DE930156C - Distribution system for television signals, e.g. B. for testing television receivers - Google Patents

Description

Distribution system for television signals, e.g. B. for testing television receivers It is known in a so-called. Clock a mixture of Feirnsehsynch: ronisierungssignalen and also to generate television picture modulation signals and several over lines Signal pick-up tubes to be connected to 'the television receivers'. can. Often there is the task of deciding on the individual signals: na; hmes.not only the signal mixture, but also the individual signals of the mixture are available to have. So far have been. for this purpose, the individual signals in front of the clock generator separately from: taken and by repositioning. alternately on the line or via additional lines the, acceptance points supplied. This made the distribution circuit proportionate complicated and expensive. In addition, the individual acceptance points were dependent on each other, and it could control the amplitudes and phases of your individual signals, only at a central one Place on the clock and not simply at the Signa ilahna; hmestelle self.

According to the invention, the mixture of television synchr'onisieru.ngssignailen and possibly also television image modulation signals, aJen, is now generated in the central clock and fed in one channel via a line, preferably a ring line, to several signal acceptance points and a signal separation stage is connected to each signal acceptance point, which separates the composite signal into individual signals. This eliminates the complicated line system for distributing the individual signals, and only the composite signal is fed to the tapping points via a single channel. The! The mixture is separated into individual signals, regardless of the valley area, directly at each signal wheel: n: ahm position in the signal barrier level. The signal separation stage contains one: input for the mixed signal, on the line and several separate: outputs for the individual signals, e.g. B. the image synchronization pulses (in the interlaced process, the raster change pulses) and the line synchronization pulses. The input for the signal generator at the signal separation stage #. Is expediently designed to be non-reactive in order to prevent load fluctuations at one acceptance point from affecting the other acceptance points. In: the separation stage, the image modulation signals can also be separated from the synchronization signals: so that the various synchronization signals - each with or without the image modulation signals - can be picked up by the signal input stage. According to the invention, the signal separation stage also contains devices to: -taken the composite signal and to change the individual signals in the phase (e.g. by reversing the polarity), and to regulate and increase the amplitude; S: power sources with small. Decrease internal resistance. According to a further development of the invention, the amplitude ratio between the synchronization signals and the image modulation signals can also be regulated in the signal separation stage. According to a further development of the invention, the composite signal can also be modulated in the clock signal onto a high-frequency or intermediate-frequency carrier. The mo, dulierteTräger is then via the conduit to the Siignalabnahmestellen: performed, demoiduliert in the signal separator, and the resulting composite signal in single s igna; le separated.

The invention and related details are with reference to the drawings for example explained.

Fig. I shows the. Schailtbild the distribution: ungsanlaige for television signals according to the invention. The clock generator i, designed in a manner known per se, generates a mixture of signals by means of tube circuits, pulse multiplication or pulse divider circuits as well as integrating and differentiating circuits. Line and picture synchronization signals from the television stations. The image synchronization signals (grid change signals) can; thereby, in a known manner, auxiliary impulses (satellites) should be added. Furthermore, the clock yellow generates Bi, Idmoidu.lationissignale, which are preferably in regular distribution and if necessary. with amplitude graduation between the synchronization signals are inserted. These appear on the screen of a television receiver as a grid of lines or points with a certain tone gradation according to type one. Gray wedge. That the complete signal mixture occurring at the output of the clock generator i! via the single-core shielded ring line 2, which at the exit with its wave resistance; 3 - is completed, the signal acceptance points A, B, C etc. .ignailei of the mixture. The signal separation stage 4 contains separation tubes, impedance converter tubes, rectifiers, phase inverter tubes, amplitude regulators, signal separation tubes, amplitude limiter tubes, etc.

An example of a circuit for a Sign: altrenüstufe according to the invention is shown in FIG. The composite signal is; from, the ring line 2 via the high-eared input 7 to the lattice circle of the tube ä supplied. The hoich.oihmige entrance causes that; no feedback from one signal pick-up point to the other; can be done. In the anode circle of the tube 8 is the low-impedance ampditude regulator 9 and; in the catho, denlz - rice the appropriately dimensioned amplitude; regulator io-. Via output ii, the amplitude controller g can pick up the complete signal mixture with low ears, with opposite phasing and with regular, fair amplitude. The mixed signal can be taken from the amplitude controller io via output r2: if low-resistance and with adjustable amplitude, but in phase with the input voltage. The tube works as an impedance converter in this circuit and the gain is less than one. By short-circuiting the output 12, the tube 8 can be switched to an amplifier stage with variable negative feedback. The amplified input voltage is then available at the output ii in; adjustable in size. Via the spoiler 13 , the signal mixture can optionally be removed from the anode circuit or the cathode circuit of the tube 8 and fed to the rectifier 14. The rectifier 14 cuts off the image module, t.ioin.s component, ie that of the synchronization signals. The polarity reversal 13 can be used to adapt to the input polarity. At the output of the rectifier. 14, the image content has been removed from the synchronization signals, and in the grid circle, the subsequent tube i @, only the synchronous, isierungseigna, le appeared. The tube 15 operates at 0 volts grid bias and acts simultaneously as an amplifier and limiter tube. It eliminates the modulation reserve that may not be left of the image modulation signals. The following tube 16 has a Doppeltrio, den system and amplified, the, in front of the image modulation, separate synchronization mixture up to a certain constant amplitude of, for. B. ro or 1 5 Vo, lt. That. right, triode system of the double tube 16 acts as a phase inversion tube. To the. Outputs 17 and 18 can thus be separated from the modulation - synchronization mixture with a constant amplitude of z. B. iö or 15 volts and opposite polarity can be removed. There you can see the picture synchronization signals and the 'Zei @ ensynchronous, ization signals mixed available without picture modulation. Its amplitude is independent of the size of the input voltage within certain limits. The polarity of the sync pulses is opposite to the output 18 as the output 17, at the output 17 z formed. B. the pulse voltage -io volts and at the output 18 the pulse voltage -i- io volts. The following tube, i9, is designed as a pulse separator tube. It has several grids (pentodes), and between. two grids, a frequency-dependent counter-coupling takes place via a timing element. In the exemplary embodiment, the time constant element consists of the capacitor 2o and the variable resistor 21 and is located between the braking grid and the screen grid of the pentode i9. It is on the line pulse frequency from, -ge agrees and can: be detuned in frequency within small limits at the resistor 21. This will. in the tube 19 the line pulse frequency is suppressed by negative feedback, so that only the image synchronization signals (raster change pulses) appear in the anode circuit. The rectifier 22 cuts off the remainder of the line that is still present in the anode circuit. The image synchronization signals (raster change pulses) can thus be picked up as single signals at output 23. In a circle. of the time constant element 20, 21, on the other hand, only the line synchronization pulses occur. These are via the. Diode 2 @. or a dry rectifier fed to output 2_5, where; they can be picked up separately from the, Bild: synchronis: ierungssignalen. The Diade2d. cuts off the remaining: image synchronization component. The diode 26 or a corresponding dry rectifier, the polarity reverser -27 and the amplitude regulator 28 have the purpose of being able to change the amplitude: ratio between the synchronization signals and the image modulation signals in the complete clock generator mixture. For this purpose, the input mixture is taken from terminals ii and 12 and fed to output 29 via polarity reverser 27, diode 26 and amp. The polarity can be changed at the polarity reverser 27. With the aid of the amplitude regulator 28, one can optionally weaken the synchronization component or the image modulation component in the input mixture.

The arrangement and the damage @ according to the invention can be used for different Applications can be used in television technology, e.g. B. for testing television receivers. In order to do this the complete television receiver including high frequency part and intermediate frequency part To be able to check, you can also see the composite signal in the clock. a high frequency or 'intermediate frequency carrier a: ufmodu: late. The modulated carrier then becomes accordingly as, in Fig. i, supplied via a ring line to the signal pick-up points. The pulse separation stage According to FIG. 2, a demodulator is added which is switched on in front of the input 7 will. The pulse separator then also contains a special output, the the modulated high-frequency or intermediate-frequency carrier is taken and immediately because the input of the television set can be fed.

Claims (3)

PATEN TANSPRL CHH: i. Distribution system for television signals, e.g. B. for testing television receivers, characterized in that, ß a clock is a mixture of television synchronous: isierungssignalen and possibly also: Fernsehb@ildmoldulat.ioinssignalen generated, which is single-channel via a line, preferably ring line, several signal receiving points, and that one at each signal collection point. Signa: internal stage connected: it is permitted to separate the composite signal into individual signals. 2. Distribution system according to claim i, characterized in that the signaling stage One input for the composite signal: as well as separate outputs for the composite signal and the individual signals, e.g. B. the image synchronization impulses: (raster change impulses) and the linesvnch, ro @ nisie, rungsimpul: se, contains. 3. Distribution announcement according to claim. i or?, characterized in that the input for the composite signal at the signal separating stage is designed to be reaction-free. q .. distribution @ san: situation according to one of claims i to 3, characterized in that in the signal separation stage @ the image modulation signals: ale separated from the synchronization signals: len and; the §ynchro @ is @ erungss: igna: le with or without: the hildmodula: tion signals can be removed, removed. 5. Distribution of shares after one. of claims i to .4, characterized in that ß the signal separation stage devices. contains, in order to change the signal mixture picked up from the line as well as the, E. single signals in: the phase (e.g. by reversing the polarity), furthermore in the amplitude! to be regulated and taken from power sources with low internal resistance. 6. according to one of claims i to 5, characterized in that the amplitude ratio: between the syn, chronisierungssib'nalen and the image modulation signals in the separation stage. is adjustable. 7. Distribution system nasch one of claims i to. 6, characterized in that the signal mixture is modulated onto a high-frequency or intermediate-frequency carrier in the clock generator, the modulated carrier is fed via the line to the: Signa: labnahme @ places, then demo.diiliert in the signal separation stage of the carrier and demo.diiliert the signal mixture into individual signals is separated. B. Distribution system according to one of claims i to 7, characterized in that a single-core shielded cable, which is preferably terminated with its wave impedance, serves as the line between the clock and the sign: alabnahmes rush. 9 :. Distribution system. according to one of claims i to. 8, characterized in that the signal separation stage contains isolating amplifier tubes, impedance converter tubes, rectifiers, phase and reversing tubes, amplitude regulators, pulse separating tubes and amplitude bending limit tubes. 1o. Signal separation stage for distribution system according to one of claims i to. 9, characterized in that the input (7) for the signal mixture accepted from the line is on the high-resistance grid circuit of an amplifier tube (8), in its anode circuit. and cathode circuit each has a low-resistance amplitude: nreglez (9, 1o) is switched on, from which the signal mixture via outputs (ii, 12) located on the sliding contact can become low-resistance with opposite polarity and regular amplitude. i i. Signal separating stage according to Claim 1o, characterized in that for separating the image modulation component. of the synchronization pulses. a rectifier (r4) is used, preferably via a UmpoIer (r3), optionally to the; Anode circuit or cathode circuit of the preceding tube (8) can be connected :. 12. SignalItrenns.tufe according to claim 1o or ii, characterized in that the rectifier (r4) a Vers.tärkerröhre (r5) in amplitude limiter circuit is nachgescha, het, which suppresses the remaining Bildmodulationsan partially. 13. Signiäl: separating: stage according to one of claims 1o to i2, characterized in that the amplitude limiter tube (r5) between two amplifier tubes, preferably in a double tube, so, chgescha, are ltet, which amplify and open the synchronization pulses limit a constant amount independent of the input voltage (e.g. 1o ... 15 volts), and that the one tube a, ls phase reversing tube is designed to transmit the synchronization signals to two separate outputs (r7, 18) to be able to decrease with opposite polarity. 14. Signal separation stage according to one of claims io to: 13, characterized in that for the separation of the image, synchronization pulses (raster change pulses) from. A multi-grid tube (i9) is provided for the line synchronization pulses, one of which is provided with a grid (e.g. braking grid), a frequency-dependent negative feedback that is matched to the line synchronization frequency via a possibly controllable time constant element to another grid (e.g. B. screen grid) takes place. 15. Signaltre: nns: stage according to claim 14, characterized in that the output (23) for the image synchronization, gsimpulsei (raster change! Lirnpu, lse) via a; Rectifier (22) is connected to the anode circuit of the Impulis: separation tube (i9). 16. Signal separation stage according to Artspruch 14 and 15, characterized in that the output (25) for the line synchronization pulses via a. Diode or troiclcen rectifier (24) to the negative feedback circuit; between two grids the impulse: separating tube (i9) b @ zw. the time constant element (2o, 21) is connected: is. 17 signal tremors according to one of claims 1o to 16, characterized in that for regulating the amplitude ratio between the synchronization signals. and a diode (26) or a voltage rectifier and an amplitude regulator (28) are provided for the image modulation signals of the single-channel signal mixture fed to the input (7) by the line; low-resistance outputs (1i, i2). for the composite signal can be connected: en, and that for the. Decrease in the signal mixture regulated with regard to its amplitude ratio, a special output (29) is present, which is connected to the anode of the diode or to a dry rectifier (26). Attached publications: "Electronics" June 1931, p. 185 (Edition Electron.ics Buyers'Guide); Telefunken "House Communications" July 1939, p. 25 ff., Article by Roosenstein; Sheet for PMZ 1951, pp. 156 to 157.