DE3641527C1 - Circuit arrangement to interrogate a contact matrix - Google Patents

Abstract

A circuit arrangement to interrogate a contact matrix by a computer is specified. The computer, which is activated only after at least one matrix element is activated, carries out an interrogation cycle. In the row and column lines of the matrix, switching means are provided for this purpose, and, when the matrix is not activated, they cause switching of a test voltage in parallel to all matrix elements and, after a switching control signal has been given by the computer, connection of an interrogation potential column by column, and access by the computer to the row lines. The computer is caused to produce the switching control signal via an AND circuit, if the test voltage on at least one row line breaks down because at least one matrix element is activated. <IMAGE>

Description

The invention relates to a circuit arrangement according to the preamble of the claim.

For querying contacts arranged in a matrix, such as they z. B. occur in key sets, by a computer a software process is mostly used today, such as it z. B. in U. Tietze, Ch. Schenk, "Semiconductor circuit technology", 4th edition, 1978, Pages 569 to 575.

The keys are arranged as a matrix, and it will a software query using the multiplex method carried out. The row lines are with outputs and the column lines with inputs of a computer connected. If no key is pressed, it is up to the Inputs at an H potential. To query one after the other to a row line L potential created (all other lines have H potential). If now a key is pressed, occurs at an entrance of the computer (column line) to an L level if the corresponding line is driven. A the corresponding counter indicates the line address.  

Another query of a matrix of individual contacts is from the IBM Technical Disclosure Bulletin, Vol. 27, No. 5, October 1984, pages 2779, 2780. The Columns of the matrix are controlled by a Program, cyclically in succession to a specific one Potential, where all rows of the matrix be queried for their respective status. If a key is pressed now, it results from the respective column address and the associated Line status the address of the key pressed.  

Since the computer constantly uses the matrix (e.g. every 10 ms) repeatedly queried, he is heavily used and can correspondingly less used for other tasks, although most of the time no actuation of the Contact matrix is done. To this constant strain to avoid the computer, it is possible to Only activate the computer when a contact is operated. However, this still requires that Provision of double contacts in the contact matrix, one of which is only the activation of the Calculator serves.

Such double contacts are complex and can be in some key set versions (e.g. Realize rubber mat key sets).

The invention has for its object a Circuit arrangement of the type mentioned create which is the query of a matrix Allows individual contacts with the help of a computer, whereby the computer only when at least one contact is activated the matrix for query is activated.

This task is characterized by the characteristics of the Part of claim 1 solved.

The computer is therefore outside of the times when inputs are actually made via the matrix Performing other tasks available.

Especially for querying key sets whose Contacts as described in claim 2, via a dome Rubber mat are operated and therefore for arrangement of double contacts are unsuitable, the invention provides a simple and economical solution.  

Developments of the circuit arrangement according to the Invention are in claims 3 and 4 described. The subject of claim 4 enables the query of additional electrical functions together with the query of a contact matrix. So z. Legs Series of testing and monitoring functions in one Matrix query cycle can be integrated. A special Subroutine for querying test voltages can thus omitted.

An embodiment of the described in claim 5 Circuit arrangement according to the invention relates to a simple embodiment.

The invention is based on a Embodiment and a figure in detail described and their function explained in more detail.

The figure shows schematically a block diagram of the embodiment. There is a matrix M with four column leads S 1 . . . S 4 and four line feeds Z 1 . . . Z 4 shown. The matrix should only contain simple contacts as matrix elements and should have no decoupling diodes. To interrogate the matrix, a clock-controlled computer R is used, the above address outputs. 1 . . 4 and an address decoder AD can cause the connection of individual column lines to zero potential. The computer is able to query the state of the row lines of the matrix via a parallel input (connecting lines 6 ... 9 ). So-called open drain drivers T 1 are located in the column leads and in the row leads. . . M 4 and M 5 . . . T 8 as goal circuits. The gate connections in the column leads connect them directly to zero potential and can be done using NOR gates NG 1 . . . NG 4 both individually from the outputs D 1 . . . D 4 of the address decoder AD can also be connected through together by a signal output by the computer via the connecting line 5 . The gate connections in the line feed lines can only be influenced together by the signal output on the connecting line 5 of the computer. You connect the row lines to the parallel output of the computer.

The circuit arrangement shown in the figure also contains an AND gate UG , the inputs of which to the non-actuated matrix via pull-up resistors RP 1 . . . RP 4 row lines connected to positive potential are connected. The output of the AND gate is connected to the computer both via a connecting line 10 and via a debouncing circuit EP and a connecting line 12 . A connecting line 11 of the computer is used to output a time clock for the debouncing circuit consisting of a flip-flop chain.

The first row line Z 1 does not lead directly to the gate circuit T 5 , but via a gate circuit T 11 and an OR gate OG . The latter combines the signal of the row line with two signals present at circuit inputs F 1 and F 2 which, instead of the unused matrix elements S 1 Z 1 and S 2 Z 2, are assigned to other electrical functions to be queried together with the query of the matrix. These signals are switched through gate circuits T 9 or T 10 to the OR gate OG and thus to the computer input when the column lines S 1 and S 2 are controlled by the address decoder AD .

At the same time, in these cases the signal of the row line Z 1 is separated from the computer input by the gate circuit T 11 blocked by a further NOR gate NG 5 , and the corresponding signal of the input F 1 or F 2 is connected to the computer input.

The function of that shown in the figure Circuit arrangement is as follows:

The clock supply of the computer is switched off in the idle state. The computer only needs quiescent current. The column lines are via the switched gate circuits T 1 . . . T 4 connected to zero potential. The gate circuits T 5 . . . T 8 are blocked. The row lines of the matrix are at their positive potential via their pull-up resistors. If a matrix element is now actuated, one of the row lines is thereby set to zero potential. The clock generation of the computer is thereby activated via the output of the AND gate and the connecting line 10 . The computer derives from its own work cycle a reduced query cycle, which it supplies to the debouncing circuit via line 11 . The debouncing circuit contains a flip-flop chain, the links of which are clocked by the interrogation clock and to which the output signal of the AND gate is fed. The supplied output signal is bounce-free when it has passed through all flip-flops without an interruption in the signal. The latter is determined by an AND operation of the flip-flop outputs and leads to an interrupt for the computer via the connecting line 12 . This interrupt signals to the computer that a matrix element has been actuated and is only reset when the matrix readout procedure that has now started has ended. The readout procedure begins with a switchover signal which the computer outputs on the connecting line 5 . This changeover signal on the one hand cancels the connection of the gate circuits T 1 . . . T 4 on and on the other hand switches the gate circuits T 5 . . . M 8 through. This enables the computer to connect the matrix columns individually to zero potential via the address decoder and to read the status of the row lines via its parallel input to each addressed column. An actuated matrix contact can then be clearly determined with the help of the column address known to the computer and the assigned row status. Multiple operations of the matrix elements, which can simulate an incorrect operation, are determined with the help of a special program and rejected as invalid.

When the readout procedure is finished, the interrupt is reset. The switchover signal on the feed line 5 disappears and the idle state of the circuit arrangement is restored until the next actuation of a matrix element takes place.

In the circuit arrangement shown, the matrix elements at the intersections of columns S 1 and S 2 with row Z 1 are not populated with contacts. Instead of the state of these two matrix elements, the presence of electrical signals supplied via feed lines F 1 and F 2 can be checked. A control signal on one of the outputs D 1 or D 2 of the address decoder AD causes the gate circuit T 11 to be blocked and the gate circuits T 9 and T 10 to be switched through via the NOR gate NG 5 . The signal to be checked is switched through to the computer feed line 6 instead of the signal of the row line Z 1 . An inquiry procedure cannot be initiated via inputs F 1 or F 2 . By expanding the AND gate by two inputs, which are connected to the inputs F 1 and F 2 , this possibility can easily be created.

Claims (5)

1.Circuit arrangement for querying a matrix of individual contacts or electrical replicas of such contacts with the aid of a clock-controlled computer, in which the column lines of the matrix are placed one after the other at a predetermined potential in a query cycle and the row lines of the matrix are queried for their respective status and at the actuated matrix elements are determined from the respective column address and the associated row status, characterized in that in the column and row inlets ( S 1 ... S 4 ; Z 1 ... Z 4 ) of the matrix (M) switching means ( T 1 ... T 8 ) are arranged which, depending on a changeover control signal of the computer (R), either enable the column-wise connection of the predetermined potential required for the query and the access of the computer to the row lines or a parallel connection of a test voltage to all matrix elements cause an AND circuit (UG) is provided t, whose inputs to the row lines ( Z 1 . . . Z 4 ) are connected to the matrix and which monitors the presence of the test voltage at the matrix elements and outputs an activation signal for the computer at its output if the test voltage breaks down on at least one row line as a result of a matrix element being switched through, and that the computer after it has been activated for a time period corresponding at least to the duration of a query cycle outputs the switchover control signal to the switchover means and executes a query cycle. 2. Circuit arrangement according to claim 1, characterized characterized in that all or part of the matrix elements Contacts of a button set are assigned to the buttons Soak in the dome of a rubber mat. 3. Circuit arrangement according to claim 1 or 2, characterized characterized in that all or part of the matrix elements are electrical replicas of contacts. 4. Circuit arrangement according to claim 1, 2 or 3, characterized in that a part of the matrix element locations is not occupied with branches or contacts, that for each such unoccupied matrix element location further switching means ( T 9 , T 10 , T 11 ) are provided, which the Disconnect the row line ( Z 1 ) assigned to the unoccupied matrix element location from the computer input ( 6 ) and, in its place, switch through another electrical signal (lines F 1 , F 2 ) to the computer input ( 6 ) and that the switching means are controlled by the same signal that the Applying the predetermined potential to the individual column line ( S 1 , S 2 ) of the matrix assigned to the unoccupied matrix element location. 5. Circuit arrangement according to one of the preceding claims, characterized in that the switching means in the column feed lines are gate circuits ( T 1 ... T 4 ), the control inputs of which are both the switching control signal and the signal of a computer output or output assigned to the respective column connection ( D 1 ... D 4 ) of an address decoder (AD) controlled by the computer, the switchover control signal blocking all gate circuits ( T 1 ... T 4 ) arranged in the column feed lines, the output signal of the assigned computer output or decoder output causes the respective gate circuit to be switched through to zero potential, and that the switchover means in the line feed lines are controlled by the switchover control signal in such a way that they switch the line lines through to a corresponding number of computer inputs ( 6 ... 9 ).