DE767750C - Circuit arrangement for re-introducing the average image brightness in television receivers with a Braunschweig tube - Google Patents

Description

It is. already known, in television ^1, the so-called direct current component, which reproduces the average brightness of the television picture, is important to be transmitted, but to re-introduce singles on the receiving side by approximating the bias voltage of the receiving source by hand. An automatic reintroduction ¹ is not possible here.

It has also already been proposed to ^{reintroduce the average image brightness using a transmission stream 1} which only reproduces the image content, but does not contain any synchronicity impulses. The reintroduction takes place in that the. Shift - the nullimie in the image content voltage is made usable solely in relation to the black values in the image content. Now, however, the black level does not only occur with buckets of black Büdrandi at the end of each picture line, but also occurs differently within the duration of the picture lines. But just ^1, this results in the charge of lying in the grid supply capacitor: depends not only on the average picture level, but rather also on the frequency and duration of the occurrence of black levels in ■ individual scan lines. The capacitor is charged via a rectifier, whose internal resistance is by no means zero, but especially with small ones. Direct currents have a very considerable value. Further

the mentioned capacitor is continuously 'discharged through a parallel resistor. Be many black spots will have a higher mean Generate image brightness in the received image than with a few black levels in the image This disadvantage does not occur with the subject matter of the invention, it is separate! playback the average image brightness is completely independent of whether the image is only a few ίο or contains many black spots.

It is also known, after each image line, a synchronizing pulse of such an individual To transmit amplitude that taking into account the mean brightness of the relevant image line, the entire voltage curve of a line and the associated: Synchronous pulse just represents a pure alternating current. This. procedure therefore requires a sync pulse of a different height and below for each image line Under certain circumstances, sync pulses with an amplitude of zero. If namely a picture line consists of nothing but black pixels a sync pulse of zero amplitude is required, d. H. the recipient can for the next line will not be synchronized at all. You transfer one Sync pulse, then the reproduction of the average brightness of the line in the receiver image again not right. Furthermore, if the average brightness of a line is very low, then so a sync pulse of extremely small amplitude must be transmitted, the then for synchronization on the recipient line was also not sufficient. . In addition, this known method to an extremely bad 'channel utilization. With high medium brightness One line must be the sync pulse, the duration of which is only a small fraction of the Line duration is given an extraordinarily high amplitude so that its area is the same the total area bounded by the image brightness voltage of the line. so but have all wireless transmitters, all amplifiers and generally all transmission links a dynamic range that must not be exceeded. If you have this Range by the sync pulse peaks, and the image signal voltages are much smaller than with this known method, the transmitter is just bad exploited. This known process has also not been in any stage of development the practice found entrance.

The invention now relates to automatically reintroducing the average image brightness in television receivers with a Braunschweig tube, provided that the image content and the sync pulses are transmitted on the same carrier wave with opposite polarity. For this purpose, according to the invention, the shift of the zero line of the voltage consisting of image content and sync pulses compared to the apex of the sync pulses, which occurs when passing through a receiving AC amplifier, should generate a voltage in the control electrode circuit of the Braun tube that increases and decreases with the average image brightness. With a device according to the invention, the disadvantages outlined above no longer occur. Some embodiments of the invention are explained below with reference to FIGS. 1 and 5 to 7. In Fig. 1 is indicated at 40 a high frequency amplifier with subsequent rectifier circuit which echselstromverstärker the content from the tubes 42, 44 and 46 existing W ^T for the image and supplies the sync pulses. From the tube 46, the image signals reach the heat control electrode 26 of a Braun tube 10, the cathode of which is denoted by 28, whose anode is denoted by 32 and whose fluorescent screen is denoted by 16, and whose cathode ray is denoted by the coil pairs 18 and 20 in the line direction and in the direction the image coordinate perpendicular to it is deflected. The grid circuit of a further tube 50 is connected to the anode of the last tube 46 of the go AC amplifier, in whose grid feed line there is also a resistor 53, while the grid leakage resistor is denoted by 51. From the anode of this tube 50, on the one hand, the sawtooth generators 22 and 24 are fed with the synchronizing pulses and, on the other hand, via a line 54, a rectifier, the cathode of which is represented by the cathode of the amplifier tube 52 and the anode of which consists of a cylinder 12, which is the cathode of the tube 52 partially surrounds. The voltage obtained in this rectifier is amplified in the tube 52 and also conducted to the heat control electrode 26 of the Braun tube 10 via the resistor 56.

The arrangement according to Fig. 1 works in detail as follows: At the anode of the Tube 42 has the image content 34 (Fig. 2) and the short sync pulses 37 as well as the long sync pulses 38 of the same amplitude (Fig. 3) existing voltage, which is shown in Fig. 4, such a phase position that the sync pulses cause a potential drop at the anode, while the image content is the anode increases potential. The original zero line 36 is no longer valid, but the Rather, the voltage curve at the anode of the tube 42 runs around the dotted line in FIG

Drawn new zero line 47. This is due to the fact that the amplifier located between the receiving antenna and the input terminals in the tube 42 does not transmit the so-called direct current component of the original voltage curve. The distance χ of the scissors of the synchronous impulses vc «ii of this shifted zero segment 47 becomes! now used to reintroduce the medium brightness.

At the anode of the tube 44 the image content and the synchronizing impulses are present existing voltage the reverse phase position as at the anode of the tube 42, and on the anode of the tube 46 the phase position of the mixture of characters is again the same as on the anode of tube 42. It is from the anode of tube 46 that all of the voltage comes on the one hand to the brightness control electrode 26

ao of the Bridal Tube. The potential of this brightness control electrode is thus shifted in the positive direction by the "image content", so that the beam current strength is increased, and the syndrome pulses shift the potential of the brightness control electrode in a negative direction, so that the beam is blocked during the short sawtooth flanks of the deflection voltage will. * On the other hand, the voltage from the anode of the tube 46 reaches the grid of the tube 50 via a coupling capacitor which is resisted by the grid conductor! 51 is assigned, as well as via the resistor 53 located in the grid lead. The grid of the tube 50 is at cathode potential as long as no voltage is transmitted from the tube 46, so that a certain anode quiescent current flows. The positive half-waves of the voltage occurring at the grid of the tube 50, ie essentially due to the image content, produce a grid current which charges the capacitor in the grid supply line. At the anode of the tube 50 the phase position of the mixture of symbols is thus again reversed as at the anode of the tube 46, ie the synchronizing pulses are in the positive direction. These now arrive on the one hand at the sawtooth generators 22 and 24 and on the other hand!) The mixture of characters via the connection line 54 and a coupling capacitor, to which the grid discharge resistor 14 belongs, to the rectifier section consisting of the anode 12 and the cathode of the tube 52. The current through this rectifier section causes a voltage drop at resistor 30 and resistor 14, which has the direction indicated by the plus and minus signs entered. This voltage is smoothed by a filter chain, which is formed by the resistor and capacitor connected to point 58, and is then applied to the control grid of tube 52, so that a corresponding voltage voltage occurs at its anode, ie at point 62 via the series resistor ¹ 56 also reaches the brightness control electrode 26 of the Braun tube. If the mean brightness of the television picture increases, the distance # in FIG. 4 increases and so does the amplitude of the voltage occurring at the anode of the tube 50. The voltage drop across resistor 30 and also the voltage drop across resistor 14 increase accordingly, and the potential at point 62 assumes a more positive value than> with a lower average brightness, ie with a lower value of x.

In Fig. 5 an embodiment is shown in which the tube 44 is used at the same time to separate the synchronous impulse from the image content and also to generate the DC voltage corresponding to the average image brightness. The entire voltage mixture (Fig. 4) is fed to the control grid 64 of the tube 44 from the anode of the tube 42 'in such a way that the control grid potential is increased in the positive direction by the half-waves containing the synchronizing pulses. In the cathode lead of the tube 44, which separates the rest of the sync pulses from the picture content by an anode rectifying effect, there is a resistor 63 bridged by a capacitor the cathode of tube 44, which is in phase with the. Potential fluctuations at the control gate 64 run. The potential of the brightness control electrode 26 with respect to the cathode 28 is thus increased via the line 68. shifted more in the positive direction, the larger the value χ in Fig. 4 is. The tube 46 still belongs with an AC amplifier and reverses the spamming mixture existing at the anode of the tube 42; so that the potential of the brightness control electrode 26 is shifted in the positive direction by the image content and in the negative direction by the synchronous pulse generator.

In the embodiment according to FIG. 6, the entire voltage occurs at the anode of the tube 46 with the same phase position as in Fig. 5. By means of the tube 70, its control grid 72 uses a fixed negative bias and! which consequently act as an anode rectifier works, those containing the synchro pulse peaks will be. Half-worlds the total tension of the; Half-worlds

the opposite polarity is separated, and because of the resistance capacitor element, a potential arises at the anode of the tube 70, which becomes more negative, the greater the distance χ . Since the anode of the tube ¹ 70 is connected to the cathode 28 of the Braun tube. the cathode ray current increases as the value of χ increases. The image content voltage together with the sync pulses is also conducted from the anode of the tube 42 via a further tube 46 to the brightness control electrode 26 and is thus again in the correct phase position; the picture content voltage is in a positive direction, the sync pulses are in a negative direction. The tube 44 serves here as a pure separation tube for feeding the deflection generators.

In the arrangement according to FIG. 7, the entire voltage again arises at the anode of the tube 42 with such a phase position, so that the anode potential increases ^{with the synchronizing pulses 1.} The image content and the synchronizing pulses are fed through the tube 46 to the brightness control electrode 26 in the same way as in the arrangement according to FIG. The tube 44 works in the same way as in Fig. 6. Instead of the anode rectifier 70 in Fig. 6, however, there is now a tube 78 operating in a grid rectifier circuit, the control grid So of which is directly connected to the cathode via a resistor. The sync pulse peaks cause a grid current in the tube yS, which charges the capacitor located in the grid lead, which can then be slowly discharged again via the resistor lying parallel to the grid cathode path. A capacitor 82 is connected in parallel with the anode resistance of the tube 78; so that at the anode of the tube 78 a more positive direct voltage potential occurs, the greater the distance χ . Since this anode is also connected to the brightness control electrode 26 , the potential of this brightness control electrode moves in a positive direction with increasing mean brightness, so that the direct current component is reintroduced.

Claims (6)

PATENT CLAIMS:; i. Circuit arrangement for re-; introduction of the average image brightness in i Television receivers with a Braunschweig tube, in which the image content and the sync pulses are on the same carrier shaft. but are transmitted with opposite polarity, thus marked net that the alternating current amplifier occurring when passing through a receiving Postponement of xullimia (36 according to 47) of the image content (34) and sync pulses (37, 38) Voltage opposite the apex of the sync pulses is a voltage that increases and decreases with the average brightness of the image generated in the control electrode circuit of the Braun tube. 2. Circuit arrangement according to claim r, characterized in that the variable with the average brightness from the half-waves containing the pulses of the voltage occurring behind the AC amplifier through a rectifier (12 in Fig. 1, 70 in Fig. 6, γ8 in Fig. 7 ) is won. 3. Circuit arrangement according to claim r, characterized in that with the medium brightness variable voltage with the help of the anode current changes a tube (50 in Fig. 1) is produced, which the impulses to the deflection devices feeds. 4. Circuit arrangement according to claim 3, characterized in that a resistor (63) with a capacitor connected in parallel is located in the cathode lead of the separating tube (44 in Fig. 5), from the cathode (66) of which the voltage corresponding to the average brightness is taken. 5. Circuit arrangement according to claim 2, characterized in that the anode of the penultimate tube (42 in Fig. 6) of the image current intensifier one in> Anode rectifier circuit working tube (70 in Fig. 6) connected to its grid is, to the anode of which the cathode (28) of the Braun tube is connected. 6. Circuit arrangement according to claim, characterized in that the anode the penultimate tube (42 in Fig. 7) of the Image current intensifier in a grid rectifier circuit working tube (78 in Fig. 7) is connected to its anode is connected to the control electrode of the Braun tube. To delimit the subject matter of the invention From the state of the art, the following publications are considered in the granting procedure been drawn: German patents Xr. 575,775, 628,663; French patents No. 273 227, 742855;
British Patent Xr. 363 979. 1 sheet of drawings 1 5254 6.53