vp- (E- Vp) R 3 / Ef < Va thus represents the lower limit value and the expression Va SVp (1 + R 3 / Rf) represents the upper limit value of the discriminator circuit for initiating the flip-flop switching function.

es When the potential Va at point a is high, that is, when the intensity of the light incident on the photoelectric element R 1 is large, the discriminator circuit operates as follows: When the potential Va am

Point a increases, the potential Vb at input b also increases.

If the potential Vb exceeds the threshold value Vp of the amplifier A , the potential at the output of the amplifier A is almost equal to the voltage of the voltage source E, so that the first switching transistor Ti turns on and the second switching transistor 72 blocks, whereupon the indicator lamp L 1 lights up. At this moment the equivalent circuit diagram according to FIG. 2a with the capacitor C and the resistor Rf changes to the state according to FIG. 2b about.

Under this condition, the potential at the input b is reduced by the capacitor C , but remains above the threshold value Vp because the potential Va at point a is high enough. The amplifier A therefore continues to provide such an output signal for the first switching transistor 71 that the latter remains switched on, while the switching transistor 72 continues to block and the indicator lamp L 1 continues to light. The potential Va at point a . At which only the indicator lamp L I is lit. State is maintained by the following Describe equation:

Vb = Va- RfZ (R 3 + Rf) ' if, however, Vb> Vp. then applies

Vp <Va- RfZ (R 3 + Rf) it follows in Va> Kp (I + R31 Rf) (7)

This means that it is possible to determine the correct exposure time by a procedure in which Vp (l \ - R3 / Rf) is equal to the potential Va am

π point a corresponding to the upper limit of the desired exposure time and Vp- (E- Vp) /? 3 / Λ / equal to the potential Va at point a corresponding to the lower limit of the desired exposure time.

: i) The procedure described above is in the summarized in the table below.

Result of the
decision Potential at point α lamp
L \ lamp
Ll Underexposure O <Vo <Vp- (E- Vp) R 3 / Rf the end A right one
exposure Vp- (E- Vp) R 3, Rf <Va i Vp
{\ + R3 / Rf) On off From a Overexposure Vp (\ + R3 / Rf) <Va <E A the end

F i g. 4 shows the range in which the flip-flop switching function occurs in the discriminator circuit, the curve labeled Vp (I + R 3IRf) indicating the upper limit value of the desired range when the resistance value Rf changes, and the curve labeled Vp- (E- Vp ^ R 31 Rf represents the lower limit value of the desired range when the resistance value Rf changes. These two curves thus limit the range of the desired value, i.e. the setpoint. As the value of the resistance Rf 'increases, this range becomes narrower.

In the embodiment described above, the collector of the first switching transistor 71 is connected to the input ft of the amplifier A via a resistor Rf and the collector of the second switching transistor Tl is connected to the input b of the amplifier A via a capacitor C. Of course, the invention is not restricted to such an embodiment; rather, other interconnections can also be used, although care should be taken that the phase relationship is the same as in the embodiment described.

When in the above embodiment

form a photoelectric element R 1 is used to determine the exposure, this element can also be replaced by another, for example, the transmitter can instead have a thermistor for measuring the temperature, the thermistor then converting a physical variable for determining the exposure time into a converts electrical quantity.

With the discriminator circuit described above, various physical quantities can be used without further can be determined by the lighting status of two indicator lamps, one being a simple one The desired measuring range can be set. The on / off cycle of the indicator lamps can also be set without further ado. Are z. B. Indicator lights with different colors arranged so that the Colors mix with one another when the indicator lamps light up, so you can use the Flip-flop switching function to achieve a variety of bright hues. In this case, the determination made with the discriminator circuit is not affected by the characteristics of the indicator lights

For this purpose 2 sheets of drawings

Claims (2)

30 claims: 1. Discrirainator circuit with a) a transducer for converting a detected by the transducer, step by step changing physical quantity into an electrical quantity in which b) an output terminal of the transducer is connected to the input of an amplifier having a threshold value, in which c but two switching transistors are) the output of the amplifier alternately driven, wherein in each case by an output signal of one of the two switching transistors, a Anzeigeeinrich- ^{| D} tung is operable, and wherein d) between the output of the first switching transistor and the input of the amplifier Resistor and between the output of the zwfcjtin switching transistor and the input of the Amplifier are connected to a capacitor, characterized by the contamination of the following features: e) the electrical quantity present at the input (b) of the amplifier (A) acts on either the first (Tl) or the second switching transistor (T2) as soon as the voltage drop (Va) across the series resistors (Ri, R 2) exceeds a threshold value (Vfcj; f) the output of the first switching transistor (Ti) is fed back via the resistor ^J , Rf) and the output of the second switching transistor (T2 ) is fed back to the input (b) of the amplifier (A) via the capacitor (C), to selectively operate the first and second display means (L 1, L 2). 2. Discriminator circuit according to claim 1, characterized in that a) the two switching transistors (Ti, T2) are connected in cascade; b) display lamps (L i, L 2) serve as display devices; c) in each case one indicator lamp (Li, L2) is connected to a collector of the switching transistors (Ti, 72). Discriminator circuit according to Claim 1 or 2, characterized in that the measuring transducer has such a photoelectric element (R 1) or a thermistor (Ri), a variable resistor (R 2) and a resistor (R 3) that the photoelectric element (R 1) or the thermistor (R 1) are connected in series with the variable resistor (R 2) and that the resistor (R 3) between the connection point (a) between the photoelectric element (R 1) or the thermistor (R 1 ) and the variable resistor (R 2) and the output (b) of the transducer or the input of the amplifier ^ is provided.