DE2134600B2 - Keypad - Google Patents

Description

The invention relates to a keypad, as can be seen from the preamble of claim 1.

A key mechanism of this type is disclosed in U.S. Patent 20 583 describes where a circuit card has several keys running parallel to one another and under all keys Has leading cable runs, which are short-circuited in the desired combination by pressing the buttons can be. The disadvantage here is that each key depends, in particular, on the coding selected must be designed. Furthermore, there is a need for two connection points for each line run must be provided, with the lines all routed under each key. Finally leave Do not arrange these cable runs as close to one another as you like, otherwise there is no reliable timing can be guaranteed according to the required coding with the help of the buttons, so that this Already a minimum size for the keypad must be specified in DE-OS 18 06 241 is a different type of Key mechanism described in which actuatable keys are provided, each of which has only one switching path able to connect electrically with each other. One key consists of a spring material dome, the can be actuated with an elastic snap-action by finger pressure in order to establish an electrical connection via a contact to manufacture. In addition to the relatively complex production and the space required for a Such a key mechanism is particularly disadvantageous that by pressing a single key electrical contact is made, but no further coding is carried out but no reliable key actuation is possible without further ado. In addition, there is no error detection provided and would be associated with particular effort.

The earlier German patent 20 06 176 relates to a keypad in which, by pressing a button, the required coding is connected to a common one Circuit element with all keys common coding lines only by means of relatively complex Mask selection can be brought about In contrast to the invention, where inevitably all each under line surfaces lying on a key when the elastic membrane is actuated with its conductive surface come into contact as a common circuit element.

The object of the invention is to provide a keypad which is improved in comparison, This is easy to use in terms of production effort, is operationally reliable and easy to use Error detection measures can be equipped.

This object is achieved according to the invention, as can be seen from the characterizing part of claim 1.
US Pat. No. 33 08 253 describes a keypad with an elastic membrane, but here the contact is made at the crossing points of two mutually perpendicular lines or a wire is brought into contact with the conductive surface of the membrane. However, this means that with this known arrangement each key or each index point must be determined by decoding the ΛΎ coordinates or, in the second case, by identifying each line for the index point. The disadvantage of this, however, is that an output code is required, that is to say a linking network must be provided in order to decrypt the index point for the given ΛΎ coordinate value. This requires a considerable effort, which can be significantly reduced by the invention described above.

The key mechanism according to the invention can be improved by the fact that the circuit card below each

Button each has at least three switch field segments that are isolated from one another and that correspond accordingly the selected code in the specified combination with the output connections stand.

In an advantageous manner, the circuit cards are on both sides with printed cable runs, areas and -connections which are connected to one another in a predetermined manner via line perforations.

The keys themselves are expediently designed so that an annular stop is provided at their lower ends, within which a plunger protrudes that pushes the membrane down at the appropriate point when the key is pressed, the annular stop only coming into contact with the pressure compensation position. Both the conductive surface of the membrane and the switching field segments are advantageously made of gold plating.

The keypad segment arrangement on the circuit board, which corresponds to the selected coding d-ei odei can contain more segments, one in each case allows only a small amount of space; d. H. the segments can be very close together. Furthermore, it is not necessary that each output terminal of the Circuit card is connected to all key positions, but the cables are on the circuit card only to lead according to the selected code.

For error detection, the key mechanism according to the invention is advantageously provided with a non-equivalence logic circuit provided, the inputs of which are connected to the output terminals of the circuit board; namely to display the simultaneous Pressing two buttons and that all switching field segments are recorded with a respective keystroke. In an advantageous further development it can also be provided that the circuit card connections have a Downstream code converter, the outputs of which are simultaneously the input of a parity bit generator head for.

Further advantages and features of the invention emerge from the following description of a Embodiment based on the drawings listed below and from the claims.

It shows

F i g. 1 shows a partial cross-section of a keyboard device running through a key button,

F i g. 2A shows the pattern of the switch plane and the lines on the top of a circuit board and

F i g. 2B the performance pattern on the back of a Circuit board,

F i g. 2C a switching mechanism connected to the circuit board,

3 shows the circuit of a circuit card for a ten-key keyboard using a 3-out-of-14 code,

4A shows the circuit arrangement of a circuit card for a numeric keypad using the EBCDIC code,

Fig.4C shows a circuit arrangement of the in Fig.4A used data selector / multiplexer.

The section in Fig. 1 shows an elastic membrane switch key, consisting of the key button 40, the membrane 51 and the circuit board 60.

The push button 40 at r-ch is shown in FIG. 1 on average shown. The finger surface 41 of this push button 40 is shown concave here, but can just as well be convex be curved or be flat. If the push button 40 in the present case also from the Keyboard plate 30 is shown outstanding, so can cut it off with the keyboard plate 30 as well or be sunk into it. Of the Outer diameter or the sliding surface 42 of the push button 40 is the corresponding hole 31 in the Keyboard plate 30 adapted. The hole 31 widens in a conical part 32, which in a widened

ίο cylindrical part 34 opens so that a Stop surface 33 forms the conically widening part 32 reduces the contact area between the Hole 31 and the push button 40. The stop surface 33 prevents the push button 40 from the hole 31 can get out.

The push button 40 also has an annular bead 44 at its lower end, which over an annular groove 43 for collecting dust, etc. in the cylindrical portion 42 of the button 40 transforms. The annular bead 44 of the push button 40 can only be rotated about its axis, so that a Seizing between the push button and the wall of the hole in the keyboard plate 30 is prevented of the push button 40 consists of the lower surface 45 of the annular bead 44 to prevent damage to the To prevent membrane 51 and on the other hand for the end of the connected to the push button 40 plunger 46 to obtain the required force-displacement curve.

The plunger 46 extends by the distance W below the surface 45 of the annular bead 44, so that in cooperation therewith a reliable and repeatable actuation of the membrane 51 results, regardless of the finger force acting on the push button. A compensation layer 50 is for several purposes intended. First of all, it prevents the diaphragm 51 from being damaged directly by hard actuation of the plunger 46 and that roughness on the plunger surface can have a detrimental effect. The fact that the movement of the ram into the compensating position 50 is limited by the stop surface 45 also serves to protect the membrane 51 from accidental unintentional or premature impacts on the push button 40.

The plunger 46 is decisive for determining the force-displacement characteristic. Its distance W defines the push button travel and its diameter together with the hardness and thickness of the compensation layer 50 is decisive for the effective push button force. Thus, a soft and thick compensating layer 50 has one

so relatively light, but long pushbutton stroke result and vice versa In general, softness and thickness of the balancing layer 50 must be chosen in Zusarnmerispiel with the distance W. Depending on the selection, the result is a long pressure action with a light push-button stop, or a softer or harder stop with any pressure action. Of course, the shape of the plunger 46 at its lower end, whether flat or round, plays a role as well as the properties of the membrane 51 and the separating layer 52. Finally, another function of the compensating layer 50 is to exert a force on the membrane 51 in such a way that that it is evenly distributed from the imaginary center line of the push button 40 to the edge and this during the movement by a corresponding path length of the push button.

The push button 40 with the plunger 46 and the annular bead 45 in cooperation with a relative

thick and soft compensating layer 50 allows repeated and reliable actuation. As already mentioned, a separating layer 52 is provided below the membrane 51, which has an opening U below the plunger 46, through which the membrane 51 comes into contact with the switch sections, ie with the switch elements of the matrix on the surface of the Circuit board 60 is brought. Both surfaces of this circuit board 60 have conductor tracks which are connected to one another via conductive through holes as required.

An insulating layer 53 insulates the circuit board 60 from the Base plate 54. The various layers 50, 51, 52, 60, 53 and 54 can be stacked on top of one another and passed through Hold screws or other mechanical fasteners together in a known manner.

The membrane 51 consists of, for example, a 0.013 to

(1 Wi mm Hirjfpn Rprvl | iiirn-KMnfpr-l_PCTi ^ riina ijnH is plated with gold, so that a resilient element results. The change in the copper layer thickness changes the actuation force of this switching element only to a small extent The separating layer 52 consists of approximately 0.08 mm thick Mylar, preferably because the switching element is then less sensitive to defects in the lower surface of the diaphragm 51 8 mm large hole in the separating layer 52 gives the approximately 0.08 mm thick Mylar separating layer 52 a sensitive switch, whereby the stresses in the membrane 51 are kept small.

The circuit board 60 used herein is made of a copper-clad epoxy resin board. The insulating layer 53 consists e.g. B. from about 0.1 mm thick Mylar and is of course unnecessary in the case when the Base plate 54 used consists of non-conductive material. This base plate 54 is preferably therefore used to protect the circuit board 60 as possible against wear.

In connection with the representations in FIG. 2A and 2B are now intended to be a preferred embodiment of the invention for a key-operated membrane switching device will be described. In Fig. 2A is the wiring pattern on the V-side (Fig. 1). so the upper side of the switching karle, which is contacted by the membrane depending on the key operation. In Fig. 2B, the line pattern is on the Z side, that is the lower side of the circuit board, which is opposite the base plate. For the sake of simplicity Both map levels are shown from the same viewing direction, so that the bottom side is shown in Fig.2B should actually be drawn in dashed lines according to the usual practice.

The key positions are in Fig. 2A each by a Arrangement of 4 squares shown. These are the switch elements or switch field segments. The black ones Lines are cable runs and the black dots are conductive holes, the cable runs on the in F i g. The surface shown in FIG. 2B with lines of conductors or switch field segments on the surface shown in FIG. 2A Connect surfaces conductively. The four square panels arranged in a square for each key position are in each case arranged electrically isolated from one another, ίπ each The panel segment arrangement is the upper right square the eight-bit, the lower right square the Four-bit, the upper left square the two-bit and the lower left square the one-bit position. The upper right The square of each panel segment arrangement is connected to either pin 68 or 78. That The lower right square of each panel segment arrangement is connected to either pin 64 or 74 tied together. The upper left square of each switch field segment arrangement is either on the connection pin 62 or 72, while the lower left square of each switch field segment arrangement is connected to pin 61 or 71 is performed. The pin 63 is to a small contact area 73 connected, which is in permanent contact with the conductive surface of the Membrane 51 is standing. Table 1 below shows that made through each communication hole V-I to V-57

Ii electrical line connection. In the middle column this table indicates the respective cable run or the respective cable area. Is the name **! nes Leisiun ^ sloches in dsr ürike "5 ™ 2! ί £ with emers Star, it means that a cable run in

. '»Of the area of FIG. 2A is connected to the corresponding line run in FIG. 2B. All other Line holes connect line areas in FIG. 2A to line runs in FIG. 2B. The other line holes are each with a panel segment of the respective

: ■! Button position connected. So is z. B. VX connected to the keyboard D, panel segment 2; V-2 is located in the switch field segment 1 of the button position Dusw.

_{! (l} Table 1 i> Vi Cable run Cable run in Vl or area Fig. 2B Line hole connections in Fig. 2 40 Vi in Fig. 2A Line V 4 8D2 72 6 hole VS 8Dl 716 V6 851 716 VI 851 716 45 ^ 8 8Z2 72 6 V9 8Zl 716 VlO 8 / V2 72 6 VU 8 / Vl 616 VM oö4 74 6 so ^ 13 * 8Z4 74 6 K14 SMl 72 6 V 15 8Ml 616 VW * 62 a 62 6 VYl 872 62 6 55 V 18 871 616 V 19 * 72 β 72 6 VlO 882 726 VIl 881 716 VIl 71 α 716 60 VV, 892 72 6 VU 891 616 VlS 8 Λ / 8 686 VU 888 686 VlT 898 686 65 VTZ 8 pounds 2 62 6 V19 8 pounds 1 716 K30 * 62 α 626 K31 * S42 726 841 716 62 α 626 72 a 726

continuation

Pipe hole

Cable run or area in Fig. 2A

Cable run in Fig. 2B

V 37 K38 K 39 K 40 K41 VM

852 851

71a

862

861

8f4

844

854

864

8Λ2

8Λ1

oll

811

72 a

62 a

822

821

71a

832

831

8Λ4

818

828

824

838

834

72 616 716

62 716 64 64 646 64 62 616 72 616 72 62 62 716 716 62 616 64 78 78 74 78 74

2 (1

With further reference to FIGS. 2A and 2B in j-, in connection with Table 2 below, the output code of the keyboard according to FIG. 2 will now be explained. A 16-key field is shown, the outputs of which have hexadecimal values from 0 to F. The different key names are SB, 81, 82, 83, 84, 85, 86, 87, 88, 89, SZ, 8Λ /. 8D. SM. £ 9 SR. The corresponding binary value representation, which appears at the connection pins SZ 1 to 678, is indicated in each case under the output binary value column. For example, a 0 in the figure-eight column means a signal on 4, pin 78, whereas an L in the figure-eight column means a signal on pin 68; a 0 in the column of four indicates a signal on pin 74, whereas an L in the column of four indicates a signal on pin 64; a 0 in the two column results in a signal on pin 72, whereas an L in the two column results in a signal on the pin; a 0 in the ones column indicates a positive signal on pin 71, whereas an L in the ones column allows a signal on pin 62 to appear

By pressing the key, the conductive surface of the membrane 51 is brought into contact with the switching field segment arrangement SB , so that the hexidecimal 0 is caused by the occurrence of signals at the connection pins 71, 72, 74 and 78 and the absence of signals the connection pins 61, 62, 64 and is shown. If the switching field segment arrangement 85 is brought into contact with the conductive surface of the membrane 51 in a similar manner, then the result is the hexidecimal 5, as indicated by the occurrence of signals at the connection pins 64, 61,78 and 72 is shown.

Table 2

Output code of the keyboard according to FIG. 2

Hexi-

decimal-

value

Output binary value
8 4 2

O O O O O O O L. O O L. O O O L. L. O L. O O O L. O L. O L. L. O O L. L. L. L. O O O L. O O L. L. υ L. O L. O L. L. L. L. O O L. L. O L. L. L. L. O L. L. L. L.

From the above it can be seen that the desired hex output is directly on the connector pins 61 to 78 occurs and can be taken from there. Using the circuit of FIG. 2C measures will now be described to protect against the effects of simultaneous pressure two buttons are used and the contact between the membrane and each of the switch panel segments at a key position. In this circuit arrangement, too, the connecting pins 61, 71, 62, 72, 64, 74, 68 and 78 are shown. The connection pin 61 is connected to an input of the antivalence sound system 11. The pin 71 is connected to the other input of the antivalence circuit 11 and to one input of the AND gate 16. The pin 62 is connected to an input of the non-equivalence circuit 12, during the Pin 72 is connected to the other input of this non-equivalence circuit 12 and also with one input of the AND element 17. The pin 64 is connected to an input of the non-equivalence circuit 13, while the pin 74 is connected to the other input of the antivalence circuit 13 and on an input of the AND gate 18. The pin 68 is connected to an input of the non-equivalence circuit 14 connected, while the pin 78 is at the other input of the exclusive circuit 14 and at one Input of the AND gate 19. The outputs of the antivalence circuits 11 to 14 are each with a The input of the AND gate 15 is connected, the output of which is in turn connected to the other input the AND gates 16 to 19 is connected. The AND gate 15 only emits a signal when from a signal is fed to each output of the antivalence elements 11 to 14. It only occurs and only then if one of the pin pairs: 61, 71; 62, 72; 64, 74; 68, 78 emits a signal But that means nothing else than that when a signal occurs at the output of the AND gate 15, only one and only one Keyboard key according to FIG. 2A has been printed The signals at pins 56 through 59 in FIG. 2C are then each elements of the in the right column of the binary key shown in Table 2.

In the circuit arrangement according to Figure 3 is a Circuit card arrangement for a ten key pad shown.

a 3-out-of-14 code is used, with protective measures against the effects of the simultaneous pressing of two keys and for determining which contacts are closed for a key position are also shown in detail here. The individual switch field segments A ₁ and C of the various touch points 90 to 99 are also located on a circuit board provided with lines on both sides and are connected to the various pins 2/4 0 to 2C3. For the sake of simplicity, only the touch points 90 to 99 of a ten-part keyboard part of a much larger keyboard are shown, whereas the circuit arrangement for the entire keyboard is shown. In the keypad of FIG. 3, dashed and solid connecting lines are shown. This is intended to indicate that the extended connecting lines are on one side of the circuit card and the line guides shown in dashed lines are on the other side of the circuit cards. It should be obvious that other wiring schemes for connecting the switch panel segments to the connection pins 2A 0 to 2C3 are also possible without further ado. The black dots in the keypad that are located at connection points between dashed and >> unplugged connection lines or between dotted connection lines with panel segments indicate line holes, whereas black dots between solid lines and panel segments represent connection points that are between lines and panel segments on a Map side. All connection pins 2A 0 to 2C3 are at positive potential + V. The membrane, which is only indicated schematically here, is at ground potential G.

The switching measure described below in detail to protect against simultaneous pressing of two keys consists of the inverters 431 to 444, the AND gates 451 to 464, the OR gates 465 to 467 and the AND gate 468. Each time a key is pressed resulting characters in the 3-out-of-14 code results in sicfi directly at the corresponding connection pins 2/4 0 to 2C3, whereas the occurrence of a signal at connection pin 470 indicates that only one key has been actuated and that, in addition, all switch field segments of this key position are in contact stepped with the membrane. This indicates that a valid character is appearing on pins 2A 0 through 2C3.

First of all, the display of characters when the various keys 90 to 99 are pressed should now be sent to the Terminal pins 2Λ0 to 2C3 occurs, described at the same time the protective measures resulting from the circuit arrangement according to FIG be treated.

First is to be pointed out that the A -Schaltsegment each button connected 90 to 99 with a connection pin of the connection pins 2A 0 to 2A 4 This is ß-switching segment of each key 90 to 99 is located at one of the terminal pins 2B 0 to 2ß 4. Finally, the C-panel segment of each button 90 to 99 is connected to one of the connector pins 2CO to 2C3. This means that an actuation of the key 90 causes a signal to appear at the connection pins 2B2 and 2A 4 and 2CO. Table 3 below summarizes all connections of this type between the switch panel segments A, B and C and the connection pins 2Λ 0 to 2C3.

Tabel

Switching connections between cubicle segments

button

92

93

94

96

Panel Connector pin aegment 90 A 2A4 9OB IBl 9OC 2C0 91 A 2Λ1 91 B 251 91 C 2CO 92 A 2Λ1 92 B 2S2 92 C 2CO 93 A 2A 1 93 B iai 93 C 2CO 94 A 2A2 94 B 201 94 C 2CO 95 A 2A2 9SB 2B2 95 C 2CO 96 A 2A2 96 B 2S3 96 C 2CO 97 A 2A3 97 B 2 sl 97 C 2CO 98/1 2A3 98 δ 2B2 98 C 2CO 99 A 2A3 99 B 2B3 99 C 2CO

Returning to the circuit arrangement according to FIG. 3, the protective measures will now be described in detail. For this purpose, the output pin 2A 0 is connected to the inverter 431 and one input each of the UN D elements 452 to 455.

The pin 2/4 1 is on the one hand at the inverter 432 and on the other hand at one input each of the AND gates 451, 453, 454 and 455. The pin 2A 2 is on the one hand on the inverter 453 and on the other hand each at an input of the AND gates 451, 452, 454 and 455. The pin 2A 3 is connected once to the inverter 434 and the other to one input each of the AND gates 451, 452, 453 and 455. The pin 2A 4 is connected to the inverter 435 and the other to each input of AND gates 451 to 454.

Pin 2B0 is connected to inverter 436 and to one input each of AND gates 457 to 460. Pin 2B 1 is connected to inverter 437 and to one input each of AND gates 456, 458, 458 and 460 The pin 2B 2 is connected to the inverter 438 and to one input each of the AND gates 456 , 457, 459 and 460. The pin 2B3 is connected to the inverter 349 and the other to one input each of the AND gates + 5S, 457, 458 and 460. The pin 254 is on the one hand at the inverter 440 and on the other hand at one input each of the AND gates 456 to 459.

The pin 2CO is connected once to the inverter 441

and on the other hand at one input each of the AND gates 462 to 461. The connection pin 2Cl is connected once ■ -werter 442 and on the other hand at one input of the AND gates 461, 463 and 464. Pin 2C2 is connected to inverter 443 and to each an input of the AND gates 461, 462 and 464. The pin 2C3 is once on the inverter 444 and to the others at one input each of the AND gates 461 to 463.

The inverter 431 is connected to one input of the AND gate 451, and the inverter 432 is connected to one input of the AND gate 452, the inverter 433 at an input of the AND gate 453, the inverter 434 an input de ;, AND gate 454, the inverter 435 at an input of the AND gate 455, the inverter 436 at an input of the AND gate 456, the Inverter 437 at one input of AND gate 457, inverter 438 at one input of AND gate 458, the inverter 139 at one input of the AND gate 459, the inverter 440 at one input of the AND gate 460, the inverter 441 at one input

Table 4

of the AND gate 461, the inverter 442 at an input of the AND gate 462, the inverter 443 an input of the AND gate 463 and the inverter 444 at an input of the AND gate 464. The Outputs of the AND gates 451 to 455 are through the input side of the OR gate 465, the outputs of AND gates 456 to 460 through the input side of OR gate 466 and the outputs of AND gates 461 to 464 through the input side of the

summarized in OR gate 467. The outputs of the OR gates 465 to 467 are connected to the inputs of the AND gate 468, the output of which is connected to the pin 470 is connected. As noted above, a signal on pin 470 indicates that the

F) mentioned type starts. In connection with Fig. 4A is intended to describe a keyboard with a corresponding circuit arrangement using an EBCDIC code wprrlpn. wopi ίρΗρς isrhnltfplHspcrmpnt ipu / pilc provides two bits in the output code to a key according to the table below:

button Connector pins for segment D. code B. C. D. AWAY C. A. 34 56 78 12th

20th
21
22nd
23
24
25th
26th
27
28
29

A3 A3 A3 A3 A3 A3 A3 A3 A3 A3

iB3 ICO I DO LL LL OO OO 153 ICO IDl LL LL OO OIL 153 ICO 1D3 LL LL OO LO 153 ICO 1D3 LL LL OO LL 153 ICl I DO LL LL OIL OO 153 ICl IDl LL LL OIL OIL 153 ICl 1Z> 2 LL LL OIL LO 153 ICl 1D3 LL LL OIL LL 153 1C2 I DO LL LL LO OO 153 1C2 IDl LL LL LO OIL

The above table with the code of the output characters and the connection scheme for the EBCDIC keyboard of FIG. 4A can be used in the following manner with the circuit according to FIG. 4A in context. The actuation of the button, which brings the switching field segment arrangement 20 into contact with the membrane indicated schematically at ground potential G , causes a positive signal to occur at the connecting pins 1.4 3, Iß 3, ICO, IDO. The corresponding output character is then LLLLOOOO. The line routing from the switch panel segment arrangement 20 to the connection pins mentioned is also arranged here on both sides of the switch card, as shown in FIG. 4A, where the switching segments and the line routing on one side of the circuit card are shown in solid lines, the black dots representing line holes between the said lines and switching segments to the dashed lines, which correspond to the line routing on the opposite side of the card. In this way, segment B of the switch field segment arrangement 20 is connected via a line shown in solid lines to the connection pin 153 and the segments A and D are connected to the connection pins XA 3 and IDO through the line routing on both sides, whereas segment C is connected via a unilateral line Line routing is connected to its associated pin ICO.

While the actuation of a given key results in the generation of a character in 16-bit code at the output connection pins MO to 1D3, a code conversion is carried out by the circuit arrangement connected to it, so that characters in the 8-bit output code are sent to the corresponding connection pin. 310,320,330,340,350,3 SO, 370 and 380 occur. The same code converter circuit is also used for the protective measures already described above, namely preventing the effect of pressing two buttons at the same time and establishing contact. Output code bits 1 and 2 are determined by the potential state of output pins 1/4 0, XA 1, XA 2 and XA 3. Output code bits 3 and 4 are determined by the potential state of pins IBO to 153. Bits 5 and 6 in the output code are determined by the potential state of the connection pins ICO to 1C3, while the bits 7 and 8 in the output code are determined by the conditions at the connection pins i DO to XD 3. For each connection pin set, i.e. A, B, C or D set, are the two mutually assigned bits in output code 0 when the O pin, i.e. XA 0,

iBQ, ICO or IDO, is at positive potential or receives a signal. If the L pin has potential, then the assigned output code bits are OL. If the 2-pin pin has potential, then the assigned output code bits are LO. And finally, if the 3-pin pin is potential then the associated output code bits are LL

In the manner described above, the output pins 1Λ0 through IA 3 on the circuit board control the Potential state of output pins 310 and 320, which represent bit positions 1 and 2. the Bit positions 1 and 2 result in 00 if the IA 0 pin is potential, OL if the IA 1 pin is potential, LO if the IA 2 pin is potential Has potential and LL if the IA 3-pin has Potentini

As in FIG. 3 is shown in FIG. 4A shows a ten-key part of a much larger keyboard, however, the circuit arrangement shown here is also designed for the entire keyboard

The mode of operation of the circuit arrangement will now be explained in more detail. The data selector multiplexers 211 to 214 used here are not described in detail here; it is sufficient only to establish that the outputs of a data selector multiplexer are only negative if one of the four inputs is positive. The NAND gates (oil) 271 to 278 have a positive output if either one or the other input is but not both at the same time, are positive. The NOR gate 219 gives a negative output when all inputs are positive. A monostable multivibrator 220 emits a pulse of a predetermined length when its input is driven by a positive pulse. The NOR circuits 230, 311 to 318 have a negative output when one but not both inputs are negative at the same time. The parity bit generator 329 has a positive output when an even number of its inputs are positive and a negative output when an odd number of its inputs are positive.

The circuit itself is implemented as follows. The pin IA 0 is connected to the data selector multiplexer 211. Pin IA 1 is on the data selector multiplexer 211 and connected to the NAND gate 272. Pin IA 2 is on the data selector multiplexer 211 and connected to the NAND gate 271. The pin IA 3 is on dsn data selector multiplexer 211, connected to the NAND element and to the NAND element 272. Of the Pin ITE is on the data selector multiplexer

212 connected. The pin IDl is to the Data selector multiplexer 212 and connected to the NAND gate 274. Pin 2S2 is on the data selector multiplexer 212 and connected to the NAND gate 273. The pin 1Ö3 is likewise to the data selector multiplexer 212, to the NAND element 273 and to the NAND element 274 connected. The pin ICO is connected to the data selector multiplexer 213. Of the Pin ICl is on the data selector multiplexer

213 and connected to the NAND gate 276. The pin 1C2 is connected to the data selector multiplexer 213 and to the NAND gate 275. The pin 1C3 is connected to the data selector multiplexer 213, to the NAND gate 275 and to the NAND gate 276. The IBO pin is connected to the data selector multiplexer 214. Of the Pin ID1 is to the data selector multiplexer 214 and connected to the NAND gate 278. The connection point 1D 2 is to the data selector multiplexer 214 and connected to the NAND gate 277. Of the

s Pin 1D 3 is on the data selector multiplexer 214, connected to the NAND gate 277 and to the NAND gate 278.

Furthermore, all connection pins IAO to 1D3 are on positive potential applied The output of the Datense The editor multiplexer 211 feeds via an inverter 215 an input of the NOR gate 219. The output of the data selector multiplexer 212 feeds through a Inverter 216 is a further input of the NOR element 219. The output of the data selector multiplexer 213 feeds a further input of the NOR element 219 via an inverter 217. The output of the data selector multiplexer 214 feeds a via an inverter 218 Another input of the NOR element 219. This creates a negative output of a data selector multiplexer inverted so that positive signals are fed to the inputs of the NOR gate 119 in this case. At the Output of the NOR gate 219 therefore only a positive signal occurs when one and only one of the A connector pins, one and only one of the fl connector pins, one and only one of the C-connector pins and one and only one of the D-pins is at positive potential. The output of the NOR gate 219 feeds a monostable multivibrator 220, the output signals of which are output on line 210.

This output line 210 shows a positive only then Potential if only one of the buttons 20 to 29 in Contact with the membrane at ground potential

stand.

The output of the monostable multivibrator 220

on line 210 also feeds one input each of the NOR gates 301 to 308 the other input of the NOR elements 3Ql to 308 is the The output of the NAND element 271 at the NOR element 301, the output of the NAND element 272 at the NOR Circuit 302, the output of NAND gate 273 the NOR circuit 303, the output of the NAND gate 274 at the NOR gate 304, the output of the NAND gate 275 on NOR gate 305, the output of NAND gate 276 on NOR gate 306, the The output of the NAND gate 277 at the NOR gate 307 and the output of the NAND gate 278 at the NOR gate 308. The NOR gates 301 to 308 each have a positive output if only one key, as indicated on line 210, has been actuated and when the corresponding bits in positions I through 8 on pins IAO through 1D3 have been decoded by NAND gates 271 through 278. the respective outputs of the NOR circuits 301 to 308 are used in latching circuits of bistable design, which consist of two NOR gates in cross coupling, stored until these latch circuits can be cleared via line 300 by a corresponding reset signal. In the same way becomes a Signal of the monostable multivibrator 220 in the off the two NOR members 230 and 200 formed Latch circuit stored so that a corresponding signal appears on pin 390 to to indicate that the character appearing on pins 310 to 380 as a can be correctly assumed.

The output of the monostable multivibrator 220 is connected via line 209 to an input of the NOR gate 230, which controls the NOR gate 260,

which in turn is fed back to the NOR element 230. The output of the NOR element 260 is located also the pin 390. The output of the NOR gate 301 is at the input of the NOR gate 311, which in turn is connected to the NOR gate 321 and whose output is once at pin 310 and on the other hand is fed back to the NOR element 311. The output of the NOR element 302 applies to the input of the NOR element 312, which controls the NOR element 322, the output of which is connected to pin 320 of bit position 2 and the other is fed back to the NOR element 312. The output of the NOR element 303 is at the input of the NOR element 313, which in turn controls the NOR element 323 the output of which is at pin 330 of bit position 3 and, on the other hand, to NOR gate 313 is fed back The output of the NOR element 304 is at the input of the NOR element 314, which in turn the NOR element 324 controls the output of which is at pin 340 of bit position 4 and, on the other hand, is fed back to the NOR element 314 The output of the NOR element 305 is at the input of the NOR element 315, which in turn is the NOR element 325 controls the output of which is on pin 350 of bit position 5 and, on the other hand, to the NOR gate 315 is fed back The output of the NOR gate 306 is at the input of the NOR gate 316, the in turn the NOR-Güed 326 controls the output of which is at pin 360 of bit position 6 and on the other hand is fed back to the NOR gate 316. The output of the NOR gate 307 is at the input of the NOR gate 317, which in turn controls the NOR gate 327 whose output at pin 370 of the Bit position 7 is and on the other hand is fed back to the NOR element 217. The output of the NOR gate 308 is at the input of the NOR gate 318, which in turn controls the NOR gate 328, whose The output is at pin 380 and, on the other hand, is fed back to NOR gate 318. The exits the NOR gates 321 to 328 are also at the input of the parity bit generator 329, its output is on pin 331. The reset signal applied to pin 300 is at the reset input the NOR element 260 and the NOR elements 321 to 328.

With the above-described and illustrated in Figure 4A circuit, the at pins 1 A 0 converted to 1 D 3 corresponding to the operated keys 20 and 29 occurring signals in an 8-bit code, which is then connected to the terminal pins 310-380 for the characters appearing there are authoritative. Furthermore, an indication signal is emitted on line 210 when keys are pressed twice, and a scanning indication signal is emitted on line 390.

The description of a data selector multiplexer is made only for the data selector multiplexer 211, since all other data selector multiplexers are of the same type. On the output line 261 of the data selector-multiplexer 211 passes a signal only when one of the terminal pins M 0 is at ground potential by pressing the appropriate button to ΙΛ3 These switches are, as described above, through the switching field segments A of the various panel segment assemblies 20 to 29 formed. Within the data selector multiplexer 211, as in FIG. 4C, the pin MO on inverter 221, pin \ A 1 on inverter 222, pin \ A 2 on inverter 223 and pin \ A 3 on inverter 224. Pins E, EO are also used to supply operating potentials to E15 are provided, of which the connecting pins ET, EW, £ 13 and £ "14 are at positive potential via a resistor A1, whereas the other connecting pins E, EO to E6, £ 8 to ElO, £ 12 and £ 15 are at ground potential .

ίο The potential occurring at pin E is inverted via inverter 229 and fed to one input each of AND elements 231 to 246. This potential serves as a control potential for said AND elements. However, this earth potential is via pin

is EO fed to an input of the AND gate 231, so that this AND element remains ineffective. In a similar way and for the same Zv ^ -sck this becomes Erdpotentiai also the connection point El and thus an input of the AND gate 232 dem Terminal pin E2 and thus the AND element 233, the connection pin £ 3 and thus the AND element 234, the Pin £ 4 and thus the AND gate 235, the pin E5 and thus the AND gate 236, the Terminal pin £ 6 and thus the AND gate 237, the Terminal pin £ 8 and thus the AND gate 239, the Pin £ 9 and thus the AND gate 240, the pin £ 10 and thus the AND gate 241, the Terminal pin £ 12 and thus the AND gate 243 and the terminal pin £ 15 and thus the AND gate 246

jo supplied On the other hand, the positive potential is the pin £ 7 and thus the AND gate 238, the Pin £ 11 and thus the AND gate 242, the pin £ 13 and thus the AND gate 244 and the connection pin £ 14 and thus the AND element 245

J5 each supplied as a control potential.

The output of the inverter 221 feeds one input of the AND gates 231, 233, via line 252. 235, 237, 239, 241, 246 and 245. In addition, the output of the inverter 221 is at the input of another Inverter 225, the output line 253 of which feeds AND gates 232,234,236,238,240,242,244 and 246.

The output of the inverter 222 is connected via line 254 to an input of the AND gates 231, 232, 235, 236, 239, 240, 243 and 244. Also, the Output of inverter 222 also via an inverter 226 and via line 255 to an input of the AND gates 233, 234, 237, 238, 241, 242, 245 and 246 connected.

The output of inverter 223 is on line 256

V) each at an input of the AND gates 231 to 234 and 239 to 242. The output of the inverter 223 is also via an inverter 227 and via line 257 to an input of the AND gates 235 to 238 and 243 to 246. The Output of inverter 224 is via line 258 at one input of the AND gates 231 to 238. In addition, the output is of the inverter 224 via inverter 228 and line 259 to one input of the AND gates 239 to 246 connected. The outputs of the AND gates 231 to

ω 246 are determined by the downstream OR gate 250 summarized, the output of which is at pin 261. With the circuit arrangement described above it is ensured that an output signal on pin 261 can only occur when a and only one input to inverters 221-224 is positive.

For this purpose 4 sheets of drawings

αηακια / HR

Claims (5)

Patent claims: 1. Keypad with a circuit board carrying cable runs, the output connections of which are connected to the cable runs in such a way that a different combination of output connections can be excited and / or produced by actuating the keys which can be reset by spring force, in that one which extends below the key field under all keys, elastic membrane when a key is pressed puts the corresponding output connection combination on a potential applied to the electrically conductive membrane surface, characterized in that the circuit board (60) below each key (40) has three or four output connections (61,62,64,68 , 71,72,74,78) connected and when a key is pressed with the conductive surface of the membrane (51) contacting switching field segments (z. B. 8Dl, SD2, 8Z> 3, 8D4) , each of which has a bit position one through the respective key (40) corresponds to the binary number to be displayed 2. Key mechanism according to claim 1, characterized in that the circuit card (60) is provided on both sides with printed cable runs, -Ages and connections, which in a predetermined manner through the circuit card (60) through line perforations (Vj, V ₇ , .. . V57) are connected to each other. 3. key mechanism according to claim 1 or 2, characterized in that d; 2 button (40) at their lower Ends each have an annular stop (44) within which a Si. ' 3el (46) protrudes, which presses the membrane (51) down when the key is pressed, in that the annular stop (44) only comes into contact with a pressure compensation layer (50). 4. Key mechanism according to one of claims 1 to 3, characterized in that one for protection against Effects of pressing two buttons (40) at the same time on the non-equivalence logic switch (Fig. 2C: 11 to 14, 15) is provided, whose inputs are connected to the output connections (61, 62, 64, 68, 71, 72, 74, 78). 5. Key mechanism according to one of claims 1 and 4, characterized in that the output connections (61, 62, 64, 68, 71, 72, 74, 78) a code converter (Fig. 3, 4A) is connected downstream, the outputs of which control the input of a parity bit generator (329) at the same time.