DE1064262B - Magnetic core shift register - Google Patents

Description

Shift registers for shifting stored information can either consist of bistable multivibrators, which consist of amplifier systems, or of magnetic cores with approximately rectangular Hysteresis loop can be established. The present invention relates to shift registers consisting of Magnetic cores are constructed.

In such magnetic shift registers, an information unit (bit) is binary-coded Information stored in a magnetic core in the form of positive or negative remanence. Should a saved Information unit are moved further, the corresponding magnetic core must be in the direction a certain remanence position, generally its so-called zero position, are magnetized. This is done in magnetic shift registers by means of the so-called shift pulse. Is located If the magnetic core is already in the zero position, it remains in this position. But was before a unit of information in the form of opposite remanence is then stored in the core the magnetic core is remagnetized with a change in the magnetic flux. Through this change of flow at the Reversal of magnetization of the magnetic core from the opposite remanence position to the zero position induced voltages in all windings. The induced voltages cause in the circuits to the neighboring magnetic cores of the shift register currents trying to break the neighboring To magnetize magnetic cores in a direction corresponding to the currents. As a result of that voltages are induced in all windings of a magnetic core during magnetization reversal, Current pulses run from the magnetized magnetic core both into one and into the other other direction of the shift register. In general, however, it is only desirable to shift the information unit in a single direction, namely in the forward direction. The one running backwards Impulse must then be suppressed. However, shift registers are also known which allow To move information units either forwards or backwards.

Another problem is that a pulse emanating from the magnetized magnetic core only then occurs in the next magnetic core may take effect if this has already been triggered by the associated shift pulse is returned to its zero position or generally after the effect of the shift pulse in this magnetic core has already subsided. It is known to use delay elements for this purpose. It is also known to use so-called intermediate cores instead of delay elements, which compared to the other memory cores by a magnetic core shift register

Applicant:

Siemens & Halske Aktiengesellschaft,

Berlin and Munich,
Munich 2, Witteisbacherplatz 2

Dr.-Ing. Karl Euler, Munich,
has been named as the inventor

phase shifted shift pulse can be controlled. The phase shift between the two shift pulses results in the necessary delay. It is also known not just two, but even three To use shift pulses whose phases are shifted from one another in time.

In all of these previously known shift registers, in order to avoid undesired information transfer, z. B. backwards or to the next core in the sliding direction, directional ladder used.

The invention relates to shift registers with three magnetic cores per bit, which are phase-shifted by three Shift pulses are controlled.

The object of the invention is to create a shift register in which no directional conductor is used any longer will. This is achieved in that to prevent undesirable reactions between The magnetic cores of the shift register each couple two successive magnetic cores dispensing with directional conductors are dimensioned in their resistance so that they are limited thereby Transmission impulses either not on their own, but only in connection with one at the same time The existing shift pulse is sufficient to reverse the magnetization of magnetic cores or their Effect in the magnetic cores, in which an information unit to be moved is not stored is to be compensated by the shift pulses, and that the pulses of the three phase-shifted Shift pulses are dimensioned accordingly in terms of their amplitude, duration and pulse sequence.

Because in the shift register according to the invention, the rectifier between the individual magnetic cores of the shift register are omitted, the register has an almost unlimited life and is largely insensitive to transient

909 609/229

Overloads. In addition, it is no longer necessary to provide the storage cores with windings that consist of consist of several turns. So far this has been used to adjust the resistance of the input and output windings the magnetic cores to the relatively high-resistance diodes required. At the shift register according to the invention it is sufficient that each winding consists of only a single turn. This kind of The construction of magnetic shift registers is particularly difficult with regard to the after all Winding of the magnetic storage cores advantageous. There is the possibility of a very cheap one Build shift registers when the lead wires of the two magnetic cores connecting the circuits simply pushed through the magnetic ring cores.

The current limiting resistors in the circuits between two magnetic cores of the Shift registers can even be saved as components if one is responsible for the circuit wires Resistance wire used.

A particular advantage of the shift register according to the invention is that they can be used optionally Shifting information both in one direction and in the opposite direction is used can be. For this it is only necessary that the phase sequence of the shift pulses has different phases is reversible.

The structure and operation of two Ausführungsbei play the shift register according to the invention are explained with reference to FIGS.

Fig. 1 shows the circuit of the shift register. It can be seen from this circuit that the individual magnetic cores are only coupled to one another via resistors. The part of the shift register shown consists of the magnetic cores Al, A "2, KZ and A'4 with the connection circuits a, b and c. In the connection circuit α is the current limiting resistor Kl, in \ ^r Getting Connected circuit b of the current-limiting resistor AE2 and c in the connection circuit of the Current limiting resistor 7-3. The sliding winding of the magnetic core A1 is connected in series with the sliding winding of the magnetic core A4, as can be seen from Fig. 2. The sliding winding of the magnetic core A 2 is likewise connected to the sliding winding of the magnetic core, not shown in FIG A5 connected in series, etc. The three phase-shifted shift pulses are applied to terminals F1, F2 and F3.

Fig. 2 shows the mechanical structure of a shift register according to the invention. The part shown consists of the magnetic cores All to A22. The magnetic cores All, ΑΊ4, A17 and A20 are controlled by the shift pulse Fl, the magnetic cores A12, A "15, A18, A'21 by the shift pulse F2 and the magnetic cores A'13, ΑΊ6, ΑΊ9, A22 by the shift pulse F3 Shift register is constructed without the use of special components for the current limiting resistors.Instead, the connecting wires between each two magnetic cores consist of resistance wire which is dimensioned in such a way that the desired limitation of the transmission pulses occurs.

3 shows a pulse diagram for the three phase-shifted shift pulses. The individual impulses of the different phases overlap each other. It can be seen that e.g. at time ί 2 both at Fl and at F 3 an impulse is effective. No pulse is effective at F2. At time ί3 there is an impulse each at Fl and F2 effective, none at F3, and at time i4 a pulse is effective at F2 and F3, but none at Fl.

At time ti , the information "one" is stored in the first magnetic core of the register by an input pulse. As a result, the magnet core Al is remagnetized from its zero position, for example the negative remanence point (-Br), into the positive remanence point (+ Br) of its hysteresis loop. The now following shift pulse at Pl magnetizes the magnetic core Kl back to - Br at about time f2 and induces a voltage on its output winding that causes a current to flow to the input winding of the magnetic core λ'2 and moves the magnetic core K2 to the positive remanence point + Br of its Brings hysteresis loop. The message "one" was thus transported on from the magnetic core A1 to the magnetic core K2 .

At time tZ a shift pulse follows at F2. The magnetic core '2 is magnetized back to - Br and thereby passes on its stored information unit via the circuit b to the magnetic core K 3. This reverse magnetization of the magnetic core '2 to -Br also induces a voltage in its input winding, which causes the current Ja to flow in the circuit α. Yes has the tendency to re-magnetize the magnetic core A'l to + Br . At the same time, however, the magnetic core A1 is still acted upon by the shift pulse current Jp 1 (see FIG. 3). In order to prevent undesired reactions in the magnetic core A'1, the resistance Rl must be dimensioned so that

Yes <JpI

is. This only applies if the sliding winding has the same number of turns as the output or input winding of the magnetic core. The equation also applies to all other circuits and shift pulses. The shift pulse must always prevail so that the corresponding magnet cores are in the remanence position. -Br be kept. This prevents the stored information unit from being transmitted in the reverse direction.

During the above-described process at time ί 3, namely the storage of an information unit in the magnetic core A3, a voltage develops at the output winding of the magnetic core A3 which tends to reverse magnetize the magnetic core A4 to - Br. The magnetic core A4 , however, is already in its remanence position - Br, so that this pulse coming from the magnetic core K 3 cannot remagnetize the magnetic core A'4. There is therefore no transmission of an information unit to the next but one magnetic core.

At time ί4, the information unit "one" leaves the first stage of the register, which consists of the three magnetic cores A1, A'2 and A3, and the register is then ready to receive a new information unit. With the message "Zero" there is no input pulse and the magnetic cores remain in their remanence position -Br .

The resistances in the circuits between the magnetic cores continue to cause the magnetic cores are not short-circuited on their output side.

It can be advantageous for slowly operating shift registers instead of a plus sequence with a pulse duty factor of 2: 1 per clock period to use two short single pulses, as also in Fig. 3 is shown in dashed lines.

Fig. 4 shows another timing diagram for a shift register according to the invention. Principle one

shift register operating according to such a pulse schedule it is, in the connecting circles between • the individual magnetic cores by appropriate Dimensioning the limiting resistors to allow a current to flow that is only half as large as the current required to remagnetize a magnetic core. For storing a unit of information In a magnetic core, the effect of this current is supplemented by a correspondingly large one Current in the sliding winding of the magnetic core, in which the information unit is stored target. This is the so-called // 2 principle, which is already known from matrix storage technology.

An input pulse the information unit "one" in the magnetic core class will stored the ^ shift register. As a result, the magnetic core K 1 is magnetized in the + Br direction. At time ill, a negative shift pulse follows on shift line P1. This has a size that is sufficient to re- magnetize the magnetic core K1 to - Br, i.e.!> /. As a result of the magnetization reversal of the magnetic core K1 , a voltage is induced in the output winding, which causes a current in the circuit α. The resistor R1 is now dimensioned so that this current is about V2 /. At the same time, the sliding winding P 2 of the magnetic core K2 _{flows into a5} . positive current of size V2 /. The magnetic core K 2 is thus acted upon by both the circuit α and the shift pulse winding with ¹ IzJ each and thereby remagnetized to + Br. As a result, the message “one” has been transported on from the magnetic core K1 to the magnetic core K2 . At time il2, the message "one" is passed on from magnetic core K2 to magnetic core K3 in the same way.

A reverse transport of stored information units is not possible. When an information unit is saved from the magnetic core K 2 and passed on to the magnetic core K 3 , a current of size ¹ IzJ also flows in the circuit α , but it is not sufficient to re-magnetize the magnetic core if I, because at time i2 flows in the Sliding winding Pl no electricity. Also flows c in the circuit due to the magnetic reversal of the magnetic core K 3 due to the storage of the information unit, a current size ¹ Is J. But here the power is not enough, umzumagnetisieren the magnetic core K \, as in the slide Winding Pl of the magnetic core K 4 no current flows at time i2. This also prevents an information unit from being transmitted to the next but one magnetic core. When the message "zero" is sent, no input pulse is sent to the first core of the shift register, and when such a message is passed on, "zero" remains
Magnetic cores in their resting state - Br.

Claims (5)

Patent claims: 1. Shift register made of magnetic cores with an approximately rectangular hysteresis loop, in which three magnetic cores are provided for a shift cycle, which are controlled by three different, mutually phase-shifted shift pulses, characterized in that between the magnetic cores (Kl, K 2, K 3,. ) of the shift register, the circuits (a, b, c, Simultaneously existing shift pulses (P1, P2, P 3) are sufficient to remagnetize the magnetic cores or their effect in the magnetic cores, in which an information unit to be shifted is not to be stored, is compensated by the shift pulses, and that the pulses of the three phase-shifted shift pulses (Pl , P 2, P 3) in their amplitude, duration and pulse sequences are dimensioned accordingly. 2. Shift register according to claim 1, characterized in that the pulses of the different Phases overlap in time and their amplitude is such that the effect unwanted impulses that arise from the magnetization reversal of neighboring magnetic cores, the undesired magnetic core is compensated by the shift pulses. 3. Shift register according to claim 1, characterized in that the resistors in the circuits between the magnetic cores are dimensioned so that the transmission of an information unit The current flowing is only half as large as that required to remagnetize a magnetic core Current is and only in the magnetic core required for the displacement is the missing current through a corresponding current is added to the sliding winding of the magnetic core. 4. Shift register according to claim 1 to 3, characterized in that the two magnetic cores connecting circuits to limit the current consist of resistance wire. 5. Shift register according to claim 1 to 4, characterized in that for optional shifting of information in two opposite directions, the phase sequence of the shift pulses different phase is reversible. 1 sheet of drawings © 909 609/229 8.59