DE756554C - Circuit arrangement for shrinkage control in television receivers - Google Patents

Description

Circuit arrangement for shrinkage control in television receivers The problem of shrinkage control in television receivers is different from the problem of shrinkage control in radio reception, as in television, apart from a series of alternating current frequencies, the so-called direct current component, which represents the average picture brightness, has to be transmitted remotely and there is no differentiation at the receiving end can determine whether a change in the mean carrier amplitude is due to a change in the transmission conditions or to a veining in the mean image brightness that is already present on a special side. One can therefore in television reception, the fading control does not perform in the same manner as Rundfunkempfäng not that so, you .that the receiving end, the average carrier amplitude by screening out all modulation frequencies from the finds from Dete! Ktorkreis supplied electricity and the gain as a function of this current influenced. Rather, one must look for other aids in order to accomplish the fading control without influencing the control device by the changes in the direct current component contained in the television signals. For this purpose, it is already known to transmit a control pulse with a constant carrier amplitude at the frequency of the line or the image or line sequence synchronization pulses in an image transmission method in which a carrier wave amplitude is increased by the permissible ildlrelligheit and reduced by the synchronizing pulses. This is separated from the image brightness signals and the synchronization pulse on the receiving side and thus provides a measure of the current loss in the receiver. According to this principle, television broadcasts can be received without shrinkage and also practically identical: the problem of the so-called field strength level for television receivers can be solved. In the already known arrangements, a capacitor has been charged on the receiving side with the direct current corresponding to the control pulse amplitude during the control pulse and the size of this capacitor has to be measured with the size of a parallel resistor in such a way that the Z ° _.itl, on constant des RC element resented the time until the next control pulse was. Since the voltage at this resistor cannot be heavily loaded, a current amplifier tube was connected to this circuit, which then represents a more resilient current duel, but does not provide a very high control voltage for the fading control able.

According to the invention, avoiding a tube in the receiver a Scli @ cin ", ull (Y circle of so little attenuation an- estol, ', en.

that he still has free oscillations beyond the duration of the control pulse executes, and the control voltage that occurs on this circuit is used to obtain the control voltage Voltage rectified.

The oscillation circuit can generate a higher voltage than by the well-known resistance capacitor element, and that of the oscillating circuit: connected rectifier can easily be designed so that he does not represent increased damping for the oscillation circuit. The current amplifier tube is thus spared and a simplification of the total necessary for shrinkage control Cost of circuit means. Achieved, since the Schwiligungskreis no heating as an intensifier tube requires and is also not subject to wear and tear.

An embodiment of the invention is illustrated in Fig. I of the drawing. It is a prerequisite that the control pulse is transmitted after all the picture change or line sequence change pulse. In 4bb. i means io a six-pole tube, and ii denotes an oscillation circuit located in the anode circuit of this tube, consisting of the isolating capacitor 12 and the choke coil 13. Another coil is inductively coupled to the coil 13, to which the grid of a tube 15 is connected, in whose @ #, nodenl: reis an RC element 16 is located. The resistor 17 and the capacitor 18 represent a sieve chain. Your grid 3 of the tube io is supplied with the voltage supplied by the rectifier circuit, which is composed of image brightness signals P, synchronization pulses Z for the line and synchronization pulses I for the The image or line sequence change consists of the R @ gel pulses, which have already been mentioned several times, which have the amplitude P and the duration t '. The grid i of the tube io is supplied with a voltage which has the duration t of the pulse L 'plus the duration t'.

The mode of operation of the circuit arrangement according to Fig. I is as follows: The tube io can only carry current as long as its grid i and its grid 3 are at a sufficiently high potential with respect to the cathode. The grid i allows the anode current to flow to me for the duration t + t '. During the rest of the time, the passage of electricity to the grille is locked. During the period t there is still a SIl # @ ri-tensioning at the grid 3, but only during the period t 'the tension of the amplitude P, ie. 1i. the control pulse. Thus, the Koidensator 12 is charged by the anode current, which corresponds to the I # egetimpttls-liöli.e P, only during the time t '. The charge of the capacitor leads to free oscillations in the oscillation circuit ii after the end of the time t ', which, due to the low damping of this oscillation circuit according to the invention, only subsided after several full periods of oscillation. The positive half-waves of this voltage curve, which is stepped up by the transformer 13, 1.f, each open the tube 15, so that the capacitor of the RC element 16 is charged during each positive half-wave. The filter plate 17, 18 suppresses the Z alternating voltage component still present on the RC element 16, so that a negative potential to earth can be tapped at the top of the capacitor 18, which is stronger the greater the pulse amplitude I ' . The potential at the top of the capacitor 18 can therefore be used directly to regulate the amplifier for the video signal voltages, for example as a bias voltage for the control grid of exponential tubes.

With the bias in the lattice circle of the tube 15, the control properties can be conveniently changed, d. H. you can, ever more negative this bias is made, the curve shown in Fig. 2 for the relationship between the Achieve size P and the control voltage at the capacitor @ toT 18, with increasing negative bias the curve shifts in the direction of arrow p.

The control pulse can also follow the synchronization pulse for the line break can be given, so that a new setting of the. Control voltage is already going on at the line rate.

The pulse for the grid i of the tube io can, for example, come from the Pulse V or from the pulses Z can be derived using a pulse lengthening circuit.

Claims (2)

PATENT CLAIMS: i. Circuit arrangement. for shrinkage control in television receivers in a transmission process in which the increasing image brightness the carrier wave amplitude is increased and the carrier wave amplitude is increased by the synchroni, sieri @ mpulse is reduced, using eilies from the transmitter with the frequency of a synchronizing pulse transmitted control pulse of constant carrier amplitude as well as using a circuit filtering out this control pulse on the receiver side, thereby characterized in that in the receiver of Aden sifted out control pulses an oscillating circuit so low attenuation is triggered that it also lasts for the duration of the control pulse in addition still executes free oscillations, and that to gain the control voltage the voltage on this circuit. is rectified. 2. Circuit arrangement according to Claim i, characterized in that the rectifier tube is transformer-driven is coupled to the oscillating circuit. To delimit the subject matter of the invention From the state of the art, the following publication is to be considered in the granting procedure drawn: British Patent No. 458 585.