DE2328165B1 - Monolithically integrable circuit for exposure time monitoring and control of still cameras - Google Patents

Description

The invention is based on the object knew monolithic integrated circuit for exposure time monitoring and control of still cameras in such a way that the complex and complex mechanical switches can be simplified. The easy replacement of mechanical Switching functions of the switch S by means of corresponding electronic switching functions is, however, made more difficult in the present case that because of the extremely small Currents flowing through the photoresistor have no mechanical switching contact in the circuit this resistor can be replaced by a transistor, if not its Emitter is connected to one pole of the battery voltage. The resistance value of the Photo resistance can be up to 100 MOhm.

The given task of simplifying the mechanical switch S is achieved by the invention specified in claim 1. Advantageous embodiments and further developments of the invention are characterized in the subclaims.

An exemplary embodiment of the invention will now be described with reference to FIG the drawing described in more detail. The mechanical switch S according to FIG. 1 is replaced by the mechanical break contact S 'as a result of the measures according to the invention, which in turn is actuated by the release button K. Furthermore, there is now the resistance R2, the photoresistor R1 and the capacitor C in the given order between the live pole of the operating voltage source UB and the circuit zero point, in the embodiment according to FIG. 2 between the plus and minus poles of the Operating voltage source Uß.

The resistor R2 is the emitter-collector path of the pnp transistor T2 connected in parallel, with the emitter of this transistor at the positive pole of the operating voltage source Us lies, while the capacitor C is the emitter-collector path of the npn transistor T1 is connected in parallel, the emitter of which is at the circuit zero point. These two Transistors act as two electronic switches, being the transistor T2 in the Monitoring phase, i.e. when the normally closed contact S 'is closed, is blocked while the transistor T1 is conductive in the monitoring phase and thus the capacitor C shorts.

For purely electronic implementation without an RC element the delay to be used in the invention between switching the two electronic switch is the base-collector path of the pnp transistor T 2 the base-emitter path of the pnp transistor T3 connected in parallel, during the Base-emitter path of the npn transistor T 1 is the collector-emitter path of the npn transistor T4 is connected in parallel. Between the base of the npn transistor T 1 and the collector of the npn transistor T4 on the one hand and the base of the pnp transistor T3, on the other hand, is the resistor R 8 and between the base of the npn transistor T4 and the collector of the pnp transistor T3, the resistor R 9.

When the normally closed contact S 'is opened, the pnp transistor T2 receives over the base-emitter path of the npn transistor Tl and the resistor R8 base current, so that it switches through and thus short-circuits the resistor R 2. Only when the When the pnp transistor T2 saturates, the pnp transistor T3 becomes conductive and controls the npn transistor T4 through, so that thereby the npn transistor Tl is blocked and the charging of the capacitor C can take place via the photoresistor R1. Of the Base current for the transistors T2 and T3 flows in the now existing timing phase via the collector-emitter path of the npn transistor T4 and the resistor R 8.

It should be noted that compared to the dimensioning of the known circuit the voltage divider ratio R2 / R3 in the circuit according to the invention is different Must assume value, since the actual function of the resistors R2 and R3 in the Invention is reversed with respect to the known arrangement. Otherwise apply also for the circuit according to the invention essentially the sizing rules of known circuit.

Claims (6)

Claims: 1. Monolithically integrable circuit for exposure time monitoring and control of still cameras with at least one of a threshold switch controlled display for an exposure time limit value, whereby during the monitoring phase a photoresistor is in series with a resistor at the operating voltage and the opening time of an electromagnetically actuated one during the time formation phase Closure as a function of the charging that takes place via the photoresistor a capacitor lying on one side at the circuit zero point is controlled, the by means of a mechanical switch operated by the release button to the photoresistor is connected in series, d a -characterized in that a first electronic Switch (T 1) is provided via which the photoresistor is in its closed state (R 1) is at the circuit zero point during the monitoring phase that a second electronic switch (T2) is provided over which in its closed state the photoresistor (R 1) during the time generation phase at the voltage-carrying pole the operating voltage source (UB) and that a delay circuit (T3, T4) is provided so that when you press the release button (K) the first electronic Switch (T1) after the closing of the second electronic switch (T2) opens. 2. Circuit according to claim 1, characterized in that the mechanical Switch only from one with its one contact on the live pole the operating voltage source (UB) lying break contact (S ') exists. 3. A circuit according to claim 1, characterized in that the temporal Delay between closing the first DL. (Tl) and opening the second electronic Switch (T2) without RC elements by utilizing the threshold voltage and the saturation voltage of transistors (T3, T4) is realized. 4. Circuit according to claim 1 or 2, characterized in that the first electronic switch (T1) has a resistor in the closed state (R 2) and the: second electronic switch (T2) in the closed state one Capacitor (c) shorts. 5. Circuit according to one of claims 2 to 4, with a positive live voltage Pole of the operating voltage source, characterized in that the first electronic Switch consists of an npn transistor (T1), the emitter of which is at the circuit neutral point, its collector at the junction of photoresistor and capacitor (C) and whose base is at the output of an electronic delay circuit and that the second electronic switch consists of an npn transistor (T1) whose Emitter at the positive pole of the operating voltage source (UB), its collector at the connection point of photoresistor (R 1) and resistor (R2) and its base at the other contact of the normally closed contact (S '). 6. Circuit according to claim 5, characterized in that the delay circuit consists of a second pnp transistor (T3) and a second npn transistor (T4), which the former with its base-emitter path is the base-collector path of the first pnp transistor (T2) is connected in parallel and which latter with his Collector-emitter path of the base-emitter path of the first npn transistor (T1) is connected in parallel, and that between the base of the second pnp transistor and a further resistor between the base of the second npn transistor (R 8, R 9) is arranged. In the magazine "Radio-mentor-electronic", May 1972, p. 226 bis 229, is a monolithic integrated circuit arrangement for exposure time monitoring and control of still cameras is described in detail. In the form of a block diagram, FIG. 1 the essential Functional parts of this integrated circuit shown. This circuit includes the threshold switch K1 for the stand display, d. H. to indicate whether a tripod is being used should be because the existing brightness and aperture setting only one shutter speed allows blurring of the image. It also contains the well-known Switching the threshold switch K2 for exposure time control, d. H. for shutter speed formation. The same photoresistor K1 is used for both functions, see above that the very complex mechanical changeover switch S is required, which has a changeover contact and a further break contact connected to the make contact of the changeover contact must have, whereby the contact is established when the release button K is pressed through chronological order must take place. The switch S switches in its drawn rest position (tripod display) the photoresistor to the resistor R 2 of the resistors R 2 and R 3 Voltage divider in parallel, the tap of which with the designated 1 input of the Threshold switch K1 is connected. The other input 2 of this threshold switch is connected to a voltage divider consisting of resistors R 4 and R 5 obtained reference voltage connected. The threshold switch K1 controls the Indicator lamp L such that it lights up when the resistance value of the resistor R1 exceeds a limit value. Furthermore, the switch S closes in its rest position the short, the exposure time co-determining capacitor C, which is at the entrance of the second threshold switch K2 is connected, at the output of which the shutter actuating electromagnet M is located. By means of the consisting of the resistors R 6, R 7 Voltage divider whose tap on the other input 2 of the threshold switch K2 a voltage threshold is also generated. When you press the switch S must first the photoresistor from Input of threshold switch K1 to the input of threshold switch K2 switched and then the short circuit of the capacitor C can be canceled.