DE2117129C3 - Circuit for controlling the exposure time in a single-lens reflex camera - Google Patents

Description

The invention relates to a circuit for controlling the exposure time in a TTL reflex camera with a light measuring circuit for generating a logarithm of the object brightness proportional output voltage, one connected to it, consisting of a changeover switch and a storage capacitor existing storage circuit for storing this logarithmic output voltage, a time circuit for generating a logarithm proportional to the time that has elapsed since the start of exposure Output voltage and a comparison circuit, the two inputs of which the output voltage voltages of the light measuring circuit and the time circuit to generate one of the difference between the two Output voltages dependent control signal for the closing process of the shutter are fed.

With single-lens reflex cameras it is impossible to take a light measurement during exposure; therefore the light reading is before the Exposure stored in the storage capacitor, and to use a large range of object brightness to be able to detect the storage capacitor, which is on the light-receiving surface of the photoresistor incident illuminance previously logarithmized.

In order to receive a control signal to terminate the exposure after the exposure has started, a comparison must be made between the light reading and the time elapsed since the start of exposure. In known circuits, therefore, when the object brightness is expressed as a logarithmic voltage is stored, a process opposite to the logarithmizing process, i.e. a delogarithmization performed and the resulting voltage with the output voltage of a timing element z. B. in one Differential amplifier compared.

In this fill, however, the quantitative change in the logarithmic voltage with a change of 1 EV of the exposure value is limited by the characteristics of the expansion element, and the result of the quantitative change in voltage per 1 EV in the course of the logarithmization is very small, which can easily lead to errors that in the The course of the delogarithmization greatly reduce the accuracy.

To eliminate this disadvantage, proposed circuits (DT-PS 17 72 106 and DT-OS 20 53 001) during exposure is the logarithm of the time that has elapsed since the start of exposure proportional voltage generated by the time circuit and this with the logarithm of the object brightness proportional output voltage of the light measuring circuit compared to the control signal! to obtain. This allows the counter-logarithmic conversion be waived.

According to DT-OS 20 53 001, a timing capacitor and diodes are connected in series to the line circle Voltage source. The voltage to control the charging current of the capacitor is between the pressed on both ends of the diodes. In this case the voltage is equal to the voltage of the power source, when charging starts. Here is a problem. Namely, the voltage of the power source is generally rated at at least several volts, while the voltage permissible for a diode is approximately 0.7 V. This problem is already shown in DT-OS 20 53 001. According to the disclosure document a sufficient number of diodes is connected in series to avoid that the individual diodes will be destroyed by excessive voltage. However, it is inevitable to use it a sufficient number of diodes higher and not beneficial in the actual manufacture of the Circuit.

But there is still another problem with the circuit according to this laid-open specification. E; has already been mentioned that the power source voltage between both ends of the series diodes is pressed on by the timing capacitor In contrast, a diode requires an optimal « Tension at both ends if it is to produce a «desired performance. That has zi mean that the voltage of the power source corresponds to the number of diodes in series must be measured, whereby the free choice of voltage of the power source is no longer possible. Aucl this circumstance is inconvenient in manufacturing the circuit.

The object of the present invention is to improve the circuit according to DT-OS 20 53 001

in their place to bring a circuit that is cheaper ; is to be notified. The new circuit should take into account the accuracy of the exposure control Improve the brightness of the object without any special effort.

The solution to this problem is that the timing circuit contains a transistor, the base bias of which is determined by another element and that a timing capacitor in the emitter circuit of the transistor and a switch which can be actuated at the start of exposure is provided, when it is actuated the Charging of the capacitor by the emitter current of the transistor begins. In this circuit, the Charging voltage of the capacitor proportional to the logarithm of the elapsed since the beginning of the exposure Time variable and an output voltage proportional to the logarithm of elapsed time of the integration circuit and comparable to the charging voltage of a storage circuit capacitor, which stores the output voltage of the light measuring circuit. So there will be a tension that changes proportionally with the logarithm of time, compared to a voltage that is the logarithm is proportional to the brightness of the object.

According to the invention, the path of the current for charging the Zeasteuerkondensers and the two points between which the voltage for the control of the Charging current is applied, separated from each other. (Here is the path of the current according to the DT-OS 20 53 001 to take into account, which runs between the two ends of the diodes in series, between to which the control voltage is also applied.) In other words, according to the present invention the path of the current runs between the emitter and the collector of said transistor, whereas the control voltage is applied between the emitter and the base of this transistor. With this Improvement, the control voltage can be kept independent of the voltage of the power source that is on is imprinted on the path of the stream. As a result, only a single element, i.e. H. a transistor takes the place of a sufficient number of diodes, whereby it is achieved that an integer number of Elements is saved and that, in addition, the voltage of the power source can be freely selected as desired can be. Furthermore, several embodiments of your choice are possible because the control voltage on the Base of the transistor can be adjusted freely. For example, there are also temperature compensation and Compensation for fluctuations in the voltage of the power source is possible when you turn the voltage on according to the base.

In one embodiment of the invention, the timing circuit consists of a transistor with a predetermined base potential, in whose emitter circuit a timing capacitor and in whose collector circuit an output capacitor is connected. These circuits are connected to the power source via a release switch which is closed when the exposure begins, and the charging voltage of the output capacitor connected to the collector of the transistor is applied to the input of the comparison circuit iv . This means that the voltage of the timing capacitor, which changes in relation to the logarithm of time, is converted into the voltage of an output capacitor, which also changes in relation to time, but with a different coefficient than that of the timing capacitor, and this voltage becomes with the voltage from the light measuring circuit, which is stored in the storage circuit capacitor, compared. In general, this conversion of the capacitor voltage is dispensed with and the voltage of the timing control capacitor is compared directly with that of the storage circuit capacitor. In this case, one must be selected for the time control capacitor with a capacity with which a suitable one

ίο coefficients for the change in voltage that receives is to be compared with the voltage stored in the storage circuit capacitor. However, the Selection of the capacitance of the timing capacitor in a range within which the transistor can work reliably and the voltage changes maintain their accuracy.

But if, as in the embodiment of the invention, the voltage change of the timing capacitor once converted into the voltage change of the output capacitor to match the Voltage in the storage circuit capacitor can be compared to the capacitance of the output capacitor be selected so that a suitable coefficient for comparison with the voltage in the Storage circuit capacitor is present. So you have a free hand in choosing the timing capacitor, without the normal operability of the transistor or a loss in the accuracy of the voltage change would be feared.

ίο It is also advantageous if one adopts the values of the Film speed and aperture corresponding voltage value from a potentiometer in the Aperture setting circuit detachable and the output capacitor of the timing circuit before the start of charging is pushable. When comparing the voltage of the output capacitor with the voltage of the storage circuit capacitor, the voltage of the potentiometer in the B'enden circle on the output capacitor given, the pre-imposed voltage not affecting the normal operability of the transistor.

An embodiment of the invention is described in more detail below with reference to the drawing. It indicates

1 shows an exposure time control circuit for measuring the exposure time via the optical system single-lens reflex camera,

Fig. 2 is an enlargement of the main part of the above circuit;

F i g. 3 is a graph showing the relationship between the logarithm of time and the charging voltage reproduces.

In the circuit diagram of the exposure time control circuit According to FIG. 1, the essential functional circuits that make it up are through dash-dotted borders marked.

(H) is the light measuring circuit, the output voltage of which is stored in the storage circuit ^ /// ^; (vi) is the time cycle, in the aperture setting circuit (vj

(, 0 the information about the film speed is also set; it is connected to the actuation circuit (vii), which is also connected to the time circuit (vij , the output voltage of which is proportional to the logarithmic value since the start of exposure

(, s elapsed time is.

The output voltages of the Beiatigungisirumkreises (vii) and the Speicherstronikreises (Hi) are compared in a comparison circuit (iv) , and at

The exposure time control circuit (viii) is reversed in order to complete the exposure. The information from the light measuring circuit (H) and the film speed and aperture setting circuit (v) are fed to the measuring or display circuit (ix) and the shutter speed is displayed. The output voltage of the light measuring circuit (H ) stored in the storage circuit (Hi) is proportional to the logarithm of the object brightness, and the output voltage of the time circuit (vi) is proportional to the logarithm of the time that has elapsed since the start of exposure. In this way, a wider range of object brightness can be detected with great accuracy, and an inverse logarithmic conversion of the light measurement voltage for the purpose of comparison with the time measurement voltage is not necessary.

The connection point between the photoresistor Ro of the light measuring circuit (H) and the fixed resistor R 1 connected in series with this is connected to the contact a of the changeover switch 53 of the storage circuit (Hi). The photoresistor / found the fixed resistor R 1 are connected to the collector circuit of the transistor 773 together with the resistor R 2 connected in parallel therewith and the variable resistor R 3 connected in series.

The emitter of the transistor Tr3 is connected to the positive pole of the power source E via the resistor R 5 to form a logarithmic circuit.

The transistor 7> 4, which has the same base potential as the transistor Tr 3, is a transistor with the same characteristics and the same current passage. The variable resistor A4 connected to the collector of said transistor Tr4 forms an adjusting circuit (v) for changing the film speed and the aperture.

The timing capacitor is connected to the emitter and collector of the transistor TrI with a fixed base potential by connecting the base to the collector of the compensation transistor TrX, between the base and collector of which the resistor R 19 is arranged and to the base of which the resistor R 10 is connected as a series resistor Cl or the output capacitor C2 connected. A trigger switch 54 is provided between the timing capacitor C1 and the positive side of the power source E , which is usually open and is closed at the same time as the shutter starts to open. The two discharge switches 51 and 52 are provided in parallel with the timing capacitor CI and the output capacitor C2. The charging voltage of the output capacitor C2 in the time circuit (vi), which is connected to the actuation circuit (vii) , which is composed of the variable resistor R 4 in series with the discharge switch 52, the resistor R 4 also the circuit fv ^ for setting the Film sensitivity and aperture belongs to the base of the transistor TrS within the differential amplifier serving as a comparison circuit (iv). The contact b of the changeover switch 53 in the storage circuit (iii) is connected to the base of the transistor 7-6 as the second input of the differential amplifier.

The emitters of the two transistors 7-5, 7r6 are connected to the collector of the transistor Tr 13, while the resistor R 12 is connected to the emitter of the transistor Tr 13. The base of the transistor Tr 13 is connected to the connection point between the resistor R 13 and the diode D 2 for temperature compensation. A resistor R 11 is switched on in front of the collector of the transistor Tr 5. These transistors Tr 5 7> 6 and Tr 13 form the comparison circuit (iv) with the resistors R \ i and R 12. In the exposure time control circuit (viii) connects

ίο the main switch 55, the coil Aides electromagnet with the power source E In addition, the transistors Tr 7, Tr 8, Tr 9 and Tr 10 form a Schmitt trigger, and the collector of the transistor 7 closes at the base of the transistor Tr 7 as the input side 5 of the comparison circuit (iv) . The electromagnetic coil M is connected to the output side which is the collector of the transistor Tr 10. The moment the main switch 55 is closed, the transistors Tr 9 and Tr ! 0 are conductive and the electromagnetic coil is excited. At a moment in which the transistor TrS of the differential amplifier is reversed, the transistors Tr 9 and Tr 10 are blocked and the electromagnetic coil M demagnetized, whereby the closing process of the

Closure begins. The MeQ or display circuit (ix) is equipped with two amplifier transistors TrII, Tr 12 in order to obtain a delay of the potential at contact a of said switch S3 and the voltage of the output capacitor C2.

Furthermore, a double- coil ammeter A is provided, the coils of which are wound in opposite directions to the difference between the electrical potential at contact a and the voltage of the output capacitor C2, namely the exposure line

to display.

Fig.2 shows a partial view of Fig. 1 and the essential part of the present invention. At the beginning of the shutter release, the two Switch 51,52 open, and when the trigger switch 54 is closed at the same time at the beginning of the shutter opening, the charging of the begins Timing capacitor Cl and the output capacitor C2.

How do the charging voltages V _{1 and V 2 change?}

of these two capacitors C1, C2 in the course of time from the point in time at which the release switch 54 is closed, that is to say the shutter opening begins? If the voltage between the base and the emitter of the transistor Tr 1 has the value V _m : \ ,

so this becomes the base potential of the transistor Tr2. The resistance value of the resistor R 19 is used for voltage compensation and is so small that it can be neglected.

So it arises when the charging voltage of the

Time control capacitor CI has the value V, and the voltage Vnri between the base and the emitter of the transistor Tr 2 is:

m: _x

and for the collector current / of the transistor Tr 2 results himself:

^v m-: ₂

'ι' Ί ·

where Vo and v are the constants of proportionality of Tr 2 .

When the capacity of the condenser (I. has the value G and the charging voltage is Vi. so follows

If you put this formula in the formula 11). m < Γοΐμΐ:

i "lou / ί i" i (,.

/ il / (2)

To obtain the relation / wipe / and ι , equation (2) is differentiated according to the line /.

C ₁ '■ "

C ₁ '"

d /

di . 1
d / 'Γ,

Provided that the characteristics of TrI and T'r2 are the same and the current flowing through TrI is / <>, the collector current of transistor Tr2 also becomes / u /., In an instant (7 = 0) when the trigger switch. * > 4 is closed, so that for the value K of the formula (3)

results.

Inserted into the equation <?>) It follows:

C, r "

1 1

(4)

C, i '"/ η

I I

Γ Γ t

C ₁ I, JaI, j _t

• \ f ·

/ "

'' "■■ '

low ('(

(c, r "'J'" ^μ / ":

(K)

<■ ,. ·, Ca-, c, "

(I ₁₁ I \ C ₁ i \

15)

Vc, i,

■ I

As can be seen from equation (b), the l.adesp, guideline V ·; in the output capacitor C'2 increases proportionally /.um l.ogarilhmus of the / eil from the time on, /.ίι that of the release switch .S'4 is closed.

Γ i g. The previous year l.adespannung J shows the relation / wipe the output capacitor f'2 and the time from closing the Auslöseschallcrs .S'4.

If the illusion sensitivity and the line value are changed, the resistance value of the variable resistor R 4 and also the voltage at the output capacitor C'2 in the initial signal change. so that. As shown in FIG. 3, the time characteristics of the charging voltage are shifted in parallel when the line sensitivity and the aperture value change.

By changing the capacity ratio. ·. ' the

Capacitors il. (2 it is possible to obtain any desired charging characteristic of the capacitor C'2.

The electrical potential at point; f is given by the logarithm of the illuminance and changes by VIi when changed by one degree of Illuminance of the light-receiving roof (I HV).

By changing the constants of the time circuit (e.g. the Kiipa / ity ratio of the capacitors (1, C2 or the base voltage of the transistor Tr2), the tendency of the charging characteristic of the capacitor C2 (cf.Fig. I) can be changed as desired , and the quantitative change per i IiV in the course of the logarithm can be carried out with the highest accuracy.

In the event that a delogarithmization by per se known means is carried out, the quantitati ve change in the process of l.ogarithmization is he a change of 1 EiV at the output of the expansion element due to the characteristics of the logarithmic mixer The expansion element is limited and the quantitative change in the logarithmic course is small, as a result of which the accuracy deteriorates.

If, for example, a transistor is used in the course of the delogation, as shown has, the quantitative change per I EV at the input de Delogarithmizing column to 18 mV at the base: limited, by the characteristics de Base voltage and the collector current of the transistor.

But if a circuit according to the present invention is used, the quantitative * Change per 1 EV in the course of the l.ogarithmicruni can be changed arbitrarily. Provided that the film speed can be reduced by 11 degrees (ASA b-ASA 6400), the image speed by de Factor S (F 1,4 -F 16) and the exposure time I has different settings (Viooo-I see) is as the available voltage amounts to 3 V, the quantitative change is pro! EV at de logarithmization up to 80 mV.

The quantitative change per 1 EV becomes greater when the invention is carried out, and dcmcn Accordingly, exposure line control of high accuracy becomes possible.

For this purpose 3 sheets / instructions

709 642/151

il u, _y : &

Claims (3)

Patent claims: 1. Circuit for controlling the exposure time in a single lens reflex camera with a light measuring circuit for generating an output voltage proportional to the logarithm of the object brightness, a storage circuit connected to it, consisting of a switch and a storage capacitor for storing this logarithmic output voltage, a time circuit for generating a logarithm the output voltage proportional to the time elapsed since the start of exposure and a comparison circuit, the two inputs of which are supplied with the output voltages of the light measuring circuit and the timing circuit for generating a control signal for the closing process of the shutter which is dependent on the difference between the two output voltages, characterized in that the timing circuit includes a transistor (Tr 2), the base voltage of which is determined by an element (Tr i) , and that in the emitter circuit of the transistor (Tr2) a timing capacitor (Ci) and one with the Be start of lighting actuable switch (Si; S 4) are provided, upon actuation of which the charging of the capacitor (CX ) begins by the emitter current of the transistor (Tr2). 2. A circuit according to claim 1, characterized in that in the emitter circuit of the transistor (Tr 2) a timing capacitor (Ci) and in its collector circuit an output capacitor (C2) are turned on and the charging voltage of the output capacitor (C 2) located in the collector circuit at the Input of the comparison circuit (iv) is present. 3. A circuit according to claim 2, characterized in that a voltage value corresponding to the values of the film sensitivity and aperture can be removed from a potentiometer (R 4) in the aperture setting circuit (v) and the output capacitor (C2) of the timing circuit can be pressed before the start of charging. 45