DE1122099B - Memory and / or counter circuit with hysteresis memory elements - Google Patents

Description

Storage and / or counting circuit with hysteresis storage elements electronic calculators and switchgear are different in the lines lying elements individually or in groups by impulses from the conductive to the blocked state or vice versa, reversed in each case. Such gates forming elements should only be permeable in one direction for certain tasks. For this Purpose it is already known to use germanium diodes or silicon diodes, whose direction of transmission is not influenced by the pulses. Just these diodes have so far for the control at high speed, z. B. by impulses of a microsecond duration has been found to be suitable. However, these diodes are very expensive.

The invention is based on the object of the gate circuit current branches to build a memory and / or counting circuit with elements in which none Diodes need to be used and are still running at high speed or short pulses can be controlled.

This task is carried out with a memory and / or counting circuit Hysteresis storage elements that have gate circuit branches, their conductivity is reversed by impulses, especially for use in electronic computing systems, solved according to the invention in that the gate circuit branches from windings exist, which are each arranged on associated storage magnetic cores and such in series with ferroelectric capacitors are that the cores through this Storage pulses supplied to series circles in their respective other magnetization state are switchable, and that the cores have additional windings that so on The ferroelectric capacitors are coupled to that switching circuits the polarization state of the ferroelectric capacitors through control pulses are formed.

In the circuit according to the invention, ferroelectric are known per se Capacitors used. Although it has already been proposed such capacitors to connect in parallel with the load and to control these capacitors in such a way that the pulses of a certain polarity applied to the input source by a pulse source and amplitude of the ferroelectric capacitors with respect to their polarity state tilt. In this case, the input pulses bypass the load. at the circuit according to the invention, however, the ferroelectric capacitors interconnected with storage magnetic cores in such a way that the supplied storage pulses either the magnetic cores or the capacitors or both elements are tilted.

Contains an embodiment of the circuit arrangement according to the invention two magnetic cores or a whole multiple of two magnetic cores, and each core is apart from one winding in the gate circuit branch with at least one further winding provided in such a way that a current branching of the capacitor displacement current via the winding in the gate circuit branch and the other winding comes about.

Another embodiment of the circuit arrangement according to the invention contains three magnetic cores or a multiple of three magnetic cores, each of which has oppositely wound windings forming two gate circuit branches, and the two windings of the cores are connected in series; Here, one winding of one core is connected in series with one winding of the next core, and the connection point is connected to one plate of a ferroelectric capacitor.

In these two circuit arrangements, a winding of one core can be coupled to a winding of the other core; In this case, one of the plates of two ferroelectric capacitors are connected to the connection points, and a ferroelectric capacitor is connected in parallel to each of the other two windings.

For a better understanding of the invention, some are given below basic properties of magnetic cores and capacitors regarding their hysteresis properties are given.

In FIGS. La and lb, hysteresis loops are shown which describe the magnetic properties of an iron core or the electrical properties of a capacitor. FIG. 1 a shows a rectangular hysteresis loop, FIG. 1 b a normal hysteresis loop. For a magnetic none, the x-axis shows the magnetic field F) and the y-axis shows the magnetic induction e3. When depicting the properties of a capacitor, the x-axis indicates the electric field that is applied to the dielectric between the two capacitor plates, while the y-axis shows the electrical displacement of the dielectric. Each point on the hysteresis loop indicates the state of the dielectric or the magnetic core, which corresponds to the applied electric or magnetic field. The dielectric constant of the dielectric or the permeability of the magnetic core can be taken from the steepness of the hysteresis loop.

If there is no electric field on the dielectric or no magnetic field on the none, the state of the dielectric or the core is given by the points S and T on the rectangular hysteresis loop. The state of the dielectric or the magnetic core with an externally applied field strength h can be seen from FIG. 1 b. This state is indicated by points H and K.

It is first assumed that a magnetic core in the state shown by the point b S in Fig. 1 is located. If a positive pulse is now applied to the winding of the core, the magnetization state only changes between points S and U. Since the permeability of the core is very low in this area, the impedance of the winding arranged on the none is also low. There is therefore only a slight resistance to the pulse current. If a negative impulse is now applied to the winding, with which a negative magnetizing force is generated, the state of the core changes according to curve p from point S to point V. The permeability of the core and thus the impedance of the winding are in this Case very big. For the negative momentum, i. H. for the pulse current in the opposite direction there is " a high resistance. After the negative pulse has passed through, the state of the core is established according to point T. The conductivity direction of the core has therefore reversed. If the core is in the state given by point T. a negative, newly arriving pulse is opposed to only a slight resistance, while a positive pulse is almost blocked.

The conditions are similar in the case of a none with a hysteresis loop according to FIG. 1 b. However, since the steepness of the curve is less here, in the event that the core has a state close to point K, the current is opposed to a relatively high resistance in both directions. If, therefore, a magnetic core with a premagnetization according to FIG. 1b is used, the resistance of the winding lying on the none is low, while at point K it is high. A strong positive impulse does not change the direction of polarization, but the state of the nucleus changes due to a strong negative impulse, in which the point K is given. If the none is in this state, a small pulse current is blocked regardless of its direction. The state corresponding to point H is reached again by a strong positive impulse.

Let us now consider the case that the two hysteresis loops shown describe the state of a dielectric of a capacitor. On the abscissa is the electric field and the ordinate shows the electric displacement.

The reversal pulses cause a new bound charge on one plate of the capacitor, while the previously existing bound charge is removed from the other plate. If there is no reversal of the polarization state, there is only a slight change in the bound charge, so that a great resistance is opposed to the pulsating current. The size of a current sufficient to reverse the polarization direction depends on the impedance of the capacitor. Since this impedance is inversely related to the dielectric constant of the dielectric, the resistance of the circuit is lower, the steeper the hysteresis loop. In contrast, the resistance is high in the areas of the low gradient of the hysteresis loop. The shift in the polarization state produced by an externally applied electric field takes place analogously to the change in the magnetization state of a magnetic core, as described above.

In a capacitor having from Fig. 1 a Hysteresiseigenschaften apparent, therefore, a positive current is opposed by a large resistance when the dielectric is in a state corresponding to point S. A negative pulse reverses the direction of polarization to the state of point T. The resistance to the impulse, which affects the electric field in a negative sense, is high.

In one provided with an electrical bias capacitor, which therefore receives an electric Vorfe.ld (corresponding to the pre-magnetization of a magnetic core), and which is characterized by a hysteresis loop b as shown in FIG. 1, the conditions are similar. When the dielectric has a state corresponding to point H, a small pulse current is always met with a large resistance regardless of the direction of the electric field. In this state, a large positive pulse current does not change the polarization state. In contrast, the polarization state of the dielectric changes due to a strong negative pulse to that of point K. In this state, the dielectric presents only a low resistance, regardless of the direction of a small applied pulse. A strong negative impulse does not change the polarization in this state. On the other hand, the state is shifted to that of point H by a strong positive impulse.

The capacitors, which have such a hysteresis property, may be used in conjunction with magnetic cores, which also have hysteresis properties have, as elements in gate circuits for use in memory and the like Tasks used in electronic computing systems.

The invention will now be illustrated with reference to several in the drawings Embodiments explained in more detail.

In the exemplary embodiment according to FIG. 2, the points P, R and Q, R each form a pair of clamps. The capacitors C 1 and C 1 have dielectrics with the hysteresis properties described above. The two magnetic cores M and M also have corresponding hysteresis properties. The circuits between the terminal P and one plate each of the capacitors Cl, C, are marked with al and a. designated. In each of these circuits there is a winding of the magnetic cells M, and M2. Another current circuit is formed between the upper plate of the capacitor Ci and the Q terminal via a respective further winding of No M, and M, pl. In addition, a circuit fl 1 is formed from the upper plate of the capacitor C2 via a further winding each of the no M 2 and Mi to the Q terminal. The winding part and i2 surrounded by the dashed lines form the actual gate circuits.

It is assumed that the capacitors C 1 and C 2 with respect to their dielectrics have a rectangular hysteresis loop corresponding to FIG. 1 a and are in the state of the point S. The upper plates of the capacitors Ci and C2 should be negatively charged, the lower plates positively charged, so that the polarization direction between PR and QR is positive. The two magnetic cores are in this example a hysteresis loop of FIG. 1 having b. If the No Mi is in the state of point H and the No M 2 is in the state of point K - i. H. that the two cores are premagnetized according to the size h - then the impedance of the gate il is low and that of the gate i 2 is large. If a positive pulse is now applied to terminals P, R , the current essentially only flows through circuit a, in accordance with the principle already explained and changes the direction of polarization of capacitor C, 1. The dielectric of this capacitor is therefore in the state corresponding to Point T offset.

If a negative pulse is now applied to terminals Q, R , the displacement current cannot flow through capacitor C. "but only through capacitor Ci, so that the state of its dielectric returns to that corresponding to point S. The The negative pulse also generates a current in the direction RQ in the circuit ßl. The direction of winding of the two windings of the none M and M2 in the circuit ß, is chosen so that the current flowing from the terminal R to the terminal Q in the core Mi has a positive direction of magnetization and in no M 2 has a negative direction of magnetization. This current therefore reverses the directions of polarization of gates i1 and i, so that the state of core Mi corresponding to point K and that of core M corresponding to point H on the hysteresis loop The impedance of port i, is therefore now high, while that of port il, is low. The next positive pulse arriving at terminal P generates d A rather a current in the circuit a, 'This reverses the polarization direction of the capacitor C2. If a positive pulse is now applied to terminal R, it generates a current in circuit ß2. This reverses the direction of polarization of the two gates.

Due to the pulses applied to terminals Q, R, the polarization direction of ports il, i 2 is reversed in this circuit, so that the current generated by the positive pulses applied to terminals P, R depends on the number of positive pulses applied to terminals Q, R applied negative pulses either via the gate il or via the gate i 2. This circuit can therefore be used very well as a storage element in electronic computing systems without the need for diodes.

In Fig. 3 , a further embodiment of the invention is shown. The toroidal cores M, M, M each have two windings i1, j and i 21 j and i ″, j3 wound in opposite directions to one another. The directions of polarization of windings i and i therefore also run in opposite directions j "positive polarization direction" is intended to mean the state of the core at point S according to FIG. 1 a, while "negative polarization direction" is intended to mean the state according to point T.

In this sense, the gate i, is polarized positively (state S), while the gate il is polarized negatively (state T). The gates i. and i 3 are each negatively polarized (state T), while gates j, and j. are each positively polarized (state S). The charge of the capacitors C, Dli C21 D21 C 3 and D 3 is chosen such that the lower plates are each positively charged, the upper plates are each negatively charged. A positive pulse applied to the terminals X, Z generates a current through the circles x, b, the polarization directions of the capacitors C, and Di are reversed.

If a negative pulse is now applied to the terminals X, Z , the polarizations of the capacitors C, 'D, are restored to their original position. The pulse generates a current through the circles y, and el. The polarization directions of the gates j, and '2 are therefore reversed. Only a small pulse current finds a great resistance. However, if the pulse voltage is high, it generates a current through the ports j and i, and this current reverses the direction of polarization of these ports. The direction of polarization of the gate i has thus returned to the starting position. After the passage of the second pulse, all dielectrics of the capacitors are positively polarized, while the gate i2 is negatively polarized.

If a further positive pulse is now applied to terminals X, Z , it generates a pulse current through circles x2, b2. The capacitors C, D2 are therefore polarized negatively. Another negative pulse at the terminals Y, Z reverses the polarization directions of the capacitors C2, D2 again. A pulse current flows through the circles y., E21 and the gates i, i, are positively polarized. At this moment only gate i3 of the j-ports is negatively polarized. If a further positive pulse is now applied to the terminals X, Z , then a pulse current only flows through the circles x., B., And this polarizes the capacitors C., D, negatively again. The next negative pulse at terminals Y, Z causes the capacitors C., D. to polarize positively, and a pulse current flows, after which the initial polarization is reached again.

The alternating arrival of positive and negative pulses at terminals X, Z or Y, Z therefore causes the j-ports to be reversed in polarity one after the other. In this way, a calculation or other program control can be carried out without the need to use diodes for this purpose.

In Fig. 4, a further embodiment of the invention is shown. In this exemplary embodiment, capacitors with a hysteresis loop according to FIG. 1 a are used, while the two magnetic none have no pronounced hysteresis loop. As can be seen from the circuit, the two none are coupled to each other. The capacitors are positively polarized, i. that is, their top plates are negatively charged and the bottom plates are positively charged. The winding direction of the windings attached to the cores is selected such that the current flowing in the same direction via the circles a1, ß2 and a2, ß, generates a voltage in the same direction in the lines 11, y coupled to the capacitors Tj, T,. induced.

If the capacitors T, or T2 are positively polarized, a pulse current flows through the lines a1, ß, or a21 ßl, which are coupled by the circuit M "M2 . If the output pulse is positive, it reverses the polarization directions, while the negative one Pulse is almost blocked. If the capacitors Ti or T, are negatively polarized, the pulse current flows through the lines al, ß, and a., Ssl, which are also coupled to one another via the none. With a positive output pulse, the corresponding polarization direction is reversed, If the capacitors C1, C2 and T, are positively polarized while the capacitor T2 is negatively polarized, then a positive output pulse flowing over the line a2 is blocked because the capacitor T2 is negatively polarized. This current can therefore only flow through the circuit al, the capacitors T 1 and C 2 reversing their polarity.

If a negative pulse is now applied to the terminals Q, R , no current can flow via the line β, since the capacitor C2 is positively polarized. The pulse current flows only via the line ßl, the capacitors C, and T2 are polarized. The change in polarization generated by the pulses at the capacitors C1, C29, Ti and T2 enables this circuit to be used for test purposes. In this exemplary embodiment, the change in the current distribution between the circuits is only achieved by changing the polarization of the capacitors.

In Fig. 5 , a further embodiment of the invention is shown. The coils Nl, N2 and N ″ serve as chokes.

It is assumed that the capacitors Cp c23 C, and T, are polarized positively and the capacitors T2 and T3 are negatively polarized and further that the first pulse applied to the terminals P, R is positive and that the pair of terminals Q, R is in the open state.

In this case, the current generated by the positive pulse causes repolarization of the capacitors T, and Cl, so that they are now negatively polarized. This current flows only through the circle al and is in the circles a2 and a. locked. A negative pulse is now applied to terminals Q, R while the pair of terminals P, R is in the open state. The capacitors C2 and C3 are positively polarized and the current generated by the pulse cannot flow in the lines b2 and e3. The throttling effect of the coils N2 and N3 prevents a current in the lines fl., Fl3.

The negative pulse therefore generates a current which branches off via the capacitor Ci and the line Bi and via the line Ei. Since the lines bi and ei lead over oppositely wound windings of the core Ni, the throttling effect of the core N is canceled.

The two pulse currents flowing via lines bi and ei therefore add up in line ßl. As a result of this current flow, the polarization direction of the capacitors C1, T, is reversed so that they are now polarized positively. The capacitors C1, C23, C, and T2 are now positively polarized, while the capacitors T, and T, are negatively polarized.

The next positive pulse applied to the terminals P, R generates a current via the line a21 whereby the polarization direction of the capacitors C2, T2 is reversed so that they are now negatively polarized.

The next negative pulse at the open pair of terminals P, R generates a current through the circuits b2, e2, these currents adding up in the line fl. As a result, the capacitors C2 and T are repolarized again. At this moment the capacitors C., C29, C3 and T, are positively polarized, while the capacitors Ti and T2 are negatively polarized.

When a further positive pulse is supplied to the terminals P, R, which are open for the passage of current, a current is generated via the line a3, and the polarization of the capacitors C3, T3 is reversed so that they are now negatively polarized.

If a negative pulse now arrives at terminals P, R, these terminals being permeable to the current, a corresponding pulse current flows only via line b., E3 into line fl3 and into terminal P. The capacitors Cl, C2 and C, are thereby positively polarized. After this pulse has passed, the initial state is reached again. In this circuit, the currents generated by the pulses are routed over the next line in the order in which the pulses arrive. This circuit is therefore to be used for image scanning and storage purposes.

For another purpose it is now assumed that the polarization direction of the capacitors C1, C29, C33 Ti and T2 is positive, that of the capacitor T is negative. The section between the pair of terminals Q, R is in the open state. If a positive pulse arrives at the terminals P, R , the current generated by this flows through the circles a1, β, 'since the circuit u3 is blocked by the negatively polarized capacitor T i. The over line a, the current flowing causes repolarization of the capacitor C "during the repolarized the capacitor C2 through the line a, the current flowing. At the same time, the polarization direction changes on the capacitors T, and T2. These capacitors are therefore negatively polarized. Now, a negative pulse is applied to the terminals Q, R , while there is continuity between the terminals P, R. The current cannot flow via the lines b, e 3 because the capacitor C 3 is positively polarized Lines b " e, β, and lines b" e 21 β2-The capacitors C " C_ T, and Tl, are positively polarized by these currents. At this moment only the capacitor T, is negatively polarized.

The next positive pulse at the terminals P, R generates a current via the lines a, U. ', and reverses the polarization of the capacitors T2, C2, T3 # C , so that they are now negatively polarized. The next negative pulse applied to the terminals Q, R generates two currents, namely via b31 e21 # 2 and via b3, e " ß .. As a result, the codensators C 2e C 3e T3 and T, are positively polarized only the capacitor T, polarized negatively.

With the next positive pulse at the terminals P, R , a current is sent over the lines a ',' al, the polarization direction of the capacitors T 3 # C3 'Ti, C, becoming negative. The next negative pulse at the terminals Q, R generates two currents via the lines b. ' e,. "and the lines bl, e, ß, Now only the capacitor T3 is negatively polarized. The current is thus shifted to the next line via two positively polarized capacitors with each pulse. This circuit is suitable for sampling and computing - and storage purposes.

In Fig. 6 , a further embodiment of the invention is shown. The capacitors Ap A2 and Ti are positively polarized, while the capacitor T i is negatively polarized.

If a positive pulse is applied to the terminals P, R , no current can flow over the line a 2 because the capacitor T 1 is negatively polarized. The current therefore flows via the lines a1 and sj, so that the capacitors T, 'Al are negatively polarized as a result.

If a negative impulse now arrives at the terminals Q, R , then due to the positive polarization of the capacitor A, a current flows through the line, and ß .. The polarization directions of the capacitor A coupled with the No L, and the with the capacitor T i coupled to no M 2 are reversed so that they are now positive. The capacitors A 1, A 2 and T are positive at this moment. The condenser T i is negatively polarized.

The polarization directions of the capacitors T, and T, have become in other words, the opposite of the initial state.

When a further positive pulse arrives at the terminals P, R , a current will flow via the line a 2 and s 2, since the capacitor Ti is negatively polarized. The polarization direction of the capacitors T. " A, is therefore reversed so that it is now negative. When a further negative pulse arrives at the terminals Q, R , a current is generated via the lines s., And #. The capacitors A_ T , are thereby positively polarized. thus, the initial state is again reached. After every two pulses, therefore, the polarization direction of the capacitor T 'T, replaced. the circuit can therefore be used for dyadic operations.

In each of the exemplary embodiments described, two pairs of clamps were used. However, it is also possible to set up circuits with several pairs of terminals, with each pair of terminals being supplied with specific pulses.

The impulses can also be transmitted through vacuum tubes. Of the The internal resistance of a tube is high due to the change in its grid tension good to influence. The on a pair of terminals of the circuits according to the invention Giving impulses can be generated by tubes. The internal resistance of the tube can be increased significantly if connected to the second pair of terminals and this pair of terminals is held in the open impedance state.

By connecting several of the circuits according to the invention in parallel a common pair of output terminals can be connected to the same tube. In this case, only a few tubes are required for a large number of lines.

In the exemplary embodiments described, it was assumed that the two pairs of clamps are each supplied with two different series of pulses. These pulse series can, however, also be dependent on one another in the sense that the second pulse series is derived from the first pulse series by differentiation.

Claims (2)

PATENT CLAIMS: 1. Storage and / or counting circuit with hysteresis storage elements which have gate circuit branches whose conductivity is reversed by pulses, in particular for electronic computing systems, characterized in that the gate circuit branches (e.g. i, i, ) consist of windings which are each arranged on associated storage magnetic cores (e.g. MI 'MJ and are in series with ferroelectric capacitors (e.g. Cl' CI) in such a way that the none through these series circles (e.g. il , C ,; i2, CJ supplied storage pulses (e.g. at P, R) can be switched into their respective other magnetization state, and that the cores have further windings which are coupled to the ferroelectric capacitors so that circuits for switching the polarization state the ferroelectric capacitors are formed by control pulses (e.g. Q, R) . 2. Circuit arrangement according to claim 1, characterized in that it contains two magnetic cores or a whole multiple of two magnetic cores and that each core except for a winding located in the gate circuit branch is provided with at least one further winding such that a current branching of the capacitor displacement current via the The winding located in the gate circuit branch and the further winding is made (Fig. 2). 3. Circuit arrangement according to claim 1, characterized in that it contains three magnetic cores or a multiple of three magnetic cores which each carry two gate circuit current branches forming oppositely wound windings, that the two windings of the none are connected in series, and that each one winding of a core is connected in series with a winding of the next core and the connection point is connected to one plate of a ferroelectric capacitor (e.g. DJ (Fig. 3). 4. Circuit arrangement according to Claims 1 and 2, characterized in that one winding of a core with a winding of the other core is coupled to the one plates of two ferroelectric capacitors are connected to the connection points, and that the other two windings each a ferroelectric capacitor is connected in parallel (Fig. 4). 5. a circuit arrangement as claimed in claims 1 , 3 and 4, characterized in that at the connection points de The ferroelectric capacitors connected to the windings, chokes with bifilar windings are connected in parallel, the connection point of the bifilar windings being connected to a tap of the interconnected windings of the none (Fig. 5). Older patents considered: German Patent No. 1038 601.