DE1218188B - Allocator with magnetic coupling elements - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

Int. Cl .:

- & Θ64- H 03 K

GERMAN

PATENT OFFICE

EDITORIAL

German class: 42 m -14 '

Pa *. Bi.% 30. 3.

Number:

File number: St 21080IX c / 42 m

Filing date: September 14, 1963

Opening day: June 2, 1966

The invention relates to an allocator with magnetic coupling elements, in particular an allocator, in which a magnetic coupling element is used for each assignment.

Various allocator circuits are known which have different control methods. What all arrangements have in common, however, is that the desired output signal can be obtained by reversing the assigned core or the assigned cores is obtained. Depending on the code selected, the Cores several output windings, so that the output power of a core is distributed to several · output circuits can be distributed. This division of services is particularly disadvantageous if that Output signal is delivered in parallel and is only generated by reversing a magnetic core will.

It is the object of the invention to create a magnetic allocator that has more output on the output side and still only needs small tax payments on the input side. The mapper with magnetic coupling elements according to the invention is characterized in that all coupling elements of the allocator are also designed as a blocking oscillator. This can be done in a simple manner that the blocking oscillator is dependent on the input information of the allocator is blocked or activated and that only when a certain input information is pending the blocking oscillator of the associated coupling element is controlled.

The magnetic allocator designed in this way requires only a small input control power, since via the Feedback path of the blocking oscillator, the reversal process of the magnetic core is carried out. This feedback process also has the advantage that the reversing process of the magnetic core is accelerated. The work speed of the assigner is thus increased significantly. The different Poled control voltages for the blocking oscillator ensure that only the blocking oscillator the selected assignment oscillates. The blocking oscillator is designed according to the invention in the simplest way so that each coupling element of the allocator has two additional windings obtained, which are switched on in a known manner in the control and output circuit of a transistor. So that the assigner is not caused by glitches. can be suggested, provides a further refinement provide that all blocking oscillators are blocked via a separate control circuit if there is no input information. To the glitches

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

To suppress non-reversed magnetic cores on the output lines of the allocator, it has already been proposed to provide the coupling elements with current-direction-dependent short-circuit circuits, which can also be controlled depending on the presence of an input signal. To this end, the invention provides that a winding of the blocking oscillator is included in the direction-dependent short circuit.
The invention is explained in more detail with reference to the drawings. It shows

Fig. 1 shows an allocator with magnetic coupling elements.

Fig. 2 shows the design of the individual coupling elements as a blocking oscillator and

Fig. 3 shows the combination of blocking oscillators and Short-circuit depending on the current direction.

In Fig. 1 is an embodiment of an allocator with magnetic coupling elements, for. B. Magnetic cores shown with a rectangular hysteresis loop, which requires two clocks Tl and Γ 2 for an assignment. In the illustration, the coupling elements are drawn as horizontal bars and the control lines as vertical lines. Leads the control line through the coupling element, ζ. Β ..

a magnetic core with a rectangular hysteresis loop, this is indicated by an oblique line at the point of intersection with the core concerned. The shown allocator has three magnetic cores Kl, K2 and K 3. Each coupling element is intended for a specific assignment. The input information acts via the input control lines α, Έ to e, e on the coupling elements of the allocator according to the selected allocation. The implementation of these control lines is such that the core assigned to certain input information is not influenced by any inhibition current when this information is present

609 577/370

will. At the same time at the timing Tl all cores is supplied via the loop S write current. The kernel Kl becomes ä, b, c, d, S, the kernel K 2 with the information ä, Έ, _ρ, ~ ä, ~ e and the kernel K 3 with the information α, Έ, Έ, Έ, β selected. The input control lines are routed through the core or past the core according to this scheme. In the first time cycle T1 , therefore, only the core selected in each case is reversed.

If the input information, F, c, Έ, e of the core K 2 is available, then the cores Kl and K 3 are blocked in the first time cycle. The kernel is activated via the control lines Έ and Έ. and the core K 3 blocked via the control lines ä, c and e.

The current in all control circuits is selected in such a way that it is definitely sufficient to remagnetize a core. The output signals appear on lines k to q in time cycle T1. The output code is determined by the routing of the output control lines k, Έ to q, g. Since the control lines Έ, 7, m, 7>, q are routed through the core X2, signal pulses occur on these output lines at the time cycle Π. The number and routing of the input and output control lines depends on the code of the input and output information.

-In timing Γ2 returns all cores Kl to K3 to their original position, and the Zuordnersteht for a new assignment ready. This reset is indicated by the pulse of the time cycle Γ 2 on the loop R , which is directed in the opposite direction to the pulse of the time cycle Π.

In order to make the signals emitted by the allocator powerful on the output lines, the coupling elements, ie the magnetic cores, are supplemented to form a blocking oscillator, as FIG. 2 shows. The magnetic cores Kl to K3 receive two additional windings wl and w2. The double slash is intended to indicate that this is not a matter of lines simply passed through the core, but of real applied windings. The two windings are switched on in a known manner in the control and output circuit of a transistor TrI to TrZ . The direction of winding of these windings is now chosen so that the transistor Tr2 is made conductive by the voltage of the selected magnetic core, for example K2, induced in the winding w 2. The voltage induced by the output of the transistor via winding w 2 supports the reversal process. The w in the control windings 2 of the unselected magnetic cores Cl and K 3 induced noise voltages lock the blocking oscillator with the transistors TrI and Tr 3. from the blocking oscillator with the transistor Tr 2 via the winding w 1 coupled power is Jür the distribution on the output lines £ ,?, m, ο and q and is not limited by the control capacity of the input information.

F i g. 3 shows in principle the blocking oscillator according to FIG. 2. A separate control circuit for suppressing the interference signals on the output lines is provided as an addition. If the control pulse in winding w2 is negative, the blocking oscillator is released. In the case of a positive control pulse, as z. B. arises from the interference pulses from unselected cores, the blocking oscillator blocks, but interference signals will still occur on the output lines. If the transistor Tr 4 is switched to the conductive state during an assignment via the control input A , then the interference pulses occurring via the control winding w 2 are short-circuited via the diodes DIl and D31. The output interference signal is limited to a value which is determined by the limiting voltage of these diodes and the selected number of turns of the control winding w2 . The allocator can be blocked in the idle state via the diodes D12 and D 32 and the transistor Tr 5, so that no blocking oscillator is released even if the interfering signals of the correct polarity are present. If the transistor TrS is made conductive at or shortly before the end of the clock pulse, then the interference signals from the unselected cores are also suppressed when they fall back into the remanence state. As can be seen from FIG. 3, the control winding w 2 of the blocking oscillator fulfills both functions, controlling the blocking oscillator and controlling the short-circuit circuits.

Claims (7)

Patent claims: 1. Allocator with magnetic coupling elements, characterized in that all coupling elements (2511, K 2, K 3) of the allocator are also designed as a blocking oscillator. 2. Allocator according to claim 1, characterized in that each blocking oscillator as a function is blocked or released by the input information of the assigner. 3. Allocator according to claim 2, characterized in that that when a certain input information is pending, only the blocking oscillator of the assigned coupling element is activated or released. 4. Allocator according to claim 1, characterized in that each coupling element (K 1, K 2, K3) of the allocator receives two additional windings (wl; w2) , which in a known manner in the control and output circuit of a transistor (TrI, Tr2, TrZ) are switched on. 5. Allocator according to claim 1, characterized in that via a separate control circuit (A, TrA, TrS) all blocking oscillators are blocked when • making no input information are. · 6. Allocator according to claim 4, characterized in that a winding (w2) of each blocking oscillator is included in a direction-dependent short circuit (Dl, D 2, Tr 4, TrS) . - 7. Allocator according to claim 6, characterized in that the short circuit is made effective in one or the other current direction depending on the presence of an input signal (A). 1 sheet of drawings 609 577/370 5.66 © Bundesdruckerei Berlin