RU2254620C2 - Method for generating charge and display element for alternating-current plasma panel - Google Patents

Abstract

FIELD: indication equipment engineering.

SUBSTANCE: method includes forming a series of charges along surface of dielectric for each indication electrode, on surface of which electrical potential relief is formed with alternating series of maximums and minimums of charge potentials of same polarity in each indication electrode of display elements. Forming of electric potential relief in indication electrode is performed by making indication electrode in form of capacity structure with constant or alternating thickness of dielectric layer, along length of display element.

EFFECT: lower consumed power due to increased light efficiency of charge, which is formed by capacity structures of indication electrodes in display elements, and also higher reliability of panel control process.

5 cl, 33 dwg

Description

The group of inventions relates to indicator technology and can be used to create plasma color AC panels for information display systems, in particular for plasma TVs and video monitors.

A known method of forming a discharge in the display elements of an alternating current plasma panel with a surface discharge between the indication electrodes, which are made of opaque conductors coated with a dielectric layer, each conductor forms a capacitor connected in series with the gas discharge gap (1). The reason that impedes the achievement of the required technical result when using the known method of forming a discharge is that in the display elements it is impossible to obtain high light efficiency of the discharge at the display frequency (100 kHz - 200 kHz) when the image frame is divided into subfields to form a gray gradation scales.

A display element of an alternating current plasma panel with a surface discharge between the indication electrodes is known, each of the indication electrodes is made in the form of a transparent conductor on which a narrow, opaque bus with high conductivity is located (2). The reason that impedes the achievement of the required technical result when using the known method of forming a discharge is that the indication electrodes in the display elements do not create conditions for obtaining high light efficiency of the discharge at an indication frequency of 100 kHz - 200 kHz.

A known method of forming a discharge in a display element, the display electrodes in which are made in the form of T-shaped transparent conductors that are connected to narrow opaque buses with high conductivity located at the boundaries of the display element (3). The reason that impedes the achievement of the required technical result when using the known method of forming a discharge is that the display elements do not create conditions for increasing the light efficiency of the discharge in the display mode, at a frequency of voltage pulses maintaining the discharge of 100 kHz - 200 kHz.

A known method of forming a discharge in the display element of an alternating current plasma panel for transferring a discharge using a transverse discharge when entering information, which is accompanied by a process of discrete accumulation of charges along the dielectric of the electrode. When applying a small amplitude of voltage to maintain the discharge to the electrodes, a series of discharges occurs, leading to a decrease in the control range of the panel and a decrease in contrast (4).

The closest method of the same purpose to the claimed method of the invention is the method of generating a discharge in the display element of an AC plasma panel with a surface discharge, voltage pulses are applied to the terminals of the display element electrodes to generate a discharge in the gas discharge gap and to accumulate charges on the surface of the dielectric covering the electrode conductors indications (5). The disadvantage of this method is that the shape of the pulses of the voltage to maintain the discharge for the proposed design of the display element does not create conditions for increasing the luminous efficiency of the display element, since with the selected shape of the pulses of the voltage to maintain the discharge, a small dynamic range of control of the panel is obtained. An additional increase in the amplitude of the voltage in the voltage pulse maintaining the discharge after the formation of the fronts increases the likelihood of a discharge between the first conductors of the display electrodes, which together form a gas discharge gap with the smallest amplitude of the occurrence of a discharge in unselected display elements.

The closest device of the same purpose to the claimed device in the group of inventions according to the shape of the design of the indication electrode is a display element in an AC plasma panel with a surface discharge, in which each electrode consists of three conductors, and the distance between the conductors is greater than the distance between the conductors in the gas discharge the gap between the indication electrodes (5). The disadvantage of this device is that in the design of the display element, the selected location of the conductors in the display electrode, taking into account the length of the gas discharge gap between the display electrodes, leads to poor control reliability when trying to increase the light efficiency of the discharge in the display element in the display mode.

The claimed group of inventions solves the problem of improving the operational and technical parameters of information display systems made on plasma color AC panels with surface discharge.

When implementing the group of inventions, a single technical result can be obtained, consisting in reducing the power consumption by increasing the light efficiency of the discharge, which is formed by capacitive structures of the display electrodes in the display elements, as well as in increasing the reliability of the panel control.

The specified single technical result in the implementation of the group of inventions in the first embodiment of the method is achieved by the fact that in the known method of generating a discharge in a display element of an AC plasma panel with a surface discharge, voltage pulses are supplied to the terminals of the display element electrodes to generate a discharge in the gas-discharge gap and to accumulate charges on the surface of the dielectric covering the conductors of the indication electrodes. In this case, in the indication mode from a voltage pulse maintaining the discharge in the gas-discharge gap between the indication electrodes, a discharge occurs, the beginning of the termination of which leads to the simultaneous initiation of the beginning of a series of discharges in each indication electrode over the surface of the dielectric, which successively occur in time along the electric potential relief. Before the onset of a discharge of the indication mode, the relief is formed in the form of an alternating sequence of maxima and minima of the potentials of charges of the same polarity in one display electrode and charges of the opposite polarity in another display electrode. Each series of discharges changes the polarity of the charges of the electric potential relief on the surface of the dielectric of the indication electrode. Moreover, with respect to the gas-discharge gap in each electric potential relief, the maximums of the potentials of the charges are located at a distance determined from the relation Lп≤Lг, where Lп is the distance between the potential maxima, Lг is the distance between the edges of the indication electrodes in the gas-discharge gap, which is chosen from the condition a surface discharge, with a length of the discharge gap, which corresponds to the value of the parameter PLg on the Paschen curve, with its location to the right of the vapor Etra PLmin for minimum firing voltage and the composition of the gas filling, where P - pressure, a Lmin - minimum length of the discharge gap. The excitation of a series of discharges along the electric potential relief over the surface of the dielectric in each indication electrode after the discharge ceases in the gas-discharge gap between the indication electrodes increases the discharge duration and, accordingly, the exposure time of the ultraviolet radiation to the phosphor of the display element, which increases the light efficiency of the display element. In accordance with the law of the parameter PLr on the Paschen curve, the selected distances between the potentials of the charges in the electric potential relief, taking into account the choice of the length of the discharge gap between the indication electrodes, make it possible to create a series of discharges on the dielectric surface of each indication electrode and stabilize the propagation process of these discharges with each change in supply voltage pulses maintaining the discharge to the display electrodes during the display mode.

The specified single technical result, when implementing a group of inventions on an object-device, in the first embodiment is achieved by the fact that in the display element of an AC plasma panel with a surface discharge, in which each electrode consists of three conductors, the distance between the conductors is greater than the distance between the conductors in the gas-discharge gap between the indication electrodes, wherein each indication electrode is made in the form of a capacitive structure of n≥2 discrete capacitors. Between the discrete capacitors gas-discharge gaps are formed, which are arranged sequentially relative to the gas-discharge gap between the capacitive structures of the indication electrodes, and in the gas-discharge gaps, the distance between the conductors is selected from the relation:

U _B ≤Usmin, where U _B is the amplitude of the voltage pulse of the discharge in the gas gap between the conductors, Usmin is the voltage of the discharge termination equal to the minimum amplitude of the voltage pulse of the discharge maintaining between the capacitive structures of the indication electrodes. In the capacitive structure of the display electrode, the conductors of discrete capacitors are made with separate leads outside the panel display field. In the capacitive structure of the indication electrode, the width of the conductors of the discrete capacitors is chosen equal to or greater than the distance between the conductors of the discrete capacitors of the gas-discharge gap. One of the indication electrodes is made in the form of a capacitive structure. In the display element, the distance between the indication electrode with a capacitive structure and the other indication electrode is selected from the relation: Lg = (1.5 ÷ 3) Lp, where Lp is the distance between the conductors of the capacitors of the gas-discharge gaps, μm, Lg is the distance between the indication electrode with the capacitive structure and another indication electrode, microns.

In the second embodiment of the invention, according to a device in a display element of an alternating current plasma panel with a surface discharge containing a gas discharge gap formed by two indication electrodes whose conductors are insulated from the gas gap by a dielectric layer, each indication electrode is made in the form of a capacitive structure of n≥2 discrete capacitors. Between the discrete capacitors gas-discharge gaps are formed, which are arranged sequentially relative to the gas-discharge gap, between the capacitive structures of the indication electrodes, while in the gas-discharge gaps and on the surface of the conductors there is a dielectric layer with a variable thickness along the length of the display element, the width of the conductors with the minimum thickness of the dielectric layer is selected from : Lшmin = V · x · t, where Lшmin is the width of the conductor with the minimum thickness of the dielectric layer, μm, V is the velocity distributed discharge type, μm / μs, t is the time between the beginning and termination of the discharge, μs, and the width of the maximum dielectric layer is selected in accordance with the relation: Lшmin≤Lmax≤Lг, where Lшmin is the width of the conductor with the minimum thickness of the dielectric layer, μm, Lmax - the width of the maximum dielectric layer, μm, Lg is the distance between the edges of the indication electrodes in the gas discharge gap, which is selected from the conditions for the surface discharge, with the length of the discharge gap, which corresponds to the value of the parameter PLg on the Paschen curve, with its location to the right of the value of the parameter PLmin for the minimum value of the voltage of occurrence of the discharge and the composition of the gas filling, where P is the pressure, and Lmin is the minimum length of the discharge gap. At the same time, in the gas-discharge gap between the indication electrodes, the dielectric layer is selected to be the minimum thickness Dmin, μm. At the minimum length Lr of the gas discharge gap, which corresponds to the value of the parameter Plmin on the Paschen curve, for the selected pressure and gas filling composition, where P is the pressure and Lg = Lmin, a dielectric layer of maximum thickness is formed in the gas discharge gap between the indication electrodes - Dmax, μm. With a minimum length Lg of the gas discharge gap, which corresponds to the value of the Pimin parameter on the Paschen curve, for the selected pressure and gas filling composition, where P is the pressure and Lg = Lmin, a dielectric layer of maximum thickness is formed in the gas discharge gap between the indication electrodes with the outermost conductors - Dmax , microns. With a minimum length Lr of the gas discharge gap, which corresponds to the value of the parameter Plmin on the Paschen curve, for the selected pressure and gas filling composition, where P is the pressure and Lg = Lmin, the thickness of each dielectric layer of the conductor of the capacitive structure of the indication electrode is selected in accordance with the ratio:

Dmax = D1> D2> D3> ...> Dn = Dmin, where Dmax = D1 is the dielectric layer of maximum thickness, μm, in the gas-discharge gap between the indication electrodes, D2 ... Dn are dielectric layers on the surface of the conductors. At the minimum length Lg of the gas discharge gap, which corresponds to the value of the parameter PLmin on the Paschen curve, for the selected pressure and gas filling composition, where P is the pressure and Lg = Lmin, the thickness of each dielectric layer of the conductor of the capacitive structure of the indication electrode is selected in accordance with the ratio:

Dmax = D1> D2> D3> ...> Dn = Dmin, where Dmax = D1 is the dielectric layer of maximum thickness, μm, in the gas-discharge gap between the indication electrodes with extreme conductors, D2 ... Dn is the thickness, μm, of the dielectric layers on the surface conductors. The maximum thickness of the dielectric layer is selected from the relation: Dmax = (1.1 ÷ 3.0) Dmin, where Dmin is the minimum thickness of the dielectric, equal to 10 μm or less. The maximum and minimum thickness of the dielectric layer are covered with a protective and emission material with different coefficients of secondary electron emission. The proposed display elements with various shapes of the design of the display electrodes allow the occurrence of a series of discharges along the surface of the dielectric of the display electrodes, taking into account the formation of an electric relief with a variable potential of charges of the same polarity.

In the second embodiment, according to the object-method, when implementing the group of inventions, in the known method of generating a discharge in a display element of an AC plasma panel with a surface discharge, in which each indication electrode is made in the form of a capacitive structure of discrete capacitors. In this case, between the gas-discharge gaps located after the gas-discharge gap between the capacitive structures of the indication electrodes, a series of discharges is formed by applying to the conductors of the discrete capacitors the gas-discharge gaps of the pulse to maintain the discharge voltage, to which an additional voltage pulse with amplitude is supplied at the time of the discharge termination in the gas-discharge gap between the indication electrodes which is determined from the relation: Ud≤Usmax - Us, where Ud is the voltage of the additional pulse, Usmax is the maximum The amplitude of the voltage to maintain the discharge, Us is the set amplitude of the voltage to maintain the discharge. The duration of additional voltage pulses is selected from the relation: tp≤td≤0.8t, where tp is the duration of the discharge, td is the duration of additional voltage pulses, t is the duration of the voltage pulse to maintain the discharge.

In the third embodiment, according to the object-method, when implementing the group of inventions, in the known method of generating a discharge in a display element of an AC plasma panel with a surface discharge, in which each electrode is made in the form of a capacitive structure of discrete capacitors, the conductors of which are formed with separate leads outside the field indication of the panel, while in the capacitive structure for occurring between gas-discharge gaps in the sequence of a series of discharges, between capacitive electrode structures indication on the conductors of discrete capacitors discharge gaps are fed successively in time the discharge sustaining voltage pulses, the fronts of which is delayed by a time duration not less prior to the termination of discharge in the discharge gap. The amplitude of the voltage pulse to maintain the discharge, the front of which is delayed for a period not shorter than the start of the discharge termination in the gas-discharge gap, is increased to the total voltage amplitude lower than the voltage amplitude of the discharge occurrence in unselected display elements by supplying additional voltage pulses. The duration of additional voltage pulses is selected from the relation: tp≤td≤0.8t, where tp is the discharge duration, td is the duration of additional voltage pulses. In the proposed methods for generating a discharge between the indication electrodes, where each indication electrode is made in the form of a capacitive structure with discrete capacitors, the implementation of the sequence of discharges increases the reliability of controlling the panel with voltage pulses for maintaining the discharge with the selected parameters and the formation of these pulses in a certain order.

The applicant conducted an additional search for known solutions in order to identify signs that match the distinguishing features of the method of forming a discharge in the display element of the claimed invention, the results of which show that the claimed invention does not explicitly follow from the prior art, since the technical solution is not known in wherein an increase in the luminous efficiency of the display element and an increase in control reliability in an AC plasma panel with a surface discharge was achieved due to the formation of a discharge in the form of a propagating series of discharges along the surface of the dielectric in each indication electrode. The conditions for the occurrence of a series of discharges are ensured by the formation of an electric potential relief of a charge of the same polarity on the surface of the dielectric of the indication electrode, and the electric potential relief is formed with the help of a capacitive structure and a dielectric layer of variable thickness, as well as with a capacitive structure, when voltage discharge pulses are maintained with the proposed parameters, and gas-discharge gaps - with a selected structure and dielectric layer of variable thickness, as well as with a capacitive structure, at the supply of voltage pulses for maintaining the discharge with the proposed parameters, and gas-discharge gaps with the selected distances between the conductors of the capacitors of the capacitive structure, taking into account the action of the Paschen law for the selected distance between the indication electrodes.

The proposed method of forming a discharge in the display element of an alternating current plasma panel is illustrated by the drawings.

Figure 1 schematically shows a display element of a prototype panel with a discharge process between the indication electrodes.

Figure 2 schematically shows a variant of the display element of another analogue of the panel with the discharge process between the indication electrodes and the diagram of electrical signals.

Figure 3 schematically shows one embodiment of the proposed display element.

Figure 4 schematically shows the processes of a discharge in a display element, according to the first method of forming a discharge.

Figure 5 shows the plot of the electrical signals of the process of the second method of forming a discharge.

6 schematically shows a display element with capacitive structures of the display electrodes and discharge processes in the element according to the third method of forming a discharge.

7 shows plots of electrical signals of the third method of forming a discharge.

On Fig shows diagrams of electrical signals of the third method of forming a discharge with additional pulses.

Figure 9 schematically shows a display element with indication electrodes, where one of the indication electrodes is made in the form of a capacitive structure, and discharge formation processes in the indication mode.

Figure 10 shows the plot of the electrical signals for the display element, where one of the display electrodes is made in the form of a capacitive structure.

11 schematically shows a display element with a variable thickness of the dielectric layer along the length of the display element.

On Fig schematically shows a display element with a variable thickness of the dielectric layer with a minimum length of the discharge gap between the display electrodes.

On Fig schematically shows a display element with a variable thickness of the dielectric layer with a minimum length of the discharge gap between the display electrodes with a maximum dielectric layer.

On Fig schematically shows a display element with a variable thickness of the dielectric layer with a maximum dielectric layer in the gas discharge gap between the display electrodes and the extreme conductors of the capacitive structure.

On Fig schematically shows a display element with a variable thickness of the minimum dielectric layer with a minimum length of the discharge gap between the display electrodes.

On Fig schematically shows a display element with a variable thickness of the minimum dielectric layer with a minimum length of the discharge gap between the display electrodes with the maximum thickness of the dielectric layer.

Plasma panel (PP) AC with a surface discharge of the prototype (figa) contains the display electrodes X1-Xn and Y1-Yn, the control electrodes A1-An. The indication electrodes in the display element 1 of the panel (Fig. 1b) are located at a distance of 2, and the conductors of the indication electrodes are at a distance of 3, while the distance 2 is less than the distance 3. On the surface of the front glass plate 4 and the conductors of the indication electrodes are coated with a dielectric 5 and electrically interconnected outside the PP indication field (figa). The control electrodes A are formed on the back glass plate 6, covered with a dielectric layer 7, on which the phosphor layer is applied 8. The control electrodes A are separated from each other by dielectric barriers, but they are not shown. Glass plates 4 and 6 of the panel are separated by a gas gap 9, the size of this gas gap is determined by the height of the dielectric barriers, which are not shown. The conductors of the indication electrodes X, Y, coated with a dielectric 5 relative to the gas gap 9, form capacitors C1, C2 and C3, as shown in FIG. 1b, 1c, 1d. If the display element was included in the PCB (Fig. 1b), then when a voltage of 180V is applied to one display electrode and a voltage of zero is applied to the other indication electrode, a negative polarity charge will be accumulated on the surface of the insulator of the indication electrode Y1, and the indication electrode XI - positive, with the potential of each charge of about 90V, which is equal to half the voltage of maintaining the discharge 180V. These charges of the capacitances of the capacitors of the indication electrodes compensate for the external electric field inside the display element; therefore, in the gas-discharge gap between the indication electrodes, the potential difference is close to zero (Fig. 1b), since the capacity of the gas-discharge gap Cg is much smaller than the capacitance of the capacitors C1, C2, and C3. When you change the polarity of the voltage to maintain the discharge on the display electrodes Y1 and XI (pigv) discharge 10 will occur, since the total voltage on the surface of the dielectric 5 between the electrodes is 360V. The occurrence of the discharge will lead to the charge of the capacitors C1, C2 and C3 with the accumulation of charge on the surface of the dielectric 5 and, accordingly, to the termination of the discharge 10, but the gas will remain in the ionized state 11 (Fig. 1d). The conductivity of the gas allows you to continue the process of accumulation of charges, as a result of which (0.2-0.3) μs after the start of the discharge, the value of the charge potential will be about 80V on the surface of each indication electrode (Fig. 1d), and during the duration of the voltage pulse (2-4) μs reaches 90V. In display element 1 (Fig. 2a), a second analogue of an alternating current plasma panel, an indication electrode, for example Y, is made of a narrow opaque conductor - bus Yш, which is usually located on a wide transparent conductor Ypr and discharge 10 occurs between the conductors Ypr and Khpr. The control electrode A of the display element 1 is located between the dielectric barriers 12. If the display element was turned on, a pulse of a voltage to maintain the discharge (Fig.2b) of positive polarity with an amplitude of + 180V was applied to the display electrode X, and a zero voltage level to the display electrode Y to maintain the discharge, then during T0 (Fig. 2d) a negative charge with a potential of 90V will accumulate on the surface of the dielectric of the indication electrode X, and a positive charge of 90V will accumulate on the indication electrode Y, on the capacitance Cg of the gas discharge gap children have zero potential. When applying a voltage pulse maintaining the discharge with an amplitude of 180V to the indication electrode Y, during T1 (Fig.2d) there will be a discharge with a duration tp = (0.1-0.3) μs, which will lead to a change in the polarity of the charges on the surface of the dielectric 5 electrodes Indications Y, X (figv). Figure 3 shows one of the options for the display elements, the design of each display electrode contains three conductors, the control electrode A is separated from the adjacent control electrodes by dielectric barriers 12. The display electrode Y consists of conductors Y1, Y2, Y3, and the display electrode X consists of conductors X1, X2, X3, which form a capacitive matrix (figure 4) of n = 3 discrete capacitors C1, C2, C3. The length Lg of the gas discharge gap 2 is greater than the length Lp of the gas discharge gap 3 between the conductors of the indication electrodes, in accordance with the ratio Lп≤Lg, as shown in figa. In the initial state T0 (Figs. 4a and 4i) between the indication electrodes, with a discharge maintaining voltage of + 200V on the indication electrode X and 0V on the electrode Y, on the surface of the dielectric of the indication electrode X there will be an electric potential relief of 13 charges of positive polarity, and the indication electrode Y electric potential relief 13 charges of negative polarity. The value of each potential maximum is conditionally approximately 100V, without taking into account the charge of the capacitance Сg of the gas-discharge gap, the charge potential of this capacitance in the considered option is practically about 2-4V, in accordance with the ratio of the capacitances of capacitors C1, C2, C3 to the capacitance Сg. This ratio in the panels is usually (25-50): 1, therefore, the value of the potential of the capacitance charge after the discharge at time T0 (Figs. 4a and 4i) can be considered equal to zero with respect to the potentials of the capacitance charges of the capacitors C1, C2, C3. To simplify the explanation of the operation of the proposed method for generating a discharge in a display element, according to the proposed figures, consider the value of all maxima of the potentials of charges on the surface of each display electrode after the process of ending a series of discharges and accumulation of charges. At present, it is impossible to measure the difference in the potential maxima in a real panel, and the potential is usually estimated by indirect methods, for example, by the intensity of the glow during the discharge. During T1 (Fig. 4b), when a voltage of + 200V is applied to the display electrode Y and 0V is applied to the display electrode, a potential difference of about 400V will appear between the capacitors C1, which will lead to the ignition of discharge 10, which will propagate along the dielectric surface of each capacitor C1 with the simultaneous process of charge onset and discharge cessation. Taking into account the magnitude of the propagation velocity of the discharge and the increase in the length of the gas-discharge gap, as well as the decrease in the potential difference due to the charge of the capacitances of capacitors C1, in accordance with the Paschen law, further propagation of the discharge over the dielectric surface will stop, but the charge accumulation process will continue. In the created plasma panels, usually (0.2-0.3) μs, the value of the accumulated charge will be about 60% - 80% of the maximum value and is determined by the gas pressure and gas composition. As shown in FIG. 4d, during T1 ′, the potentials of the charges of the negative and positive polarity of the capacitors C1 will be about 90V, and in the gas-discharge gap there will be conductivity 11. A change in the polarity of the charges will lead to the appearance of a potential of about 180V on the surface of the dielectric between the capacitors C1 and C2 , which will be sufficient for the occurrence of discharges between them during T2 (Fig. 4d), at which the capacitance C2 starts charging, since the external voltage for maintaining the discharge Us and the conductivity 11 remain. When the potential of the accumulated charges on the capacitors C2 is about 80V and the potential difference between the capacitors C2 and C3 is about 180V, discharges will occur between the capacitors C2 and C3 during T3 (Fig. 4d), and the process of accumulation of charges on the surface of the dielectric of the capacitors C2 of the indication electrodes Y, X, as shown in FIG. 4e during T0 ′, since the external discharge maintaining voltage Us and the conductivity 11 remained. During T0 '(Fig. 4g), the state of the electric potential relief will be similar as the moment T0 (Fig. 4a), only the polarity of the charges on the surface of the dielectric will change. The time plots of the electrical signals (Fig. 4i) show the shape of the voltage pulses for maintaining the discharge Us and the time moments of the formation of a series of discharges tp1, tp2 and tp3, which increase the total discharge duration Traz. Each discharge occurs after the beginning of the cessation of the previous discharge, as can be seen in Fig. 4i in the diagram of the discharge current Ip, where the total discharge duration Trz consists of the duration of three discharges tp1, tp2 and tp3. Figure 5 shows the plot of the electrical signals of the second method of forming a discharge for the design of the display element 1 with the capacitive structure of the display electrodes (figure 3). To increase the reliability of the panel, with the proposed method of forming a discharge in the display mode, the pulses of the voltage to maintain the discharge with a voltage amplitude Us between the maximum value Umax and the minimum Umin (Fig. 5) are applied to the electrodes, and after discharge 10 during T1 in the gas discharge gap 2 (FIG. 3), during T2, an additional pulse 14 is supplied with an amplitude Ud1 of FIG. 5), with a duration not less than the duration of the discharge tp1 and the charge accumulation time. After the discharge 10 '(Fig. 3), the next pulse 15 with an amplitude Ud2 (Fig. 5) is supplied during TK. The whole series of discharges tp1, tp2, tp3 forms a combined discharge with a duration of Traz. The process of forming a series of discharges for the display element shown in figure 3, with individual leads of the conductors of the capacitive structure C1, C2, C3, each electrode of the indication outside the display field (Fig.6 and 7). In the initial state at time T0, an electric potential relief 13 is formed on the surface of the dielectric 5 of each indication electrode 13 with distances Lп between the potential maxima (Fig. 6a), and a positive polarity discharge voltage of 200V is applied to all the conductors of the indication electrode X, and the indication electrode Y is supplied - zero voltage level. As shown above, the capacitance Cg of the gas-discharge gap between the indication electrodes at T0 will have an almost zero level of charge potential. When the supply voltage for maintaining the discharge is changed at time T1, when the voltage for maintaining the discharge is applied to conductor Y1, the voltage level is zero at conductor XI, a potential difference of about 400V is formed between these conductors, which leads to discharge 10 (Fig.6b). Discharge 10 is accompanied by the accumulation of charges on the surface of the dielectric of each indication electrode. The charging process leads to a decrease in potential between the conductors X1 and Y1, but there is a potential difference between the conductors of each display electrode (Fig.6c) during T0 'between the conductors X1 and X2 of the display electrode X, and the conductors Y1 and Y2 of the display electrode Y. The difference the potential between these conductors in each indication electrode becomes sufficient to initiate the occurrence of discharges 10 ', while applying a voltage of + 200V to conductor Y2 and a zero voltage level to conductor X2, as shown in Fig.6d during T2 after discharge poison in tp1 (FIG. 7) when it starts to stop. Since the conductivity 11 remains in the gas-discharge gap between the indication electrodes, the process of charge accumulation on the surface of the dielectric 5 of capacitors C1 will continue and the voltage will increase from 80V to 90V. With the subsequent supply of voltage to maintain the discharge to conductor Y3 and zero level to conductor X3 at time TK (Fig. 7), after discharge tp2, a 10 "discharge will occur with a duration tp3 (Fig. 7) between the conductors Y2 and Y3 of the indication electrode Y and between the conductors X2 and X3 of the indication electrode X (Fig.6d), the process of accumulation of charges will continue on the dielectric surface of the capacitors C1, C2. At time T0 ', as shown in Fig.4g, potential electric reliefs will be formed on the surface of the dielectric of the indication electrodes charge The total duration of the traz discharges from the series of discharges tp1, tp2, and tp3 is shown in Fig. 7. Fig. 8 shows diagrams of the electrical signals of the third method for generating a discharge with additional voltage pulses 16, 17, which are applied after the discharge tp1 in the gas discharge gap between the capacitive structures of the indication electrodes shown in Fig. 6. A display element with indication electrodes, where one of the indication electrodes is made in the form of a capacitive structure, is shown schematically in Fig. 9. In the display electrode Y with a capacitive structure contains three conductors Y1, Y2, Yc, the findings of which are located outside the display panel. The conductor Yc is the electrode through which the addressable display element is selected and in the display mode is in the high-impedance state z (Fig. 9). In the initial state (Fig. 9a), in the display element on the surface of the insulator 5 of the indication electrode Y, an electric potential relief 13 will be formed between the capacitors C1 and C2 with a potential of about 100V and charges of negative polarity, with a voltage maintaining the discharge Us = + 200 V in time T0 in FIG. 10. The voltage on the capacitance Cg of the gas-discharge gap between the indication electrodes will be about zero (Fig. 9a), in accordance with the above explanations. When T1 is applied to the Y1 conductor during voltage T1 (Fig. 9b) and the discharge support voltage Us = + 200 V to the electrode X1, a potential difference of about 400V will appear on the capacitor Cr, which will provide the appearance of discharge 10 and the process of accumulation of charges of a different polarity on the surface dielectric 5 electrodes (pigv). The accumulation of charges on the surface of the dielectric of conductor Y1 after a discharge with a duration tp1 (Fig. 10) will lead to a potential difference between the conductors Y1 and Y2 conditionally around 180V and a discharge 10 'between these conductors at the moment T2 (Fig. 9c), in the presence of conductivity 11 between conductor Y1 and display electrode X1. After a discharge with a duration tp2 at time T3 (Fig. 9d), the process of accumulation of charges will continue, in the presence of conductivity 11 of the ionized gas, and the polarity of the charges of the electric potential relief 13 will change. The total duration Trz of the current Ip of the discharge is equal to the sum of the discharges tp1, tp2, as shown in FIG. 10. Shown in FIG. 11, a display element 1 with indication electrodes Y and X, each of which is made in the form of a capacitive structure of conductors Y2, Y2, Y3 and X1, X2, X3, is isolated from the gas gap by a dielectric layer 5 with a variable thickness Dmax, Dmin, while the gas discharge gap 2 between the indication electrodes has a length Lr greater than the length Lp of the gas discharge gaps 3 between the conductors of the capacitive structure. The width Lшmin of the conductors of the capacitive structure of the indication electrodes with a dielectric layer is selected taking into account the discharge propagation velocity V for the time t of the beginning of the discharge and its termination, and the width Lmax of the maximum dielectric layer is selected taking into account the width Lшmin of the conductors with the minimum dielectric layer thickness and the length Lr of the gas discharge gap 2 between indication electrodes. Display elements 1 with a gas discharge gap 2 between the indication electrodes, the length Lg of which is less than the length Lp of the gas discharge gap 3 between the conductors of the capacitive structure and various configurations of the thickness of the dielectric layer 5 are shown in FIG. 12, 13, 14, 15, 16. In FIG. 12 schematically shows a display element with a variable dielectric layer thickness Dmax, Dmin, with a minimum length Lg = Lmin, in accordance with the value of the parameter PLmin on the curve of the Paschen law, gas discharge gap 2 between the display electrodes and with the maximum dielectric thickness of this gap Dmax, and in FIG. .13 in the display element 1, the conductors Y1, X1 of the capacitive structures of the indication electrodes also have a maximum thickness Dmax of the dielectric layer 5. A variant of the display element 1 (Fig. 14), with a variable thickness of the dielectric layer 5, in which the gas-discharge gap between the indication electrodes and the extreme conductors Y1, X1 of the capacitive structure have a maximum Dmax dielectric layer 5, and the conductors Y2, Y3, X2, X3 of the indication electrodes Y and X together with the gas discharge gaps have a minimum Dmin dielectric layer 5. In FIG. 15, 16, display elements 1 with a variable dielectric layer thickness D1> D2> D3> ...> Dn are shown with respect to each conductor Y1, Y2, Y3, X1, X2, X3 of capacitive structures of the indication electrodes and gas discharge gap 2 between them, in which an electric potential relief of charges of the same polarity is formed for a series of discharges in the indication mode. The method of forming a discharge and a structural display element (Fig. 9) was checked in a panel with an information capacity of 853 × 480 color pixels of display elements arranged in increments of 1.05 mm with an opaque electrode width of 90-100 μm. This method of forming a discharge made it possible to obtain a panel luminous efficiency of about 1.5 L / w with a dynamic controllability range of 14 V and a frequency of 120 kHz in the display mode, with an optical window transparency of 55%, along the length of the display element, and an analog (2) has 1.2 L / w, with an optical window of 84%, where the width of each bus is about 70 microns. The optical window is the area of the display element through which the light radiation passes, and it is not covered by opaque indication electrodes. The proposed group of inventions allows to increase the luminous efficiency of the panel as part of a control system with increased control reliability.

Thus, the above information indicates the fulfillment of the claimed group of inventions when using the claimed group of inventions of the following combination of conditions:

- a tool embodying the claimed group of inventions in its implementation, is intended for use in video display systems containing plasma color AC panels with surface discharge in the display element, in particular monitors and televisions;

- for the claimed group of inventions, as described in the independent claims 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 US 6100641, CL G 09 G 3/10 dated 08/08/2000

2. Patent US 6295040, CL G 09 G 3/28 dated 09/25/2001

3. Patent US 6492770, CL H 01 J 17/49 dated 12/10/2002

4. Ngo P.D.T. "Charge Transport in an AC Plasma Panel" - IEEE Transactions on Electrons Devices, 1981, V.28, No. 6, p. 659-665.

5. Application FTA WO 02/33690, cl. G 09 C 3/28 of 04/25/2002

Claims (18)

1. A method of generating a discharge in a display element of an alternating current plasma panel with a surface discharge, in which voltage pulses are supplied to the terminals of the display electrodes of the display element to cause a discharge in the gas discharge gap and to accumulate charges on the surface of the dielectric covering the conductors of the display electrodes, while in the display mode from a voltage pulse maintaining the discharge in the gas-discharge gap between the indication electrodes, a discharge occurs, the termination of which leads to one excitation of a series of discharges in each indication electrode over the surface of the dielectric, which successively occur in time along the potential electric relief, which, before the onset of the discharge of the indication mode, is formed as an alternating sequence of maxima and minima of the potentials of charges of the same polarity in one indication electrode and charges of opposite polarity in another electrode of indication, and each series of discharges changes the polarity of the charges of the electric potential of the relief on the surface of the dielectric of the indication electrode, while in each electric potential relief relative to the gas-discharge gap between the indication electrodes, the potential maxima of the charges are located at a distance determined from the relation Lп≤Lг, where Lп is the distance between the potential maxima, Lg is the distance between the edges of the indication electrodes in the gas discharge gap, which is selected from the conditions for the surface discharge when the length of the discharge gap corresponding to the value of the parameter PLg on the Paschen curve, with its location to the right of the value of the parameter PLmin, for the minimum discharge voltage and gas filling composition, where P is pressure and Lmin is the minimum discharge gap length. 2. The display element of the AC plasma panel with a surface discharge, in which each electrode consists of three conductors, the distance between the conductors is greater than the distance between the conductors in the gas-discharge gap between the indication electrodes, each indication electrode is made in the form of a capacitive structure of n≥ 2 discrete capacitors and between discrete capacitors gas-discharge gaps are formed, which are located in series with respect to the gas-discharge gap between capacitive trukturami display electrodes, discharge gaps and the distance between the conductors is selected from the relationship U _B ≤Usmin, where U _B - occurrence of discharge voltage pulse amplitude in the discharge gap between the conductors, Usmin - discharge termination voltage equal to the minimum amplitude of discharge sustain voltage pulse between capacitive structures electrodes of indication. 3. The display element of the plasma panel according to claim 2, characterized in that in the capacitive structure of the indication electrode, the conductors of the discrete capacitors are made with separate terminals outside the panel display field. 4. The display element of the plasma panel according to claim 2, characterized in that in the capacitive structure of the indication electrode, the width of the conductors of the discrete capacitors is chosen equal to or greater than the distance between the conductors of the discrete capacitors of the gas-discharge gap. 5. The display element of the plasma AC panel according to any one of paragraphs. 2-4, characterized in that one of the display electrodes is made in the form of a capacitive structure. 6. The display element of the plasma panel according to claim 5, characterized in that in the display element the distance between the indication electrode with the capacitive structure and the other indication electrode is selected from the relation Lг = (1,5 ÷ 3) Lp, where Lp is the distance between the conductors of the capacitors gas-discharge gaps, μm, Lg - the distance between the indication electrode with a capacitive structure and another indication electrode, μm. 7. A display element of a surface-discharge AC plasma panel comprising a gas discharge gap formed by two indication electrodes whose conductors are insulated from the gas gap by a dielectric layer, each indication electrode being made in the form of a capacitive structure of n≥2 discrete capacitors, between discrete capacitors gas-discharge gaps are formed, arranged in series relative to the gas-discharge gap between the capacitive structures of the indication electrodes, in gas discharge gaps and on the surface of the conductors a dielectric layer with a variable thickness is applied along the length of the display element, the width of the conductors with a minimum dielectric layer is selected from the relation Lшmin = V × t, where Lшmin is the width of the conductor and the minimum dielectric layer, μm, V is the propagation velocity discharge, μm / μs, t is the time between the beginning and termination of the discharge, μm, and the width of the maximum dielectric layer is selected in accordance with the relation Lшmin≤Lmax≤Lг, where Lшmin is the width of the conductor and the minimum dielectric layer, μm , Lmax is the width of the maximum dielectric layer, μm, Lg is the distance between the edges of the indication electrodes in the gas discharge gap, μm, which is selected from the condition for the surface discharge at the length of the discharge gap corresponding to the value of the parameter PLg on the Paschen curve, to the right of the value of the parameter PLmin , for the minimum value of the voltage of the occurrence of the discharge and the composition of the gas filling, where P is the pressure, and Lmin is the minimum length of the discharge gap, while in the gas discharge gap between the electric rows indicate the dielectric layer is selected minimum thickness Dmin, um. 8. The display element of the plasma panel according to claim 7, characterized in that for a minimum length Lg of the gas discharge gap corresponding to the value of the parameter PLmin on the Paschen curve for the selected pressure and gas filling composition, where P is the pressure and Lg = Lmin in the gas discharge In the interval between the indication electrodes, a dielectric layer of maximum thickness Dmax, μm, is formed. 9. The display element of the plasma panel according to claim 7, characterized in that for a minimum length Lg of the gas discharge gap corresponding to the value of the parameter PLmin on the Paschen curve for the selected pressure and gas filling composition, where P is the pressure and Lg = Lmin in the gas discharge In the interval between the indication electrodes with the outermost conductors, a dielectric layer of maximum thickness Dmax, μm, is formed. 10. The display element of the plasma panel according to claim 7, characterized in that for a minimum length Lg of the gas discharge gap corresponding to the value of the parameter PLmin on the Paschen curve for the selected pressure and gas filling composition, where P is the pressure and Lg = Lmin, the thickness of each the dielectric layer of the conductor of the capacitive structure of the display electrode is selected in accordance with the relation Dmax = D1> D2> D3> ...> Dn = Dmin, where Dmax = D1 is the dielectric layer of maximum thickness, μm, in the gas-discharge gap between the display electrodes, D2 .. .Dn - dielectric layers on the surface and conductors. 11. The display element of the plasma panel according to claim 7, characterized in that for a minimum length Lg of the gas discharge gap corresponding to the value of the parameter PLmin on the Paschen curve for the selected pressure and gas filling composition, where P is the pressure and Lg = Lmin, the thickness of each the dielectric layer of the conductor of the capacitive structure of the display electrode is selected in accordance with the relation: Dmax = D1> D2> D3> ...> Dn = Dmin, where Bmax = D1 is the dielectric layer of maximum thickness, μm, in the gas-discharge gap between the display electrodes with the outermost conductors , D2 ... Dn - thicknesses on, um, dielectric layers on the surface of conductors. 12. The display element of the plasma panel according to any one of paragraphs. 7-11, characterized in that the maximum thickness of the dielectric layer is selected from the relation Dmax = (1.1 ÷ 3.0) Dmin, where Dmin is the minimum thickness of the dielectric, equal to 10 μm or less. 13. The display element of the plasma panel according to any one of paragraphs. 8-11, characterized in that the maximum and minimum thicknesses of the dielectric layer are coated with a protective and emission material with different coefficients of secondary electron emission. 14. A method of generating a discharge in an display element of an alternating current plasma plasma panel with a surface discharge, each electrode in which is a capacitive structure of discrete capacitors, while a series of discharges are formed by applying to the conductors between the gas-discharge gaps located after the gas-discharge gap between the capacitive structures of the indication electrodes discrete capacitors of gas-discharge gaps of the voltage pulse maintaining the discharge, to which at the time of termination of the discharge in the gas an additional voltage pulse with an amplitude that is determined from the relation Ud≤Usmax-Us, where Ud is the voltage of the additional pulse, Usmax is the maximum amplitude of the voltage to maintain the discharge, Us is the set amplitude of the voltage to maintain the discharge, is supplied to the discharge gap between the indication electrodes. 15. The method of generating a discharge according to claim 11, characterized in that the duration of additional voltage pulses is selected from the relation tp≤td≤0.8t, where tp is the duration of the discharge, td is the duration of additional voltage pulses, t is the duration of the voltage pulse to maintain the discharge. 16. The method of forming a discharge in the display element of an AC plasma panel with a surface discharge, in which each electrode is made in the form of a capacitive structure of discrete capacitors, the conductors of which are formed with separate leads outside the panel display field, while in the capacitive structure for occurrence between gas-discharge gaps the sequence of a series of discharges located after the gas-discharge gap between the capacitive structures of the indication electrodes on discrete conductors ndensatorov discharge gaps fed sequentially in time the discharge sustaining voltage pulses, the fronts of which is delayed by a time duration not less prior to the termination of discharge in the discharge gap. 17. The method of generating a discharge according to claim 16, characterized in that the amplitude of the voltage pulse maintaining the discharge, the front of which is delayed for a period not shorter than the start of the discharge termination in the gas discharge gap, is increased to a total voltage amplitude less than the amplitude of the voltage of the occurrence of the discharge in the unselected display elements by applying additional voltage pulses. 18. The method of generating a discharge according to claim 17, characterized in that the duration of additional voltage pulses is selected from the relation tp≤td≤0.8t, where tp is the duration of the discharge, td is the duration of additional voltage pulses, t is the duration of the voltage pulse to maintain the discharge.

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