DE1095557B - Switching matrix for data processing systems - Google Patents

Description

In the art of message processing machines, e.g. B. the calculating machines, is very common given the task of controlling a very specific line from among a multitude of lines. These Task is z. B. given in memory technology when individual cores within a magnetic core memory must be controlled.

It is known to achieve such a control with the aid of magnetic cores. Here is Each individual line to be controlled has a magnetic core with an at least approximately rectangular hysteresis loop assigned, and the individual magnetic cores are provided with control windings, that as soon as a certain core and thus a line are to be controlled, this magnetic core is remagnetized, with one (or possibly several) pulses via the corresponding line gives.

In Fig. 1 of the drawing, a known arrangement is shown. The arrangement consists of a so-called magnetic core matrix, a total of thirty-six magnetic cores K being arranged in a matrix form. Each individual core can be controlled via two lines, namely one of the lines in the "X direction" and one of the lines in the "F direction". Every single core is provided with a bias winding. The bias current is selected in relation to the winding so that the individual cores, each of which has a rectangular hysteresis loop, assume a defined rest position.

Should then, for example, the core located in the third row and in the third column be activated so that he has the output winding assigned to him, which is shown in the figure by a simple Slash is indicated, passes a pulse, then it is transmitted accordingly via the third Z-line and the third F-line is given a current pulse. Both lines are on the same line with everyone or column lying core concatenated and the current impulses are chosen so that that by a pulse induced field within a core is insufficient, the core, which, as mentioned, premagnetizes accordingly is to tip over. When adding two currents that flow through one of the X lines and through one the F-lines can only add up in one core, however, this core is magnetized and transmits both during magnetization reversal and magnetization reversal the bias current from a pulse. One of these two impulses is usually with the help a direction-dependent resistance suppressed.

As can be seen from the illustration according to FIG. 1, with the help of a total of twelve so-called switching matrices for data processing
Investments

Applicant:

Siemens & Halske Aktiengesellschaft,

Berlin and Munich,
Munich 2, Wittelsbacherplatz 2

Dipl.-Phys. Rudolf Buser, Munich,
has been named as the inventor

Driver stages, namely six for the six X lines and six for the six F lines, thirty-six Magnetic cores or one of these thirty-six magnetic cores can be controlled. For every Line, a driver stage is therefore usually necessary, since the magnetic cores have a relatively need high current for magnetization reversal and the control pulses, for example within a Calculating machine occur, cannot or may not be loaded to such a high degree.

The field conditions in the control of an individual magnetic core are explained with reference to FIG.

This figure shows the rectangular hysteresis loop of a magnetic core. With the help of a bias current - or a permanent field - the magnetic core is kept in the defined state α .

The bias field corresponds to the vector Vl. Currents are now sent via the X-lines and the F-lines, which induce a field in the core that is opposite to the bias field. These vectors are shown below the hysteresis loop by the vectors V2 and V3 . As can be seen here, neither of the fields, i.e. neither the field represented by the vector V2 nor the field represented by the vector VZ, is sufficient to re-magnetize the core, so that a pulse only occurs in the output winding when both fields are added, which is assumed in FIG. In this case, the core tips over into position b . An output pulse is induced here, and when the pulse-shaped magnetization on the core has subsided again, the magnetic core tilts back to its defined starting position (point α) via the left branch of the hysteresis loop.

009 679/284

The invention relates to a circuit arrangement of this type, with the aim being with to make a selection from a large number of cores with relatively little effort. This is achieved according to the circuit arrangement according to the invention in that the cores at least electrically multidimensional, e.g. B. in several levels, arranged and with one of the number of dimensions the number of excitation windings corresponding to the arrangement are concatenated, the excitation currents xo are coordinated in such a way that a certain core is only activated when it is controlled via all windings is, is remagnetized and emits a pulse in the process. According to the invention, for control a planar matrix is not used for a particular line, but a spatial arrangement is used the cores, which accordingly have to be controlled via more than two lines, are provided, which results in a considerable saving in driver stages for the control itself. In the simplest and even in the clearest case, it is sufficient to arrange the cores three-dimensionally, for example in several levels one above the other, with each of the cores being carried by a total of three lines, accordingly the three dimensions.

3 of the drawing shows an exemplary embodiment. In this figure, a cube can be seen which is intended to represent the spatial arrangement of a total of sixty-four cores, the cores being arranged in four levels of sixteen cores each one above the other. Each individual core is linked with an X, a Y and a Z line, whereby initially only one core is present at each crossing point, so that if an excitation pulse is given over a line of one dimension, only one core is remagnetized will. This core then forwards a pulse to its assigned output line. As can be seen from FIG. 3, it is possible, with the aid of twelve driver stages, which represent the greatest effort in such a switch, to achieve a selection from sixty-four lines instead of the previous thirty-six lines. With even more lines, the ratio between the cost of driver stages and the number of lines from which one is to be controlled becomes even more favorable.

As mentioned, each individual core is chained to one of the X, F and Z lines. In order to create unambiguous conditions, a current is then given via each of the lines for control, which induces a field in the core that is uniform for all lines. The size of the field is chosen so that the core is not yet remagnetized due to the superposition of two magnetic reversal fields, but that this core is surely overturned when a magnetic reversal pulse occurs in all three lines.

This is shown in FIG. 2 by the vectors VA, VS and V6 , it being seen that the addition of two vectors does not yet reach the right branch of the magnetization loop, seen from point α, while the addition of three Vectors a magnetization reversal must take place. After the remagnetization pulses have subsided, the core is returned to its starting position (point 0) in a circuit arrangement according to the invention with the aid of a premagnetization, which in turn can be effected in a manner known per se by a premagnetization current.

With reference to Fig. 3 it was explained that in an electrical three-dimensional arrangement, the core a magnetic reversal of the cores is caused by currents of the size // 3, where it is assumed that the current / is certainly sufficient for a reversal of magnetization. Due to the somewhat finer subdivision of the Magnetic reversal currents compared to the known arrangements in which // 2 currents were used is obtained, especially when the bias field is not chosen to be just as large can like the magnetic reversal field generated by the partial currents in the other line that Magnetization reversal process and reverse magnetization process run differently, so that the pulses emitted via the output winding, one of which is of course suppressed may, are different. This is disruptive and impaired, especially at higher switching frequencies the mode of operation of the magnetic core. According to a development of the inventive concept, therefore suggested to support the pre-magnetization with a pulse during the reverse magnetization, so that the reverse magnetization process, there is now also a pulse for the reverse magnetization is present, at least approximately in the same way as the magnetization reversal process.

This is shown in FIG. 2 of the drawing by the auxiliary pulse V7 corresponding to a vector, which generates a field which is superimposed on the premagnetization Vl in the same direction. While the output pulses of the core, as can be seen from FIG. 4a, turn out to be unequal with a constant premagnetization, a curve shape according to FIG. 4b can be forced with the aid of a reset pulse which is superimposed on the premagnetization. This is particularly of great interest when the switching matrix is used to control a magnetic core memory in which the positive pulses are used, for example, to read the information stored in the memory, while the negative pulses that occur immediately afterwards are used to write a new one Information, or the information read out from the memory, can be used.

An adaptation of the output pulses induced by the reset to the pulses occurring during magnetization reversal can also be achieved with the aid of switching elements in the output line itself. This is clearly shown in FIG. 5, it being assumed that the core KZ, which is located within a switching matrix according to the invention, is positive and negative when controlled via its windings to the line L passing through the individual memory cores S 1 to Sn Emits current pulse. The end of this line L is terminated with a resistor capacitor element in such a way that, together with the inductance of the line itself, the desired current distribution or deformation of the output pulses occurs. The resistance capacitor element is dimensioned in such a way that the steep reset edge (cf. FIG. 4a) is deformed in such a way that the pulse shape corresponds at least approximately to the function shown in FIG. 4b.

According to a development of the inventive concept, the cost of driver stages for a Switching arrangement with a plurality of magnetic cores are thereby further depressed that on every single point of intersection of the line corresponding to the dimensions of a spatial arrangement several, at least two cores are arranged.

Each of the cores at a crossing point is connected to all magnetization reversal lines, so for example linked to the X line, the F line and the Z line.

Such an arrangement is shown in extracts in FIG. In this figure, only an X line, an F line and a Z line can be seen, and it is assumed that initially two cores are arranged at the intersection of this line. As the figure shows, both the core k 1 and the core k 2 are concatenated with the Z line, with the X line and with the F line. However, each core has its own output winding, not shown for reasons of clarity, and each core is linked to a different bias winding, i.e. the bias winding, which is linked within a spatial matrix with all cores that are arranged in the matrix, is just like connected to a large number of cores in a simple matrix, but never with two cores within a crossing point. With this arrangement it is achieved in a simple manner that with the same number of driver stages double or multiple cores can be controlled, in which case only switching of the bias winding is necessary in order to make certain cores assigned to one another effective within a cubic switching matrix .

When explaining the invention, the control that takes place via the individual lines was nothing said. This control, the control pulses that contain information or can be derived sequentially from clock pulses of a clock line, must order depending on the Erf and in particular the structure of the switching matrix and the structure of the switching matrix switching elements to be controlled, e.g. B. a memory matrix, each dimensioned. That here occasionally also worked with the help of positive control impulses canceling negative impulses can only be mentioned for the sake of completeness.

Claims (7)

Claims: 45 1. Switching matrix for data processing systems to control a specific line under a plurality of lines with the help of magnetic cores assigned to the individual lines with rectangular hysteresis loop; which are forced into a via a premagnetization Rest position and the respective line assigned to them by magnetization reversal emit a pulse, characterized in that the nuclei are at least electrically multidimensional, z. B. in several levels, arranged and with one of the number of dimensions of the arrangement corresponding number of excitation windings are provided, the excitation currents so one on top of the other are matched so that the core only ever when it is controlled through all windings is, is remagnetized and emits a pulse in the process. 2. Circuit arrangement according to claim 1, characterized by a three-dimensional arrangement the cores in several levels, with each core by a total of three lines accordingly the three dimensions is controlled. 3. Circuit arrangement according to claim 1 and 2, characterized in that the windings on the cores and the currents flowing through these windings are coordinated in such a way that that the field necessary for reversal of magnetization is applied in equal parts. 4. Circuit arrangement according to claim 1 to 3, characterized in that the back magnetization the bias current is superimposed on this supporting pulse-shaped current, which is selected so that the output pulse of the core is at least approximately the same with reversed magnetization and reverse magnetization. 5. Circuit arrangement according to claim 1 to 4, characterized in that the premagnetization field, optionally amplified by a pulse, is matched to the field generated for remagnetization so that both fields on the opposite side have the same value from the line HO . 6. Circuit arrangement according to claim 1 to 5, characterized in that with the aid of timing elements coincidence of the positive and negative output pulses is enforced. 7. Circuit arrangement according to claim 1 or one of the following, characterized in that at each crossing point of the excitation lines at least two cores are arranged, all of them with all excitation windings, but with different bias and different Output windings are chained, so that different by the choice of bias Cores take effect. Considered publications:
U.S. Patent No. 2,740,949;
Journal Applied Physics, 22, 1951, pp. 44-48. 1 sheet of drawings 009 679/284 12.60