DE1258447B - Circuit arrangement for automatic reception tuning for television receivers operating according to the differential carrier method - Google Patents

Description

Circuit arrangement for automatic reception voting for after TV receivers using the differential carrier method For TV receivers, which work according to the differential carrier method, it is difficult to get the device on to optimally tune each received frequency band so that the image carrier on the Middle of the Nyquistfianke and the sound carrier in the area as horizontally as possible running part of the overall tuning curve, namely on the so-called clay staircase, lie. The television receiving devices have so far been used to tune each television receiving channel with fine tuning in the form of a variable capacitance on the local oscillator has been provided, which is set by hand so that with a sufficiently strong TV picture large amplitudes of the audio signal do not cause any picture disturbances. These However, the type of setting is unsatisfactory, especially in recent times Adjustment means, so-called »sharpeners« or »clarifiers«, are provided, which make the received television picture sharper. These means do indeed a considerable increase in image sharpness, but at the same time make the cheap Adjustment of the aforementioned fine-tuning is so critical that it is often used for a technically inexperienced operator is practically impossible. One is therefore recently switched to using special voting displays, in particular in the form of luminous sectors, which are similar to the so-called "magic eye" of a radio set when fine-tuning the television set. if also such voting displays clear displays of the most favorable setting for If the fine-tuning results, they require a series of manipulations. This one are often too complicated for laypeople and, as a result, not properly executed the advantage of such arrangements is often lost.

To avoid these difficulties, retuning circuits are available for receiving devices working according to the differential carrier method have been developed, which automatically tune the local oscillator to the middle of the Nyquistfianke.

In particular, a circuit is known in which a phase-rotated Control voltage from the grid side of the oscillator tube via an RC element to the Control grid of a reactance triode is fed back, which is in cathode base circuit works and its anode is connected to the anode of the oscillator tube. That at The RC element provided for this circuit inevitably results in an incomplete phase shift. In addition, the frequency deviation changes disadvantageously when switching from one Receiving channel on the other. The present invention provides a circuit arrangement proposed which does not have these disadvantages, d. H. especially which one the frequency deviation is approximately the same over several receiving channels.

It consists in the fact that it is designed as a triode of great steepness Reactance tube works with essentially the same frequency variation as the capture range, by providing a phase-rotating control voltage via an RC element in a manner known per se is supplied and by the phase rotation of this control voltage through the series connection a first inductor and one of a second inductor and one in parallel Corrected to this lying capacitor the existing resonant circuit to exactly 90 ° will. The oscillating circuit is dimensioned in such a way that it has the value of the first inductance in the television band of the low frequency, for example below 100 MHz, to its inductive Share increased and in the television band of the higher frequency, z. B. at 200 MHz to his capacitive part decreased.

Another advantage of this circuit is that the reactor tube only has little influence on the oscillator amplitude.

The circuit arrangement according to the invention makes the usual of Manual fine adjustment and the one previously required when changing the belt Manual correction of the oscillator is completely unnecessary, but it improves at the same time also the automatic retuning of this oscillator.

It therefore becomes an automatic one for each television band in the receiving device Reception adjustment of the image carrier to the middle of the Nyquist flank achieved. As a result, the sound carrier is inevitably on the staircase of the overall tuning curve, so that image disturbances caused by incorrect setting of the sound carrier Avoid safety and additives to improve contour sharpness of the television picture can be fully utilized. This goes without saying a sufficiently strong received signal that does not contain any significant noise in the Receiving device results, provided. However, in exceptional cases it can happen that in particularly unfavorable reception conditions only a weak reception signal is available, which results in a higher-contrast image when you use the image carrier on the Nyquist flank instead of in the middle. In such special cases because of the weak signal and the resulting noise component to the Image quality no great demands are made. Here it comes, in short, only look to a picture that is as strong as possible under the given circumstances. To that too Reach, it is useful to the reactance tube from the control voltage that of the is derived from the picture IF carrier controlled discriminator, optionally on from Manually adjustable DC control voltages to be switchable. In this way you can then place the image carrier as high as possible on the Nyquist flank and accordingly obtain a maximum of image enhancement.

The subject matter of the invention is shown below with reference to the circuit examples, which are shown in the drawings, explained in more detail: _ F i g.1 shows an im essential known circuit arrangement for obtaining a control voltage the picture IF of a television receiver and to amplify this control voltage to an amount required for the settlement. By means of a separation tube 1 is in the usual IF part of a television receiver operating according to the differential carrier method The received image-sound-signal mixture is tapped via a small capacity 2 (connection a) and fed to an output filter 3, the resonant circuits 4 and 5 of which on the image IF (e.g. 38.9 MHz) are matched. These oscillation circles feed in themselves known discriminator circuit (Riegger rectifier) two diodes 6 and 7, the generate a DC voltage dependent on the received signal at point b, which corresponds to the Control grid of an amplifier tube 8 is fed. DC voltage amplification takes place here, by the triode 8 and a compensation diode 9 on the anode side from point c line return pulses are fed. As a result, the increased control voltage has the same for Zero crossing symmetrical shape like the control voltage of the tapped at point b Discriminator. It is independent of mains voltage fluctuations and remains also obtained when switching on, since the triode 8 and the compensation diode 9, for example in the composite tube PABC 80, have a common cathode and fed by the same retrace pulses. The increased control voltage is picked up at point d and special for automatic reception coordination Retuning circuits according to the invention, which are shown in FIGS. 2 and 3 shown are.

Only marginally - because it does not belong to the invention - it should be noted that when switching on the audio carrier IF or the differential carrier frequency tuned oscillating circuits 10 and 13 with the respective coupled secondary circuits 12 or 14 at point e at the same time also with the additional use of the diodes 6 and 7 obtained differential carrier tone signal can be taken.

With the in F i g. The circuits shown in FIGS. 2 and 3 has the reactance tube 17 the effect of a controllable negative capacitance with a negative attenuation conductance. The negative capacitance of this tube prevents the switching and tube capacitance the reactance stage increase the total mean tuning capacity of the oscillator. In the oscillator circuit, therefore, the L / C ratio is not due to the Reak dance circuit worsened. The negative attenuation conductance compensates for the increasing slope the inner positive conductance increases in the reactance tube. As a result, as Reactance tube can be used without the disadvantage of a triode, as opposed to a pentode because of their smaller tube capacity and because of their better performance at high Frequencies is more advantageous.

For this reactance circuit are shown in FIG. 2 an example with a grid-sided Coupling of the oscillator oscillation and in FIG. 3 an example with a cathode side Coupling of the oscillator oscillation shown.

The oscillator tube 15 works in Colpitt's circuit on the as a z-circle to be understood oscillating circuit 16, in which the dashed capacity indicated is formed by the anode-cathode capacitance CAK of the oscillator tube. The generated The oscillator frequency is fed to the mixer at f. The tube 17 works in reactance circuit with the capacitor 18 (C = 3 - 5 pF) and the ohmic resistance 19 (R = 10 ohms). The controlling voltage is fed to terminal d, which is the with the same letter d designated connection in F i corresponds to g.1.

In the circuit according to FIG. 2 the oscillator oscillation becomes the grid side coupled into the reactance tube. This must because of the required phase rotation by 180 ° the grid of the tube 17 to the grid-side end of the oscillator circuit 16 coupled and the anode of the tube 17 to the anode-side end of the oscillator circuit 16 be connected. In this circuit there are between the reactance stage and the oscillator two connections necessary.

In the circuit according to FIG. 3 the oscillator oscillation is on the cathode side coupled. The cathode of the reactance tube 17 is connected via the capacitor 18 to the Anode side of the oscillator circuit connected. This circuit has the advantage that it only requires a connection between the oscillator and reactance stage. the Circuit according to FIG. 3 has compared to that according to FIG. 2 for high frequencies the further advantage that the tube capacities have less of an effect on the oscillator circuit impact.

With regard to the use of the reactance tube 17 in the various TV bands 1 and III in these circuits, according to the present invention, becomes as follows Measure applied: The frequency range to be covered with the reactance tube in the oscillator can be expanded considerably (factor 3 to 5) if, as in the F i g. 2 and 3, additional inductors 20 and 21 are arranged, Which versus the remaining damaging tube capacities, especially those between the cathode and the ground of the tube 17 according to FIG. 3, have a phase-correcting effect. The resistor 19 and the inductance 20 can be combined into one component, if you use sheet resistors with an incised helix (e.g. a 10 - 9-layer resistor as a helix with one to two turns). The inductance 21 is bridged by a small capacitance 22 (-40 pF), so that both have a resonance circuit for about 110 MHz. This circle works for the oscillator in TV band I. (below 100 MHz) as inductance. It works for TV band III (at 200 MHz) on the other hand capacitive, so that here the inductance 20 by the capacitive component of 21, 22 in Volume III is reduced and thus becomes smaller. One achieves that way with the same control voltages (supplied at d) despite the different oscillator frequencies practically the same frequency variation in the individual television channels, such as it is especially useful for automatic reception tuning in each individual television channel is desirable. So it is possible without any difficulty within each received TV channel the reception tuning of the image carrier automatically to the center of the To lay Nyquist flank.

If you want this automatic in a few special cases To deviate reception coordination, then the point d needs in the circuits after the F i g. 2 and 3 only by means of a switch from the discriminator output d of the F i g.1 separated and connected to a manually adjustable by means of a potentiometer variable DC voltage to be applied. Then you have a fine-tuning by hand, with which one can place the image carrier on the Nyquist flank according to the special case can put higher.

The arrangement according to the invention can of course not only be the step-by-step channel setting, as was previously the case in bands I and III is, but also with a continuous vote like that for the television band IV is provided to be used with advantage. It causes at a continuous Coordination provides greater security in the most favorable reception setting by, even if the frequency is not set precisely by hand, the image carrier is automatic correct to the middle of the Nyquist slope of the overall tuning curve of the television receiver is placed.

Claims (2)

Claims: 1. Circuit arrangement for television receivers operating according to the differential carrier method for automatic reception tuning to the center of the Nyquist flank with a discriminator controlled by the picture IF carrier and a reactance tube connected to the receiving oscillator tube on the anode side, dadu rchge denotes that the triode is larger The steepness of the reactance tube (17) with essentially the same frequency variation operates as a capture range by being supplied with a phase-rotating control voltage via an RC element (18, 19) in a manner known per se and by the phase-rotation of this control voltage being connected in series with a first inductance ( 20) and an oscillating circuit consisting of a second inductance (21) and a capacitor (22) lying parallel to it is corrected to exactly 90 °, the oscillating circuit (21, 22) being dimensioned so that it has the value of the first inductance ( 20) in the television band of the low Frequency, for example below 100 MHz, increased by its inductive component and in the television band of the higher frequency, z. B. at 200 MHz, reduced by its capacitive component. 2. Circuit arrangement according to claim 1, characterized in that that the reactance tube (17) is controlled by the control voltage of the picture IF carrier Discriminator (6, 7) can be switched to manually adjustable DC voltages. Documents considered: German Patent No. 953 810; British Patent No. 651226; U.S. Patents Nos. 2,298,870, 2,448,908, 2,504,663, 2,666,847, 2,738,380, 2,773,119; H. P i t s c h, "Textbook of radio reception technology", 1948, pp. 651 to 654; "FTZ", 1955, No. 7, p. 378; »AEÜ«, 1948, issue 2/3, p. 88 to 101.