DE1499823C3 - Selection circuit with unipolar switches - Google Patents

Description

3 4

The diodes 9 ... 109 are connected to the switch 13, because the row2 in this case is grounded and

connected, the diodes 10 ... 110 with the circuit- the reverse bias of the diodes of the other-

ter 14, the diodes 11 ... 111 with the switch 15, ren unselected lines, such as the

the diodes 12 ... 112 with the switch 16 etc. diode 5 of row 2 would be canceled. As

The write and read pulse generators GS and 5 mentioned, the switches 14 and 7 could be used simultaneously

As can be seen from Fig. 1, GI are switched, opened and closed in such a way that

that the sign of the unselected lines could thus these switches by a single

supplied pulses can be replaced both for the read pulse and switch, whereby the difference between

the same is also true for the write pulse (in the intended read and write function, this is given

lying example: plus). This is achieved by the fact that the read and write pulses from different

that, as shown, the negative terminals of both separate generators at different times

generators are grounded and their positive terminals are passed over.

Switches and diodes on opposite ends of this replace the two switches with one

Lines are created. single is practically only possible if the

Each row is connected via a sufficiently large 15 to row 1 and the resistor R connected at its ends to a voltage source V containing diodes 3, 4, 9, 10 of the circuit of the sen, which in the example shown is positive and the two generators G. / and GS as well as the greater than the circuit containing the write or read pulse zigen switch with respect to the maximum peak voltage reached without load the conductive connection are separated. One suspicion is. ao-like arrangement is shown in Fig. 2, which the

Let us now assume that the switches in their preferred embodiment, i. H.

Line 1 is selected for reading. The switches 7 as transistor circuits, shows

and 13 are closed, the line through In Fig. 2, only line 1 and the assigned

the latter is kept practically at earth potential. subordinate selection means shown. Line 1 is on

The read pulse generated by the generator GI 25 connected to both ends with diodes, namely with

runs through switch 7, which is not biased to diodes 3 and 4 on side A and diodes 9

Diode 3, diode 9 and switch 13. On the other hand, and 10 on side B.

the line 2 through the resistor R corresponds to the transistor 17, whose collector voltage is held that of the voltage source + V tor via the diode 4, the line 1 and the resistor is approximately the same, because the switches 8 and 15 ge - 3 ° stand R is connected to the voltage source + V , which are open. Diodes 5 and 12 are inverted switches 8 of FIG. 1.

biased, and in particular the diode 5 prevents the emitter of the transistor 17 is grounded, and

the pulse coming from the generator G / its base is at the terminal Tl, through which he the

start entering line 2. It does not receive any control signals that would cause it to be

Transient currents through the line, and the pulse 35 tend to be in the blocking state and vice versa

is not affected by the line capacity. transforms.

If, in the case of a write pulse, line 1. The one on side B is also emitter

is to be selected, the switches 14 and 8 lying transistor 18, which has its control signals

closed, so that line 1 has terminal TI practically at ground, corresponds to switch 13

potential lies. The write pulse runs through the 40 of FIG. 1.

Switch 14, the non-biased diode 10, which in place of switch 7 of FIG. 1 is a trans line 1, diode 4 and switch 8 to earth. Formator 19 (Fig. 2) to the read pulse generator Gl Die on the side B to the switch 14 connected, the secondary winding 20 of which is connected to a separate, unselected line 101 because the end with the diode 3 of the line 1 and with others , the switch 108 is open, held at the voltage + V 45 in a similar manner to the other unselected, so that the diodes 103 and 110 are inversely biased rows of the same group of connected diodes. This prevents in particular is connected. The other end of the secondary winding diode 110 that the write pulse to the line 20 is grounded.
101 enters. The primary winding 21 of the transformer 19 is

It is clear that what has been explained for the line 2 in the back 5 ° with one end to the output of the read pulse look at the read pulse and for the line 101 in the generator GI and with the other end about a view of the write pulse Diode 22 is connected to the collector of an npn transistor 23 in the same way for all other, not shown, whose emitter is grounded and the lines that apply to the switch 7 with the base at terminal Γ 3 apply , via which the line group 55 control signals connected for the read pulse are received,
belong, as well as for the lines not shown on the side B , instead of the switch 14 of the various groups, which are provided on the switch 14 for Fig. 1, a transformer 24 (Fig. 2), write pulse are connected. the secondary winding 25 of which is grounded at one end

From the arrangement shown in Fig. 1 and at the other end with the diode 10 of the line 1 it can be seen that when the line 1 is connected by closing the ⁶ ° as well as with other diodes, the switches in switch 7 on side A and 13 on Side B is selected for reading in a similar way to unselected lines, also the switch 14 on side B, which are closed, which in different groups is intended to occupy this line for writing to the same place. The primary winding 26, without any disadvantage, can be closed with one end to the output of the write, because of the write pulse generator GS in 65 pulse generator GS and with the other end the period reserved for the read operations via a diode 27 to the collector of the transistor none Pulses are generated. 23 switched

On the other hand, the switch 8 cannot be closed. Thus, the transistor 23 works as usual

Switch for the write and read circuits of line 1 and other lines, although the write and read circuits are non-conductive connected to each other.

The diodes 22 and 27 prevent any mutual influence between the primary windings 21 and 26 containing circuits.

In order to send a read pulse to line 1, transistors 18 and 23 are switched by suitable, Control signals fed to terminals Γ 2 and Γ 3 are made conductive. This will put line 1 over the Transistor 18 grounded and the reverse bias of diode 3 canceled. Then sends the read pulse generator G / a pulse through the primary winding 21, the diode 22, the transistor 23 and earth encompassing circuit. The diode 27 prevents this pulse from the primary winding 26 of the transformer 24 affects. This effects the primary winding 21 of the transformer 19 Pulse the flow of a read pulse through the secondary winding 20, the row 1, the diode 3, the Diode 9 and transistor 18.

In order to send a write pulse to line 1, transistors 17 and 23 are the control signals supplied to terminals Π and T 3 are made conductive. This will put line 1 over the Transistor 17 grounded and the reverse bias of diode 10 canceled. ,

The write pulse generator GS then sends a pulse through the circuit containing the primary winding 26 of the transformer 24, the diode 27 and the transistor 23. The diode 22 prevents the primary winding 21 of the transformer 19 from being influenced by this pulse which, through the primary winding 26, causes a write pulse to flow through the secondary winding 25, the diode 10, the row 1 and the diode 4 to earth. Fig. 3 shows the arrangement according to the invention.

ίο The in F i g. Elements corresponding to the switching elements shown in FIG. 2 have been given the same reference numerals and are distinguished from one another by lowercase letters (a, b). To select one of the lines and to determine the direction in which a pulse is to be sent over the line, corresponding potentials must be applied to one of the terminals Γ 3 and one of the terminals T1 or Γ2. In order to select and determine the direction, only two switches need to be actuated, whereby, as can be seen in an N-line arrangement, a total of only 3 VN switches are required to select and determine the pulse direction.

It is understood that the circuits described not only with transistors, but also with other means known to the person skilled in the art, such as gate circuits and the like, for example, can be achieved be able.

For this purpose 3 sheets of drawings

Claims (1)

Claim: Circuit arrangement with unipolar switches for the transmission of electrical pulses in optionally opposite directions via a line to be selected from a multitude of individual lines, to which a pair of oppositely polarized diodes is connected on both sides, with the one (first) side of the lines being connected to the Corresponding diodes are combined with their free ends to form several groups and on the other (second) side of the lines the free ends of corresponding diodes are in turn combined into groups to which only a single line belongs from each group formed on the first side , and in which the groups of diodes intended for coupling the pulses to the lines in the different directions are each connected to the secondary winding of a pulse transmitter, to whose primary winding a pulse generator assigned to the pulse direction is connected, and the other diode groups are each connected to ground via the collector-emitter path of a transistor which determines the pulse direction in the conductive state and determines the row selection, and in which the lines are each connected to a bias voltage source via a resistor, characterized in that the pulse-carrying primary circuits each contain a common branch in which a single switching transistor (23, 23 d) is arranged. The present invention relates to a circuit arrangement with unipolar switches for Transmission of electrical impulses in optionally opposite directions via an off a multitude of individual lines to be selected, one pair on each side oppositely polarized diodes are connected to one (first) side of the lines the respective corresponding diodes combined with their free ends to form several groups and on the other (second) side of the lines the free ends correspond to one another Diodes in turn are grouped together, each made up on the first page formed group only belongs to a single line, and those for coupling the Pulses on the lines in the different directions to certain groups of diodes respectively the secondary winding of a pulse transformer are connected to its primary winding the pulse generator assigned to the pulse direction is connected, and the other groups of diodes one each over the collector-emitter path defining the pulse direction in the conductive state and ■ the transistor determining the row selection is connected to ground, and in which the lines are each connected to a bias voltage source via a resistor. Such an arrangement is known from DT-AS 1178 896. Such arrangements are used especially in memories for electronic data processing. The disadvantage with them is the large number of switches that are required in order to select a single one from a multiplicity of lines and to determine the direction in which a pulse is to be sent over the selected line. For this purpose a total of 4 VN switches are required in the circuit arrangement according to the above-mentioned DT-AS 11 78 896 with an N-line memory. Since data processing systems should work as quickly as possible, these switches must be able to work particularly quickly. In modern data processing systems, switching transistors are preferably used as switches; these are relatively expensive. The IT-PS also shows a matrix selection arrangement which is similar to the arrangement mentioned at the outset 6 45 378. As many switches are required for the described dialing purposes as for the Arrangement according to DT-AS 1178 896. The present invention is based on the object of a circuit arrangement of the type mentioned at the beginning Specify the type for which the required counters, d. H. in modern Circuit technology on required switching transistors compared to arrangements according to the state of the Technology, is diminished. This object is achieved according to the present invention in that. the impulsive ones Primary circuits each contain a common branch in which a single switching transistor is arranged. Compared to the prior art, the invention requires fewer VN switching transistors for the selection and choice of direction in the presence of N lines compared to the prior art. The invention is not limited to the selection of memory lines in accordance with the method of coincidence selection working ferrite core memories, but can also be used for memories after other methods, such as word choice, work and also for memories of others Constructions such as thin film storage, cryogenic storage and, in general, the one Number of two-pole circuit elements to select one, through which the current in both directions should flow. These and other features and advantages of the invention are intended below with reference to the drawings are described in more detail. It shows F i g. 1 four lines of a memory matrix according to the state of the art, F i g. 2 a row of a memory matrix and its selection means according to the present invention, 3 shows the matrix selection arrangement according to the invention. Fig.l shows an arrangement known from IT-PS 6 45 378, in which each line 1, 2 ... 101, 102 ... is provided with two diodes at each of its two ends, namely the diodes 3, 4; 5, .6; ... 103, 104; 105.106; ... on side A and diodes 9, 10; 11, 12; ... 109, 110; 111, 112; ... on side B. The diodes of side A are each, as in FIG. 1, connected to one-way switches 7, 8 ... 107, 108 ..., and on the B side are one-way switch pairs 13, 14; 15.16; ... intended.