DE3604120A1 - Contact-sensitive sensor - Google Patents

Abstract

The sensor (1) is provided with a number of transparent first strips (3) and transparent second strips (5) which are insulated from one another and are alternately located next to one another in the same plane (x, y). The first strips (3) are provided with a contact which is connected to a reference potential (via a measuring instrument 13). The second strips (5) are provided at their front-end mutually opposite edges with contacts which are connected to a voltage source (7a, 7b). A measuring instrument (13) is connected between each first strip (3) and the reference potential (M). When a finger (26) presses on the sensor (1), an electrical coupling is produced between two adjacent strips (3, 5). The information to which measuring instrument (13) has responded directly determines the y coordinate of the pressure point (15). The x coordinate is derived directly from the amplitude and polarity of the voltage value indicated on the measuring instrument (13). The sensor (1) is simple and insensitive to interference. It has no hollow spaces entailing the risk of the creation of microorganisms. A transparent carrier is provided for the mechanical stabilisation of the sensor (1). This carrier can be formed directly by the screen (22) of a monitor tube (20). <IMAGE>

Description

The invention relates to a touch-sensitive Sensor. In particular, it concerns a large area Sensor that connects to a screen in the medical technology can be used.

Touch sensitive sensors are used in many areas technology. For example, get big flat sensors as so-called "touch screen" in front of picture screens used (U.S. Patent 4,340,777; U.S. Patent 4,355,202; EP-OS 0 126 345) e.g. B. in medical technology. The Touch sensitive sensor is transparent so that symbols projected from the picture tube onto the screen for operating functions such as B. Volume, Bright speed, etc., are visible from the outside. By touching the Sensor with your finger at the point where you want Operating function is visible, this is in progress puts. The Koordi is first of all generated by the sensor nate of finger pressure determined that of the concerned Operating function is assigned, and then the associated setting parameters changed.

In the case of complicated devices (e.g. computer display, patient monitor) with many setting parameters, the above-mentioned placement of the sensor in front of the picture tube has been adopted. This offers the advantage of being able to occupy the same location on the sensor several times, i.e. with different functions. In the same xy coordinates, different operating functions from the picture tube can be projected onto the screen and thus onto the sensor. Depending on the projection shown, the finger pressure changes different setting parameters.

A contactless sensor is known from the company publication "CM 504 Touch Pad Module" from BSR (USA) Ltd., 3/84, which consists of two layers of conductive material lying one above the other. The two layers are separated from one another by flexible, foam-like spacers. The edges of the lower layer are each provided on their opposite sides with a pair of contacts. In this way, the resistance of the lower layer can be determined both in the x direction and in the y direction. By pressing on the upper of the two layers, which are at a reference potential, e.g. B. ground potential, a short circuit to ground is made at any point in the lower layer. The two partial resistances for the x coordinate between the contact side and the short-circuit point can be determined via the edge contacts of the first layer. This applies analogously to the two contact sides that are assigned to the y coordinate. In this way, the location of finger pressure on the sensor can be determined relatively easily. In this sensor, the two layers are each applied to a transparent plexiglass pane. This creates four interfaces for visible light, which each have a reflection of approx. 4% even in the highly polished state. Overall, a disruptive reflection of approximately 16% occurs if an expensive anti-reflective coating is not used. Furthermore, it should be borne in mind with this sensor that cavities are formed between the first and the second layer, which inevitably form an approach for the formation of microorganisms. This can adversely affect the life of the sensor.

The object of the invention is a touch Lichen sensor so that it is largely unaffected is against climatic changes and at the same time has a low reflection behavior.

The invention is based on the consideration that the ge mentioned concerns can be resolved if it ge succeeds in creating a single-layer sensor.

According to the invention, the stated object is achieved with a Solved sensor, which verse with the following features hen is:

• a) a number of first and second against each other isolated strip of an electrically conductive Material,
• b) electrical contacts on an edge of the first Stripes and on opposite edges of the two strips are attached,
• c) a voltage source connected to the front con clock the second strip is connected, and
• d) a measuring device for determining the coordinate of a exerted on at least two adjacent strips Pressure at which an electrical coupling between these two adjacent stripes is, the measuring device in each case on a contact a first strip and a contact of a be adjacent second strip is connected.

By the measure of the stripes isolated from each other fen is achieved that the in the explanation of Stan of the two layers mentioned in the technology and are arranged side by side. This results in the Advantage that only one carrier is necessary to the Keep sensor mechanically stable. It means that the reflection behavior is significantly improved: on  Instead of four interfaces there are only two interfaces effective areas. The strips are either directly with touchable and therefore accessible or secured against contamination by a protective layer. In In both cases there are no cavities within the Sensor, which with unfavorable climatic conditions for a microclimate, such as B. moisture, fungal formation, etc., is responsible. The metrological effort is comparable to that of existing sensors, so that from no disadvantages have to be accepted there. The voltage source can be a DC or AC voltage source of supply. The electrical coupling for fingers pressure is either galvanic or capacitive.

Further advantages and refinements of the invention he result from the description of execution examples len based on two figures. Show it:

Fig. 1 shows the supervision of a single-layer touch-sensitive sensor and

Fig. 2 shows a cross section of the sensor, which is arranged on the outer surface of a picture tube.

In Fig. 1, 1 denotes a flat, large, touch-sensitive sensor, a so-called "touch screen". The sensor 1 comprises a number of first strips 3 and interleaved between them a number of second strips 5 , both of which consist of transparent, electrically conductive material. A mixture of indium oxide and tin oxide has proven itself as the material. These strips are applied to a plexiglass support (not shown), in particular a thin plexiglass sheet. The plexiglass support is located below the strips 3 , 5 in the plan view according to FIG. 1. It serves to stabilize the sensor 1 , since the strips 3 , 5 are made of very thin material.

Instead of the plexiglass pane, it is also possible to select a picture tube directly as a support for the strips 3 , 5 . In this case, the strips 3 , 5 are evaporated, for example, on the outer glass surface of the picture tube and then provided with a thin protective layer. The protective layer protects both against contamination and against poisoning of the strips 3 , 5 upon contact with the operator's finger while the sensor 1 is actuated. Furthermore, the protective layer has the function of protecting against mechanical damage and, insofar as the sensor 1 is used in the medical field, to meet the safety requirements there with regard to the electrical voltage. The application of the sensor 1 in combination nation with a picture tube is shown in Fig. 2 and will be described later.

The first strip 3 and the second strip 5 are alternately arranged with their long side next to each other net and electrically isolated from each other by an intermediate space 4 . The first strips 3 are connected to an arbitrary edge via a high-impedance resistor (not shown separately) to a reference potential, e.g. B. to Mas se. The second strips 5 are connected to a voltage source 7 at their short, front edges. In the exemplary embodiment shown, the left end edge of the second strip 5 is provided with a contact and leads to a common contact path 9 , which leads to a DC voltage source 7 a with a voltage -U _B of z. B. -5 V is connected, which is at its other pole at the reference potential. Analogously, the right edge of the second strip 5 is connected to a contact path 11 , which to a DC voltage source 7 b of the operating voltage + U _B with z. B. +5 V. These also have their other pole at the reference potential between the right edge of the second strip 5 and the left edge of the second strip 5 , so there is a potential difference of 10 V. The center of the second strip 5 is at potential zero, that is to say the reference potential for the first strips 3 .

Each of the first strips 3 is connected to the reference potential via an associated measuring device 13 , which contains the aforementioned high-resistance resistor. In the execution example, each measuring device 13 is a DC voltage measuring device. Instead, a single measuring device 13 can also be provided, which is placed in multiplexing (not shown in ge) on the individual first strips 3 .

In Fig. 1, a Cartesian coordinate system with its axes x, y located. When a finger is pressed on any point 15 of the sensor 1 , an electrically conductive connection is formed between a first strip 3 and an adjacent second strip 5 . This happens inevitably, since the stripe width is chosen so that at least two adjacent stripes are bridged when tapping only with the fin gerspitze.

As a width for each of the strips 3 , 5 and for the insulating space between the strips 3 , 5 , about 1 mm has proven to be useful. As a result of the connection by the finger pressure, the affected first strip 3 is no longer at reference potential. Depending on the location of the pressure along the x axis, the potential on strip 3 is set to a value between -5 V and +5 V. The DC voltage value is linearly dependent on the x coordinate of the printing point 15 . If the finger pressure has been exerted, for example, on the left edge (x = x ₁ ) of the sensor 1 , the potential strip 5 V is impressed on the first strip 3 , which is detected by the associated measuring device 13 . In the event that the finger pressure was exerted, for example, on the right edge (x = x ₂ ), the first strip 3 is at the potential +5 V, which in turn is detected by the associated measuring device 13 . At x = (x ₂ - x ₁ ) / 2 the measured potential is 0 V. Because of the linear dependence of the voltage value on the coordinate x , the x coordinate can be derived in a simple manner from the measured voltage value. The measured voltage value is itself a direct measured value for the location x .

To determine the y coordinate, it is only neces sary to detect which of the measuring devices 13 has a deflection, ie which indicates a voltage value not equal to zero. Since each first strip 3 is assigned its own measuring device 13 , the position of the first strip 3 with respect to the y coordinate can be derived directly therefrom.

With the present arrangement, a sensor 1 is ge, which consists only of a single layer of conductive strips 3 , 5 and additionally a see-through carrier. As a result, there is no space between the first strip 3 and the second strip 5 , which is a starting point for a microclimate, for. B. with moisture and fungus formation.

Instead of the two same DC voltage sources 7 a , 7 b , which was used here for simplicity of illustration, it is equally possible to use an AC voltage source. In this case, an electrically conductive contact is not caused by the finger pressure, but a different type of coupling, specifically a change in capacitance between the strips 3 , 5 . The location x of the finger pressure can then z. B. determine via a resonant circuit or the phase shift of the AC voltage. The location is again determined by the measuring instrument 13 that has addressed.

In Fig. 2, the sensor 1 is a side view of a picture tube 20 Darge in side view with direct application on the screen. The first and second transparent strips 3 , 5 are applied directly to the outer surface of the glass plate 22 of the picture tube 20 . For example, they can be glued or vapor-deposited there. The spaces between the strips 3 , 5 are filled with a protective layer 24 , which also covers the upper sides of the strips 3 , 5 . In this way, no cavities arise in the sensor 1 . The protective layer 24 preferably has a thickness of λ quarter, the wavelength λ being, for example, approximately 550 nm. It is important to ensure that the two refractive indices of sensor 1 and glass plate 22 are well matched. The finger of the operator who, by means of his finger pressure, guides a location and, depending on it, an operating function (ie the change in a setting parameter on the picture tube 20 and on a device connected to it) is identified by 26 .

Claims (12)

1. Touch-sensitive sensor with

• a) a number of first and second mutually insulated strips ( 3 , 5 ) made of an electrically conductive material,
• b) electrical contacts which are attached to one edge of the first strips ( 3 ) and to opposite edges of the second strips ( 5 ),
• c) a voltage source ( 7 a , 7 b ), which is connected to the end contacts of the second strip ( 5 ), and
• d) at least one measuring device ( 13 ) for determining the coordinate ( x , y ) of a pressure exerted on at least two adjacent strips ( 3 , 5 ), in which an electrical coupling between these two adjacent strips ( 3 , 5 ) is caused , wherein the measuring device ( 13 ) is connected to the contact of the first strip ( 3 ) and one of the contacts of an adjacent second strip ( 5 ).

2. Sensor according to claim 1, characterized in that the contacts of the first and second strips ( 3 , 5 ) spatially alternately to the voltage source ( 7 a , 7 b ) or via the measuring device ( 13 ) to a reference potential ( M ) are laid. 3. Sensor according to claim 2, characterized in that the voltage source ( 7 a , 7 b ) placed second strip ( 5 ) are connected at their two end edges with a common contact path ( 9 , 11 ). 4. Sensor according to claim 3, characterized in that the contact path ( 9 ) of one edge of the strip ( 5 ) with a different potential (-U _B , + U _B ) is applied than the contact path ( 11 ) of the other edge. 5. Sensor according to one of claims 1 to 4, characterized in that the voltage source ( 7 a , 7 b ) is ausgebil det as an AC voltage source and the measuring device ( 13 ) for capacitive measurement. 6. Sensor according to one of claims 1 to 5, characterized in that the strips ( 3 , 5 ) are provided with a protective layer ( 24 ) for avoiding pollution. 7. Sensor according to claim 6, characterized in that the protective layer ( 24 ) has a thickness of lambda quarter, the wavelength lambda being approximately 550 nm. 8. Sensor according to one of claims 1 to 7, characterized in that the strips ( 3 , 5 ) are transparent to visible light. 9. Sensor according to one of claims 1 to 8, characterized in that the strips ( 3 , 5 ) are applied directly to the outside ( 22 ) of a picture tube ( 20 ). 10. Sensor according to one of claims 1 to 9, characterized in that the strips ( 3 , 5 ) consist of a mixture of indium oxide and tin oxide. 11. Sensor according to one of claims 1 to 10, characterized in that the strips ( 3 , 5 ) each have a width of approximately 1 mm. 12. Sensor according to one of claims 1 to 11, characterized in that next to each first strip ( 3 ) is at least one in the same plane (x, y) arranged further strip ( 5 ).