DE1172881B - Logical element and circuit made up of logical elements - Google Patents

Description

Logical element and circuit made up of logical elements The invention relates to logic elements with magnetic cores and from these elements built-in circuits for performing logical operations. Logical elements generally consist of at least one magnetic core with a rectangular hysteresis loop, on one primary winding for writing a binary input pulse, one Secondary winding to form a readout pulse and a tertiary winding with diode connected in parallel to transmit the readout pulse to a subsequent one Element are wound.

For the proper operation of a logical element with only one Magnetic core is a prerequisite that the characteristic of the core is exactly the rectangular shape corresponds to what is known to cause great difficulties in practice. Further Difficulties arise from the fact that the to be connected to the pulse source Load impedance changes with the respective operating state of the magnetic core, what the supply of a suitable pulsed current to operate the element is very difficult.

Logical elements with two magnetic cores have the advantage over this that minor deviations of the core characteristics from the ideal rectangular shape are of lesser importance, but these elements show other serious ones Disadvantage. Since the writing process is only carried out by means of an input information signal takes place, its intensity must be very high. Accordingly, there is always the risk that incomplete writing processes take place, and it is hardly possible to get an output signal with constant intensity. For these reasons, the entry page can also be used no independent logical operation is performed on such a logical element but only in combination with the output side, which means that a complex, a circle consisting of a large number of elements is made considerably more difficult. Further it is not possible to connect several branch circuits because the energy of the output information signal derived from a single logic element is limited. Ultimately, it is the speed of operation of such elements low, since the switching of the respective states of the residual magnetism of both cores takes place only by means of the input signals.

The aim of the invention is to overcome these difficulties and to create a logical element that works even with weak input information ensures a complete write-in operation and output signals more constant Emits intensity. The output intensity should be so great that a large number can be connected by branch lines. A further aim of the invention is to train the logical element in such a way that it is independent of the logical operation the output side can perform a variety of logical operations.

The logical element should ultimately be expandable to logical circles which have no links other than magnetic cores, windings and gate switching elements have and have a high speed of operation.

The invention is based on a logic element with two magnetic cores, a write-in circle, a reset circle and a read-out circle, and draws is characterized by the fact that in addition a write-in bias circuit made up of two coils connected in series, wound on the cores, and a second inscription circuit, which also consists of two coils connected in series and wound on the cores, are provided. The bias circuit generates write-in information when it arrives a magnetic force of about the same size, but in the opposite direction as the reset circuit, through which Intensive output signals can be generated even with the weakest input signals, while the second registered circle with the arrival of an input information with a constant pulse current is fed, the amplitude of which is an odd multiple corresponds to half the amplitude of the write-in information, which makes it possible is to perform logical operations in the element that are independent of its output side.

The gates can consist of non-linear rectifiers. To Another development of the invention, however, can also include the gates from transformers with cores of a substantially rectangular characteristic, the secondary turns of which are switched on in the readout circuit and their primary windings from a bias current are flowed through, except during the duration of the desired readout pulses causes a high impedance opposite to the current in the readout circuit.

The read-out coils are expedient in a manner known per se in the winding direction of the registered reels wound.

For the transfer of a variable with the help of a logical The circle of two elements according to the invention are advantageously the recording coils of the second element and the end clamps of the first element opposite to the direction of flow of the constant pulse current of the second element connected to one another.

A logic circle of three elements according to the invention is expedient designed in such a way that the third element is provided with two inscription circles one of which is in a positive direction than one of the two load impedances of the first Elements and their other in the negative direction as one of the two load impedances of the second element is used, the constant pulse current of the third element is positive for the "or" link and negative for the "and" link.

Further advantages and details of the invention, in particular as well the combination of elements according to the invention to form logical circles result from the description, the drawing and the claims. There are some in the drawing Embodiments of the invention shown by way of example, namely show A b b. 1. a, 1 b and 1 c circuit diagrams of three different embodiments of the invention, A b b. 2 a is a block diagram to explain the circuit arrangements of A b b. 1, A b b. 2b timer pulse trains for the circuit arrangements according to the invention, A b b. 3 Hysteresis characteristics of magnetic cores as used in the invention are, A b b. 4 is a graph showing the relationship between the amplitude of the readout pulse and the number of branches, A b b. 5 a graphic Representation of experimentally found values that show the relationship between the readout signal and the resulting write-in amplitude shows A b b. 6, 7, 10, 12 a and 13 further embodiments of the invention.

A b b. 8 a, 8 b, 9 a, 9 b. 11, 12 b, 14 a and 14 b are symbolic circuit diagrams for the respective explanation of the embodiments according to A b b. 6, 7, 10, 12 a and 1.3, A b b. 15, 16 and 17a three further embodiments of the invention.

A b b. 17b schematically shows the circuit according to Fig. 17a, A b b. 17c a symbolic representation to explain the circuit according to A b b. 17 a.

A b b. 18 shows a representation of the link according to a further exemplary embodiment of the invention, A b b. 19, 20a and 21 three further embodiments of the invention.

A b b. 20b shows a symbolic representation of the circuit of A b b. 20th a and A b b. 22 a characteristic of a "reverse diode". According to A b b. 1 a are on the magnetic cores Ml and M. "each of which has a rectangular hysteresis characteristic according to A b b. 3, wound: 1. Inscribed windings Ni, N2 and N .; for the supply of a write-in signal in pulse form from any preceding one Stage, 2. another registered winding N ,. for feeding a constant Pulse current, 3. a write-in bias winding W for the feed a bias current that supports the writing process, 4. a reset winding S for the supply of a reset pulse current that the State of each magnetic core in its original state before the writing process returns, and 5. a readout winding N, for reading out the magnetic cores to the Point in time when a readout pulse stream 1 is applied to this winding during the readout period got.

The registered windings N1, N., and N .; (first registered circle), the constant signal winding N ,. (second registered circle) and the elite winding No are wound on the two magnetic cores Ml and M., each in the same direction. while the bias winding W and also the reset winding S in each are wound on the two cores in the opposite direction. On the coils of the Readout winding N, gate switching elements (gates) G1 and G., connected and at these load impedances Z1 and Z.,. Terminals X and X interpose the readout current the gates and the load impedances.

In this circuit, a bias current is applied to the magnetic gate element supplied simultaneously with the arrival of a write-in bias current, creating a high impedance to the current flowing in the output winding is obtained.

In A b b. 1 c is another embodiment shown in which rectifier elements, such as B. diodes are used as gates. If in this case a write-in bias current is supplied, the circuit consisting of the output winding takes one high impedance in accordance with a non-linear characteristic of the rectifier elements, on the other hand, however, a low impedance when a readout current Ir is supplied. In the Circuits according to A b b. 1 a, 1 b and 1 c are the impedances of the input winding the next stage represented by Z1 and Z.

A b b. 2 a shows a schematic representation of the structure of the circuit arrangement according to A b b. 1. That System is divided into two groups, those of two timer phases can be switched cyclically. E: it is assumed that the Circuit is initially in a first phase. At time t1, a reset pulse current becomes IS, the amplitude of which is large enough to put the magnetic core in the state of B, in the larger hysteresis loop of A b b. 3, fed to the winding S, which brings the magnetic cores M1 and M2 into the states of -B and + B. These In the following, states are to be designated with (-) and (+).

Then at time t .. a bias pulse current I ", with a Amplitude, which is a magnetization corresponding to the coercive force of the magnetic core causes, fed to the winding W, whereby in the magnetic cores M, and M2, respectively Magnetic forces + H, and -H, are induced.

Simultaneously with the impressing the bias current I ", the coil W N2 and N3 Einschreibesignale be applied to the input windings Ni, given and furthermore, the winding N, a constant pulse signal I, imprinted. Polarity and amplitude of the pulse signal 1, thereby, as later in described individually, selected according to the logical operation to be carried out in the input side.

If the resulting signal of the logics at the input stage is positive and corresponds to +11, the effective pulse current supplied to the magnetic core M1 becomes (+ 1l +1 ",), whereby the magnetic core M1 comes to the state of + B, (to the point c in A b b. 3).

Further, the effective pulse current, which the magnetic core M2 is supplied, so that the state of the magnetic core M2 is not changed to (-f-11-I ") and in the state + B remains (point b in A b b . 3).

In the case assumed above, both magnetic cores are M1 and M2 in the (+) state.

However, if the resulting signal of the logics at the input stage is negative and corresponds to -11, the pulse current supplied to the magnetic core becomes M1 to (-11 +1 ",) and the pulse current supplied to the magnetic core M., to (-Il -I",), whereby the state of the magnetic core M2 in that of the point d in A b b. 3 changed will. In this case, both magnetic cores M1 and M2 are then in the (-) state. As above described, the resulting signal of the logics at the input stage is fed into the Circuit written and the write signal in the magnetic cores to the next Readout period saved.

When the readout pulse stream is 1, at time t. of the output winding No. is supplied, the impedance of one of the wound on the magnetic cores M1 and M. Output windings compared to the current I, a high impedance, the impedance of the other coil, however, decreases according to the core states.

If, for example, the states of the two magnetic cores are (+) and a readout pulse current I, is supplied, this current I, is divided into two currents II and I2, as shown in A b b. 1 is shown. The core M1 can only be brought by a current 1i from a magnetic state corresponding to point c of its hysteresis loop to point e (A b b. 3), the latter point corresponding to a low core impedance. In contrast, the current 12 brings the core M2 from the state corresponding to point b of its hysteresis loop to point f (Ab b. 3), whereby the core assumes a high impedance. After the supply of the read-out pulse 5 current 1, the state of the magnetic core M reaches point g in A b b. 3. As a result, most of the readout pulse current I is current 11, and current 12 is much smaller than current II.

On the other hand, if both magnetic cores M1 and M2 are in the state (-), the output winding of core M1 takes a high impedance to the readout current 1, on and the output winding of the core M., a low, making the largest Part of stream 1, as stream 12 flows.

As described above, the high impedance assuming magnetic core maintains its high impedance during the readout operation and becomes in its state corresponding to approximately the point f in A b b. 3 recorded. Point f depends on the load and tends to move sequentially to points fa, fb, f c , etc. as the load decreases, as shown in A b b. 3 is shown. However, the field impressed on the core by the change in point f is essentially constant, so that the output current is kept at a constant value. The change in the readout signal as a result of a change in the load shows a very favorable constant characteristic, as can be seen from the experimental result according to A b b. 4 results, the readout signal having a waveform which corresponds completely to that of the timer pulse stream.

The results according to A b b. 4 and 5 have been obtained for the case that the following windings and cores have been used: Ni = 3 turns N, = 3 turns W = 1 turn S = 1 turn Nu = 45 turns The ferrite core has an outer diameter of 2 mm , an inner diameter of 1.2 mm and a height of 0.6 mm. As a result, the waveform of the output current II is very favorable and corresponds approximately to that of the timer pulse current.

Since the timer pulse stream is supplied by a pulse source, which can reach a constant amplitude, the output current (readout current) the circuit fully amplified and limited. These output currents 1i and I2 are sent to the input circuit of the next stage as input signals (write-in signals) fed. Because in this way, as described above, the input signal as corrected constant pulse current is supplied, the effect of the binary pulse current is very strong favorable, thereby a complete storage of the information signal in the core state is made possible. This also follows from the experimental result of A b b. 5 even in the case when an input signal with a smaller value is used whereby an amplified and limited output signal can be obtained.

If exactly the same reset current IS is fed to the reset winding S at the time t ¢ as at the time t1, the state of the magnetic core M1 is brought to point a (Ab b. 3) and that of the magnetic core M.2 from point g to the Point b, whereby both cores are returned to their initial states. With this, the operation is repeated in the same manner as described above.

The current in the read-out circuit can be controlled by means of diodes during the write-in period can be suppressed as already described. However, it is also possible to use the electricity in the readout circuit by the internal impedance of the power source.

Due to the special properties of the circuit arrangement according to A b b. 1 the following advantages are achieved: 1. Despite changing the load impedance is always a precisely defined one due to the partial switching of the high impedance Get output signal current.

2. The reset current 1, the circuit can be in its initial Return state every time the readout period has expired, whereby safe, high-speed operation is ensured.

3. There are no switching elements other than magnetic cores and gate elements necessary.

4. The bias write-in pulse current I "increases at the complete storage of the input information signal in the magnetic core part.

5. It is possible to have many branches. 6. As the enrollment period is separated from the readout period, the logics at the input stage and formed independently of the output stage.

7. The desired combination of logics both at the input than at the output stage is exactly achievable. With the help of the winding N, the a constant signal of an amplitude equal to an odd multiple of half the information amplitude is impressed, it is possible to have both odd and even combinations of input information signals. In addition, the possibility created to perform various types of logical operations. As examples cases are described below in which the amplitude of the constant Signal according to the one-half or. three-half times the amplitude of the input information signals is equivalent to. That by writing the information signals into the cores themselves resulting core - residual magnetism - receives the correct, positive or negative Polarity, independent of the polarity and the respective combination of the information input signals.

As a result of the above-mentioned favorable characteristic, the inventive Switching arrangement with a high speed and reliability any complicated logical operation not only on the input stage but also on the output stage carry out.

A b b. 6 shows a circuit in which a single transmission of the information signal is carried out. In the circuit according to FIG. 6, one of the output terminals X of the switching element x is connected to the write-in winding Ni of the switching element y in the positive direction, and a constant signal current I, which is equal to half the amount of the signal current corresponding to the binary information "1", is applied to the winding N ,. of the element y fed in the negative direction. If the information in element x corresponds to "1" in binary notation, the output current 1i is received at terminal X. This has the consequence that a positive input signal reaches the element y, and an output signal is produced at the output terminal Y of the element y.

If, on the other hand, the information in element x corresponds to the number "0" in binary notation, no output signal stream appears at terminal X. As a result, a negative pulse signal is applied to element y, so that no output signal is output at terminal Y. of the element y arises. These processes are shown in Table 1. Table 1 x 1 1 0 0 As can be seen from Table 1, a variable can thus be transferred. Another single transmission circuit is in A b b. 7 shown. In this circuit, the terminal X of the element x is connected to the input signal winding of the second element y in the negative direction, and the constant signal current h. becomes the constant current winding N ,. of the element y fed in the positive direction.

If element x receives a signal corresponding to "l" in binary notation, no output signal occurs at terminal T, but a positive input signal changes the state of element y, so that an output signal is obtained at terminals Y of element y.

On the other hand, if the element x has a signal corresponding to "0" in binary notation is supplied, an output signal appears at terminal X, and the negative input signal at element y does not change the state of element y, so that at terminal Y there is no Output signal is obtained.

These operations correspond to the logics in Table 1. The load impedances ZL. = In A b b. 6 and ZL i in A b b. 7 correspond to the input impedances of the following logical elements. These circuits according to A b b. 6 and 7 are symbolically in A b b. 8 a and 8 b are shown in which the large circles represent the elements should represent. A bold line running from left to right shows the Connection of an output terminal to the following input terminal; a little The circle denotes the terminals X of the element x and the short horizontal line on the connecting line the connection of the input terminal in the negative direction; (-) in the big circle denotes a constant current signal that is fed in the negative direction. and (-) in the large circle means a constant current signal, which in positive Direction is fed. In A b b. 9 a and 9 b is the arrangement of "no" circles shown. Furthermore, branches can be created by connecting the input windings in series many elements yi, y2,. .. y "of the output stage can be obtained as shown in A b b. 10 is shown. This is also symbolic in A b b. 11 shown.

While the previous description relates to the transmission of a variable, a logic circuit for two variables will be described below. A b b. 12a shows a logic circuit for two variables, and two for a logic sum. It is assumed that the input variables are x and y, for example. The input terminal X of one switching element x is connected to an input winding of the switching element z of the next stage in the positive direction, whereby + X is shown on the output side of the element z. On the other hand, the output terminal Y of the switching element y is connected to another input winding of the switching element z in the negative direction, whereby -Y is shown on the output side of said element z. Furthermore, a constant signal h ", which is equal to half of the output signal X, is fed to the constant input winding N in the positive direction, whereby + C is shown on the output side of the element z. These links, based on the connections at the input stage, can be represented by the following equation: Z = X-Y + C. (1) (1) If x = 0 and y = 0, X = 0 and Y = 1, then we get: Z = 0-1 + ' / 2 = - '/ 2, whereby the input signal of the element z becomes negative and its output signal corresponds to the binary digit "0".

(2) If x = 1 and y = 1, X = 1 and Y = 1, then : Z = 1-1 + 1/2 = + 1/2, whereby the input signal of the element z becomes positive and its output signal corresponds to the binary digit "l".

(3) If x = 0 and y = 1, X = 0 and Y = 0, then we get: - 0 + '/ 2 = +1/2.

This is the same case as in (2), so an output signal accordingly the binary digit "1" is given by the element z.

(4) If x = 1 and y = 1, X = 1 and Y = 0, then : Z = 1 - 0 + 1/2 = 3/2, whereby the input signal of this element z becomes positive and its output current is the Binary digit "1" corresponds.

The above logical operations are summed as shown in Table 2 below. Table 2 x Y z 0 0 0 1 0 1 0 1 1 1 1 1 The circle according to A b b. 12 a can according to A b b. 12 b can be represented symbolically. If in the logical circle according to A b b. 12 a, the constant signal current 1 is supplied in the negative direction, equation (1) changes as follows: Z = XYC. (2) The equation (2) represents a so-called logical product. Logical operations with two variables, which are represented by the equations (1) and (2), can be summed up as shown in Table 3: Table 3 Logics shortcuts of the input windings x + y X-Y + C .x + Y X-Y + C xy XYC .x. y XYC x Y XYC x. Y XYC x + 1 Y X-Y + C x + xy X-Y + C Furthermore, a logic circuit for three variables in connection with A b b. 13, in which three input signals x, y and z are fed to the input switching elements x, y and z, respectively. The output terminals X, Y and Z of the elements x, y and z are each connected to one of the input windings of the switching element F of the next stage in the positive direction or in the positive and negative direction, and the constant current I, is the constant current winding N, des Elements -Ü supplied in the negative direction, the current I ,, being selected so that it corresponds to an odd multiple of an output signal "1". This circuit can be represented by the following equation (3): U = X + YZC. (3) (1) When x = 0, y = 0 and z = 0, the output of the switching elements x, y and z becomes "0" and "1", respectively, whereby equation (3) is as follows: u = 0 + 0-1-1 / 2 = -3 / 2.

Accordingly, the Schalteleihent 17 is supplied with a negative input signal; whereby an output signal corresponding to the binary digit "0" is emitted from the element TI.

In the same way the following results are obtained: (2) If x = 1, y = 0 and z = 0 or X = 1, Y = 0, Z = 1, then u = 1 + 0 - 1 - 1 / 2 = -1/2.

(3) If x = 0, y = 1. and z = 0 or X = 0, Y = 1, Z = 1, then u = 0 + 1-1-1 / = - 1/2. In each of these cases (2) and (3), an output signal corresponding to the binary digit "0" is obtained from the element * U. The circuit according to A b b. 13 is symbolic by A b b. 14 a. A b b.13 and 14 show a logic operation circuit of the majority decision type and can be represented by the following logic equation (4): u = xyz + Xyz + xyz + xyz. (4) The above representations are summed up as shown in Table 4 below: Table 4 x 1 y 1 z 1 U xyz U 0 0 0 0 1 1 0 1 1 0 0 0 1 0 1 1 0 1 0 0 0 1 1 1 0 0 1 0 1 1 1 1 As another example for three variable input signals, the following link can be formed: u = X + Y-Z + C. (5) This case is symbolic in A b b. 14b and can be represented by the following equation (6): u = x + y + z. (6) The logical operation of this circle is summed as shown in Table 5 below: Table 5 xy .. 1t 0 0 0 0 1 0 0 1 0 1 0 1 0 0 1 1 1 1 0 1 1 0 1 1 0 1 1 1 1 1 I 1 If, as described above, three variable inputs are used, relatively complex logical operations can be achieved according to the invention by only a single element.

Some examples of the relationships between the logics and the connections of the input windings for the case that I ,. = Ih, is shown by Table 6: Table 6 Logics shortcuts of the input windings xyz XYZC zyz X -YZC xyz X -YZC xyz XYZC Xyz X -YZC xyz XYZC .xyz X -YZC x + y + z X + Y-Z + C z + y + z X + Y-Z + C x + y + z X + Y-Z + C Table 6 (continued) Logics shortcuts of the input windings x + y + z X A- Y-Z + C X + y + z X + Y - Z - # -C z + y + z XY-Z + C x + y + z X-, Y - Z + C X + y + z X-LIY-Z + C xyz + zyz + xyz-rxyz X + Y-ZC XY-Z + C xyz + Xyz + xyz + Xyz X-- Y- Z- C XY-Z + C xyz + xyz + xyz + xyz X - YZC XYZ + C xyz + xyz + xyz + xyz XYZC XY-Z + C zyz + Xyz + xyz + xyz X + YZC XY-Z + C Xyz + Xyz + xyz - @ Xyz XrYZC XY-Z + C xyz + xyz + xyz + xyz X + YZC XY-Z + C xyz + zyz + Xyz + xyz XA-YZC XY-Z + C When the constant current I ,. equal: ü '= is chosen, further logical operations can be obtained.

Obviously it is easily possible to do various logical operations for a system with four variables, five variables, and so on. Farther can by any choice of the current h. (Multiples of ';' z) the kinds of logical Operations are further enlarged.

As stated above, the individual elements must work exactly, to ensure complex logical operations. The accuracy of a logical Operation depends on the accuracy of the magnetic flux reversal in the magnetic cores of the switching elements. In order to achieve a high level of accuracy, the different switching currents have constant current characteristics. The absolute amount the currents at the last switching element must still be exactly the same as those at the first switching element, a phase deviation must not occur, and in particular it is necessary that the supply of the pulse currents I, and I ". at the same time as that of the other phase currents he follows.

Since each of the binary windings and reset windings only consists of one Coil and its impedances are low, interference does not occur, even then not if several hundreds of switching elements are connected in series. However, it is necessary that the impedance of the power source be high in order to maintain a constant To maintain current characteristics. For this reason, circuits are generally used used with vacuum tubes that have a grounded electrode.

The readout pulse current Ir can be branched off at the output terminal be distributed. For this purpose, a constant current of a power source can be higher Impedance consisting of a large number of switching elements connected in series Circle are fed. Such a system is shown in FIG. 15 shown in which Transformers T., and T4 are used to operate the divided circuit and to be able to supply the pulse current Ir. There is a self-bias circuit made up of a CR parallel circuit on each output side of the transformers exists so that the impedance on the power source side is opposite to the switching element side is high.

As in A b b. 16 shown, the constant current h. from the transformers T- and TB, as in the case of the supply of the pulse current 1 ". The winding ratio of the transformers is selected according to the required amplitude of the output current. The switching arrangement according to A b b. 16 is almost the same as that according to A b b. 15, with the exception of the fact that diodes D are used in place of the CR circuits: With the system according to Fig. 16 it is possible to feed a much larger number of switching elements with the constant current 1 than in that Case of the pulse current I "without diode attenuation occurring on the output sides of the switching elements.

As described above, the output windings take the magnetic cores Ml and M2 have high impedance or low impedance depending on the input signal. With in other words, the flow of the pulse current, I, through any one of the output windings corresponds to the establishment or interruption of a contact in a relay circuit. Furthermore, in the above system, the writing-in period and the reading-out period are completely independent of each other, a logical operation which is analogous that of a relay circuit can be obtained at the output stage, where this operation is completely independent of that at the input stage. A corresponding embodiment is shown in A b b. 17 a shown in which the diodes containing output windings divided and in accordance with the required Logics are connected appropriately. Since in this circuit an output signal at the Output terminal 1 is only obtained when x = 1, y = 1, forms this circuit a logical product. The circuit according to A b b. 17 a can be represented symbolically are controlled by a logic relay circuit as shown in A b b. 17 b or in A b b. 17c is shown. In A b b. 17 c, the double circle represents the logic of the output stage and the letter A denotes the "and" circuit.

One of the most effective logical links at the output stage is a fast working transformer in parallel addition. In a parallel adder, which can perform arithmetic operation at high speed is limited the transmission the speed of operation. To the speed limit many detector circuits have been investigated however, most of them are very intricate in construction and require a long display time.

In contrast, a high-speed transfer indicator circuit, which is constructed from the above-mentioned switching elements according to the invention, extremely easy and quick. This circle is shown in relay in A b b. 18 shown. The circuit connection of the output winding of a digit is in A. b b. 19 shown. The circuit implementation of A b b. 18 is based on the following arithmetic basics.

Let us first assume that the two numerical values G and H can be represented by the following equations: G = g02,0 + g121 +. g222 +. . . . + g121 + ... + gn2n. H = ho20 + h 21 + h222 + ... + hi2i + ... + 1.2n. In these equations, the letters gi and hi represent the binary digits "0" and "1", respectively.

The sum D of the values of G and H is represented by the following equation. D = d020 + d121 + d222 + .. # + di2i + ... + dn2n + dn + 12n + 1. In this case the following equation results: di = Ci-lgihi + Ci-1gihi + Ci-lgthi + c1-19174 In this equation, Ci-1 means a carry over from the lower digit.

For the carry c from the lower digit is: co = go ho .

cl = g1 hl + g1 ho + hie. .

ei = gi hl + gi ei -1 + hi ei _ i . en = gn hn + gn en _ 1 +% 2n en - i .

As in A b b. As shown in Fig. 3, the magnetic core has high impedance before Transition into the high impedance range an area of lower impedance (b-b, part in A b b. 3). Sometimes this area of lower impedance causes the core to be higher Impedance a disturbance in the logics at the output stage, because of this Current referring to a low impedance part reduces the effective output signal. In order to switch off this unfavorable current, a pre-magnetizing pulse current, whose amplitude corresponds exactly to that of the unfavorable current, during the Readout period of the bias pulse winding W supplied. Then can be complex Logics at the output stage have been carried out without interference. Like already mentioned before, the combined logics at the input and output stage are taken into account drawn.

A representation of the combined logics is in A b b. 20 a, wherein "and" logics are obtained on the output sides of the switching elements v and w and "or" logics are obtained on the output sides of the switching elements x and y . The result of this output logic is combined with the output of the switching element z, and this combined result is fed to the inputs of the switching element u, which forms an "and" operation of the three signals. In this case, the constant pulse current is selected to be 3 / a and is supplied in the negative direction. The symbolic representation of the circle according to A b b. 20 a is in A b b. 20b shown. The logical operation of the circle according to A b b. 20 a is listed in Table 7. Table 7 0 0 0 0 0 0 1 0 0 0 0 0 0 1 0 0 0 0 0 0 1 0 0 0 0 0 0 1 0 0 0 0 0 0 1 0 1 1 1 0 0 0 1 0 0 0 0 0 1 0 0 1 0 0 Table 7 (continued) _r yzu 1 0 0 0 1. 0 0 1 1 0 0 0 0 1 0 1 0 0 0 1 0 0 1 0 0 0 1 1 0 0 0 0 1 0 0 0 0 0 0 1 1 0 1 l 1 0 0 0 1 1 0 1 0 0 1 1 0 0 1 0 1 0 1 1 0 0 1 0 1 0 1 0 1 0 0 1 1 0 0 1 1. 1 0 0 0 1 0 0 1 0 0 1 0 1 1 0 0 0 1 1 1 0 1 1 1 1. 0 0 1 1 1 0 1 0 1 1. 0 1 l 1 1 0 1 1. 1 0 0 1 1 1 1 0 1 1 1 1 1 1 As can be seen from the preceding description, the most varied combinations of the logics at the input and output stages can be achieved, and the output signals of the switching elements become > A " or" 0 ", in accordance with the binary number" 1 "or" 0 ".

If "- # l" and "-1" signals are required, it is advantageous to to combine the switching elements in a manner as in A b b. 21 is shown. In A b b. 21, the output circuit consists of a bridge circuit and the output signals +1 and -1 are obtained at the To terminals. This circuit can be a logical one Perform operation at very high speed for a logical operation however, if the speed is still higher, the switching time of the magnetic material must be shorter be. For this purpose, thin magnetic material in film form can be used, in which case diodes with low attenuation are then required as gates, for example "Reverse diodes" with a characteristic according to A b b. 22nd

Claims (17)

Claims: 1. Logical element with two magnetic cores of essentially rectangular characteristics, a write-in circuit made up of at least one pair of series-connected coils wound on the cores, a reset circuit made up of two series-connected coils wound on the cores, one against and one against the cores other is wound in the winding direction of the write-in coils, a read-out circuit made up of two series-connected coils wound on the cores, two series-connected load impedances that are connected to the read-out coils via gates, and two end terminals that control the read-out current between the two read-out coils and the pick up both load impedances, characterized by an additional write-in bias circuit (W) consisting of two coils connected in series and wound on the cores (Ml, M2), which, when a write-in information arrives, generate a magnetic force of about the same magnitude, but in the opposite direction, like the coils of the reset circuit (S), and by a second write-in circuit (N,) consisting of two series-connected coils wound in the direction of the coils of the first write-in circuit (N1, N2, N3) on the cores (Ml, M.,) , which at the time (t.,) a constant pulse stream (1,) is impressed upon the arrival of input information, the amplitude of which corresponds to an odd multiple of half the amplitude of the written information. 2. Element according to claim 1, characterized in that that the gates consist of non-linear rectifiers (D "D.,). 3. Element according to Claim 1, characterized in that the gates consist of transformers (T1, T. which, except during the duration of the desired readout pulses, causes a high impedance that is opposite to the current in the readout circuit. 4. Element according to any one of claims 1 to 3, characterized in that that the read-out coils (N,) in a manner known per se in the winding direction of the write-in coils (NI, N, "N3) are wound. 5. Logical circle made up of two elements according to claim 4 for the transmission of a variable, characterized in that the recording coils (N1) of the second element (y) and the end clamps (X, X) of the first element (x) against the direction of flow of the constant pulse current (1,.) of the second element (y) are connected to each other. 6. Circuit according to claim 5, characterized in that for a link in a simple series connection, the direction of flow of the constant pulse current (1J of the second element (y) is selected such that the cores of the second element (y) have a positive residual magnetism Residual magnetism of the nuclei of the first element (x) corresponds to the binary number "1". 7. Circle according to claim 5, characterized in that for a "No" link the direction of flow of the constant pulse current (I,) of the second element (y) in such a way is chosen that the cores of the second element (y) have a negative residual magnetism exhibit when the residual magnetism of the nuclei of the first element (x) of the binary number "1" corresponds to. B. Logic circuit made up of three elements according to Claim 4 for the transmission of two variables, characterized in that the third element (z) has two inscribed circles . ) , one of which is used in the positive (NI, N I, direction as one of the two load impedances of the first element (x) and the other in the negative direction as one of the two load impedances of the second element (y), the constant pulse current ( IJ of the third element (z) is positive for the "or" link and negative for the "and" link. 9. Logical circuit of four elements according to claim 4 for the transmission of three variables, characterized in that the fourth element (u) is provided with three writing circles (N1, N2, Ns), one of which (N1) in the positive direction as one of the two load impedances of the first element (x), while the other two write-in circuits (N2, N3) serve in the negative direction as one of the two load impedances of the second (y) or third element (z), the constant pulse current (1J des fourth element (u) is selected for the "or" link in the positive direction and for the "and" link in the negative direction. 10. Logical circle of four elements according to claim 4 for the transmission of three variables with linkage according to a "majority decision", characterized in that the fourth element (u) is provided with three inscribed circles (N1, N2, N3) , with negative directed constant pulse current (1J of the third element (z) one of the write-in circuits (N3) in the negative direction as one of the two load impedances of the third element (z) and the other two write-in circuits (N1, N2) in the positive direction as one of the two load impedances of the first or second element (x, y) serve, while with a positively directed constant pulse current (1J of the third element (z) one of the write-in circuits (N3) in the positive direction as one of the two load impedances of the third element (z) and the other two Write-in circles (N1, N2) serve in the negative direction as one of the two load impedances of the first or second element (x, y). 11.Logical circle from a large number of items listed in Art elements switched by branch circuits according to claim 4, characterized in that, that in each case one write-in winding (N1) of all elements (y1 * i, * y,), with the exception of one Main element (x are connected in series and as one of the two load impedances of the main element (x). 12. Logical element according to one of claims 1 to 3, characterized in that the readout circle (N.) is split into two partial circles each of which includes a readout coil and a gate, the readout coils are wound opposite to the winding direction of the recording coils. 13. More logical Circle with a main element according to claim 4 and any number of secondary elements according to claim 12, characterized in that in each case one reading sub-circle of all Secondary elements connected in parallel with the readout circuit of the main element is. 14. Logic circuit according to claim 13, characterized in that only one secondary element is connected to the main element and that a readout sub-circuit of the secondary element, which generates an output bit "1" when the residual magnetic flux of the cores is positive, with that of a readout coil and is coupled to a gate existing series circuit of the main element, which in the same case generates an output bit "1", namely the coupling consists in a parallel circuit for an "or" link and in a series circuit for an "and" link. 15. Detector circuit according to claim 13, with high transmission speed, characterized in that a base group (0) from a main element and a secondary element as well as a multitude of other, groups (1 to n) constructed in the manner of a ladder are provided which consist of two Pairs of secondary elements exist, with two pairs of one secondary element pair each belonging reading sub-circuits are connected in parallel and form the ladder rails, while the two other pitch circle pairs are connected in series and the conductor crossbars form, and that all groups are connected to each other in a cascade connection. 16. Logic circuit according to claim 13, for achieving an output current accordingly "-I-1" or "-1", characterized in that there is only one secondary element with the main element is coupled and the reading sub-circles of the secondary element as load impedances of the Serve main element, with the desired output current at the connection points (T ") of the two items is available. 17. Pulse power source for operating a A multiplicity of logical elements or circles according to one of Claims 1 to 16, characterized by a transformer, the impulse currents from the same Feeds windings of the elements or element groups to built-up series circles, and by a switching element made of a capacitor and inserted in the series circuits Series-connected resistor that biases the logic elements feeds. Papers considered: “The Annals of the Computation Laboratory of Harvard University ", Vol. XXX, Cambridge, 1959, pp. 299-301.