EP0905670A1 - Simplification of the addressing of a microtips display with resetting electrode - Google Patents

Abstract

The display screen has a micro-point cathode emitting electrons and an associated grid to extract the electrons. The cathode/grid is formed from conductive rows (15') which can be addressed sequentially and perpendicular columns (14') that can be addressed individually and simultaneously during addressing of the rows. A return electrode (30) set to a positive potential is connected via a resistance to each grid or cathode row.

Description

The present invention relates to the field of screens microtip viewing dishes.

Figure 1 shows schematically the structure of a flat screen with microtips of the type to which the invention relates.

Such a microtip screen essentially consists a cathode 1 with microtips 2 and a grid 3 provided with holes 4 corresponding to the locations of the microtips 2. The cathode 1 is placed opposite a cathodoluminescent anode 5 of which a glass substrate 6 generally constitutes the surface screen.

Cathode conductors are arranged in columns on a glass substrate 10. The microtips 2 are produced on a resistive layer 11 deposited, for example, on the conductors cathode and are conventionally arranged inside meshes defined by the cathode conductors. Figure 1 partially represents the interior of a mesh, the conductors cathode do not appear in this figure. Cathode 1 is associated with grid 3 which is organized in lines. The intersection of a row in grid 3 and a column in the cathode 1 defines a pixel.

This device uses the electric field created between the cathode 1 and grid 3 so that electrons are extracted from microtips 2 to phosphor elements 7 of the anode 5. In the case of a color screen, as shown in Figure 1, the anode 5 is, for example, provided with alternating strips of elements phosphors 7, each corresponding to a color (blue, Red Green). The bands are separated from each other by a insulator 8. The phosphor elements 7 are deposited on electrodes 9, consisting of corresponding strips of a layer transparent conductor such as indium tin oxide (ITO). The sets of blue, red, green bands are alternately polarized with respect to cathode 1 so that the electrons extracted from microtips 2 of a pixel of the cathode / grid are alternately directed towards the phosphor elements 7 opposite each of the colors. In the case of a monochrome screen (not shown), the anode consists of a plan of phosphors of the same color or of two sets alternating bands of phosphor elements of the same color.

The present invention relates more particularly to the cathode / grid of such a screen.

Figures 2A to 2D illustrate an example of structure conventional cathode / microtip screen grid, Figures 2B and 2D being respectively enlargements of parts Figures 2A to 2C. Multiple microtips 2, for example sixteen, are arranged in each mesh 12 defined by the cathode conductors 13 (Figure 2B). The intersection of a line 14 of grid 3 and a column 15 of cathode 1 corresponds here, for example, at sixty-four meshes 12 of a pixel of cathode (Figure 2A).

Cathode 1 generally consists of layers successively deposited on the glass substrate 10. The figures 2C and 2D partially represent a sectional view according to the line A-A 'in Figure 2B. A conductive layer is deposited on the substrate 10. This layer is etched in a pattern of columns 15, each column having meshes 12 surrounded cathode conductors 13. A resistive layer 11 is then deposited on these cathode conductors 13. This resistive layer is intended to protect each microtip 2 against an excess of current when starting a microtip 2. Such a resistive layer 11 homogenizes the electronic emission of the microtips 2 of a pixel of cathode 1 and thus increases its lifespan. The resistive layer is deposited, either on the conductive layer constituting the cathode conductors, either under this layer conductive as described in the document EP-A-0 696 045. An insulating layer 16 is deposited on the layer resistive it to isolate the cathode conductors 13 from the grid 3 (Figure 2D), formed in a conductive layer. Of holes 4 and wells 17 are respectively made in the layers 3 and 16 to receive the microtips 2.

To avoid current leakage from one column to another of the cathode (which cause excessive heating of the cathode which can lead to a screen break during operation), the resistive layer 11 must, most often, be engraved, in columns corresponding to the columns (15, Figure 2A) of the cathode. Such an engraving requires a separate mask from that used for making cathode conductors, the resistive layer not being meshed.

FIG. 3 illustrates schematically and in perspective, an example of conventional addressing of a microtip screen.

For reasons of clarity, the mesh of the columns K of cathode 1 has not been shown. Likewise cathode 1 a been shown discarded from grid 3 while, in practice, the vertices of the microtips 2 arrive at the level of the holes 4 performed in grid 3. In addition, only nine microtips per pixel have been shown. In practice, they are among several thousand per pixel of screen. On the anode 5 side, the surfaces pixels P are shown in phantom.

An image is displayed for a period of time image (for example, 20 ms for a frequency of 50 hertz) in suitably polarizing the anode 5, the cathode 1 and the grid 3 by means of an electronic control circuit (partially shown for the grid control).

Being a monochrome screen anode 5, the plane phosphor elements of the anode is permanently polarized at a potential Va making it possible to attract the electrons emitted by the microtips 2. This potential is chosen taking into account, in particular, the distance between the cathode / grid and the anode and is, for example, of the order of 400 volts. For a color screen, the bands of phosphors of the anode are sequentially polarized by a set of bands of the same color during a frame time corresponding to a third of the reduced image time times required for switching.

The display is done line by line, polarizing sequentially the lines L of the grid 3 during a "time of line "during which each column K of cathode 1 is carried at a potential Vk which is a function of the brightness of the pixel at display along the current line (for example, Lj). Polarization columns K of cathode 1 changes with each new line. A "line time" (for example 40 µs) corresponds to the duration of a frame divided by the number of lines L of the grid 3. The current line Lj is brought to a potential + Vg (by example, 40 volts) while the other lines Lj-1, Lj + 1 are at a potential -Vg (for example, -40 volts) during this time of line. Columns K of the cathode are brought to potentials respective Vk (i-1), Vk (i), Vk (i + 1) between a potential maximum emission potential and no emission potential (for example, respectively 0 and -40 volts) representing, for each line, the brightness of the pixel defined by the intersection of the column K and row L. The choice of the values of the potentials of polarization is related to the characteristics of the phosphor elements and microtips. Conventionally, below a potential difference of around 40 volts between cathode 1 and grid 3, there is no electronic transmission, and the transmission maximum used corresponds to a potential difference about 80 volts.

The lines of grid 3 addressed sequentially are individually controlled by an amplifier 20, generally essentially consisting of two MOS transistors P and N connected in series between two supply lines at potentials + Vg and -Vg. The midpoint of serial association of transistors P and N is connected to the grid line to which the amplifier 20 is associated and the MOS transistors, respectively P-channel and N-channel receive signals on their gates control (not shown) adapted to successively polarize lines with high potential + Vg, all unaddressed lines being brought to low potential -Vg. It is indeed necessary to reduce the unaddressed lines to the potential -Vg so as to avoid that a previously addressed line has sufficient potential allowing the extraction of electrons.

A disadvantage of conventional screens is that amplifiers 20 must be made in CMOS technology, this which increases the cost of the control circuit. In addition, as a amplifier per line is required, the number of amplifiers CMOS technology is far from negligible compared to the size and overall cost of the ordered.

It has already been proposed to simplify the structure of the amplifiers control the grid lines leaving the lines not addressed to a floating potential. Such a solution requires the use, on the cathode side, of an additional column of microtips constituting a so-called zero reset electrode unaddressed grid lines. Such a solution is described in French patent application No. 2 687 841. The lines of grid are extended there from one side of the screen to a column additional cathode. This cathode column is addressed independently of the other columns and is carried, between each line time, at a sufficiently low potential compared to at nominal grid bias potential to allow an electronic transmission by this reset column to zero. The electrons then emitted by the microtips of this column are intended to fall back onto the grid line coming to be addressed to lower its potential.

If such a solution allows to use only one transistor by gate line addressing amplifier, it has several drawbacks.

First of all, this solution requires the addition an additional cathode column, and this column should, in practice, be located outside the active area of the screen, that is to say the display area, which increases the size of the screen. In addition, the fact that the additional electrode is placed at one end of the grid lines leads that the lowering of the potential of the line that has just been addressed the longer the grid lines are. This is why this document plans to add a second reset column at the other end of the screen. That further increases the size of the screen surface without constitute an optimal solution. In addition, provide reset columns distributed among display columns cathode is an unsuitable solution. All first, you have to move aside the display columns of the cathode which affects the resolution of the screen, the surfaces of reset columns to be important to issue enough electrons to quickly lower the potential of the grid lines. In addition, it makes it more complex the realization of the anode, which must then be polarized at a potential lower than the addressing potential of the lines of grid, to allow to repel the electrons emitted by the reset column to grid. In addition, there is that the electronic emission by the additional column (s), between each line time, harms the lifespan of the screen.

According to a first aspect, the present invention aims to propose a new solution to simplify the structure of sequential addressing amplifiers of the scan lines of a flat display with microtips.

The present invention aims, in particular, to propose a solution that does not require electronic transmission.

The present invention also aims to provide a solution which does not lead to an increase in the surface of the screen, nor to a decrease in the resolution of a conventional screen.

The present invention also aims to provide a solution which does not require modification of the anode of a classic screen.

According to a second aspect, the present invention aims also that the simplification of amplifier structure of sequential addressing of the lines is accompanied by a simplification of the method for producing the screen cathode.

To achieve these objects, the present invention provides a flat display screen, comprising a cathode with electronic emission microdots associated with an extraction grid of microdots, the cathode / grid comprising grid or cathode conductive lines suitable for be addressed sequentially, and cathode columns or grid respectively perpendicular to said lines and proper to be addressed individually and simultaneously during line addressing, the screen further comprising an electrode recall capable of being biased at a recall potential corresponding to a potential for absence of electron extraction, each grid or cathode line being connected, via at least one resistive element, to the return electrode.

According to an embodiment of the present invention, the return electrode consists of conductive lines, inserted between two neighboring lines of the grid or cathode, and interconnected to the return potential.

According to an embodiment of the present invention, said grid or cathode lines and the electrode lines recall are made in the same conductive layer engraved, each line of the return electrode being spaced from two lines adjacent to the grid or the cathode.

According to an embodiment of the present invention, a resistive layer is present on or under said layer conductive.

According to an embodiment of the present invention, each line of the grid is associated with a control amplifier one output stage of which exclusively comprises a transistor P channel MOS, sandwiched between a high addressing potential and the line, the return electrode being polarized at a low potential.

According to an embodiment of the present invention, each conductive line of the return electrode is dimensioned to form a resistive element between a grid line neighbor and the potential for recall.

According to an embodiment of the present invention, each line of the cathode is addressable by an amplifier control of which one output stage exclusively comprises a transistor N-channel MOS, sandwiched between a low addressing potential and the line, the return electrode being polarized at a high potential.

According to an embodiment of the present invention, the microtips are deposited on said resistive layer forming a resistive element between each cathode line and the electrode reminder.

According to an embodiment of the present invention, the return electrode consists of conductors, interposed between the grid columns and separated from the conductive layer in which the lines of the cathode are formed, by the resistive layer.

According to an embodiment of the present invention, the reminder electrode is polarized between the addressing periods of two successive lines, and is left floating for addressing lines.

les figures 1 à 3 qui ont été décrites précédemment sont destinées à exposer l'état de la technique et le problème posé ;

la figure 4 représente, vu de dessus, un premier mode de réalisation d'une grille selon la présente invention associée à une cathode classique ;

la figure 5 représente, partiellement et en perspective coupée, un deuxième mode de réalisation d'une grille selon la présente invention associée à une cathode classique ;

la figure 6 représente, partiellement et en perspective coupée, un troisième mode de réalisation d'une grille selon la présente invention associée à une cathode classique ;

la figure 7 représente, vu de dessus, un mode de réalisation d'une cathode/grille selon un deuxième aspect de la présente invention ; et

la figure 8 représente, partiellement et en perspective coupée, la cathode/grille de la figure 7.

These objects, characteristics and advantages, as well as others of the present invention will be explained in detail in the following description of particular embodiments given without limitation in relation to the attached figures among which:

Figures 1 to 3 which have been described above are intended to show the state of the art and the problem posed;

FIG. 4 represents, seen from above, a first embodiment of a grid according to the present invention associated with a conventional cathode;

FIG. 5 represents, partially and in cut perspective, a second embodiment of a grid according to the present invention associated with a conventional cathode;

FIG. 6 represents, partially and in cut perspective, a third embodiment of a grid according to the present invention associated with a conventional cathode;

FIG. 7 represents, seen from above, an embodiment of a cathode / grid according to a second aspect of the present invention; and

FIG. 8 represents, partially and in cut perspective, the cathode / grid of FIG. 7.

The same elements have been designated by the same references to the different figures. For reasons of clarity, the representations of the figures are not to scale and only the elements necessary for understanding the invention were shown in the figures and will be described later.

A feature of the present invention is bring each scan line that has just been addressed to a potential corresponding to a potential for no electronic emission, by means of an ohmic contact of this line of scanning with a return electrode polarized at this potential.

As before, a screen according to the present invention consists of a microtip cathode associated with a grid, the cathode / grid being placed opposite an anode cathodoluminescent provided with phosphor elements. The display an image is performed by sequentially addressing electrodes in rows of the grid or cathode, electrodes in perpendicular columns of the cathode or grid being addressed simultaneously and individually during addressing of each line to fix the respective brightness of the pixels defined by the intersections of the columns with the current row. In the case of a color screen, the brightness of the color component of the corresponding pixel, the anode being, by example, with three sets of alternating bands of elements phosphors of different colors. In a monochrome screen, we set the gray level of the corresponding pixel, the anode consisting of a plane of phosphor elements of the same color or two sets of alternating bands of phosphor elements of the same color.

According to a first aspect of the present invention, of which several embodiments are illustrated by FIGS. 4 to 6, the scanning electrodes are formed by lines grid conductors. The cathode is then, according to this first aspect, a classic cathode organized in columns whose addressing is also carried out in a conventional manner.

According to this first aspect of the invention, each line of the grid is connected, via at least one element resistive, to a so-called reset or return electrode, polarized at a low potential corresponding to a potential at which the grid lines prevent the emission of electrons.

FIG. 4 represents, partially and in top view, a first embodiment of a cathode / grid according to the first aspect of the invention.

For reasons of clarity, only one hole 4 has been shown in each row 14 of the grid at the intersection of a column 15 of the cathode.

Each line of the grid is individually addressable and sequentially, by means of a control amplifier 21. According to the invention, each amplifier 21 consists of a single MOS transistor, here with P channel, connected between a potential top of addressing + Vg and the corresponding line. Each transistor P is, for example, controlled by a two-state signal C, a given line being addressed when the signal C is in a low state, i.e. at a potential sufficiently lower than the potential + Vg to turn on the corresponding transistor P. Unaddressed lines are therefore left to a floating potential from the point of view of the control amplifiers 21 of these lines.

According to the embodiment of Figure 4, each line 14 of the grid is connected, via a section resistive 22, to a conductor 23 polarized at a low potential -Vg. The sections 22 are, for example, made up of a conductor very fine so as to make the contact between each resistive line 14 and conductor 23.

Thanks to the resistive contacts 22, each line 14 of the grid is, at the end of addressing, reduced to a sufficiently sufficient potential low to prevent any electronic emission by this line. The dimensioning of the resistive sections 22 depends on the functional characteristics of the screen, and in particular respective values of the addressing potentials.

The sections 22 are produced, preferably, at the same time as the construction of lines 14. The sections 22 are preferably made of the same material as lines 14 and electrode 23, from a layer conductive deposited on the insulation layer (16, Figures 2C and 2D) separating the grid from the cathode.

The return electrode is, for example, polarized in permanence at potential -Vg. In this case, a dissipation appears in the resistive element connecting a line being addressed to the return electrode. To remove this dissipation during addressing, provision may be made not to polarize the electrode as a reminder that between two line times. In this case only dissipation that occurs while the return electrode is polarized is related to the recall, towards the low potential, of the line electrode that has just been addressed.

As a particular example, for a screen of approximately 13 cm diagonal (5 1/4 inches), sections 22 can be made up of conductors 120 mm long and 12 µm wide. With a material (e.g. niobium) having resistance square of 4 Ω, we obtain a resistance of 40 kΩ by section 22. If the potential + Vg is 80 volts, the potential -Vg being the mass and the addressing potentials Vk of the columns being between 0 and 40 volts, the leakage current linked to the section 22 is of the order of 2 mA, which causes dissipation about 160 mW. Of course, the layout of the sections 22 may have various shapes (serpentine, zigzag, etc.) allowing achieve the desired resistance depending on the space available.

Figure 5 illustrates, in a partial perspective view cut, a second embodiment of a cathode / grid a microtip screen according to the first aspect of the invention.

Cathode 1, produced on a substrate 10, for example glass, consists of 13 conductors organized in columns from a conductive layer. A first resistive layer 11 of homogenization of the electronic emission is interposed between the cathode conductors 13 and the microtips 2 which are deposited on this resistive layer. The structure of the cathode shown in Figure 5 can be similar to that illustrated by Figures 2A to 2C. Alternatively, the layer resistive may be deposited under the cathode conductors, the microtips 2 being preferably deposited on the layer resistive 11, in the center of the mesh defined by the conductors cathode. Cathode 1 is separated from grid 3 by a layer insulator 16 and the grid is formed in a conductive layer 24, engraved according to a pattern of lines 14 perpendicular to the cathode columns. According to the invention, additional conductors 27 are inserted between the lines 14 of the grid. These conductors 27 are interconnected at one of their ends and constitute the return electrode at low potential -Vg (figure 4). Each line 14 of the grid is addressed by an amplifier 21 as shown in FIG. 4.

According to the embodiment of Figure 5, a layer resistive 26 is added to layer 24 in which are lines 14 and 27 constitute each line 14 of the grid 3 is therefore, laterally, in resistive contact with two conductors 27.

An advantage of this embodiment compared to embodiment illustrated in Figure 4 is that the resistance of contact between grid lines 14 and lines 27 is homogeneous along lines 14.

Figure 6 illustrates a third embodiment of the first aspect of the invention which differs from the embodiment exposed in relation to FIG. 5, by the fact that the resistive layer 26 ′, for organizing resistive contacts between lines 14 of grid 3 and intermediate lines 27 of the return electrode is under the conductive layer 24 '.

Note that, in the two embodiments illustrated by figures 5 and 6, no additional masking step is not necessary compared to a conventional method of fabrication of a cathode / grid. We simply add a step deposit (the second resistive layer) and an etching step holes in the resistive layer (in the same etching mask than the one conventionally used to etch the insulating layer 16).

An advantage of the present invention is that it simplifies the constitution of line control amplifiers without the need to transmit electronics by dedicated microtips, which improves the lifespan of the screen.

Another advantage of the present invention is that the fine conductors 22 (Figure 4) or intermediate lines 27 (Figure 5, 6) of the return electrode may be of a bulk low enough to be inserted between each line 14 of the grid without affecting the resolution of the screen.

A second aspect of the present invention will be described thereafter in relation to FIGS. 7 and 8.

According to this second aspect of the invention, the electrodes sequentially addressed scans consist of conductor lines of the microtip cathode, and the electrodes addressed simultaneously consist of columns grid conductors.

FIG. 7 represents, partially and seen from above, an embodiment of a cathode / grid according to this second aspect. FIG. 8 is a partial view, in cut perspective, a cathode / grid according to this embodiment.

Here, the scanning line recall electrode is intended to be in resistive contact with the lines of the cathode.

In the embodiment shown in Figures 7 and 8, a conductive layer 28 is deposited full plate on the substrate 10. This layer 28 is etched according to a definition pattern 15 'cathode lines and intermediate conductors 29 of the return electrode. Although it is not shown in FIGS. 7 and 8, the lines 15 ′ of the cathode are preferably engraved with a mesh pattern (12, Figure 2A, 2B). A resistive layer 11 is deposited full plate on (or under) cathode conductors and intermediate conductors 29. The intermediate conductors 29 interposed between the lines 15 ' are interconnected at one end of the screen and the interconnect line 30 (Figure 7) is intended to be polarized to a high potential + V1 corresponding to a potential for no emission electronic. Each 15 'line can be addressed individually by means of a control amplifier 32 (FIG. 7), essentially consisting here of an N-channel MOS transistor connected between the end of line 15 'and a low potential -V1 for addressing the line concerned. The N transistors are sequentially controlled by signals C 'with two states, one line being addressed when signal C 'is in a high state (at a potential greater than the potential -V1) making the conductor transistor N. Unaddressed lines are left floating by their respective control amplifiers 32.

As in the case where the grid constitutes the electrodes scanning, the return electrode is permanently polarized, or temporarily at the end of each line time.

The resistive layer 11, deposited full plate on the lines 15 'and 29, forms a resistive bond between each line 15 'of the cathode and the two intermediate conductors 29 which frame it. Thus, the lines are brought back, at the end of addressing and through the resistive layer 11, at the potential + V1 preventing electronic transmission.

The microtips 2 are deposited on the resistive layer 11 in the meshes (12, FIGS. 2A, 2B) defined by the conductors (13, FIG. 2B) of lines 15 ', in holes 4 etched in the insulating layer 16 and in a conductive layer 24 in which the grid is produced by being organized in 14 'columns. Columns 14 'of the grid are addressable individually and simultaneously by being each brought to a potential corresponding to the desired brightness for the pixel defined by the intersection of the line 15 'of addressed cathode and of the corresponding column 14 '.

As a particular embodiment, the potential -V1 is equal to -40 volts, the potential + V1 corresponding to +40 volts. The grid columns 14 'are addressed to potentials Vc between 0 and +40 volts, a corresponding maximum emission at a potential Vc of +40 volts while the line 15 ' corresponding of the cathode is biased at the potential of -40 volts.

An advantage of the invention according to this second aspect, where the addressing of the grid and the cathode is reversed with respect to a conventional screen, is that the amplifiers 32 for controlling the lines can be made using MOS transistors only at channel N.

Another advantage of providing such reverse addressing is that this saves a resistive layer (26, figure 5 - 26 ′, FIG. 6), and the resistive layer 11 of homogenization is used of electronic emission to achieve resistive contact to the return electrode.

In the embodiment illustrated by Figures 7 and 8, it is no longer necessary to burn the layer resistive 11 insofar as the cathode conductors are not no longer addressed simultaneously, but sequentially. So there is more risk of current leakage between cathode conductors. In addition, the grid columns being separated one others by the insulating layer 16, there is no leakage of current between the columns addressed simultaneously. An advantage of the present invention according to this embodiment is that the absence of etching of the resistive layer saves a step masking and engraving of the manufacturing process of the cathode / grid.

According to a second embodiment (not shown) implementing the second aspect (reverse addressing) of the present invention, the resistive layer 11 is etched according to the pattern of lines 15 'of the cathode. In this case, sections of this resistive layer, perpendicular to the lines 15 ', are maintained to contact the conductors 29. Such an embodiment is, for example, intended for a screen in which the substrate 10 constitutes the surface of the screen. In this case, the cathode conductors and the conductors 29 are preferably made on the resistive layer 11 deposited directly on the substrate 10, and the cathode conductors have a structure meshed.

According to another embodiment not shown, putting implementing the second aspect of the invention, the conductors of the return electrode are deposited on the resistive layer 11, between the columns of the grid and parallel to them. In this case, the insulating layer (16, figure 8) is etched before the deposition of the conductive grid layer which is etched, in the same step, according to the pattern of the columns 14 'of the grid on the insulating layer 16 and according to the pattern of the conductors (in columns) of the return electrode on the resistive layer 11.

Material dimensions and characteristics used to make the resistive elements between the scan lines and the return electrode conductors will be adapted to minimize consumption due to handing over zero scan lines, and for that time to this reset is less than the duration of addressing a line, this time being related to the capacity of the scanning lines.

As a particular example, we can make a screen of approximately 13 cm diagonal in which the lines 15 'of cathode have a length of the order of 100 mm leaving remain an interval of 10 µm between each line 15 'and the two conductors 29 which surround it. Assuming that the layer resistive 11 has a resistance of 300 MΩ per square, the value of the resistance between each line of the cathode and the potential of recall is around 30 kΩ. Assuming a tension of the order of 80 volts between potentials -V1 and + V1, consumption due to the recall is around 420 mW.

If the capacity of a cathode line is of the order of 450 pF, the time required to bring back a line that comes to be addressed to the potential + V1 is around 7 µs which is perfectly compatible with a line time which is generally around 40 µs for such a screen.

Of course, the present invention is capable of various variants and modifications which will appear to the man of art. In particular, we can seek to reduce consumption linked to the recall by increasing the space between the lines of sweep and the conductors of the return electrode, and / or etching the resistive layer so as to leave only point recall resistors between lines and conductors of the return electrode.

Claims (10)

Flat display screen, comprising a cathode (1) with microtips (2) of electronic emission associated with a grid (3) for extracting electrons from the microtips, the cathode / grid comprising: conductive lines (14; 15 ') of grid or cathode suitable for being addressed sequentially; and cathode or grid columns (15; 14 ') respectively perpendicular to said lines and suitable for being addressed individually and simultaneously during the addressing of a line, characterized in that it comprises a return electrode (23, 27; 30) capable of being biased at a return potential (-Vg; + V1) corresponding to a potential of absence of electron extraction, each line grid or cathode being connected, via at least one resistive element (22, 26, 26 '; 11), to the return electrode. Screen according to claim 1, characterized in that the return electrode (23, 27; 30) consists of lines conductive (22, 27; 29), inserted between two lines (14; 15 ') adjacent to the grid (3) or the cathode (1), and interconnected at the recall potential (-Vg; + V1). Screen according to claim 1 or 2, characterized in what said lines (14; 15 ') of grid (3) or cathode (1) and the lines (27; 29) of the return electrode (30) are made in the same conductive layer (24, 24 '; 28) etched, each line of the return electrode being spaced from the two lines near the grid or the cathode. Screen according to claim 3, characterized in that that a resistive layer (26, 26 '; 11) is present on or under said conductive layer (24, 24 '; 28). Screen according to any one of claims 1 to 4, characterized in that each line (14) of the grid (3) is associated with a control amplifier (21) including a stage of output exclusively includes a P channel MOS transistor, interleaved between a high addressing potential (+ Vg) and the line, the return electrode (23, 27) being polarized at a low potential (-Vg). Screen according to claims 2 and 5, characterized in that each conductive line (22) of the return electrode (23) is dimensioned to constitute a resistive element between a neighboring grid line (14) and the return potential (-Vg). Screen according to any one of claims 1 to 4, characterized in that each line (15 ') of the cathode (1) is addressable by a control amplifier (32) including a stage of output exclusively includes an N-channel MOS transistor, interleaved between a low addressing potential (-V1) and the line, the return electrode (30) being polarized at a high potential (+ V1). Screen according to claims 4 and 7, characterized in that the microtips (2) are deposited on said layer resistive (11) forming a resistive element between each line of cathode and the return electrode. Screen according to claim 8, characterized in that that the return electrode consists of conductors, interposed between the columns (14 ') of the grid (3) and separated from the conductive layer (28) in which the lines are formed (15 ') of the cathode (1), by the resistive layer (11). Screen according to any one of claims 1 to 9, characterized in that the return electrode (23, 27, 30) is polarized between the addressing periods of two lines (14, 15 ') successive, and is left floating during the addressing of lines.

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