DE1025935B - Circuit arrangement for generating a stepped pulse train - Google Patents

Description

GERMAN

The invention relates to a circuit for alternately charging and discharging a capacitor Voltages of opposite sign from a DC voltage source to this capacitor to generate block-shaped or step-shaped stresses. The circuit according to the invention is particularly useful in cathode ray tubes of the type described in U.S. Patent 2,692,532. Cathode ray tubes of this type have between the electron beam source and the phosphor screen or electron capture screen one or more grids extending generally in the same plane as the screen. Each grid (if there are several) has two sets of interlined, mutually insulated conductors, which are common lie in a flat or cylindrical surface. As described in the aforementioned patent Alternating conductors of the grid are among the two isolated sets of conductors that make up the grid form. By applying potential differences between the two sets, the electron bundle, wherever the point of impact may be on the surface of the grid, at its transition between the grid and deflected the screen in a direction usually perpendicular to the grid conductors. At a Embodiment of this type of tube, the screen has several phosphor strips, which when electrons hit light up in different colors. These phosphor strips are in a repetitive manner Color cycle attached, with the strips usually running parallel to the grid conductors. The device is such that with a potential difference of a sign and a suitable size between the two sentences of lattice conductors, the electron bundle hits phosphorus parts of one color, while at the opposite Potential difference the phosphor sites of a different color are hit and in the absence If there is a potential difference between the two sets of conductors, phosphorus points are hit with a third color will. In these tubes, the grid is combined with a conductive layer on that side of the Phosphorrasters used, which is facing the electron beam source, to accelerate and focus To achieve tension between the grid and the screen.

In order to display data in different colors on the screen, switching voltages must be applied to the grid be, d. that is, a number of potential differences must be between the two sets of grid wires be created. For certain types of reproduction, this is preferably done with the aid of step-shaped Voltages, and the present invention particularly relates to a circuit for such Use of cathode ray tubes.

At the frequencies that are currently used in the circuit arrangement for generating
a stepped pulse train

Applicant:

Chromatic Television Laboratories, Inc., Emeryville, Calif. (V. St. A.)

Representative: Dipl.-Ing. K. Lengner, patent attorney,
Hamburg 1, Mönckebergstr. 7th

Claimed priority:
V. St. v. America August 2, 1955

Arthur Schlang, Long Island, NY (V. St. A.),
has been named as the inventor

applied cathode ray tubes of the type mentioned above is the impedance of the grid structure at the terminals with which the two sets of conductors are connected, almost purely capacitive. The invention relates on the modulation of this capacitance, in such a way that the voltage between the terminals and thus between adjacent conductors of the two inter-lined sets of conductors has an almost rectangular shape. The invention creates means by which such a rectangular shape, the potential differences of opposite signs and contains intervals with a potential difference equal to zero, between the two sets of Lattice conductors can be laid from a DC voltage source.

In a circuit arrangement for alternately charging, reloading and discharging a capacitor from one DC voltage source based on voltages with opposite signs to generate a step-shaped Pulse sequence, an excellent effect, in particular a high edge steepness, is achieved if according to the invention the circuit contains four electronic discharge devices, each with an anode, a cathode and a control grid and these devices are arranged as branches of a four-armed bridge circuit in such a way that that the anodes of two consecutive devices and the cathodes of the other two devices are conductively connected to each other and the two connection points of the two at the DC voltage source Anodes or cathodes are connected and the capacitor is connected to the other two connection points of the bridge circuit is connected, and if the alternating

709 309/137

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the application of positive signals to the control grid of the pre-signal voltage at Vl and V 4, and a transformer 20 directions in diagonally opposite one another allows the application of a signal voltage to the pairs of the mentioned capacitor with alternating tubes V2 and F3. Each transformer has two opposite signs and is charged in the case of secondary windings, which each form a grid-cathode circuit with simultaneous application of positive signals to the control grid 5 of one of the tubes. The secondary windings of all devices the capacitor is discharged. Transformer 18 are in the grid-cathode circles The invention is explained in more detail with reference to the drawings of the tubes V1 and P ^r 4, while that of the transformer, in which FIGS of V2 and VZ represent embodiments of the invention and are switched on. The transformers are illustrated via their Fig. 5 voltage forms which are useful in explaining the primary windings of voltages of suitable form according to the invention. In Fig. 1, the mutual capacitance of the two desired forms of control voltage, preferably interlining sets of grid conductors, is achieved in the case of an electro-narrow pulse. The sign must be of the type in US Pat. No. 2,692,532, of course, such that the type described for the transformers 18 is denoted schematically by C. The 15 and 20 applied signals to positive voltages on the circuit of Fig. 1 is to lead to the generation of a block control grid of the tubes.

shaped voltage across C from a DC voltage If Vl and F4 set up a sufficiently long power source 2 from. For this purpose, C is made conductive (this time can in practice be very short between two diagonally opposite one another), terminals 4 and 6 assume the potential terminals or connection points 4 and 6 of the branches 20 tiale of the terminals of the source 2 so that the complete one bridge circuit, the other, diagonal supply voltage across the capacitor C occurs. Conversely, opposite terminals 8 and 10 are conductive when the control source 2 connected to the transformer 18 is connected. To charge the capacitance C signal, the power line from Fl and F 4 is limited to a shorter one with voltages from alternately opposite times, the voltage across C is limited to a part of the characters, the bridge circuit has four switches in the supply voltage. A source 2 with a bridge branch can be favorable for the speed form of vacuum tubes F1 to F4, one in each speed of charging. Each tube contains an anode to apply a higher voltage than that supplied by C method and a control grid. The anodes of the tubes is desired Fl, and the voltage charged to the C and V3 are connected to the connection point 8, is to be limited by the fact that the time during which the charged simultaneously with the positive terminal of the source 2 30 C can, is limited, while the cathodes of the tubes F2 If C are connected with a voltage of a sign through and F4 are connected to the junction point 10, the line through which a pair of tubes is charged, which is simultaneously with the negative terminal of the source 2 the Return these tubes to the locked state. In the embodiment according to FIG. 1 (by removing the signal at the transformer 18) the tubes themselves form the four bridge arms, however, 35 leave a charge above C , which they will retain (with the exception of discharge, as will be described later in the further embodiment via the leakage resistances examples of the invention will emerge, those of the circle), until the tubes F2 and T * 3 current-conducting bridge branches also contain other impedance elements. will. If in or after the moment in which Fl When the tubes Fl and F 4 return to a mutually opposite and F4 to their blocked state, V2 is made conductive via attached bridge arms 40 and V3 by applying a signal to the Trans, while the Tubes V2 and V3 in the other formator 20 become conductive, C is quickly discharged via opposite pairs of bridge arms and then charged with opposite signs, their control grids are kept locked, the During the discharge phase of the process, the capacitor C with a sign to a potential operating potential namely equal to the instantaneous potential, which after a certain period of time will be practically above C together with the voltage of the source 2. If, table equals the voltage of source 2. If instead of the usual zero potential difference across C of which tubes F2 and F3 are made conductive during one phase of the full switching cycle while F1 and F4 are held off, this can be achieved by increasing the voltage of C in the same way according to a time course determined at the same time, the two transformers 18 and 20 are controlled practically equal to the voltage 50, so that all tubes F1 to P "4current of source2be, but become conductive with the opposite sign.

In both cases, the capacitor charges according to an It is obvious that it is also possible to charge some or approximately exponential function. If all four tubes all tubes are electrically conductive at the same time by means of parallel connections, the potential of C stands and capacitances in the grid-cathode circles become the same. Zero. 55 of the tubes instead of using voltage sources with The time intervals that are necessary to provide the voltage with a bias. In order to allow the tubes to reach the voltage of source 2 with respect to C or to allow overdrive to return in the event of faults in the controls after the NuUwert, the separate bias anode resistance of the tubes and the internal resistance 16 for the tubes F2 and F4, the source 2 was dependent on the shape of the voltages applied to the 60 during the creation of the bias voltages on the grids of the tubes. These tubes, which are connected in parallel with resistance intervals, can be selected to be very short, namely by the capacities and capacities of the order of magnitude of a few microseconds. In general, it is desirable that the time required for the embodiment of FIG. 1 to be held by a transition of C from a desired voltage tubes F1 to F4 via their control grid by separate 65 of a sign to a desired voltage de-biasing sources and kept is required in pairs of opposite signs and / or zero voltages generated by externally generated signals, is very short. This can be achieved by being made conductive. The bias sources are labeled so that the grids of the tubes are controlled with signals out-12 for V1 , with 14 for F3 and with 16 for F2 and F4, which have very steep leading edges. A transformer 18 is used to apply a 70 by means of small internal anode resistances of the tubes,

5 6

By limiting the internal resistance of the separate bias voltage sources, sources 2 can be avoided at all and by applying a terminal voltage, without including the tubes in a blocking oscillator at source 2, which is higher than the maximum voltage, and without the tubes of danger the C needs to be charged. to suspend an overdrive if the modulation for generating step-shaped voltages with a 5 signals are missing, by means of a circuit such as that used for the different device according to FIG.
Circuits known for the grids of the tubes Vl . Fig. 4 shows an embodiment which can be used several up to F 4. A low anode resistance has features which are not present in the embodiments for the tubes can be achieved by suitable selection according to FIGS. 1 to 3. In Fig. 4 are their characteristics and in particular by modulation i ° tubes V1 to F4 in a bridge circuit of these tubes with strong signals including the switches as well as the already described off signals, which guide their grid in the area of the grid current. Vl and V3 are called pentodes and V2 boost. If, however, the grids are driven positively and F4 as two triode parts in a common envelope, the control pulses must be narrow in order to be displayed. All four tubes are to be avoided by grid losses in the tubes that are large in size. 15 cathode circles lying resistors 30 and parallel

To achieve the desired strong modulation capacitors 32 provided with a bias voltage,
the interrupter grid proves it to be advantageous for some users to fertilize alternately with opposite signs, as transformers 18 and 20, the capacitor C to be charged consists of the capacity to use transformers of two blocking oscillator circuits. Between the two sets of grid wires, the anode grid feedback 20 is designated 114 and 116, in an electrical transformer of each circuit with two additional cathode ray tubes 100 of the type used in the USA .-Patentlung, which was described between the grids and the Catholic script 2,692,532. This tube has the two opposite interrupter tubes in the bridge a cathode 102, which are heated by an incandescent body 104 circuit of the invention. A control grid 106, first and second anodes 108 can also, as shown in FIGS. Interrupter tubes V1 to F4 to function as outside The grid has to be set up for the two sets of isolated and controlled blocking oscillators. In Fig. 2 interlining conductors 114 and 116. Behind the switching belonging to the tubes F1 to F4 transformers TRl grid is a fluorescent screen 120. The second to TR4 :. Each of these transformers has a primary anode is connected to a conductive layer 118 on the inner winding 21 for the input of a trigger voltage 3 ° wall of the conical part of the tube. The and two additional, inductively coupled windings 22, electrode 118, can be in the form of a metal cone in tubes and 23, one in the anode circle and the other in the lattice of metal construction instead of glass construction, a cathode circle of the tube in question. Take the connection.

of the windings 22 and 23 is such that they have a regenerative The tubes F1 to F4 are energized

relative feedback from the anode to the grid as at 35 controls, the transformers designated by 46 and 48

causes a blocking oscillator. A gate to the winding originate. Each transformer has a primary

21 applied signal of suitable sign occurs via the winding 50 and two secondary windings 52 and 54.

Winding 23 and makes the tube conductive, and the transformer 46, the windings 52 and work

the feedback effect between the windings 22 54 such that they conduct the tubes F1 and F4 current

and 23 leads to a single short pulse 40, while with transformer 48 the winding

strong anode current, whereupon the tube in its counter 52 and 54 conducts the tubes F2 and F3

locked state returns and remains in it until a make.

new signal is supplied to the associated winding 21. The DC voltage source consists of the in the figure The tubes have separate bias voltage sources 12, 14, shown by dashed lines device 2, 15 and 17, which generate voltages such that the 45 a rectifier 34 with an output filter of known tubes are only conductive when she owns about her trans kind. The filter has series resistors 33 and formators can be switched. The primary windings of 35, shunt capacitors 37 and a cascade of transformers TRl, TRA, TR3 and TR2 can be voltage stabilizer tubes 36. The positive and negative pairs are connected in series, tive terminals of source 2 are denoted by 38 and 40, parallel or in some other way, around the tubes Vl, VA 50 net. These supply source terminals are to be made conductive together with the connections or the tubes F2 points 8 and 10 of the bridge via two identical resistors and F3 are made conductive together. Noticed 42 and 44 would be conductively connected. In the event of faults in FIG. 2, the capacitor C can be switched either between the cathodes of F1 and F3 originating from the transformers 46 and 48 or between the anode control signals on the grids of the tubes, which limit these from F2 and F4 ; the same applies to the current carried through the tubes for the embodiments according to FIG. 3. A safe value in both of the resistances.

Figures 2 and 3 are the anodes of the tubes F1 and F3 That two equal resistors are attached, one

through the windings 22 of their transformers from the one in each line of the source 2, serves to avoid

Bridge connection 8 disconnected. Changes in the mean potential on the surface of the

Another embodiment according to the invention is 60 grid 112 opposite the other electrodes of the elec-

shown in Fig. 3. This corresponds to that according to the CRT during the switching cycle. While

Fig. 2, with the difference that the tubes F1 to F4 a single resistor, e.g. B. one of the resistors 42

are connected as blocking oscillators with a bias and 44, the tubes of the bridge circuit against over-

voltage generated by parallel connections of one counter control each in the event of faults in the switching signal on the

Stand 24 and a capacitor 26 in their grid 65 would protect output of transformers 46 and 48,

Cathode circles is brought about. The tubes can would be attaching unequal resistances between

therefore act as free-running blocking oscillators, and the terminals 8 and 10 of the bridge and the terminals

Windings 21 of their transformers rather serve the supply source 2 to change the mean potential

for a synchronizing as a switching func- tial during the switching cycle in the surface of the grid

tion. 70 lead; ζ. B. when the resistor 42 is present and the

7 8

Resistor 44 would be absent, would at the high and medium potential of the plane through the grid 112 and Discharge of the grid 112 to voltages opposite the potential of the jacket, compared to that of the others Set the sign of the mean potential of the grid electrodes of the tube 100 to be a constant voltage area equal to a voltage, which have in the middle between ratio. The mean tension in the plane the voltages 5 occurring at the terminals 38 and 40 through the grid 112 must be set to negative values lies. that of the mantle. To this

This would also apply if the grid capacitance C purpose, the resistors 70 and 72 are dimensioned in such a way be limited to a lower voltage by the fact that, in view of the voltage drop in the objection, that the times during which the tubes stood through 33 and 35, the voltage at the lower end of the The transformers 46 and 48 can be conductive, io resistor 70, which is shortened by means of the tap 74 to get voted. So even if there are unequal readings, the voltage at terminal 40 in stands in the two lines from the bridge to a level that is at least equal to the The source of the charging current is the mean potential at half the potential difference between the terminals Grid area is uniform compared to the rest of the electrical 38 and 40. The tension difference between the that of the cathode ray tube for the two charging * 5 jacket and the grid area is in practice about phases of the switching cylinder, assuming that, as it is in 200 to 600 volts.

is generally the case, a constant voltage variation. The embodiment according to FIG

Relationship between a point in the source 2 and the circuits that are used to control the switching tubes Vl other electrodes of the tube 100 is present. If you are suitable up to F 4. These circuits are explained in greater detail on the basis of but no voltage on the two halves of the grid, 20 of FIG. In FIG. 5, B represents a meander, all four tubes V1 to F4 are simultaneously current-shaped voltage, those from (not shown) are conductive and discharge the grid. So if the resistance means is generated and it is assumed that stands between the connection points 8 and 38 and it occurs at an input terminal 200 of the control voltage between the connection points 10 and 40 different generator, which as a whole are indicated by the dashed line, is during the Discharge time the mean span line 202 is shown. 5 only shows the alternation of the grating area by half of the current components of the voltages from source 2, and one deviates from the voltage supplied and this therefore has not attempted to shift the correct mutual amplitudes across the other elements of the tube 100. of the various tensions. In addition, this difference in resistance will therefore lead to modulation are the charging and discharging times of the voltages at the mean potential in the grid area 112 opposite the control grids of the tubes and the resulting electron beam source in the tube 100. These voltages of the capacitance C of the switching grid of the electron cause a slight change in the deflection sensitive cathode ray tube chosen to be vanishingly small compared to the speed of the tube, i.e. in the ability to transfer the electrons to the time intervals of the switching cycle shown in the cathode ray tube due to voltage differences, which alternate the capacitance in A sign differentiated between the two grid halves 114 and 116 35 is charged, discharged thereon and charged in opposite positions of any color on the screen 120 with the sign set off. With this chip deflection, so that incorrect colors can arise. If it can be assumed that the capacitor is a resistor in series with the bridge circuit sator C with the two signs on the complete and the supply source, it must also be in the two voltage, for which the DC voltage source is capable of lines between the bridge circuit and which is positive 40 is charged. The voltage B has a fundamental and negative terminal of the supply source frequency, the period of which is 2t , with time being taken, as shown in FIG. vall between two adjacent vertical lines in

The current limiting resistors 42 and 44 have the Fig. SB is. The voltage B can be generated by known means with a tendency to increase the charging and discharging times, for example with the aid of a bistable multidie for the voltage of the capacitance C of the grid 112 45 vibrator, which are necessary for a pulse shown in FIG. 5A To achieve a desired value, series is controlled. The voltage form B is in a but this can be compensated, as already differentiated differentiating circuit, which was noticed a capacitor, that the voltage of the supply source contains larger sator 204 and a resistor 206, and the voltage differentiated as the maximum voltage appearing at the capacitance, which is reproduced at C, is selected and / or the tubes Vl to F 4 to larger 50 is placed on a bistable multivibrator, which are controlled from anode currents. Triodes V201A and V201B exist. The resulting

In the embodiment according to FIG. 4, the source 2 voltages at the anodes of these tubes are shown in FIGS. 5 D and 5 E for providing a desired voltage difference. These voltages are used between the mean potential at the grid surface 112 at the control grid of triodes F202 / 1 or V203A and the voltage at the tube jacket 118. The 55 placed, each forming a part of an adding device, jacket has a positive voltage compared to that of the tubes V 2102 A and F202.B and the middle potential of the grid in one case for the purpose of removing the tubes F203..4 and in the other case F203 B. Secondary electrons that occur when the electron- The voltage B is control grids of the tubes V 202 B beam on the grid conductors. When this and F203.B are fed to these adders. If the electrons were not to be removed, they would be 60 at the output of the adder 1 * 202.4 - F 2031? as a result of the voltage occurring between the grid as a whole and the voltage in Fig. 5 F and the corresponding acceleration voltage applied to the anode of V 203 A - V 202 B of this screen, and when it hits is shown in Fig 5G shown. The voltages F and G are on the screen, as a result of their arbitrary distribution, they would imitate rectangular voltages whose fundamental frequency grains the unsaturated colors displayed on the screen have a period At , and the component. To achieve such a voltage, G is 180 ° out of phase with respect to the resistors 70 and 72 via the output of the equivalent component of F.

judge 34 switched, and a tap 74 connects F 2044 and F20423 form limiting circuits,

a point of the resistor 70 with the jacket 118. which is the low voltage part of the at the parallel anodes This connection creates a relationship between the 70 of V202A - F202.B and V203A - F2035 occurring

9 10

Limit voltages to small differences in these generated by the block-shaped signals H and /

Anode voltages that are based on differences in the two.

Adding devices are due to be eliminated. Naturally, other forms of stress can occur on the

The limiters are adjustable at the same time as the fixed grid capacitance C can be generated. The pulse series M

set the amplitudes of the voltages F and G, which 5 and N result z. B. in a stepped voltage,

from them to the grids of the tubes V205 A and as shown in Fig. 5O.

V206A can be let through. The invention enables in various ways a double triode V205A-V205B and V2Q6A-V20QB, control of the amplitude of the generated on the capacitor C, which are shown in Fig. 4, the one in the control channel of the voltage. Some of these have already been mentioned. Transformer 46 and the other in the control channel of the io So can the final charging speed of the transformer 48, are provided for the removal of the capacitor C in combination with control pulses DC component of the current flowing through the primary windings suitably selected duration to control the charging SO of the transformers. Although other methods of preventing a transformer are used at levels lower than the source, where effective control of maintaining saturation by direct current can be used, this is achieved by controlling the duration of the pulses in a method illustrated in those embodiments. constant voltage of the supply source, and vice versa, play desirable according to the invention, in which an amplitude of the block-shaped voltages occurs at the low-frequency switching cycle, since capacitors capacitor C can also be uncomfortably large according to the invention for this purpose. Control of the bias of the tubes in the branches of the DC component to remove the chip 20 bridge circuit lying be changed, F and G voltages in the primary windings 50 of the transport These tubes do not need any bias voltages F and G are to transformers locked in unge - to become. Except perhaps in the case of tubes, filtered form applied to tubes V205A and V206A . which are connected as blocking oscillators may be switched on or before the two pairs are applied to the tubes V205B and V206B at low levels between the two, the voltages on their mean or 25 applied control signals will be conductive. In the case of direct current values in resistance-capacitance filter circuits of a fixed bias, the control of the pre-set, which are designated by 208 and 210, takes place. The voltage naturally by changing the value of the tubes V2Q5A-V2Q5B and F2064-F206.B are supplied with a bias voltage source. In embodiments in which the cathode is loaded; the primary winding of the trans- a self-excited bias voltage can be used, the formator 46 is connected to the cathodes of the tubes V205A- 30 bias level by changing the amplitudes of the F 205 2? connected, and the primary winding of the trans- control signals are controlled. All of these deformers 48 can be driven with the cathodes of F206 ^ 4-F206 B to produce asymmetrical chip connections. Since only the direct current component of F are used at voltages on the capacitor C , so z. B. the cathode of F 205 Z? occurs, only the alternating voltage of one sign has a larger current component on the primary winding of the trans- 35 amplitude than the voltage with the opposite pre-transformer46; this is also the case for G and the sign. Thus, the pulses that are used to control the transformer 48. With a suitable choice of the winding direction of a pair of tubes, longer duration of the windings of the transformers can be selected than those of the other pair of tubes, voltages F and G of the secondary windings the trans- The bias levels in the two formers 46 and 48 can also be taken and between 40 different tube pairs can be selected using the grid and the cathode of the switching tubes associated with this secondary use of one of the above-described methods for the windings with reverse control of the bias level. For example, when the sign occurs, as shown in FIGS. 5H and 51, an asymmetrical embodiment according to FIG. 4 can be provided. This block-shaped voltage to the tubes F1, F4 or F2, V3 on the two halves of the electrical lead voltages are achieved at the capacitor C of the cathode ray tube grid 112 in that the grid 112 in the electron ray tube 100 creates a span the amplitudes of the two pairs of tubes Fl, F4 voltage, as indicated in Fig. 5 with /. and F2, V3 control signals applied to different Ge-The-bridge circuits according to the invention, are switched on chooses what these results two tube pairs in different bias voltages to eventually the embodiment of Fig. 4, can. However, the amplitude of the control signals can also be regulated using pulses instead of block-shaped voltages. In general, there is no need for potentiometers 212 and 214 in the anode circuits of the power line in the two pairs of switching limiting tubes F204.4 and F20423. The additional cyldus or in all four switching tubes during the whole potentiometer 216 and 218 serve as variable resistors to maintain the discharge phase of the switching cycle. The 55 are switched, in order to achieve a minimum limiting control pulses only need a sufficient period of time at which changes in the output have in relation to the anode currents that these voltages generate the adding devices F202 4-F20223 pulses in the switching tubes for charging and F203J.-F20323 can be blocked. Within further the capacitance to the desired level and its limits, regardless of the bias level of the tubes to allow discharge; If the voltage of the supply 60 in the bridge circuit is selected as a function of the amplitude of the source higher than the maximum control signals applied to the capacitance, these signals will bring the tube rate C desired voltage, it will generally bring it to practically a bias voltage equal to zero and even be necessary to use shorter pulses than the charging during the occurrence of the control signals completely current phases of the switching cycle. In general, make it conductive. However, because of the bias levels, pulses are preferable to block voltages, 65 the tubes can be used during the intervals between them to keep the required control energy low. The control signals are completely blocked or made semiconducting Fig. 5 K and 5 L represent pulse trains that are to be. Obviously, a small current conduction in both tube pairs of the bridge circuit will after one pair of tubes as opposed to blocking the sensation can be applied in order to reduce an output rate with which the other tube voltage / voltage is generated which is equal to that 70 pair the Capacitor C will charge.

It is also within the scope of the invention to select the voltage for charging the capacitor C to a voltage with one sign greater than that for charging it to a voltage with the opposite sign. So z. B. a pair of potentiometers connected in series can be connected via the voltage source with the tapping of one potentiometer to the anode of the tube Vl and the tapping of the other potentiometer to the cathode of the tube F 4 opposite in the bridge, which is made conductive at the same time as Vl , so a charging path for the capacitor C forms. If the taps of the two potentiometers are moved in opposite directions by the same voltage changes, e.g. B. by means of a suitable control device, one for higher voltages, the other for lower voltages, the effective supply voltage for the tubes Vl and V 4 can be increased or decreased, e.g. B. from a mean value at the midpoints of these potentiometers. In this case, the available voltage at the grid surface, which results in a charge via Vl and F 4, will lie in the middle between the voltages occurring at the terminals of the supply source. If necessary, the other pair of tubes can be connected in a similar way in series with the voltage source via a similar pair of potentiometers with the taps for the tubes Vl and V 2 associated potentiometers, which are coupled to one another, while the potentiometers associated with the tubes V 3 and V 4 likewise are coupled to each other. With the four potentiometers coupled in this way, a decrease in the effective supply voltage occurring in the series connection of Vl, C and F4 would be accompanied by an increase in the effective supply voltage occurring in the series connection of VS, C and V2 .

Claims (7)

Patent claims: 1. Circuit arrangement for alternately charging, reloading and discharging a capacitor from a DC voltage source to voltages with opposite signs for generating a stepped pulse sequence, characterized in that the circuit contains four electronic discharge devices, each with an anode, a cathode and a control grid and that these devices are arranged as branches of a four-armed bridge circuit in such a way that the anodes of two successive devices (Vl, VS) and the cathodes of the two other devices (V2, F 4) are conductively connected to one another and the two connection points of the two are connected to the DC voltage source Anodes or cathodes lie and the capacitor is connected to the other two connection points of the bridge circuit (4, 6), and that when positive signals are alternately applied to the control grid of the devices in diagonally opposite pairs of the mentioned capacitor with deviating is charged with the opposite sign and when positive signals are simultaneously applied to the control grids of all devices, the capacitor is discharged. 2. A circuit according to claim 1, characterized in that the devices mentioned are such Have bias voltage so that the anode currents are practically suppressed at this voltage. 3. A circuit according to claim 1, characterized in that one or more of the devices in the Grid-cathode circuit contains the parallel connection of a resistor and a capacitance. 4. Circuit according to one of the preceding claims, characterized in that each terminal the DC voltage source with a connection point of the bridge circuit via a resistor is connected, the two resistors being practically equal to each other. 5. Circuit according to one of the preceding claims, characterized in that each of the mentioned Devices is designed as a blocking oscillator. 6. Circuit according to claims 1 to 4, characterized in that the circuit has two transformers possesses, each with a primary winding and two secondary windings, each secondary winding in the grid-cathode circuit of one of the devices is that the two secondary windings of one of the Transformers in the grid-cathode circuits of the devices in two non-contiguous branches the bridge circuit mentioned and that the secondary windings of the other transformer in the grid-cathode circles of the other two devices, with alternating signals on each the primary windings are supplied separately to charge the capacitor with alternating opposite Sign and signals on the two primary windings simultaneously to discharge the Capacitor are fed. 7. Circuit according to one of the preceding claims, characterized in that said Capacitor is formed by two sets of mutually insulated, interlined conductors that make up the switching grid a color display tube of the type in which such a switching grid between the electron beam source and the screen is present. 1 sheet of drawings © 709 909/137 3.58