DE570383C - Method for achieving a sufficiently linear characteristic for the current causing the remote image transmission as a function of the brightness values of the image - Google Patents

Description

In most systems for remote image transmission using reflected Light for scanning the image is the dependence of the light-sensitive Cell supplied current intensity not proportional to the light intensity. The present Invention eliminates this disadvantage and superimposes the current of the photosensitive cell a stream that makes the difference between

ίο the actual and the desired rectilinear Compensates for the characteristic curve of the light-sensitive cell, for example the gain increases in the dark areas and weakens in the light areas.

As an example, the invention is applied to that in the accompanying drawing The overall circuit shown is described without, however, being limited thereto. the end This example is the basic idea of the

so proceeding.

ι is a photoelectric cell, the hacked, light modulated with the image brightness values via any scanning device is fed. This cell receives hers

The anode voltage via the resistor 8 and is connected via a capacitor 14 to the grid of the first tube 4 of a four-stage amplifier. The tubes 5, 6 and 7 of the second, third and fourth stages are coupled to one another via resistors 10, 11 and 12 and capacitors 16, 17 and 18. The primary winding of an output transformer 13 is located in the anode circuit of the fourth tube, from which the remote transmission then takes place by means of known transmission devices.

A second photoelectric cell 2 is supplied with the same chopped light that also acts on cell 1; however, in this case it will not be with the image values modulated. The cell 2 is fed via a resistor 9 from the battery 19 and is connected to the grid of the first tube 4 via the capacitor 15. The cathode this cell is connected to the anode of the tube 3.

The grid of a tube 21 acting as a detector lies parallel to the grid of the tube 6. The anode of this tube receives its voltage from the battery 20; the cathode is on Earth, so that the anode circuit is closed via resistor 23 and earth. This resistor can be used to adjust the bias voltage for the grid Tube 3 can be removed via resistor 22.

The grid of the first tube 4 thus receives, on the one hand, a pulsating, modulated voltage from cell 1, on the other hand a pul-

emitting but not modulated voltage from cell 2. The anode current of this tube is therefore equal to the sum of two currents of the same phase but different amplitudes. The amplitude of the non-modulated current of the cell 2 can be adjusted by regulating the light intensity to be influenced. The anode current of the tube 21 is in phase with that of the Tube 4; the amplitudes are proportional. As a result, the voltage drop is in the resistor 23 also in proportion to the grid voltage fluctuation of the Tube 4, which in turn depends on the respective brightness value of the image. The arrangement for improving the proportionality the current amplitudes as a function of the image values now acts in the following way: If z. B. von Schwarz in White tints passing in front of the photoelectric cell 1 arise increasing amplitude values at the grids of all tubes 4, 5, 6 and 21. The The voltage drop in resistor 23 also increases. As a result, the grid becomes the Tube 3 more and more negative compared to the negative potential of the filament, so that the resistance between the filament and the anode of the tube 3 increases and causes decreasing current values in the cell 2. Of the The voltage drop in the resistor 9 is reduced in the same way as that of the cell 2 the grid of the tube 4 supplied additional alternating voltage. The reverse is true if the amplitudes of the modulated current decrease, i.e. at the transition of the tones from white after black.

In Fig. 2, α schematically shows the course of the modulated current supplied by the cell 1 as a function of the image values, b the course of the current that is caused by the additional cell 2, which is excited by the chopped, unmodulated light and is changed in its operating voltage through the tube 3. c shows the resulting current curve determined for the transmission. It can be seen that this resultant c has an approximately straight course.

Instead of the additional cell, another alternating current source can be used, when this supplies a current that is both in phase with that in the main circuit flowing current is controlled as well as by a tube serving as a resistor with one or more electrodes will.

To achieve the same effect, the additional cell 2 can be omitted and turn on the tube 3 in the circuit of the main cell ι.

Claims (2)

Patent claims: I. Method for achieving a sufficiently linear characteristic for the the long-distance image transmission depending on the current on the light-sensitive Scanning cell-acting brightness values of the image, characterized in that that the current of the light-sensitive scanning cell is in phase Current is superimposed, the difference between the actual and the desired rectilinear course of the Compensates for the characteristics of the light-sensitive cell. 2. Device for generating the equalizing current for the method according to claim i, characterized in that part of the amplified current of the photosensitive Cell controls a three-electrode tube with a polarized grid. 1 sheet of drawings