DE1138424B - Circuit arrangement for correcting the gradation of a video signal - Google Patents

Description

Circuit arrangement for correcting the gradation of a video signal As is well known, it is often necessary to adjust the gradation, i. H. the relationship between signal value and brightness value, to be corrected in the case of a television video signal, because some of the transfer elements switched between image acquisition and image reproduction have a non-linear characteristic.

Usual correction devices of this type only change the about a parabola .following curvature of the signal characteristic, which is a change in the Exponent "gamma" of a parabolic function can be viewed.

However, some transmission links, in particular a camera, have S-shaped distortion, so that the black values and the white values corresponding parts of the characteristic curve show an opposite curvature. For equalization must then also have a corresponding characteristic curve in opposite directions and with different curvatures a correction member can be used. Circuit arrangements are known for this purpose, which allow a very good correction, but they also require a great deal of effort require and therefore not for simpler devices, especially for receiving devices be considered.

From the USA patent specification 2 641649 and the German patent specification 1033 703 it is also known to perform such an equalization by opposing parallel to make switched diodes or tubes. But the problem arises here Activation of the bias voltages required for the individual tubes or Diodes should be different. In practice, however, non-earthed DC voltage sources can be used cannot be implemented without an unacceptably high level of effort.

In a circuit arrangement for correcting the gradation of a Direct current component containing video signal with at least two parallel lying Diodes with opposite forward direction and different bias voltage are used these disadvantages are avoided, and one can surprisingly with little effort good and also adjustable change in the Transfer characteristic obtained when according to the invention between the video signal source and the output resistance of the correction arrangement in the series branch a first and a second diode with polarity permeable to the direct current component and one Third diode lying parallel to them is switched on with opposite polarity are and if the connection point of the first and the second diode via a series resistor with a bias voltage source having the polarity of the DC component connected is.

The invention is illustrated below with reference to the drawing, for example explained in more detail.

Fig. 1 shows one between the video demodulator and the input of one Video amplifier stage switched on correction arrangement according to the invention; Fig. Figure 2 shows an arrangement by which the required bias is obtained from the intermediate frequency signal can be derived.

In FIG. 1, the intermediate-frequency oscillations of a television receiver, which are modulated with the video signal, are fed to the terminals 1, which are connected to an IF oscillating circuit 2. The inductance of this resonant circuit 2 is coupled to a coil 3 which is connected on the one hand to earth and on the other hand to the cathode of a demodulator diode 4 , the anode of which is connected to earth via a load resistor R. The IF oscillations are kept away from the load resistor R by a smoothing capacitor 5.

Demodulated video signals of the voltage E appear at the resistor R. negative polarity between a value of low negative voltage -E. " for white signals (ws) and a value of more negative voltage -Esw for black signals (sw) as well as a strongly negative peak value for synchronization signals fluctuate, as indicated in Fig.l left .above is where part of a conventional video signal voltage E is shown as a function of time. The video signals become the cathode fed to a diode X, the anode of which is connected to the cathode of a diode Y, the anode of which on the grid of a video amplifier tube 6 grounded at the cathode, e.g. B. a pentode. The series connection of diodes X and Y is reversed Forward direction a diode Z connected in parallel. The junction of diode X and Y is across a series resistor V connected to the negative pole of a bias voltage source U, whose positive pole is grounded. Between the grid of the video tube 6 and earth is an output resistor G is also switched on.

Due to the action of the bias source U, a current flows through it the series resistor V, the diode Y and the output resistance G to earth, so that especially when the diodes X and Z are blocked, a negative with respect to earth Voltage on the grid of the tube 6 adjusts, which is preferably approximately the middle value corresponds to the video voltage occurring at the resistor R, which is in the modulation range can occur. The diode shows an average forward resistance, which is As can be seen below, when the signal occurs, something changes because the current through this diode also changes.

If the signal reproduces a white value (ws) and also less strongly is negative, the voltage across resistor R is positive compared to the voltage across Resistance G, so that the diode Z becomes conductive. You from the current flowing through it dependent resistance then determines the relationship between the voltage across the resistor R and the voltage across the resistor G and causes a curvature in the transmission characteristic in such a way that the signals for bright white values have a relatively increased amplitude occur on the grid of the video amplifier tube 6.

If, on the other hand, darker gray values are transmitted, the voltage more negative at resistor R than at resistor G.

Then the diode X becomes conductive, and passes through the diodes X and Y. the input voltage to the resistor G, in particular the curved characteristic the diode X, but also the effective in the same sense diode Y cause the darker gray values have relatively greater voltage changes on the grid of the video amplifier tube 6 evoke.

Assuming that the diodes X and Z are both blocked, so can one can find that the bias on the diode X by the voltage drop on the Diode Y (which is always conductive) is more negative than that of diode Z.

So there is a certain range in which the input voltage can change without the; Voltage across resistor G assumes a different value. The limit values E1 and E2 result from where Yo is the resistance of diode Y when diodes X and Z are blocked. The difference between the two voltages is It is therefore essentially proportional to the forward resistance Yo of the diode Y, whereby the approximation given on the right is valid if this forward resistance is small compared to the sum of the values of the series resistor V and the output resistance G. In general, the area in which a transmission should take place the diodes X, Y and Z does not take place, just be small. This is the case when the quotient of the forward resistance Yo of the second diode Y and the sum of the values of the series resistor V and the load resistance G is less than nine tenths, preferably less than one tenth to one third, of the quotient from the variation of the The input voltage in the control range, ie in particular between the voltage across the resistor R for light white and for black, to the voltage of the bias voltage source U is: The larger values are particularly permissible if a correction is only desired at the outer edges of the variation range. A linear transmission in the intermediate area in which the diodes X and Z are blocked can be achieved in that the diode Z is connected in parallel with an ohmic resistor P.

As a correction primarily for the greater brightness values Area is desired, d. H. so for low frequency signals, it can be useful be to bypass the arrangement by a capacitor C for high frequencies.

The fact that the signals corresponding to the white level are only routed via the diode Z, but the signals corresponding to the black level via the series connection of the diodes X and Y , means that the white signals can be distorted in a slightly different manner than the black signals. If the diode Y were replaced by an ohmic resistor, there would be a certain linearizing effect such that the black signals would be less distorted if the diode Y were not carrying a bias current; this would possibly result in a stronger distortion of the black signals compared to the white signals. Because in the arrangement according to the invention the current flowing through the series resistor V from the source U keeps the diode Y continuously conductive, it can be achieved that the black signals and the white signals are distorted at least almost to the same extent.

On the other hand, in practice there is often a different distortion he wishes. This can be done by setting the bias voltage U and the size of the Series resistor V, in particular by shifting the area in which the Diodes X and Z are both blocked, can be obtained. For this it can be advantageous be the voltage of the source U and / or the value of the resistor V adjustable close.

The pre-resistance V is expediently large compared to the mean forward resistance Yo of the diode Y. It can also be advantageous that the value of the series resistor V is in the order of magnitude of the value of the output resistance G. Will be expedient the diode Y chosen and adjusted so that its mean forward resistance Yo is of the order of magnitude of the output resistance G.

The bias voltage U can in particular be obtained in that a resistor 7, preferably bridged by a large capacitor 8, is connected in the cathode circuit of the tube 6 and that the end of the series resistor V facing away from the diodes X and Y with that facing away from the cathode of the tube 6 , is preferably connected to the grounded end of the resistor 7, as indicated by dashed lines in Fig.l. So that the voltage across the resistor 7 is as constant as possible and independent of the average image brightness, the resistor 7 should have a non-linear characteristic such that the voltage remains essentially constant when the cathode current changes. Such switching elements are commercially available as "VDR resistors". The stabilization can be further improved by supplying an additional bias current to the cathode resistor 7 via an auxiliary resistor 9 from the positive pole of the supply source.

Because the area in which the diodes X and Z are blocked, only through the bias source U, the series resistor V, the working resistor G and the properties the diode Y is determined, it follows that with a smaller signal, as it is z. B. at a visually impaired transmitter can occur in the event of fading, the uncorrected Area is moved to another part of the dynamic range so that instead of the desired equalization, an annoying additional distortion can result.

It can therefore be useful to control the bias voltage U proportionally to the signal amplitude. This is shown in FIG. 2. With the resonant circuit 2 connected to the input terminal 1, there is coupled to the winding 3 (according to FIG. 1) a further winding 11 , which is connected on the one hand to earth and on the other hand to a capacitor 12, the other layer of which is connected the anode of a diode 13 is connected to earth. The anode of the diode 13 is also connected to the cathode of a diode 14, the anode of which is connected to ground via a capacitor 15 and a potentiometer 16 connected in parallel to it. This creates a negative voltage at the resistor 16, in particular through peak rectification of the sync pulses, of which a part U 'can be taken from the wiper of the potentiometer 16 and made effective in place of the voltage U in the circuit according to FIG.

By means of a resistor K between the resistor R and a The tap on the working resistor G can be switched on by means of a switch S, it is possible to use the correction arrangement with the diodes X, Y and Z at least for To bridge part and thereby get an uncorrected transmission. Of the Tap on the resistor G is expediently chosen so that when you close the Switch S the range of voltage change across resistor G does not change significantly is opposite to the voltage change that occurs when the correction voltage is switched on Lattice of the tube 6 occurs.

Claims (13)

PATENT CLAIMS: 1. Circuit arrangement for correcting the gradation a video signal containing a direct current component with at least two in parallel lying diodes with opposite forward direction and different bias voltage, characterized in that between the video signal source (R) and the output resistor (G) the correction arrangement in the series branch a first and a second diode (X, Y) with polarity permeable to the direct current component and one parallel to them lying third diode (Z) with opposite polarity are switched on and that the connection point of the first and the second diode via a series resistor (V) with a bias voltage source having the polarity of the DC component (U) is connected. 2. Circuit arrangement according to claim 1, characterized in that that the output resistance (G) with the grid and the cathode of a video amplifier tube (6) is connected and that the bias voltage is one in the cathode branch of the video tube lying resistor (7) is removed, which is bridged by a capacitor (8) is. 3. Circuit arrangement according to claim 2, characterized in that the cathode resistor (7) has such a non-linear characteristic that the voltage changes with changes of the current remains essentially constant. 4. Circuit arrangement according to claim 3, characterized in that the cathode resistance from the positive pole of the supply source an additional Voistrom is supplied. 5. Circuit arrangement according to one of the preceding claims, characterized in that the bias is approximately the same is the voltage of a signal in the middle of the dynamic range. 6th Circuit arrangement according to one of the preceding claims, characterized in that that the bias voltage (0 corresponds to the signal amplitude, in particular its peak value, changes. 7. Circuit arrangement according to claim 6, characterized in that the Bias voltage (U) from the signal through rectification, preferably through peak rectification, is obtained. B. Circuit arrangement according to one of the preceding claims, characterized characterized in that the bias is adjustable. 9. Circuit arrangement according to one of the preceding claims, characterized in that the series resistor (V) is large compared to the forward resistance (Yo) of the second diode (Y) when blocked the first and the third diode (X, Z). 10. Circuit arrangement according to one of the preceding claims, characterized in that the value of the series resistor (V) is of the order of magnitude of the value of the output resistance (G). 11. Circuit arrangement according to one of the preceding claims, characterized in that the forward resistance (Yo) of the second diode when the first and the third diode (X, Z) are blocked in the The order of magnitude of the output resistance is, preferably about the same. 12. Circuit arrangement according to one of the preceding claims, characterized in that that the quotient of the forward resistance (Yo) of the second diode when blocking the first and the third diode (X, Z) and the sum of the series resistor (V) and the load resistance (G) less than nine tenths, preferably approximately one tenth to one third of the quotient from the variation of the input voltage in the control area for preload (0 is. 13. Circuit arrangement according to one of the preceding claims, characterized in that the third diode (Z), an ohmic resistor (P) and optionally a capacitor (C) effective for the higher frequencies of the transmission range, lies in parallel. Considered publications German Patent No. 1033 703; Swiss Patent No. 281913; U.S. Patent Nos. 2,641,649, 2,777,058; "Telecommunications", November 1955, p. 496.