DE1125000B - Circuit arrangement for code pulse generators for generating, decrypting or converting signals - Google Patents

Description

Circuit arrangement for code pulse generators for generation, decryption or conversion of signals The invention relates to circuit arrangements for code pulse generators for generating, decoding or converting signals according to a (k) code using a device with several polarity reversals or switchable magnetic cores, each with several windings, one of which an output winding, with the help of which a selected core can be switched from one magnetization state to the other, whereby a signal is generated in the output winding of the core.

Such devices can be used, for example, as decryption devices and converters can be used in self-connecting telephone systems. So z. B. a signal in the form of both decryption devices and converters one or more impulses are transmitted after a combination of input circuits. In a decryption device, an output pulse becomes one of a A plurality of output circuits generated in response to the transmitted signal.

In the following, the expression "switchable magnetic core" is intended for a component made of ferromagnetic material, which has such a hysteresis loop has that after transmission or construction and after removal or disappearance a magnetic field with a corresponding sense of direction to thereby determine the magnetization state of the material from one to the other of two stable magnetization states (which are referred to as "A-state" and "B-state" in the following) bring out a zero outer field after saturating the core in the two respective ones opposite magnetic sense of direction arises or occurs, whereby then, if the strength of the magnetic field having the corresponding sense of direction of Zero to a first value increases the magnetic flux within the material a relatively small value changes while when the strength of the magnetic field increased beyond the first value by one compared to this small value becomes, it becomes a relatively large magnetic flux change, hand in hand with a change in sign occurs, whereas when the strength of the magnetic field is then reduced to zero, only a relatively small change in the magnetic flux or a small change in the magnetic field occurs.

Suitable materials are those whose hysteresis loops are known have a rectangular shape. A hysteresis loop can be addressed as rectangular at which the remanent magnetic flux in the »A state« and in the »B state« is 80% or more of the magnetic flux present at saturation. This definition however, it is not limited to cores made of such materials.

A well-known circuit for converting or converting four binary numeric digits requires not just four, but eight input lines, d. H. all input lines after this circuit are, so to speak, doubled, and if a binary 1 is selected for a particular digit, one must Line, and if a binary 0 is selected, another must Line are energized.

The purpose of the invention is to create a circuit arrangement which compared to the known is much easier. By having the number of required Input lines is reduced by half, namely from eight to four also reduces the number of tubes required. on these Way, a considerable amount of switching elements is saved, and moreover If the matrix is large, the energy saving required is very considerable.

According to the invention, this is primarily achieved in that input blocking windings and a switching winding are assigned to each core, the switching winding being connected to an excitation control circuit delivering pulses and the blocking input windings being connected in series in groups so that they form a plurality of m input circuits, where m is greater than k and the arrangement is such that k blocking input windings of the magnetic cores are each connected in different combinations of k each of m input circuits, and that when the input circuits are applied to a pulse-supplying actuation control circuit, after all magnetic cores by the excitation control circuit or have initially been brought into their A state by simultaneous excitation of all blocking input windings, upon the transmission of a predetermined input signal, which consists of current signals which are transmitted to mk of the input circuits, all magnetic cores except for one in i Their A-state are locked so that only this one core is brought from the A-state to the B-state by a switching signal which is transmitted to the switching windings by the excitation control circuit.

In order to ensure that only one core is not blocked for each input signal, it should be obvious that the maximum number of cores; which can be approved in a facility for which the number of input circuits is m and the number of blocking input windings assigned to each core is k, N = m! l k! (m - k)! which is the maximum number of combinations of k input circuits of m.

In addition, it should be obvious that the N has a maximum value for a given value m when k = m / 2 or (m-1-1) / 2, accordingly whether m is odd or even.

Devices in which the number of cores is less than N for a given value of k and m can be regarded as devices obtained from an apparatus in which the number of cores is N by omitting some cores and their associated windings .

In one embodiment of the invention, each core is an output winding assigned, the decrypted output signal by a pulse in this Winding is formed and preferably represents a decimal number.

In another embodiment to implement a Code into another code are assigned to at least one core of two or more output windings, each output winding being connected to an output terminal, either directly or via an output winding on another core or via series-connected output windings on other cores.

Finally, according to a further development of the invention, it is also proposed that to train the actuation control circuit so that it normally follows current signals to transmit all input control circuits and the transmission of current signals able to interrupt for a time interval after all, except ra-k input circuits, during which the excitation control circuit excites the switching windings.

The invention is explained in more detail with reference to the drawing reproducing it as an example, namely FIG. 1 shows a schematic circuit arrangement of a decryption device according to the invention, while FIG. 2 shows a schematic circuit arrangement of a converter according to the invention. The first decryption device consists of ten ring magnetic cores, which are indicated schematically by the lines CI to C10 and which are each connected to ten output windings 01 to 010 , while they are all magnetically connected to a central switching core S. Five ratchet wires 11 to 15 are provided, each of which is connected to the cores C1 to C 4, to the cores C 1 and C 5 to C 7, to the cores C 2, C 5; C 8 and C 9, to which cores C 3 @ y, C6, C 8 and C10 and to cores C4, C7, C7 and C10 are connected. The switching core S is connected to an excitation control circuit EC, while the blocking cores I1 to 15 are connected to an actuating control circuit 0C. Both the five blocking cores and the switching cores are all threaded through the cores in the same sense of direction and negative pulses, which are transmitted to the cores by the actuation control circuit 0C or the excitation control circuit EC, switch the cores through which they are wound into their A states um, or at least they try to make that change. Thus, positive pulses which are transmitted to the switching core by the excitation control circuit EC switch the cores to their B-states, or they at least try to carry out this change. The actuation control circuit is designed so that it can transmit negative pulses to selected blocking wires, while the excitation control circuit is designed so that it can transmit negative reset pulses and positive switching pulses to the switching wire.

In operation, a negative reset pulse is transmitted after the switch wire S to ensure that all cores are in their A state. The actuation control circuit transmits negative pulses after three selected blocking cores 11 to 15, whereby all cores, with the exception of one, are blocked. While this pulse is being transmitted, the actuation control circuit transmits a positive switching pulse to the switching core S and thereby switches this one core from its A state to its B state. An output pulse is now induced in the output wire which, in decrypted form, reproduces an input encryption corresponding to the selected three input wires.

In Table I below is the unlocked core with reference to three selected ratchet arteries.

The converter illustrated in FIG. 2 consists in a similar manner of ten ring magnetic cores C 1 to C 10, through which a central switch wire S is threaded. Five ratchet wires 11 to 15 are provided, each of which is formed by the cores C 1 to C6, by the cores C 1 to C 3 and C 7 to C 9, by the cores C 1, C 4, C 5, C 7; C 8 and C 10, through the cores C 2, C 4, C 6, C 7; C 9 and C 10 and through the cores C 3, C 5, C 6 and C 8 to C 10 are threaded.

The five blocking wires are connected to an actuation control circuit OC which normally maintains currents in the wires, thereby maintaining the cores in their A states. The switching wire is connected to an excitation control circuit EC which is designed so that it is able to transmit pulses to the wires S, whereby the cores are switched from their A-states to their B-states or an attempt is made to switch them. Table 1 15th The three selected veins Unlocked core 11, 12, 13 C 10 1 1, 12, 14 C 9 20 11, 12, 15 C 8 11, 13, 14 C 7 11, 13, 15 C 6 1 1, 14, 15 C 5 25 12, 13, 14 C 4 12, 13, 15 C 3 12, 14, 1 5 C 2 3 0 13, 14, 15 C 1 In operation, the actuation control circuit interrupts the currents in three selected blocking wires for a short period of time, thereby removing the blocking condition in one core. During this short period of time, the actuation control circuit transmits a pulse to the switching core and thereby switches this one core from its A state to its B state.

In Table II below, the unlocked core is given with respect to any three selected lock cores. Table II 45 The three selected veins Unlocked core 1 1, 12, 13 C 1 11, 12, 14 C 2 50 11, 12, 15 C 3 11, 13, 14 C 4 11, 13, 15 C 5 11, 14, 1 5 C 6 55 12, 13, 14 C7 12, 13, 15 C 8 12, 14, 1 5 C 9 60 13, 14, 15 C 10 As can be seen, the cores are provided with output windings which are connected to four output connections 01 to 04 in such a way that the digits 1 to 10 are generated in binary code as the output of the converter. For example, when the core C 1 is switched, an output pulse is produced at the terminal 01 ; when the core C 2 is switched, an output pulse is produced at the terminal 02; when the core C 3 is switched; an output pulse is generated at connections 01 and 02, etc .:

Claims (6)

PATENT CLAIMS: 1. Circuit arrangement for code pulse generators for generation, decryption. or conversion of signals according to a (k) code using a device with several reversible polarity or switchable magnetic cores, each provided with several windings, one of which is an output winding, with the help of which a selected core from magnetization state A to state B can be switched, whereby a signal is generated in the output winding of the core, characterized in that each core is associated with input blocking windings and a switching winding, the switching winding being connected to a pulse-supplying excitation control circuit (EC) and the blocking input windings in series in groups are connected so that they form a plurality of m input circuits, where m is greater than k and the arrangement is such that k blocking input windings of the magnetic cores are connected in different combinations of k of m input circuits each, and that when the input circuits are applied to a bet delivering impulses actuation control circuit (0C), after all magnetic cores have been initially brought into their A state by the excitation control circuit or by simultaneous excitation of all blocking input windings, upon the transmission of a predetermined input signal, which consists of current signals which are transmitted to mk of the input circuits, all magnetic cores to be locked to one in their A-state, so that only this one core is brought from the A-state to the B-state by a switching signal which is transmitted to the switching windings by the excitation control circuit (EC). 2. Circuit arrangement according to claim 1, characterized in that the number of cores m! / k! (m - k)! amounts to. 3. Circuit arrangement according to claim 2, characterized in that that k-m / 2 or (m + 1) ./ 2, depending on whether m is even or odd. 4. Circuit arrangement for decoding a (k) code according to claim 1, 2 or 3, characterized in that an output winding is assigned to each core, the decrypted output signal being formed by a pulse in this winding and preferably represents a decimal digit. 5. Circuit arrangement for implementation one (k) code into another code according to claim 1, 2 or 3, characterized in that that at least one core is assigned two or more output windings, wherein each output winding is connected to an output terminal, either directly or via an output winding on a different core or via series-connected output windings on other cores. 6. Circuit arrangement according to one of claims 1 to 5, characterized in that the actuation control circuit (0C) is designed to normally send current signals to all input control circuits to transmit and transmit current signals to all but m-k input control circuits; able to interrupt for a time interval during which the excitation control circuit (EC) energizes the switching windings. Publications considered: German U.S. Patent No. 968,205; German Auslegeschrift I9667 VIII a / 21a3 (published on October 31, 1956).