DE1207957B - Receiving device for pulse-shaped signals, which have different polarities with respect to a reference level, with means for equal regeneration according to both polarities - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

EDITORIAL

Int. α .:

H03k

German class: 21 al - 36/04

Number: 1 207 957

File number: N 24922 VIII a / 2 IaI

Filing date: May 5, 1964

Opening day: December 30, 1965

The invention relates to a receiving device for pulse-shaped signals, which compared to a Reference levels have different polarities.

Such devices are used, among other things, for receiving and regenerating double-stream telegraphic signals. The task arises here, the rest and work elements of opposite polarity without preference for one or the other different polarity, d. H. to regenerate without preferential deformation.

The invention aims to provide a receiving device of the type mentioned, in which, besides a galvanic separation between the telegraph line and the receiving device a restoration the shape of the rest and work elements is effected with a minimal preferred deformation.

The receiving device according to the invention is characterized in that the pulse-shaped Signal together with a periodic sampling signal with a periodically recurring pulse shape with opposite polarity in alternating periods, which pulse shape is caused by a sampling pulse with a steep front flank and a slightly inclined rear flank and through a dem Sampling pulse formed following auxiliary pulse with slightly inclined slopes and opposite polarity is attached to a core made of magnetic material with a rectangular hysteresis loop Windings is applied, with each auxiliary pulse having sufficient strength to with the values of the pulse-shaped signal, in which the core is not clearly magnetized, the magnetization state of the core to switch, and with an output winding one on the polarity and the amplitude of the output pulses induced in the output winding responsive circuit with is connected to two stable equilibrium states.

The invention further aims to provide a simple embodiment of the receiving device according to the Invention to create, wherein the period of the scanning signals and auxiliary pulses small against the length the received pulse is.

A preferred embodiment of the receiving device according to the invention has the feature that to derive the scanning signal from a periodic signal with steep front and front Trailing edge a sensing winding attached to the core in series with a resistor an inductance is connected in parallel and that the parallel connection in series with a capacitor Receiving device for pulse-shaped signals which are different with respect to a reference level Have polarities, with means for even regeneration according to both polarities

Applicant:

N. V. Philips' Gloeilampenfabrieken,

Eindhoven (Netherlands)

Representative:

Dipl.-Ing. E. E. Walther, patent attorney,

Hamburg 1, Mönckebergstr. 7th

Named as inventor:
Roelof Reinier van Derveen,
Einar Andreas Aagaard,
Hilversum (Netherlands)

Claimed priority:

Netherlands 8 May 1963 (292 509)

is connected, which series connection is a periodic Signal with steep leading and trailing edges is fed.

The invention and its advantages are explained in more detail below with reference to the drawing.

F i g. Fig. 1 shows a preferred embodiment of the device according to the invention;

F i g. 2 shows some waveforms where
F i g. 3 shows a hysteresis loop to explain the mode of operation of the device shown in FIG.

The in F i g. 1 shown device for receiving pulse-shaped signals, the opposite have different polarities at a reference level, e.g. B. Double Stream Telegraphy Signals, contains one Core 1 made of magnetic material with a rectangular hysteresis loop and a number attached to the core Windings. The input winding labeled 2 is connected via a series inductance 4 an incoming double stream telegraph line 3 is connected, the line stream of which the core in excited one way or the other depending on whether a resting element or a work

509 760/307

3 4

element is received. Part of the received intersection points of the vertical branches of the hysteresis alternating current telegraphy signal is shown in FIG. 2a and the abscissa represented by / 5 in FIG. When a work element is indicated with a positive PoIa- and ζ 6. These limit values are inrity with M and a rest element with a negative sequence, the symmetry of the hysteresis loop is denoted by S , the telegraphic signal can be 5 large and only have a different sign, the signal can be denoted by MSMMS ... The effect of the sampling pulses P on the through

Wave form of the telegraph signal is symmetrical the line current magnetized core is nachzum Zero level, and the duration of the rest and standing for values of the line current explained that Work items at zero level are the same for both. lie outside the limit values, i.e. for values of the

The receiving device is galvanically separated from the line current, which is greater than / 5 or less than the telegraph line, so that z'6 are in the receiving line. It is assumed that the line device, the operating voltages to earth free current at a certain sampling time tn can be selected. Has value ζ 1 and that the magnetic effect of the

The purpose of the illustrated receiving device fed to the scanning winding at this point in time is that the original rectangular shape of the resting scanning pulse Pn is negative. During the steep and working elements to be restored under the leading edge of the scanning pulse, the magnetization of the core passes through the hysteresis of the working elements. loop very quickly from the point α through the

A sensing winding attached to the core points / and h after point b. During the 26 a periodic scanning signal with an abbreviation of traversing the vertical branch of the hysteresis scanning frequency is supplied, which is high compared to the signal loop when a large negative magnetization rate occurs. The peri- change on, and it is in an output winding 5 which is periodically reproduced on the core anodic sampling signal, a voltage-reversing sampling times, which are induced by ti, ti, t3, ... pulse with a large amplitude, whose Po are designated are plotted in Fig. 2b to the same as larity by the sign of the magnetization time scale as in Fig. 2a. Part of the change is conditional. The polarity in this periodic sampling signal is assumed to be negative in one case in FIG. 2c. During the slightly inclined trailing edge of the scanning pulse compared to FIGS. 2a and 2b, the bar is shown. With reference to Fig. 2c, the sampling current slowly decreases and the magnet passes through the sampling signal as a periodic signal with 30 tization of the hysteresis loop in the reverse direction of a periodically repeated pulse shape with alternating periods of opposite polarity slowly starting from point b via points g and e after Point α. Defined in the output winding, which pulse shape is induced by a scanning pulse during the trailing edge of the scanning pulse pulse P with a steep leading edge, a voltage pulse that has positive polarity and a slightly inclined trailing edge and by 35 rity, the amplitude of which, however, is significantly smaller than that The auxiliary pulse H following the scanning pulse is formed as that of the voltage pulse which was induced during the opposite polarity with the slightly inclined leading edge of the scanning pulse. The periodic scanning signal can, when the magnetic effect of the Abtastzeitsomit of a series of sampling pulses Pl, Pl, point in effective sampling pulse Pn is positive, PZ, ... with alternately opposite polarity 40, the magnetization passes through the saturation branch and from a number of Hilfsimpulsenifl, Hl, the hysteresis loop from the point «over the H3, ... also with alternately opposite point c and back to point a. Polarity is thought to be composed, with no major changes in magnetization, so that an auxiliary pulse always lies between two scanning pulses that follow each other - at most low interference voltages in the output winding - and the same voltages are induced. If the line current has the value il , like the sample following the auxiliary pulse, a pulse is generated during the leading edge. of a sampling pulse, its magnetic effect

In Fig. 3 schematically shows a hysteresis loop is positive, a positive voltage pulse with a large size of the magnetic core 1 is shown. In this figure, amplitude is induced in the output winding. Plotted as the abscissa of the line current and as the ordinate of 50 during the trailing edge of this sampling pulse indu magnetization state of the core. The graceful negative voltage pulse has also in this line current, on the right side of the ordinate case a significantly lower amplitude than the nate than positive and on the left side of the ordinate during the leading edge induced pulse. One accepted as negative. With certain values of the scanning pulse, the magnetic effect of which is negative for the conduction current, the core is clearly magnetized, 55 induces in the output winding at most ge and with other certain values of the line ring, interference voltages are induced. In this way, the core is not clearly magnetized. at the values of the line current which belong to a value z "1 of the line current are greater than the limit values With the values of the way, the value ζ 2 clearly belongs to the magnetization state indicated by the conduction current, which is smaller than the limit value point b . 16, positive impulses with a large amplitude in the value ζ3 belongs to that through point e or point / the output winding induced,
indicated magnetization state and the value The voltage induced in the output winding 5

z'4 of the 65 voltage pulses indicated by point g or point h with a large amplitude become in the down-magnetization state. The limit values of the dependence on the polarity on one or on the line current, between which the core is not clearly magnetized to another trigger circuit input of a bistable, approximately correspond to the trigger circuit supplied. The toggle switch will

formed by two transistors 12 and 13 with separate collector resistors 14 and 15, the The emitter is grounded and the collectors and the bases cross over the parallel connection of a resistor 16 and a capacitor 17 and the parallel connection of a resistor 18 and a capacitor 19 are connected. The flip-flop inputs are through the base terminals of the transistors educated. This bistable, known per se

the magnetization after point e , and during the leading edge of this sampling pulse, a negative voltage pulse with a large amplitude is induced in the output winding. This also applies if the line current z. B. has the value z'4, at which value the magnetization of the core is set to point g or h of the hysteresis loop.

In order to remedy the difficulties due to the ambiguous flip-flop circuit has two stable states in which io magnetization of the core contains that one of the transistors always carries current, while periodic scanning signal, as shown in Fig. 2c, the other transistor is blocked. The starting point is, between two consecutive development S is tapped in the middle, and the two strobe pulses Pn and Pn + 1 an auxiliary pulse Hn ends are via the diodes 10 and 11 with the inputs with slightly inclined edges and with the same gangs Toggle connected. The tapping point 6 of the output winding 5, like the sampling point 6 of the output winding 5 following the auxiliary pulse, is determined by a pulse P η + 1.

negative bias at the connection point The effect of an auxiliary pulse H is

biased between the resistors 7 and 8, standing for the values of the line current explained, while the tapping point for alternating currents lie between the limit values iS and j 6. It is grounded through the capacitor 9. The preload is assumed that the line current at a voltage is set in such a way that the voltage induced during the predetermined sampling time tn and the edges of the sampling pulses so that the magnetization of the core at point e of the large-amplitude pulses is set by the diodes through the hysteresis loop and further that the are left and the magnetic effect of the voltage pulses 95 and the sampling pulse P η induced at the sampling time acting on the sampling pulses is negative. If the amplitude is too small, similar to other interference voltages, the latter condition is where the diodes are blocked. If the pre-magnetization after the end of the scanning pulse voltage from one induced in the winding 5 again at point e. The magnetic effect of the voltage pulse is exceeded, in Ab- the scanning pulse P η following auxiliary simpulses H η dependence on the polarity of the output pulse 30 is positive and has such a strength that the magnevon of the diode 10 emits a pulse on the basis of the tisierung Point / is transferred. During the transistor 12 or from the diode 11 a pulse slightly inclined leading edge of the auxiliary pulse occurs after the base of the transistor 13 is passed. a large positive change in magnetization, but if the transistor in question at this point in time, by suitable choice of the edge steepness, can generate a current, the transistor will be secured by the pulse 35, that the one in the output winding at the base terminal is blocked, and as a result of the induced positive voltage pulse is smaller than the cross coupling, the other transistor becomes conductive. the bias of the tapping point 6. Select-If the transistor in question is no longer carrying any current rend the trailing edge of the auxiliary pulse no longer occurs, it remains blocked. The state of the large change in magnetization, so that the flip-flop is thus dependent on the polarity 40 rend of the trailing edge at most an interference pulse in which the output pulse and remains unchanged is induced in an output winding. The polarity of the

the sampling pulse Pn + 1 following the auxiliary pulse Hn is equal to that of the auxiliary pulse and thus has a positive magnetic effect. During this 45 sampling pulse, the magnetization passes through the saturation branch of the hysteresis loop from point / via point α to point /, and at most low interference voltages are induced in the output winding. The next auxiliary

has states and that the magnetization of the core 50 impulses the magnetization to point e, by the successive scanning pulses, whereby the voltage induced in the output winding of opposite polarity is switched back and forth between these two states. There-

Sequence of output pulses of the same polarity. The reconstructed double stream telegraphic signal is taken between the collectors of transistors 12 and 13.

With values of the line current which lie between the limit values i S and 16, the problem arises that with these current values the magnetic core has two possible opposing magnetization

are voltage pulses with a large amplitude

voltage pulses are again smaller than the bias. The effect of the auxiliary pulses can thus be summarized in such a way that it induces the scanning pulses following the auxiliary and alternately opposite polarity in the 55 pulses for the values of the output winding, which pulses make the line current ineffective between the state of the limit values i connected to the output winding S and 16 lie, always change its toggle switch. If the line current has a value greater than ζ 5

tung stream has at a sampling time in, for example, to or less than 16, reverses the magnetization value / has 3 and the magnetization of the core is set at 60 after completion of the auxiliary pulse in the through the point s of the hysteresis loop, so line current is set point of the Hysteresedie magnetization by means of a scanning pulse that loops back and has a positive magnetic effect on the auxiliary pulse M-sen, after the point / end of the scanning pulse the above-described shifted, and during the steep preliminary effect. As a result of the slightly inclined leading and edge of the scanning pulse, a positive trailing edge of the auxiliary pulses is guaranteed that

Voltage pulse with a large amplitude in the output winding induced. The next following scanning pulse, the magnetic effect of which is negative, applies

even if the line current is greater than i 5 or less than / 6, the voltage pulses induced in the output winding are less than the

7 8

voltage, so that the flip-flop are only grounded to one and their collectors and bases cross,

of the sampling times ti, ti, t3, ... switch over connected via the capacitors 24 and 25

can. are. This known astable toggle switch

The current values ΐ 5 and ζ 6 are due to the symmetry has two astable states, where in one state metry of the hysteresis loop symmetrical to zero 5 the transistor 20 and in the other state of the level, which in Fig. 2a by dashed lines on transistor21 is conductive. The toggle switch switches is interpreted so that no preference for line currents is always between these two astable states the one or the other polarity is present and the around and remains in during the same periods in Preferred deformation is minimal. The receive before one state and in the other state. By direction fulfills the same function as a mecha- io the diodes 35 and 36 become the points 29 and 30, nical polarized relay, the response values of which are grounded via diodes 31 and 32, alternate for positive currents equal to the response values for wise brought to earth potential, whereas the non-negative Currents are, with the essential grounded point, a negative voltage across the difference however, that the symmetry of the described stand 34 or 33 receives. The collector of the non-receiving device on a material intrinsic 15 conductive transistor 20 or 21 has to the time shaft founds, d. H. the symmetry of the hysteresis point at which the astable multivibrator switches over, loop of the magnetic core, and that the symmetry is the negative voltage of the feed line. Its a chip polarized relay of its mechanical voltage takes on the switching point very quickly Structure is dependent and in practice only increases up to earth potential, while the voltage of the difficult to realize completely. 20 collector of the other transistor exponentially

In practice the limit values / 5 and f 6 do not increase up to the negative supply voltage. The white-so sharply defined, since the vertical branches of the lenform of the collector voltage of a transistor has hysteresis loop to the abscissa are not perpendicular. in this way steep leading edges and if the line current increases z. B. from the value i 3 to exponentially running trailing edges. The collector to the value ζ 1 increases, the amplitude of the output voltages of the transistors 20 and 21 increases gradually via transition pulses. The two inputs of the diodes 35 and 36 at points 29 and 30 can have different sensitivities, so that those between these points have an effect, so that the trigger circuit switches a waveform with a steep gradient of a limit value earlier than in the event of an excess voltage has the leading and trailing edges. The times when the other limit value is exceeded. The 30 at which these edges occur determine the influence of the difference in sensitivity between the sampling times ti, ti, t3.

The points 29 and 30 form the connection points can be reduced by the level of the limit values of a circle, which is formed by the series / S and i 6 compared to the level of the pulse-shaped circuit of the sensing winding 26 and a damping circuit. Signal is made small, which is caused by the fact that the number of turns of the input 27, the parallel circuit thus formed in series winding 2 and the material and dimensions with the capacitor 28 is connected in parallel with an inductance. of the core 1 can be chosen appropriately. In the following, the effect of the circle between the limit values ζ 5 and ζ 6 takes place between the connection points 29 and 30 closer to two sampling times, so that the time of 40 was written. Just before the point in time at which the tran-toggling of the flip-flop circuit begins to carry current through the sistor 21, the connection duration has a period of the scanning signal compared to point 30 ground potential and connection point 29 which is shifted from the point in time when it was exceeded. negative voltage of the feed line, of the condensate - this time delay can be made very small by the sator 28 up to the voltage of the point 29 by counter-45 loading the period of the scanning signal. The charge of the capacitor in this case over the duration of the working and resting elements of the polarity of the voltage is considered positive, the pulse-shaped signal is made small or, in other words, by a high sampling frequency switching time of the flip-flop circuit ground potential , where is used. through a discharge circuit for the capacitor 28

A considerable advantage of the described recommendation 50 is concluded which discharge circuit from earth over

The catching device is that after the transistor 21, the diode 35, the capacitor

th of the limit values the hysteresis loop while 28, the inductance 27, parallel to the series connection

the leading edge of a sampling pulse to the extent of the damping resistor 37 and the sampling winding

is traversed faster than the difference between 26 and via the diode 32 back to earth

see the value of the line current and the 55 runs. This discharge circuit remains closed until

Limit value is smaller. The amplitude of the voltage at the time when the direction of the current

impulses in the output winding is then also reversed by diode 32. At this time

larger, so that the receiving device is very fast, the discharge current of the capacitor is just the same

responds when the line current exceeds the limit values of the low level flowing through the resistor 34

exceeds. 60 electricity. The series connection of the damper

It is shown on the basis of FIG. 1 a preferred design resistor 37 and the sensing winding 26 Management form of the receiving device described, flowing part of the discharge current has a pulse which is the periodic sampling signal directly of the form with a steep leading edge and a periodic signal with a steeply sloping trailing edge and thus has the Leading and trailing edges is derived. In Fig. 1 65 desired shape for a sampling pulse. The through an astable flip-flop is shown, which the inductance 27 flowing part of the discharge current Transistors 20 and 21 with separate collector increases slowly and consequently drains the resistors 22 and 23, the emitter of which is sensing winding 26 current in such a way that the Rieh-

direction of the current through the sensing winding 26 is reversed. At this point of reversal, the whole flows Discharge current of the capacitor 28 through the inductance 27. The discharge current of the capacitor 28 continues to decrease, and the magnetic energy stored in inductor 27 overdischarges the sense winding 26, the waveform of the current flowing through the sense winding 26 being the has the desired shape and polarity for an auxiliary pulse. At the time the current passes through the Diode 32 has dropped to zero, diode 32 is blocked. The capacitor 28 is then over the resistor 34 is charged in the opposite direction. The charging current flowing here has a low value and essentially flows through inductor 27. At the time the transistor 20 becomes conductive and the connection point 30 assumes ground potential, the capacitor 28 is negative charged. The phenomena described above then take place in reverse Direction. It is effected in this way that of the steep leading and trailing edges of the between the connection points 29 and 30 effective periodic signal waveforms are opposite Polarity can be derived by each as a sampling pulse with a steep leading edge and a slightly inclined trailing edge are formed, which an auxiliary pulse with slightly inclined Edges and opposite polarity follows.

The receiving device can also receive and regenerate single stream telegraph signals be used. In this case, the desired reference level is not the zero level, as with double-stream telegraph signals, but a level approximately halfway between the Zero level and the level of the line current. A bias current corresponding to this reference level is fed to an additional winding 38, the strength of the bias current and the polarity thereof can be adjusted so that the magnetic effect of a single stream telegraph signal depending on the polarity compared to the reference level is positive or negative.

Finally it should be noted that the inductance 4, which is connected in series in the telegraph line 3 is recorded, prevents the scanning pulses from affecting the telegraph line and ensures that the line impedance does not place too much stress on the input winding.

Claims (2)

Patent claims: 1. A device for receiving pulse-shaped bipolar signals with means for uniform regeneration according to both polarities, ie electronic polarized relay, characterized in that the pulse-shaped signal together with a periodic scanning signal (P) with a periodically recurring pulse shape with opposite polarity in alternating periods, which Pulse shape is formed by a scanning pulse with a steep leading edge and a flat trailing edge and by an auxiliary pulse (H) following the scanning pulse with flat edges and opposite polarity, applied to windings attached to a core made of magnetic material with a rectangular hysteresis loop, whereby each auxiliary pulse has sufficient strength to switch the magnetization state of the core at the value of the pulse-shaped signal in which the core is not clearly magnetized, and then to an output winding A circuit with two stable states of equilibrium responsive to the polarity and amplitude of the output pulses induced in the output winding is connected, the period of the scanning signals and auxiliary pulses being small compared to the length of the received pulses. 2. Apparatus according to claim 1, characterized in that for deriving the scanning signal from a periodic signal with steep leading and trailing edges The sensing winding attached to the core connected in series with a resistance of an inductance is connected in parallel that the parallel connection is connected in series with a capacitor and that the series connection produces a periodic signal with steep front and trailing edges is supplied. 1 sheet of drawings 509 760/307 12.65 © Bundesdruckerei Berlin