DE2304944A1 - DRIVE CONTROL CIRCUIT FOR A PLASMA DISPLAY PANEL WITH MEANS FOR APPLYING A BASE VOLTAGE TO ALTERNATING IGNITION IMPULSE VOLTAGES - Google Patents

Description

Drive control circuit for a plasma display panel with means for Applying a base voltage to alternating ignition pulse voltages

The invention relates to a drive control circuit for controlling an outer electrode discharge display panel, usually called a plasma display panel, with an array of identical gas discharge cells lying in one plane, a plurality of first electrodes and a plurality of second electrodes, the first and second electrodes on the outside of the cells are arranged with one cell each between a pair of first and second electrodes.

A plasma display panel generally comprises a stack of three thin ones flat glasses or transparent dielectric sheets. The center plate has a plurality of holes at predetermined locations. The edge of the stack is hermetically sealed. The internal voids are evacuated and then filled with a neon gas or similar inert gas or gases. Outside on both sides of the outer panels are the so-called

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Matrix electrodes attached, which are perpendicular to each other with the holes in between intersecting parts and column electrodes. In each case one of the selected holes corresponding to the letter to be mapped or symbol correspond, intersecting matrix electrodes is selectively applied with a high frequency voltage, whereby the gas discharge in the selected holes to display the desired letter or symbol. In an improved embodiment, the conventional one The plasma display panel of the above structure uses two thick glass plates or transparent dielectric plates as the outer plates and provided with a thin glass or other dielectric film on their inner surfaces. Suggestions have also been made a plasma display panel without a center plate; and a plasma display panel for numerals in which segment electrodes are taken in place of the matrix electrodes be to use.

In each of the conventional display panels, discharge occurs in a gas space, which is hereinafter referred to as the cell, on which is opposed by a pair outer electrodes, which is selectively applied with a direct voltage that is higher than the ignition voltage of the cell (the voltage drop across the dielectric plates is neglected). Once discharge occurs in a cell, charged particles generated by the discharge charge and decrease the dielectric plates the strength of the electric field in the cell until the discharge disappears, when the sum of the applied voltage and the charges resulting from the charges stored on the dielectric plates is reversed Voltage becomes smaller than the voltage sustaining the discharge in the cell. Will the polarity of between the opposite outer Electrode pair supplied DC voltage reversed to the same polarity like having the voltage resulting from the charges, then the voltages applied to the cell are superimposed and sufficiently large than the ignition voltage. The discharge then begins again until it finally disappears. By repeating this process, viz

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by applying an alternating or sequential voltage reverse polarity between the opposite outer electrodes it becomes possible to maintain the short-term discharge. Will the Repetition frequency of the short-term discharge per unit number optimally determined (for example 10 kilohertz), then it is also possible to use a To create a display with sufficient brightness.

To provide an external electrode discharge display panel in time selection manner or to operate time-division multiplexed, is a drive control circuit from so-called first type has been proposed, as described in US Pat. No. 3,614 and which will be described in more detail below, in which one group of row electrodes and another group of column electrodes can be selectively applied with pulse voltages, the timing of the pulse voltages corresponding to the corresponding electrode groups are supplied, is selected such that one of the electrode groups is applied with the voltage, while the other electrode group no voltage is applied. There was also a drive control circuit of the so-called second type proposed here, as it is proposed in the Japanese publication "Densi Zairyö" (Electronics Materials), July 1971, Page 89, and which will be discussed in more detail below, in which the group of row electrodes and the other group of column electrodes Pulse voltages can be applied selectively, the pulse voltages supplied to the corresponding groups varying at the same time will.

The drive control circuit of the first type has the disadvantage that the application of the impulses causes a discharge in those cells which have not been selected, and that there are time intervals in which some of the cells are not energized to one The ignition voltage of these cells increases. The drive control circuit the second kind does not have these defects mentioned.

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In connection with the drive control circuits of the first and the The second way, however, is to say that the initial discharge experiences a considerable delay when voltages are applied to the cells that are considerably higher than the ignition voltage and after they have not been in operation for a few days. The delay is up to 10 seconds, even if the board is exposed to 100 lux lighting.

In order to avoid the delay in the initial discharge, it was proposed that that electrons and / or ions should always be present in the cells. An attempt was made to trap a radioactive gas in the cells and to cause a radioactive substance to act on the display panel. These attempts are, however, not viable because it is not easy with dealing with radioactive material, and it is difficult to find obsolete display boards and to safely accommodate destroyed display boards. Furthermore, such attempts have proven to be expensive because the radioactive Material had to be introduced into the scoreboard in an additional process.

It is therefore an object of the invention to provide a drive control circuit for a create external electrode discharge display panel that eliminates such a delay the initial discharge, which in practical applications is negligible. ·

It is also an object of the invention to provide a plasma display panel of the type described Create type that can operate on low voltages.

It is also an object of the invention to provide a plasma display panel, which does not contain radioactive material.

This task is accomplished by a drive control circuit of the type described above Type solved, which is characterized according to the invention in that the circuit pulse-generating means for selective supply a group of pulse voltages to a selected pair of first and two-

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ter electrodes with alternating polarity for generating a gas discharge. charge in the cell arranged between the selected pair of electrodes has that the voltage is less than four times the ignition voltage each of the cells and greater than twice the ignition voltage and that direct voltage superimposing means for superimposing a direct voltage on a group of the pulse voltages supplied to at least a predetermined pair of the first and second electrodes are, the DC voltage having the character of the alternating polarity of the pulse voltages overlaying the DC voltage not eliminated.

Further features and expediencies of the invention emerge from the description of exemplary embodiments with reference to the figures. From the figures show:

Fig. 1 waveforms for use in a drive control circuit the so-called first type for an external electric discharge display panel;

Fig. 2 waveforms for use in a drive circuit of the so-called second kind:

Fig. 3 is a diagram in which the ignition voltage against the pulse width in the drive control circuits of the first and second type are worn away;

FIG. 4A shows the discharge generating waveform for use in FIG Drive s control circuit of the first type on an enlarged scale;

4B shows the typical properties of the ignition voltage in the drive control circuit of the first type plotted against the repetition frequency the impulses for different impulse ratios of the impulse voltage;

Fig. 5 is a diagram in which the delay time of the initial discharge is plotted as a function of the voltage applied to the cell;

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Fig. 6 is a representation of a typical waveform as shown in a Drive control circuit according to the invention is used;

Fig. 7 is a schematic representation of the circuit in the drive control waveforms used;

Fig. 8 shows an important circuit part for a drive control circuit; and Figures 9-12 show circuits for various embodiments of the invention.

Before describing a preferred embodiment of the invention the operation of a conventional external control circuit for a plasma display panel is examined in connection with Figs. 1-5; to facilitate understanding of the principle on which the invention is based.

Reference is first made to FIG. 1. A drive control circuit not shown or drive circuit of the so-called first type here, as described in the above-mentioned US Pat. No. 3,614,769, comprises means for the supply of first or timing selection pulse voltages as shown at (a), (b), (c), and similar pulse voltages for the first, second, third and like timing electrodes (not shown). Each of the pulse voltages consists of a pulse group with a predetermined Duration, and each group in turn consists of pulses with a pulse height V, which is sufficiently higher than the ignition voltage V., and has one Pulse width W and a repetition frequency f. The pulse voltages for the successive row electrodes are by the amount of the predetermined Duration shifted and repeated with a period of η times the predetermined duration, where η is the number of row electrodes in one Group such as is for a single letter. The drive circuit further comprises means for selectively supplying second or address pulse voltages, as depicted at (d), to at least a selected one of the column electrodes, such as the m-th column electrode (not shown). Shall a discharge in arranged along a certain one of the column electrodes Cells are generated, then that of the special column elec-

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trode applied second pulse voltage pulses with the level V in such an offset ratio against the pulses of the first voltages applied to the row electrodes that the determined Cross the column electrode on the desired cells, so that the pulses of the second pulse voltage are within a predetermined range Time voltages of the first voltage pulses applied to the last-mentioned row electrodes occur, while the pulses djeser first pulse voltages just disappear. The drive circuit in this way supplies the resulting pulse voltages shown at (e) and (f) to the cells of the first row, m-th Column and the second row, m-th column. In Fig. 1 (e), the discharge occurs in the cell of the first row, m-th column in response on a first pulse 21 and extinguishes as the reverse voltage increases as a result of the discharge generated charged particles. In response to a second pulse 22 applied to the cell of the same polarity as that The voltage generated by the discharge increases the discharge in the cell until it finally disappears. Similar Processes follow an eighth pulse 28. Insofar as the interior of the cell consists of insulating material, it remains the reverse voltage caused by the discharge caused by the eighth pulse 28 persist for a considerable period of time, so that the pulses of the polarity of the reverse voltage, such as a ninth pulse 29, do not cause a discharge can. It follows from the foregoing that the discharge occurs only in the cells determined by the waveform of the column electrodes applied pulse voltages can be determined. fact is, however, that the discharge also occurs, for example, in the cell of the second row 'm-th column' as a result of the cells applied to it resulting stress as shown in Fig. 1 (f) is. More precisely, a pulse 31 causes the discharge. A second pulse 32 and the following pulses with one polarity contrary to the voltage resulting from the charges, does not produce a discharge. A fifth pulse 35 with the same However, the polarity has the opposite polarity to the voltages resulting from the charges and creates one again momentary discharge. A sixth pulse 37 and the following pulses of the same polarity do not cause a discharge, but do a ninth pulse 39 again causes a temporary discharge. The un- 309836/0381

real discharges strongly contribute to the brightness of the undesired ones Cells with the result of a false indication if the pulse count is Mein within the predetermined duration. On the other hand, that demands Increasing to such a number is a large switching speed of the drive circuit and is economical and technical undesirable.

Reference is made to FIG. 2 below. A drive circuit the so-called second type here has means for supplying at (a), (b), (c) shown first pulse voltages and similar pulse voltages to the first, second, third and the same row electrodes (not shown). Each of the pulse voltages has the same waveform as that In the pulse voltages as in the drive circuit of the first type and is repeated in the same way. The drive circuit further comprises means for the selective supply of second pulse voltages, as shown at (d) are to at least a selected one of the column electrodes, such as the m-th column electrode (not shown). In the event that a discharge is to take place in cells arranged along a specific one of the column electrodes, then has the one fed to the specific column electrode In the pulse voltage negative pulses with a pulse height V, which coincide with the first pulse voltages, which the row electrodes, which cross the specific column electrode on the selected cells. The drive circuit thus provides those shown in (e) and (f) resulting voltages on the cells of the first row, m-th column and the second row, m-th column. Particular attention is now drawn to Fig. 2 (e) Referenced. A positive pulse triggers a discharge in the cell of the first row, m-th column and the reverse from the charges that follow resulting tension. A negative pulse 42 follows, which is added to the reversed voltage in order to generate a discharge again. In this way, the intermittent discharge is supported as long as the polarity of the pulse voltages changes alternately up to the fourth negative pulse 44. During the duration of this pulse 44, the

/ wsr d. end. en Discharge as a result of the positive 'voltage' resulting from the charges

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tion. The subsequent occurrence of a positive rising pulse 46 therefore does not contribute to the discharge. A subsequent negative pulse 47 has insufficient height to create a discharge. In the cell determined by the second row and mth column, only a first pulse 49 triggers, resulting from the negative pulse of the second pulse voltage supplied to the m-th column electrode, a temporary discharge. the The following impulses of both polarities cannot carry the intermittent discharge. It is known that the voltage V should be greater than the ignition voltage V "and less than twice the ignition voltage.

Reference is now made to FIG. 3, in which the abscissa of the the cell of a plasma display panel and the ordinate the voltage (ignition voltage) at which the pulses cause the gas discharge in the Trigger cell, display. It can be seen that the ignition voltages for the drive circuit of the second type are at the same repetition frequency the impulses are considerably lower than in the drive circuit of the first type.

The waveform shown in Fig. 4A from the Mm drive circuit of the first type used in the pulse voltage have a repetition frequency f and a pulse width W _n . In Fig. 4B the repetition s frequency f is plotted on the abscissa and the ignition voltage V on the ordinate. The ignition voltage hardly varies as a function of the repetition frequency, but as a function of the duty ratio (P) of the pulse voltage.

In order to better understand the results shown in FIG. 4B now consider the process of the growth of the avalanche in the discharge. It can be assumed that the electrons and those during the Duration W of the pulse generated ions during the time W in the Pulses are absent, as a result of diffusion, neutralization and, similar disappear. The frequency of occurrence of avalanches during the portion W in which a pulse is present is W. v./d, where

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ν. is the speed of the ions and d is the distance between the row walls represent in the direction of the electric field. The number of ions increases during the time W according to

(exp («d) - lj j ^W pV ^d ,

where cc and 1 represent the first and second Townsend coefficients of ionization. It can be assumed that the ions disappear as a result of diffusion and neutralization during each interval W between the pulses according to approximately exp (-W / t), where t represents time. Under these circumstances, the number of ions varies according to

jexp (£ d) - 1} J ^W pV ^d . exp (-W _D / t) (1)

during a series of intervals W + W. If the value of the equation (1) is at least equal to one, then the avalanche grows to discharge. The condition for the avalanche to grow into a discharge is then

exp («d) £ JexpfPd / (v.t) j +1 (2)

Since y and d are constants for a plasma display panel, the equation shows (2) that the ignition voltage V-, which is implicit in <X (V) and v. (V) is included, is a function of the pulse ratio P and not of the repetition rate f depends. From Fig. 4B it can be seen that the assumptions made above are acceptable and that the ignition voltage assumes its minimum when the pulse ratio is zero. That also explains the decrease in Ignition voltage obtained with the drive circuit of the second type as shown in FIG.

With this consideration it is shown that the discharge in the outer Electrode discharge display panels occurs when the condition given in equation (2) is met. In other words, no discharge occurs at the single

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a first impulse, but as a result of the application of different impulses as a result of which the ions and / or electrons that are present in the cell before the first pulse occurs, gradually increasing the current will. It is now concluded from this that the ignition voltage can be reduced by increasing the current amplification and that this is carried out can be achieved by continuously applying voltage to the cells.

Regarding the constant application of voltage to the cells is the drive circuit To be preferred to the second type because the impulses such as 41 and 42 are always present, so that the time W_ of the non-existence of the Impulse is in principle zero. under these circumstances, equation (2)

exp (* d) i 1 // + 1
and further

Apd. exp (-B (pd / V) ^1/2 J * In (I // + 1) (3),

where A and B are constants and ρ is the pressure in the cell. Equation (3) is identical to the relationship between the coefficient if and the ignition voltage of an internal electrode discharge tube. In other words, the mechanism of the initial discharge, which is initiated in an external electrode discharge display panel by pulses of alternating polarities of the same pulse height when there is no discharge (voltage resulting from the charges) in the cells, is the same as the mechanism of the discharge in one inner electrode discharge tube. This explains the delay in the initial discharge in cells that do not contain radioactive material.

Reference is made to FIG. 5 below. The average of the time lag that is required for starting the discharge after applying a voltage V to a cell of a plasma discharge panel is for various Light intensities of the cells in ambient light are shown, where the voltage V is shown on the abscissa by the ratio of the difference

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rence between the voltage V and the ignition voltage V "in the ignition voltage. It follows from Fig. 5 that the ratio as 1, 5 must be so that the delay is large shorter than a practically acceptable value of 0, 5 seconds (average) for the external electrode discharge display panel in the possible darkest ambient light of 5 lux. On the other hand, in connection with a drive circuit of the first or the second type, it becomes clear that the ratio is greater than 1.0 because the application of a voltage of V is greater than twice the ignition voltage V "(the change in voltage levels is greater than twice the ignition voltage Vp) to the row and column electrodes causes the discharge to occur in all cells arranged along the electrode, and it becomes impossible to select one or more of the cells Adjust the voltage to about two thirds of the ignition voltage V ", ie the ratio to about 0.5. Consequently, the delay is inevitably up to 20 seconds with the ambient lighting of 5 lux. In this regard, the drive circuit of the second type is unsatisfactory.

Reference is now made to FIG. 6. It has also been proven that a DC voltage V, which is higher than the ignition voltage, a pulse discharge (a current pulse with a width of less than one microsecond) in an external electrode discharge display panel evokes. The charged particles formed by the discharge give a wall voltage V in the DC voltage opposite sense. As a result, the voltage across the cell is reduced to V "-V. In particular, assume that a Pulse voltage 50 with pulses at an initial pulse height V and alternately positive and negative direction from a base DC voltage V "to a Cell of a plasma display panel by appropriate one of the row and column electrodes is created. In response to the base of the pulse 51, a pulse discharge occurs. The charged particles thereby create a wall tension, as shown at 52. The voltage applied to the cell is now determined by the difference between the pulse voltage 51 and the

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Wall tension. Insofar as the wall voltage 52 is a superposition of the wall voltage generated by applying the pulse voltage shown in FIG. 4A to the cell over the direct voltage V _n , the effects caused by the direct voltage _{component V n} of the effective voltage applied to the cell disappear after the start short-term discharge. However, the DC voltage V _n is only used at the beginning of the discharge on the cell. In this way, when the pulse voltage 51 is used, the delay is markedly reduced.

Reference is made to FIG. 7 below. A drive circuit includes conventional means for supplying first or timing selection pulse voltages as shown at (a), (b), (c) and similar pulse voltages to the first, second, third and the like row electrodes. The first pulse voltages are similar to those shown in connection with FIGS. 1 (a), (b), (c) and FIGS. 2 (a), (b) and (c). The drive current kr eis also has new second means for selectively supplying second or address pulse voltages, as shown at (d), to selected ones of the column electrodes, such as the m-th column electrode. The second pulse voltages are similar to those shown in Fig. 2 (d), but are superimposed _{on a sock DC voltage V n.} If there were no wall voltage, the pulse voltage shown at (e) would be applied to the cell of the first row, m-th column, so that a negative voltage with the absolute value V + V _{n is applied} to the cell. The ratio mentioned in connection with FIG. 5 is consequently (V _n + Av) / V. which means an unexpected reduction in delay. The voltage used on the cell of the second row, mth column in the manner shown in Fig. 7 (f) is not much different from the voltage shown in connection with Fig. 2 (f).

8 shows a circuit for superimposing a direct current component having the value V _n on a pulse voltage derived from a panel control. The circuit may have a capacitance 61 between the drive controller and each panel electrode and a rectifier 62 for setting

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of the potential of the display electrode to the DC voltage V _n .

Reference is made to FIG. 9 below. A first embodiment is fed by a DC voltage source 71 and a control signal generator and controls a plasma display panel having opposing electrodes 73 and 74. The DC voltage source 71 provides a positive DC voltage V to a first conductor 75 with respect to a second conductor 76 which is grounded. The control signal generator 72 supplies a continuous sequence φ of negative frequency pulses (referred to below as negative high-frequency pulses) to a third conductor 77, time selection pulse sequences T of positive pulses (referred to below as positive pulses) T1, T2,. . . cyclically on a plurality of fourth conductors 78 and a cell address pulse train t of selective positive pulses on at least one selected fifth conductor 79. The first embodiment comprises a plurality of pnp switching transistors 81, 82, ..., which are connected to the corresponding row electrodes 7 3, and an equal number of npn transistors 91, 92, ... connected to the respective column electrodes 74. Each of the switching transistors 81, 82, ..., 91, 92, ... is designed so that it can switch a comparatively high DC voltage, and has an emitter, a collector and a base. The emitters of the pnp transistors 81, 82,... Are connected directly to the first conductor 75. The collectors of these pnp transistors are connected directly to the corresponding row electrodes 73 and to the second conductor 76 via resistors 101. The emitters of the npn transistors 91, 92,. . are directly connected to the third conductor 77. The collectors of these npn transistors are connected to the first conductor 75 via resistors 102. Between each of the npn transistor collectors and the associated column electrodes 74, a circuit 105 superimposing a direct current component, as is described in FIG. 8, is connected. The bases of these npn transistors are connected to the second conductor 76 via resistors 106, and the corresponding fifth conductors 79 via resistors 107. The first embodiment further comprises a plurality of npn auxiliary transistors 111, 112, ..., each have an emitter, a collector and a base.

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The emitters of the auxiliary transistors 111, 112, ... are directly connected to the third Conductor 77 connected. The foil gates of these auxiliary transistors are with the collector voltage V is applied via resistors 121. The bases of these auxiliary transistors are connected to the second conductor 76 via resistors 122 and connected to the corresponding fourth conductors 78 via resistors 123. The bases of the pnp switching transistors 81, 82,. .. are with the first conductor 75 through resistors 126 and to the collectors of the corresponding Auxiliary transistors 111, 112, ... connected via capacitors 127.

During operation, the auxiliary transistors 111, 112,. . . as AND circuits, which are put into operation in response to the negative high-frequency pulse train φ and the positive time selection pulse train T1, T2, etc. When the base and the emitter of one of these auxiliary transistors 111 are acted upon by the negative high-frequency pulses and the positive pulses of the time selection pulse sequence Tl, the auxiliary transistor 111 switches on, amplifies the high-frequency pulses and delivers the current-amplified and polarity-inverted pulses to the base of the associated pnp- Switching transistor 81 via the capacitance 127 for temporarily switching on the transistor 81 during the periodically positive periods of the time pulse train Tl. In response to the temporary switching on of the pnp switching transistor 81, the voltage of the relevant row electrode 73 varies essentially between the positive voltage V and that at the relevant of the resistors 101 applied positive voltage. The npn switching transistors 91, 92, ... serve as AND circuits, which respond to the negative high-frequency pulses and the positive pulses of the address pulse trains ti, t2, etc. More precisely, the negative high-frequency pulses temporarily reduce the emitter potential of these npn switching transistors essentially to ground potential. On the other hand, raise the positive address pulses of the address pulse trains ti, t2,. . . the base potentials to supply bias voltages to the base-emitter connections of these npn switching transistors. For example, during the positive periods of the address pulse train ti, the relevant npn switching transistor 91 is temporarily turned on in response to the negative pulses, so that the voltage

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of the associated column electrode 74 drops to ground potential, the otherwise is essentially stretched to the DC voltage V. It is now understood that the voltage shown in Fig. 7 (e) across the cell or the cells between those coupled to the switching transistors 81 and 91 Row and column electrodes is applied.

As can further be seen from Fig. 9, the output impedance is the drive control circuit for considerable parts of the pulse track pairs, that are delivered to a selected cell or cells, very low, because the respective switching transistors, such as 81 and 91, are turned on during the occurrence of these considerable parts. It it is also clear that the time constant determined by resistor 126 and capacitance 127 is considerably greater than the width of the high-frequency pulses and that the resistance value of the collector resistance

101 or 102 is chosen such that the resistance and the Stray capacitance between the associated one of the electrodes 73 and 74 and the remaining one of electrodes 73 and 74 exists, is determined is smaller than the interval between the high frequency pulses. On the the other side should be the resistance value of the collector resistor 101 or

102 can be noticeably large in order to reduce the power consumption in these resistors to be reduced when the associated Sehalttransistors are switched on. For example, the capacitance between one of the electrodes 73 and 74 and the remaining of them are 30 pF, and the frequency and The pulse width of the high frequency pulses should be 50 kHz and 5 microseconds, under these circumstances the resistance value of each of the collector resistors can be 100 KiIohm.

In one example of an external electrode discharge display panel, the ignition voltage V "130 V, and the individual electrode ignition voltage, namely the ignition voltage, which is only fed to the row or column electrode or the row or column electrodes, is 220 V. The "delay of the Initial discharge was measured with the display panel in a dark

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Space was arranged and the drive control circuit according to the first embodiment with a DC voltage of 160 V from the DC voltage source 71 was applied. The delay was less than 0.5 seconds. For comparison, the delay was below measured the same circumstances with a similar drive control circuit but without the DC component superposition circuits 105. The delays were up to 80 seconds. In addition, the DC voltage was increased from the ignition voltage to the ignition voltage of the individual electrode enlarged with a drive control circuit according to the first embodiment. No malfunction was found.

In Fig. 10, a second embodiment is shown, which is similar to is the first embodiment, in which, however, the circuits 105 superimposed on the direct current component of the type shown in FIG. 8 are now also included the respective row electrodes 73 and to the row drive control circuits are connected to superimpose a direct current component -V across the row electrode voltage. The results of the measurements of the initial discharge were the same as those obtained with the corresponding circuits of the first embodiment.

It should be noted that the invention is applicable to any of the Drive control circuits of the second type that the above-described embodiments but on the third embodiment of the plasma display panel drive control circuit based », as described in German patent application P 22 56 528. 2 (Japanese patent application Syo 46-92088) is suggested. These embodiments are advantageous for the Used with a control signal generator 72 having a relatively high output impedance for the timing selection and address pulse trains and are preferred in view of the low output impedance for the cell firing pulses and the resulting high brightness of the display compared to a conventional drive control circuit of the second type.

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A third embodiment of the invention is described in FIG. 11, which is based on the first embodiment proposed in the above-mentioned patent application. The same components are provided with the same reference numerals as in the first and second embodiments. Instead of a single continuous sequence of negative high-frequency pulses, the control generator 72 now supplies a pair of continuous sequences φ and φ of positive and negative pulses to a third pair of conductors 77 and 77 '. The emitters of the npn auxiliary transistors, for example 111, are connected directly to the second conductor 76, but not to the third conductor 77 or 77 *. Instead, these auxiliary transistors with the corresponding positive time selection pulse sequences T1, T2,. .. via the positive logical AND circuits, for example 131, acted upon. Instead of the npn switching transistors, for example 91, serving as AND circuits, a plurality of pnp auxiliary transistors 132 are provided in the third embodiment, which are connected to the corresponding npn switching transistors and from the negative high-frequency pulse sequence φ and the corresponding negative address pulse sequences, for example ti, are applied via the negative logical AND circuits 133. In this context, the positive high-frequency pulses and the time selection pulses should extend from the ground potential to the collector voltage V and the negative high-frequency pulses and address pulses drop from the collector voltage to the ground voltage.

In operation, the positive logical AND circuit 131 shown in FIG is shown, briefly go through the positive rising high frequency pulses only when the positive rising time selection pulses of the Result Tl occur. The associated npn auxiliary transistor 111 causes one Current amplification of the sampled high-frequency pulses with the opposite polarity. The negative logical AND circuit 133 can be similarly the negatively falling high frequency pulses only pass through when the negatively falling address pulses of the sequence ti occur. The associated pnp auxiliary transistor 132 causes a current amplification of the sampled high-frequency pulses and reverses their polarity.

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A fourth embodiment of the invention is described in FIG. 12, which is based on the second embodiment proposed in the above-mentioned patent application. The same components are described with the same reference numerals as in the third embodiment of the invention. The bases of the pnp transistors 81 are acted upon by the negatively falling high-frequency pulse sequence φ and the negatively falling address pulse sequence ti via the negative logical AND circuits 136. The bases of the npn transistors 91 are acted upon by the positively rising high-frequency pulse sequence φ and the positively rising time pulse sequence T1, T2,... Via positive logical AND circuits 137. This embodiment is particularly advantageous if the output impedance of the control signal generator 72 is sufficiently small.

It should be remembered once again that once in a cell A discharge ignited on a plasma display panel generates charged particles. This discharge also generates photons. These charged particles and similar creeps to neighboring cells. Accordingly, the delay in the neighboring cells is reduced when the voltage is applied to them Cells during the life of the charged particle is applied. It is therefore sufficient that the DC voltage superimposed on the pulse voltage is only applied to cells where discharge is likely to begin can. Additionally, it is clear that the plasma display panel is not necessary Must have row and column electrodes but segment electrodes or may have other opposing electrodes.

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Claims (1)

Claims Drive control circuit for controlling an outer electrode discharge display panel with an array of identical gas discharge cells lying in one plane, a plurality of first electrodes and a plurality of second electrodes, the first and second electrodes being arranged on the outside of the cells with one cell each between a pair of first and second electrodes are, characterized in that the circuit has pulse generating means for selectively applying a group of pulse voltages to a selected pair of first and second electrodes with alternating polarity for generating a gas discharge in the cell arranged between the selected pair of electrodes, that the voltage is less than that Four times the ignition voltage of each of the cells and greater than twice the ignition voltage and that DC voltage superimposing means for superimposing a DC voltage on a group of the pulse voltages, the at least one predetermined pair of first and second electrodes are provided, the DC voltage not eliminating the alternating polarity of the pulse voltages superimposed by the DC voltage. 2 «Drive control circuit according to claim 1, characterized» that the DC voltage superimposing means a capacitance ■ between the pulse generating means and a of the first electrode and the second electrode of the predetermined at least one pair and that which are to be machined Means are provided for fixing one of the first or second electrodes to the potential of the direct voltage are" 309836/0391 Blank page