DE935549C - Television transmission device with picture transmission tubes - Google Patents

Description

Usually one prevents the occurrence of a return line on the fluorescent screen in a known manner a cathode ray television receiving tube by suppressing the beam during return, both of which for the line return as for the line return. It also proved advisable to use the cathode ray in the case of image capture transmitter tubes to block during its return movements, so that the beam cannot partially discharge the light-sensitive screen during the return movement. It was now but found that the aforementioned suppression of the cathode ray of the transmitter tube is electrical

Causes disturbance which is difficult to suppress. Its origin has not yet been clarified, but it should come about because the beam suppression causes a sudden results in a strong shift in the equilibrium conditions in the operation of the tube.

The object of the present invention is the scanning beam of the television picture receiver tubes To block the transmitter tube for a longer time than the beam return time, so that the Beam return time falls into the blocking time.

This makes it possible to completely eliminate the above-mentioned disturbances in the suppression of the cathode ray.

to suppress men. In addition, the cathode ray remains of the transmitter tube during the whole Duration of the jet return safely blocked. To the effect of the disturbances also in the receiver to suppress safely, one gives the blocking impulses for the beam suppression in the receiver a longer duration than the pulses that block the cathode ray of the transmitter tube.

Rectangular tensioning pulses are used for beam suppression, which are placed on the control grid of the cathode ray tube. These must therefore have a longer duration than the synchronization pulses, which control the deflection circles of the transmitter tube. Similar square-wave voltage pulses are also sent to the receiver Suppresses the cathode ray of the receiver tube during the return and gives these pulses a longer duration than the pulses that block the cathode ray of the transmitter tube. The invention is explained in an example with reference to the drawings.

In Fig. Ι a television transmission device is more common Art drawn. The pulse generator 1 supplies control pulses over the lines 2, 3 for the Line and line supply deflection circuits 4, 6 of the cathode ray transmitter tube 7, blocking pulses via the - Line 8 and synchronization pulses on line 9, both of which are intended for the receiver. In the known type of image catcher transmitter tube 7, the image signals are generated via the image intensifier 24 given to a transmitter 26 and broadcast. Before that, however, the blocking and Synchronization pulses added. The locking signals are via line 8, amplifier 27 and Line 28 to one stage of the amplifier 24, the synchronizing pulses via line 9, amplifier 29 and line 31 to the following stage of the amplifier 24 led.

The blocking pulses for the suppression of the cathode ray of the transmitter tube 7 during the Returns are appropriately tapped at resistors 32, 33 and 34 and via amplifier 36 given on the control grid 12. These blocking pulses now receive a according to the invention longer duration than the return times of the deflection circuits 4, 6 of the scanning tube, because their synchronization pulses in the deforming members 37 and 38 experience a shortening.

These deformation members 37 and 38 can be designed differently. There are already Circuits known which convert pulses of a given duration into pulses of shorter duration. An expedient embodiment for such a deformation member 37 is shown in FIG. It contains four resistively coupled tubes 39, 41, 42 and 43 are connected to the input circuit via supply line 2 (Fig. 1) of the tube 39 via a coupling capacitor 44 and a relatively high resistor 46. The input circle of the Tube 39 also contains a high resistance 47 between grid and cathode. In parallel is a capacitor 48 of relatively high capacity. The circle with the resistor 47 and the capacitor 48 serves as an integration circuit, so that the rectangular pulse 40 is given the shape 49. Of the Reshaped pulse 49 is transmitted through the tube at that indicated by dashed line 51 Cut off level and therefore causes the pulse 52 in the output of the tube 39. Here is as provided, of course, that the grid of the tube 39 and the grids of the other tubes in the Circles that are supposed to cut off pulses in a known manner with the required negative bias are provided.

The tube 41 only serves to reverse the polarity of the pulse 52; occurs in their exit hence the pulse 53 on. This impulse is given to a differentiation circle, the one Coupling capacitor 54 of relatively very low capacitance and a grid resistor 56 of correspondingly low resistance. The impulse that arises at the entrance of the tube 42, has the shape 57. This is then indicated by the dotted line 58 by means of the tube 42 Height cut off, so that at the input circle of the tube 43 a pulse of the shape 59 arrives. This tube 43 intersects the pulse 59 in that indicated by the dashed line 61 Height and thus delivers the desired rectangular pulse 62, which is now narrower than that Input pulse 40. The effect of the circuit 2 is explained again by Fig. 3, in which the individual conversion stages of the impulse with. the same numbers as in Fig. 2 are indicated.

Figs. 4 a to 4e now show a comparison between the corresponding lengths of the synchronization pulses, the ramp-down times and the blocking pulses. In Fig. 4 the synchronizing or Control pulses 62 that arise in the output circuit of the pulse converter 37 are shown again. Of the In contrast to Fig. 2, pulse 62 appears here with slightly sloping edges because it is practical it is impossible to produce or transmit a perfect square pulse.

Fig. 4b shows the sawtooth curve of the current delivered by and through the deflection device the line deflection coils of the transmitter tube 7 flows. After the sync pulse has elapsed, a certain. Time until the cathode ray of the tube 7 has finished its return and the scanning of the new line begins. The reasons for this lie in the time constant caused by the inductance and the different capacities of the deflection circuit is given, also in the delay in the transmission via the line connecting the deflection circuit to the coils. Therefore must be the duration the synchronization pulses 62 for the transmitter tube be shorter than the duration of the blocking pulses Transmitter tube, so that the blocking is over the entire return period of the beam in the transmitter tube extends.

The impulses 40, which are unchanged in duration, are now used as blocking impulses for the transmitter tube are shown at the entrance of Figs. 2 and 3 and also in Fig. 4c. These impulses have

As shown above, a longer duration than the synchronization pulses, which is also sufficient to completely suppress the cathode ray during the return movement. In practice, the blocking pulse that occurs at the control grid 12 of the transmitter tube has the shape of Fig. 4d, because the different capacitances cause a certain deformation of the flanks.
The blocking pulses 60, which are given their shape in the device 27 of FIG. 1 and are transmitted to the television receiver in order to block the cathode ray of the receiver tube during the line retrace, are shown in FIG. 4ε. These impulses have a somewhat longer duration than the blocking impulses in Fig. 4d, so that disturbances that occur when blocking the cathode ray of the transmitter tube cannot be noticeable on the fluorescent screen of the receiver tube. If the blocking pulses at the transmitter and the receiver were of the same length, the interference due to the suppression of the cathode ray in the transmitter tube would make itself felt to some extent in the receiver, because there is a certain delay in the transmission of the blocking pulses and the two blocking times do not exactly coincide .

The considerations made relate to both the line train synchronizing and blocking pulses as well as the line pulses. This can be seen from Fig. 5. Here are the synchronizing and blocking pulses shown in more detail. A line train pulse for the transmitter tube 7 is shown in 63 specified. This pulse is transmitted through the line 3 (Fig. 1) via the pulse converter 38 to the Zeilenzugablenkkreis 6 led. The line sync pulses 62 for the transmitter tube according to the Fig. 2, 3 and 4 a are indicated in the second row of Fig. 5 with vertical flanks to the Simplify drawing. One of the line train inhibit pulses transmitted by amplifier 36 to the Grid 12 given is superimposed with the line lock pulses 40 and drawn in 64. He is longer than the line train pulse 63, as can be seen by comparing the curves. In this picture is the difference in the length of the line sync pulses 62 and the line lock pulses 40 not clearly stated.

The combined line and line train lock impulses intended for the receiver are given to the transmitter 26 via the line 8 and the image intensifier 24 as shown in Fig for the cathode ray of the receiver tube has an even longer duration than the blocking pulse 64 for the transmitter tube. The complete signal with which the carrier of the transmitter 26 is modulated is given below in Fig 66, the line and interline synchronization pulses, which are set at the peaks of the blocking pulses, denoted by 67 and 68. The image signals 69 appear between the blocking pulses 60. The black level of the image is at the point marked 71 at the peak of the blocking pulses This is sufficient for beam suppression. The synchronization pulses 67 and 68 therefore protrude in a known manner beyond the black level.

It is advisable that the blocking pulses for the transmitter tube begin a little earlier than the synchronization pulses for the transmitter tube. It is also useful that the blocking signals for the receiver tube begin a little earlier than the blocking signals for the transmitter tube, as indicated in Fig. 4a to 4e for the line sync and line lock pulses. In order to have one pulse begin earlier than the other, any suitable delay element, transmission line or the like can be used, e.g. B. one can switch delay elements 30 and 40 ₀ (Fig. 1) in the channels for the line and line train deflection in order to delay the synchronization pulses by a certain amount. Such a delay circuit should also be included in the amplifier 36 in order to delay the blocking pulses for the tube 7 by a small amount, while the blocking pulses for the receiver are transmitted without any significant delay.

The receiver according to FIG. 6 shows in a known manner a cathode ray tube 72 with line and line extension deflection coils. The image, blocking and synchronizing signals, shown in the lower part of Fig. 5, are given by the receiving circuit 74 via the amplifier 76 to the control grid 73 of the cathode ray tube. The same signal is also fed to a separating circuit 77 , in which the image signals are first separated and the line and line train synchronization pulses are also separated from one another and amplified. These control the corresponding deflection circuits 78 and 79.

When applying the invention, all disturbances remain in the transmitter due to the return of the Cathode ray can arise without any influence on the image reproduction on the fluorescent screen 84 of the recipient.

Claims (4)

PATENT CLAIMS: 1. Television transmission device with image capture tube with scanning cathode ray, thereby characterized in that the blocking pulses for the scanning beam of the transmitter tube have a longer duration have as the beam return, such that the beam return time falls into the blocking time. 2. Device according to claim 1, characterized in that that generated by a generator pulses, preferably by one of four resistively coupled tubes Circle are transformed into pulses of shorter duration and these are the deflectors for control the scanning tube while the unchanged generator pulses act as blocking pulses for serve to suppress the beam from the transmitter tube. 3. Device according to claims 1 and 2, characterized in that the receiver transmitted, the beam of the receiving tube suppressing blocking pulses have a longer duration than the blocking pulses for the beam the transmitter tube. 4. Device according to claims 1 to 3, characterized in that, for. B. by Interposition of delay elements in the circles for the line and line extension deflection and for the blocking pulses of the transmitter tube, the blocking pulses of the receiver tube start earlier than the corresponding ones Pulses from the transmitter tube. Cited pamphlets: "Telefunken-Zeitung", 1936, No. 74, pp. 36 to 42; "ENT", 1936, issue 4, pp. 142 to 144; British Patent No. 422,658. For this purpose 2 sheets of drawings I 509575 11.55