DE1125478B - Television receiver - Google Patents

Description

GERMAN

PATENT OFFICE

Z 2877 Vnia / Ha ¹

REGISTRATION DATE: AUGUST 16, 1952

NOTICE
THE REGISTRATION
AND ISSUE OF THE
EDITORIAL: MARCH 15, 1962

The invention relates to television receivers for receiving television signals which are composed of picture signal components and sync signal components, the amplitude of which is greater than the maximum amplitude of the image signal components, with means for separating the sync pulses, for controlling the deflection signals, for phase synchronization deflection and automatic gain control.

In known television receivers for the separation of the sync signals, the generation of Deflection signals, the phase comparison to derive a control voltage for the automatic frequency control, the frequency control of the deflection devices and the derivation of a control DC voltage for automatic Gain control of the receiver usually uses special electron tube stages. As a result, besides a very complicated receiver circuit, particular problems arise, such as e.g. B. Adjustment, adaptation, etc., which can make stable work of the receiver very difficult.

The object of the invention is to provide an improved television receiver of the above type, which in simplified circuit structure enables greater operational stability.

According to the invention, this is achieved by a single beam deflection tube performing the functions mentioned with an elongated cathode for emitting a flat electron beam, with several collecting anodes, a collecting anode and deflection electrodes to which the video signals are placed are.

The invention will now be explained in more detail with reference to the drawing. It shows

Fig. 1 shows the circuit of a television receiver with the arrangement according to the invention,

Fig. 2 is a perspective view showing the arrangement of certain parts of a receiver shown in Fig. 1 used cathode ray tube.

The term "television signal" means the modulated carrier received during the The term "video signal" is used for the modulation content after rectification.

In operation, the positive video signals with their DC voltage components are taken from the output of the first video amplifier 7 is applied to the deflection plate 24 via a voltage divider which is derived from the There is a series connection of the two resistors 33 and 34. For the AC components of the No voltage division is required for video signals. The resistor 33 can therefore be used for the signal frequency television receiver

Applicant:

Zenith Radio Corporation,
Chicago, 111. (V. St. A.)

Representative:

Dr.-Ing. H. Ruschke, Berlin-Friedenau, Lauterstr. 37, and Dipl.-Ing. K. Grentzenberg, Munich 27,

Patent attorneys

John G. Spracklen, Chicago, 111. (V. St. Α.),
has been named as the inventor

zen be bridged by the capacitor 61. The deflection plates 23 and 24 are prestressed in such a way that the beam passing through the opening 14 of the accelerating electrode 15 strikes a part of the collecting anode 16 which is impermeable to electrons, e.g. the part of the anode next to the openings, in greater proximity to the deflecting electrode 23. The application of the positive video signals to the deflection electrode 24 causes the beam to be transversely deflected in accordance with the instantaneous signal amplitude. The operating voltages of the individual electrodes are set so that various longitudinal parts of the beam are completely deflected into the opening 17 or partially into the opening 18 of the collecting anode 16 in response to the synchronous pulses of the applied video signals, while the electron beam is completely deflected by the anode 16 during the image signal intervals is caught. As a result, a current can flow to the collecting anodes 19, 20, 21 and 22 only during the sync pulse intervals. Since the collecting anode 19 is connected to a positive bias voltage B + via the resistor 35, voltage pulses corresponding to the sync pulses of the applied video signal arise at the resistor 35. These pulses are integrated by the circuit 36 and serve as control pulses for the deflection circuit 37. In other words, the Collecting anode 19 serves only to deliver image frequency pulses for synchronizing the image deflection generator. The left system of

209 519/201

Cathode ray tube 12 acts as a line frequency generator. Sinusoidal ones in antiphase Voltages are applied to the baffles 29 and 30 through winding 41 and capacitor 47, which are tuned to the line frequency and which are in series with the line deflection coil 40 switched winding 52 are supplied. Thus, the beam is in the left system of the cathode ray tube 12 alternately on the anodes 27 and

28 impinge, so that a voltage across the resistor 53 occurs with a rectangular course. This square wave voltage is generated by the capacitor 54 and resistor 55 differentiated, and the resulting positive or negative pulses become used to control the line deflection circuit 39.

At the same time, the collecting anode 20 or 21 in the right system of the cathode ray tube 12 is pressed by the anti-phase, sinusoidal voltages supplied to the deflection plates 30 and 29. As has already been stated, the current flowing to the collecting anodes 20 and 21 is limited to the synchronous signal intervals due to the shape and arrangement of the collecting anode 16. Furthermore, the current to the collecting anodes 20 and 21 is dependent on the instantaneous voltage on these electrodes during the synchronous signal intervals. The anti-phase, sinusoidal voltages supplied via the winding 41 and the capacitor 47 serve as comparison signals for the phase comparison. If the phase of the comparison signals matches the incoming line synchronization pulses exactly, the voltages present at the anodes 20 and 21 at the time of the arrival of each -Ί synchronization pulse are the same; there is no DC voltage difference between these anodes. If, however, the comparison signals and the incoming line synchronization pulses are not in phase, these instantaneous voltages at the two collecting anodes 20 and 21 are different during the arrival of each line synchronization pulse, so that there is a voltage difference between them. Since each of these collecting anodes is connected to the baffle 30 or

29 in the left system of the cathode ray tube 12 is directly connected, the beam in the left System accelerated or decelerated in its course from the anode 27 to the anode 28 and back. Consequently the timing of the positive and negative half-waves of the resistor 53 changes Square-wave voltage and thus the phase position of the line deflection circuit 39 supplied Control pulses obtained by differentiating the square wave voltage. To get the desired To achieve automatic frequency control, it is important that a state in which the comparison signals compared to the incoming synchronization pulses lag, leading to an increase in the frequency of the deflection device in the left system of the cathode ray tube 12 and thus the line deflection circuit 39 and the feedback loop 52, 41 leads. This work is due to the common direct connections for the sinusoidal comparison signals and the DC voltage for the automatic Frequency control from the collecting electrodes 20 and 21 to the deflector plate 30 and 29, respectively, is guaranteed. at An unsuitable phase relationship between the comparison signals and the control pulses can do this Tear off the oscillation of the line deflection circuit 39.

This state can be eliminated solely by reversing the polarity of the terminal connections of the feedback winding 52 or 41 or, if special leads are provided for the anodes 27 and 28, by reversing the connection connections of these two anodes. The actual entrainment effect is automatically guaranteed for the state in which the oscillation begins.
Since the opening 17 in the collecting anode 16 is delimited in a certain way, the deflection of the beam beyond the opening causes it to be caught by the collecting anode 16. Thus, foreign interference pulses, the amplitude of which is generally greater than that of the synchronizing pulses of the video signal, do not reach the collecting anodes 19, 20, and 21. In this way, the deviation from synchronism caused by foreign pulse interference is almost avoided. If video signals occur on the deflection plate 24, extraneous interference pulses, the amplitude of which is greater than that of the synchronizing signals, result in a beam deflection beyond the opening 17. These glitches are therefore not transmitted to the output circuits of the collecting anodes 19, 20 and 21, and it is approximated

as freedom from interference achieved.

The operation of the automatic gain control will now be explained. A scanning voltage, which consists of positive line return pulses or other suitable pulses which have a certain phase for the line scanning of the image display device 6, passes from the line deflection circuit 39 to the collecting anode 22 via the capacitor 56 and the resistor 57. The collecting anode 22 is of electrons through the Opening 18. Of the collecting anode 16 only reached when it is positive. Thus, a negative pulse occurs at the resistor 57 when the synchronous signal components of the video signals coincide with the positive control signal fed to the collecting anode 22

on. This pulse is passed through resistor 59 and the capacitor 60 integrated, so that a negative DC voltage arises on the line 58, which serves as a control voltage for the automatic gain control. They are in a state of equilibrium

Deflection electrodes 23, 24 biased so that through the tips of the synchronizing signals of the electron beam centered on the long vertical edge of the opening 18 will. When the signal amplitude increases, the electron beam is deflected further to the right, see above that the electron flow to the collecting anode 22 increases. This leads to an increase in the receiving circuit 2, 3 and 4 pushed through the feed line 58 Control voltage. In this way the gain of these circuits is reduced and the

The amplitude of the input character applied to the deflector plate 24 is set back to the equilibrium value.

On the other hand, if the signal amplitude decreases temporarily, the negative gain control voltage decreases, and the gain in the receiving circuits increases, so that the equilibrium is restored. The interference pulses occurring during the image signal intervals affect the Control voltage is not applied because the collecting anode 22

during these intervals by the deflection circuit 39 incoming key voltage is kept at or below the cathode voltage. Further deliver even during the synchronic

valle occurring glitches, even if they have sufficiently large amplitude, due to the limited opening 18, no contribution to the control voltage. As a result, in the arrangement according to the invention, a greater freedom from noise than in the known automatic gain control devices can be achieved, the grid-controlled tubes for Use gain control voltage.

Since it is used for the transmission of the synchronizing signals from the collecting anode 19 to the image deflection circuit 37 it is desired that the synchronizing signals have a constant amplitude, it is preferable that the peaks of the sync signal components of the applied video signals a deflection of the upper one Cause beam part completely in the opening 17. At the same time, the synchronous signal components effect The supplied video signals are only partially distracted due to the automatic gain control of the lower part of the electron beam into the opening 18. Through the overlapping or parallel The opening 17, which is offset relative to the opening 18 in relation to the longitudinal direction of the cathode, is guaranteed, that when the state of equilibrium is restored by the automatic gain control at the collecting anode 19, synchronization pulses of constant amplitude for the image deflection circuit 37 are obtained and that the limiting level of the synchronizing signal separation circuit is automatically set will.

When using the receiver for the first time or during the switching processes in the transmission channels the receiver circuits are set to full amplification. Is under these conditions the signal to which the receiver is tuned is strong, so the automatic gain control device could become ineffective if special precautions were not taken for the If a negative control voltage arises, ensure the automatic gain control. thats why the opening 18 in the transverse direction is substantially wider than the opening 17. Such a construction increases at least partially the susceptibility of the automatic gain control device to external, glitches occurring during the sync signal intervals. The length of the opening is advantageous parallel to the longitudinal direction of the cathode 13 different to the ineffectiveness of the receiver during initial commissioning or while switching operations are carried out in transmission channels to avoid, while at the same time the freedom from interference during the synchronous signal intervals is at least partially achieved.

The different length of the opening 18 is achieved by joining two rectangular ones Parts of different lengths reached parallel to the longitudinal direction of the cathode. The longer part of the opening is effective with a smaller deflection of the electron beam. Such a shape of the opening 18 always allows a minimum emission current to flow to the collecting anode 22 in the case of strong characters when the Receiver is first put into operation, so that immediately a negative control voltage for the automatic Gain control is obtained to reduce the gain in the receiving circuits and to establish the state of equilibrium. However, the opening 18 has a constant length in parallel to the longitudinal direction of the cathode, the automatic gain control device is free from interference completely equivalent to that achieved with known systems in commercially available receivers.

The circuit according to the invention requires only a very small number of switching elements, and the cathode ray tube 12 can be constructed entirely from simply stamped metal plates. As a result the staggered arrangement of the receiving surfaces of the anodes becomes the exact limiting level for the sync signal separation circuit for all receiver input levels , automatically adjusted, this advantageous property without the use of additional Switching elements is achieved. In addition, this is a result of deviations or incorrect settings inaccurate synchronization signal separation caused by the automatic gain control circuit, as is observed with common receivers, impossible. Another benefit is there in that the position of the reproduced television picture on the screen of the picture display device almost insensitive to the setting of the automatic frequency control circuit within the Take away area is.

Although the desired operating characteristics in the right system of the cathode ray tube 12 by the Anode 16 arranged in front of the collecting anodes 19, 20, 21 and 22 and provided with openings is achieved the same effect can also be achieved by the design of these electrodes in terms of their Size, their shape and their spatial arrangement corresponding to the openings 17, 18 achieved thereby be that the anodes 19, 20, 21, 22 an anode to collect the not collected by them Space electrons follows.

The receiver shown and described in connection with FIGS. 1 and 2 is in the cathode ray tube 12 a separate collecting anode for generating image sync pulses which are sent to the image deflection circuit are applied. But it is also possible to use the desired image sync pulses by an integration circuit between the center tap 42 of the winding 41 and earth. In this way, the output currents of the collecting anodes 20 and 21 are used to achieve the desired To win image sync pulses, which are then used to control the image deflection circuit. This modification of the circuit can be a considerable simplification of the same mode of operation Reach tube structure.

Claims (7)

PATENT CLAIMS: 1. Television receiver for the reception of television signals, which consist of image signal components and synchronous signal components, the amplitude of which is greater than the maximum amplitude of the image signal components, with devices for separating the synchronizing pulses, for controlling the deflection signals, for phase synchronization of the deflection and for automatic gain control, characterized by a single beam deflection tube (12) which performs these functions and has an elongated cathode (13) for emitting a sheet-like electron beam, with several collecting anodes (19 to 22J, a collecting anode (16) and deflection electrodes (23, 24) to which the video signals are applied. 2. Television receiver according to claim 1, characterized in that for the separation of the Synchronizing pulses from the video signal the collecting anode (16) has an opening (17) behind the the collecting anodes (19, 20, 21) are arranged such that the beam during the sync pulse intervals through the opening (17) on the collecting anodes (19, 20, 21) meets during the Image signal intervals, however, is completely absorbed by the collecting anode (16). 3. Television receiver according to claim 1 or 2, characterized in that the collecting anodes (20, 21) a comparison signal with a fixed phase relationship to the horizontal deflection signals is placed, from the phase deviation of which to the horizontal sync pulses a rule voltage for establishing phase synchronization of the deflection signals with the horizontal sync pulses is derived. 4. Television receiver according to claim 3, characterized in that the collecting anodes antiphase comparison signals are placed. 5. Television receiver according to claim 3 or 4, characterized in that in the beam deflection tube (12) further anodes (27, 28) and further deflection electrodes (29, 30) are provided which are connected to the collecting anodes (20, 21), and that the control voltage of one of the anodes (27 or 28) is removed. 6. Television receiver according to one of claims 1 to 5, characterized in that for A further collecting anode (19) is provided for the image frequency synchronization in the beam deflection tube (12) which is coupled to the frame rate deflection system (37) of the receiver. 7. Television receiver according to one of claims 1 to 6, characterized in that for automatic gain control in the beam deflection tube (12) another collecting anode (22) is arranged behind an opening (18) in the collecting anode (16) that the over the Edge of the opening (18) also deflected part of the electron beam depending on its Deflection amplitude generated a control voltage taken from the collecting anode (22). Considered publications:
German patent specification No. 816 271. 1 sheet of drawings © 209 519/201 3.62