DE3910159A1 - Method for the touch-controlled windowing of a display which is effective in at least one step on at least one of four sides of a display at right-angles to each other - Google Patents

Abstract

The windowing of a display is managed, in the method shown, by means of a two-dimensionally assigned electro-optically alterable medium whose electrodes are preferably arranged in a matrix shape. The method relates to the control of the windowing. It is achieved by means of a coordinate-shaped arrangement of touch sensors, preferably capacitive sensors lined up in a row of any length, this row being able to be inside or outside the display. This is likewise achieved by means of capacitive sensors which are inside the display and which use electrodes which likewise already rest on a part of the electro-optically alterable layer. The area defined by the coordinate arms behaves in each case in a way suitable for a scale for the display which is to be influenced. By means of touching one coordinate arm, that coordinate is defined as far as which the desired display dimming is to carried out. This process is possible at most twice per coordinate, in total a maximum of four times, so that the rectangular transparent region can be positioned in any desired position and be of any desired size within the display.

Description

The invention relates to a method for the touch-controlled dimming of a light field, in particular for viewing devices operating in the transmitted light method, such as, for. B. X-ray negative viewing devices, overhead projectors and the like with relatively large light fields. The method is effective in at least one step on at least one of four sides of a light field at right angles to one another by means of an electro-optically variable transparency layer of the area of the light field to be influenced with a matrix-like, m lines located between the light source and the object to be viewed and n column-yielding optically transparent electrode arrangement, a system of touch sensors and an electronic circuit.

For masking a relatively large light field like that of the ange The given groups of devices have so far mostly been mechanical processes for use in which one or more to be introduced into the light field low or to be removed panel elements are moved by hand. at Photographic cameras are also known to control methods electrically easy way, z. B. by means of a motor, the mechanical parts in motion to set or to dispense with these entirely by removing panel elements an electro-optically variable material, e.g. B. ferroelectric material are used (e.g. DE 28 16 851 or DE 23 29 014).

These known methods have the disadvantage that they, provided that construction parts are moved mechanically, they can jam, such as B. in the case of the blinds used for X-ray negative viewing devices, or these can easily slip and get lost, e.g. B. the at Overhead projections made makeshift paper as screen elements leaves. In addition, all mechanical processes have the disadvantage of the er increased wear of the components involved and the more cumbersome and relatively slow usability.

If it is a known method that is mechanically moved If you do without parts, they have the disadvantage that the position of the translucent permissible range is fixed in advance by the panel arrangement and cannot be set variably.

These disadvantages are intended to be overcome by the invention. Task of The invention is therefore to provide a method for masking a light field To provide mechanical wear and tear on the used Parts are avoided, which is relatively quick and easy to control and that is the generation of rectangular, translucent surface areas in any area and variable position within his Area of action permitted.

The object is achieved based on the method described at the beginning according to the invention that in each step for controlling and defining the area of the transparent area a matrix-like or coordinate-like system of touch sensors is used inside or outside the light field so that when a coupling has taken place any individual sensor whose position within the area or on the coordinate-like legs of the sensor system is registered by means of a signal detector circuit;
this signal is then converted and addressed as a drive signal to mx line detectors and ny column electrodes of the electro-optically variable layer, the electrical fields of which are used to generate a transparent and a shielded surface area;
and on their common boundary line or common corner point there is that point which geometrically corresponds to the position of the coupled individual sensor within its matrix or on a coordinate leg on a scale of 1: f.

Equally, the task is based on the above-described method, dispensing with a separate system of touch sensors, in that the electrode arrangement of the electro-optically variable layer also serves as a system of capacitance sensors and is used so that in each step of defining the translucent area in one Capacitive coupling of any electrode group serving as a single sensor by means of a signal detector circuit whose position within the surface or on the edge areas of the surface of the electro-optically variable layer serving as coordinate legs is registered, this signal is then converted as a driver signal and addressed to mx row electrodes and ny column electrodes whose electrical fields are used to generate a translucent and a shielded surface area, on whose common boundary line or common corner point the capacitively coupled electrodes are located group is located.

Such a method is achieved that on mechanically moved Parts can be dispensed with and the desired translucent Surface area variable on contact in the entire effective area is definable.

In a preferred procedure, the individual sensors are through Touch capacitively coupled. They serve together in groups of two grouped electrodes as single capacitors, grouped into groups of three Electrodes as two series-connected capacitors operating at the same time or fed sequentially from an alternating current source and with a Signal detector circuit can be connected. This procedure has opposite a conductive coupling of the sensors, which is particularly important in the case of a coordi natural execution of the sensor system is also possible, the Advantage that cavities in the sensor and contact impairments Pollution and oxidation can be avoided.

According to a further idea of the invention is in a, operating moderately determined by the electronics way at least one more Definition step of another boundary line or another The corner point of the translucent area is carried out as described. So, depending on the intended use, up to four sides of a rectangular Translucent area determined one after the other and thus its location can be designed in a completely variable manner. To avoid operating errors, e.g. B. when displaying material for viewing, delay circuits, Operating codes (e.g. touching the same point twice only leads to the switching process), reset buttons and much more. m. to be used.

According to yet another idea of the invention, at the same time Coupling of more than one single sensor, which can be achieved with a finger touch emotion can occur at any time, a point out of that covered by it Area as a geometric reference point for the driver signals Area definition of the translucent area utilized. this guaranteed in view of its relatively large dimensions a sufficient definition.

It is suggested that the sensor system, if it has its own, be operated by the electro-optically variable layer represents separate unit, this in to reproduce a certain scale over a large area or in the form of coordinates and, if necessary, provided with a touch protection layer. Provided it is a sensor system within the light field should its components must be transparent so as not to allow light to pass through affect what happens when using ITO or similar materials as conductor tracks and transparent dielectrics is guaranteed. It is advisable to view this as close as possible behind the plane of the tend object to be arranged in order to achieve good coupling properties by means of To achieve finger touch.

Provided that the electrode arrangement of the electro-optically variable layer also serves as a system of capacity sensors, can also be used here as well Matrix-like and coordinate-like control panels be realized. The latter is achieved in that electrodes of z. B. two mutually perpendicular, relatively narrow edge zones of the electro-optically variable layer in a linear arrangement is used for this will. Again, it is advisable to keep a small distance between Pay attention to the contact surface and electrode arrangement.

In the case of insufficient selectivity of the sensor system or functional impairments due to stray voltages, it is thought to improve the switching behavior of the individual sensors with an additional union, transparent or non-transparent mask-like shielding electrode or electrode layer, eg. B. in a further way to form each of these from three electrodes. With a large number (mxn) of coordinate points to be controlled in the electro-optically variable layer, sensor systems designed in the form of coordinates have certain advantages over sensor systems designed in the manner of a matrix: their crosstalk attenuation is higher and the required electronic effort is lower. Matrix-like designed sensor systems, however, are used, especially on a scale of 1: 1 within the light field to be influenced, when a direct control of the electro-optically variable layer from the object plane in direct correspondence with finger contact is desired. This could e.g. B. be the case with jammed negatives that cannot slip or be smeared during operation.

A large number are used for the medium of the electro-optically variable layer of materials under consideration:

Liquid crystal material is most commonly used for such purposes today manure. The contrasts that can be achieved are not too high, but for certain applications of the method described are sufficient. Even though its contrast behavior is strongly dependent on the viewing angle and it to excessive heating with a change in its optical and elec tric properties, it is because of its relative cost cheapness and the existing experience with its processing good to use.

Ferroelectric ceramic material offers the advantage of higher achievable Contrasts, but is more expensive to manufacture and is currently in Pieces of only a small area on the market, which is manufacturing-related. Both of the materials mentioned so far have in common that they are based on an applied electric field with a change in its light scattering properties (transparent-scattering) or their light birefringence react.

Higher contrasts can be achieved with them if they are between two Polarizing filters are arranged. These should be within their level be rotated so that electrically field-free areas are as transparent as possible (Positive contrast) or darkened to the maximum (negative contrast). If with a matrix-shaped electrode arrangement more than one limit line of the translucent area is to be defined, come in general, only those materials are considered for positive contrast that a storage capacity for a set transmission state be sit. The materials that take one to maintain the same need the current flow, should in the above requirement in negative contrast operate.

Colloidal suspensions and electrochemically alterable material are for the electrically field-free state dark or with storage capacity manufacturable (z. B. DE 36 43 690 A1), so they are suitable for the above purposes. Doping of some materials with dye molecules can cause their usability either be a prerequisite or for contrast reduction improve (see also Knoll, P. M .: "Displays"; Heidelberg 1986, pp. 129-226).

When using material that does not extend sufficiently large voltage is available in one piece, it is suggested that the electro optically variable layer in adjacent segments under structure. In order to optimize a possibly insufficient darkening, it is also possible to subdivide them into consecutive segments.

The invention is based on the drawings, which are shown in schematic representation Development contain method and exemplary embodiments, explained. Show it

Fig. 1-5 by way of example according to the method described in the first step dimmed light fields, which in

Fig. 1, a coordinate- shaped sensor system (1 ) outside the light field is assigned, which on the touch at point ( 2 ) through a, this touch geometrically on a scale f = 1: 1 corresponding limit line in a darkened ( 3 ) and a translucent ( 4 ) surface area is divided, Fig. 2 a coordinate- shaped sensor system (1 ) is assigned within the light field, which on the touch at point ( 2 ) by a, this touch geometrically on a scale of f = 1: 1 corresponding limit line is divided into a darkened ( 3 ) and a translucent ( 4 ) area,

Fig. 3 is assigned a matrix-shaped sensor system ( 1 ) within the light field, which upon contact at point ( 2 ) through a corner point of two boundary lines corresponding to this contact geometrically on a scale of f = 1: 1 and through this into a darkened ( 3 ) and a translucent ( 4 ) surface area is divided,

Fig. 4 is a coordinate- shaped sensor system (1 ) outside of the light field is assigned, which on the touch at point ( 2 ) through a, this touch geometrically on a scale f = 0.5: 1 corresponding boundary line in a darkened ( 3 ) and a translucent ( 4 ) surface area is subdivided,

Fig. 5 is assigned a matrix-shaped sensor system ( 1 ) outside the light field, which on the touch at point ( 2 ) through a, this touch geometrically on a scale f = 0.5: 1 corresponding limit line in a darkened ( 3 ) and a translucent ( 4 ) surface area is subdivided,

FIG. 6 and FIG. 7 exemplary embodiments for capacitance sensor arrangements are greatly exaggerated. In the coordinate-shaped figure in FIG. 6, the electrodes ( 7-10 ) are arranged to run linearly, are provided with a contact protection layer ( 5 ) and in a small area with an additional electrode (11 ). The dielectric ( 6 ) serves as a carrier.

In the matrix-like illustration in FIG. 7, a third electrode layer ( 14 ) is allocated over a large area to the electrode groups ( 12, 13). Here, too, the carrier is a dielectric ( 6 ). Finally show

Fig. 8 and Fig. 9 selected configuration options located in the light field components in lateral view. Between a light source ( 20 ) and an object to be viewed ( 15 ) is located in Fig. 8 behind a stabilizing transparent layer ( 18 ), the z. B. can be a ground glass, the electro-optically variable layer ( 19 ) with its matrix-shaped electrode arrangement and optionally in front of it a system of touch sensors ( 17 ), primarily capacitance sensors with a contact protection layer (16 ), and in

Fig. 9 in front of the stabilizing transparent layer ( 18 ), which also z. B. can be a Fresnel lens with a glass plate, the electro-optically variable layer ( 19 ) with a contact protection layer (16 ), between which the two optionally a system of touch sensors ( 17 ), vornehm Lich capacitance sensors can be.

Claims (16)

1. Method for the touch-controlled dimming of a light field,
in particular for viewing devices working in the transmitted light method, which is effective in at least one step on at least one of four sides of a light field that are at right angles to one another, by means of a layer of the area to be influenced, located between the light source and the object to be viewed, with an electro-optically variable transparency in its transparency Light field with a matrix-like, optically transparent electrode arrangement resulting in m rows and n columns,
a system of touch sensors
and an electronic circuit,
characterized in that
In each step for controlling and defining the area of the transparent area ( 4 ) a matrix-like or coordinate-like system of touch sensors ( 1 ) inside or outside the light field is used so that when any individual sensor ( 2 ) is coupled by means of a signal detector circuit Position is registered within the area or on the coordinate-like legs of the sensor system;
this signal is then converted as a driver signal on the mx row electrodes and ny column electrodes of the electro-optically variable layer is addressed, the electrical fields of which are used to generate a light-permeable ( 4 ) and a shielded ( 3 ) surface area;
Finally, on their common boundary line or common corner point is that point which geometrically corresponds to the position of the coupled individual sensor within its matrix or on a coordinate leg on a scale of 1: f. 2. A method for the touch-controlled dimming of a light field, which is effective in at least one step on at least one of four sides of a light field at right angles to one another, by means of a layer of the area of the to be located between the light source and the object to be viewed and electro-optically variable in transparency influencing light field with a matrix-like, optically transparent electrode arrangement resulting in m rows and n columns and an electronic circuit, characterized in that the electrode arrangement of the electro-optically variable layer also serves as a system of capacitance sensors and is used in such a way that in every step of defining the translucent area if any electrode group serving as a single sensor has been capacitively coupled by means of a signal detector circuit, its position within the surface or on the edge areas of the surface serving as coordinate legs The electro-optically variable layer is registered, this signal is then converted as a driver signal and addressed to mx row electrodes and ny column electrodes, the electric fields of which are used to generate a translucent and shielded surface area, on whose common boundary line or common corner point the capacitively coupled te are Electrode group is located. 3. The method according to any one of claims 1 and 2, characterized in that to form the individual sensors, two electrodes each as a capacitor serve simultaneously or sequentially from an AC power source fed and connected to a signal detector circuit. 4. The method according to any one of claims 1 and 2, characterized in that to form the individual sensors three electrodes each as two in Series connected capacitors are used simultaneously or in succession other fed from an AC power source and with a Signalde detector circuit are connected. 5. The method according to any one of claims 1-4, characterized in that at least one further independent definition step by others Boundary lines or corner points of the translucent area in is carried out in the manner indicated. 6. The method according to any one of claims 1-5, characterized in that with simultaneous coupling of several individual sensors a point from the of this area covered as a geometric reference point for the Driver signals is used. 7. The device operated according to the method according to claim 1, characterized in that the system of touch sensors is a unit of the area or coordinate extension of the light field to be influenced on a scale of f : 1, which is essentially made of dielectric carrier material ( 6 ) on it applied electrodes ( 7-13 ), conductor tracks and possibly a contact protection layer (5 ). 8. Apparatus according to claim 7, characterized in that the electrodes and conductor tracks of the system of touch sensors from optically trans parent material (e.g. ITO) insist on an optically transparent rent carrier material between the electro-optically variable layer and the object to be viewed are as close as possible behind it. 9. Device operated according to the method according to one of claims 1-6, characterized in that serving as individual sensors, the electric a further individual electrode or electrode layer over a large area assigned. 10. Device operated according to the method according to one of claims 1-6, characterized in that the electro-optically variable layer as Medium contains liquid crystal material in which by the electro the electric field required for operation in light direction of spread is oriented. 11. Device operated according to the method according to one of claims 1-6, characterized in that the electro-optically variable layer as Medium contains ferroelectric ceramics (e.g. PLZT) in which through the electrode arrangement the electrical field required for operation is oriented longitudinally or transversely to the direction of light propagation. 12. Device according to one of claims 10 and 11, characterized in that that the electro-optically variable layer has two polarization filters are allocated in such a way that the layer is between them located and controlled areas maximally transparent or maximally appear darkened (negative or positive contrast). 13. Device operated according to the method according to one of claims 1-6, characterized in that the electro-optically variable layer in their medium contains a colloidal suspension. 14. Device operated according to the method according to one of claims 1-6, characterized in that the medium of the electro-optically variable Layer by means of an electromechanically reversible reaction in their Light transmission is changeable. 15. Device according to one of claims 10, 13 and 14, characterized in that the material of the electro-optically variable layer with Dye molecules is doped. 16. Device operated according to the method according to one of claims 1-6, characterized in that the electro-optically variable layer in several segments are divided into one level or next to each other two levels are arranged one behind the other.