FR2704967A1 - Flat, microdot screen with doubly-switched anode - Google Patents

Abstract

The subject of the present invention is a flat, microdot screen with doubly-switched anode. The device according to this invention consists of a flat screen with matrix addressing in which the anode (9) is segmented into groups of strips of luminophores, each group being linked electrically to the other groups alternately in such a way that a group of strips set to a defined potential is surrounded by two groups of strips set to another potential. It relates in a general way to the field of flat, visual-display screens with row-column matrix addressing, and more particularly the screens using the technology of microdots, that is to say consisting of an enclosure which has been evacuated and which is formed of two thin glass plates, the rear plate or cathode plate including a matrix array of electron-emitting microdots, and the front plate or anode plate covered with a transparent conducting layer carrying luminophores.

Description

FLAT SCREEN WITH MICROPOINTS, WITH ANODE
DOUBLE SWITCHED
The present invention relates to a flat screen with microtips with doubly switched anode.

 It generally relates to the field of flat display screens with row-column matrix addressing, and more particularly screens using microtip technology, that is to say made up of an enclosure in which the empty and formed of two thin glass plates, the rear plate or cathode plate, comprising a matrix network of electron-emitting microtips, and the front plate or anode plate, covered with a transparent conductive layer carrying phosphors.

 Microtip screens are characterized by electronic field effect emission from an extended flat cold cathode with microtips, by matrix addressing from the integrated tip-grid structure and light emission by low to medium voltage cathodoluminescence, as well as a low consumption and a fast response time (1 rus).

 In this type of screen, each light point (pixel) is associated with an emissive surface located opposite the corresponding phosphor and made up of a large number of microtips. This emissive surface is defined by the intersection of a line (grid) and a column (cathode conductor) of the matrix.

The cathode of a microtip screen consists of at least three layers deposited successively on a glass or silicon substrate, namely: a conductive layer playing the role of column conductor, an insulating layer and a second conductive layer constituting the wire rack. Some embodiments include a fourth resistive layer deposited above or below the "column conductor" layer. After depositing the above-mentioned layers, holes are made in the grid and the insulating layer in which the microtips are then deposited,
Image formation on microtip screens presupposes the use of row and column addressing circuits allowing each pixel to be excited individually. The production of a trichrome screen requires depositing a mosaic of red phosphors (R ), green (V) and blue (B) on the conductive surface of the anode, arranged opposite the cathode emissive surfaces of the corresponding pixels. Two anode structures are currently used:
- the classic structure derived from that of liquid crystal displays; an emissive surface is associated with each luminophore of elementary color;
- a structure specific to microtip screens, called a switched anode: a single emissive surface is associated with each triad, the red, green, blue phosphors being electrically isolated from each other. The addressing of colors is sequential by successive polarization of red, green and blue.

The cathode is identical to that of the monochrome screen of the same definition.

 This second solution has several advantages. It requires three times less column circuits (one per triad instead of one per color), its manufacturing process is simpler (no alignment between anode and cathode), it allows higher resolution and the purity of the colors is better .

 According to known technology, the phosphors are made up of successively red, green and blue parallel bands, electrically isolated from each other. The color images are produced by superimposing three images (blue, green and red) obtained by switching the anode: the strips of RGB phosphors are alternately polarized at the anode voltage, while the only cathode which faces the RGB triplet delivers alternately the electronic currents of the three colors sequentially.

 In the case of a monochrome screen, it is not normally necessary to resort to cutting the anode, it is continuous and the anode polarization (electron acceleration voltage) is constantly applied.

 However, in practice, the switched anode embodiments do not make it possible to achieve a high definition with a high proximity contrast. Indeed, as well for the monochrome screens as for the color screens, the proximity contrast is limited by the importance of the cone of dispersion of the electrons emitted by the points and, in the case of the switched color anode, by the attraction of bands of phosphors of the same color from neighboring pixels.

 The object of the present invention is to remedy these limitations by allowing an improvement in the proximity contrast not only with a larger cathode-anode space, but also with smaller pixels.

 The device according to this invention consists of a flat screen with matrix addressing in which the anode is divided into groups of bands of phosphors, each group being electrically connected to the other groups alternately so that a group of bands set to a determined potential be surrounded by two groups of bands set to another potential.

In the appended schematic drawings, given by way of nonlimiting examples of embodiments of the subject of the invention:
FIG. 1 is a cross section illustrating the operating principle of a known microtip screen,
FIGS. 2 and 3 represent parts of monochrome screen anodes according to the invention, respectively forming groups having the width of a pixel and a half-pixel
and FIGS. 4 and 5 represent parts of color screen anodes according to the invention, respectively forming groups having the width of a pixel and a half-pixel
The basic principle of a microtip screen is shown diagrammatically in FIG. 1, on which we see successively from bottom to top (in practice from back to front): a plate 1 of glass or silicon, an underlay d coating 2, the cathode conductors or column conductors 3, a resistive layer 4, an insulating layer 5, the line or grid conductors 6, an empty space 7 and a layer of front glass 8 covered on its internal face with a layer transparent conductor constituting the anode 9, and phosphors 10.

 An electron beam 11 emitted under vacuum by the microtips 12 electrically connected to the cathode conductors and modulated by the potential of the grid 6 is accelerated towards the anode 9 where it excites the phosphors 10 (triode type operation). Thanks to the short tip-anode distance, focusing is obtained by proximity effect without any electronic optics.

 The device according to the invention consists of an anode 9 for microtip screens cut into groups of bands of phosphors juxtaposed and electrically isolated from each other, each group having the width of a pixel and being able to be surrounded by two at any time. put groups has different potential.

 For the monochromatic screens (FIG. 2) the groups are in fact each formed by a single band of phosphors P or I electrically connected to the others alternately so that a band P set to a potential is surrounded by two bands I to another potential. The same phosphor covers the two series of bands. Thus by alternately polarizing each of the two arrays of anode bands 13, 14, the electrons emitted from the cathode are attracted (focused) exactly on the group of polarized bands which faces it, without the possibility for the electrons to overflow (d ' be captured) on the adjacent bands.

 The use of this "switched monochrome anode" must be done simultaneously with suitable control electronics in which all the columns of a row are not addressed simultaneously, but in two stages: in half a time, the even bands are addressed P, in the other half time the odd bands I.

 For color screens (Figure 4), in addition to the division into three sub-pixels, a second electrical separation of the anode is carried out between two neighboring pixels, the groups 15, 16 each comprising three bands R, G, B, (red, green Blue). We therefore have to do with six arrays of anode bands instead of three.

 The addresses are then treated as in the case of switched monochrome screens, and this for each of the colors, so that two neighboring pixels 17 cannot at the same time attract the electrons emitted by the corresponding cathodes. In the first half time, the three bands R, G, B, of the even groups 16 will be addressed successively, and in the second half time, the three bands R, G, B of the odd groups 15.

 According to an alternative embodiment (Figures 3 and 5), the groups 15, 16 of phosphor strips are half a pixel wide, which makes it possible to simultaneously excite several neighboring pixels and no longer one in two at the same instant.

In the case of color screens (Figure 5), the control of each pixel 17 will then be ensured by six bands, two red R, two green V and two blue
B, the two groups of the same pixel 17 not being addressed simultaneously.

 The alternating polarization of the groups of phosphors allows the realization of a focusing effect and the elimination of the overflow of the electron bombardment on the neighboring pixels.

 It then becomes possible to move the anode away, or to bring the pixels closer (greater definition) for a given anode-cathode space, without worrying about the problems of defocusing the electron beam. This distance from the anode makes it possible to apply greater acceleration voltages (up to 1000 volts), and thus to obtain a better quality image in association with small pixel sizes.

 The positioning of the various constituent elements gives the object of the invention a maximum of useful effects which had not, to date, been obtained by similar devices.

Claims (4)

 10. Flat screen with microtips with double switched anode, relating to the field of flat display screens with matrix row-column addressing, and more particularly screens using microtip technology, allowing an improvement in proximity contrast in conjunction with use a greater cathode-anode distance, or the production of smaller pixels,  characterized in that the anode (9) is cut into groups (15, 16) of bands (I, P, R, V, B) juxtaposed with phosphors electrically isolated from each other, each group being electrically connected to the other groups alternatively in such a way that at any time a group of bands set to a determined potential is surrounded by two groups of bands set to another potential.  20. Monochrome microtip flat screen according to claim 1, characterized in that the groups (15, 16) are each formed of a single strip (P, I) of phosphors electrically connected to the others alternately so that 'a band (P) put at a potential is surrounded by two bands (I) at another potential, the same phosphor covering the two series of bands.  30. Color microtip flat screen according to claim 1, characterized in that the groups (15, 16) each consist of three bands (R, G, B,) (red, green, blue), the control being provided by six networks of bands, two red (R), two green (V) and two blue (B).  40. Flat microtip screen according to any one of the preceding claims; characterized by the fact that the addressing of the strips forming the anode (9) is carried out in such a way that two neighboring groups (15, 16) cannot at the same time attract the electrons emitted by the corresponding cathodes, thanks to a adapted control electronics in which the two groups are not addressed simultaneously, but in two half-times: in the first half, we address the even groups (16), in the other half the odd groups (15 ).  5 ". Flat microtip screen according to any one of the preceding claims, characterized in that each group (15, 16) of bands (I, P, R, V, B) of phosphors has the width of one pixel (17).  60. Flat microtip screen according to any one of claims 1 to 4, characterized in that each group (15, 16) of strips (I, P, R, G, B) of phosphors half a pixel wide.