DE3504886A1 - Liquid-crystal display device and method for driving it - Google Patents

Abstract

The invention relates to a liquid-crystal display device which can be produced cost-effectively and in which the information to be represented is input in an essentially optical fashion and inherently stored. This is achieved by a whole-area photoconductive layer which is provided between the liquid-crystal layer and a whole-area electrode layer as well as by switching the frequency of the alternating voltage applied to the electrode layers. <IMAGE>

Description

description

Liquid crystal display device and method for driving it The invention relates to a liquid crystal display device according to the preamble of claim 1 and a method for their control according to the preamble of claim 6.

For some use cases it is necessary to do one in a short time to store running graphic information and this stored information to represent. Such an application is, for example, in a so-called Given overhead projector. For example, a sketch to be displayed is created there with the help of a Ink and / or felt pen drawn on an optically transparent plastic film. During the drawing, this is light method on a Projected screen and thus visible to several viewers at the same time.

There is a first disadvantage of such an information display in the fact that only a slight contrast is possible, because it will also be the one described Part of the plastic film is illuminated. It also has such a representation generally a poor definition, so that legibility is disadvantageous is decreased.

A second disadvantage is that it is difficult to partially correct misrepresentation. In such a case it is advisable to have a to make a completely new representation. Such a method is disadvantageous Way very time consuming. It is obvious to partially offset these disadvantages eliminate the fact that already prefabricated plastic films are used, e.g. are inscribed by photographic processes. With such an information display However, it is not possible to make short-term corrections, e.g. if these be worked out in the course of a discussion.

The invention is based on the object of a generic liquid crystal display device and to specify a method for their control, with which in a cost-effective manner A high-contrast and memorable representation on a large display area of graphically representable information is possible and with which this representation can be changed quickly and easily.

This object is achieved by the in the characterizing parts of Claims 1 and 6 specified features.

Appropriate refinements or developments are set out in the subclaims removable.

The invention has the advantage that the information to be displayed is entered essentially optically and stored essentially inherently will. As a result, no inexpensive electrical storage device is required and no inexpensive electrical control and driver circuit for control a variety of display points.

The invention is based on a liquid crystal that has two stable switching states and is therefore suitable for information storage. The switching states differ in terms of the alignment of the liquid crystal molecules the display level. Due to the frequency-dependent sign of the anisotropy of the Dielectric constant it is possible by changing the frequency of an electrical Alternating field it is possible to make the liquid crystal molecules perpendicular or parallel to align to the display plane, so that the light transmission of the liquid crystal layer will be changed.

The invention is illustrated below using an exemplary embodiment and a schematic drawing explained in more detail. They show: FIG. 1 shows a cross section through the embodiment; FIG. 2 is a schematic diagram to explain the mode of operation of the exemplary embodiment.

FIG. Figure 1 shows a first substrate 1 and a second substrate 2, e.g. Glass plates with a thickness of about 1 mm, which are essentially parallel to each other are arranged and spaced about 10 µm apart. There is a space in between which is filled with a liquid crystal layer 5. For controlling the liquid crystal layer 5 it is necessary on the facing sides of the first and second Substrate 1, 2, an essentially light-permeable first electrode layer 3 and to apply a substantially translucent second electrode layer 4. For economic reasons, it is advantageous to have the electrode layers 3, 4 over the entire area to raise and leave it that way. So-called ITO layers ("indium-tinoxide") are suitable for this. which consist of indium tin oxide, have a thickness of about 50 nm and are electrical are sufficiently conductive to control the liquid crystal layer 5. On the first Electrode layer 3, only a protective layer 6 is applied, e.g. approximately one 60 nm thick layer of silicon dioxide (sir2), as well as an orientation layer 13, e.g., an approximately 30 nm thick layer of polyimide.

On the other hand, there is initially a photoconductor layer on the second electrode layer 4 10 attached over the entire surface, e.g.

an approximately 200 µm thick layer of zinc cadmium sulfide. These Photoconductor layer 10 is for liquid crystal layer 5 separated by a protective layer 6 and an orientation layer 13.

The liquid crystal layer 5 contains, for example, a nematic-fast liquid crystal, with two stable switching states due to the formation of special edge orientations possible are. The possible edge orientation to create these two stable ones Orientation states of liquid crystals is described, for example, in US Pat Document by J.Cheng et al., 19807 Biennial Display Research Conference, October 1980, page 180. To explain this behavior, FIG. 2 the dielectric constant e of the liquid crystal as a function of the frequency f a to the liquid crystal applied alternating electric field. The dielectric constant c is their component cl perpendicular to the longitudinal axis of the molecule is almost independent of the frequency f, while the parallel component cl II shows a strong frequency dependence. The dielectric constant therefore has an anisotropy = 6l-el, which is for a first frequency fl is greater than zero and less than for a second frequency f2 Zero.

This frequency dependence of the anisotropy de is used to display information exploited as follows: between the electrode layers 3, 4 is first a electrical alternating voltage applied, which e.g. the first frequency fl, e.g. 100 Hz, and has a peak voltage of approximately 5 volts. Where is the peak voltage chosen so that with an electrically high resistance (e.g. about 10 MOhm / mm2) photoconductor layer 10 no change in the switching state of the liquid crystal in the liquid crystal stall shift 5 takes place. The photoconductor layer 10 is now closed over the entire area in the direction of the explanatory trigger light 12 illuminated in such a way, e.g. with a special erase lamp, that the photoconductor layer 10 is electrically low (e.g. about 10 kohm / mm2), thus the electric alternating field strength applied to the liquid crystal layer 5 is no longer sufficient to bring the liquid crystal into a first switching state, which corresponds to the first frequency fl. The liquid crystal layer 5 is now for example The entire surface is opaque to the projection light 8, e.g. the light of a so-called overhead projectors. The extinguishing lamp mentioned as an example is now switched off, so that the photoconductor layer 10 is returned to the high-resistance state, and the liquid crystal layer 5 accordingly remains in the first switching state the first frequency fl.

Due to the properties of the selected liquid crystal as well as the corresponding orientation layer 13, this first switching state is also retained, when no electrical voltage is applied to the electrode layers 3, 4. Between the electrode layers 3, 4 is then an electrical alternating voltage applied, which the second frequency £ 2, e.g. 5 KHz, and a peak voltage of also has about 5 volts. The first switching state of the liquid crystal does not initially change, since the photoconductor layer 10 has an electrical effect over its entire surface possesses high resistance state. According to the information to be displayed, emitting from a trigger light source 9, e.g. a point light Light pen, emitted trigger light 12 in such a way via the second Substrate 2 moves that the photoconductor layer 10 only in the places illuminated thereby becomes low resistance. As a result, at these low-resistance points in the liquid crystal layer 5 generates the second switching state, which corresponds to the second frequency f2. In the second switching state, the liquid crystal is essentially translucent for the projection light 8. A bright optical information display is created, e.g. a light line on a dark background. This second switching state remains due to the storage behavior of the liquid crystal also received when the trigger light 12 is switched off.

In particular, to partially delete the information displayed, e.g. an erroneously displayed line is applied to the electrode layers 3, 4 Again the alternating voltage with the first frequency fl is applied and the one to be deleted Places illuminated with the trigger light 12.

The photoconductor layer 10 is only used at the illuminated points now sufficiently low so that there is a switching of the liquid crystal from the second is enabled in the first switching state, which is the dark background is equivalent to. Unlit areas remain in the second switching state.

To generate or increase the contrast of the information displayed and / or to avoid disturbances, e.g. from ambient light, it is advisable to to attach polarization and / or filter foils 7 to the outside of the substrates i, 2.

The previous description referred to a light information display on a dark background. However, the invention also enables the reverse case. For this purpose, an alternating voltage is first applied to the electrode layers 3, 4 with the second frequency f2 is applied and the photoconductor layer 10 is illuminated over the entire area. As a result, the second, translucent layer becomes over the entire surface of the liquid crystal layer 5 Switching state generated. A subsequent writing of the information in the described Way, however, at the first frequency fl produces a dark display of information on a light background.

This correctable, storing display can also be used without the rear Projection light can be operated. It is from the structure and the control electronics assesses a very simple and therefore inexpensive advertisement.

Claims (8)

Claims 1. Liquid crystal display device, at least consisting of a translucent first substrate, one essentially parallel to it arranged translucent second substrate and one the space between the first and second substrates filling liquid crystal layers, respectively on the substrate side by at least partially translucent first and second electrode layers is limited, characterized in - that the first electrode layer (3) and the second electrode layer (4) are applied essentially over the entire surface, - That between the second electrode layer (II) and the liquid crystal layer (5) an essentially light-transmissive full-surface photoconductor layer (10) is present is, - That trigger light emitted by a trigger light source (9) (12) passes through the second substrate (2) onto the photoconductor layer (10) and in this the electrically low-resistance areas are generated - that in low-resistance areas Areas of the photoconductor layer (io) that sloping over the liquid crystal layer (5) electric voltage rises so that the liquid crystal are switched can, and - that in the liquid crystal layer (5) a nematic liquid crystal is present, in which two stable through formation of a special edge orientation Switching states are possible which are achieved by switching the frequency of the electrode layers (3, 4) applied AC voltage can be set. 2. Liquid crystal display device according to claim 1, characterized in that that in the middle of the liquid crystal layer (5) the liquid crystals parallel or can be aligned perpendicular to the plane of the layers, according to the set Switching status. 3. A liquid crystal display device according to claim 1 or claim 2, characterized in that at least on one outside of a substrate (1, 2) an optical filter and / or polarization layer (7) is attached. 4. Liquid crystal display device according to one of the preceding Claims, characterized in that the trigger light source (9) as a light pen is trained. 5. The liquid crystal display device according to any of the previous models Arlsprüche, characterized in that the trigger light source (9) as a light pen is formed and that an optical projector generates the projection light (8). 6. Method of driving a liquid crystal display device according to one of the preceding claims, characterized in that for displaying an item of information - initially an alternating voltage between the electrode layers (3, 4) with a first switching frequency (fl or f2) is applied, which is a first switching state of the liquid crystal, - the photoconductor layer (io) initially in the direction of the trigger light (12) is illuminated essentially over the entire area in such a way that this becomes low and that the liquid crystal has a first switching frequency over the entire surface (fi or f2) sets the corresponding first switching state, - the photoconductor layer (10) is put into a high-resistance state over the whole area by switching off the full-surface lighting, - the second switching frequency (~ 2 or fl) is selected, - the trigger light (12) is moved according to the information to be displayed, so that in the Fotolei terschicht (10) partially the low resistance State is generated and the liquid crystal there accordingly the second Switching frequency (~ 2 or fl) and - the information displayed by a Projection light (8) is illuminated. 7. A method of driving a liquid crystal display device according to claim 6, characterized in that for the partial deletion of the displayed Information the first switching frequency (fl or ~ 2) that is selected with the trigger light (12) the parts to be deleted are illuminated and that then again on the second switching frequency (~ 2 or fl) is switched. 8. A method of driving a liquid crystal display device according to claim 6 or claim 7, characterized in that only during the When the information to be displayed changes, the electrode layers (3, 4) can be controlled electrically.