SU857912A1 - Automatic photographic shutter - Google Patents

Description

(54) AUTOMATIC PHOTO SHOT

Claims (1)

The invention relates to photographic equipment and can be used to automatically set shutter speeds in cameras and photo relays for printing. An automatic photo gate containing a power source, a photoresistor, a group of transistors and a threshold element with an electromagnet at the output and a capacitor and a sync contact at input 1 is known. The disadvantage of the photo gate is the error in the processing of the exposure time due to the nonlinearity of the photoresistor. The closest to the inventive invention is an automatic photopatch containing a power source, a photoresistor connected afterwards with a master clock capacitor in parallel with which a sync contact is connected and two transistors connected to the actuator f2 through a threshold element} The disadvantage of this device is low accuracy due to the linearity of the photoresistor's light characteristic, the sensitivity of which decreases with increasing illumination. As a result, the error of the automatic photo shutter on the edges of the working range of illumination reaches 100-I50%. The chain of the invention is a precision trick by correcting the non-linearity of the photo or apert. This goal is achieved by the fact that in an automatic photo gate containing a power source, a photoresistor connected in series with the time by a driving capacitor, in parallel with which a sync contact is connected, two transistors connected through a threshold element to the actuator of the gate, the transistors are included as a composite transistor between the photo resistor and the time by the driving capacitor, the emitter of which is connected with the photoresistor, the collector is connected to the time by the driving capacitor of the atom and the threshold element, and the base is connected It is connected with the common point of the entered voltage divide connected to the opposite power supply buses, one of the arms of which is equipped with a thermal compensating diode, while a resistor is inserted between the driving capacitor time and the power supply bus. FIG. 1 is a schematic diagram of the device; in fig. 2 shows the luminosity lag time for the ideal and real photoresistors. The device contains a power source I, a voltage source 2, made in the form of a voltage divider with a thermal compensating diode 3 of a composite transistor formed by transistors 4 and 5, the emitter of which is connected to the photoresistor 6, the collector is connected to the time by the drive capacitor 7 and the threshold element 8, and the base is connected to the common point of the voltage divider; in this case, a resistor 9 is inserted between the driver reference capacitor 7 and the power supply source bus I in parallel with which the synchronous switch 10 is connected, and the output of the threshold element 8 is connected Artist 1b M-element 11 in the form of an electromagnet. The device works as follows. When the power supply 1 is on, the actuating element 11 is under current, the time of the assault, the capacitor 7 is discharged and the input voltage of the threshold element 8 is equal to zero. The collector current of the composite transistor is determined by the voltage value at its base and the resistance value of the photoresistor 6, which depends on the illumination. When the sync contact 10 is opened, the collector current ToK of the composite transistor will flow through time the driving capacitor 7 and the resistor 9. As a result, the voltage across the resistor 9 creates a voltage drop, which is subtracted from the turn-on voltage of the threshold element 8. more current will flow through the resistor 9, causing a reduction in the charging time of the driving capacitor 7, which determines the shutter-release time. This relationship is expressed in the following form: t-, shutter release time; the turn-on voltage of the threshold element 8; capacitance time setting capacitor 7; the current flowing through the photoresistor 6; R is the resistance of the resistor 9. The resistance value of the resistor 9 is adjusted so as to correct the nonlinearity of the light characteristic of the photoresistor 6 at relatively high levels of illumination. At low illumination levels, the current Sf is small, the RC component compared to (jcfj, is very small and does not have a practical effect on the accuracy of working out the exposure. Figure 2 gives an illustration of the correction of nonlinearity of the photoresistor 6. Curve C) corresponds to an ideal dependence of the exposure time t the photogate from illumination E in relative units, and the curve - J - to the real photoresistor 6 at large levels of illumination. The curves a and f are shifted relative to each other in the ordinate by an amount RC, allowing effective correction at high light levels and not having any practical effect at its low levels. A composite transistor, a differential transistor, also takes part in correcting the nonlinearity of the photoresistor 6. the output resistance of which decreases with an increase in the collector current, i.e. the current Eff. At the same time, this relationship is hyperbolic in nature, i.e. the composite transistor also corrects the nonlinear component. Contents of the proposed invention allows to reduce the error in the automatic processing of rods cameras and light barrier for printing in 4-5 times. Automatic photogate Formula invention comprising a power source, a photoresistor in series with a capacitor Time Sets, couple