DEI0009062MA - - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

Registration date: August 24, 1954. Advertised on July 5 , 1956

GERMAN PATENT OFFICE

It is known to e from materials with a rectangular or approximately rectangular hysteresis loop to produce toroidal cores and the two stable states of magnetization of such cores to use for storing dual values. For the implementation of a computer system, for example desired large storage capacity are many such cores in a plane according to arranged in a matrix and provided several such levels one above the other. On the kernels are windings, usually consisting of one turn, applied by selection devices be supplied with magnetizing current. Generally only when occurring at the same time of currents in two or three windings reaches the field strength required for magnetization reversal. The circuit of the core windings and the selection devices are such that only one core at a time or some of a number of cores in a recording or extraction process be remagnetized.

An important consideration in memory design is reducing the time it takes for a recording or extraction process

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is consumed. Since a considerable part of this time is taken up by the magnetization of the core it is useful to speed it up. One way to do this is to increase the magnetic reversal field strength. Known arrangements

^: make this field strength so great that, taking into account the scattering of the material properties, it surely exceeds the coercive force and produces the saturation induction.

ίο Through the selection devices and the circuit of the windings is achieved that this field strength is only in one core (or in some) occurs, while the others were only influenced by the current of one or the other magnetizing winding Cores reach half the value of this field strength, which is also certainly smaller than the coercive force. The latter cores do not suffer from magnetization reversal, but deliver but undesirable contributions to the useful signal during a removal process.

In an effort to keep the interference contribution of the unselected nuclei small, Circuits designed in which the field strength of these nuclei is one third and less of its value achieved, which is impressed on the selected cores. The field strength value of the selected nuclei has the size described above, i. H. it brings about saturation, and half its value lies below the coercive force.

With the enlargement of the remagnetizing , Field strength increases the speed of magnetization reversal, but also the current required for this. The invention relates to a circuit arrangement for a three-dimensional magnetic core memory to select a few from a number of cores at the same time, with both Ends of the series-connected magnetizing windings selection devices are provided. Only the windings of this row of cores have current flowing through them. The field strength of the unselected Cores of the series lies below the coercive force and corresponds to half the saturation field strength, that of the selected nuclei has three times the value. To increase the steepness of the ascent of the magnetizing current is an amplifier stage equipped with a transistor Feedback provided.

The invention will now be explained in more detail with reference to the figures.

Fig. Ι represents an idealized hysteresis curve of a magnetic material that is used for Cores used in the circuit according to the invention;

Fig. 2 shows how one of the two magnetic switching elements can be caused to have its to change magnetic state, while the other magnetic switching element is unaffected remains;

Fig. 3 is a circuit diagram to scale and shows how eight magnetic elements are cubic can be arranged in four word lines each, each containing two digits, and how these Lines of words in two - dimensions of such a cubic arrangement are selected and their places can optionally be determined in the third dimension;

Fig. 4 shows in a partial circuit how a change in state of a magnetic element can be amplified by a semiconductor amplifier;

Fig. 5 shows a circuit in which certain elements are shown to scale in three dimensions and in the transistors in the word position circuits of a single word line circuit are provided.

Fig. Ι shows an idealized hysteresis loop of the magnetic material used, as it can actually almost be achieved. The material has a high remanence, so that at its positive saturation corresponding to point e it has a force line flow corresponding to point f . If the material is now in the state representing the binary O, that is, if it is negatively saturated up to point j and then after switching off the MMK the flow of force corresponds to point a , when an MMK is applied that is sufficient to keep the material in the to saturate positive direction, e.g. + 2Ji, run through the curve abcde, and when this MMK is switched off, the point / is set. In this state, the binary 1 is stored in the core. When a strong or weak positive MMK is applied, there is then no change in state, and the flow of force in any case assumes the value f again after this positive MMK has been switched off. Likewise, if the material is not excited in the negative direction up to the value g , there is no change in the state, and the power flow returns to the value / after this MMK is switched off. However, if the MMF is increased above the value corresponding to point g, e.g. B. to - 2 H ₁ , the curve fghij is traversed; and when this MMK is switched off, the power flow is then set to the value represented by point α.

In the circuit according to FIG. 2 , information can be stored in binary form. On each of the two cores 1 and 2, which consist of material with the properties shown in FIG. 1, there are two excitation windings. The winding 3 of core 1 and the winding 4 of core 2 are connected in series with the tubes 5 and 6. When these tubes become conductive, enough current will flow through windings 3 and 4 to produce a positive MMK in cores 1 and 2, respectively, with a value of + 2 H ₁ . The other two windings 7 and 8 'of these cores are in separate circuits. If an O is stored in both cores, that is, if the power flows through both cores correspond to point α in FIG MMK of + Ji ₁ results, with simultaneous excitation of coil 3 a resulting MMK + 3JJ ₁ results; the core is controlled by a flux of force that corresponds at least to the value e

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flowed through, so that when this MMK is switched off from the core ι the value / is set, which represents a binary ι. When the coil 8 is switched on in a circuit through which such a strong current flows that an MMK-H ₁ arises, If the coil 4 is excited at the same time, a resulting MMK + H _{1 will} result; the state of core 2 is thus not changed, so that when the MMK in core 2 goes back, the power flow will again assume the value that represents the binary O.

Said coils are switched on by the relay 9, which is in a circuit with the pushbutton contacts 10 and a battery, so that the relay 9 is actuated when the pushbutton is depressed. The capacitor 11, which bridges a resistor 12 and the battery 13 ¹ , is charged in the idle state. When the relay 9 is actuated, the capacitor 11 ih a circuit with the resistor 14 and the relay 15 is switched on, so that the capacitor discharges through the relay 15, which responds temporarily to it for a short time. During this very short time a positive voltage is applied to the grids of the tubes 5 and 6, and a current pulse flows through the coils 3 and 4. At the same time, a current flows through the coil 7, by which the core 1 is positively excited, and through the coil 8 a current by which the core 2 is negatively excited.

The circuit of Fig. 2 is only intended to show how the cores are more suitable by simultaneous application positive or negative pulses to different parts of the circuit in one or the other State can be brought. This circuit only serves to contribute to the following circuit diagrams to make the smallest possible number of switching elements easier to understand. The relay 9 is used to select the relevant tubes,

z. B. the tubes 5 and 6, and for applying current pulses with the appropriate polarity the word location coils, e.g. B. to the coils 7 and 8. Relay 15 represents the means for the simultaneous Generating and transmitting the various pulses is used. In practice, of course, a relay like the one shown could be used Relay 15 cannot be used for this purpose because its switching speed is way too is slow compared to that obtained by using the magnetic cores according to the invention can be achieved. Fig. 2 shows, however, how such magnetic switching elements are controlled can be.

In the arrangement according to the invention, there should now be many coils, several memories or word lines form, each of which contains several coils corresponding to the word positions which in a circuit are to be connected in the three dimensions of a scale drawing can be represented. A line showing the "intersection of the plane perpendicular to the forward." runs in the X direction, with a plane perpendicular to the routing in the Y direction extends, can be, is represented by the coil circuit of FIG. Each, contained therein Coil, represents an intersection of this line with a plane perpendicular to the .Continuing in the Z-direction extends. The different lines of words are in a matrix connected to each other, and therefore a diode must be connected in each word line so that. that Flow of leakage currents is prevented.

Fig. 3 shows a so-called three-dimensional arrangement for four word lines, each with one Represents memory for two word digits. A practical device in a mainframe computer could be 4096 word lines (64 X-planes and 64 F-planes) with 40 characters each (40 Z-planes); this The 2X2X2 arrangement according to FIG. 3 is only used to illustrate the principle used.

This figure shows eight cores 20 to 27. Cores 20, 22, 24 and 26 are in the same X-plane, cores 20, 21, 24 and 25 are in the same Y- plane and cores 20, 21, 22 and 23 are in same Z plane. Through the Z selection of the line 28 and the F selection of the line 29, the word line consisting of the cores 20 and 24 can be selected. The core 20 or 24 can be optionally influenced by the connections optionally applied to the various Z planes.

Each core has three coils, one for recording and the second for sensing and the third serves to selectively store a word position in the relevant core. the Coil 30 of the core 20 · is in the recording circuit, its coil 31 in the sensing circuit and the Coil 32 in the Zi plane of the Zi point. Every Coil is provided with a point indicating the polarity; the polarity of the sensing coil 31 is opposite to that of the recording reel 30. All Z-coils are connected in the same way, so that the polarity of the coils in the different Z-planes outside the matrix by optional Application of excitation current to the connections for each such level is controlled.

When a word is to be stored in the word line represented by cores 20 and 24, connections 28 and 29 are selected and tubes 34 and 35 are controlled via recording line 33. A current flows from the positive pole of the battery via the tube 34, the coil 30 of the core 20, the coil 36 of the core 24, the diode 37 and via the tube 35 to earth in such strength that each of the cores 20 and 24 through an MMK of + 2H _{1 is} excited (see. Fig. 1). Because of the diode 37, no undesired shunt currents can flow. This excitation of the nuclei is so strong that a change of state can occur when the nuclei are in the state representing the binary O. However, this change of state is still influenced by the coils 32 and 38. Assuming that coil 32 is now energized and _{producing an MFC of + H 1} in core 20, then there is a resulting MFC therein

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of + 3 H ₁ , and there is a change of state. In addition, an MMK of + H ₁ arises in the other cores 21, 22 and 23 of the Z i plane , but this is not sufficient to switch the state of one of these cores, and it therefore does not interfere with the word positions, dfie in another previous operation have been introduced therein. If it is also assumed that the coil 38 is now excited in such a way that an MMK of _{-H 1 is produced} in the core, then the total MMK-IH ₁ = (+ 2H _{1 -H 1} ) arises therein, and it kicks off no change of state in the core 24. At the same time, an MMK - H ₁ occurs in the other cores 25, 26 and 27 in the Z2V level; However, this MMC is not sufficient to bring about a change of state in these cores, regardless of whether they have previously stored a binary 0 or a binary 1.
In addition, FIG. 3 shows that when the tapping line 39 is charged instead of the recording line 33 via the control circuit 40, the tube 41 instead of the tube 35 is made conductive. In this case, the pick-up coils 31 and 42 instead of the recording coils 30 and 36 are energized. Since the polarity of the pick-up coils is opposite to that of the recording coils, each of the cores 20 and 24 can be negatively excited by an MMK having a value of at least -2, H _1. The Z-plane coils are not involved in the extraction and therefore all cores of this word line are set to the state expressing the binary 0.

Can be used to extract output pulses during the acceptance and recording processes each core having a fourth coil, e.g. B. the coil 43 on the core 20. When the core 20 ' changing its positive state (binary 1) to its negative (binary 0) is due to the breakdown its positive field and an impulse through the build-up of its negative field induced in the coil 43, the polarity of which is characteristic of the removal process. An impulse opposite polarity is induced in coil 43 when the state of the core is different from the binary 0 is switched to binary 1, i.e. during a recording process. The output pulses generated in each case can be used if necessary can be fed to other circuits to trigger work processes.

In the circuit according to the invention, in which only the coils of the selected line of words are energized a greater excitation ratio can be achieved. Previously had to be with direct arousal of the coils in the matrix, the resulting excitations of other coils are necessarily so dimensioned be that the algebraic sum of the excitations of other coils in the matrix, however was not always smaller in the selected word line than that which was used to bring about a state- ' change was necessary; therefore 2: 1 was the best ratio that could be achieved. When selecting at the same time of the two ends of a word line circuit according to the invention can have a relationship from 3: ι to be reached; an even bigger ratio can even be achieved upon removal. Therefore, the working speed can be greatly increased, e.g. B. from about 700 microseconds to about 50 microseconds.

Fig. 4 shows a sub-circuit in which a transistor is used. The core 50 has the four windings 51, 52, 53 and 54. When a negative voltage is applied to the lower terminal of the coil 53 during recording, the collector electrode 55 is negatively biased. If a negative switching pulse is then applied to the base electrode 56 of the transistor by applying a recording pulse to the coil 51, a positive feedback is produced in the windings of the core 50, which work as a transformer. The voltage drop across the collector electrode winding 53 induces a voltage in the base electrode winding 52, as a result of which the base electrode 56 is biased even more negatively. This allows a larger current to flow in the collector electrode winding 53. This positive feedback continues until core 50 is saturated; then, however, no more voltage can be induced in the base electrode winding 52; the feedback stops. Magnetic motor forces MMK much greater than H ₁ can be achieved and recording times of about 5 microseconds - with selected core materials and transistors - can be achieved.

A three-dimensional memory system using transistor feedback circuits is shown in FIG. According to FIG. 5, a single word line consists of the core 60 in the Z i-plane for a word position, the core 61 in the Z2-plane for a further word position and the kernel 62 in the ZiY-plane for a third word position. By a X-selection, the tube 63 becomes conductive, and a Y-selection and Be ¹ ■ actuation of the recording control circuit 64, the tube 65 becomes conductive. As a result, such a strong current flows from the positive pole of the power source through the tube 63, via the sinks 66, 67 and 68, the diode 69 and the tube 65 to earth that an MMK + H _{1 in the cores 60, 61 and 62} occurs, but this alone is not enough to change the state of one of the nuclei. If only the tube 70 becomes conductive during the Z selection, a negative voltage occurs at the collector electrode of the transistor 71 and a negative switching pulse occurs at the base electrode coil 72 as a result of the pulse via the coil 6j. In this case, the positive feedback, as has already been described, greatly increases the recording pulse via the coil.67, so that a change in state in the core 61 is generated. It is assumed that the Z-selection does not energize the tubes 73 and 74 so that there is no change of state in the cores 60 and 62.

When the word stored in the word line is to be extracted, the tubes 63 and 75 made conductive so that the field of each nucleus. in this line, which has a binary 1 stored,

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is reversed and, as a result, a pulse is sent out through the take-off coil. While running of the withdrawal pulse through the coil 77, a withdrawal pulse is passed on by the coil 78, which is connected in series with all the same extraction coils in the same Za level.

This series connection can be useful e.g. B. used as a computing unit of a computing machine

, will.

Claims (6)

PATENT CLAIMS: 1. Circuit arrangement for three-dimensional magnetic core memory with arranged in predetermined X, Y, Z planes bistable cores, which are used to store binary encrypted information, in particular word or numerical information, for the simultaneous selection of a multi-digit word line, characterized in that two Windings (30, 31 and 36, 42) of all cores (20, 24) lying one behind the other in the Z-direction are connected in series and at both ends of this series connection there are selection devices (218, 29) for selecting the Z or F plane and the recording - or removal process (33, 39) are connected, 2. Arrangement according to claim 1, characterized in that that the upper ends of all series connections of a Z-plane to the cathode a discharge device (34) and the lower ends of the series connections a Separate F-level for recording and removal to the anode of one discharge device each (35, 41) are connected. 3. Arrangement according to claims 1 and 2, characterized in that in a recording or removal process only the windings of a word line from one sufficient for remagnetization or this preparatory magnetizing current are flowed through. 4. Arrangement according to claims 1 to 3, characterized in that the cores not to be switched over are exposed to the field strength H, the cores to be switched over to the field strength 3 H , where 2 H is the saturation field strength and H is a field strength which does not cause a permanent change in the magnetic state . 5. Arrangement according to claims 1 to 4, characterized in that to increase the Switching speed of the memory cores an amplifier circuit with positive feedback is coupled to the storage core windings. 6. Arrangement according to claim 5, characterized in that the amplifier is a transistor serves, which is coupled via an additional winding of the storage core. Considered publications: Proceedings of the I. R. E. April 1952, pp. 475-478; Journal of Applied Physics, January 1951, p. 44 to 48; RCA Review, June 1952, pp. 183 to 201. 1 sheet of drawings