SE440969B - DEVICE AT KEYBOARD - Google Patents

Description

shows in view the 3 F; but; the execution form; Fig. 7 shows a section along the line VII-VII in Fig. 6; the fifth embodiment in section; Fig. 9 shows the sixth embodiment in perspective view; Figs. 10-12 show in front view the same embodiment in three different use-perspective nose arenas if a body is pressed with complete abutment against one of the surfaces of the prism.

Through this phenomenon, for example, by pressing the finger against the prism, one can obtain a measurable change by means of a photosensitive element of the light which leaves the prism when it is exposed to a luminous flux.

In the mentioned and other principles for forming so-called touch keys, a keyboard with several operating functions can be built up as a single plate on which the various operating functions are marked as surfaces, which are to be touched with the fingertip. Although a keyboard can in this way be built up by a single one which selectively responds to the control pulse which is transmitted to the specific area belonging to the sensing means in question. Even if they have succeeded in eliminating mechanical elements such as keys and electrical switches, they still have a large number of elements and essentially the same as a multiple of the number of operating functions. The wiring also becomes complicated and essentially as complicated as with older, mechanical systems.

The present invention has for its object to provide a device at the keyboard for a plurality of operating functions, through which the number of required elements can be considerably reduced.

A particular object of the invention is then to achieve said object in a device which utilizes the said optoelectronic principle in order to achieve the operating function.

A further object of the invention is to enable the elimination of the noise from certain sources of interference, such as periodic signals from the environment.

The object of the invention is achieved by carrying out the device with the features stated in claim 1.

To exemplify the invention, six embodiments thereof are described below, in which certain variants are also stated. A reference to the concerned, previously known technology is also made. For clarification of the description, reference is made to a number of drawings in which Fig. 1 shows as an example the initially mentioned optoelectronic system; Fig. 2 shows an external view of a keyboard according to the first embodiment of the invention; Fig. 3 shows an internal view of the keyboard according to Fig. 2, which view simultaneously constitutes a wiring diagram; Fig. 4 the second embodiment; Fig. 5 shows in view the third embodiment Fig. 6 shows an external view of a part of a keyboard according to the fourth Fig. 8 shows the condition; 1 and fig. 13 and 14 show time diagrams of the device's function in two different variants. plate, however, special sensing means are required for each operating function. As an example of the technique to which the invention is applied, Fig. 1 shows an optoelectronic key device of the aforementioned type. It is described in the Swedish patent specification no. 7613597-9, which corresponds to U.S. Pat. No. 4,254,333 and GB patent specification no. l 600 556. The basic device is multiple to form a keyboard. Its outer side is formed by the outer surface 1 of a glass plate 2.

The second surface 3 of the glass sheet is provided with a light-tight coating 4 with a number of windows under which glass prisms 5 are arranged in optical contact with the glass sheet.

Fig. 1 shows three glass prisms 5 and each of these is exposed to a light beam 6 from a light emitting element 7, such as an LED, which receives current from a power supply device 8. Next to each prism is arranged a photosensitive element 9 such as a photodiode, which is connected to a signal processing device 10. As long as the part of the glass surface 1 located in the middle of each prism 5 is not touched, substantially total reflection takes place within the prism as a straight block with respect to its edges and the photosensitive element 9 which is arranged at the edge is thus not reached by the radiation from the light-emitting element 7. If, on the other hand, a surface is shown, here shown as belonging to a fingertip 11 with complete contact with the surface 1 of the glass plate 2, the reflection is at least partially canceled and a certain amount of light leaves the prism and hits the photosensitive element 9. The difference in the amount of light hitting the photosensitive element was used to produce a signal from the signal processing device 10, which is used as an operating pulse for the operating function assigned to the corresponding point of contact on the glass surface 1. For a more detailed description of the principle in its various forms of use and the equipment for utilizing it, however, reference is made to said patents.

As can be seen from Fig. 1, in the known device now described, a complete system consisting of a light-emitting element, a prism and a light-sensitive element is required for each operating function. The power supply device, on the other hand, can be common to all light-emitting elements as well as the signal processing device, especially if modern semiconductor technology is used and, for example, a microprocessor is used for the purpose. The said fact that certain vital elements must correspond in number to the number of operating functions while other elements may be common also applies in principle to key devices according to other physical principles which can be used in the present invention. The following description of the application of the invention, which is clarified by Figures 2-11 of the drawings, is, however, linked to the optoelectronic principle now described.

Following the description given of the optoelectronic device, the application of the invention to such a device is now described. Fig. 2 shows a view of a keyboard 15 consisting of a glass plate 16 with a number of marking surfaces 17 bearing QtifiLITY v ... -f- ~ os, which bear designations 18 with symbols A-F for marking certain operating functions. Fig. 2 also shows a light-sensitive element 19, for example a photodiode and a signal processing device, for example a microprocessor with associated power supply device, for example a battery, together forming a unit 20. Between the element 19 and the edge of the glass plate 16 there is an air gap essentially eliminates the influence of light sources other than the elements 21. The figures also show certain electrical wires.

Below the glass plate 16 there are further elements and these are shown in Fig. 3.

They consist of a number of light-emitting elements 21, for example LEDs. They correspond to the number of fields 17 and are located under separate fields. Fig. 3 also shows the light-sensitive element 19, the electronic unit 20, which is shown here in the form of a microprocessor 22 and a power supply battery23.

Since Fig. 3 also constitutes a wiring diagram, it appears from the same that the LEDs 21 are separately connected to the microprocessor 22 and that the light-sensitive element 19 is also connected to the same. Also shown are a number of lines 24 which are intended for delivering signal pulses to the means to be operated from the keyboard. The keyboard can, for example, be arranged on a washing machine, the different control fields representing different washing programs.

In such a case, the signal lines 24 run to the machine's software for setting the same to execute the selected program.

The various details of the device must be designed in such a way that the said optoelectronic function can be achieved. Thus, the light emitting elements 21 should be arranged to send their radiation into the glass plate 16 from its rear side, which is opposite to the side on which the marking fields 17 are actuated by pressing a finger.

The light-sensitive element 19, on the other hand, is arranged at the edge of the glass plate with an air gap for receiving the radiation which, when touched by the respective marking fields 17, is totally reflected within the plate. Although a light-sensitive element is a preferred embodiment, it may be appropriate to provide several light-sensitive elements, especially for large keyboards. In other words, the disc is not provided with any special prisms but acts in its entirety as a prism with a number of functions, namely to achieve total reflection within the glass disc as soon as any of the marking fields 17 are touched. Suitably the glass sheet 2 is provided with a non-light transmissive coating in areas where it is desired to avoid secondary radiation into the sheet from external light sources.

Fig. 2 shows how the fields 17 are clearly separated from each other and arranged in rows. This is suitable when selecting on / off mode for a number of "I functions. In other operating cases, a different disposition may be suitable. Fig. 4 thus shows an arrangement which is intended to replace a so-called joy- l - ii * .-. Ii f, _12? .Rev i: f "* Te -f- fl e-í-ii Li» 5 2401551-s stick. With such, different degrees are generally selected by two functions, for example height position and side position or speed and direction. In the device shown in Fig. 4, a glass plate 26 within a marked area 27 has a very large number of contact fields arranged in horizontal and vertical rows, which on the underside of the plate each correspond to a light emitting element 28. An arrow 29 indicates that a movement in vertical direction gives an increase in speed from zero and with an arrow 29 it is indicated that when moving in the side directions a change of direction is obtained from straight ahead to left and right turn respectively. Depending on the position of the contact element, for example the fingertip within the field 27, a vehicle can thus be controlled to speed and direction of travel by moving in different directions in the field. Fig. 5 shows a device which is suitable for obtaining a change of direction. A circular ring-shaped area 32 is marked here on a glass plate 31, below which a number of light-emitting elements 33 are arranged in an annular shape. An arrow 34 indicates that if a contact element, for example the fingertip, is moved within the circular ring-shaped field 32 clockwise, a change of a feature. Suitably the device is used for adjusting a device in different rotational positions. An example is use in an antenna converter. Although no radiation from the light emitting elements can substantially reach out through the edges of the glass sheet other than when applying a surface to the glass sheet, when the light passes through the sheet to its outer surface, where the fields of pressure are located. In other words, you see the light-emitting elements from the front of the disc. They can therefore be used for marking where the pressure fields are located and also for signaling occupied operating positions, waiting positions and the like.

In the embodiments described so far, there have been no mechanical elements in the form of keys. Operation thus takes place only by pressing some element, preferably the fingertip, against the corresponding field on the glass plate. If desired, another element can be used and this is necessary if maneuvering is to be possible with a gloved hand. In this case, the element must provide total contact with the surface of the glass sheet, which can be achieved with, for example, soft rubber.

There are also cases where, for physiological reasons, one needs the feeling of a direct impression of some element, not just a touch. This is the case, for example, with calculators, where it is very important to register the correct number.

It is therefore desired to overcome a certain pressure resistance, so that registration is not inadvertently achieved by a light touch of a surface. In the case of typewriters and piano instruments, the same situation applies in general, and in general those who are to use such instruments have a long-term training from such with depressible keys or the like. It may therefore be desirable to provide the device according to the invention with keys. Despite this, the invention offers a considerable possibility for simple design in relation to known key devices. There is also the possibility of making the device completely closed, the glass plate can be inserted tightly in a housing so that delicate functions are protected from external influences. An embodiment which gives said advantages is shown in Figs. 6 and 7.

Fig. 6 shows a part of a keyboard 36, which constitutes the keyboard of a typewriter. Fig. 6 shows a number of keys 37 which are included in openings 38 in a hard plate 39. As can be seen from Fig. 7, the keys 37 are projections on a plate 40 which is made of rubber-elastic material which is optically light_t at the radiation used. This plate is held by the said plate 39 and an underlying plate 41, which is also provided with openings 42, through which the opposite projections 43 of the keys 37 extend.

Opposite these projections is a glass plate 44 with an upper surface 45 and a lower surface 46. When the keys 37 are not affected, the outer surface 47 of the projections 43 has a distance to the surface 45 of the glass plate 44. If a key is pressed, the surface 47 will be pressed against the glass plate surface. 45 in that the material in the plate 40 is able to spring. This can be facilitated, as shown, if the keys 37 and the projections 43, respectively, connect to the plate otherwise via notches. Since the material in the plate 40 with the projections 43 is made of a rubber-elastic material, said total abutment is obtained against the surface 45 of the glass sheet 44.

The glass plate 44 is in turn inserted into a housing 48 in which a number of light-emitting elements such as light-emitting diodes 49 are located in opposite positions to the projections 43. At the edge of the glass plate a light-sensitive element 50 is arranged. Also in this embodiment there are devices for power supply and signal processing.

Fig. 8 shows a further simplified form of a keyboard with pressable keys. The keyboard device according to Fig. 8 has as a housing a box 60 (shown only with its edge portion), which is intended to enclose the electronic equipment. A projecting edge 61 of the box 60 is enclosed by a lid 62 of rubber-elastic material, the main part 63 of which forms the front of the device. The main part 63 is provided with raised portions 64, which form the "tangents". By means of the edge 65 of the lid 62, which is held to the box 60, a glass plate 66 and a hard plate 67 with holes 68 are also held. The glass plate 66 is included in the optoelectronic device in the manner previously described. The hard plate keeps the lid 62 away from the glass plate. However, its raised portions 64 can be pressed down through the holes 68, each of which is located in the middle of a ridge 64. The ridges then reach the surface of the glass sheet and achieve the described function.

For the embodiments now described, it has been stated that the light produced next to the respective control field is provided by means of a light source arranged next to each field, suitably a light-emitting diode. However, it is alternatively possible to use a traveling light beam from one or more light sources. This ray of light must then sweep over the prism so fast that the eye, through its inertia, perceives the fields as illuminated at the same time. Since the beam is located within each field for a certain period of time of its sweep cycle, it is possible to select the light signals from the fields which are obtained when they are touched for operation.

Fig. 9 shows an embodiment based on this principle. A cathode ray tube 70 with an electron gun 71 is used. Opposite the electron gun is a prism in the form of a glass plate 72. This glass plate is arranged to be illuminated by the cathode ray either by constituting the screen 70 of the tube 70 or by placing the glass plate in front of the screen. . At the edge of the glass plate a light detector 73 is arranged, as previously described, Fig. 2 compares with the associated description sections. The glass plate 72 constitutes the operating table of the device and its operating field is formed by light fields 74 produced by means of the electron beam.

The device is connected to a control device which provides a sweeping movement of the electron beam, during which it is switched on and off in such a way that different images can be built up. Such a device for creating images is, however, previously well known from oscilloscopes and TV technology and a standard video screen can be used. In addition, there is a control device which detects from which field a signal received by the light detector 73 originates.

This possibility for constructing light images on the glass plate 72 is used to create the control fields 74. By suitable influence of the control device, different figurations can be built up, so that a variable control table is obtained.

How this can be used is shown in Figs. 10-12. Thus, you can imagine that you have a computer terminal, which allows ordering tickets. The terminal is equipped with a control table of the type now described. If it is then indicated that you wish to order tickets, a control image according to Fig. 10 can be produced where different types of tickets are indicated. Here it is assumed that "T" indicates theater tickets. If the field marked "T" in question, thus the field 75 in Fig. 10 is touched, this causes a change of the control device so that the electron beam instead builds up the figuration according to Fig. 11. Here it is stated after the selection that one wanted to order theater tickets. indications for different theaters. Assuming that one now selects the theater "D" by touching the field 76 in Fig. 11, a new change of the image is effected to, as shown in the example in Fig. 12, a presentation of the seat configuration in the theater "D". In this, it is stated by information transfer to the terminal which locations are already occupied. Each place not marked in this way forms a light field which can be touched and thereby provide a selectable signal via the light detector 73, which is forwarded to the main computer for the corresponding order marking line at the theater in question. This is only an example of how a variable control table can be used.

This embodiment has been described with a cathode ray tube, which is a common form of the device for constructing light images. However, the idea of utilizing the optoelectronic phenomenon fundamental to the invention and the characteristic of the invention to thereby detect different signals diverted from one and the same prism can also be used together with other image-building devices. Thus, it is conceivable to use it together with monitors which utilize LC technology or monitors which utilize a large number of light sources, thus of the type of light boards. A simple projection device, which moves a light beam from the control field to the inner field at a certain rate, can also be used. Presentations in both color and black and white can be used.

In all the cases described, the desired operating function is achieved by detecting the position on the glass plate of the pressure relief element, thus the fingertip or the projection of the key plate (Figs. 8-9). This is achieved by means of the light which is deflected at the touch, so that the receiver, thus the light-sensitive element, is affected. However, the receiver is not able to detect from which field the light is deflected to the receiver. Only the distance between the respective light field and the receiver can not be used to provide securely separable signals. The meaning of the invention is that the different light fields are distinguished for detecting which of them has been used and in the following way. The function of the embodiments according to Figs. 1-8 is first described: The said signal processing device, which is suitably a microprocessor, is arranged to transmit a special activation signal to each of the light emitting elements. It can also be seen from Fig. 3 how each of these is connected by a special line to the signal processing device 20.

In addition, the device is designed to select the different signals obtained from the light receiving element and corresponding to the signal emitted by the light emitting element in question when its light is transmitted to the light receiving element. In accordance with this selection of the signals, it can be determined at which light emitting element the pressing has taken place and the signal processing device emits the predetermined, adequate control signal accordingly.

You can use different paths to create distinct signals. Fig. 13 shows in diagrammatic form a time shift between the signals. Each of the curves A-F indicates the signal processing for the different fields A-F, shown in Fig. 2. The fields can be said to represent contact paths. In Fig. 13, there, s4o1ss1 + s at the solid lines light signals from the light emitting elements and the dashed lines indicate periods during which individual contact paths are open for influence from the light receiving element. Thus broadcast from it. field A corresponding to the light emitting element a flash at 52, curve A in Fig. 13. During the course of the flash 52 the signal processing device is susceptible to influencing a special contact path of a signal from the light receiving element for a period of time 53. Said contact path is arranged so that a activation by means of a light pulse during the period 53 produces a signal in the control line corresponding to the control function A. Similarly, the light emitting element at the contact field B receives a light pulse during the time period 54 and within the same time period or a slightly longer time period is the corresponding contact path. receptive to an impulse from the light receiving element, see time period 55. If, on the other hand, as shown in curve C, the corresponding field is not obscured, no light pulse is obtained during the activation period of the contact path corresponding to field C and no control signal is output. When all the light emitting elements have been traversed, a new sequence is started, as shown on the right in Fig. 13. Fig. 13 thus almost illustrates the case that all fields except field C are covered. The sequence length must be so short that it is shorter than the shortest contact time, which must be considered for maneuvering.

Fig. 14 shows how the light pulse can be divided into several sub-pulses 56, a number of which are within the activation area 57 for the contact path in question. The signal processing device is then arranged to be activated only by a signal with a certain determined frequency. Thus, signals of a different frequency do not produce a control signal even if they occur during the respective reception periods. By choosing a frequency that is outside the frequency of ambient light, you can obtain a high degree of protection against error maneuvers through incident light. In itself, a device is the optoelectronic principle described, relatively insensitive to ambient light, but under specific circumstances there may be a risk of interfering with the operation of the device. Usually, however, light in the surroundings is either even, the daylight does not vary according to any particular frequency, or, in the case of electric light, flashing in step with a mains frequency. By selecting a frequency that is at a distance from the mains frequency, you can select the light emitted by the emitting elements from both daylight and the electric light.

As an alternative to a time shift of the light pulses, the different light-emitting elements can be caused to emit light of a frequency specific to each element. The signal processing device shall then be equipped to transmit the control signals in accordance with the frequency received and which indicates that the corresponding field has been touched. Within the scope of the invention is also the use of other types of coding of the signal than the use of different frequencies. The function of the device according to Figs. 2 and 3 is thus that if one of the fields A-F is touched, the light pulse from the corresponding light-emitting element will be transmitted on to the light-sensitive element. The signal processing device is during the period when the light pulse is emitted sensitive to the influence of a specific "grind'z", which is arranged to emit an operating signal to the operating means corresponding to the field in question when a light pulse is received by the light-sensitive If, on the other hand, the field is not affected, the light pulse will never reach the light-sensitive element and no corresponding control signal will be emitted.

If, as previously mentioned, the light emitting elements are used for marking certain functions, for example that a certain position has been taken, the light emitting element in question can be allowed to shine for longer periods between the identifying light pulses. With a sufficiently fast signal sequence, this can be perceived by the eye as a fixed glow, which can be observed from the front of the keyboard. It is also possible to arrange special light emitting elements under the plate for marking certain functions. If these then deviate from a common code system, they will have no effect on the control function. This applies, for example, if they are lit with a steady light while the "control transmitters" flash at a certain frequency, cf. Fig. 13 with the associated description. The device according to Figs. 6, 7 and 8 operates in a corresponding manner, only with the difference that instead of controlling the light with the fingertip, control takes place by pressing the projection 43 of the key plate 40 against the glass plate.

In the case of the "joy-stick" plate according to Fig. 4, a more complicated interpretation of the signals must be applied. affects the degree of another function, for example the turning of the steering wheels in a vehicle.

In the embodiment according to Fig. 5, the position of the affected field is compared with the position of a part to be operated, for example the rotational position of an antenna. Setting then takes place until the latter mode corresponds to the former. As has been seen, a transmitting element is used for the device according to the invention now discussed, for each operating function, but for the whole device only one receiving element, or in exceptional cases, for example, for large keyboards, a few receiving elements. The simplification and thus the cost reduction becomes significant and increases with increasing number of functions. In the optoelectronic system, the reduction in the number of receiving elements, thus phototransistors or the like, is of great importance because such elements as components entail higher costs than transmitting elements, the light emitting diodes. The reduction in the number of photosensitive elements takes place in the face of the sacrifice that a more complicated signal processing system must be introduced. However, the required functions can be obtained at a very low component price by means of modern microprocessors. The cost does not increase in proportion to the number of functions, while the cost of the light-sensitive elements is directly related to the number of elements. With a large number of control functions, the cost increase through the more complicated signal processing is therefore practically negligible, while the savings due to the reduced number of light-sensitive elements are of great importance from both a cost and space point of view. The invention makes it possible to use very complicated control panels even in consumer products where the cost is of great importance. In addition, the special advantages of the optoelectronic system, namely safe function and great insensitivity to influences from the environment, can also be used on complicated keyboards with a large number of operating functions.

In the previous functional description, with reference to Figures 13, 14, it has been stated how a selection of the different fields is achieved by a time division of the respective lighting of the fields. Such a time division is built into a system with a sweeping, image-building beam as indicated in connection with Figures 9-12. This available effect can thus be used to detect which field is affected during a maneuver.

Using the scanning technique used to build a TV picture, each light field 74 (Fig. 9) will be built up of a plurality of lines, each of which forms a section of a line across the entire width of the screen. This means that for each light field emitted when pressed, which has a duration that extends over several complete structures of the image field (a complete image is usually produced in 1/25 - 1/30 second), a number of very short light pulses will be diverted to the light detector. 73. Each of its light pulses has its own specific time period throughout the sweep cycle. By a suitable signal processing of the signal obtained from the light detector according to the adequate time sections obtained by the control of the sweeping beam, any conceivable operating field constructed as a light field can be detected.

As stated above, the term "control field" represents not only permanently marked, visible fields on the control table but also mechanically maneuverable fields such as keys and also fields which consist only of illuminated sub-surfaces of the control table without any permanent material marking.

Claims (11)

ßâ fi iiäsš- “lëå '/ z PATENTKRAV Device at the keyboard, which has a surface area (1) of a hard, translucent body, preferably of glass in the form of a prism (16), which is divided into control fields (17), each of which is assigned a control function and which are intended to obtain, at the desired respective operating function, abutment against the surface of the prism by a surface such as the surface of a fingertip, thereby deflecting light produced next to the field in relation to the luminous flux in the untouched surface, which light flux change is transmitted to a light detecting receiver (19 ) by means of which an adequate control signal is produced, characterized in that a control device (20) is arranged to produce by means of transmitter elements a signal specific for each field (17), detectable from the light flux signals from other fields, that as receiver element (19) is preferably provided a single element or a few elements to the number of less than the number of fields (17) and that a signal processing device (20) therein is arranged to select the signal received from the receiver element in accordance with the specific signal character of the transmitter elements and to send an appropriate control signal to the respective field in accordance with this selection, the keyboard operating in a manner known per se according to the optoelectronic principle. Device according to claim 1, characterized in that the receiving element (19) or the elements are protected against influence from foreign radiation by means of an air gap to the adjacent surface of the prism (16). Device according to claim 1 or 2, characterized in that the signals produced next to each field are separated by being output in sequence during the assignment of each at least a specific time period (52, 54) and that the signal processing device (20 ) is arranged to select the received signal by determining the time period or periods (53, 55) within which it was received and which substantially correspond to the period or periods within which it was transmitted. Device according to claim 3, characterized in that the control and signal processing schemes (20) are formed by a processor which is arranged to activate the light production in the said manner next to the fields (17), so that the signals are emitted during a time section specific to each of the fields and during the same time section keeping a signal path open from the receiver (19) to a specific control line (24), which corresponds to the control function assigned to the field (17) in question, so that a the activation period for respective light production from the receiver mediated sigma] åstadkt-nttiit-x- a rnaxiövf. r signal in the corresponding control signal line. 5. A device according to claim 1, 2, 3 or 4, characterized in that price-food. consists of a transparent disc (16) on one of which, outer surface (1) the fields (17) are arranged and next to whose other, surface-emitting surface (3) light-emitting elements (21) are arranged in connection with each and one of the fields for producing said light and that the light detecting element (19) is arranged at the edge of the disc, the two said surfaces connecting. Device according to claim 5, characterized in that the control and signal processing device (20) is arranged to provide the light-emitting elements (21) with a light signal flashing at a certain frequency, which frequency differs from the frequency for light. in the environment, for example the mains frequency, and that the control and signal processing device is at the same time arranged to be activated only by signals received from the receiver element (19) with said frequency produced by the transmitter elements. Device according to claim 5 or 6, characterized in that the light-emitting transmitter elements (21) are arranged to be observable through the disc (2) in a light-emitting state and are arranged to be controlled by the control and signal processing device ( 20) in such a way that an instruction signal for the operation of the keyboard can be transmitted, for example a light signal showing the temporarily assumed operating position. Device according to one of Claims 1, 2, 3 or 4, characterized in that the prism (72) is arranged to be illuminated by at least one light beam, which by means of a device, for example a cathode ray tube (70), is moved over the surface of the prism, so that light fields (74) are built up successively, which light fields form said control field and that the selection of the light deflected from each field takes place by detection by means of the signal processing device (20) on the basis of which time period the light field (74) in question is built up by the movement of the beam. Device according to any one of claims 5, 6, 7 or 8, intended to perform the function of a so-called joy stick, characterized in that the fields (27, 28) are arranged in coordinate formation in a plurality of rows therewith a car. a surface area (27) and that the signal processing device is arranged to transmit two control signals for two control functions, each of which is assigned in accordance with the coordinates indicating the position of the signal transmitting element temporarily transmitted to the surface (26) by abutting the surface (26). an ht-stšitnd coordinate within the surface area. Device according to any one of claims 1, 2, 5, 6 or 8, characterized in that substantially every one. of the fields on the surface M (ffäèäiße-fä _ L / 9 (44) is arranged an antryck scrotum (43) with a surface (47) by means of which, when abutting against the surface of the disc, said change in the luminous flux is effected, which bodies form parts of keys (37), so that a mechanical keyboard is formed, by means of which said optoelectronic function can be exercised indirectly. Device according to claim 10, characterized in that the keyboard comprises of at least one plate (40) of an elastic material with a plurality of keys (37), each connected to an impression body (43), said surfaces (43) 47) in the unaffected state of the plate is spaced from the surface (45) of the disc (44) with the plate made of such a resilient material that by pressing against one of the keys (37) the surface (47) to its corresponding pressure body '. (43) can be moved to abut against the surface of the disc.