DE1200373B - Allocator with magnetic coupling elements - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

EDITORIAL

373 Int .. CL:

H04m

German KL: 21 a3-32 / 20

Number: Μ ^ ΒΗ
File number: St 21045 VIII a / 21 a3
Filing date: September 4, 1963

Display day:

September 9, 1965

The invention relates to an allocator with magnetic coupling elements, in which for each allocation a coupling element, ζ. Β. a magnetic core is inserted.

In known assignments with magnetic cores, one of the number of assignments is desired the same number of magnetic cores is provided. Each of these magnetic cores is connected to each of the input control lines, via which the input information is supplied in parallel, concatenated in such a way that accordingly of the assignment, only one core is remagnetized at a time. The concatenation can be, for. B. be done so, that all cores receive a bias current and a countercurrent via the input control lines. The input control lines are routed through the magnetic core or past the magnetic core according to the assignment. Is there a certain input information on, then only the assigned magnetic core receives that much via its input control lines Countercurrent, that the bias current is compensated and exceeded so far that the core is magnetized will. However, this coincidence method can only be used for a limited number of input variables realizing safely. Differences in the characteristic values of the magnetic cores have an unfavorable effect the end. The reliability of the assignment is further reduced by tolerances in the control circuits. It are the operating conditions for safe folding of a magnetic core with large allocators when applicable Input information and safe non-flipping can no longer be mastered with only slightly deviating input information.

The object of the invention is to create a new allocator with magnetic coupling elements, which is independent of the number of input and output variables and the size of the assigner always results in safe switching conditions for the magnetic cores, even if the characteristic values of the individual coupling elements vary somewhat and relatively large tolerances occur in the control circuits. The allocator with magnetic coupling elements according to the invention is characterized in that a marking current is simultaneously supplied to all coupling elements by a control pulse and the Assignment is made so that none of the inhibition currents generated by the input information the selected coupling element acts. This type of control ensures that all coupling elements that are not affected are kept in the same remanence state and only the selected one Coupling element is magnetized by the marking current. Through appropriately guided training

Allocator with magnetic coupling elements

Applicant:

Standard Elektrik Lorenz Aktiengesellschaft,

Stuttgart-Zuffenhausen, Hellmuth-Hirth-Str. 42

Named as inventor:
Dipl.-Phys. Friedrich Ulrich,
Stuttgart-Bad Cannstatt

Output information can be assigned to output control lines. The choice of Currents in the control circuits is not critical. The marking current must be so large that each coupling element can be safely remagnetized. In the

Currents flowing through the input control lines must reliably compensate for the marking current. Since they the magnetic cores can only drive into the saturation range, these currents are allowed to drive the marking current overcompensate at will. The assignments are now made so that only one input information associated magnetic core of no inhibition current of the input control lines, which in general If carried out in an adversarial manner, is influenced. Through the inhibition currents are induces small interference voltages in the unselected magnetic cores, which the output pulses counteract the reversed core.

For this reason, the allocator according to the invention provides that the inhibition currents in the unselected coupling elements generated output voltages by a current direction-dependent Short circuit can be suppressed. The current direction-dependent short circuit is by an additional winding of the magnetic core and a correspondingly switched on rectifier educated. According to the invention, the short circuit can also be designed so that the short circuit only becomes effective during the control pulse, and in the opposite case in the absence of a control pulse Current direction becomes effective. The control of the short circuit can also be from creating and Switching off the control pulse can be made dependent. This influencing the short circuit is especially useful when using magnetic cores without a pronounced rectangular hysteresis loop important so that the magnetic cores return to their initial state immediately after an assignment

509 540/84

can take. However, if magnetic cores with a rectangular hysteresis loop are used, then the short circuits can be omitted. However, the cores must be reset in a second clock pulse before a new assignment can be carried out. To determine the output power of the To increase allocator, the invention also provides that all coupling elements of the allocator as Blocking oscillators are formed. The blocking oscillators are dependent on the trigger pulse blocked by the input information and only the blocking oscillator of the relevant assignment is released.

The invention is explained in more detail with reference to the drawings. It shows

Fig. 1 shows an assignment according to the invention second time cycle for resetting,

F i g. 2 an allocator with a clock and short circuits and the

F i g. 3 to 5 different configurations of short circuits.

In Fig. 1 shows a allocator according to the invention with three magnetic cores Kl, Kl and K 3. The input variables α to e are contradictory, so that a total of ten input control lines α, Έ to e, e are available. The assignments are selected as follows:

Kl = Έ-bcde, KI = Έ-Έ-c-'ä-'e, K3 = α-Έ-c-Tl-e.

These relationships indicate which control lines do not affect the magnetic cores. The control lines ä, b, c, d and e are z. B. bypassed the core KX, so that this core receives no inhibition current / 1 to / 5 with this input information. The effective in the opposite direction in the loop S Marking current can at clock pulse Tl therefore remagnetize the core Cl. The selected assignment (the output lines Ic, Ί, m, η and "ö are routed through the core Kl ) results in the assigned output information on these lines. In the representation of the assigner, the cores are shown as horizontal bars and the control lines as vertical lines . If the control line runs through the core, this is indicated by an oblique line at the intersection. The oblique lines are drawn from bottom right to top left or vice versa. This indicates the direction of the implementation. In the example shown, the input information is similar · "B · c · ~ ä ■ ~ e an. As one can easily see for oneself, with this information the core K1 does not receive any inhibition currents and is consequently magnetized. The cores Kl and K 3 are kept in their remanence state via the inhibition currents / 2 and / 4 or II, / 3 and 75. When the core Kl is reversed, pulses are generated on the output lines Έ, Ί, m, H and ο that represent the assigned output information. As indicated by the oblique lines, these lines are routed through the core K1 . When the input information a · Έ · c · Έ ■ e is present, the core .O finally emits the output information kl · ~ ηϊ · η · ο . A new magnetic core is to be provided for each additional input information item, through which the input and output lines penetrate according to the desired assignment.

When choosing the control currents, it is only necessary to ensure that the marking current is in the loop.!? and each of the inhibition currents / 1 to / 5 is so large that the reversal of a magnetic core is reliably effected. Since the inhibition currents only drive the core into the saturation range, these currents can be selected in such a way that they safely.Jaijmpensieren the marking current. Since at least one inhibition current flows in all unaffected males, it is ensured that all nonselected cores are not reversed. In the case of the selected core, on the other hand, only the marking current is always effective, so that the core is reliably reversed. If magnetic cores with a rectangular hysteresis loop are used as coupling elements, the core involved must be reset again after the assignment. In a time cycle T 2 , all cores are reset by a reset current in the grinding shop. applied. This current works in

ao direction of the inhibition currents and therefore places the core involved in the assignment back into the Starting position back.

F i g. 2 shows an allocator which is based on the same principle of the control. Here is the assignment of the F i g. 1 retained. If conventional magnetic cores are used as coupling elements, ie without a pronounced rectangular hysteresis loop, the assignment can be carried out in a time cycle T. The inhibition currents magnetize all unselected cores in one direction and only the selected core in the other direction. In doing so, pulses of one and the other polarity are induced on the output lines according to the assignment. The output pulses of the unselected cores on the output lines can be suppressed via a direction-dependent short-circuit, which is implemented by the additional winding w of each core and a correspondingly polarized rectifier D1, Dl, D 3. The two lines of the winding w indicate that the wires are passed through the core several times and thus translate the limiting voltage of the diode in the output control lines to a very low value. In this way, the interfering signals of the unselected cores cannot noticeably influence the useful signal of the selected core. With the selected core, the short circuit is not effective, since the polarity of the induced voltage is such that the constant light is stressed in the reverse direction.

F i g. 3 shows only the short circuits of three magnetic cores of an allocator. The mode of operation of the protective circuit has already been explained. Like F i g. 3 shows, the short circuits of the allocator are opened by a contact T. This contact is in the control time cycle T of the allocator according to FIG. 2 closed in order to suppress the undesired output signals. If the timing pulse T is switched off, then the short circuit is opened so as not to delay the resetting of the selected core. Like F i g. 4 shows, the short circuit can also be closed and opened via a transistor Trsi, Trsi, Trs3. The control circuits of the transistors of all short-circuit circuits are connected in parallel and are fed by the clock pulse T directly.

In Fig. 5 is a controlled by the clock pulse T , switchable in both current directions short-circuit

1 AiU " υ» **

circle shown. For one current direction, the winding vv is short-circuited via the diode DIl, D 21, D 31 and the transistor Trsa and for the other current direction via the diode D 12, D 22, D 32 and the transistor Trsb. The two control circuits of the transistors Trsa and Trsb are combined and are fed by the clock pulse T via an AC element. The i? C element is used to shift the potential when applying and disconnecting the clock pulse T. When the pulse is applied, the transistor Trsa becomes conductive and the short-circuit circuit is effective in one current direction, while when the pulse is turned off, the short-circuit circuit becomes effective in the opposite direction. In this way, the undesired interference signals can be suppressed during both switching processes.

In order to make the output signals of the allocator more powerful, each coupling element is designed as a blocking oscillator. For this it is only necessary to equip each magnetic core of the allocator with two additional windings, which are switched into the output and control circuit of a transistor in a known manner. The additional winding w of the short circuit can also be used here.

Claims (12)

Patent claims: 1. Allocator with magnetic coupling elements, in which a coupling element is used for each allocation, characterized in that a marking current (S) is supplied to all coupling elements (Kl, K2, K3) simultaneously by a control pulse (Tl, T) and the allocation is so What is made is that none of the inhibition currents (71 ... / 5) generated by the input information (a · a ... e · e) acts on the selected coupling element (K 2). 2. Allocator according to claim 1, characterized in that the coupling elements (Kl, K2, K3) are penetrated by additional output lines according to the selected output information (k, Tc ... o, o). 3. Allocator according to claim 1 and 2, characterized in that the output voltages generated by inhibition currents (/ 1 ... / 5) in the unselected coupling elements (Kl, K 3) are suppressed by a short circuit dependent on the current direction. 4. Allocator according to claim 3, characterized in that the current-direction-dependent short circuit is formed by an additional winding (w) of the coupling element and a correspondingly switched on rectifier (D 1, D 2, D3) (Fig. 2). 5. Allocator according to claim 1, characterized in that when using magnetic cores with a rectangular hysteresis loop in a second clock pulse (T 2), the coupling elements are reset to the starting position (F i g. 1). 6. Allocator according to claim 3 and 4, characterized in that the short circuit is effective only during the control pulse (T) (F i g. 3 and 4). 7. allocator according to claim 3 and 4, characterized in that the short circuit in the absence of Activation pulse (T) takes effect in the opposite current direction. 8. allocator according to claim 1 and 5, characterized in that all coupling elements (Kl, K2, K3) of the allocator are designed as a blocking oscillator. 9. allocator according to claim 8, characterized in that the blocking oscillator when the control pulse (T) is blocked or released depending on the input signal. 10. allocator according to claim 3 and 4, characterized in that the short circuit when applying and switching off the control pulse (T) takes effect in a different direction. 11. Allocator according to claim 8 and 9, characterized in that all coupling elements with two additional windings applied in opposite directions are equipped. 12. Allocator according to claim 11, characterized in that one of these windings is used at the same time as winding (w) in the short circuit. 1 sheet of drawings 509 540/84 4.65 © Bundesdruckerei Berlin