DE19744791C2 - Capacitive keyboard - Google Patents

Description

In addition to the measurement of capacities, capacitive sensors are also used Proximity switches known to convert into a high / low signal, the Sensor surface is often arranged on the front of a compact housing and their Capacity to the housing mass affects the vibration condition. Such a The oscillator must be installed directly at the measuring location, a local separation from Sensor surface and evaluation electronics is due to the sensitivity reducing Influence of parasitic capacities avoided. Inductors and feedback effects Keyboard arrangements force selective solutions, create matching and Positioning problems and stand in the way of miniaturization. In principle, they only achieve low switching frequency and are sensitive on foreign fields and the presence of water with its high Dielectric constant. From document DB 40 06 119 A1 it is known that the active Electrode of a compact capacitive displacement transducer, consisting of an oscillator, transmitter and Receiving capacity, demodulator and switching amplifier consisting of a Shielding electrode has been added to reduce the influence of water and static Shield capacities. From DE 94 03 322 U1 there is one Confirmed touch switch plate, whose selective electronics immediately behind the Electrodes is arranged on a flexible printed circuit board in order to create a to achieve extensive bonding with a curved front plate. In the Document EP-0 517745 B1 is a capacitive circuit card with a special Layer structure of conductor track grid and screen areas different when used conductive materials described to influence parasitic coupling elements push back and still an evaluable signal for downstream amplifiers receive. High-frequency keys have become known as back glass keyboards can be installed together with directly connected evaluation electronics. As an alternative to capacitive sensors, mechanical contacts and switches are used as Input elements of information with not inconsiderable technical effort magnetic, optical and other sensors replaced. EP-0 618680 B1 describes how through a glass pane from the reflection of an infrared beam e.g. For example, on an approaching finger, an output signal is safely derived.  

In the patent DE 195 01 232 C1 is a method and a circuit arrangement for a capacitive, digital proximity switch described, the static via a control loop Ambient capacities compensated and only capacity changes, for example by a Manual approach triggered, evaluated.

In the document WO 8503605 there is a possible arrangement of neighboring ones Sensor areas shown.

In the document DE 88 12 393 U1 are capacitive switching foils with excitation surfaces and neighboring sensor areas described, with a conductive additional Shielding area should reduce parasitic coupling capacities.

This principle is also used in US 5239152, the two Coupling surfaces are designed to be translucent and therefore additionally one enable illuminated key labeling.

In the document DE 295 19 714 U1 a cooktop with troughs described in which a finger with earth potential can be placed. Below the A tapping electrode is located in the troughs, one to the grounded finger forms measurable capacity. Again, the presence of the finger becomes Generate a positioning command, e.g. B. for switching on a hob, in one redesigned electronics used.

With many researched solutions, it proves to be disadvantageous to have one at the point of entry Information on the back of a housing wall or electronic converters on it need to arrange mechanical switches and ensure their power supply. The capacitive systems that have become known also have the disadvantage of capacitive changes in the detection range and in the presence of dielectric Fabrics to change the switching properties. An installation on metallic surfaces leads to strong capacitive shunts and loss of sensitivity. Only that Patent specification DE 195 01 232 C1 specifies to automatically compensate for environmental influences and to be able to position the evaluation electronics far from the sensor surfaces. The simultaneous Use of a hand-held keyboard as an interface for external control devices is not known.

The object of the invention is, for. Example for the in the patent DE 195 01 232 proposed evaluation electronics to find a capacitive key and keyboard arrangement, which can be placed flat on any surface with an extremely flat design, transparent for underlying objects such as graphic prints, projection screens, LC displays, indicator lights and PC screens are vandal-proof and also used as a back glass keyboard and at extreme ambient temperatures can be. It should not only be used for manual input, but also as a capacitive one Interface can be used for external control units.

This task is solved by a keyboard with the Features of claim 1.  

With the capacitive key and keyboard arrangement according to the invention in connection with a suitable evaluation method, e.g. For example, described in DE 195 01 232 C1 Buttons are extremely close to each other, environmental influences are compensated for and the evaluation electronics are arranged far away. The simple structure can therefore extremely compact, monolithic, flat, shatterproof, transparent, chemically inert and for can be designed over a wide temperature range. It is in front of and behind dielectric Walls can be operated just as securely as they are easy to attach. It does not need to be compared power supply and the extremely low displacement currents allow for their Transmission of high-resistance supply lines, which can therefore have extremely small cross-sections. Foil lines with vapor-deposited conductor lines are also suitable for this. The elimination any mechanics and electronics on site, the possibility of both-sided operation of the keyboard and almost complete freedom from wear and vandalism security practically lead to unlimited life. The dielectric material can be glass, plexiglass, Polycarbonate, tiles, marble, plastics, wood, lacquer layers and the like. a. used and a high degree of protection can be achieved. The keyboard and keyboard according to the invention Arrangements can be operated from one or both sides. With these properties, inexpensive, universally usable keyboards and buttons are available Elevators, timers, locks, gaming machines, information areas, wet rooms, Medical technology, automation technology up to touchscreen applications for rough Operating conditions ready.

The invention is described below using an exemplary embodiment explained.

Fig. 1 shows a schematic section of the layer structure of a keyboard according to the invention. Parallel conductor tracks ( 2 ) and ( 5 ) intersect in the form of a matrix ( 14 ) (see FIG. 2), each at the crossing point ( 11 ) having a width widening, preferably in the form of two symmetrical squares within a button ( 13 ). It is filled in half by both widenings ( 12 ). A button ( 13 ) can also be filled by only one expanded conductor track (single button).

Approaching or removing a finger from the buttons ( 13 ) is associated with relatively large changes in capacity due to the widening of the area ( 12 ) of the conductor tracks ( 2 ) and / or ( 5 ), which changes separately from the connected evaluation electronics ( 3 ) as an approach and distance signal is registered for each line. A logical combination of these signals is done e.g. For example, in a microcomputer downstream of the evaluation electronics ( 3 ).

The structure of the invention enables the keyboard to be operated from both sides. If this is not desired, an additional screen surface ( 7 ) is used. The additional static capacities are eliminated by the evaluation electronics ( 3 ).

Strip lines ( 8 ) or coaxial cables ( 8 ) take over the connection between the keyboard and the evaluation electronics. It can be arranged well over 10 meters away and can be an integral part of peripheral additional electronics.

Choosing transparent, dielectric layers ( 1 ), ( 6 ) and steaming transparent conductor tracks ( 2 ), ( 5 ) z. For example, on a glass substrate, the keyboard becomes transparent and it can be illuminated from the side or from below. A key assignment table can be stored. In conjunction with a computer screen, the invisible buttons can be defined in software and serve as a touchscreen.

Installation of the keyboard in the device housing no longer requires an attached unit. The plastic housing wall of the device itself takes on the function of a first dielectric layer ( 1 ). Knobs, troughs or imprints can be used to optically locate the buttons or mark capacitive coupling surfaces for external control devices. This eliminates breakthroughs in the device wall.

A single button, built according to this principle, is at every point on the inside of the housing positionable. Extremely flat, a single key or keyboard can also be opened any surface can be glued or screwed on.

Claims (5)

1. Capacitive keyboard with a matrix shape on one another arranged between a first dielectric layer (1) and a second dielectric layer (6) conductive tracks (2, 5), wherein the conductor tracks (2, 5) at their crossing points (11) each having a width widening (12 ) within a common button ( 13 ), and the dielectric layers ( 1 , 6 ) above the buttons ( 13 ) have thickened areas ( 9 ) or troughs ( 10 ) which form capacitive coupling areas for externally arranged control units ( 15 ). 2. Arrangement according to claim 1, characterized in that a conductive screen surface ( 7 ) is optionally arranged on the outer surfaces of one of the dielectric layers ( 1 or 6 ). 3. Arrangement according to claim 1, characterized in that the dielectric layers ( 1 and 6 ), the conductor tracks ( 2 and 5 ), the insulating layer ( 4 ) and the screen surface ( 7 ) are optionally transparent. 4. Arrangement according to claim 1, characterized in that the conductor tracks ( 2 and 5 ) and the shield surface ( 7 ) are connected galvanically or capacitively via lines ( 8 ) to a remote evaluation electronics ( 3 ). 5. Arrangement according to claim 1, characterized in that the dielectric layer ( 1 ) and / or the dielectric layer ( 6 ) are optionally part of a wall.