DE1763053U - CIRCUIT ARRANGEMENT FOR TELEVISION RECEIVERS OPERATING ACCORDING TO THE INTERCAREER PROCEDURE. - Google Patents

Description

S A B A Black Forest apparatus construction institute August Schwer Sons G. m. b. H.

Villingen-Black Forest Switching arrangement for after the third carrier process working television receivers.

For televisions that use the intercarrier method, it is difficult to optimally tune the device on each received frequency band in such a way that that the image carrier in the middle of the Nyquist flank and the sound carrier in the area of a part of the overall tuning curve that runs as horizontally as possible, namely on the so-called clay stairs. The television receivers have been voted on so far each television reception channel with a fine tuning in the form of a variable Capacitance has been provided on the superimposed oscillator, which is set by hand is that with a sufficiently strong TV picture, large amplitudes of the audio signal do not yet cause picture disturbances.

However, this type of setting is unsatisfactory, especially in recent years Time special setting means, so-called "sharpener" or "clarifier" provided that make the received television picture sharper. These means make an impact although a considerable increase in image sharpness, but at the same time make the cheapest Adjustment - the aforementioned fine-tuning so critical that they frequently is practically impossible for a technically inexperienced operator. Man has therefore recently switched to using special voting displays, especially 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. Albeit such voting indications clear indications of the most favorable setting for fine-tuning, they require a number of manipulations. Since these are often too complicated for laypeople and consequently not properly executed the advantage of such arrangements is often lost.

The aim of the innovation is to avoid these difficulties. she is that in a circuit arrangement for after the intercarrier method working television receivers, in which the reception of the image carrier is each respective received frequency band can be adjusted to the middle of the Nyquist edge automatic reception coordination of the picture carrier controlled by the picture IF carrier Discriminator-serves, one of which brings about the automatic reception voting Control voltage is derived.

The innovation makes the usual, manually operated fine adjustment and the manual correction of the oscillator that was previously required when changing bands completely dispensable. It is useful for precise automatic control of the local oscillator a reactance tube that derives from the discriminator Control voltage, if necessary after DC voltage amplification, is fed. A particularly favorable mode of operation of the automatic reception tuning results look for further features of the innovation if the one acting on the local oscillator Reactance tube is connected so that it acts as an adjustable negative capacitance when negative Damping conductance works.

For this purpose, the reactance tube acting on the local oscillator On the grid side via a phase-rotating voltage divider with the oscillator circuit be connected, for example the grid side of the reactance tube on the grid side End of the oscillator circuit and the anode of the reactance tube on the anode side End of the oscillator circuit or vice versa are connected.

On the other hand, the reactance tube acting on the local oscillator Via a phase-rotating voltage divider partially connected between the anode and cathode be connected to the oscillator circuit, the anode side of the reactance tube at one end, for example the anode-side end or the grid-side end of the oscillator circuit is connected.

The circuit arrangement according to the innovation is therefore for each Television tape in the receiving device an automatic reception adjustment of the image carrier reached the middle of the Nyquist flank. As a result, the sound carrier inevitably lies on the tone staircase of the overall tuning curve, so that by incorrect setting of the toh carrier induced image disturbances can be avoided with certainty and additives for Improvement of the contour sharpness of the television picture fully exploited can be. A sufficiently strong reception signal is of course required for this, that does not result in any significant noise component in the receiving device, provided. It However, in exceptional cases it can happen that the reception conditions are particularly unfavorable only a weak received signal is available, which has a higher contrast Image results if the image carrier is higher on the Nyquist flank instead of in the middle lays. In such special cases, because of the weak signal and the No great demands are placed on the image quality due to the amount of noise that occurs will. In short, it comes down to only one thing as possible under the given circumstances strong image. To achieve this, it is advisable to remove the reactance tube from the control voltage derived from the discriminator controlled by the picture IF carrier is optionally switchable to manually adjustable DC control voltages design. In this way you can then put the image carrier on as high as possible place the Nyquist flank and accordingly obtain a maximum of image enhancement.

In the aforementioned circuit arrangements can correspondingly one Further development of the innovation of the discriminator that generates the control voltage at the same time as a mixing stage to form a low-interference differential carrier for the Ton-IF are used, the input filter of the discriminator expediently as Combination filter is formed. Finally, the one obtained from the discriminator can Control voltage can also be used, one of the middle. Image brightness to control dependent Willfeldlicht for the television set.

Further refinements of the circuit arrangement according to the innovation emerge from the following description of several exemplary embodiments which are shown in the drawing. 1 shows a circuit arrangement for obtaining a control voltage from the picture IF of a television receiver and for amplifying this control voltage to an amount required for control. By means of a separating tube 1, in the usual Zf part, a drive working television receiver over a small Capacity 2 the received picture-sound-signal mix. grabbed (connection a) and fed to an output filter 3 "whose oscillating circuits 4 and 5 on the image IF (e.g. 38.9 MHz) are matched. These oscillation circles feed in one known discriminator circuit (Riegger-Gleich- richter) two diodes 6 and 7, which at point b generate a DC voltage dependent on the received signal, which is fed to the control grid of an amplifier tube 8. A DC voltage amplification takes place here in that the triode 8 and a compensation diode 9 on the anode side are supplied with the same line return pulses from point a. As a result, the amplified control voltage has the same shape symmetrical to the zero crossing as the control voltage of the discriminator tapped at point b. It is independent of mains voltage fluctuations, and it is retained during the switch-on process, since the triode 8 and the compensation diode 9, for example in the composite tube: PABO 80t, have a common cathode and are fed by the same line return pulses. The amplified control voltage is tapped at point d and fed to special retuning circuits for automatic reception tuning, which are shown in FIGS. According to a further development of the innovation, in addition to the discriminator circuit for the control voltage, the output filter 3 also contains an arrangement for the formation of a low-interference differential carrier for the tone-to-noise. The anode side of the tube 1 is in series with the oscillating circuit 4 for the Bild-ZE '(for example 38.9 MHz) another Oscillating circuit 10, which is based on the tone carrier frequency for example 33.4 MHz) is tuned. The secondary sides 11 and 12 of these oscillating circuits are connected in series in such a way that, with regard to the sound carrier frequency, the diodes 6 and 7 act as diodes connected in parallel instead of as a discriminator, as for the video carrier frequency. So you represent a pure rectifier or. Mixing stage for the formation of a differential carrier from the video carrier and the audio carrier frequency (for example 38.9-33.4 = 5.5 MHz).

The resonant circuit 13 is accordingly on the differential carrier 5.5 MHz tuned, the audio IF of 5.5 MHz is decoupled via the secondary side 14, and it can be tapped at point e. The Ton-Zu obtained in this way is special Low-interference, as the output filter 3 only covers the frequency ranges around 38.9 MHz (circle 4) and 33.4 MHz (circle 10) lets through, the one for the disturbing harmonic formation The frequency range in question from 36 to 38 MHz is suppressed. The for The oscillation circuits required to obtain the control voltage from the image IF carrier 4 and 5 are with those required for decoupling the sound differential carriers Oscillation circuits 10 and 13 advantageously become one in a common Combination filter to be accommodated shield combined, as shown by the dashed lines in Fig. 1 is indicated.

The Figg. 2 and 3 show examples of the inventive circuit of a reactance tube in such a way that it works as a controllable negative capacitance with a negative attenuation conductance. The negative capacitance of the dummy tube prevents the switching and tube capacitances of the reactance stage added here from increasing the total mean tuning capacitance of the oscillator. In the oscillator circuit, the L / C ratio is therefore not deteriorated by the reactance circuit. The negative damping conductance compensates for this increasing steepness of the blind tube growing inner positive conductance. As a result, a triode can be used as the dummy tube without disadvantage, which is more advantageous than a penthode because of its smaller tube capacity and because of its better performance at high frequencies.

For this reactance circuit, FIG. 2 shows an example with the grid-side coupling of the oscillator oscillation and FIG. 3 shows an example with the cathode-side coupling of the oscillator oscillation. The oscillator tube 15 works in Golpitt circuit the oscillation circuit 16 to be understood as the f-circle the capacity indicated by the dashed line through the anode Cathode capacity OAK. the oscillator tube is formed. The generated oscillator frequency is applied to the mixing level given. The tube 17 operates in a reactance circuit with the capacitor 18 (C = 3-5 pF) and the ohmic resistance (R = 10 Ohm). The controlling regulating voltage is fed to the connection d, which corresponds to the connection denoted by the same letter d in FIG.

In the circuit according to FIG. 2, the oscillator oscillation is on the grid side coupled into the reactance tube 17. This must because of the required phase rotation around 1800 the grid of the tube 17 to the grid-side end 9 of the oscillator circuit 16 coupled and the anode of the tube 17 to the anode-side end h of the oscillator circuit 16 be connected. In this circuit there are between the reactance stage and the oscillator two connections required.

In the circuit according to FIG. 3, the oscillator oscillation is on the cathode side coupled. The anode and the cathode of the reactance tube 17 are directly or Via the capacitor 18 at point i and the anode side h of the oscillator circuit 1. 6 connected This circuit has the advantage that it only has one connection requires between oscillator and reactance stage. The circuit of Fig. 3 has compared to that of FIG. 2 for high frequencies the further advantage that the tube capacities have less of an impact on the oscillator circuit.

With regard to the use of the reactance tube 17 in the various television bands I and III, another novel measure is used in these circuits: The frequency range to be covered with the reactance tube in the oscillator can be expanded considerably (factor 3 to 5) if you know how in Figs. 2 and 3, additional inductors 20 and 21 are arranged, which have a phase-correcting effect on the remaining harmful tube capacitances, in particular that between the cathode and the ground of the tube 17 according to FIG. 3. The resistor 19 and the inductance 20 can be combined to form a component unite if sheet resistors with set cut helix is used (e.g. a 10-layer wi- as a helix with one to two turns). The Induc- activity 21 is due to a small capacitance 22 (eV 40 pF) bridged, so that both result in a resonance circuit for approx. 110 MHz. This circuit acts as an inductance for the oscillator in TV band I (below 100 MHz). For television band III (at 200 MHz), on the other hand, it has a capacitive effect, so that here the inductance 20 is reduced by the capacitive component of 21/22 in band IHR and is therefore smaller. In this way, with the same control voltages (supplied at d), practically the same frequency variations are achieved despite the different oscillator frequencies in the individual television channels, as is particularly desirable for automatic reception tuning in each individual television channel. It is therefore possible without difficulty to automatically place the reception tuning of the picture carrier on the center of the Nyquist flank within each received television channel.

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

Fig. 4 finally shows a further circuit example, such as the control voltage obtained from the discriminator from the image ZB carrier for automatic Control of the television setting can be used. Here will be at the same time an automatic reception adjustment and one corresponding to the average image brightness achieved automatic setting of the ambient lighting in a television receiver. With regard to the reception tuning, reference is made to the description of FIG. 1.

It has been shown that ambient lighting in television receivers is necessary to protect the human eye. That is why the introduction of an additional light source that surrounds the room is becoming more and more popular Usually the TV will be brightened a little normal Leuchtbinmn so concealed that they Slightly brighten the area around the TV. It is now best if this ambient lighting corresponds to the average brightness of the television picture. The circuit arrangement according to the innovation offers a simple possibility of automatically adapting the brightness of the ambient lighting to the average image brightness in the television receiving device. The circuit arrangement according to FIG. 4 corresponds with regard to the control voltage for the automatic reception tuning with the parts 1, 2, 4, 5, 6, 7 and 11 as well as the supplied picture-sound-signal mixture (connection a) and with regard to the dependent on the received signal DC voltage at point b completely corresponds to the arrangement according to FIG. 1. While there, however, only the differential directional voltage is used to control a reactance tube at point b, the total directional voltage occurring at point g 'is now used at the same time to control a tube 23 on the grid side The anode current, which changes the changing control grid voltage, is used to operate an incandescent lamp 24, which brightens the space around the television receiver. In this simple way, the ambient lighting can be controlled automatically in accordance with the average image brightness of the television receiver, which is gentle on the eyes.

The arrangement according to the innovation can of course not only be the gradual eanal setting, as has been common in bands 1 and III so far is, but also with a continuous vote as it is for the television band IV is intended 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 manually, the image carrier automatically correct to the middle of the Nyquist slope of the overall tuning curve of the television receiver is placed.

Claims (8)

Protection claims 1. Circuit arrangement for according to the intercarrier method working television receivers, in which the reception of the image carrier is each respective received frequency band is adjustable to the middle of the Nyquist flank, thereby characterized in that for the automatic reception adjustment of the image carrier a from Image IF carrier controlled discriminator (4-7) is used, one of which is the automatic one Control voltage effecting reception tuning is derived. 2. Circuit arrangement according to claim 1, characterized in that a reactance tube for the precise automatic control of the local oscillator (15) (17) is used, the control voltage derived from the discriminator (4-7), if necessary after DC voltage amplification, is supplied. 3. Circuit arrangement according to Claims 1 and 2, characterized in that that the reactance tube (17) acting on the local oscillator (15) is gridded Via a phase-rotating voltage divider (18-22, Fig. 2) with the oscillator circuit (16) is connected, for example the grid side of the reactance tube (17) at the grid-side end (g) of the oscillator circuit (16) and the anode of the reactance tube (17) at the anode-side end (h) of the oscillating circuit (16) or vice versa are connected. 4. Circuit arrangement according to claims 1 and 2, characterized characterized in that the reactance tube acting on the local oscillator (15) (17) via a phase-rotating one partially connected between anode and cathode Voltage divider (18 to 22, Fig. 3) with the oscillator circuit (16) tied together with the anode side (i) of the reactance tube (17) at one end, for example the anode-side end (h) or the grid-side end (g) of the oscillator circuit : ses (16) is connected. 5. Circuit arrangement according to claims 1 to 4, characterized in that that the reactance tube (17) of the control voltage that of the picture IF carrier controlled discriminator (4-7) is derived on manually adjustable DC voltages is switchable. 6. Circuit arrangement according to Claims 1 to 5, characterized in that that the discriminator (4-7) generating the control voltage acts as a mixer at the same time (11-14) to form a low-noise differential carrier for the tone-to-use. 7. Circuit arrangement according to claim 6, characterized in that the input filter of the control voltage for automatic reception tuning the image carrier and the differential carrier for the audio IF forming discriminator (4, 5; 10-14) is designed as a combination filter (3). 8. Circuit arrangement according to Claims 1 to 7, characterized in that that the control voltage generated by the discriminator (4-7) is simultaneously sent to a control element (23) for controlling an ambient lighting that is dependent on the mean image brightness (24) of the television receiver is connected.