RU2196361C1 - Colored panel with surface gaseous discharge and method for control of it - Google Patents

Abstract

FIELD: radio engineering, in particular, display engineering, applicable in development of display elements on colored panels with a surface discharge of alternating current gas. SUBSTANCE: each pixel has a glow area in the form of a rhomb, the pixel consists of three colored display elements with a glow area in the form of a parallelogram, and these parallelograms are positioned with a mirror symmetry relative to one another. The line panels are combined in pairs. The display elements have one common scanning electrode each, which with the nearest display electrodes forms preparatory discharge gaps. Formation of the preparation discharge and address discharge at introduction of information are accomplished alternately and after each carrying-over the discharge stabilization procedures are carried out. EFFECT: enhanced contrast and reliability of control of colored panels at a high brightness and light efficiency, as well as reduced quantity of scanning electrodes. 9 cl, 6 dwg

Description

 The group of inventions relates to the display technique and can be used to develop means of display on color panels (CPUs) with a surface discharge of alternating current gas.

 Known CPU with a surface discharge of gas of alternating current, containing in each element three parallel electrodes and a control electrode separated from them by a dielectric layer located perpendicular to them, all electrodes are located on one glass plate [1]. The reasons that impede the achievement of the required technical result when using the known device include the fact that in this plasma panel with a surface discharge of alternating current gas there are no conditions for creating display elements with a phosphor with a different glow color for displaying color information.

 There is a method of controlling a plasma panel with a surface discharge of alternating current gas, which consists in the formation of preparation mode pulses, half-sample pulses in the address discharge mode for inputting information and voltage pulses for maintaining the discharge in the addressing mode [1]. The reasons that impede the achievement of the required technical result when using the known method include the fact that in the known method there are no conditions for controlling the operation of display elements for the information input mode with gradations of gray scale brightness.

 A known CPU with a surface gas discharge, in which a pixel has a luminescence area in the form of a square, and the display elements are a rectangle, each display element contains two parallel indication electrodes and a control electrode with a phosphor spatially perpendicular to it, which is separated by the color of the glow from the adjacent control electrodes by dielectric barriers, which also apply the phosphor [2]. The reasons that impede the achievement of the required technical result when using the known device include the fact that the known CPU has no conditions for displaying information with increased contrast and it is impossible to reduce the number of scanning indication electrodes.

 A known method of controlling a CPU with a surface discharge of alternating current, in which each display element contains two parallel indication electrodes and a control electrode, which consists in dividing the image frame into a brightness subfield to obtain a gray scale of gradations when entering television information and to form preparation modes in each subfield of brightness , addressing and indication [3]. The reasons that impede the achievement of the desired technical result when using the known method include the fact that in the known method there are no conditions for increasing the image contrast, since the discharge in the preparation mode occurs between the display electrodes, the background illumination occurs over the entire area of the display element and, accordingly, over the entire area of the pixel .

 The closest device of the same purpose to the claimed device in the group of inventions by the totality of features is a color panel with a surface gas discharge, in which each line contains pixels and each pixel consists of three color display elements R, G, B with a glow area in the form of a rectangle. On the back glass plate, display elements are separated by parallel dielectric barriers by the color of the glow, between which are located the control electrodes, the surface of which, together with the dielectric barriers, is coated with a phosphor. In the display element, an indicator discharge gap with a surface discharge is formed on the front glass plate with two parallel indication electrodes, one of which is scanning, and the indication electrodes are perpendicular to the control electrodes [4]. For reasons that impede the achievement of the required technical result when using the known color panel with a surface gas discharge adopted as a prototype, the number of scanning electrodes is increased in this panel due to the accepted arrangement of color display elements and there are no conditions for increasing the contrast when displaying a television information.

 The closest way to the same purpose for the totality of features is to control a color panel with a surface gas discharge, in which in each display element the indicator discharge gap is formed of two parallel indication electrodes, one of which is a scanning electrode, and control electrodes are located perpendicular to the indication electrodes interconnected by dielectric barriers, which consists in the formation of a training discharge in the display elements by general recording pulses and and erasure address discharge between the scan electrodes and the control pulses poluvyborki when entering information, and a discharge gap in an indicator indicating the discharge sustain voltage pulses between the electrodes of the display [4].

 The reasons that impede the achievement of the required technical result when using the known method adopted for the prototype include the fact that in this method of controlling the color panel there are no conditions for reliable control when entering information with gradations of the gray scale of brightness, since there are no circuit methods for creating an electrical elimination mode statistical delay of the occurrence of a discharge in the display elements before entering information, therefore, control pulses with increased amplitudes are applied second voltage, which reduces the reliability of the control circuit, and a large number of scanning electrodes in an increased number of display elements in the panel provides the required input speed information for displaying television information.

 The essence of the invention is as follows: the claimed group of inventions solves the problem of improving the operational parameters and technical parameters of display means containing colored panels with a surface discharge of alternating current gas.

 When implementing the invention, the following single technical result can be obtained: increased brightness, luminous efficiency and image contrast of a color panel; reduced number of scanning electrodes and microcircuits for entering information; the reliability of operation and control of display means as a whole has been increased by optimizing the electrical mode of the panel and reducing the voltage of control pulses.

 The specified technical result for the object - device is achieved by the fact that in a color panel with a surface gas discharge, each line contains pixels and each pixel consists of three color display elements R, G, B with a glow area in the form of a rectangle. On the back glass plate, display elements by the color of the glow are separated by parallel dielectric barriers between which the control electrodes are located. The surface of the electrodes, together with the dielectric barriers, is coated with a phosphor; in the display elements, an indicator discharge gap with a surface discharge is formed on the front glass plate by two parallel indication electrodes, one of which is scanning. Indication electrodes are arranged perpendicular to the control electrodes, the luminous area of each pixel is made in the form of a rhombus and consists of three colored display elements R, G, B with the luminous area in the form of a parallelogram, in which two sides are formed by dielectric barriers. The rows of the panel are combined in pairs and on the common border of the luminescence areas of the display elements of the combined rows are two preparatory discharge control spaces with a common scanning electrode. In each display element, the indicator discharge gap is formed by two indication electrodes, while in the combined lines, the display elements with the glow area in the form of a parallelogram are arranged with mirror symmetry between themselves relative to the common border of the combined lines in pairs.

When the luminescence area of each display element is a parallelogram, the value of one angle α between the sides of adjacent parallelograms formed by the dividing dielectric barriers of the display elements of the combined rows is selected from the range of values:
angle α = 30 ÷ 130 ^o .

In each preparatory discharge control gap, the minimum distance L1 between the edges of the indication electrode and the common scanning electrode of the indication is established from the condition for the surface discharge gap to be realized with the minimum length Lmin, while the length of the discharge gap is chosen for the minimum value of the ignition voltage depending on the parameter PL (Paschen law) where P is the gas pressure; L is the length of the discharge gap and, accordingly, L = Lmin and L1> Lmin, and the distance L2 between the edges of the remaining display electrodes is selected from the relation
L2 = (0.5-3.0) Lmin.

 In each preparatory discharge control gap, the discharge gap is closed by opaque material, in the display element, the indication electrodes, in addition to the common scanning indication electrode, are made of transparent and opaque conductors, while the transparent conductor is wider than the opaque conductor. An opaque conductor is located in the center of the transparent conductor.

 The execution in each row of the panel of the luminescence area of the pixel in the form of a rhombus, consisting of three color display elements, the luminescence area of which is a parallelogram, allows to increase the brightness and light efficiency by lengthening the dielectric barriers, at which the area of the phosphor located on these barriers is expanded. In the design of the display element, almost half of the light flux intensity comes from a phosphor located on dielectric barriers.

 Pairing lines together allows you to have one common scanning electrode on two lines with two preparatory discharge gaps that reduce the background light when preparing the panel for entering information, increase the contrast of the image, and also reduce the number of scanning electrodes and microcircuits for their control. The location of the glow areas of the display elements with mirror symmetry between the combined lines relative to the common border of these lines allows you to reduce the interaction between the display elements with the same glow color from the action of the ultraviolet radiation of the gas discharge, which propagates along the dielectric barriers of these display elements, which increases the vertical contrast of the image.

 The proposed range of values of the angle between the sides of adjacent parallelograms of the display elements of the combined lines with one glow color allows us to optimize the vertical contrast and improve the quality of the displayed information. The choice of the minimum distance between the edges of the electrodes in the preparatory discharge gap, taking into account the parameter PL (Paschen's law), allows to reduce the voltage amplitude of the control pulses. Closing the discharge gap with opaque material in the preparation discharge gap further enhances image contrast. The use of indication electrodes with a transparent conductor by increasing the area of the gas discharge allows you to further increase the brightness.

 The specified technical result when implementing a group of inventions on an object - method is achieved by the fact that in the method of controlling a color panel with a surface gas discharge, in which in each display element the indicator discharge gap is formed from two parallel indication electrodes, one of which is scanning, and perpendicular to the electrodes Indications are located control electrodes separated by dielectric barriers, which consists in the formation of a discharge of preparation in the elements of reflection by general recording and erasing pulses, an address discharge between the scanning and control electrodes, half-sampling pulses when entering information and a discharge in the indicator gap of the indication by voltage pulses of maintaining the discharge between the indication electrodes, in line display elements combined in pairs with a common scanning electrode for two adjacent preparatory discharge gaps , the formation of the discharge of preparations and the address discharge when entering information is carried out alternately and sequentially in time , first in the first of the adjacent preparatory discharge gaps, and then in the second. In this case, after entering information in each preparatory discharge gap, the voltage pulses of maintaining the discharge carry out stabilization modes of the discharge and transfer the discharge into the indicator display period with subsequent stabilization of the discharge. The number of pulses of the voltage to maintain the discharge is determined from the normalization time of the voltage level of the wall charges.

 After the end of the indication modes and the formation of a general discharge in all display elements in the preparation mode, the general erase pulses are formed by setting the voltage on the indication electrodes to zero voltage with a duration not less than the time of gas discharge deionization. After the discharge is transferred to the indicator gap during discharge stabilization and indication, the common scanning electrodes are set to a high impedance state. During discharge stabilization and indication, the control electrodes are set to a high impedance state.

 The formation of the preparatory discharge and the address discharge in two preparatory discharge gaps in time during data input allows halving the amplitude of the discharge current of the general recording pulse, which reduces the level of interference voltage in the control circuit and increases the reliability of the control of the display device as a whole. The introduction of the discharge stabilization mode in the preparatory discharge gap before the discharge transfer and the subsequent stabilization of the discharge in the indicator discharge indication gap for a certain number of pulses of the discharge maintaining voltage allow optimizing the electrical operation mode of the panel display elements, ensuring the correctness of the process of forming gray scale gradations when displaying television information.

 The formation of a general erase pulse with a zero voltage level and a time not less than the discharge deionization time provides the optimal level of discharge accumulation necessary for the occurrence of an address discharge in the preparatory discharge gap of the selected element when entering information. Setting the scanning and control electrodes in a high-impedance state during stabilization and indication eliminates the influence of these electrodes on the gas discharge process in the indicator discharge gap of the indication.

 The claimed group of inventions meets the requirement of unity of invention, since the group of equal object inventions forms a single inventive concept, moreover, one of the claimed objects of the group — a method for controlling a color panel with a surface discharge of alternating current gas — is intended for use in another object of the group — a device, with both objects of the claimed groups of inventions are aimed at solving the same problem with obtaining a single technical result. The analysis of the prior art, including a search by patent and scientific and technical sources of information, and identifying sources containing information about analogues of the claimed group of inventions, both for the object device and the object method made it possible to establish that no analogues were found for both color panels with a surface discharge of alternating current gas, and for the method of the claimed group, characterized by features identical to all the essential features of a color panel with surface discharge of alternating gas current, and the control method of the claimed group of inventions, and the determination from the list of identified analogues of prototypes for both a color panel with a surface discharge of alternating current gas and for the method closest to the combination of features of analogues made it possible to identify the set of essential technical parameters as seen by the applicant the result of the distinguishing features for each of the claimed group objects set forth in the claims.

 To check the compliance of each of the objects of the claimed group of inventions with the requirements of the inventive step, the applicant conducted an additional search for known solutions in order to identify signs that match the distinctive features of the selected prototypes for the plasma panel and control method of the claimed group of inventions, the results of which show that each of the objects of the claimed group inventions should not be obvious to a specialist from the prior art, since no technical solutions have been identified in Some increase in brightness, efficiency and contrast would be achieved due to the fact that in pixels the glow area is made in the form of a rhombus, and the glow area of colored display elements is parallelograms, panel lines are pairwise combined and parallelograms of the glow areas of the display elements of these combined lines are arranged with mirror symmetry along the common border of display elements with the same glow color.

 The alternate formation of a preparation discharge and an address discharge makes it possible to use one common scanning electrode for two display elements of combined lines, which reduces the number of these electrodes in the panel and microcircuits for their control, reduces the amplitude of the current pulse from the power source and the noise level while igniting half of all elements display in preparation mode. In addition, the discharge stabilization optimizes the operation of the panel display elements when displaying television information.

 The proposed design of the color panel and its control method are illustrated by drawings.

 Figure 1 shows a part of a color panel with a surface discharge of alternating current gas, the pixels of which have a luminous area in the form of a rhombus, and the luminescence area of the display elements is in the form of a parallelogram, the lines are paired, the display elements of these lines have common scanning electrodes.

 Figure 2 shows on an enlarged scale the color pixels of two combined lines with a common scanning electrode.

 On figa presents two display elements of two combined lines with a common scanning electrode, and on figb presents in section the display elements of two combined lines.

 In FIG. Figure 4 shows a panel of two combined lines, two display elements with a common scanning electrode; in the display elements, the display electrodes are made of transparent and opaque conductors.

 Figure 5 presents the plot of the electrical signals of the control method.

The color panel with a surface gas discharge, according to figure 1, contains a pair of 1 combined lines 1 ₍₁₎ and 1 ₍₂₎ and the next pair 2 with a line 2 ₍₃₎ , pixels P ₍₁₎ and P ₍₂₎ each with an area a diamond-shaped glow, consisting of three color display elements 3 (R), 3 (G), 3 (B), each of which has a parallelogram glow area, and each display element 3 of combined lines contains two indication electrodes 4 and a common the scanning electrode 5, which is spatially intersected by the control electrode 6. The color display elements 3 are separated by Do a dielectric barrier 7.

In figure 2, in pixels P ₍₁₎ and P _{(2) of the} combined lines, the display elements are located relative to the common border of the lines at an angle α, the value of which is selected from a range of 30 ÷ 130 degrees. The display elements 3 shown in Fig. 3a contain a common scanning electrode 5, which is located on the common border of these display elements, the dielectric barriers are located at an angle α relative to each other, which limits the propagation of discharge ultraviolet radiation between adjacent display elements of the same color of the glow of the combined lines . The common scanning electrode 5 with the nearest indication electrode forms the preparation discharge gaps with the distance between the edges of these electrodes L1, and the indication electrodes 4 form the indicator discharge gaps with the distance between the edges of these electrodes L2.

From those shown in FIG. 3b by section of the display elements 3 ₍₁₎ , 3 _(2), and FIG. 1 it can be seen that the indication electrodes 4 and the scanning electrodes 5 located on the front glass plate 8 are coated with a transparent dielectric 9 and the control electrodes 6 located on the back glass plate 10 are covered with a dielectric 11, on which phosphor 12 is applied together with dielectric barriers 7. Dielectric barriers 7 create a gap 13 ranging in size from 80 to 150 microns between the front glass 8 and the rear glass 10 plates. The gap 13 is filled with a gas mixture, for example, Ne + Xe 1% with a pressure of 500 torr. Indication electrodes 4 on the glass plate 8 form between each other indicator discharge gaps 14 ', 14 "with the distances between the edges of the electrodes L2, and the scanning electrode 5 with the nearest indication electrodes 4 form adjacent preparatory discharge control gaps 15' and 15" with the distance between the edges of the electrodes L1. Adjacent preparatory discharge gaps can be covered with opaque material 16. The scanning electrode 5 is located on the common border of 17 display elements of the combined lines 1 ₍₁₎ and 1 ₍₂₎ .

 In Fig. 4, the indicator discharge gaps 14 ', 14 "formed by the indication electrodes 4, which contain transparent electrodes 4', increase the discharge current and, accordingly, the intensity of ultraviolet radiation, which increases the brightness of the luminescence of the display elements. In the proposed control method for this color panel design with a surface discharge, according to the presented diagrams of the electrical signals in Fig. 5, the preparation discharge mode T1 is carried out at the first adjacent preparation discharge gap 15 ' m supplying pulses to the scanning electrodes 5 (Y) and display electrodes 4 (S'1) of the display elements of the first 3 lines.

In pairwise combined lines, the voltage of the general ignition pulses 18 is of positive and negative polarity of duration T1. For example, as in FIG. 1 and 4, ignition pulses are fed to the electrodes of the display elements of lines 1 ₍₁₎ , 2 ₍₁₎ from pairs of combined lines 1, 2, etc. As a result of discharge in adjacent preparatory gaps 15 'of lines 1 ₍₁₎ , 2 ₍₁₎ , etc. on the surface of the transparent dielectric 9 of the scanning electrode 5 and the nearest indication electrode 4, charges will be accumulated due to the capacitive structure of the electrodes. After the supply of ignition pulses 18, the general erasure pulses 18 'are formed on these electrodes and on the control electrodes in the form of a zero voltage level with a duration T2 no less than the time of deionization of the gas plasma. These pulses reduce the level of charges to a level insufficient for a second discharge to occur when voltage pulses are maintained to maintain discharge 19, and normalize the wall charge level in all display elements before the address discharge mode.

 To create an address discharge mode with a duration of T3, a bias voltage of 20 is set on the scanning electrodes Y, and half-sampling pulses 21, which together with half-sampling pulses 22 at the control electrodes X1, X2, etc., are formed at this voltage level. excite the address discharge in the selected display elements between the scanning and control electrodes. The duration of T3 is equal to the number of scanning electrodes multiplied by the duration of the sampling pulse 21, for example, if the number of scanning electrodes is 240 pcs., And the duration of the half-sampling pulse is 3 μs, then the duration of T3 is 240 • 3 = 720 μs.

 At the end of the address discharge mode, the discharge is transferred from the gap between the scanning and control electrodes to the preparatory discharge gap between the electrodes Y and S'1. The voltage maintenance pulses of discharge 19 are supplied to these electrodes. The number of these pulses is determined by the normalization time of the level of wall charges, the speed of the process of maximum charge accumulation depends on the gas mixture and the amplitude of the voltage pulses of maintaining the discharges. It was experimentally determined that the minimum number of pulses of the voltage to maintain the discharge should be from 2 to 5 ÷ 8.

 In FIG. Figure 5 shows an example of stabilization of a discharge in a preparatory discharge gap with two pulses of voltage to maintain a discharge at electrode Y with a time interval T4 and with two pulses of voltage to maintain a discharge at indication electrode S "2, when the discharge is transferred to the indicator discharge gap 14 'between the indication electrodes S' 1 and S ’2 during the discharge stabilization interval T5.

 After stabilization of the discharge T5, the preparation mode is performed by the general ignition and erase pulses 18 in the second adjacent preparatory discharge gap 15 "in the intervals T6, T7, which are respectively equal to the intervals T1, T2, and then in the interval T8 enter information into adjacent lines of the combined lines, as , for example, in figures 1, 2, 4, line 1 (2), etc., and after stabilization of the discharge and its transfer to the indicator discharge gap 14 "between the electrodes S" 2 and S "2 in the intervals T9, T10 occurs general display mode in the display elements of all pages ok panel. The duration of the display interval T11 when displaying information with gradations of a gray scale depends on the method of forming the brightness levels. When forming a scale of brightness levels by dividing the image frame into subfields with a fixed brightness of each subfield due to a different number of pulses of the voltage to maintain the discharge in each subfield in accordance with the binary system, for example, in the first subfield - 2 pulses, in the second - 4 pulses, in the third - 5 pulses, in the fourth - 16 pulses, etc., the value of the duration of the display intervals T11 will also correspond to the values of the binary system.

 After the indication mode in the interval T12, information is erased by quenching the discharge in all display elements of the panel in which there was a discharge during the indication mode, due to the formation of general erase pulses 18 'with a zero voltage level on all indication electrodes. These pulses reduce the level of wall charges to almost zero, which allows for the same level of accumulation of wall charges in the display elements after the action of the general ignition pulse, regardless of whether there was a discharge in the display elements before. The subsequent supply of general erase pulses with a duration of not less than the deionization time makes it possible to clearly normalize the wall charge level in all display elements before the address discharge mode, which ensures a stable process of ignition of the address discharge in all selected display elements when entering information.

 The stability of the panel is increased if, at intervals T13 and T14, the scanning electrodes are set to a high impedance state. This state of the electrodes eliminates the influence of the scanning electrode on the discharge in the indicator discharge gap. Finding the control electrodes in a high impedance state in the intervals T15, T16 stabilizes the operation of the panel display elements after entering information. Thus, a periodic cycle of inputting information with different display durations makes it possible to display information with gradations of a gray scale in the proposed color panel design, and pairwise combination of lines in which display elements are located with mirror symmetry relative to these lines increases the contrast and image quality.

Thus, the above information indicates the fulfillment of the following set of conditions when using the claimed group of inventions:
- a tool embodying the claimed group of inventions in its implementation, is intended for use in display systems containing color panels with a surface gas discharge, in particular in color video modules for TVs;
- for the claimed group of inventions, as described in the independent claims, the possibility of its implementation using the means and methods described above or known prior to the priority date is confirmed;
- a tool that embodies the claimed group of inventions in its implementation, is able to ensure the achievement of the perceived by the applicant technical result.

Sources of information
1. USA patent 4914352, CL G 09 G 3/10 dated 04/03/90

 2. Patent EP 0554172, CL H 01 J 17/49 dated 1/27/93.

 3. Patent EP 0549275, cl. G 09 G 3/28 dated 12/18/92

 4. Patent US 6088010, CL G 09 G 3/28 from 07/11/2000

Claims (8)

 1. A color panel with a surface gas discharge in which each line contains pixels and each pixel consists of three color display elements R, G, B with a total area of luminescence in the shape of a quadrangle, which are separated by parallel dielectric barriers on the back glass plate by the color of the luminescence, between which are located the control electrodes, the surface of which, together with the dielectric barriers, is coated with a phosphor, in the display elements an indicator discharge gap with a surface discharge is formed on the front glass plate by two parallel indication electrodes, one of which is a scanning indication electrode, while the indication electrodes are perpendicular to the control electrodes, characterized in that the luminous area of the pixel is made in the form of a rhombus with the luminous area of each display element in the form of a parallelogram in which two the sides are formed by dielectric barriers, and the panel lines are combined in pairs, and on the common border of the glow areas of the display elements combined with There are two preparatory discharge control spaces with a common scanning electrode located in the line, while in the combined lines the display elements are arranged with mirror symmetry between themselves relative to the common border of the combined lines in pairs. 2. The color panel according to claim 1, characterized in that when the luminescence area of the display element is parallelogram, the value of one angle α between the sides of adjacent parallelograms formed by the dividing dielectric barriers of the display elements of the combined rows is selected from the range of values: angle α = 30 ÷ 130 ^o . 3. The color panel according to any one of paragraphs. 1-2, characterized in that in each preparatory discharge control gap, the minimum distance L1 between the edges of the display electrode and the common scanning electrode is established from the condition for surface discharge at a minimum discharge gap length Lmin, while the discharge gap length is selected for the minimum ignition voltage in depending on the parameter PL (Paschen's law), where P is the gas pressure, L is the length of the discharge gap and, accordingly, L = Lmin and L1> Lmin, and the distance L2 between the edges x indicating electrode is selected from the relation
L2 = (0.5-3.0) Lmin
4. The color panel according to any one of paragraphs. 1-3, characterized in that in each preparatory discharge gap of the control of the display element, the discharge gap is closed by a opaque material.  5. The color panel according to any one of paragraphs. 1-4, characterized in that in the display element, the indication electrodes, in addition to the common scanning indication electrode, are made of transparent and opaque conductors, while the transparent conductor is wider than the opaque conductor.  6. A method for controlling a color panel with a surface gas discharge in which an indicator discharge gap is formed from two parallel indication electrodes in each display element, one of which is a scanning electrode, and control electrodes located perpendicular to the indication electrodes are separated by dielectric barriers, which consists in formation of a training discharge in the display elements by pulses of general ignition and erasure, an address discharge between the scanning and control electrodes when entering information and a discharge in the indicator gap in the mode of indication by pulses of voltage to maintain the discharge between the indication electrodes, characterized in that in the line display elements combined in pairs with a common scanning electrode for two adjacent preparatory discharge gaps, the formation of a preparation discharge and an address discharge upon input information is carried out alternately, first in the first of the adjacent preparatory discharge gaps, and then in the second, and after entering information into each m of the preparatory discharge gap, the discharge maintaining voltage pulses carry out stabilization modes for the discharge and transferring the discharge to the indicator display period with subsequent stabilization of the discharge, while the number of discharge maintaining voltage pulses is established from the normalization time of the wall charge voltage level.  7. The control method according to claim 6, characterized in that after the end of the display mode and formation of the preparation discharge by the general recording pulses in all display elements in the preparation mode, the general erasure pulses are formed by setting the voltage on the indication electrodes to zero voltage with a duration not less than the discharge deionization time gas.  8. The control method according to any one of paragraphs. 6 and 7, characterized in that after the discharge is transferred to the indicator gap during discharge stabilization and indication mode, the common scanning electrodes are set to a high impedance state.  9. The control method according to any one of paragraphs. 6-8, characterized in that during stabilization of the discharge and display mode, the control electrodes are set to a high impedance state.

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