DE2652407A1 - Data processor keyboard input encoder - accommodates complex messages with several letters actuated by single button where required - Google Patents

Abstract

The encoder network for a data processor keyboard input allows single button inputs to correspond to single or multiple letter input messages. The network can be matched to a large number of keyboard types. Each keyboard input button or switch (ZTO, ZTi ...ZTn) is interrogated in a counting sequence by a counter (TAZ) multiplexer (TAM) and marker flip flop (TAS) which switches on when a button is depressed and when the sequential interrogation reaches it. This activates a single encoding store (CSP) or, where appropriate a multiple digit encoder (SQS, SQZ) which generates the required signal output or sequence of outputs and feed them down a highway to the output unit (PSU) for display and further processing.

Description

Circuit arrangement for entering code signals for characters in

a data processing system, in particular in a display device control The invention relates to a circuit arrangement for entering code signals for Characters, symbols, commands and the like (character signals) in a data processing system, especially in viewing device controls, with a keyboard, the keys of which are each one or several characters, symbols, commands or the like are assigned and at whose actuation the character signals are emitted.

In a known such arrangement, which is in the Siemens magazine 1976, H. 4, page 187, each key is assigned a specific character. Only one character signal can be generated by pressing a key. In particular in viewer controls it is often desirable to use a variety of characters and Enter symbols with a keyboard so that e.g. B.

Flow diagrams and the like using the keyboard on the screen a display device can be built. Such keyboards have a large number of keys to which different characters and symbols are assigned depending on the application Need to become.

The present invention is based on the object of a circuit arrangement of the type described at the outset to be used in different, also very extensive Keyboards can be easily customized.

According to the invention this object is achieved in that an interrogation device polls the switch positions of the buttons cyclically one after the other and when polling a actuated key stores an area of a character signal assigned to this key Coding memory calls. The coding memory is expediently a programmable one Semiconductor read-only memory, a so-called PROM. In this each key is an area z. B. a memory cell assigned.

The interrogation device expediently consists of a key interrogation counter, which is counted cyclically, and a multiplexer, which is from the key query counter is controlled and asks a different key for each number supplied to it. To the Key query counters are also connected to the address inputs of the coding memory, so that if the nultiplexer detects a certain switching state, that a key is actuated, the associated memory cell in the coding memory is called up and the character signal contained in this cell is read out. So is a Assignment between key and character signal established via the key query counter. By writing another character signal in a memory cell, a Another character signal can be assigned to the key. By changing the coding memory Any other meaning can be given to the individual keys.

Several areas in the coding memory can also be assigned to one key be. For example, the keyboard may contain a toggle key which, when pressed another area of the coding memory released for the output of character signals is than in the non-actuated state. The key query counter calls in one Case the cells of a first memory area in which z. B. the character signals for capital letters are stored, and in the other case the cells of a second Memory area in which accordingly z. Bo the character signals for lowercase letters are stored on. This can be achieved in that the output signal the shift key represents a base address for the coding memory to which as The partial address of the key query counter is added. In the simplest In this case, this shift key controls the most significant address bit of the coding memory.

At the output of the multiplexer polling the keys is useful a key query memory connected, which when querying an actuated key is set and locks the key query counter in the set state and after completion of the output process selected by pressing a button is reset.

Often times it is desirable to have a sequence with a single keystroke to issue of character signals, e.g. B. a whole word or even a whole sentence or a command sequence. According to a particularly advantageous development of the invention is assigned to a key in the cell of the coding memory for this purpose is, when actuated once, a sequence of character signals are emitted is to store a starting address for a sequence memory array. Will be a If such a key is actuated and queried, then the one in the assigned coding memory cell The address contained in the sequence memory arrangement is supplied. This then gives a predetermined sequence of character signals in succession until an end signal occurs in the memory cell with the supplied address and in memory cells with addresses derived therefrom are stored. The cher arrangement is appropriate from a sequence memory storing the character signals and an address input thereof driving sequence counter that corresponds to the output from the interrogation device Addresses can be preset and their status after each readout of a character signal is increased or decreased by one until the end signal occurs. Appropriate the end signal is contained in the cell of the sequence memory in which the last Character signal of the character string is stored.

Character signals and addresses for the sequence memory arrangement are thus in the coding memory saved. To differentiate, you can also use the cells of the coding memory the type of information stored is stored identifying identification signals be that control a changeover switch in the case of an identification signal for a character signal this switches through to an output unit and blocks the sequence memory arrangement and in the case of an identification signal for an address this to the address input the sequence memory arrangement switches and its output signal to the output unit switches through, Often times the same characters or strings are meant to be repeated can be entered. The operation can be simplified in that the character signal as long as it is entered repeatedly in certain time intervals as the associated Button is pressed. To achieve this, repeating signals can be generated in their presence after output of a character signal from the coding memory or a character signal marked with an end signal from the sequence memory arrangement and when pressed, the output character signal or the output sequence of character signals assigned key the character signal or the sequence of character signals is issued again. It is advantageous to have the repeat signals in the cells of the coding memory to be entered in which such character signals or addresses of Character signal sequences are stored, which are usually entered repeatedly, such as B. the character signal for a write mark transport command. The repeating signals can also be generated with a repeat key, so that any character can be entered repeatedly as long as the assigned key and the repeat key are pressed. To simplify operation, you can press the repeat button be saved, e.g. B. by snapping into place, so that the repeater key and the Key for the character signal can be operated one after the other.

With the aid of the drawing, the invention and pages are described below Advantages and additions described and explained in more detail.

With ZTO ... ZTn character keys of a keyboard are designated, with which code signals for characters, symbols, commands and the like in a display device controller to be entered, which is connected to an output unit PSU, to whose a contact z. B. log. "1" signal is set, which when the button is pressed to a the inputs ETO ... ETn of a key query multiplexer TAM arrives. This multiplexer is controlled by a key interrogation counter TAZ via lines zs' and zs. This Counter is always counted by clock pulses that his via a line t1 Count input are supplied. When the counter reading is zero, for example, the input will be ETO and when the count is n, the input ETn with the output TMA of the key query multiplexer TAM connected so that when a key is pressed, the log applied to it. "1" signal via the TMA output of the keypad question multiplexer TAM to the preparation input TSV one formed by a bistable multivibrator Key query memory TAS is switched through. The clock input of this trigger stage are switched via a line t2 to the key query counter via the line t1 TAZ supplied counting pulses supplied clock pulses. The counter and the multivibrator can be designed so that the same pulses are fed to them and the The counter switches on the leading edge and the trigger level switches over on the trailing edge. is If no character key is pressed, the toggle stage enters TAS via lines za and za ' Release signal to a blocking input SPZ of the counter TAZ. But is one of the keys ZTO .. ZTn is pressed, if the counter TAZ is the one assigned to this key Level reached, the flip-flop TAS switched over with the next pulse on line t2 and the counter TAZ blocked. The polling cycle of the multiplexer TAM is therefore stopped. At the same time, a control unit STW via a line zea11, which is connected to the flip-flop TAS is connected, reports that a key is pressed. The control unit STW then gives an enable signal to a coding memory via a line fzs CSP, at whose address input CAE2 the status of the key query counter via a line zs'l TAZ is created. The control unit STW is in the manner of the known sequence controls built up, which query the signals at several inputs and depending of the input signals emit output signals for controlling functional units.

A base address can be fed to a second address input CAE1 whose meaning is described below and is not taken into account for the time being will. With the release, the memory cell of the coding memory CSP is read out, whose address is the same as the reading of the key query counter TAZ and thus the same as the one Number of the activated character load ZTO ... ZTn is. So there is an assignment between the keys ZTO ... ZTn and the cells of the coding memory CSP.

The content of the selected cell of the coding memory CSP is displayed given a line csa, which via a line csa 'with the output unit PSU is connected, which is a parallel-to-serial converter in the exemplary embodiment. is the content of the selected memory cell the code signal for a character, a symbol, a command or the same, then the output unit PSU is via a line fps released by the STW control unit. After issuing the chensignals outputs the control unit STW via a line ze to a reset input TASR Flip-flop TAS a reset signal, and the counter TAZ is used to query the other Keys released.

As a rule, regardless of the length of time the button is pressed, a signal should be provided can only be issued once. This is achieved by accessing the reset input TASR supplied reset signal the signal on line t2 and on this the Counting pulse on line t1 follows. As a result, when the key, with which triggered the output of the character signal after the reset signal was received is still pressed, the flip-flop is switched back to the state in which the Counter TAZ is blocked before a counting pulse is supplied to it. The query of the ZTO ... ZTn keys is therefore interrupted as long as a key is pressed is.

A sequence memory arrangement is used to output specific sequences of character signals with a sequence counter SQZ and a sequence memory SQS available. Each of these Character bursts are assigned to only one key. These buttons are in a Query cycle queried with the keys, when pressed only a single character signal is issued; If such a key is pressed, the cell of the Coding memory CSP called, the address of which is equal to the status of the key query counter TAZ is. In this case, the content of this cell is not a signal, but an address for the sequence memory SQS. With this address the Lines csa and lines csa "of the sequence counter SQZ are preset. Be Status is fed to the address input SAE of the sequence memory SQS, which, if he is released via a line fsq from the control unit STW, the content of the addressed Memory cell via the lines zf into the lines csa 'and thus into the input of the output unit PSU. After outputting the character signal, the control unit gives STW sends a counting pulse to the sequence counter SQZ via a line t3, its status increases by one and the next cell of the sequence memory SQS is called. This process is repeated until a memory cell is read out, in which, in addition to a character signal, a sequence end signal is wear is, which is fed to the control unit STW via a line sqe. Thereupon be the release signals and clock pulses on the lines fsq and th blocked, with a pulse on the line ze of the key query memory TAS reset and the Key interrogation counter TAZ released so that the key interrogation can be continued can.

Character signals and addresses are mixed in the coding memory CSP registered. The addresses must not be issued via the PSU output unit, do not use the character signals for outputting character signals from the sequence memory Lead SQS. In order to achieve this, the cells of the coding memory CSP contain identification signals that indicate whether the information contained in the cell is an address or is a sign signal.

The identification signals are sent to the control unit via a line sq STW given. Is on this line z. B. "O" signal to indicate that the If the signals given on the line csa are character signals, the control unit blocks STW over the line fsq the sequence memory SQS and gives over the line fps the Output unit PSU free. With an "l" signal on the line sq as a sign that that the signal lying on the line csa is an address, the output unit becomes PSU blocked and the above-described reading out of a sequence of character signals started from the memory SQS. After accepting the output from the coding memory CSP The address in the sequence counter SQZ is sent to the coding memory with a signal on the fzs line CSP blocked so that the lines csa 'for the transfer of the from the sequence memory SQS read out character signals is free.

The addresses contained in the coding memory CSP, which are the start addresses for the signal sequences contained in the sequence memory SQS can be completely free to get voted. It is expedient to set them so that the signal sequences are stored in the sequence memory SQS are stored immediately after each other, so that the capacity of the Storage SQS is used up.

It was mentioned above that the coding memory CSP has an input CAE1 can be supplied with a base address. The change in the base address is triggered by pressing a shift key UST. Closing this button will via a line usl reported to the control unit STW, the one on it the corresponding signal is sent to the us2 line. E.g. is when the toggle key is open UST the signal on the line us2 log. "O" and log when the key is closed. "1". There can therefore be two different ranges depending on the switch position of the UST switch of the coding memory CSP can be selected with the status of the key query counter TAZ, so that with the character keys ZTO ... ZTn two different character signals or addresses or a character signal and an address can be generated.

The shift key UST allows two different character signals or sequence of character signals via the output unit PSU by pressing a output with a single key, but it can also happen that with one key Only one signal should be output. Such a key and the toggle key UST is pressed, a non-programmed area of the coding memory CSP is selected and given information to the output unit PSU. To prevent this, is in the cells of the coding memory CSP in which there is no information to be output is entered, a locking signal is entered, which when you select this cell over a line vs is given to the control unit STW and in this causes at least the output unit PSU is blocked.

In the cells of the coding memory CSP there is also one place each in which a repeating signal can be entered.

If a cell is read out with a repeat signal, this is indicated by a line rps reported to the control unit STW, which, as described above, after the transmission of a character signal from the coding memory CSP or after occurrence an end signal on the line sqe connected to the sequence memory SQS with a signal on the line ze the bistable flip-flop TAS resets the with the following pulse on line t2, if the key is still pressed, is set again. The repetition signal on the line rps now causes after Expiry of a predetermined time, e.g. B. 1/2 sec, is checked, z. B. by means of a Reset pulse to the toggle stage TAS, whether the button is still pressed. Is this the case, the flip-flop is again with the following pulse on line t2 set what that Control unit STW via the line za "is reported, which then starts a new output process. The character signal or string are output as long as the key is pressed. Then the tilting stage TAS finally reset, so that the counter TAZ and the interrogation process continue to count can be continued.

The repetition signal is only the one contained in the coding memory CSP Add character signals and addresses that are issued repeatedly, z. B. the character signal for the cursor of a display device. To repeat A repeat key RPT is provided for outputting other character signals and addresses, with the over a line rpt log. "1" signal can be given to the control unit STW can then perform the same functions described above as when a Repetiersignal executes on the line rps. By pressing the repeat button RPT can repeat all stored character signals or character signal sequences are issued. The repetition frequency is expediently adjustable.

The circuit arrangement described is for connection to keyboards suitable with almost any number of character keys. The possible number of keys depends on the capacity of the key interrogation counter TAZ and the number of cells in the coding memory CSP off. Key elements that are inserted individually into the keyboard are expediently used can be adjusted so that the number of keys can be adapted to the task at hand can. The buttons only need to be unipolar. As a bouncing because of the nature of the Inquiry does not cause an error, cheap key elements can be used. Each key can have any character signal or a sequence of character signals be assigned. Used for coding and sequence memories instead of read-only memories (PROM) read / write memory (RAM) is used, so the properties of the character keys can be changed at will by a data processing system by pressing the buttons assigned character signals entered in the memories and, if applicable, addresses, from Control unit coordinated, replaced. With this reloading and changing the key properties can e.g. B. made the most favorable key arrangement for a specific operation be, with the buttons not required for this operation are locked by locking signals from the data processing system into the coding memory are registered.

13 claims 1 figure

Claims (13)

Claims C1. Circuit arrangement for entering code signals for characters, symbols, commands and the like (character signals) in a data processing system, especially in viewing device controls, with a keyboard, the keys of which are each one or several characters, symbols, commands or the like are assigned and at the actuation of which the character signals are emitted, characterized in that an interrogation device (TAZ, TAM) the switch positions of the buttons (ZTO ... ZTn) interrogates cyclically one after the other and when interrogating an actuated key one of these Assigned to the key. Area of a coding memory (CSP) storing character signals calls. 2. Circuit arrangement according to claim 1, characterized in that the interrogation device contains a cyclically counting key interrogation counter (TAZ), on the one hand a key interrogation multiplexer (TAM) that controls the switching status of the keys (TZO ... TZn) and on the other hand the address input (TAE2) of the coding memory (CSP) controls, from which the content of the addressed memory cell is read out, when the requested key is pressed. 3. Circuit arrangement according to one of claims 1 or 2, characterized characterized in that a shift key (UST) is provided with its output signal the coding memory (CSP) is controlled in such a way that in the non-actuated state the Key interrogation counter (TAZ) the cells of a first memory area and in the actuated State calls the cells of a second memory area. 4. Circuit arrangement according to claim 3, characterized in that a base address for the coding memory from the output signal of the shift key (UST) (CSP) is formed. 5. Circuit arrangement according to one of claims 1 to 4, characterized in that that the interrogator contains a key interrogation memory (TAS), which is used for queries an actuated key is set and, in the set state, switching to the next the Interrogator locks and is reset after releasing the button. 6. Circuit arrangement according to claim 5, characterized in that the key query memory (TAS) is a bistable multivibrator, which is used when a pressed key is prepared and set with a subsequent clock pulse and is reset after outputting a character signal. 7. Circuit arrangement according to claim 6, characterized in that the reset and clock pulses for the key query memory (TAS) and the counting pulse for the key interrogation counter (TAZ) in the sequence reset, clock, counting pulse are supplied. 8. Circuit arrangement according to one of claims 1 to 7, characterized in that that in the coding memory (CSP) addresses for a sequence memory arrangement are stored are that after the supply of an address read out from the coding memory (CSP) one after the other emits character signals in the memory cell until an end signal occurs with the supplied address and in memory cells with addresses derived therefrom are stored. 9. Circuit arrangement according to claim 8, characterized in that the sequence memory arrangement from a sequence memory storing character signals (SQS) and a sequence counter (SQZ) controlling its address input (SAE), which can be preset with the addresses output by the coding memory (CSP) and its status after each readout of a character signal from the sequence memory (SQS) is increased or decreased by one until an end signal occurs. 10. Circuit arrangement according to claim 8 or 9, characterized in that that the end signals are contained in the cells of the sequence memory (SQS), in which entered the character signals of the character signal sequences to be output last are. 11. Circuit arrangement according to one of claims 8 to 10, characterized characterized in that in cells of the coding memory (CSP) character signals and in others Cell addresses for the sequence memory arrangement (SQZ, SQS) as well as the type of stored Information identifying identification signals are stored and that the identification signals control a changeover switch (STW), which in the case of an identification signal for a character signal this switches through to an output unit (PSU) and the sequence memory arrangement (SQZ, SQS) blocks and, in the case of an identification signal for an address, it opens the sequence memory arrangement switches and its output signal to the output unit (PSU) through. 12. Circuit arrangement according to one of claims 1 to 11, characterized characterized that in the cells of the coding memory (CSP) repetition signals (RPS) can be stored, when they occur at the output of the coding memory (CSP) Output of a character signal from the coding memory (CSP) or one with an end signal marked signal from the sequence memory arrangement (SQZ, SQS) and when pressed, the output character signal or the output sequence of character signals assigned key the character signal or the sequence of character signals again is issued. 13. Circuit arrangement according to one of claims 1 to 12, characterized characterized in that a repetition key (RPT) is present, the switching status of which after outputting a character signal from the coding memory (CSP) or one with a End signal marked character signal from the sequence memory arrangement (SQZ, SQS) is queried and with the Repeat button (RPT) pressed and the output Character signal or the key assigned to the output character signal sequence, the character signal or the character signal sequence is output again.