EP0507774A1 - Configurable entry device for data processing systems - Google Patents

Abstract

A pre-configurable input device for data processing systems, such as computers, includes two keyboards, one or more printed circuit boards, and electronic circuits with corresponding electrical switching elements. The input device comprises electronic preselection devices capable of being controlled by means of mechanical switches arranged on the printed circuit boards. These preselection devices allow the keyboard to be optimally adapted to different fields of application and facilitate the rhythmic blind use of the keyboard with ten fingers during a working session. The input apparatus includes a left part and a right part. Both parts contain keys, mechanical switches and electronic circuits; they are mechanically separated from each other and therefore can be moved at will relative to each other. The keys can be coupled for coding purposes, thereby generating coding signals. First and second switch keys are coupled to switch devices. The switching devices are directly coupled to coding units by means of control lines or are coupled to one or more preselection devices which allow control of a plurality of additional coding units.

Description

 Configurable input device for a data processing system

INTRODUCTION

It has long been used in various ways to enable the human hand to control electrical or mechanical systems by operating suitable input devices. Such an input device is the classic mechanical typewriter. Since the introduction of electronic data processing systems and robot controls, mechanical typewriters have been largely replaced or replaced by electronic input devices for personal computers, larger computing systems, control systems for automatic machine tools, control systems for automatic assembly systems and robots and the like added.

Among the input devices mentioned, those that are characterized by rapid, full-blown, blind, rhythmic operation of a limited number of keys are particularly distinguished allow all 10 fingers of both hands, as the classic mechanical typewriter has made possible. Unfortunately, this advantage of the classic, mechanical typewriter has been negated by the introduction of the input keyboards for personal computers. In the published documents DE 3629417 and Eu 0 257 490 an electronic input keyboard was presented, with which text and other data can be entered into the usual data processing systems without having to use the usual auxiliary keyboards for control functions and numbers. Due to the preferred position of a second shift key 41 under the basic position of the fifth finger of the right hand, the keyboard can easily be switched to one or two working states using the usual first shift key, in which cursor functions and other programmable computer functions and many other key functions within the Main keyboard can be operated easily accessible. This has the advantage of operating the keyboard mentioned above without the annoying arm movements quickly and completely blindly and rhythmically with ten fingers. An elegant, electronic switching arrangement was presented in the opening instruction Eu 0 361 533, which is characterized by an extraordinarily high degree of compactness and an extraordinarily low susceptibility to malfunction, and which can support the above-mentioned keyboard. In particular, with this switching arrangement, code signals can be forwarded to a computer, which can be interpreted by the computer, for example with a table for 8-bit code signals similar to the known 7-bit ASCII code.

On the other hand, the keyboard mentioned is limited to four operating states. In addition, only 256 different signals can be transmitted with an 8-bit code and an additional bit for parity control.

Keyboards for transmitting signals of all kinds can be used in many different ways. It is an object of the present invention to present an input device which can be used in an extended range of applications without the fast, perfect, blind, rhythmic operation of the keyboard being significantly disturbed with ten fingers. The solution to the task presented here is based on the fact that working on display devices and other locations for keyboards can be concentrated in individual work sessions. Keyboards can be used for very different purposes, for example to write business letters, enter computer programs in different programming languages, create computer graphics works of art, write poems, bilingual texts or, scientific texts (language science, mathematics, physics, chemistry ect. ) to write, to operate robot control systems, machine tools to control entire industrial plants and the like. There are few people who do all of these activities in their lives and it will never happen that they want to do all of these activities at the same time. It is therefore a good idea to combine several similar work tasks on input devices and do them in a single work session. A working day of a business scientist on a screen device could therefore begin with a work session in which he types in several business letters, followed by a work session in which he enters a computer program for controlling a scientific instrument and can see it end with a working session in which he works on a scientific text for his clientele.

Depending on the type of work session, the assignment of key functions can be optimized differently. For example, the digits usually play a subordinate role when editing a linguistic text, while they become much more important in programming replacements or when writing certain business letters. It should therefore be aimed at in the 2 additional new operating states of the keyboard made accessible by the second shift key 41 again and again to make new, cheap groupings of key functions, partly in repetitions of certain functions in a geometrically advantageous position, differently accessible again and again to be able to optimally support certain types of work tasks on the screen.

On the other hand, many people have been trained in blind operation of the classic typewriter keyboard. This training requires a long training and a hard drill. It is therefore important to ensure that, in the working state of the input device, the classic key assignments are possible, as is the case with the Typing machines are given, as few changes as possible have to be made in order not to neglect the aforementioned training of the large number of people. On the other hand, additional training for additional yet new configurations of the keyboard is possible and sensible if the types of work sessions that are supported as a result will be required by an individual for a long time in the future.

The input device should be portable and can be connected anywhere in order to enable it to be used in various work sessions that are spatially far apart (example: repair service from a computer specialist). Input devices should be personal property in order to enable an optimal configuration for each individual. The input device can only be transported and meaningfully connected to different devices if the signal code is unique and self-identifying, so that the conventional consideration of the spatial design of the key assignments when interpreting the code signals by the computer can be completely dispensed with. An 8-bit bus (plus 1 bit parity control) is therefore not sufficient here and an expansion to a larger bus width is necessary. DESCRIPTION OF THE INVENTION

The object of this invention is to provide an input device for a data processing system in which the keyboard can be preconfigured in a simple manner by the user before starting work, in order to operate the keyboard undisturbed, quickly, completely, blindly, rhythmically at ten Enable fingers during a work session in an optimized way; this is to be done by preselecting the assignment of key functions for each individual key that are contained in the two key fields, by making the individual keys connectable to several different groups of coding units. A simply designed work station which is suitable for accomplishing the task of this invention can comprise a personal computer with screen, central unit, two keypads and, for example, a wall-mounted switch board, as shown in FIGS. 15 and 16. With the levers of the switchboard, control signals can be generated by the users of the workstation, which cause the keyboard to be preconditioned. In contrast, in a preferred embodiment of the invention, much smaller ones Switchboards are added to the left and right keypads and can be installed in a common housing with the keypads. Such a structure is shown in supervision for the left hand in Figure 1 and for the right hand in Figure 2.

The following linguistic definitions are hereby displayed for all parts of this document:

The device shown in top view in FIG. 1 is referred to below as the left sub-device; the device shown in top view in FIG. 2 is referred to below as the right sub-device. Together, the left and right sub-devices form the input device, according to claim 1. Should the left and right keypads be mentioned together below, they are referred to as the keyboard, which represents part of the input device. The terms signal lines and signal lines are used synonymously and mean metallized lines or lines on an electronic circuit board (electronic card) which can carry electronic circuits and circuits and not only on at least one front and one rear side but also in intermediate layers ( Sandwich) can carry metallized lines or lines, so when crossing bundles of several Signal lines can be dispensed with if possible. However, individual bridges are possible, as at the position indicated by B1 in FIG. 17, where two 9-bit buses cross.

Si gna l lines (630-632) in Fig. 17 connect the two sub-devices, so that a signal from one of the switch boards can change a configuration in both sub-devices at the same time; in another version of the inventions, the signal lines (630-632) are separated, however, so that the configuration can be carried out separately in each subunit. In Fig. 15, the input device is powered by the central processing unit of the computer (46008). In contrast, in a preferred embodiment of the invention, the input device will have its own network connection. Furthermore, Fig. 16 shows for execution forms of the invention, in which many electronic circuit boards are used, an additional box (46016) of the input device, which can accommodate these circuit boards. To support these boards, the additional box has its own connection cable (46023) to a socket (46017) of the public network. The additional box contains the conventional means for voltage conversion, which provide at least + 5V-, + 12V, + 24V for the power supply of the boards also to the sub-devices should. A power supply for the input device that is independent of the computer to be connected also has the significant advantage that the input device can be transported to various computer systems, even if its electronic components require unusual power supplies. The partial keyboard of FIG. 1 shows a control key (410), the function of which is either that of a repeat key or that of a second shift key in addition to key 41. The electronic circuits for supporting the control key and the other keys on the keyboard are shown in FIGS. 11 and 12 See, which also show that both sub-units contain a first (83) and second (84) switching device, which are identical to the first and second switching device of Fig. 5, wherein the electronic switching device for switching device (83) in Fig. 7 and the switching device switching circuit (84) is shown in FIG. 8. The following can be seen in FIGS. 11 and 12:

1.) Power supply: cables (20120, 20124) to ground; Cables (20123, 20127) to + 5V; Lines (20121, 20125); to a conventional electronic clock for generating a square wave adjustable frequency; Cables (20122, 20126) to + 12V or + 24V to support special units such as Schmitt triggers, monostables Mu lt ii brators and the like for generating a special + 5V pulse of higher power, with the advantage that such special units and connected widened signal lines for key actuation signals need only be assigned to individual keys. 2.) Schmitt trigger monostable le Mu lt i vi bratoren or similar pulse-forming units of lower or increased output are lei stung in means (2000) whose Schaltbi ld in an Au ^{'sführungsform} for low power in Figure 13 is shown. (2086) is a derivative.

3.) Conventional one-step or two-step buttons can be used in the present keyboard. Peculiarities of the shape of the button head are irrelevant for a blind user. However, if the quality of the conventional keys is different, it is important to ensure that the key mechanism does not affect the speed of the finger movement. In particular, the feedback device for the key head, which usually comprises one or more mechanical springs or spring systems, can withstand the repetition speed of a master's fingers. Each two-stage button is connected to a double switch; the button is depressed in a first step to a first mechanical resistance level, so a first electrical contact is closed in the double switch; if the button is pressed even further down to a second mechanical resistance level, a second electrical contact in the double switch is closed and the first contact is opened. The electronic circuit diagram for double switches (2001) of FIGS. 11 and 12 is shown in FIG. 14; (20109, 20110) are bleeder resistors, which have similar tasks as (2086) in Fig. 13. Two level keys have the advantage over single level keys that they make a repeat key superfluous. Therefore, each double Ischa tter must also be connected to a signal line that can deliver a periodic square wave signal. Simple switches (2002, 2003) are shown for individual buttons; The switch (2002) does not need to be coupled to a device (2000); The switch (2003) must be coupled to a device (2000).

4.) The double switch (2001) and the device (2000) for the control button (410) from FIG. 1 are connected in FIG. 11 to the two preselection switches (2008, 2009) in order to perform the control button for a function other than the function to be able to feed a Wi ederho Ltaste; FIG. 11 shows that the control key can take over the function of a second shift key, so that together with the key (41) a second shift key can be operated from both sub keyboards. The output signal lines of the switch device (84) from both keypads can be coupled so that both second switch buttons are effective in both sub-devices (the first switch buttons must be effective in both sub-devices); however, the effectiveness of the two second switch buttons can be separate for both sub-devices; for this case, separate signal lines (94100, 94101) are shown in FIGS. 21A, 21B for the right-hand subunit.

5.) The connections (22102-22105) can be connected to the connections (21102-21105) on the back of an electronic card; also (22167-22169, 22410) with (21167-2169, 21410).

6.) From each device (2000) for each key, a single signal line leads to a connection. In the left subunit, the connections (2101-2111) are individually assigned to the corresponding buttons (1-11); the following assignments also apply: (2113-2117) to (13-17), (2119-2124) to (13-17); in the right keypad (2125-2140) to (25-40), (2142-2148) to (42-48), (2150) to (50), (21411-21 12) to (411-412). All connections together or groups of connections can be connected to a single connector or several plug connections can be combined so that bundles of signal lines for key actuation signals in cables combined in a partial device can be routed from a first electronic card, which carries the parts described for FIGS. 11 and 12, to a second electronic card. In both sub-devices, the signal lines are combined on the second electronic card and on a number of further electronic cards, which are connected one behind the other by means of cables and plugs, to form a bus. In FIG. 5, this bus is common to both keypads, shown in simplified form as four lines which emanate from four key switches (60-63). 17-20, the bus is also shown in simplified form by means of four lines. FIGS. 21A, 21B show the left version of this bus for key actuation signals, and FIGS. 22A, 22B show the right version of this bus in its full width, with the line numbers (901-911, 913-917 , 919-924) of the left bus are assigned to the key numbers (1-11, 13-17, 19-24), while for the right part the line numbers (925-940, 942-948, 950, 9411, 9412) of the right one Busses are assigned to the key numbers (25-40, 42-48, 50, 411, 412). The simplest version of the present invention is shown in FIG. 17. Fig. 17 shows a simplified Circuit which is present exactly once in each sub-t, whereby only one configuration device (4570) is present in each sub-device, the electronic circuit diagram of which is shown in FIG. 28. The configuration device comprises at least three bistable pins or flip-flops (615-617) (one pin for each configuration of the keyboard), diodes (633-638), and AND gates (618-621, 6181, 6201, 6211) . The symbolic connections (6110-6113, 6171) indicate that the configuration unit can be expanded if more pins, diodes and AND gates are added. The connections (630-632) from both subunits are connected via a cable, so that the entire keyboard can be configured together from just one switchboard (4601) in one subunit, or from two switchboards that are distributed across both subunits . The separation of the cable connections (630-632) enables the two sub-units to be configured separately, whereby the alphabet must be repeated. The electronic circuit for the coding units (70-73) is shown in FIG. 9. There are two bus control units (4710) which are controlled by the control button (410) with switch (452) when it is shaded as a repeat button. The units (4710) comprise conventional means for Independent storage of 9-bit signals and for re-reading the stored signal as long as button (410) is depressed. The presence of two data busses (74-82) and (74A-82A) has certain advantages for the connected computer in that a partial IDecoding of the code signals is made possible by the division of the bus in advance. Essentially, code signals for an alphabet and the digits 0-9 appear on bus 74-82, while on the second bus more heterogeneous code signals, for example for computer controls and rare characters, also appear a repetition of the digits 0-9 if this is the working session favored by an individual. On the other hand, the bus control units (4710) can additionally have conventional 9-bit gates, which can receive an ^' open signal ^' through a selector switch (not shown) in the bus control unit, so that both buses can be connected to one another. Furthermore, both bus control units (4710) can still have conventional means for sequencing the 9-bit code signals. In this case, a second source of a periodic square wave signal is required, the frequency of which must be at least 10 times higher than that which is provided by the repeater device by means of switches (452). is used (additional signal line to the bus control unit (4710), the supply lines from the Power supply in Fig. 17 are not drawn. Figure 18 shows an electronic circuit for an expanded version of this invention. While in FIG. 17 the key combinations are always changed over to coding units in every reconfiguration process for all operating states of the second switching device (84), it is also possible according to FIG. 18 to ensure that only individual parts of the keyboard have a certain reconfiguration echani smus are subordinate. In FIG. 18, three switch boards (4601), (4602) and (4603) are therefore shown as subunits, from which the user can reconfigure individual parts of the keyboard. These switch boards are each coupled to a configuration device (457). The circuit for the configurator shown in Fig. 26.

Only a part of all coding units can be made optionally connectable to the keys from each switchboard. Such a part, which can be made couplable from a single dashboard, is referred to below as the group of coding units belonging to the dashboard. The number of coding units that can be coupled in an operating state of the configuration devices depends on the internal structure of the configuration devices; Devices (4570) can each make 4 coding units couplable at the same time, while devices (457) can only make two coding units coupled together. Those coding units that are made couplable at a certain moment in accordance with the set operating state of the configuration devices are referred to as the configured set of coding units. Only one of the coding units of the configured set is kept open for signals on the bus for key actuation signals by the second switching device (84), depending on the operating state of the second switching device, depending on which switching buttons (12 ), (18), (410), (41), (49) if the configured set comprises 4 units. However, if the configured set only comprises two units, then a coding unit of the set is only kept open in two operating states of the second switching device.

The control board (4602) in FIG. 18 includes a group of coding units which can predominantly generate code signals for various alphabets (Latin, Cyrillic, Arabic, etc.). The configured sentence of the group contains two units and is able to generate code signals for a complete alphabet, whereby one unit for the large and the other unit for the small letters generates the code signals (in alphabets with large and small letters). (Switchboard (4602) configures a group of coding units that correspond to the keys (1-11), (13-17), (19-24), (25-29), (31-35), (37-40) , (43-47) and (50) can be coupled (according to sub-claim 4.) To the control board (4603) in FIG. 18 is a group of coding units, which can predominantly generate code signals for national letters of different languages, the configured sentence contains two units, the whole alphabet is not supported here, since only the keys (30), (36), (42), (48), (411), (412) can be coupled to the coding units of the group 29-32 are these Keys marked with "LA" (for language = language) (according to subclaim 5.)

The control board (4601) in FIG. 18 includes a group of coding units which can predominantly generate code signals from a specific set of session-specific characters. The configured set of coding units comprises two units. Only the keys (1-6), (7-7), (13-15), (19-21), (24), (25-30), (33-36), (39-40), ( 42-48), (50), (411.412) can be coupled to the coding units of the group. In the figures (29-32) these keys are marked with "SE" (for session = session). (According to sub-claim 3.)

The combination of an entire first alphabet with a few letters of a related second alphabet, and the possibility of reconfiguring the combinations as shown here, offers the user of a keyboard tremendous advantages over a conventional keyboard, since he can assume a complete alphabet , for whom he learned blind writing in his country and in his language with his national keyboard, and then supplemented his knowledge of blind typing for a few letters of a foreign language that are different from the usual ones. Of course, this combination works only for related alphabets such as English and German with the umlauts according to Fig. 29 and 30, but not for a combination of English and Russian. The performance of the system is shown using the example of a working session for writing international business letters in Russian (see FIGS. 31, 32). The size of the Russian alphabet is so large that the third and fourth levels of meaning for the keys are used to represent the Ukrainian special characters (second languages). It can be seen that a combination of session-specific characters and national alphabets can be meaningfully designed.

DESCRIPTION OF THE DRAWINGS

A preferred embodiment of the input device is shown in FIGS. 1 and 2, with FIG. 1 representing a left and FIG. 2 a right sub-device.

Fig. 1 shows a plan view of the left sub-device, in which there are three small switch boards (46101), (46102), and (46103) next to a left keypad with 25 keys (1-24), (411), which indicator light (46108) and label holder (46109) included for each of six mechanical switch devices. A frame (52001), a cover plate (52002) and a cable 53 can also be seen.

Fig. 2 shows a top view of the right sub-device, in which there are next to a right keypad with 28 keys 25-50), (411-412) three small switch boards (46104), (46105), and (46106) with indicator lights and Signage holders for each of six switching devices are located. Furthermore, a frame (52000), a cover plate (52003), a cable (54) and a control lamp (51) for the second shift key can be seen. All conventional means are suitable as mechanical switching devices in FIGS. 1 and 2, in particular and preferably small buttons such as (46107) in FIG. 1 similar to those of pocket calculators, small levers (46111) in FIG. 2, switches, latches, levers, buttons and the like, since these Umscha Ltvorri chtungen not have to be suitable for blind and rhythmic operation, but are used as a pre-configuration for the keyboard.

3 and 4 show a left and right keypad, respectively, in which the keys are arranged in a geometrically displaced manner compared to the keypads of FIGS. 1 and 2.

5 contains an electronic circuit diagram with a first (83) and a second (84) switching device for the first and second switching keys, with four coding units (70-73), a data bus (74-82) and symbols of key switches (60- 66).

FIG. 6 contains an electronic circuit diagram for a key switch (60-66) in FIG. 5, which includes Schmitt trigger means (87) and a bleeder resistor (86). FIG. 7 shows an electronic circuit diagram for the first switching device (83) in FIG. 5.

FIG. 8 shows an electronic circuit diagram for the second switching device (84) in FIG. 5

Fig. 9 shows an electronic circuit diagram for an encoding unit (70-73) in Fig. 5 including an AND gate and an encoder for each key of the keyboard. Each encoder has 9 diodes and 9 pairs of contacts.

Fig. 10A shows a view of the right side wall (52004) of the left device; Fig. 10B shows a view of the left side wall (52005) of the right subdevice; Furthermore, the screw holes (55-58) for screwing together the two Tei lgeräte can be seen, as well as the frames (52006) and (52007), which can serve as Kabe Idurch Lass when screwing the sub-units together.

10C and 10D show top views of the upper edges of the outer and inner walls (52008) and (52009) of the left and right sub-units, respectively; there are several bushings and frames (not shown) in the inner and rear walls; in the side rooms (52010) and (52013) in addition to the Switchboards auxiliary devices such as power supplies, a conventional clock, a data bus control unit and the like are located; in the main rooms (52011) and (52012) there are a number of electronic cards which are connected with plugs and cables and which are preferably screwed together and stacked using spacer rings or individually screwed to the side and inner walls; the frames and cover plates (52000- 52003) are screwed onto the upper edges of the outer and inner walls. Furthermore, conventional metal grids or other metal or plastic supports can be screwed onto the walls as supports for the buttons.

FIGS. 11 and 12 show electronic circuits in which the key actuation signals are generated for each key of the left or right key field.

Figures 13 and 14 show details of units 2000 and 2001 of Figures 11 and 12, respectively.

Figures 15 and 16 show workplaces for the use of the input device presented here. FIG. 17 shows an electronic circuit diagram comprising a control board (4601), a configuration device (4570), two 9-bit buses and two bus control units (4710).

FIG. 18 shows an electronic circuit diagram containing configuration devices (457) and switching boards (4601-4603) for pre-configuration of the keyboard with regard to the required session-specific characters according to claim 3, for pre-configuration of the keyboard with respect to a complete alphabet, according to claim 4, or for pre-configuration of the Keyboard with respect to a couplable subset of a second alphabet according to claim 5.

Figures 19 and 20 describe claim 6.

Figures 21A, 21B, 22A and 22B describe in greater detail the details from Figures 17-20.

FIG. 23 shows the electronic circuit diagram of the coding units 702 in FIGS. 18 and 21A and 22A. FIG. 24 shows the electronic circuit diagram of the coding units 704 in FIG. 21A.

Figure 25 shows encoder controls 4580 in Figures 19, 20 and 22A.

Figures 26, 27, 28 are configuration devices (457), (4573), and (4570).

Figures 29-32 represent an example of a switchable pre-configuration of key assignments.

Claims

PATENT CLAIMS

1. An input device for the blind and rhythmic operation by the ten fingers of the two human hands to control a data processing system consisting of a left and a right sub-device consisting of;

- A keypad containing a number of one- or two-stage keys with functions of letter keys of different alphabets, number keys, symbol keys, graphic keys, space keys, computer control keys, programmable function keys, robot control keys, carriage return keys, repeat keys, and the like, as well as first shift keys (12) , (18), (49) and a second shift key (41);

- An electrical switchgear containing connections to an attached electronic power supply with network connection Luss, which measures a conventional electronic clock to generate a periodic square wave adjustable frequency; electronic switching elements and gates; Contact devices and Schmitt triggers for signal enhancement associated with each key; a number of coding units, each containing at least 6 coders, a first and a second Switch device that can be controlled by the first and second switch buttons; a bus for 26 Signa L lines, the key actuations i gunssigna Le forward to the coding units; an 18-bit bus or two separate 9-bit buses for forwarding code signals to a data processing system; a bus control line which contains conventional 9-bit or 18-bit storage medium L for storing the last generated code signal and conventional means for sequenced input of the last generated code signal to a data processing system;

- Several switchboards, each with at least six conventional len, mechanical switching devices and the electrical contact devices which can be actuated by them and coupled signal lines, as well as lamps and damage;

the input device mentioned is characterized in that the second switching devices of both sub-devices are each coupled to a first, a second and a third configuration device, each configuration device additionally having the mechanical switching devices of a control panel which allow it at least three different operating states of the assigned configuration device, optionally to be inserted, as well as with the corresponding configuration device in the other part device, as well as with a number of assigned coding units and coding control devices in their own part device, which can optionally generate code signals as well as simple control signals, wherein the coding units and coding control units which can be controlled by one of the three configuration devices are connected to all or only to a part of the signal lines belonging to the 26-line bus for the key actuation signals, and that the actuation of one of the mechanical switching devices of a control panel to select a work session, the assigned configuration device is set to an operating state in which the configuration device selectively selects a selection of coding units and coding control devices from the total amount of the assigned n makes coding units and coding control units accessible to the controller by means of the first and second switching keys via the first and second switching devices, so that those coding units and coding control units can be activated by the keyboard which are in one working session total needed.

2. Input device as in claim 1, characterized in that in each sub-device only a single configuration device (4570) is arranged behind the second switching device such that all four output signals of the second switching device are passed on to this configuration device and that the configuration device has control lines to all coding units of one subunit and to the configuration device of the other subunit, so that these lines with the signal lines for the actuation signals of the keys (1-11), (13-17), and (19-24) in the left Tei lgerat, and (25-40), (42-48), (50), and (411, 412) in the right Tei lgerät can be optionally coupled by one of the two coding devices of the device.

3. Input device as in claim 1, characterized in that a second configuration device (457) is arranged behind the second switching device such that only a third and fourth of a total of four output signals of the second switching device are sent to the configuration device Tet, and that in each operating state of the configuration device from two units each from a group assigned to the configuration device Coding units and coding control units a unit with the Signa L lines for the actuation signals of the keys (1-6), (7-9), (13-15), and (19-21), and (24) in the left part, and (25-30), (33-36), (39-40), (42-48), (50), and (411, 412) in the right part of the device can optionally be coupled to a coupling state by the first shift key, so that In the two key fields in both coupling states together, code signals can be generated from a specific set of session-specific code signals.

4. Input device as in claim 1, characterized in that the second configuration device (457) is arranged behind the second switching device such that only a first and a second of a total of four output signals of the second switching device are forwarded to the configuration device, and that in every operating state the configuration device, each consisting of two units from a group of coding units and coding control devices assigned to the second configuration device, has a unit with the signal lines for the actuation signals of the keys (1-11), (13-17), and (19-24) on the left Subunit, and (25-29), (31-35), (37-40), (43-47), and (50) in the right-hand subunit can optionally be coupled to a coupling by the first shift key to a coupling, so that in the two key fields in both coupling states together, code signals can be generated from a set for a complete alphabet as well as digits and other characters of the top row of keys.

5. Input device as in claim 1, characterized in that a third configuration device (457) is arranged in the right-hand subunit behind the second switching device such that only the first and second of a total of four output signals of the second switching device are forwarded to the configuration device, and that in each operating state of the configuration device, each consisting of two units from a group of coding units and coding control devices assigned to the third configuration device, one unit with the signal lines for the actuation signals Le of the keys (30), (36), (42), (48) , and (411-412) in the right-hand subunit can optionally be coupled to a coupling state by actuating one of the first shift keys, so that code signals from a language-specific subset are combined in the right keypad in both coupling states of an alphabet or for any other code signals can be generated.

6. Input device as in claim 1, characterized in that the second switching devices of both sub-devices are coupled to at least one first configuration device (457), the configuration device being arranged behind the second switching devices such that only the third and fourth of the total four output signals Len of the second switching device is forwarded to the configuration device, and that the configuration device is coupled to at least two additional configuration devices (4573), which in turn are coupled to a number of assigned coding units and a coding control device (4580), which is associated with the two associated ones

Additional configuration devices by Konfi guri er lines (4582-4585) and a reset line (4581) is connected, and which can optionally deliver code signals to a bus as well as simple control signals to the configuration lines, the choice being made by setting mechanical switching devices of a control panel (45734) takes place, so that almost all keys of both key fields can take on the function of additional shift keys if they are coupled via the up to 26 signal lines on the bus bus of a partial device for the key actuation signals to coding control devices (4580).

7. Input device as in claims 1 and 2, characterized in that a number of Codiersteuer¬ devices (4580) can be coupled with a reset line (45733), which has a connection (4579) and a cable to all

Configuration devices of the entire keyboard can be connected, so that almost all keys of both key fields can take over the function of a general reset key if their associated signal line in the 26 signal lines bus of a sub-device for key actuation signals can be coupled to the reset line (45733) via the coding control device .

8. Input device according to claim 1, characterized in that the left keypad has a control key (410) which can either have the function of a repeat key or a second shift key in addition to the second shift key (41) by opening and closing two switches (2008) and (2009) the function of the button is set.