RU2214007C2 - Ac color gas panel and its control process - Google Patents

Abstract

FIELD: display engineering; ac color gas panels for information display. SUBSTANCE: novelty is that panel electrodes are functionally separated for its different modes of operation, pixel glow pads are made in the form of parallelogram, pixels of adjacent lines being disposed in mirror symmetry, and discharge stabilization process is introduced after address mode discharge in discharge transfer from preparatory discharge gap to display one for reversing surface discharge during display mode in picture element. EFFECT: enhanced contrast and reliability of panel control at higher brightness and light efficiency. 15 cl, 8 dwg

Description

 The group of inventions relates to the display technique and can be used in information display systems, in particular in color TVs with gas discharge color panels (GPC) of alternating current.

 A GPC of alternating current is known, in which a pixel has a luminescence area in the form of a square, and the display elements are a rectangle, and each display element contains two parallel indication electrodes and a spatially perpendicular control electrode with a phosphor, which are separated by dielectric barriers in color [1].

 The reasons that impede the achievement of the required technical result when using the known device include the fact that in the known GPC there are no conditions for increasing contrast and brightness. A known method of controlling an AC GCP, each display element contains two parallel indication electrodes and a control electrode, which consists in the formation of preparation, addressing and indication modes [2]. The reasons that impede the achievement of the desired technical result when using the known control method include the fact that in the known method there are no conditions for increasing contrast, since the discharge in the preparation mode occurs between the display electrodes, therefore, the background illumination occurs over the entire area of the display element and, accordingly, over the entire area pixel: from the combination of the half-sampling pulse generation circuit and the passage of the voltage pulses, the discharge is maintained in the indication mode increased heating of microcircuits of targeted electrodes. The reliability of these microcircuits decreases, because of this it is necessary to reduce the frequency of the voltage pulses of the discharge maintenance and, accordingly, reduce the brightness of the glow of the display elements.

 There is a known AC GP, containing in each display element one discharge indication gap formed by two parallel indication electrodes, which is located perpendicular to the control electrode, and the pixel has a luminous area - square, and display elements - a rectangle, while the phosphor in the display elements is located along the electrodes indication, and not along the control electrodes, while the area of the luminescence of the display element is a rectangle, and it is bounded on all sides by dividing b Riera [3]. The reasons that impede the achievement of the required technical result when using the known gas-discharge color AC panel include the fact that such an arrangement of display elements reduces the input speed by several times, which makes it impossible to use this panel design with a large information capacity of display elements for displaying television information .

 A known method of controlling an AC GCP, each display element contains two parallel indication electrodes, one of which is an address electrode and a control electrode, each display element is separated from all sides by dielectric barriers, which consists in the formation of a discharge between the address and control electrodes during information input and maintenance discharge between the indication electrodes in the information display mode [3]. The reasons that impede the achievement of the required technical result when using the known method 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 mode that eliminates the statistical the delay in the occurrence of a discharge in the display elements, before entering information, therefore, control pulses with an increased voltage amplitude are used I, which reduces the reliability of the control circuit, and the arrangement of color display elements increases the number of address electrodes, with an increased number of display elements in the panel, the necessary speed of information input for displaying television information is not provided.

 The closest device of the same purpose to the claimed device in the group of inventions in terms of features is a gas-discharge color AC panel, each line of which contains pixels, each of which 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 are located the control electrodes, the surface of which is f with dielectric barriers is coated with a phosphor. In the display elements, indicator discharge gaps with a surface discharge are formed on the front glass plate with the number of parallel indication electrodes n≥3, one of which is an address electrode and indication electrodes are perpendicular to the control electrodes. The geometric parameters of the indicator discharge gaps and their gas filling are established from the operating conditions of the reverse surface discharge in the display element during the indication [4]. The reasons that impede the achievement of the required technical result when using the known gas-discharge color AC panel adopted as a prototype include the fact that there are no conditions for creating contrast when displaying video information, and the strong electrical connection between adjacent display elements along the control electrode leads to "graininess" image, which manifests itself in the form of separate, brightly burning groups of display elements at the boundaries of brightness changes.

 The closest method of the same purpose to the claimed method in the group of inventions according to the totality of features is a method for controlling a gas discharge color AC panel. In each display element, the indicator discharge gaps are formed from n = 3 parallel indication electrodes, one of which is an address electrode, control electrodes perpendicular to the indication electrodes separated by dielectric barriers, consisting in the formation of a preparation mode in the display elements with general write and erase pulses, mode address discharge between the address and control electrodes, half-sampling pulses and the mode of reverse discharge indication by voltage pulses discharge sustain Ia. 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 increasing the image contrast and there is no way to increase the reliability of the operation of the address electrode microcircuits with increased brightness of the display elements.

 The claimed group of inventions solves the problem of improving the operational and technical parameters of display means containing gas-discharge color AC panels and technical parameters of the panel. When implementing the group of inventions, the following single technical result can be obtained: increased brightness, light efficiency and contrast of the displayed information on the panel; the reliability of the operation of microcircuits of address electrodes is increased due to the functional separation of electrodes into electrodes of preparation, addressing and electrodes for an indication mode.

 The specified technical result in the implementation of the group on the object device is achieved by the fact that in the gas-discharge color AC panel, each line of which 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 elements, indicator discharge gaps with a surface discharge are formed on the front glass plate with the number of parallel indication electrodes n> 3, one of which is an address electrode and indication electrodes are perpendicular to the control electrodes, and the geometric parameters of the indicator discharge gaps and gas filling are set from the condition the operation of a reverse surface discharge in the display element during the indication. In each display element, the address electrode consists of two conductors and is located on the line border of one side of the rectangle of the glow area of the display element parallel to one of the extreme display electrodes and perpendicular to the control electrode, while the preparatory, control, and discharge gaps are formed by the conductors of the address electrode. The pixel glow area is made in the form of a rhombus and consists of three color display elements R, G, B with the glow area of each display element in the form of a parallelogram, in which two sides are formed by dielectric barriers, while relative to the common border of adjacent lines, the glow area of the parallelogram display elements are arranged with mirror symmetry, with the luminescence area of each display element being a parallelogram, the value of one angle α between the sides of adjacent parallelograms formed will divide lnymi dielectric barrier display elements combined strings selected from a range of values
angle α = 30 ÷ 130 ^o .

On the front glass plate, the indication electrodes and the first conductor of the address electrode are located with the same step size, and the distance a ₂ between the edges of the remaining indication electrodes is selected from the relation:
a ₂ = (0.5 ÷ 3.0) a ₁ ,
and ₁ is the distance between the conductors of the address electrode, the discharge gap is closed by a opaque material. In a display element with three indication electrodes, the middle indication electrode is made of transparent and opaque conductors, while the transparent conductor is wider than the opaque conductor, and the opaque conductor is located in the center of the transparent conductor.

 The location of the address electrode made of two conductors on the border of the luminous area of the display element allows you to create a preparatory discharge gap with a reduced background illumination area during the preparation mode, which increases the contrast of the image, and the luminescence area of the element in the form of a parallelogram with mirror symmetry between the display elements between adjacent lines with a certain angle α between the sides of the formed parallelograms of the glow areas, adjacent elements tobrazheniya relatively rows can increase the contrast by reducing the vertical ultraviolet radiation along a dielectric barrier discharge.

 The uniform step of the location of the display electrodes simplifies the manufacturing process of the panels. The selected distance between the edges of the conductors of the address electrode and between the indication electrodes makes it possible to optimize the magnitude of the general recording pulses in the preparation mode and the amplitude of the voltage pulses for maintaining the discharge for a reverse indication discharge, as well as to ensure the transfer of the discharge from the preparatory discharge gap to the indicator discharge gap. Closing the discharge gap with opaque material further increases the contrast of the image. The use of transparent conductors can further increase the brightness of the glow of the display elements by increasing the area of the gas discharge. In addition, the luminous area of the parallelogram display element increases the luminous efficiency due to the lengthening of the dielectric barriers, since the area of the phosphor located on these barriers is expanded. In this design of the panel display element, almost half of the light flux comes from a phosphor located on dielectric barriers.

 The specified single technical result in the implementation of the group of inventions by the object method is achieved by the fact that in the known method of controlling a gas-discharge color AC panel, in each display element of which indicator discharge gaps are formed from n≥3 parallel indication electrodes, one of which is an address electrode, and perpendicular to the display electrodes are the control electrodes separated by dielectric barriers. In the formation of the preparation mode in the display elements by the general recording and erasing pulses, the address discharge mode between the address and control electrodes, half-sampling pulses, and the reverse discharge mode of the indication by the discharge maintaining voltage pulses.

 The preparation mode is carried out between the conductors of the address electrode by general write and erase pulses, in the addressing mode in the selected display elements, half-sampling pulses are formed on one of the conductors of the address and control electrodes, and at the end of the addressing mode, the discharge stabilization voltage pulses are maintained between the address electrode conductors, and at the next extreme display electrodes set the voltage level to zero. After the stabilization mode of the discharge between the conductors of the address electrodes, in the display elements, the discharge pulses of the voltage to maintain the discharge are transferred to the discharge gap between the nearest extreme display electrode, the conductor of the address electrodes and the discharge stabilization mode is conducted between it, and at this time other conductors of the address electrodes are set to high impedance condition, and at the following indication electrodes form a zero voltage level. In the mode of reverse discharge indication, each indication electrode, relative to which the discharge is not carried out, is set to a high impedance state. In the stabilization modes 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 display mode and after the formation of the general discharge in all display elements in the preparation mode, the total erasure pulse is formed by setting a zero voltage level on the indication electrodes with a duration of at least time deionization of the gas discharge. After the discharge is transferred to the indicator gap in the reverse discharge indication mode, the conductors of the address electrode are set to a high impedance state. During stabilization of the discharge and the reverse mode of the indication display, the control electrodes are set to a high impedance state.

 Implementation of the preparation mode between the conductors of the address electrode and the addressing mode between one of the conductors of the address electrode and the control electrode allows the function of electrical modes to separate the electrodes of the display elements, as well as circuitry to separate from the display electrodes and eliminate the passage of discharge current of the display mode in the microcircuits of the address electrode, which increases reliability the work of these microcircuits. In addition, restrictions on the increase in the frequency of pulses of the voltage to maintain the discharge are eliminated, which makes it possible to increase the brightness of the panel. The introduction of the discharge stabilization mode in the preparatory discharge gap before transferring the discharge and the subsequent stabilization of the discharge between the address electrode conductor and the nearest extreme indication electrode for a certain number of pulses of the discharge sustaining voltage allow optimizing the electrical operation mode of the panel display elements, ensuring the correctness of the process of formation of 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. The installation of the scanning and control electrodes in a high-impedance state during stabilization and indication allows eliminating the influence of these electrodes on the process of reverse gas discharge in the indicator discharge gap by the electrodes and reducing the relationship between the display elements of the same glow color vertically of adjacent rows.

 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 gas-discharge color AC panel — is intended for use in another object of the group — a device, while both objects of the claimed group of inventions are directed to solve the same problem with obtaining a single technical result. An analysis of the prior art by the applicant, including a search by patent and scientific and technical sources of information and identification of sources containing information about analogues of the claimed group of inventions for both the device object and the method object, made it possible to establish that the applicant did not find analogues for gas discharge a color AC panel, and for the method of the claimed group, characterized by features identical to all the essential features of both a gas discharge color AC panel and the control manual of the claimed group of inventions, and the determination from the list of identified analogues of prototypes of both a gas-discharge color AC panel and the method of the analogues closest in the aggregate of features made it possible to identify the set of distinctive features significant for the applicant's technical result for each of the declared objects of the group, 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 An increase in brightness, efficiency, contrast, and reliability of operation would be achieved due to the fact that the preparatory discharge gap is formed by conductors with separate terminals, and it is located on the boundary of the display element, which can coincide with the line boundary, and in pixels, the luminescence area of which is made in the shape of a rhombus, and the area of the glow of colored display elements - a parallelogram, allows you to increase the brightness, separate formation of the preparation mode, address discharge mode from the display mode allows It eliminates the passage of the discharge current through the microcircuits of the address electrodes and improves the reliability of their work by eliminating their heating. In addition, the discharge stabilization optimizes the operation of the panel display elements when displaying television information.

 The proposed design of a gas discharge color panel and a method for controlling it is illustrated by drawings.

 In FIG. 1a schematically shows the GPC pixels of two lines with a surface discharge, consisting of three color display elements, where the luminous area of each pixel is a square, and the luminous area of each display element is a rectangle, each display element contains three indication electrodes and an address electrode consisting of two conductors, and on figb in section presents a display element.

 In FIG. 2a schematically shows the GPC pixels of two rows with a surface discharge, consisting of three color display elements, where the luminous area of each pixel is a rhombus, and the luminous area of each display element is a parallelogram, in FIG. 2b, in the display elements, the middle indication electrode has a transparent conductor.

 Figure 3 schematically shows a portion of the GPC on the front side, where the screen field contains pixels having a luminous area in the form of a rhombus, and the display elements are a parallelogram.

 In FIG. 4 shows plots of electrical signals of the control method. In FIG. Figures 5 and 6 schematically present display elements in which the state of electric charges on the electrodes corresponds to various modes of operation of the panel during control.

 In the gas discharge color panel, on figa, b, the pixels P1 and P2 of lines 1 and 2 have the shape of the glow area in the form of a square, and the display elements 3 in different colors of the glow: R-red, G-green, B-blue in the form of rectangles, in each display element 3, the indication electrodes 4 form an indicator gap 4 in., and the address electrode 5, consisting of conductors 5 Pr. 1 and 5 Pr. 2, forms a preparation gap 5 under. with the distance between the edges of these conductors equal to a1. The electrodes 4, 5 and the control electrode 6 are covered with a transparent dielectric layer 7, respectively, located on the front glass plate - 8 persons. and on the rear glass - 8 rear. while the phosphor 9 is deposited on the dielectric layer 7 of the control electrode 6, on the dielectric barriers 10. The gap 11 between the glass plates of 8 faces. and 8 rear. is determined by the height of the dielectric barriers 10 and is filled with a gas mixture, for example, Ne + Xe 1% and a pressure of 500 Torr. In the display elements 3, the indication electrodes 4 and the conductor of the address electrode 5 closest to them are arranged with the same step size in accordance with the distance a2 between the edges of these electrodes, which simplifies the panel manufacturing process. For a panel with a step of 1.05 mm, “a1” is most optimal with a value of 0.08 mm, “a2” with a value of 0.15 mm, with a width of electrodes and conductors of 0.07 mm.

 The pixels P1, P2 of adjacent rows 1 and 2 in FIG. 2a are arranged relative to each other with mirror symmetry, and the sides of the display elements 3 formed by dielectric barriers 10 are at an angle α, and in the display elements 3 of the first row, the address electrode 5 is located at the boundary lines 1 and 2, and in the display element 3 of the second line, the address electrode 5 is on the border with the next adjacent line. Preparatory discharge gap 5 under on the face plate of 8 persons. closed by an opaque material 12, and Fig.2B in the indicator gap 4 in. the middle indication electrode 4 consists of a transparent electrode and an opaque electrode, which is located in the center of the transparent electrode. Transparent conductors of the middle indication electrode 4 increase the discharge current and, accordingly, the intensity of ultraviolet radiation, which increases the brightness of the glow of the display element. In the part of the gas-discharge color panel shown in FIG. 3, the screen field contains three lines in which the luminescence area of each pixel in the form of a rhombus, adjacent to each other, is arranged at an angle α, which limits the propagation of ultraviolet radiation in the display elements of the same color of luminescence vertical in these pixels and allows you to increase the contrast of the image vertically.

 The proposed method of controlling this design of the GPC allows you to display television video information. To do this, we use the method of forming the brightness levels of the gray scale of gradations by dividing the image frame into subfields with a fixed brightness of each subfield due to the different number of pulses of the voltage for maintaining 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 - 8 pulses, in the fourth - 16 pulses, etc. The maximum brightness of the selected element is obtained by burning in all subfields, and the minimum brightness of the selected display element, if the burning was in only one subfield with the least number of voltage pulses of maintaining the discharge. In accordance with this method of forming the brightness levels of the gray gradation scale, Fig. 4 presents electrical diagrams of the signals on the panel electrodes for one subfield.

 At the beginning of each subfield, a training regime consisting of two intervals T1 and T2 is carried out. In the interval T1 pulses of General record 13 positive and negative polarity by feeding them to the conductors of the address electrodes of the preparatory discharge gaps 5 under. a discharge is excited in them, while the control electrodes X are in a high impedance state. For example, for one display element, as in FIG. 4, an address electrode 5 having conductors Y1 and Y2, a positive pulse 13 is supplied to the conductor Y1, and a negative pulse of the overall recording is sent to the conductor Y2. As a result of the discharge between the conductors Y1 and Y2 on the surface of the transparent dielectric layer of these conductors, as shown in Fig. 5, the interval T1, charges are accumulated due to the capacitive structure of the electrodes relative to the gas-discharge gap between them. After the supply of pulses of the general record 13 in the interval T2, conductors 14 of general erasure 14 are formed on the conductors Y1 and Y2 and the control electrode X (Fig. 4) in the form of a zero level with a duration not less than the time of deionization of the gas plasma. These pulses reduce the level of charges to a level that is insufficient for a second discharge to occur when voltage pulses are maintained to maintain the discharge after the address discharge mode, and form a charge level, i.e. set the same level of charges on the surface of the conductors in all the address electrodes, while the polarity of the charges does not change, as shown in figure 5 (interval T2). In all figures, a change in the charge level is shown as a decrease in the number of charge signs.

 In the address discharge mode, in the interval T3 (Fig. 4), bias voltage 15 is set on conductor Y1 and, relative to this voltage level, half-sampling pulses 16 are formed, which in selected display elements together with pulses 17 on control electrodes X excite an address discharge between conductor Y1 and control electrode X (figure 5, the interval T3). At the end of the address discharge mode, to transfer the discharge from the gap between the conductor Y1 and the control electrode X and then stabilize the discharge, voltage pulses for maintaining the discharge 18 are supplied to the conductors Y1 and Y2 of the address electrode.

 When the first pulse of the voltage to maintain the discharge is applied to the conductor Y1, a discharge occurs first between the conductor Y1 and the control electrode X (Fig. 5), the interval T4a, and then the discharge between the conductors Y1 and Y2 of the address electrode (Fig. 5), the interval T4b, when the conductor Y2 is supplied with a voltage pulse maintaining the discharge 18 (figure 4). The number of voltage pulses for maintaining the discharge 18 in the interval T4 for stabilizing the discharge is determined by the normalization time of the level of charges, and the rate of charge accumulation depends on the gas mixture and the amplitude of the voltage pulses for maintaining the discharge.

 It was experimentally determined that the minimum number of pulses of the voltage to maintain the discharge should be from 2 to 5-8. During discharge stabilization, charges also accumulate on the 4S1 display electrode, because the voltage level is set to zero on this electrode. After stabilization of the discharge in the interval T4, the discharge in the interval T5 (Fig. 4) is transferred to the discharge gap between the conductor Y2 and the indication electrode 4S1 (Fig. 5), the interval T5a, then the discharge is stabilized by voltage pulses maintaining the discharge 18 with normalization of the level of charges. 6 in the interval T5b shows the charge on the conductor Y2 and the indication electrode 4S1 before transferring it to the indicator discharge gap between the indication electrodes 4S1 and 4S2. In the interval T5, charges also accumulate on the 4S2 indication electrode, since it is connected to the zero voltage level at this time. After the discharge is transferred by voltage discharge voltage pulses to the indicator discharge gap between the indication electrodes 4S1 and 4S2 in the interval T6, the mode of the reverse indication discharge (Fig.6) is the interval T6a, b, c.

 In the mode of reverse discharge indication, the discharge is alternately ignited in the discharge gaps between the indication electrodes. This discharge moves from one indication electrode to another and returns back, while the indication electrode 4, relative to which there is no discharge in the interval T7 (Fig. 4), is set to a high-impedance state, which increases the stability of the panel.

 In each subfield, the duration of the interval T6 is different and is determined by the number of pulses of the voltage to maintain the discharge 18. At the end of the display mode in the intervals T8, T9 (Fig.6), the discharge is transferred from the indicator discharge gap, and the gap between the nearest conductor 5Y2 of the address electrode and indication electrode 4S1, by forming pulses 14 of general erasure (Fig. 4), they reduce the level of charges on the panel electrodes, which is insufficient for a discharge to occur when the voltage pulses of the discharge maintain voltage again, and after that uyuschaya total feed pulses allows more accurate recording normalized level of charges in the training mode, which increases the reliability of the control panel when entering information. Separation of the discharge gaps for different panel control modes makes it possible to facilitate the electrical operation of the address electrode microcircuits, which increases the overall reliability of operation, for example, of a video module when displaying television information.

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 industry, it is on the basis of a gas-discharge color AC panel to create a video module for a TV;
- for the claimed group of inventions as described in the independent clause of the claims below, 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. Patent EP 0554172, CL H 03 J 17/19 dated 1/27/93.

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

 3. Patent US 6088010, CL C 09 G 3/28 dated 07/11/2000

 4. Patent US 6229504 B1, CL S 09 G 3/10 dated 05/08/2001

Claims (15)

 1. A gas discharge color AC plasma panel, each side of which contains pixels, consisting of three color display elements R, G, B with the area of the glow formed by a rectangle, separated by the color of the glow by parallel dielectric barriers located on the back glass plate, between which are located control electrodes, the surface of which, together with the dielectric barriers, is coated with a phosphor, perpendicular to the control electrodes on the front glass plate parallel indication electrodes, while each display element contains n≥3 indication electrodes, one of which is an address electrode, between which during indication a reversible surface discharge is carried out, characterized in that in each of the display elements located on the same discharge line colored AC panel, an address electrode consisting of two conductors is located on the side of the rectangle of the luminescence area of the display element, bordering the next line, while between a preliminary discharge gap is formed by the conductors of the address electrode, and one of the indicator discharge gaps is formed between one of the conductors of the address electrode and a display electrode adjacent to it.  2. The gas-discharge color AC panel according to claim 1, characterized in that on the front glass plate the indication electrodes and the conductor of the address electrode closest to them are located with the same step size. 3. The gas-discharge color AC panel according to claim 1, characterized in that in each display element, the distance a ₂ between the edges of the display electrodes is selected from the ratio a ₂ = (0.5 ÷ 3.0) a ₁ , where a ₁ is the distance between the edges of the conductors of the address electrode.  4. The gas-discharge color AC panel according to claim 1 or 3, characterized in that between the conductors of the address electrode, the discharge gap is closed by a opaque material.  5. A gas discharge color AC panel according to any one of claims 1, 3 or 4, characterized in that in the display element with three indication electrodes, the middle indication electrode is made of transparent and opaque conductors, while the transparent conductor is wider than the opaque conductor, and an opaque conductor located in the center of the transparent conductor. 6. A gas discharge color plasma AC panel, each side of which contains pixels with a luminance area formed by a rhombus, consisting of three color display elements R, G, B with a luminescence area formed by a parallelogram, separated by the color of the glow by dielectric barriers located on the rear glass a plate forming two sides of the parallelograms of the glow areas of the display elements containing control electrodes located on the back glass plate, the surface of which together with dielectric barriers, it is covered with a phosphor, parallel indication electrodes located on the front glass plate perpendicular to the control electrodes, each display element contains n≥3, one of which is an address electrode, between which a surface discharge is performed during the indication, characterized in that the parallelograms of the areas of the glow of the display elements relative to the common border of adjacent rows are located with mirror symmetry, and the sides of the parallelograms n the illumination of the display elements formed by the dividing dielectric barriers, with respect to the common border of adjacent lines form an angle α = 30-130 ^o , while in each of the display elements located on the same line of the gas-discharge color AC panel, an address electrode consisting of two conductors, located on the side of the parallelogram of the luminescence area of the display element adjacent to the next line, while a preparatory discharge gap is formed between the conductors of the address electrode k, and between one of the conductors of the address electrode and a nearby indication electrode one of the indicator discharge gaps is formed.  7. The gas-discharge color AC panel according to claim 6, characterized in that on the front glass plate the indication electrodes and the conductor of the address electrode closest to them are located with the same step size. 8. The gas-discharge color AC panel according to claim 6, characterized in that in each display element the distance a ₂ between the edges of the display electrodes is selected from the relation a ₂ = (0.5 ÷ 3.0) a ₁ , where a ₁ is the distance between the edges of the conductors of the address electrode.  9. A gas discharge color AC panel according to any one of claims 6 and 8, characterized in that the discharge gap is closed between the conductors of the address electrode by a lightproof material.  10. A gas discharge color AC panel according to any one of claims 6, 8 and 9, characterized in that in the display element with three indication electrodes, the middle indication electrode is made of transparent and opaque conductors, while the transparent conductor is wider than the opaque conductor, and opaque The conductor is located in the center of the transparent conductor.  11. A method for controlling a gas-discharge color AC panel, each display element of which contains n≥3 indication electrodes, between which a reverse surface discharge is carried out during indication, while one of the indication electrodes is an address electrode consisting of two conductors, between which is formed preparatory discharge gap, and between one of the conductors of the address electrode and a nearby indication electrode one of the indicator discharge gaps is formed, elements from the brazings are separated by parallel dielectric barriers located on the back glass plate, between which control electrodes are located perpendicularly to the indication electrodes, consisting in the formation of a preparation mode in each display element between the conductors of the address electrode with general write and erase pulses, and formation of the address discharge mode in the selected elements display between one of the conductors of the address electrode and the control electrode pulses of half-sampling, while other e the conductors of the address electrodes are set to a high-impedance state, the discharge stabilization mode is conducted between the conductors of the address electrode at the end of the address discharge mode in the selected display elements by the voltage pulses to maintain the discharge, while the voltage level closest to the address electrodes is set to zero, after the discharge stabilization mode between the conductors of the address electrodes discharges the pulses of voltage to maintain the discharge transferred to the discharge gap between one of the conductors of the address electrode and the nearest indication electrode, a discharge stabilization mode is carried out between them, while the other conductors of the address electrodes are set to a high-impedance state, and a voltage level of zero is formed on the following indication electrodes, then the discharge is transferred to discharge the gap between the indicating electrode closest to the address electrode and the following indicating electrode, after which the reverse mode Nogo surface discharge, wherein the discharge is successively ignited in the discharge gaps between display electrodes in the display elements, each display electrode with respect to which no discharge is performed is set in the state vysokoimpendansnoe.  12. The control method according to claim 11, characterized in that in the preparation mode when applying the general recording pulses to the conductors of the address electrodes, the control electrodes are set to a high-impedance state, and the general erase pulses of a duration not less than the deionization time of the gas discharge are formed by setting the address conductors on the conductors electrodes and control electrodes of zero voltage level.  13. The control method according to claim 11, characterized in that in the stabilization modes of the discharge the number of pulses of the voltage to maintain the discharge is set from the normalization time of the voltage level of the wall charges.  14. The control method according to claim 11, characterized in that after the end of the display mode, a general erase pulse of duration not less than the deionization time of the gas discharge is formed by setting the voltage level at the indication electrodes to zero.  15. The control method according to claim 11 or 13, characterized in that after the discharge is transferred to the indicator gap in the reverse indication mode, the conductors of the address electrode are set to a high-impedance state.

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