DE1175274B - Pulse frequency divider or pulse reducer with switching elements made of material with hysteresis properties - Google Patents

Description

Pulse frequency divider or pulse reducer with switching elements Material having hysteresis properties The invention relates to electronic Pulse frequency dividers, as they are numerous today in information and data processing, z. B. be used as an electronic counter, and relates to a novel electronic Coasters, in which perforated discs or plates made of a material with a rectangular shape Hysteresis loops serve as switching and / or storage elements.

So far, such electronic coasters could be with electron tubes or transistors are built. The state of the open or closed electronic switch was z. B. by the de-energized or energized state the electron tube or the transistor shown. Known as such an electronic Switch is the bistable trigger circuit or flip-flop circuit, in which two electron tubes or transistors alternately, controlled by pulses, in the currentless or current-carrying State to be brought. By connecting individual bistable multivibrators in series build an electronic counter. The Input impulses scaled down in a ratio of 1: 2; with n flip-flops connected in series So the reduction ratio of the electronic counter is 1: 2n. It is now basically possible, also flip-flops with electron tubes or transistors for a reduction ratio of 1: 3n.

Electron tubes or transistors have been used as reduction elements in both of the specified types of circuit for reductions of 1: 2n and 1: 311. The identification of the count is done by distinguishing between de-energized and energized state.

This identification of the count has the disadvantage that the Failure of the supply voltage in the electronic meter lost information goes.

Another disadvantage of this reduction method is that in Idle state of the electronic meter for storing the information entered always power has to be expended.

An electronic coaster without these disadvantages, as a pulse divider built up with the reduction ratio 1: 3n (ternary reduction), now arises in the invention in that no active switching element is used as a reduction element like electron tubes or transistors, but perforated disks. or Plates made from a material with a rectangular hysteresis loop. The disks or plates consist of ferrite material in the circuit arrangement. Active Switching elements such as electron tubes or transistors are only used in the feedback paths used. The input pulses are sent to the reduction element on only one line fed. The arrangement according to the invention thus consists of a ferrite plate with at least three holes and a network of those around the holes magnetic fluxes via feedback paths containing active switching elements in linked in a cyclical sequence. One at a time through all three holes guided winding forms the common input of the reducer. Be for the Input and feedback winding of each hole assuming the same number of turns, then the feedback pulse that arises when the input pulse is a magnetic one The area around one of the holes is magnetized to be larger than the input pulse, via the common input loop to all three magnetic signals at the same time Areas.

A preferred embodiment of the invention in which equal ampere-turns are present in the input and feedback circuit, looks in the input winding each hole is a series connection of two resistors, their connection point with the feedback path of the respective associated magnetic area a directionally permeable switching element with a permeable polarity for the feedback pulse connected is.

Since the counting status of the pulse scaler is solely by the directions The magnetic fluxes shown in the ferrite material remain in one electronic counter from coasters constructed according to the invention entered information preserved even if the supply voltage fails. Also takes place at the pulse scaler according to the invention only during the duration of an input pulse a performance turnover instead, so there is a performance-free information storage possible.

Another advantage is that due to the few components the overall structure is very space-saving.

Further details and advantages can be found in the following description of exemplary embodiments. In the drawings, F i means g. 1 the circuit arrangement an electronic pulse frequency divider working as a ternary divider, F i g. 2, 3 and 4 are graphs of the magnetic states of the coaster element in FIG the switching arrangement.

In Fig. 1 is the circuit of an electronic pulse frequency divider, working as a ternary coaster. As a reduction element is for this application example a disk-shaped rectangular ferrite 5_ with four holes 1, 2, 3 and 4, as active switching elements in the feedback paths are for example Transistors 6, 7 and 8 have been chosen. -UB denotes the supply voltage. The magnetic fluxes are shown as arrows and labeled 4) 1, (D, and q).

Four windings are passed through each of the holes 1, 2 and 3_, and through hole 1 the windings Wo, WW W11 and W1 ″ through hole 2 the windings W., W2 "W21 and W22, through hole 3 the windings W., W30, W31 and W3.,.

The windings W "are in series and are connected to the terminal 9. The windings W", W., "and W3o are connected via the symmetrical series connection of the resistors R11, R12; R21, R;.,.,; R.31 , R3. = Also connected in series with one another. The centers of this symmetrical series connection are connected to terminals 10 and 11.

Each of the windings W11, W., 1 and W31 is grounded on the one hand and on the other hand connected to the base of one of the transistors 6, 7 or 8, from their collectors feedback lines via the load resistors R13 ,, R.20 or R3,3 of the transistors to the third winding of the following in the cycle Loches - so Wii-6-W., "W21-7-W.12 or W31-8-Wi, - lead. Furthermore, the Feedback lines via the diodes Dl, D. = and D3, which are polarized so that they are permeable for the output pulse of the associated transistor, in cyclic Follow a pair of resistors in the connection at the inner connection points between the windings W1., W ,, and W33, i.e. 6-Di-R "terminal 11, 7-D, -R32 terminal 11. or 8-D .3-R12 terminal 11.

The ring loop, in which the windings W1., W.20 and W. "are located, forms the input of the reducer. Terminal 10 is the input terminal of the circuit. Terminal 11 carries the voltage - U, 1. Terminal 9 becomes The output pulses of the circuit can optionally be picked up at terminals 12, 13 or 14.

The mode of operation of the circuit arrangement is as follows: For the initial state it is assumed that the magnetic flux (D1 clockwise around the hole 1, the magnetic Rivers -D2 around hole 2 and (D.3 around hole 3 are counter-clockwise (F i G. 1). A positive input pulse at terminal 10 is effected via the winding Wlo a reversal of the magnetic flux (Dl around the hole 1. During this flux reversal a voltage Ui is induced in the winding W, 1, which makes the transistor 6 conductive power. The positive output pulse of the transistor 6 interrupts once via the Diode Dl the input pulse current through the winding W, a, because the connection point between the resistors R, 1 and R _, _, receives the same potential as the terminal f0 and, on the other hand, causes the magnetic reversal via the winding W, Of the flux (D., around the hole 2. The voltage induced at the reversal of 4), at W, 1 U., is directed so that the transistor 7 remains de-energized. Likewise takes place through the input pulse current via winding W; "no flux reversal from (D .; around hole 3_ instead, since around hole 3 there is already a direction of magnetization which is the same as that through the input pulse current is achievable, so that transistor 8 also remains de-energized.

In Fig. 2 the flow distributions are shown as they are according to the first input pulse.

With a second positive input pulse, the winding W., "the flux (DZ again reversed. The voltage induced at the winding W." makes the transistor 7 conductive.

The positive output pulse from transistor 7 causes on the one hand over the diode D, an interruption of the input pulse current via the winding W.33, and on the other hand via the winding W.32 a flux reversal of q).;. The one with this one Magnetization reversal at winding W31 induced voltage U.3 leaves transistor 8 in the de-energized state.

The transistor 6 also remains de-energized because of the input pulse via winding W1, no flux reversal from D1 to hole 1 takes place.

The flux distribution after this second input pulse is shown in FIG. 3 shown.

With a third positive input pulse on line 10, the River q) .; around hole 3_ again, but now reversed over winding W.3 ", and the one there Voltage induced in winding W.31 opens transistor B.

The positive output pulse from transistor 8 now interrupts on the one hand via the diode D.3 the input pulse current in the winding W, and causes on the other hand A reversal of the flow via winding W12 (D1 around hole 1. The one at the flow reversal voltage induced from 4D1 to W1, is thus directed. that the transistor 6 is de-energized remain. Transistor 7 also remains de-energized because the input pulse current is over Winding W. = "the direction of flow is not changed.

In Fig. 4 the flow distribution is shown as it is according to the third positive input pulse results.

A comparison of FIG. 4 with F i g. 1 shows that now, that is after three input pulses, the initial state of the flow directions of D1 again, dD2 and q) .3 has set.

In the case of a series connection of the described ternary reducer to an electronic counter is used to advance the subsequent reduction stage by the output pulses of the transistors 6 or 7 or 8 of the previous reduction stage. The ternary scaler or its series connection can after a finished counting process by a positive pulse through the winding Wo into the output or zero position (see Fig. 1).

From the description of the switching arrangement and its mode of operation F i g. 1 it can be seen that the hole 4 is not essential for the function of the circuit is. It is necessary to be able to apply the windings W101, W 2o and W3, and can be omitted if in the input circle per hole, as in FIG. 1 shown, only one turn is required. But it can also come from savings in material and weight be left.

Furthermore, disc-shaped parts that hold the individual magnetic Areas around the holes 1, 2 and 3_ also contain detached from the entire ferrite ring without affecting the flux distribution and thus the function of the circuit something changes. This means that the invention can also be punched with three individual holes Cores, e.g. B. toroidal cores, can realize through the specified network or circles equivalent to it are linked.

It is also arbitrary which flux directions the magnetic Areas for the individual counting states are assigned, they then only have to be combined with the winding sense of the individual windings set once and then retained will.

It is also possible, instead of using the diode feedback path of the each switched magnetic circuit provides the input pulse for the other circuit to suppress the number of ampere turns of the feedback winding versus the To enlarge the input winding accordingly. The directional switching elements can thus be saved. If still in the input circuit instead of the parallel feed a series connection of the input windings are provided, the im Resistances lying in the input circuit are omitted (see Fig. 5).

Claims (4)

Claims: 1. Pulse frequency divider or pulse reducer, characterized by the use of material known per se with rectangular hysteresis behavior in the form of a plate (5_) with at least three holes or a corresponding number of perforated cores whose surrounding magnetic fluxes (D1, (D2, (D3)) can be controlled simultaneously via an input winding (Wlo or W2, or W3,) and by a network that generates the magnetic fluxes (D1, 02, (Ds) around the holes (1, 2, 3_) via active circuit elements (6 , 7, 8) containing feedback paths (Wl1-6-W22 or W21-7-W32 or W31-8-W12) linked to one another in such a way that one active circuit element each via an output winding (W11 or W21 or W31) (6 or 7 or 8) can be controlled, which reverses the magnetic flux (4) 2 or q) 3 or (D1) by the following in the cycle via a feedback winding (W22 or W32 or W12) Hole (2 or 3_ or _1) causes and the state of the magne surrounding the holes table areas that can be recognized by the potential over the active circuit elements during the switching process taking place via the input winding. 2. Pulse frequency distributor or pulse scaler according to claim 1, characterized in that the three parts of the input loop are each connected in series comprised of two resistors (R11; R12; R21; R22; R31; R32) and the connection point of each resistor pair with the feedback path of the one in the cyclic sequence other part of the input loop associated magnetic circuit via a direction-permeable, circuit element with a permeable polarity for the feedback pulse (Dl, D2, D3) connected is. 3. Pulse frequency distributor or pulse scaler according to claim 1 or 2, characterized in that the three rivers via a further loop (Wo) are linked to each other, via which reset pulses can be given. 4. Pulse frequency divider or pulse reducer according to claim 1 or 2 and 3, characterized by an annular disc (5) on which three holes (1, 2, 3) with their Windings lie on a pulley diameter.