EP0972282A1

EP0972282A1 - Device for controlling a matrix display cell

Info

Publication number: EP0972282A1
Application number: EP98949077A
Authority: EP
Inventors: François Maurice
Original assignee: Thomson-LCD
Current assignee: Thales Avionics LCD SA
Priority date: 1997-12-15
Filing date: 1998-10-19
Publication date: 2000-01-19
Anticipated expiration: 2018-10-19
Also published as: US6844874B2; KR20000070943A; DE69828158D1; US20020130827A1; FR2772501A1; WO1999031650A1; DE69828158T2; JP2001512588A; FR2772501B1; EP0972282B1

Abstract

The invention concerns a device for controlling a matrix display cell comprising a set of control circuits (P'ij) arranged in lines and in columns and controlling an elementary point (XL), the state of each elementary point being a function of first and second control signals (L'i, C'j) applied on the control circuit (P'ij) respectively by the lines (L'I) and the columns (C'j). The control circuit (P'ij) consists of a first transistor (MN2) connecting the elementary point (XL) to the corresponding line (L'i) receiving the first signal and a second transistor (MN1) whereof a first electrode is connected to the first transistor grid, which is itself connected to the corresponding column (C'j) receiving the second signal, and whereof the second electrode is connected to a reference potential. The invention is particularly applicable to flat screens such as liquid crystal displays or electroluminescent displays.

Description

DEVICE FOR CONTROLLING A CELL OF A MATRIX SCREEN

The present invention relates to a matrix control device, more particularly a matrix control device used in a flat screen such as an active matrix type liquid crystal screen or other types of flat screen.

In the prior art, a matrix control device is used, for example, to control the cells of a flat screen such as liquid crystal cells. In this case, it is a liquid crystal screen of the active matrix type also known by the abbreviation AM-LCD. Such an active matrix type liquid crystal screen is shown in FIG. 1. In this case, the screen is made up of a number of electro-optical cells each formed by an electrode and a counter-electrode enclosing the liquid crystal. These cells are referenced XL in said figure. The electro-optical cells are arranged in rows and columns, and each controlled by a switching circuit forming part of a matrix type control device. As shown in FIG. 1, the switching circuit is produced by a transistor T, one of the electrodes of which is connected to a column Cj and of which the other electrode is connected to the electro-optical cell XL. On the other hand, the gate of transistor T is connected to one of the lines Li of the control device. Most often, the electro-optical cell XL is associated with a storage capacity CP mounted in parallel on the capacity formed by the electro-optical cell at the output of the transistor T. The assembly formed by the transistor T and the capacity CP forms an elementary control circuit referenced Pij in FIG. 1. On the other hand, each of the selection lines Li is connected to a control circuit 2 or "line driver" which successively applies to each line a control pulse having a voltage typically varying between - 10 and + 20 volts. Similarly, each of the columns Cj or data lines is connected to a column control circuit 3 or "column driver" which sends to the columns Cj an analog signal corresponding to the video signal more particularly representing a gray scale whose voltage varies typically between + and - 5 volts. With this matrix control device, the control of an electro-optical cell XL is carried out as follows. When a pulse is applied to a selection line Li, the switching transistor T becomes conducting. As a result, the analog voltage applied to the column Cj is transmitted to the terminals of the electrodes of the electro-optical cell XL which displays a gray level corresponding to the data signal.

In general, a matrix control device of this type has switching transistors which are most often constituted by thin film transistors TFT for "Thin Film Transistor". Such a device is generally made of amorphous silicon. On the other hand, the lines and columns control circuits 2,3 can be integrated on the substrate plate on which the flat screen is produced or can be produced independently. When they are integrated on the substrate plate, they are produced using also amorphous silicon.

One of the problems encountered with this type of matrix control device is a consumption problem due in particular to the amplitude of the signals applied to the rows and the columns. This problem is all the more important since the technique known as "line inversion" is used for addressing lines of the matrix screen, the inversion of polarity taking place at each line. In this case, a consumption of up to one watt can be obtained for a line frequency of 30 KHz.

Another problem encountered with this structure when it is made with polycrystalline silicon or monocrystalline silicon transistors, relates to the leakage current of the switching transistor T in the blocked state which tends to discharge the elementary points or electro-optical cells XL.

The present invention aims to remedy the drawbacks mentioned above by providing a matrix control device having a new structure for the elementary control circuit of each elementary point, this structure being particularly well suited to the use of polycrystalline or monocrystalline silicon for the production of transistors or other semiconductor circuits.

The present invention therefore relates to a matrix control device comprising a set of control circuits arranged in rows and columns and controlling an elementary point, the state of each elementary point being a function of first and second control signals applied to the control circuit respectively by the lines and the columns, characterized in that each control circuit is an electrical circuit whose impedance between its output and that of its inputs which conveys the first signal becomes low following the application of a pulse of adequate voltage on this first signal, and in that this same impedance becomes very high following the application of an adequate voltage on the second signal.

In this case, the first signal is a signal which, at first, makes it possible to activate all the control circuits of the corresponding line by making them passable, then to apply a voltage ramp which is transmitted at the output of the command at the corresponding elementary point. According to a preferred embodiment, the first signal consists of a ramp-shaped signal preceded by a negative precharge pulse. According to an improvement, preferably, the instant of triggering of the ramp-shaped signal is adjusted from line to line so as to compensate for the propagation delays over the columns.

On the other hand, the second signal is a switching signal of digital type determining the duration during which the activated control circuits remain on. According to a preferred embodiment, the second switching signal is constituted by PWM type pulses for "Puise Width Modulation" in English. Preferably, the moment of triggering of the pulses is adjusted from column to column to compensate for the delays on the lines. According to a preferred embodiment of the present invention, the control circuit consists of a first transistor connecting the elementary point to the corresponding line receiving the first signal and a second transistor of which a first electrode is connected to the gate of the first transistor, whose gate is connected to the corresponding column receiving the second signal and whose second electrode is connected to a reference potential.

According to an additional characteristic of the present invention, the elementary control circuit further comprises a capacitor connected between the gate of the first transistor and the corresponding line. Likewise, the second electrode of the second transistor is connected to the previous line. According to another characteristic of the present invention, the circuits are produced using polycrystalline silicon.

Other characteristics and advantages of the present invention will appear on reading the description given below of a preferred embodiment, this description being made with reference to the attached drawings in which:

- Figure 1 already described is a schematic representation of a matrix control device used in the case of an active matrix liquid crystal screen associated with row and column control circuits according to the prior art;

FIG. 2 is a schematic representation of a matrix control device according to the present invention in the case where the elementary point is constituted by a liquid crystal cell, this device being associated with row and column control circuits,

FIG. 3 represents the shape of the different signals applied respectively to the lines, the columns, at point A, at point B and the source gate voltage of the transistor MN2 in the case of the elementary control circuit of FIG. 2, and, - Figure 4 is a schematic representation of a matrix control device according to the present invention in the case where the elementary point is constituted by an electroluminescent material, this device being associated with row and column control circuits.

In the figures, to simplify the description, the same elements have the same references. On the other hand, the present invention will be described with reference to a liquid crystal display. However, it is obvious to a person skilled in the art that the invention can be applied to elementary points constituted by any circuit for storing an electrical signal such as an electro-optical cell or the like.

In Figure 2, there is shown a matrix control device according to the present invention associated with a line control circuit 20 and a column control circuit 30, said circuits can be integrated or not on the same substrate as the control device matrix. In the matrix control device of FIG. 2, the elementary control circuit referenced P'ij has been modified so as to limit the electrical consumption and thus allow production in polycrystalline silicon. More specifically, the elementary control circuit P'ij arranged in rows and columns controls an elementary point constituted, in the embodiment shown, by an electro-optical cell XL, more particularly a liquid crystal cell. On this electro-optical cell is mounted in parallel a storage capacity CP, said cell itself playing the role of a capacity and its optical properties being modified as a function of the value of the electric field which passes through the liquid crystal.

We will now describe an embodiment of an elementary control circuit P'ij whose main characteristic is to have an output signal according to the input signal when it is activated by a first signal, namely that applied to the lines L'i, and whose impedance between the input and the output becomes very large under the effect of a second signal, namely the signal applied to the columns C'j. In the case of FIG. 2, the control circuit P'ij consists of essentially by a switching device MN2 preferably consisting of a thin film transistor or TFT. An electrode of the transistor MN2 is connected to an electrode of the electro-optical cell XL while its other electrode is connected to a line L'i. On the other hand, the gate of transistor MN2 is connected to an electrode of a second transistor MN 1, the other electrode of which is connected to ground in the embodiment shown and whose gate is connected to a column C'j . As shown in FIG. 2, a capacitor referenced CB is connected between the gate of the switching transistor MN2 and the line L'i. The connection point between the capacitor CB and the gate of the transistor MN2 is referenced A while the connection point between the electrode of the transistor MN2 and the electrode of the electro-optical cell XL is referenced B. The lines L'i are connected to a line control circuit 20 which provides on the lines a data signal constituted by a signal which, at first, makes it possible to activate all the elementary control circuits of the corresponding line by making them passable, then then apply a voltage ramp which is transmitted at the output of the elementary control circuit to the XL cell. Likewise, the set of columns C'j is connected to a column control circuit 30 which supplies, on each column, a second signal constituted by a switching signal of digital type, more particularly pulses of PWM type determining the duration during which the activated P'ij control circuits remain on.

We will now explain, with reference to Figure 3, the operation of the control circuit shown in Figure 2. As shown in Figure 3, the signal applied to the lines L'i, L'i + 1 is constituted by a pulse negative allowing to activate all the elementary control circuits of a line followed by a ramp whose amplitude typically varies between - 5 volts and + 10 volts preferably. The duration T of the signal L'i corresponds to a line time. On the line L'i + 1, the same signal is applied but offset by a time T as shown in FIG. 3. On the other hand, on the columns C'j is applied a switching signal constituted by pulses of PWM type to modulate the pulses in width, the signal having levels included typically between 0 and 2 volts, in the case of an embodiment in polycrystalline silicon or in monocrystalline silicon.

When the line L'i is not addressed, the elementary control circuit mainly consisting of the two transistors MN 1 and MN2 operates in the following manner. As shown in FIG. 2, the second electrode of transistor MN1 is at a reference potential, namely either to ground in the embodiment shown or to the potential of the preceding line which is itself at a reference voltage, because it is not addressed. When a pulse is applied to column C'j, namely to the gate of transistor MN 1, the transistor

MN 1 becomes conducting and point A, namely the gate of transistor MN2 passes to the reference potential. At this point, the source gate voltage

Vgs of transistor MN2 is zero and the "off" current of transistor MN2 is minimum. As a result, the electro-optical cell XL does not discharge.

When the line L'i is addressed, namely when it applies a signal as represented by L'i in FIG. 3, the line L'i first undergoes a negative voltage drop - V. Point A , due to the capacity CB, undergoes the same instantaneous voltage drop. The column C'j receiving a positive pulse, as shown in FIG. 3, the transistor MN1 is on and, therefore, the potential of point A is brought back to the level of the reference potential, namely to ground or zero, in the case of the embodiment shown. The source gate voltage Vgs of the transistor MN2 becomes positive and goes to a value corresponding to the voltage drop on the line L'i which makes the transistor MN2 on. Immediately after, the voltage applied to the column C'j drops to zero, causing the transistor MN 1 to go to the "off" or high impedance state. The source gate voltage Vgs of the transistor MN2 remains constant due to the capacitance CB. When the voltage ramp is applied to the line L'i, the transistor MN2 being on, the voltage at point B copies the voltage of the ramp until a new positive pulse on the column turns the transistor MN 1 on , which has the effect of reducing the voltage at point A to the potential reference. At this moment, the transistor MN2 becomes non-conducting and the voltage at point B remains constant as shown in FIG. 3.

The new elementary control circuit above therefore makes it possible to display gray levels corresponding to the duration during which the ramp is applied to point A. For use in a flat liquid crystal screen, the voltage of each elementary cell P 'ij can therefore reach any value in the range of variation of the ramp provided by the first signal. The polarity of each cell can therefore be chosen independently of that of its neighbors provided that the voltage of the counter electrode is adjusted to a value close to half of the maximum voltage reached by the first signal.

The control circuit described above makes it possible to effectively reduce consumption. Indeed, the consumption is given by Vz f CV ₂ , f being the line frequency, V the amplitude of the applied signal and C the capacities.

The table below shows the difference in consumption between the control device in FIG. 1 and in FIG. 2 for a liquid crystal screen comprising 600 rows and 2400 columns on a diagonal of the order of 30 cm.

On the other hand, when using polycrystalline silicon produced on glass or monocrystalline silicon to produce the control device, the MN2 transistors operate with a controlled gate-source voltage Vgs, which gives a lower "off" current. .

Another advantage of this invention is that the "column drivers" 30 have a digital only function, and operate at low voltage, which facilitates their design and reduces their cost.

FIG. 4 presents a variant of the invention where the output of the elementary control circuits P'ij identical to those shown in FIG. 3 is no longer connected to a liquid crystal element, but to the gate of a transistor MN3 whose the role is to deliver, to an electroluminescent material, an excitation current controlled by this voltage.

Claims

1. Matrix control device comprising a set of control circuits (P'ij) arranged in rows and columns and controlling an elementary point (XL), the state of each elementary point being a function of first and second signals (L'i, C'j) control applied to the control circuit (P'ij) respectively by the lines (L'i) and the columns (C'j), characterized in that each control circuit (P'ij) is a electrical circuit whose impedance between the output and that of its inputs which conveys the first signal becomes low following the application of an adequate voltage pulse on this first signal (L'i), and in that this same impedance becomes very high after applying an adequate voltage to the second signal.

2. Device according to claim 1, characterized in that the first signal (L'i) is a signal which, at first, makes it possible to activate all the control circuits (P'ij) of the line (L ' i) corresponding by making them passable then applying a voltage ramp which is transmitted at the output of the control circuit (P'ij) to the corresponding elementary point.

3. Device according to claim 2, characterized in that the first signal (L'i) consists of a ramp-shaped signal preceded by a negative precharge pulse.

4. Device according to any one of claims 2 and 3, characterized in that the triggering of the ramp-shaped signal is adjusted from line to line so as to compensate for the propagation delays on the columns (C'j).

5. Device according to claim 1, characterized in that the second signal (C'j) is a digital type switching signal determining the duration during which the activated control circuits (P'ij) remain on.

6. Device according to claim 5, characterized in that the second switching signal (C'j) consists of pulses of PWM type (Puise Width Modulation).

7. Device according to any one of claims 5 and 6, characterized in that the triggering of the pulses is adjusted from column to column to compensate for the delays on the lines (L'i).

8. Device according to any one of claims 1 to 7, characterized in that the control circuit (P'ij) is constituted by a first transistor (MN2) connecting the elementary point (XL) to the line (L'i ) corresponding receiving the first signal and a second transistor (MN 1) whose first electrode is connected to the gate of the first transistor, whose gate is connected to the corresponding column (C'j) receiving the second signal and whose second electrode is connected to a reference potential.

9. Device according to claim 8, characterized in that it further comprises a capacitor (CB) connected between the gate of the first transistor (MN2) and the corresponding line (L'i).

1 0. Device according to claim 8, characterized in that the second electrode of the second transistor (MN1) is connected to the previous line (L'i-1).

1 1. Device according to any one of the preceding claims, characterized in that the circuits are produced using polycrystalline silicon, amorphous silicon, or monocrystalline silicon.

1 2. Device according to any one of the preceding claims, characterized in that the elementary points are electro-optical cells.

1 3. Device according to any one of the preceding claims, characterized in that the output of the elementary points P'ij serve to modulate the excitation current of an electroluminescent material.