DE975532C - Voltage comparison indicator tubes - Google Patents

Description

Voltage comparison indicator tube In the main patent 950 946, voltage comparison indicator tubes are described in which, by crossing the electrodes connected to the voltages to be compared, luminous pattern parts immigrating into the symmetry position in opposite directions indicate a voltage difference.

In order to achieve a higher display sensitivity and special The invention proposes display effects, the voltage comparison display tube described in the main patent equipped with suitable amplifier systems. Voltage comparison indicators are already available known with amplification systems. In these known arrangements, however, the Amplifier systems stacked one above the other. These known arrangements all of which are caused by the inconstant tube properties, such as cathode temperature, Heating capacity. Contact potential of the electrodes, mechanical system change through Thermal expansion, unstable structure and the like, caused sources of error.

To eliminate these sources of error, the invention proposes a Voltage comparison indicator tube with two connected to the voltages to be compared Electrodes, according to the main patent 95o 9.46 by crossing these electrodes in opposite directions Luminous pattern parts immigrating into the symmetrical position, voltage equality and in opposite directions emigrating light pattern parts indicate voltage diversity before that everyone of the crossed electrodes one symmetrical to the common cathode of an amplifier system arranged anode of the same height is assigned. These anodes, the following are referred to as control anodes, are preferably symmetrical to an in the plane lying on the cathode axis. You will be in the operating state of the display tube expediently connected to the same voltage source via the same external resistance. The control anodes can be along the axial cathode, most advantageously below it of the display system, either one on top of the other, but preferably in be arranged the same height around the cathode circumference. Also a symmetrical arrangement the control anodes around the part of the cathode which is not effective in the display system, e.g. B. in the case of a non-centric display system structure, is provided by the invention. In the discharge space of these control anodes are now electrodes, so-called control electrodes, in the form of metal sheets, struts, grids and the like control the current flowing through the control anodes. On at least two of these electrodes the voltages to be compared are applied. The arrangement of the control anodes and this control electrode is made so that if the voltage equals the comparison voltages The same currents flow in the control anodes, if there is a difference in voltage, unequal currents. The simplest way to achieve this is that these control electrodes have the same shape have and are arranged symmetrically to a plane which is also a plane of symmetry to the control anodes. To increase the control sensitivity of these electrodes they can be attached in the space charge field of a lattice. In the discharge space of the Control anodes can now be fitted with additional controllable electrodes. The order of these electrodes, hereinafter referred to as symmetrically controlling electrodes is made so that when there is a change in the voltages applied to them the current in the two control anodes is influenced in exactly the same way.

These control electrodes can in addition to their intended control function also other functions, e.g. B. the generation of a space charge, the setting a desired current level of the control anodes and the like. Continues to see the invention suggests that it is also preferably at a positive potential Trapping electrodes inside or outside the actual discharge space of the Control anodes. The purpose of these is to prevent disruptive streams of electrons from the Record discharge space and the current level or voltage level of the control anodes and to influence the control action of the control electrodes in the desired manner.

Fig. I shows an embodiment of the amplifier or control systems. The round-profiled cathode i indicated in FIG. I can be used here, as with all of them the following exemplary embodiments, also have a different profile section .. As an advantageous profile with regard to the favorable utilization of the cathode emission an oval cut shape is considered. Ask in the same way. also those in the Figures indicated profile sections of the other electrodes of the system only exemplary embodiments The cathode i is surrounded by two grids only partially encompassing the cathode and 3 surrounded. The equivalent stresses are applied to these grids. The geometrical The same control anodes arranged symmetrically to the system structure are given the reference numbers 1z and 13. The grids z, 3 can, as in Fig. I and the following Figures for representation comes in the usual form from a holding strut be executed wound helix. A mechanically more stable and symmetrical one System structure and thus a better electrical symmetry of the two systems but achieved through the use of plate grids. The plate grids can be made from a straight or curved piece of sheet metal with somehow profiled cutouts, z. B. circular holes exist. The invention prefers narrow, strip-like cutouts.

The embodiment of Fig. A differs from that of the Fig. I in that a further control electrode is introduced into the discharge arrangement will. This grid 8 takes on the function of a symmetrical control electrode. The number of symmetrically acting control electrodes can be determined by another, the cathode enclosing grids are expanded .. The invention provides for these grids as well in the space between the comparison control electrodes and the cathode.

As stated above, plate grids are made with strip-shaped panels Excerpts applied, so can be in addition to an increased symmetry of the systems possibly also a more favorable mutual penetration ratio of the successive ones Achieve control electrodes. The arrangement is expediently made so that that the direction of the strip sections intersect at an angle of about 9o °. The plate grids can also be combined with the usual spiral grids arrange.

In the following examples of embodiments of the invention are consistently indicated in the figures grids, in which a helix on a or several struts is wound. The invention also provides for it in its place other types of grilles, e.g. B. to attach the aforementioned plate grids.

In the further exemplary embodiments, the controllability of struts, sheets and the like, which are introduced into the discharge space, use made. The use of such control electrodes is advantageous because they are simple Means can be produced and with regard to the required electrical symmetry of the discharge spaces have a high mechanical stability and with great accuracy in the system can be attached. In Fig. 3 is such a Embodiment shown in which the symmetrically acting control electrodes 8 and 9 in the form of preferably round struts within those surrounding the cathode Comparison control grids 2 and 3 are located. The struts 8 and 9 are electrically connected to each other connected or form a unit. This can e.g. B. can be achieved in that a strut is bent in the shape of a hairpin and is inserted into the system according to FIG. 3 is introduced.

In the embodiment of FIG. 4, the order of the grid functions is reversed. Here the display control electrodes are represented by two round struts that are symmetrical to the rest of the electrode system and within the symmetrically acting control grid 8. The reference numerals 12 and 13 denote the control anodes. The arrangement of the comparison control electrodes within the space charge effect of the grid 8, which is designed here as a four-part grid, for example to increase the space charge effect and mechanical stability, results in a great control sensitivity of the struts 2 and 3 Control organs can also be expanded. An example of this type is shown in FIG. The comparison control struts 2 and 3 and 4 and 5 are electrically connected or form a unit such that these units have the shape of a hairpin. The cathode is marked with the number i, the symmetrically effective control electrode with 8 and the control anodes with the numbers i2 and 13 . In Fig. 6 an embodiment is shown in which two separate, symmetrically effective control electrodes, the electrically interconnected struts 9 and io and the grid 8 are effective. The other reference numbers are the same as in Fig. 5.If control electrodes are operated with voltages that are positive with respect to the cathode and if the lowest possible control powers are desired, the mutual arrangement can be made so that the electrodes in question are provided by control electrodes placed in front of them or by electrodes of another type fully or partially covered. An exemplary embodiment for this is shown in FIG. Here the electrodes 8, 9, io, ii preferably represent the symmetrically effective control electrode. The struts of the comparison electrodes 2 and 3 are placed in the electron shadow of the struts 8, 9, io, ii. For the electron flow of the grids 2 and 3 with a positive operating voltage, only the grid wires or grid plates that are in the discharge channel are effective.

In the structural design of the present amplifier or control systems, the special arrangement of the electrodes of the display system, which is generally located in the upper cathode part, can also be taken into account. This results in arrangements with a simple structure. A special embodiment of this type is shown in FIG. The discharge space consists of a cathode i, the two comparison control electrodes 3 and z, e.g. B. in the form of round struts, the symmetrically acting control electrode 8 and the two control anodes 12 and 13. The peculiarity of this arrangement is that the two control anodes 12 and 13 are extended so that they protrude into the upper display system and there at the same time are effective as display electrodes for the lighting system. The two comparison control electrodes 2 and 3 can also have a shape other than that of a round strut, e.g. B. according to Fig. 9, have the shape of a baffle. This results in a greater concentration of the electron beam passing over to the anode and thus an increased controllability of these comparison electrodes. The control anodes 12 and 13 or the display electrodes of the lighting system consist of round struts according to FIGS. 8 and 9. FIG. 10 shows an exemplary embodiment for two control anodes which consist of pieces of sheet metal. The piece of sheet metal is shaped so that it takes over the function of the display electrodes in the display system in a suitable manner. The arrangement of this special type of system can be expanded according to the embodiments i to 6 by further control electrodes. An exemplary embodiment for this is shown in FIG. A further such electrode 9 was added to the symmetrically acting control electrode 8. The electrode can simultaneously fulfill the function of generating a space charge. This increases the control sensitivity.

All previously mentioned embodiments were characterized by that the discharge spaces of the control anodes are influenced separately, d. h., the The control electrode of a certain discharge space has no or no essential one Influence on another discharge space. The relatively small impact on the mutual discharge systems of the embodiments indicated in FIGS. 8, 9, i o, i i are not considered here. Some exemplary embodiments are now shown below indicated in which the discharge space of the control anodes is more or less closed Unity forms. Each control electrode of the common discharge space acts here on each control anode. In a preferred embodiment, the invention provides for such System arrangements provide that the comparison control electrodes less the function of a Amplification or weakening of the electron flow emanating from the cathode as rather a suitable distribution of this current to the individual control anodes exercise. The advantage of such an embodiment is that the desired equal current distribution in the control anodes with the zero voltage difference of the the voltage applied to the comparison control anodes is largely independent of the cathode properties and the effective cortex surface. This is in view of the required The symmetry condition and the temporal constancy of this condition are advantageous. aside from that results in the Advantage that the display process during the voting or the adjustment process is more symmetrical. An embodiment of this Art is shown in FIG. The cathode is from the comparison control electrodes 2, 3 and the symmetrically effective control electrode, a grid 8, surrounded. as Control anodes are used by two round struts 12 and 13. They are also display organs for the equivalent stress in the display system by extending it into this system are. A catch plate 14 is attached as a further electrode. This catch plate will preferably applied to a positive voltage and has the purpose of increasing the current level to increase the currents passing over to the control anodes and possibly interfering electron currents of the discharge space. The catch plate 1.4 can be attached to a during the adjustment process changing positive tension. In this case, the catch plate works also affects the size of the current passed to the control anode. Corresponding The symmetrical arrangement of the catch plate has this effect on the control anodes also symmetrical. Under these operating conditions, the catch plate can be used as a symmetrically acting control electrode can be understood. In a modified embodiment 13, the two control anodes can also be made from sheet metal pieces 12 and 13 be made. Here, too, the control anodes are suitably shaped at the same time as comparison electrodes in the display system. A collecting electrode can be added to the system, preferably in the form of a round strut 14 are added. About the connection options the operating voltage on this catch plate, the same statements apply as they with respect to the capture bleach 14 of FIG. 14 is one embodiment shown in which the comparison control electrodes are in the form of baffles are trained. These baffles can also have a curved shape or a have mutually inclined position as shown in FIG. The system is here corresponding to the example of FIG. 13, a collecting electrode 14 in the form of a round one Strut added. The special position of the two control anodes shown in FIG 12 and 13 are preferred in this embodiment.

The following are examples of applications of the display tubes given with the amplifier devices according to the invention. As the main area of application is the display of adjustment or tuning processes of electrical arrangements considered.

Electrical arrangements should include, for example, electrical measuring devices, especially those that make use of the principle of the electrical measuring bridge, Receiving devices for electrical vibrations and the like are understood. To this The purpose is the asymmetrical control electrodes of the amplifier arrangement of the display tube connected to such voltages of the electrical arrangement that are close the exact adjustment or adjustment position in a characteristic, recognizable manner change. Such switching points of the electrical arrangement are preferred which the tensions either against the ground reference point or against one or more referring switching points in the correct balancing or tuning point the voltage difference Zero and a corresponding voltage difference in the detuned or not balanced state exhibit. The symmetrically acting control electrodes of the amplifier system can one that cannot be changed during the tuning or adjustment process Voltage (e.g. at the ground point of the device or at the cathode point of the display tube) or to a voltage that changes during the adjustment or tuning process be created. In the second case, this allows special display effects to be achieved, or a multiple adjustment or multiple adjustment can be carried out.

The invention contemplates the use of the display tube as an indicator for the tuning state of combined AM-F: NI receivers as particularly advantageous. In the usual receivers of this type there are switching points or voltages that are change according to the above. Voltages or switching points of this type are z. B. the differential voltage of an FM discriminator according to F o s t e r-S e e1 y or a ratio rectifier, the total voltage of a ratio rectifier, the grid circle of a so-called limiter stage of an FM receiver, the control voltage or the low frequency demodulator stage of the AM part of a receiver or a AM receiver and the like. The circuit arrangements should be based on the drawings explained.

Fig.16 shows an embodiment for the circuit of the tube for Display of the tuning status of receivers for combined frequency and amplitude modulation or only for FM or AM. The numbers in FIG. 16 and in the following exemplary embodiments mean: 4o the display grid, 41 the cathode, .12 and 43 the asymmetrically acting Electrodes of the amplifier system, 44 the symmetrically acting electrode of the amplifier system, 45, 46 the control status, 47, 48 the display electrodes of the lighting system and 49 of the Luminescent screen. The control anodes 45 and 46 are more preferred in the exemplary embodiments Way connected to a potentiometer. In the place of the potentiometer you can also, as indicated in the following exemplary embodiments, two separate ones Resistances are used. The center tap of the potentiometer 2o is with a positive voltage with respect to the cathode, preferably with the fluorescent screen voltage tied together. With the potentiometer it is possible to determine manufacturing inaccuracies of the display tube, which have an effect in the sense of a negative report, to compensate. The cathode 41 can connected to the ground point either directly or via a cathode resistor will. As display voltages are generally applied will the change during the tuning process so that on the control electrodes opposite both positive and negative voltage values occur at the cathode, results when using the cathode resistance the advantage that on the control electrodes There is little or no power loss with positive voltage amplitudes. The digits 1 ', 2' and 3 'represent suitable switching points for taking the display voltage an FM discriminator, in the present case an FM ratio rectifier For example, at switching point 51, the negative total voltage, at switching point 52 the positive total voltage and at switching point 53 the differential voltage decrease. The switching point 54 is located in the circuit of a conventional IF rectifier for demodulating the AM oscillation. The symmetrically acting control electrode 44 can expediently with the interposition of a resistor with the help of a Switch to switching point i 'for FM reception and to switching point for AM reception 54 are placed. This switch can be saved if the electrode 44, as indicated in the switching example 16, via the resistor 57 to the switching point i 'and via the resistor 12' to the switching point q. ' connected is. One asymmetrical acting control electrode, in embodiment 16 the electrode 42, is with the Ground point, the other control electrode 43 via a resistor 56 to the point 53 of the ratio rectifier connected. By using a switch 32, which is closed with AM reception, symmetry errors in the control systems, which may lead to picture disturbances in the display, switch off. With With the help of switch 31, the cathode resistor can be closed during AM reception. This results in a greater AM display sensitivity. Will be next to the switch 32 if a further switch 33 is actuated for AM reception, another switch results Increase in display sensitivity for AM reception. In the lead of the electrode 42 can be a further resistor 17, which preferably has the same resistance value like resistor 56, can be attached. This will keep the tube open during operation also loaded symmetrically with regard to the external resistance. Any changes in contact potential that occur the control electrodes during the life of the tube will be more symmetrical Way influenced.

A somewhat modified embodiment is shown in FIG. The two control electrodes 42 and 43 are opposite to the exemplary embodiment 16 with two equal resistors 18 and i9 with the switching point 51 of the ratio rectifier tied together. The switching point 52 is connected to the electrode 43 and the electrode 42 the resistor 17 is connected to the grounding point. The resistors 17 and 56 have preferably the same values. In this circuit, the electrodes 42 and 43 negatively biased when tuning to an FM carrier. So the display is in influenced symmetrically. The advantage of this arrangement over the arrangement of the embodiment 16 is that the control electrodes accordingly the thickness of the incident beam are negatively pre-stressed and thus no or a small voltage drop across resistor 56 for positive differential voltage amplitudes he follows. This is particularly beneficial when the differential voltages take on very great values. The cathode resistor 16 can thus be superfluous, The electrode 44 is in a known manner via the resistor 55 with the switching point 54 of the IF rectifier connected. Modifying the embodiment 16 will be in this example the control anodes 45 and 46 with a fixed resistor 22 and one variable resistor 21 connected, Another embodiment is shown in FIG 18 indicated. It differs from that of FIGS. 16 and 17 in that the symmetrical grounding of the ratio rectifier takes place via a resistor 21. In order not to reduce the usable .NF voltage, the resistance can be operated with a Capacitor 24 can be bridged. The switching point 59 of the ratio rectifier is connected to the electrode 43, the switching point 53 in the usual way via the resistor 56 connected to electrode 42. In the case of a positive one effective at the electrode 42 Display voltage arises around resistor 23, corresponding to that of the electrode 42 absorbed current, a voltage drop. The switching point 59 and thus the electrode 43 thereby receive a negative voltage with respect to the ground point. It surrenders thereby an increased display sensitivity and a display curve that is more symmetrical runs to the tuning center.

Another embodiment is shown in FIG The discriminator is grounded via a voltage divider 25. The Andes Switch points 6o and 61 have display voltages occurring in relation to the ground the characteristic of the differential voltage occurring across the ratio rectifier. However, their phase is offset from one another by 1.90 °. The occurring Display voltages are applied across resistors 56 and 17 to the deflection electrodes 42 and 43 connected. A part of the voltage divider can be used here again to increase the To reduce the drop in usable LF voltage, bridged with a capacitor 24 will. As a special characteristic it should be noted that here the sum of the Voltages appearing on deflection electrodes 42 and 43 in each tuning phase has the same value. The advantage of this circuit is that the sequence of the display during the voting with respect to the voting center point completely runs symmetrically.

In the embodiment of Fig. 2o are by a so-called Difference discriminator generates display voltages even with AM reception, the result in a voting pattern similar to that of FM reception. The switching point is for this purpose 64 of the AM difference discriminator is connected to electrode 42 via resistor 56. In accordance with the exemplary embodiment in FIG. 16, the electrode 43 is over again the resistor 17 is connected to the switching point 53 of the FM ratio rectifier. The remaining circuit arrangement is in principle the same as in the exemplary embodiment of Fig. 16. The electrode 42 can also be connected to the ground point. In In this case, a changeover switch must be provided to control the resistance during AM reception 17 connects with switching point 64, with FM reception with switching point 3.

Another exemplary embodiment in which a similar one for AM reception Fig. 21 shows how the tuning picture is generated for FM reception the switching points 62 and 63 by the known discriminator over the switch 34 and the resistors 56, 17 are connected to the electrodes 42 and 43. With FM reception the electrodes are connected to the FM ratio rectifier by the changeover switch 34 in the manner indicated and the device ground. The electrode 44 lies across the resistor 57 the switching point 5 i of the FM ratio rectifier.

In the embodiment 22, the display grid 40 is by means of a Resistor 26 connected to switching point 52 of the ratio rectifier. Since this switching point has a If positive voltage is generated, the luminous image is brightened. Through appropriate Dimensioning of the cathode resistor 16, it can be achieved that the tuning pattern is completely extinguished in the case of free reception and only then becomes visible, when tuning to a station. The resistor 26 limits the brightening of the luminous image with large carrier amplitudes due to the display grid current that occurs or by the voltage drop occurring at resistor 26. The rest of the execution corresponds to the previous exemplary embodiments.

In the example of FIG. 23, the end of the resistor 57 is not with switching point 5 i, as before, but with switching point 52 of the ratio rectifier tied together. When an FM carrier arrives, this, in contrast to the previous Embodiments, the voltage of the two control anodes 45 and 46 is reduced. This results in different display effects. It may be for the display prove advantageous, albeit with AM reception the display voltages the control electrode 44 act so that they in a similar manner the anode voltages 45 and 46 decrease as the transmitter strength increases. In this case the IF voltage should of the AM receiver part can be rectified via a special diode.

In the exemplary embodiment of FIG. 23, the AM reception is then the To connect switching points 42 and 41. The Fig.24 shows an application example of the present tube for the display of the tuning status of an FM = discriminator according to Foster-Seely. The rest of the circuit is basically the same as that given so far Embodiments. The at the switching point i of the grid circle of the so-called The carrier-dependent voltage produced by the limiter is negative compared to the ground point is used here for the carrier display for FM reception.

Fig.25 shows an application example of the tube for displaying the Of a Wheatstone bridge. The electrode44 is in the generally connected to the ground reference point. But you can also if, for example a double adjustment is to be carried out with a further variable voltage get connected.

In the circuit example of FIG. 26, the control electrodes 42 are and 43 connected to control anodes 44 and 45 through resistors 18 and icg. The interconnection is preferably made in such a way that the control anodes and the control electrodes are mutually connected in accordance with the figures in the individual systems. In this circuit, the electrode 42, which in the exemplary embodiment is not controlled by the display voltage, due to the changing voltage of the Control anode 45 influenced in the opposite sense. This results in an increased Display sensitivity and a symmetrical display course during the voting process.

In the - embodiment of FIG. 27 is between the controlled asymmetrically acting control electrode43 a nonlinear resistor54, the one has decreasing resistance characteristics with increasing voltage. It is sufficient if this resistance only applies to a voltage of the electrode 43, which is negative with respect to the cathode, takes effect. For example, resistance can through a rectifier path, for example through a semiconductor barrier layer or a Vacuum diode. In the case of a vacuum diode, this can turn into a vacuum vessel separate from the display tube or in the same vacuum vessel as the display tube. The advantage of this circuit is that without Sensitivity limitation for small control voltages, very large ones, at the electrode 43 effective control voltages can be limited. The tuning picture is thereby generally clearer and clearer.

The circuit diagram of Fig. Z8 differs from the usual ones up to now in that the negative bias is not caused by a cathode resistor, but by a negative voltage source, which is between the ground reference point and the point of symmetry of the discriminator (switching points 53 and 54) is reached will. As a result of this measure, the electrodes 41 and 42 are biased negatively. Compared to the use of a cathode resistor, there is the advantage that that the electrode43 is at cathode potential in this case. It arises from it greater display sensitivity with AM reception. The necessary bias between the switching points 53 and 54 can, for. B. can be generated in that a resistor placed between the ground reference point of the device and the Arode voltage generator will. The tube's cathode current flowing in the device is used in a known manner creates the necessary tension.

In the embodiment of Fig. 29, a resistor 52 is between the cathode of the display tube and the positive anode voltage supply of the FM part switched. This anode voltage part is generally in order to be mutual To prevent disturbance of the reception circuits, switched off with AM reception. In the application of circuit 29 becomes the positive bias of the cathode of the display tube at AM increased compared to the ground point. The working conditions of the display tube can be designed so that the AM display sensitivity under the same FM display conditions is increased.

In the examples of FIGS. 30 and 31, provision is made to reduce the operating voltages of the control anodes in relation to the fluorescent screen voltage. This is advantageous when the display conditions are such that high negative control voltages on the asymmetrically acting control electrodes overdrive the tube and cause picture disturbances. By reducing the anode voltage, the control range of the display tube is limited. In order to maintain the modulation range in AM mode and thus the display sensitivity, the anode operating voltage can be connected to the fluorescent screen using a switch in AM mode. In fig. 30 , the voltage reduction is produced by a resistor located in the luminescent screen circuit and, in the example of FIG. 31, by a voltage divider operated parallel to the luminescent screen voltage. The invention provides for the ends of the anode external resistances to be connected to other switching points of the device which have a voltage that decreases compared to the fluorescent screen, e.g. B. the screen grid voltage of amplifier tubes to connect. Switching points are preferred which have approximately the operating voltage of the fluorescent screen in AM reception and a reducing voltage in accordance with the desired modulation limit in FM reception.

In the circuit example in FIGS. 16 and 17, a potentiometer or adjustable resistors are provided in the control anode circuits to avoid manufacturing inaccuracies of the tube, which act in the sense of a false indication, to compensate. The invention but has also provided other options for this. For example let The two ends of the anode external resistances can also be set at different levels Connect voltages. Such tensions can be z. B. by voltage divider Establish tight between the screen span and your ground point. Another possible application 32 and 33 show. In this case, the asymmetrical (n) Control electrodes) 42 and 43 opposite the cathode with adjustable bias voltage operated. In the exemplary embodiment of FIG. 32, the voltage is set by a cathode resistor and in the embodiment of Figure 33 by a Voltage divider operated in parallel with the fluorescent screen voltage. Which procedure In the individual case, preference is given, depends on the particular embodiment, the special manufacturing process of the display tube and the intended switching effort away. In general, preference will be given to the method with the greatest constancy the calibration values occur during continuous operation.

The specified circuit arrangements for amplifier arrangements with at least one symmetrical and two asymmetrical control electrodes can be in a similar way for amplifier systems with only two asymmetrical control electrodes use according to your embodiment of Fig. i. In the exemplary embodiment 17 can, for example, dispense with the control electrode 44 Display effects can be achieved when the switching point 51 is above a suitable resistance is connected to your switching point 54.

Claims (4)

PATENT CLAIMS: i. Voltage comparison indicator tube with two with the to compare voltages connected electrodes, in the case of the main patent 95o 9I6 migrating in opposite directions into the symmetry position by crossing these electrodes Light pattern parts Equal voltage and light pattern parts migrating in opposite directions Display voltage difference, characterized in that each of the crossed Electrodes arranged symmetrically to the common cathode of an amplifier system Associated with anode of the same roughness. 2. Electron tube according to claim i, characterized characterized in that the anodes of the amplifier systems are symmetrical to the common Cathode are arranged. 3. Electron tube according to claim i, characterized in that that the amplifier systems or control systems are at the same height around the cathode are arranged. 4. Electron tube according to claim i, characterized in that the amplifier or control systems symmetrically around those in the display system that are not effective Part of the cathode are arranged. 4. Electron tube according to claim i, characterized in that that the control anodes in the operating state of the display tube with the same External resistance are connected to the same voltage source. 6. Electron tube according to claim i, characterized in that control electrodes are in the discharge spaces of the control anodes are arranged in the form of sheets, struts or grids. 7. Electron tube after Claim 6, characterized in that the control electrodes are symmetrical to the Control anodes are arranged. B. electron tube according to claim 6 and 7, characterized characterized in that at least two of these control electrodes are connected to the comparison voltages be created. G. Electron tube according to Claim 6, 7 and 8, characterized in that that the control electrodes are surrounded by at least one grid. ok Electron tube according to claims i to 9, characterized in that the control anodes and control electrodes for the comparison voltage of the control system or systems are arranged so that at Equal voltage of the comparison voltages are the same and in the event of a voltage difference unequal currents flow to the control anodes. i i. Electron tube according to claim 6, characterized in that as a grid, coiled grids, bar grids or punched grids be used. 12. Electron tube according to claim ii, characterized in that that the longitudinal axes of the grid openings are as large as possible. Angles to each other form. 13. Electron tube according to claim i to 12, characterized in that in the discharge chambers of the amplifier or control systems additionally one or several further electrodes (symmetrically acting electrodes) are arranged, which affect the current to the two control anodes in the same way. 14. Electron tube according to claim 13, characterized in that the symmetrically acting electrode is represented by a grid surrounding the cathode. 15. Electron tube according to claim 13, characterized in that the symmetrically acting electrodes consisting of two struts symmetrically arranged in the discharge spaces of the control systems exist. 16. Electron tube according to claim 15, characterized in that the Struts are arranged within the comparison control electrodes. 17. Electron tube according to claims i to 12, characterized in that the comparison control electrodes from two (or a multiple thereof) symmetrical to the two control anodes attached rounds. Striving exist. 18. Electron tube according to claim 17, characterized characterized in that the comparison control electrodes are surrounded by a grid, which takes over the function of the symmetrically acting control electrode. ig. Electron tube according to claims i to 18, characterized in that when using two control electrodes in the form of struts in each discharge space the same from a hairpin curved strut are formed. 2o. Electron tube according to Claim i, characterized in that that the stener anodes also act as reference electrodes in the display system are. 21. Electron tube according to claim i and 2o, characterized in that the Control anodes consist of round struts. 22. Electron tube according to claim i, characterized characterized in that the comparison control electrodes are symmetrical about the plane of symmetry. of the display system are arranged. 23. Electron tube according to claim 22, characterized characterized in that the symmetrically acting control electrodes in the plane of symmetry of the display system. 2q .. electron tube according to claim i to 23, characterized characterized in that the comparison control electrodes consist of round struts or metal sheets exist. 25. Electron tube according to claim i to 2q., Characterized in that the symmetrically acting control electrode consists of a grid, which is the effective Includes circumference of the cathode. 26. Electron tube according to claim 25, characterized in that that the remaining control electrodes are located within this grid. 27. Electron tube according to claims i to 26, characterized in that the comparison control electrode is arranged so that it has a current-distributing effect on the control anodes exercising passing total current. 28. Electron tube according to claim i to P-7, characterized in that outside or inside the discharge space one or several electrodes at a positive, possibly variable potential are arranged. 29. Electron tube according to claim i to 27, characterized in that that these electrodes are arranged symmetrically to the two control anodes. 30th Electron tube according to Claims 27 and 29, characterized in that the electrodes consist of preferably curved plates that are symmetrical to the two control anodes are arranged. 31. Electron tube according to claim 28 and 29, characterized in that that the electrodes) consists of round struts. 32. Circuit arrangement for an electron tube according to claim i, characterized in that for the purpose an electrical tuning or balancing process, the asymmetrically acting control electrodes respectively. Control electrode depending on the adjustment position or adjustment position Tensions that are in the vicinity of the exact adjustment or adjustment position in a characteristic change in a recognizable manner, while the symmetrically acting control electrode or Electrodes on. a constant voltage or to one with the adjustment position or adjustment position also changing tension can be applied. 33. Circuit arrangement according to claim 32, characterized in that the so-called differential voltage of the FM discriminator Via a resistor on one or on the asymmetrically acting control electrodes one or the amplifier systems and the so-called control voltage of the AM demodulator effective via a resistor on one or the symmetrically acting control electrodes are. 34. Circuit arrangement according to claim 32, characterized in that the Control anodes (45 and 46) are connected to a potentiometer, the center of which is gripped is due to a positive voltage with respect to the cathode. 35. Circuit arrangement according to claim 32, characterized in that the cathode either directly or via a resistor, which can be short-circuited by means of a switch if necessary can, is connected to ground. 36. Circuit arrangement according to claim 32, characterized characterized in that the symmetrically acting control electrode (44) with the help of a Switch to the negative total voltage for FM reception and to switch on for AM reception the AM control voltage is applied. 37. Circuit arrangement according to claim 32, characterized characterized in that the symmetrically acting control electrode (44) has a resistor with the negative total voltage and via a further resistor with the AM control voltage connected is. 38. Circuit arrangement according to Claim 32, characterized in that that one of the asymmetrically acting control electrodes of the amplifier systems either directly or via a resistor to ground, while the other via a resistor is connected to the differential voltage of the ratio rectifier. 39. Circuit arrangement according to claim 3a, characterized in that the resistors in the supply lines the asymmetrical control electrodes of the amplifier systems have the same ohmic Have resistance. 4o. Circuit arrangement according to Claim 32, characterized in that that the asymmetrically acting control electrodes of the amplifier systems have two equal resistances with the negative total voltage of the ratio rectifier are connected. 41. Circuit arrangement according to Claim 32, characterized in that that one control anode via a fixed resistor and the other via a variable Resistance connected to voltage. 42. Circuit arrangement according to Claim 32, characterized in that the symmetrical grounding of the ratio rectifier takes place via a resistor. 43. Circuit arrangement according to claim 42, characterized characterized in that this resistor is bridged by a capacitor. 44. Circuit arrangement according to Claim 32, characterized in that the symmetrical The ratio rectifier is grounded via a voltage divider. 45. Circuit arrangement according to claim 32, characterized in that an asymmetrical control electrode of the amplifier systems via a resistor with the differential voltage of the AM difference discriminator and the other control electrode via a resistor with the differential voltage of the FM ratio rectifier are connected. 46. Circuit arrangement according to claim 32, characterized in that an asymmetrically acting control electrode with ground is connected and a toggle switch for AM reception the resistance in the supply line the other control electrode with the differential voltage of the AM differential discriminator and for FM reception with the differential voltage of the FM ratio rectifier. 47. Circuit arrangement according to claim 32, characterized in that the two asymmetrical control electrodes of the amplifier systems each with a resistor the AM differential voltages of the AM differential discriminator are connected. 48. Circuit arrangement according to Claim 47, characterized in that one of these Control electrodes. with FM reception with the differential voltage of the ratio rectifier and the other control electrode can be connected to ground by means of a changeover switch. 49. Circuit arrangement according to claim 32, characterized in that the grid of the display system via a resistor with the positive total voltage of the ratio discriminator connected is. 50. Circuit arrangement according to Claim 49, characterized in that that the resistance limits the brightening of the luminous image at large amplitudes. 5 r. Circuit arrangement according to Claim 32, characterized in that the cathode resistance is dimensioned in such a way that the tuning image is completely wiped out when reception is free of transmission and only becomes visible after voting on a transmitter. 52. Circuit arrangement according to claim 32, characterized in that the symmetrically acting control electrode via a resistor with the positive total voltage of the ratio discriminator connected is. 53. Circuit arrangement according to claim 32, characterized characterized in that the IF voltage of the AM receiver part via a special diode is rectified. 54. Circuit arrangement according to Claim 32, characterized in that that the anode voltage of the amplifier systems is reduced with FM reception. In References considered: British Patent No. 52o 655; U.S. Patent No. 2 124 7'40.