FR2605778A1 - Liquid crystal visual display panel and method of writing data onto this panel - Google Patents

Abstract

The present invention relates to a liquid crystal visual display panel and a method for writing on it. Each liquid crystal cell CL11, CL12, CL13 has one of its electrodes linked to a column connection C1, C2, C3, etc., common to the cells arranged in the same column. The other electrode of each cell is linked to the point B common to two diodes in series d1, d2 d3, d4, etc., having identical characteristics. Each diode is also linked to a line connection l1, l2, l3 etc., and each line connection is linked to two diodes connected to two cells belonging to successive lines of the panel. Moreover, the line connections are linked alternately to the anode and to the cathodes of the diodes.

Description

LIQUID CRYSTAL VISUALIZATION PANEL
AND METHOD FOR RECORDING DATA
ON THIS PANEL
The present invention relates to a liquid crystal display panel. It also relates to a method of recording data on this panel.

 The liquid crystal display panels generally consist of two parallel plates of insulating and transparent material, such as for example glass or quartz, between which are the liquid crystals. On the faces of the plates in contact with the liquid crystals conductive deposits constituting the connections of rows and columns are made. The intersection of row and column connections determines a matrix array of liquid crystal cells, evenly distributed along rows and columns.

 Figure 1 shows a well-known embodiment of liquid crystal display panel. Each liquid crystal cell is symbolically represented by a rectangle labeled CL. In this embodiment, one of the plates constituting the display panel carries both the line connections and the column connections. For example, only three line connections li, 12, 13 and three column connections C1, C2, C3 are shown as examples. The plate constituting the panel door, in this case, a single contact rellé all liquid crystal cells. Each liquid crystal cell is connected to a line connection and a column connection via a thin film transistor, amorphous silicon, often designated by the initials T. F. T for "Thin Film Transistor".

 In FIG. 1, the references T1 1, T 12, T 13, T 21, T 22 are designated these transistors. These transistors have their gate connected to a line connection, their source has a column connection and their drain to one of the two electrodes of each liquid crystal cell. The other electrode of each cell is the electrode common to all the cells of the panel.

 The liquid crystal cells are addressed line by line. The information to be displayed on the addressed line is presented in parallel on the columns. The transistors used make it possible to send the information on the columns only to the cells of the addressed line.

 The embodiment of the liquid crystal panels illustrated in FIG. 1 has the disadvantage of requiring the completion of line connections and column connections that intersect on only one of the two plates that comprise the display panel. Another disadvantage of this embodiment is that it requires a thin-film transistor for each liquid crystal cell which causes difficulties due to lack of space and technological problems.

Another embodiment of a liquid crystal cell and its means of inscription is proposed in an article entitled "A new amorphous silicon crystal liquid crystal PIN TV display", having for sisters Z. Yaniv, Y. Baron,
V. Cannella and J. McGill and published in May 1986.

 This embodiment is illustrated in FIG. 2 and concerns only one liquid crystal cell C.L.

represented by a capacitor. One of the terminals of the cell is connected at a point D to a column connection C1 made on one of the plates of the display panel.

The other electrode of the cell is connected to a point B, which is the common point to two diodes d1 and d2 in series between a point A and a point B. In FIG. 2, the anode of the diode d1 is connected at point A, its cathode is connected to point B, as well as the anode of diode d2, and the cathode of diode d2 is connected to point C. Point A is connected to a line connection li and point C at the next line connection + li + 1. Line connections such as li and li + 1 are carried by another panel of the display panel than that carrying the column connection Ci.

The operating principle is as follows. When it is desired to store a given voltage VDO at the terminals of the liquid crystal cell CL, the diodes d1 and d2 are biased directly by applying adequate voltages to the line connections li and 11 + 1. For example, DC voltages of opposite sign + V1 and -V1 may be applied to the lines li and li + 1. These voltages are defined to a constant, and they can be shifted by a value VO and apply for example voltages V1 + VO and -V1 + VO lines li and li + 1. Simultaneously, we impose on the column
Ci the voltage VDO or VDO + VO that IVon wants to store on the liquid crystal cell. The diodes d1 and d2 are chosen with identical characteristics, and the point B stabilizes at zero voltage or at VO. The voltage VDO is then applied to the liquid crystal cell CL. To store this voltage on the liquid crystal cell, the diodes d1 and d2 are polarized in the opposite direction by applying to the lines li and 11 + 1 opposite direct voltages equal for example to -V2 and + V2. As before, these voltages are defined to a constant. The two diodes d1 and d2 in reverse behave like capabilities. These capacitances must be of low value in front of the capacitance of the liquid crystal cell, so that any variation of voltage on the column connection Ci is entirely transmitted to the point B and that the voltage across the terminals of the liquid crystal cell remains constant and equal to VDO. Consequently, the other liquid crystal cells connected to the same column Ci can be addressed without disturbing the voltage VDO stored on a given liquid crystal cell.

 Voltage variations that may occur on the column Ci when addressing other cells should not be able to cause live diodes d1 and d2.

The voltages V2 and -V2 are thus chosen according to the information to be displayed on the different cells connected to the same connection of columns to avoid this.

 The advantage of the embodiment of Figure 2 is that it does not require cross-connections of rows and columns on the same plate of the display panel, since these connections are carried by different plates.

 It also has the advantage of not requiring thin-film transistors.

 The aforementioned article is limited to the description of a single liquid crystal cell. FIG. 3 shows the diagram of a display panel in which each liquid crystal cell is controlled in the same manner as in the case of FIG. 2.

 In Figure 3, there is shown by way of example a display panel having only three rows and three columns of liquid crystal cells. Each liquid crystal cell CL is connected by one of its electrodes to a point B which is the point common to two diodes d1 and d2 in series between a point A and a point C which are connected to two line connections 11 and 1, 12 and 1'2, 13 and 1'3. The other electrode of each liquid crystal cell is connected at a point D to a connection of columns C1, C2, C3. In Figure 3, the column connections are shown in dotted lines because they are located on one of the plates constituting the panel different from that which carries the line connections.

 The present invention relates to a liquid crystal display panel which retains the advantages of the embodiment shown in FIG. 3, with regard to the suppression of row and column crossings and the suppression of thin film transistors. In addition, the invention has the advantage of eliminating a line connection in two, compared to the embodiment of Figure 3, resulting in a simplification of the technology and allows a better resolution.

 The reduction in the number of connections, which are opaque, makes it possible to increase the useful surface reserved for each pixel.

 The present invention relates to a liquid crystal display panel, comprising liquid crystal cells, distributed along lines and columns, line connections, deposited on one of the two walls of the panel and column connections deposited on the other wall of the panel, each cell having two electrodes, one of the electrodes of the cells of the same column being connected to the same column connection and the other electrode of the cells of the same column being connected to the common point with two diodes, of substantially identical characteristics, in series, each diode being also connected to a line connection, characterized in that each line connection> except the first and the last of the panel, is connected to two diodes, connected to two liquid crystal cells belonging to two successive lines of the panel, and in that the line connections are connected alternately to the anodes and the cathodes of the diodes.

The present invention also relates to a method of writing data on a liquid crystal display panel such as that defined above, characterized in that it comprises the repetition of the two following steps
a first step during which all the diodes of the panel are inversely polarized by application to the connections of even rank lines of a DC voltage, defined b a constant, and by application to the connections of lines of odd rank of the same voltage but of opposite sign
a second step during which the data on one of the lines L of liquid crystal cells of the direct polarization panel are printed on the diodes connected to this line and on a neighboring line Lt, by application to the common line connection to these diodes of adequate DC voltage and by application to the column connections, voltages to be inscribed on the given line, increased by the voltage that the direct passage of the diodes shows on the electrodes of the liquid crystal cells connected to these diodes, a new first step then recommences, then a new second step during which the liquid crystal cells of said adjacent line L 'and another line of L "crystal cells are inscribed, and so on.

Other objects, features and results of the invention will become apparent from the following description given by way of nonlimiting example and illustrated by the appended figures which represent
FIG. 1, the diagram of an embodiment of a liquid crystal display panel according to the prior art
- Figure 2, the diagram of an embodiment of a liquid crystal cell and its control means known from the prior art;
FIG. 3, the diagram of a liquid crystal display panel derived from the diagram of FIG. 2
- Figure 4, the diagram of an embodiment of a liquid crystal display panel according to the invention.

 In the different figures, the same references designate the same elements, but for the sake of clarity, the dimensions and proportions of the various elements are not respected.

 Figures 1, 2 and 3 have been described in the introduction to the description.

Tira 4 represents an embodiment of a
The connections of the CL11, CL21, CL31 liquid crystal cells of the first column are exemplified. The cells of the other columns are connected in the same way.

 On the other hand, it is possible without disadvantage, and contrary to the example of FIG. 4, to connect the connections of odd-rank lines 13 and 15 to the cathodes of the diodes and the connections of lines of even rank 12 and 14 to their anodes.

 We will now explain how the inscription of the liquid crystal display panel of FIG. 4 is carried out.

 This inscription comprises the repetition of the two following steps: a "memory" step and a registration step.

 During the "memory" step, all the diodes of the panel are reverse biased.

 In the embodiment of FIG. 4, the odd-rank line connections 11, 13 and 15 are connected to the anodes of the diodes and the even-rank line connections 12 and 14 are connected to the cathodes of the diodes.

 It is of course possible to envisage an embodiment of the invention where conversely the connections of odd-rank lines are connected to the cathodes of the diodes and the connections of lines of even rank are connected to the anodes of the diodes.

 In the embodiment of FIG. 4, a positive direct voltage equal to, for example, å + V 2 is applied to the connections of lines of even rank and the same negative DC voltage of value -V 2 is applied to the connections of lines of odd rank.

 As in the case of Figures 2 and 3, these voltages are of course defined at a constant and can use DC voltages equal to V2 + Vg and -V2 + Vg, where VO is a DC voltage.

 All diodes in the panel are blocked. The diodes of the panel are chosen so that their capacitance in the blocked state is small compared to that of the liquid crystal cells. The information stored on these cells is then fixed and does not vary when the potential of the columns varies.

 During the registration step, the data is written on one of the liquid crystal cell lines of the panel.

For example, to register the cells of the first line of the panel, the voltage applied to the line connection 12 is changed so that the diodes connected to the first and second rows of liquid crystal cells are forward biased. For example, the line connection 12 has a DC voltage equal to -V2 -2V1. The polarization of the other line connections is not changed. The point B which is the point common to the diodes connected to the cells of the first and second lines of the panel is then brought to a voltage substantially equal to -V2 -V1, provided that the two diodes' connected to each crystal cell Panel fluids have identical characteristics. To simplify control of the panel all the diodes of the panel are chosen so that their characteristics are substantially identical.

 We then apply on columns C1, C2, C3. the voltages to be written on the cells of the first line of the panel increased by the value -V2 -V1.

 The cells of the first line are polarized at the desired voltages. On the other hand, the cells of the second line are polarized at the same voltages as the cells of the first line, which constitutes false information that must be erased later.

 With regard to the voltage -V2 -2VlaPPliCated at the line connection 12, it is also defined to a constant close. If during the memory step, voltages + V2 + Vg and -V2 VO are applied to the different line connections, then a voltage equal to 4 - V2 + VO - 2V1 must be applied to bias the diodes in direct line.

 After the registration step just described, there is a new step "memory" during which the voltage of the line connection 12 is reduced to V2. All the diodes are blocked and the information stored by the liquid crystal cells is frozen.

 During the next registration step, we will register the liquid crystal cells of the second line which will allow to erase the false information they contain since the registration of the cells of the first line. For this purpose, the diodes connected to the cells of the second and third lines of the panel are directly biased by passing the voltage applied to the line connection 13 from -V2 to V2 + 2V1. The voltages to be written on the second line of liquid crystal cells increased by the voltage V2 + V1 appearing on the middle point B of the diodes are then applied to the columns.

 The cells of the second and third lines are then registered with the information to be displayed on the cells of the second line. During the next registration step, the cells of the third line are written with their own information which erases the previous information.

 It is therefore preferable to inscribe the panel by regularly exploring its lines, either by inscribing the lines according to an ascending order number lines 1, then 2, then 3 .... either according to a descending order number.

 The inscription of the third line of liquid crystal cells is done in the same way as the inscription of the first line by carrying the line connection 14 to - V2 2V1. Likewise, the inscription of the fourth line of liquid crystal cells is like the inscription of the second line carrying the line connection 15 to + V2 + 2V1.

 When registering a line of liquid crystal cells, except for the diodes connected to this line and to a neighboring line, all the other diodes of the panel are in reverse. Since the reverse diode capacitances are low during those of the liquid crystal cells, the information stored on the liquid crystal cells connected to a pair of diodes in reverse is fixed and does not vary when the potential of the columns varies, that is, ie when registering another line.

 More generally, the inscription of a liquid crystal display panel according to the invention comprises the repetition of the two following steps.

 A first step during which all the diodes of the panel are reverse biased by application to the connections of even rank lines of a DC voltage, defined to a constant close, and by application to connections of odd-rank lines, the same voltage but of opposite sign.

 A second step during which the information is written on one of the lines of liquid crystal cells by direct polarization of the diodes connected to this line and to a neighboring line, the one which follows or which precedes, by applying to the connection of common line to these diodes a suitable DC voltage equal to V2 + 2V1 or å - V2 - 2V1 depending on whether this line connection is connected to the anodes or cathodes of the diodes and by applying to the column connections the voltages to be written on the given line increased by the voltage -V2-V1ou + V2 + V1, that the direct passage of the diodes shows on the electrodes of the liquid crystal cells of this line which are connected to diodes.

 After this second step, a new first step begins again, then another second step during which we register the liquid crystal cells connected to diodes that have been forward biased during the previous second step, and so on.

Claims (2)

 1. A liquid crystal display panel comprising liquid crystal cells (LCDs) arranged in rows and columns, line connections (11, 12> 13..), Deposited on one of the two walls of the panel and column connections (C1, C2, C3), deposited on the other wall of the panel, each cell having two electrodes, one of the electrodes of the cells of one and the same column being connected to the same column connection ( C1, C2, C3) and the other electrode of the cells of the same column being connected to the common point (B) with two diodes of substantially identical characteristics, in series, each diode also being connected to a line connection (11). , 12, 13 ...)> characterized in that each line connection (l1, 12, 13 ...)> except the first and the last of the panel, is connected to two diodes connected to two liquid crystal cells belonging to to two successive lines of the panel, and in that the conn lines (11, 12, 13 ...) are connected alternately to the anodes and the cathodes of the diodes (d1, d2, d3).  2. A method of writing the data on a liquid crystal display panel such as that of claim 1, characterized in that it comprises the repetition of the two following steps  a first step during which all the diodes of the panel are inversely polarized by application to the connections of lines of even rank (12, 14 ...) of a DC voltage (V2), defined to a constant, and by application connections of lines of odd rank (11, 13> 15 ...) of the same voltage but of opposite sign (-V2) ;;  a second step during which the data are written on one of the lines L of liquid crystal cells of the panel by direct polarization of the diodes - connected to this line and to a neighboring line L ', by application to the line connection common to these diodes a suitable DC voltage (V2 + 2V1 or - V2 - 2V1) and by applying on the connections of columns (C1> C2, C3 ...) voltages to be registered on the given line, increased by voltage that the direct passage of the diodes shows on the electrodes of the cells connected to these diodes, a new first step begins again, then a new second step during which the liquid crystal cells of said adjacent line L 'and d are inscribed 'another line of liquid crystal cells L' and so on.