DE1208766B - Binary number chain running forwards and backwards with magnetic cores and diodes, in particular for use for pilot-controlled, step-by-step level control in carrier frequency communication systems - Google Patents

Description

Binary counting chain running forwards and backwards with magnetic cores and Diodes, in particular for use for pilot-controlled, step-by-step level control in carrier frequency communication systems The invention relates to a pre- and backward running binary counting chain with magnetic cores and diodes for counting of pulses, in particular for use as pulse-controlled, purely electronic Setting device for the pilot-controlled, step-by-step level control in carrier frequency communication systems, z. B. high-quality multi-channel long-distance systems is suitable.

A binary counting chain with transistor or tube flip-flops and diodes (German patent specification 1118 831), which is known for this particular purpose, allows counting in both directions. However, it has the disadvantage that it constantly consumes energy not only during the individual counting processes but also in the pauses between these counting processes and that the existing counting status is irretrievably lost if the operating voltage fails or is switched off.

A forward and backward binary counting chain with rectangular ferrite cores and diodes is also known (AEÜ, 1962, No. 4, p. 191). This counting chain has twelve magnetic cores, eight of which are required for the counting process and four for the display of the switching states or digits. The counting chain is only able to adopt four different switching states or to display four different digits, with each digit being assigned a specific core. This is not a real binary representation of the digits, in which you can set different switching states or represent digits with counting levels 2n. If the known counting chain is extended to more than four digits, since the number of digits increases multiplicatively with the increase in the number of counting levels, there is inevitably greater effort than with the real binary representation, in which an increase in the number of levels results in an exponential increase in the number the numbers that can be displayed.

These disadvantages are avoided according to the invention in that in the individual counting stages of the counting chain that are identical to one another, preferably in a transistor amplified counting pulse via a first toroidal core (scoop core) to the control winding of a transfluxor is transmitted, the inner and outer web of decrease coils wear the diodes, the bias voltages of which determine the counting direction, to the next counting stage are coupled that parallel to the decrease winding of the outer Web a second toroidal core (short-circuit core) enclosing control winding and that both toroidal cores and the Transfluxor each have a reset winding, with the reset windings of the transfluxor and short-circuit core in each stage are connected in parallel to each other and the reset winding of the scoop core the aforementioned reset windings in a preferably common to all counting levels Reset circuit is in series or in parallel.

The invention is illustrated below with reference to two in FIGS. 1 and 2 illustrated embodiments explained in more detail.

The in F i g. 1 occurring at terminal a of the counting stage shown Counting pulses are generated in a transistor T1 with a collector current limiting resistor R, amplified and the control winding W, a first toroidal core K, supplied. This so-called scoop core has the task of transferring the control impulse to a second Winding W #. transformable pulse of suitable duration and amplitude. W3 is the reset winding of the scoop core. The winding W2 is via a diode 1), connected to the control winding W4 of a transfluxor Ti with three holes 1, 2 and 3. The inner web of the Transiluxor has a removal winding between holes 1 and 2 W5 and the outer web between the hole 2 and the outer edge of the transfluxor one Acceptance winding Ws. The ends of these windings are on the one hand at points r and v, which carry different positive potentials to ground, on the other hand via diodes D2 or D3 at the counting pulse input of the next stage, of which only transistor T1 ' is shown. The remaining elements of this stage and the other following stages, all of which correspond to the illustrated first stage are through the two perpendicular ones dashed lines L1 and L2 only indicated schematically. Through hole 3 are a read winding W7 and an output signal winding W $ out. The winding WE is also connected via a diode D4 to the control winding W3 of a second toroidal core K2, the so-called short-circuit core, connected. The reset winding wlo this one The toroidal core and the reset winding Wll of the transfluxor are within the stage in a reset circuit common to all counting stages, parallel to one another and connected in series with the reset winding W3. The windings Wlo and Wll respectively one diode each D5 or D6 in series. The reset circuit is the one with a Current limiting resistor R2 provided collector circuit of a transistor T2, whose base connection terminal b the reset pulses are supplied. The two toroidal cores and the transfluxor consist of one, preferably the same magnetic material, z. B. ferrite, with an approximately rectangular hysteresis loop. The diodes Dl, D4, D5 and Ds are used to suppress disturbing current flows with incorrect polarity. The transistor of the reset circuit T2 is common to all stages.

The mode of operation of the counting chain is as follows: It is assumed that the scoop core K1 and the short-circuit core K2 are labeled "0" in the same way And the transfluxor is in the positive remanence point -I- Br.

If a first counting pulse is now given to input terminal a, then the transistor T1, which has been blocked until then, becomes conductive, and that through the winding W1 flowing current pulse generated by appropriate dimensioning and polarity of this winding a magnetic flux in the core K1, which magnetizes the core and into the opposite remanence position "l" brings. The one that occurs when the magnetization is reversed in the core Magnetic flux generates a voltage pulse in the winding W2, which has an in Forward direction through the diode Dl flowing current pulse has the consequence. The control winding W4 of the transfluxor Tr is polarized and the number of turns selected so that this Current pulse is just able to take half the cross-section of the transfluxor and to re-magnetize the inner bridge. As a result of this current pulse is the Transfluxor is brought into a set state marked with an »E«.

If a first reset pulse is sent to terminal b, the previously blocked transistor T2 is conductive, and a reset current pulse flows which makes the counting level available again for the next counting pulse. The reset current pulse flows through the winding W3 and the parallel connection of the windings Wlo, 1V11. The winding W3 is polarized and dimensioned in terms of the number of turns that the scoop core K1 is reset to the remanence position 0. Because of the in the blocking direction Diode Dl cannot send the reset current pulse to the transfluxor via winding W2 works. The winding Wlo is polarized so that the reset current pulse hits the short-circuit core K2 from the remanence position 0 into the corresponding saturation position of the same polarity leads. With a core made of rectangular material, however, there is hardly any change in induction tied together. There is therefore almost no voltage drop across the winding Wlo; h., she educates, apart from their low ohmic resistance, a short circuit. The entire reset current pulse So flows through the winding Wlo, and the Transfluxor can through the winding W11 cannot be reset, although the latter has the correct winding sense for resetting owns.

The following second counting pulse flips the scoop core back into the remanence position 1, and a current pulse passes through the winding W4 via the diode D1. Since the inner web is already magnetized in the direction in which this current pulse would flip it, the outer web is now magnetized and the transfluxor is moved out of the set position E and into the negative remanence position - Br. The change in the magnetic flux in the outer web induces a voltage pulse in the winding Ws, which results in a current pulse in the forward direction of the diode D4 through the winding W9, which in turn flips the short-circuit core K2 from the remanence position 0 into the remanence position 1.

The now following reset pulse folds the scoop core K1 back into place the remanence position 0. Since the short-circuit core K2 is now in the remanence position 1 is, the reset current pulse flowing through the winding W »generates a dem existing magnetic flux opposite magnetic flux, so that this core flipped over will. During the folding over of the core, a voltage drops across the winding Wla from, whereby part of the reset current flows through the winding W "and in the transfluxor a magnetic flux opposite to the magnetic flux present there and the transfluxor is brought back into the remanence position + B. The number of turns the windings Wlo and Wll are expediently chosen so that the short-circuit core K2 and the Transfluxor Tr have the same turn-over times and therefore both go through the Reset current pulse completely into remanence position 0 or into the positive remanence position + B ,. to be postponed. The starting position has thus been reached again.

The above are repeated for further counting and reset pulses described processes in a corresponding manner.

In the take-off windings WS and Ws, a voltage pulse is induced with every first or second counting pulse, of which, however, due to the different bias voltages of diodes D2 and D3 in each counting direction, only one voltage pulse is used to control the next counting stage, for example for the up counting direction the voltage pulse derived from the winding W, via the diode D3. This corresponds exactly to the above-mentioned known forward and backward counting chain with transistor flip-flops, in which the control pulse for the subsequent stage of the desired counting direction is optionally taken from the output of the first or second transistor of the first stage in any stage. The respective state of the stage is queried by an alternating voltage applied to the reading winding W7. In the set state E of the transfluxor, ie after the first, third, fifth, seventh, etc. counting pulse, an output signal is obtained at the winding Ws, since the magnetic circuit around the hole 3 allows transmission. In the remanence positions - Br and -I- Br of the transfluxor, ie after the second, fourth, sixth, eighth etc. counting pulse and the subsequent reset pulse, no transmission from winding 977 to winding TV is possible, so that no output signal is obtained .

Table 1 shows the counting process of one stage and Table 2 shows the counting process of two successive stages of the counting chain according to the invention once again. Z = counting pulse, R = reset pulse and A = output signal on winding W8. In the columns under K1, Ti and K , the state of the nuclei or the transfluxor after the impact of the impulses listed in the first column is given. Table 2 clearly shows the reversal of the counting direction with the fifth counting pulse. Table 1 K , Ti. K 1 A Starting position ........ 0 - @ - Br 0 - 1. Z ................ 1 E 0 1 1. R ................ 0 E 0 1 2. Z ................ 1 - B, 1 0 2nd row . . . . . . . . . . . . . . . 0 -f- Br 0 0 Table 2 1st stage 2nd stage (K1 @ Tr 1, K @ A @ Ki Tr IKEA Starting position ... 0 -f- Br 0 0 0 + B, 0 0 i Positive counting direction 1.Z ......... 1: E 0 I1 @ 0 + Br 0 0 1st R. . . . . . . . . 0 E 0 1 0 + Br 0 0 2.Z ......... 1 -Br1 @ 0 '1 E 0 1 2nd row . . . . . . . . 0 -f- B "i 0 0 0 E j 0 1 3rd Z ........ 1 E 0 @, 1 0 E j 0 1 3rd R ........ 0 E 0 @ 1 0 E 0 1 4.Z ......... 1 -B,.! 1 @, 0 @ 1 -Bri 1 I0 4th row . . . . . . . 0 + B2- 0 0 j 0 -; - Br 0 10 Negative counting direct 5.Z ........ 1 E 0 11 E '0' 1 5.R ......... 0 E '0 1 @ 0 E 0 1 6.Z ......... 1 -B, 1 0 0 E 0 1 6.R ........ 0 + Br ' 0 @ 0 0 E' 0 I1 7.Z ......... 1 E 0 11 # 1 -B, 1 10 7th R. . . . . . . . 0! E 0 1! 0 -f- Br 0! 0 B. Z ......... 1 I-B9 '1 @ 0' 0 + Br @ 0 0 B. R. . . . . . . . 0 -I- Br 0 0 I 0 + Br I 0 # 0 The counting chain described according to FIG. 1 only consumes energy at the moment of counting, since all transistors are blocked between counting processes. The count status is retained indefinitely and can be queried as often as required. If the supply voltage fails or is switched off, the respective count status is not lost. Assuming an unlimited service life for ferrite material and a limited service life for transistors, the counting chain according to the invention is about twice as reliable as a conventional transistor flip-flop counting chain, since the first counting chain only has half the number of transistors needed.

In the embodiment according to FIG. 2 serves in place of a special one Short-circuit core is the outer web of the Transfluxor, the reset winding W11 of the transfluxor only its inner Ridge encloses and the control winding of the special short-circuit core with this not applicable.

It can cause a complete magnetization reversal during the counting process To ensure the scoop core, it should be appropriate that in particular in the second and the following counting stages the scoop core carries an auxiliary winding which is in series with a resistance between the base and emitter connection of the belonging to each stage Input transistor for the counting pulses is switched.

Claims (4)

Claims: 1. Forwards and backwards running binary counting chain with Magnetic cores and diodes, in particular for use for the pilot-controlled, stepwise Level control in carrier frequency communication systems, d a d u r c h g e k e n nz e i c h n e t that in the individual, equal counting levels of the Counting chain of the counting pulse, preferably amplified in a transistor (T1), via a first toroidal core (scoop core K1) to the control winding (W4) of a transfluxor (Tr) is transferred, the inner and outer webs of which carry acceptance coils (W, W.), those via diodes (D., 1) 3), whose bias voltages determine the counting direction, to the next counting stage are coupled that parallel to the acceptance winding (WE) of the outer Web a second toroidal core (short-circuit core K #.) Enclosing control winding (W3) and that both toroidal cores (K1, K.) and the transfluxor each have a reset winding (W3, Wlo and W,) wear, with the reset windings of the transfluxor in each stage and short-circuit core (Wla, W11) are connected in parallel to one another and the reset winding (W3) of the scoop core to the aforementioned reset windings in one preferably reset circuit common to all counting stages is in series or in parallel. 2. Counting chain according to Claim 1, characterized in that interfering Current flows in the control and reset circuits of the transfluxor Jr) and short-circuit core (K #.) Diodes (Dl, D4, 1) 5, DJ are switched on. 3. Counting chain according to claim 1 and 2, characterized in that instead of a special short-circuit core, the outer, only provided with a reset winding web of the transfluxor is used and that the Reset winding of the Transfluxors only encloses its inner web. 4. Counting chain according to claim 1, characterized in that in particular in the second Stage and the following stages the scoop cores (K1) carry an auxiliary winding that in series with a resistor between the base and emitter connection of the input transistors (T1) are switched on for the counting pulses. Considered publications: Archive for electrical transmission (A. E. Ü.), 1962, issue 4, pp.189 to 192.