DE1158114B - Arrangement for the compensation of interference pulses in magnetic core memories - Google Patents

Description

Arrangement for the compensation of interference pulses in magnetic core memories The invention relates to an arrangement for compensating for interference pulses in magnetic core memories, in particular to compensate for pulses that are inductive are transmitted from the control wires to the reading wire.

In the case of magnetic core memories, the magnetic cores are arranged in rows and columns are known to occur when driving a certain selected magnetic core In addition to the useful signal read, there are also interference signals. These interfering signals stir before mainly because, in addition to the selected magnetic core, other magnetic cores as well can be supplied with a control current. Get the unselected cores generally with magnetic core memories working according to the coincidence principle only half the current required to remagnetize a magnetic core. But since the The hysteresis loop of the material used for the storage cores is not strictly rectangular occurs when the magnetic cores are activated with half the magnetic reversal current certain interference voltages in the output windings of the magnetic cores, d. H. the reading winding of the magnetic core memory.

To compensate for these unwanted glitches, there is already a a whole number of arrangements and methods have become known. This is how it is, for example known, the reading wire in a certain way through a plane of magnetic core memory respectively. It is also known that the magnetic cores in the manner of a herringbone pattern to arrange. The interference voltages originating from a magnetic core are thereby through compensates for the interference voltages of another magnetic core, since this one in opposite Direction is traversed by the wires. It is also known with the reading winding of the magnetic core memory to link a special compensation core that the during the reading process on the reading line occurring interference pulses through opposite directional impulses compensated.

However, the invention relates to these known compensation methods does not affect the compensation of the partial magnetization of magnetic cores caused interference voltages, but from interference voltages that arise as a result, that inductively transmit interference pulses from the control wires to the reading wire will. To solve this problem, it is known to use the inductive properties of the magnetic core memory simulating transformer, its primary winding is switched on in the control circuit and its secondary winding so with the reading circuit is connected that interference voltage and compensation voltage cancel each other out.

Because the reading wire of a magnetic core memory together with the control wires represents a transformer consisting of loosely coupled air coils, it is advantageous to have the compensation transformer also made up of two loosely together to build coupled air coils. The present invention relates to Formation of such a transformer and consists in that the column-parallel or the line-parallel holding wires for the reading wire of the magnetic core memory than the secondary winding coupled to the control wires of the magnetic core memory of the transformer and used to compensate for the interference voltage in the reading wire are included. By using the drive wires in this way as the primary winding and the inclusion of the column-parallel or row-parallel retaining wires in the read circuit as the secondary winding of the transformer is unnecessary an additional transformer. The compensation of the interference voltages occurring in the reading circuit takes place without additional components by using the otherwise only for mounting serving lines or columns parallel holding wires as the air-core coil of the compensation transformer.

The figure shows a special structure and how it works the arrangement according to the invention explained in more detail.

The figure shows an essentially known matrix arrangement of magnetic cores for storing information units. The magnetic cores are arranged in rows and columns. The Y-wires are used to select a specific row and the X-wires are used to select a specific column. Furthermore, a so-called inhibit or information wire is linked to all the cores of the matrix arrangement and is passed through the individual magnetic cores parallel to the column wires. In the arrangement shown, which, as shown, is only one half of a matrix level, the inhibit or information wire begins at terminal 11 and ends at terminal 12. In addition, a read wire is linked to all cores, which is also in itself is passed through the magnetic cores in a known manner. A special feature is that this reading wire is divided into two parts in each half of the matrix level. B. starts at terminal A and ends at terminal B and its second part z. B. starts at terminal C and ends at terminal D. This arrangement of the reading wire in two parts results in a certain distribution for its sense of direction in relation to an assumed column and row direction at the edges of the matrix. This distribution of the direction of the wires is shown by small arrows at the edge of the matrix. As can be seen from the direction of these arrows, the sense of direction of two adjacent reading wire loops running along the edge of the matrix is opposite to one another. However, the sense of winding of those reading wire loops that run parallel to the column wires at the edge of the matrix is the same everywhere. Inside the matrix, the reading wires run in a straight line and always cross the row and column wires at the same angle, but with alternating directions. The number of crossing points resulting in the entire matrix level is an even number. For this reason, the interference voltages induced along these rectilinear parts compensate each other from the wiring.

The reading wire loops that are parallel to the row wires As can be seen, on the one hand they have the sense of direction, to the the other half the opposite direction of the row wires. The induced in them Interference voltages also compensate each other. But there the one in the one to the column wires loops of the reading wires lying parallel to each other all have the same sense of direction the interference voltages induced in them do not cancel each other out.

A compensation transformer is used to compensate for these interference voltages provided, according to the invention on the primary side from the column wires and on the secondary side consists of the column-parallel retaining wires. These retaining wires are included in the reading group for this purpose. As can be seen from the figure, consists therefore both between point B and point C and between point D and the point E a connection through the column parallels attached there Holding wires. The sense of direction of these two holding wires with regard to their activation in the reading circle is also shown by an arrow and has, as can be seen is, the opposite direction as the sense of direction of those holding wires reading wire loops lying in a parallel direction. The ones in these two holding wires The voltages induced in each half of the matrix thus act as a compensation voltage for the interference voltages in the reading wire loops running parallel to the columns be induced.

Claims (1)

PATENT CLAIM: Arrangement for the compensation of interference pulses in one Magnetic core memories that inductively transfer from the control wires to the reading wire with a simulating the inductive properties of the magnetic core memory Transformer, its primary winding in the control circuit and its secondary winding is connected to the reading circuit in such a way that interference voltage and compensation voltage cancel each other, characterized in that the column-parallel or the line-parallel holding wires for the reading wire than with the control wires of the magnetic core memory coupled secondary winding of the transformer used and to compensate for the Interference voltage are included in the reading wire. Legacy Patents Considered: German Patent No. 1056 396.