DE1524780B2 - CIRCUIT ARRANGEMENT FOR SELECTING DISPLAY EQUIPMENT USING A MATRIX ARRANGEMENT - Google Patents

Description

to switch on the line whose associated display means are to be selected. The cells in this row then store the information, ie whether the cells have been selected or not, for the duration of one cycle until the row in question is put back again in the next associated time slot. Once the cells of one row have been acted upon via the switches that connect the control potential to the column wires, these switches can then successively apply control potential to the cells of the other rows. While m switches are used for the lines in the illustrated embodiment 2, namely «! Switch for resetting the rows and m switches for the preliminary setting of the rows, which are then supplied with the control potential across η column switches, it is otherwise possible with only get m + 1 switches for the lines, namely apart from the m setting switches with only one switch for resetting the lines, which can be done, for example, at the beginning of the scanning cycle. A disadvantage of such a matrix arrangement is that the cells in the lines set first after the start of the scanning cycle put the associated display means in the selected or unselected state for a somewhat larger part of the scanning cycle than the cells in the lines scanned later within the Do sampling cycle. In many practical applications of the matrix arrangement, this disadvantage may be insignificant and outweighed by the savings in m-1 reset switches and the control means for these switches.

In the figure, each cell has a controllable semiconductor rectifier or a thyristor TH and a decoupling diode DD , the cathode of which is connected to the control electrode of the rectifier. The cathodes of the thyristors located in a row are connected to a first row wire provided for each row and the anodes of these thyristors are each connected via an individual display means L to a second row wire provided for each row. In the exemplary embodiment, the display means is a signal lamp, and the matrix arrangement is therefore part of a device for optical information display. The anodes of the decoupling diodes DD located in a column are each connected to an associated column wire.

The respective first row wires of the rows are used for the preparatory setting of the thyristors, while the respective second row wires of the rows are used to reset the thyristors; the column wires have a control potential V 4 applied to the thyristors selected in the rows. The first row wires are connected via individual ON / OFF switches S (working contacts) to a terminal carrying a setting potential Vl and to the anodes of further individual decoupling diodes D. The cathodes of these diodes D are connected to a terminal carrying a holding potential V 2. This potential V 2 is chosen so that when the setting switch S is not closed and the control potential is switched on, the thyristors of the row in question do not fire. The second row wires are connected via a common or, as shown, via individual reset switches R (break contacts) to a terminal carrying an operating potential V 3. The column wires are connected to a terminal carrying the control potential V 4 via individual control switches T (normally open contact). Setting, reset and control switches are monostable switches and do not need a mechanical or electromechanical type, but can be semiconductor switches that can be switched more quickly. If semiconductor switches are used, it must be ensured that the setting and control switches are closed simultaneously for such a period of time that any selected thyristor can be made conductive by the potentials V 1, V 4, and that the reset switches are opened for such a period of time are that conductive thyristors can return to the non-conductive state.

The resetting of the controllable semiconductor rectifier can also be done in another way. Instead of interrupting the anode current line by line with the reset switches R , a resistor of such a value can be connected in parallel to the rectifiers that the anode current of each rectifier falls below the holding current. The arrangement can be made for this purpose in such a way that the current source supplying the operating potential V 3 has an internal resistance of a certain minimum value, that the switches R are replaced by a galvanic connection and that this connection, via at least one series circuit of a 'resistor and a Reset switch is led to a potential point whose potential is equal to or more negative than the potential of the terminal V 1.

In the figure, the reference numbers indicate the row and column, except for the potentials V 1 to V 4. The rows are numbered from 1 to m and the columns are numbered from 1 to η. In the case of two-digit numbers, the first digit means the row and the second digit the column.

The holding voltage for the thyristors is applied to terminals V 2 and F 3, the potential of terminal V 3 being approximately 50 V more positive than the potential of terminal V 2 , for example. The setting potential of terminal V 1 may be 12 V more negative than the potential of terminal V 2 , while the control potential of terminal V 4 is either equal to or approximately 1 V more negative than potential V 2 . An only slightly negative control potential reduces the risk that the thyristor will respond as a result of the control potential on the corresponding column wire in the absence of the setting potential on the corresponding first row wire; this precautionary measure is taken in addition to blocking by means of the decoupling diode D.

For the description of the mode of operation it is assumed that the matrix is in the state at the beginning of a scanning cycle. All setting switches S and control switches T are open, and all reset switches R are closed, so that a voltage V3-V2 is applied to the anode-cathode paths of all thyristors. The thyristors may be partly conductive and partly non-conductive. During the first time slot of the scanning cycle, the reset switch R 1 is opened, with the setting switch Sm being closed at the same time, as will be explained in more detail below. Opening the switch R 1 puts all thyristors in the first row into the non-conductive state by interrupting the anode voltage. Then the reset switch R 1 is closed again, and at about the same time the setting

switch 51 closed, whereby the thyristors of the first row are prepared for an eventual ignition, and the reset switch R 2 is opened, whereby the thyristors of the second row are reset. Alternatively, the opening time of the reset switch Rl can also follow the closing time of the setting switch 51, but this slows the scanning speed by about half. In the preferred exemplary embodiment, the setting switch assigned to a line is closed at the same time as the reset switch assigned to the next line is opened, for a period of approximately 400 μ5. If the matrix is e.g. B. has 30 lines, the duration of a scanning cycle is 12 ms. While the setting switch 51 is closed, the potential Vl is applied to the thyristors TH 11, TH 12 ... ΓΗ1 n. Since the potential V 2 is positive compared to the potential V1 , the diode D1 is blocked. The control switches T 1, T 2 ... Tn may now dependent concluded by the monitored signal states, said control potential to the corresponding column wires passes and switching to the selected lamps L 11, L 12 ... L 1 η effected by the assigned thyristors are controlled to be conductive via the corresponding decoupling diodes DD 11, DD12 .. .DDIn. For example, effects the closing of the control switch Γ 2, the application of the potential V 4 via the diode DD 12 to the control electrode of the thyristor TH 12. The resultant control current are added at suitably selected parameters for the electrical characteristics of the thyristor TH and the decoupling diode DD of the thyristor TH 12 into the conductive state, so that its anode-cathode current causes the lamp L 12 to light up. When the control switch T 2 is closed, the potential V 4 is also fed to the anodes of the diodes DD 22, DD 32 ... DDm 2 , but the associated thyristors cannot conduct because the potential V 4 is more negative than the potential V 2 and on the other hand, there is a voltage drop across some of the diodes D, which is caused by the currents flowing through the conductive thyristors in the corresponding rows. This voltage drop causes the cathodes of some "undesired" thyristors to become even more positive than the potential V 4. Once the thyristor 77il2 has become conductive, it remains conductive and the lamp L 12 burns, even if the control current disappears when the control switch T 2 is opened again. This lamp remains on until the reset switch R1 is opened again in the next scanning cycle. The control switch can therefore be opened again because the thyristor TH 12 works as part of a binary memory cell. If the control switch Tl is not closed during the closing period of the setting switch Sl , then the decoupling diodes DD 21, DD 31 ... DDmI prevent the thyristor THU from being conductive due to the positive potential at the control electrodes of any other conductive thyristors in the first column State is controlled. At the end of the time slot of the scanning cycle assigned to the first line, the setting switch S1 opens, and the cathode current of the thyristor TH12 then flows via the diode D1 to the terminal V 2, whereby it slightly increases the cathode potential of the thyristors in the first line and thus the thyristors are less sensitive to the control potentials that apply to thyristors in other rows and in the same column. The potential difference V3-V2 must of course lie above the holding voltage which is specific to the particular thyristor type.

After reopening the setting switch 51 at the end of the time slot assigned to the first line; the reset switch R 3 is opened and the setting switch 5 2 is closed, whereby the beginning of the j time slot assigned to the second line is marked, in which the control switches Tl, T 2 ... Tn correspond to those for the second line apply j the external signal states are actuated again. The other lines are controlled accordingly within the scanning cycle.

The control switches Tl, T 2 .

In the simplest form of the matrix arrangement, the selector switches 5, R, T can be non-lockable, manually operated switches or contacts of remote-controlled relays, which can be returned to the normal state, for example by means of springs, namely into the open state with regard to switches 5 and T and in the closed state with regard to the switch R. The mode of operation of such a matrix arrangement is similar to the mode of operation already described, with the exception that manual operation is not tied to regular scanning. In manual operation, individual lines can be reset in any desired sequence by actuating the reset switches assigned to the lines, or all lines can be reset by means of a common switch R , not shown, which, when actuated, removes the potential V 3 from the entire matrix . In such a simple, hand-operated matrix arrangement, it is possible to conduct a thyristor in a row by operating the corresponding switches 5 and T without first having to reset the entire row by operating the switch R provided for this row.

With a better design of the matrix arrangement, the matrix arrangement has means for cyclic scanning of the memory cells, as has already been described. The scanning means can be of a known type. For example, a ring counter can be used to determine the time required to scan a line and to trigger a number of monostable multivibrators, one multivibrator always being triggered during a particular ring counter state. These multivibrators operate the reset switches R, and the tilting of the multivibrators can be used to operate further multivibrators, which then operate the setting switches 5 and synchronize the operation of the control switches T in each line period in accordance with the state of a corresponding set of signal input channels . Such synchronization can be achieved by means of gate circuits which are switched on between the sampling circuits and the control switches T. With a better design of the scanning circuit, additional scanning means are provided, the individual control switches T successively.

and not operate simultaneously during any line period.

In a further improved embodiment of the matrix arrangement with scanning circuit means are provided which periodically block the control switches in such a way that they are normally under the control of the input signals mentioned for a certain number of scanning cycles and then for a certain further number of scanning cycles independently of these Input signals are blocked. These blocking means can advantageously have a counter for counting the scanning cycles determined by the aforementioned ring counter and also gate circuits for blocking the control switch T. During each interval in which the control switches are disabled in this way, the entire matrix is reset, with all cells non-conductive. This further improved embodiment requires an additional device for the special case in which each of the selectable display means is a signal lamp, this device allowing temporary operation of the entire lamp field. In this way, a special alarm state can be used to activate the cyclically operated blocking circuits and thereby light the lamps, for example at a frequency of 2 Hz. With a typical sampling cycle of 12 ms, the blocking circuits would therefore alternately be active and inactive for the Duration of successive sets of 20 sampling cycles each.

If the matrix arrangement has lamps as display means, it can also be used as a character generator instead of as a multi-channel signal indicator. For this purpose only a single reset switch R is necessary for the entire matrix, and the scanning circuit can be modified so that only a single scan of the matrix is carried out line by line and that each scan requires a new character to be displayed. The signal input channels transmit information

ao nen about the presence or absence of any sign element.

1 sheet of drawings

209 520/329

Claims (9)

Patent claims: 1. Circuit arrangement for the selection of display means by means of a matrix arrangement, characterized in that for each row between two row wires series circuits of a display means (L) and the switching path of a controllable semiconductor rectifier (TH) are arranged that on one row wire via an individual or for all Rows common reset switch (R) one operating potential (F 3) and the other operating potential (Fl) to the other row wire via a setting switch (S ) as well as to the control electrodes of the semiconductor rectifier column by column (by means of T) control potential (F 4) can be connected and that in each case the row wire connected to a setting switch (S) is connected to a wire carrying holding potential (V 2) via a decoupling element (D). 2. Circuit arrangement according to claim 1, characterized in that the decoupling elements Diodes are. 3. Circuit arrangement according to claim 1, characterized in that in each case the control electrodes of the semiconductor rectifiers arranged in a column are decoupled by diodes (DD). 4. Circuit arrangement according to claim 1, characterized in that a lamp (L 11 ... Lmn) is used as the display means. 5. Circuit arrangement according to claim 1, characterized in that the control potential has such a value and polarity with respect to the holding potential that the Receiving control electrodes of the semiconductor rectifier not to be switched through blocking potential. 6. Circuit arrangement according to one or more of claims 1 to 5, characterized in that scanning means are provided for cyclical and line-by-line successive scanning of the matrix crosspoints, with the setting switch assigned to a line being closed and the reset switch assigned to the following line being opened in a line period Control switch (T) assigned to columns can be selectively closed. 7. Circuit arrangement according to claim 6, characterized in that gate circuits between the scanning means and the control switches are connected and that these gate circuits have means to synchronize the setting and control switches. 8. Circuit arrangement according to claim 7, characterized in that the synchronization means cause successive actuation of the selected control switches. 9. Circuit arrangement according to claims 6 to 8, characterized in that the Scanning means have locking means connected to the control switch and alternating between the control switches disable and enable again, each for the duration of a number of scanning cycles. The invention relates to a circuit arrangement for selecting display means by means of a matrix arrangement. Matrix arrangements are known in which the crossing points are formed by display means. Furthermore, from the German Auslegeschrift 1 200 375 there is a matrix arrangement with at the crossing points arranged bistable four-layer transistors known. With this matrix only ίο a galvanic connection from one line to one Gap made on the basis of a stop mark and a coincident temporary control mark will. After switching through a crossover transistor, the setting is also a further transistors in the same row are not possible. Also the sole setting of an additional transistor another column is not possible. The object of the invention is to provide a circuit arrangement for selecting display means to create by means of a matrix arrangement in which the display means in any desired manner Combination can be set quickly. This is achieved according to the invention in that each Line between two line wires Series connections from a display means and the switching path a controllable semiconductor rectifier are arranged that to the one row wire via an individual or a reset switch common to all lines and the one operating potential to the other Row wire via a setting switch to the other operating potential and to the control electrodes the semiconductor rectifier can be switched on column-wise control potential and that in each case the with Row wire connected to a setting switch via a decoupling element with a holding potential leading wire is connected. These and other features of the invention are explained in more detail using an exemplary embodiment. The matrix arrangement shown in the figure has a number of binary information storage cells which are provided at individual crossing points of a matrix with m rows and η columns. Each memory cell is connected in series with a display means to be selected and is either conductive or non-conductive, depending on which of its binary states it has been placed in. The use of such memory cells as selection and switching means for the individual display means has the advantage that mn display means can be selected using only m + η + 1 selector switches, although 2m + η selector switches are used in the illustrated embodiment. The use of memory cells allows cyclical scanning with a reduced number of selector switches, which are used to reset any conductive cells in each row row by row to the non-conductive state and, during the immediately following part of the scanning cycle, to select those cells in the row that has just been reset column by column which should be made conductive and have to switch on the associated display means. In each complete scanning cycle, each line is put back once and immediately thereafter a set-up potential is applied; While this setting potential is being fed to a row, the control potential is fed successively or simultaneously to the column wires in order to select those cells in the relevant