DE844323C - Method for the multiple transmission of signals through pulses - Google Patents

Description

Method for the multiple transmission of signals by means of pulses The invention has a method of transmission from Si gna'.eii on several communication channels through interlocking features of recurring the impulses to the object, which the principle according to the time division and the modulation the pulse position used. In particular, the process of creation finding on multiple systems with time-divided Impulses in which each character impulse has two is subjected to superimposed modulations, the both its temporal position with respect to predetermined Influence reference times, but one exclusively depending on the one modulation signal corresponding to one channel, the other acting as a function of the totality of the modulation signals corresponding to all or several other channels.

As is known, in various known methods for multiple transmission with time-divided pulses, the total time of the transmission is divided into equal time intervals of duration T, which are themselves divided into equal and shorter intervals of time elements T / (N-i), where N is the number of Connection channels and an (N + i) -th interval of the time element is reserved for a synchronization signal. This signal, which is usually referred to as a: s synchronization pulse, s and which is not subject to any modulation, is given a special form through which it can be easily identified by the receiving devices and which is used to synchronize these devices. All of the time intervals reserved for each channel need not be the same, but this arrangement is generally chosen because it is easier to implement.

In such systems, within each time interval of a channel a pulse is generated, its temporal position as a function of the instantaneous amplitude of the corresponding channel modulation signal is changed. Under "temporal situation" of a pulse is to be understood as the time interval between a reference point in time, that in relation to the ends of the duration of the time interval allocated to a channel is fixed, and the point in time at which this pulse occurs, if it is of very short duration. If the impulse has a significant duration, that serves Time of the start of this duration to define its temporal position, which in hereinafter referred to as "location" for short. The totality of all transmitted in time T. Impulse is called an »impulse group«. The entirety of those corresponding to a given channel Impulse is referred to as an "impulse train".

Such multiple transmission methods offer numerous advantages; However, they have the disadvantage that, in the case of a system with a large number of channels, do not partake of the statistical advantage that is associated with the multiple systems Carrier currents are present which use amplitude or frequency modulation, since every time element interval allocated to a channel remains completely underutilized, if there is no modulation signal in this channel at a given moment.

The statistical effect mentioned was particularly evident in a work entitled “Load rating theory for multichannel amplifiers” by BD Ho 1 b no ck and j. T. Dixon investigated, which appeared in the journal "Bell System Techniral Journas" of October 1939, Vol. XVIII, pp. 624-644. The results of this work are figures that relate to the extent of the statistical effect mentioned. It should be noted that in the case of telephone transmission, the peak of the signal is seldom reached and that if it is limited by clipping so that the clipping value is reached during 90% of the time, an instantaneous value is present for 90% of the time that falls below or reaches a quarter of the vertex clipping value. In the case of a pulse system which uses position modulation, this comes down to the fact that three quarters of the duration of the time interval allocated to each channel are generally unused. In a system with a large number of channels, where it must be taken into account that the modulations of the various channels do not add arithmetically but according to the laws of probability, this effect is even more pronounced. To exploit this statistical effect, systems have therefore been proposed in which the duration of a time element interval is reserved for the symbol pulse corresponding to a channel only during the time when this total duration is actually used, which makes it possible to display the following symbol pulse during the supplementary time to approach them.

In the case of a system that makes use of this possibility the number of connection channels transmitted increases in proportion to the number that is given with the usual systems, or it could be the other way around for a fixed channel number the value of the displacement of the position of a character pulse and consequently the signal-to-noise ratio can be increased.

The aforementioned option has already been suggested for certain Systems exploited for multiple transmission. Such a system is described in French patent specification 946 345, according to which the current I_a "e of a Channel pulse by the set of modulations of a certain number of others Channels is influenced, and in German Patent 91595o, the pure variant concerns, in which the modulation imposed on each impulse is derived from the norma'.en Telefonicwechsel @ elstromsignal composed of which one of the ampliitude of this signal proportional direct current component is added, as is the case according to the French Patent 870,474 was proposed.

These various proposed systems have the common characteristic da. (while in the absence of any modulation the N Zcicheti impulses of a system with N channels near one end of the time interval reserved for a pulse group T are grouped and therefore only occupy a small part of this time interval, the position modulations of the impulses of the various channels have an additive character exhibit. For example, suppose that in the absence of any modulation, the Set of character pulses in the vicinity of the synchronization pulse at the beginning of the time interval T is grouped, the modulation of the first channel becomes the Current position of the corresponding character pulse in relation to the synchronization pulse shift, the modulation of this second channel becomes the location of the corresponding one Impu ', ses around a quantity proportional to this modulation with respect to the instantaneous Shift the position of the pulse corresponding to the first channel, etc.

In short, the modulation cincs given channel is proportional represented by the time interval nvi the one corresponding to this channel Impulse and the previous impulse, the latter in the case of the first Channel is the synchronization pulse (cf. the publication »Te: emetering fron V-2 Rockels «by V. L. H e re n and others. in the magazine »Electrotiics« from March 1947, p. Too, especially Fig. 4). Due to the above-mentioned statistical Effects can then be applied to each character pulse for the same modulation signal one give greater shift in position than would be the case if d.'cs, he character impulse always within a time interval that can be changed to the corresponding channel should remain.

With the various impulse transmission systems, which these additive Using the type of modulation, it also has to be, if the modulation to be transmitted is a telephony signal or a similar signal with an alternating current character than proved advantageous to add a direct current component to it that is approximately proportional to the instantaneous amplitude of that signal. This arrangement offers the advantage that the modulation signals are then given a unipolar character, with the corresponding Shifts in the position of the impulses are of irrelevant magnitude, but are always of the order of magnitude "! take place in a direction. As can easily be seen, this is a necessary one Condition when considering the statistical effect for both the positive. as well as wants to use for the negative half-change of the telephony signal.

The various known methods for carrying out this type of operation of impulse transmission, however, have in their implementation and in particular Certain difficulties with the demodulation of the signals by the receiving devices.

The invention has a method of transmission (sending and receiving) to the subject that avoids these difficulties. The method of the invention is at the same time a special transmission method, which is carried out in a simple manner enables the transmission type described above, and a receiving method which the restoration of the channels originally imposed on the various channels of communication Modulation signals are permitted by means of a special selection device, with it is taken into account that the time element intervals assigned to each character pulse train With this transmission system there are no fixed positions with regard to the synchronization pulses or with respect to predetermined reference times.

The method of the invention is characterized in that in the Transmission in equal time segments with the frequency of the pulse groups the momentary : 'Amplitude of each to be transmitted. Modulation signal measured and the so measured Amplitudes during a certain period of time, which is preferably equal to the duration of a Pulse group is to be retained; the one corresponding to the first connection channel maintained amplitude is used to determine a time interval that is from the synchronization pulse or from a reference time track which is related to this synchronization pulse is fixed, counts and the maintained amplitude is proportional to which corresponds to your first connection channel; at the end of this Time interval, a first symbol pulse is healthy, which corresponds to the first channel; this first pulse and the maintained amplitude, which corresponds to the second Kair; rl, are used to initiate the initiation of time, that of this first impulse counts out and is proportional to this retained amp; itude corresponding to the second channel is; at the end of this time interval: a second character pulse is sent, and the procedure is carried out in the same way until all channels and all are exhausted Character pulses continued; thereby the transmission of the various character impulses staggered in time in such a way that, even in the absence of any modulation, two different character impulses can never coincide in time.

When receiving, the synchronization pulse is first applied by known means separated from the other pulses and used to produce locally generated pulses or auxiliary pulses with a constant frequency, which correspond to the frequency of the pulse groups is the same, used; the successive time intervals which the character pulses separate, are measured, and electrical quantities are derived from them, which are proportional to these time intervals and are recorded in separate circles, in the same number as these time intervals and consequently as the connection channels are provided; these electrical quantities are maintained for a certain time and used to generate the auxiliary pulses with constant frequency in amplitude or To modulate duration and proportionally to these quantities; these auxiliary impulses are demodulated by known means to obtain signals that are original Modulation signals are proportional, and the results of the demodulation will be supplied to the useful circles.

With the usual modulation methods that are used to carry out the same Transmission type are determined, a crosstalk is on each connection channel introduced by the fact that the time, which two successive fo.lgend@e decompositions of the modulated signal during transmission and two successive restorations this same modulation signal separates when receiving, is not constant.

The advantage of the method according to the invention is that the Time, what two decompositions or two consecutive restorations of the same modulation signal of a channel is constant, although the time which two consecutive characters corresponding to the same channel i-mpu '.; s @ e separates, is variable according to the chosen transmission principle.

Applying a common principle for measurement and storage in the case of transmission and reception, it is possible in the method of the invention the instantaneous amplitudes that are tapped from the modulation signal, to reproduce the same distance on arrival and departure. It is then always possible, however large the number of channels may be that each To make maximum use of the time reserved for drawing impulses, be it to improve the signal-to-noise ratio to improve, be it to reduce the passband required for transmission. Further Details and advantages of the invention will emerge from the following description of exemplary embodiments on the basis of the drawing. In the drawing, Fig. I is -ein schematic circuit diagram of an embodiment of the arrangement for performing the Method according to the invention, Fig.2 as a function of time the diagram a modulation signal, as it is usually z. B. present in a telephone circuit is, Fig.3 as a function of time, the diagram of a modulation signal with superimposed direct current component as used in the method of the invention shall be; Fig. 4 shows on line A the temporal positions of the tendons larger amplitude differentiated synchronization pulse as well as the character pulse with respect to the ends of a time interval of equal duration as that of one Impulse group, in the case where there is currently no connection channel a modulator signal is present, while on line B the temporal positions of the same Pulses are shown when modulation signals @ e occur on the connection channels; Fig. 5 shows schematically a measuring and storage device for the transmission system according to Fig. I, which is suitable for determining the amplitude of a modulation signal or the measure and maintain the time interval occurring between two character pulses; Fig. 6 is a diagram of the between different points of the transmission system existing tensions.

In the following description as well as in the figures, the To simplify the explanation, assume that the transmission system has only three connection channels and that the modulatory signals are telephony signals. The invention is but also in systems with a much larger number of connection channels or applicable to the transmission of other types of link signals.

The mode of operation of the arrangement according to Fig. I can be explained as follows: The modulation signals coming from three connection channels are fed to three devices 104, 105 and io6 at ioi, 102 and 103, which add the direct current component that is required to them by known means, to make them unipolar and to transform their appearance according to Fig.2 into that of Fig.3. At the output of 104, 105, io6, the changed signals are each fed to an input of the three measuring and storage devices 107, 108, iog, the mode of operation of which will be explained in detail later. On the other hand, these measuring and storage devices are provided with two series of periodic pulses fed, which come from a generator ii o of short-term pulses, which they emit with the period T of the pulse groups, ie with the frequency of the synchronization pulses. Coming from i io pulses are supplied as decomposition pulses via a delay network i L i according to a second input of each measuring and storing device 107, 108, 109, and on the other hand directly supplied as reset pulses to a third input of these devices to make it at the end of each working period T in Put to sleep. The measuring and storage devices have the task of measuring and maintaining the instantaneous amplitude of the changed modulation signals which are fed from io4, io5, io6 to one of their inputs for a certain time, which is slightly shorter than the duration of a pulse group. The instantaneous amplitudes retained appear in the form of electrical voltages at the output of 107, 108, 109 and are fed to pulse position modulators 1 12, 1 13 and i 1 4 of the usual type. Since the delay achieved by the network iii has a low value and only aims at a clear separation of the point in time at which the signals coming from io4, io5, io0 are measured from the point in time at which the synchronization pulse is generated, electrical voltages occur at the outputs of 107, 108, 109 for almost the entire duration T of each pulse group, the magnitude of which is proportional to the respective maintained amplitudes of the modulation signals. These electrical voltages are referred to below as stored modulation signals.

The Lagemodu: ators 1 12, 1 13, 114 have the task of determining the point in time or the temporal position of the pulses fed to its other input by one Delay amount proportional to the stored modulation signals which are fed to one of their inputs. The basic structure and the operation of such position modules, ators are known per se in pulse technology. As is well known, capable pulses are usually differentiated generated by duration modulated pulses, and methods are numerous known for duration modulation, which can be used here. For example is the method described in French patent 912 617 can be used.

According to Fig. I, the position modulator i 12 corresponding to the first connection channel is fed on the one hand by the stored modulation signal, which comes from 107, and on the other hand with a control pulse that is delayed by an amount with the help of the delay network iii with respect to the synchronization pulse, which exceeds the delay given to it by part of the network iii of the splitting pulse fed to the second input of 107 in relation to the synchronization pulse, so that the position modulation in the modulator i 12 only after the end of the measurement in the measurement - and storage device 107 is going on.

As a result, a symbol pulse is generated at the output of i 12, which on the one hand is fed to the mixer 117, the use of which will be explained later, and on the other hand, after a slight delay by a delay i; etz «-crk i 1 5, is fed to an input of the lag modulator i 1 3, at the other input of which the stored modulation signal is fed, which comes from lob and corresponds to the second connection channel. A second character pulse is thus obtained at the output of 113, which is delayed in relation to the first by an amount which is proportional to the amplitude stored by 108. This second pulse is in turn passed to 117 and, after a slight delay, is used in the same way as the first pulse in connection with 113 by a delay network 116 in connection with the third position modulator 114.

All pulses together are fed to a mixer 117 which, as can be seen from Fig. 1, four inputs, which the synchronization pulse and correspond to the character pulses and have an output. This mixer stage is a simple device through which one and the same output circuit signals, which come from several input circuits can be supplied. The delay networks 115 and 116 are therefore required; i because when on one or more connecting channels the modulation signals are temporarily zero, avoiding soot that the various Impulses can mix.

The pulse group starting from 117 then becomes the transmission channel 1118 and transmitted by any known means to its end of reception.

When receiving, the impulse group is initially two devices in parallel supplied, of which the first, 119, selects the synchronization pulses and local Synchronization pulses with the period T s, ow: e auxiliary pulses of the same period, whose task will be explained later is generated. The second device, 120, is one with Counting working pulse selector which has as many outputs as Connection channels are present, and at their output with the ordinal number n provides a derived signal whose amplitude is constant and whose duration is the same is the duration which separates the (it-1) -th and the n-th symbol pulse.

Such a device consists of as many twin tube flip-flops with two stable states according to E c c 1 e s - J o r d a n, like connecting channels are available, with each flip-flop connected to the e: 1lcm output of the device is. It also has two entrances. The sync pulse and the character pulses are fed to all flip-flops at the same time through the first input of the device. A special impulse, hereinafter referred to as the reset impulse and none other than that of 1 1 o outside the, through the delay network 125 delayed synchronization pulse, is generated by the z% @ citcn input of the device fed to the first flip-flop.

The reset pulse brings the first toggle switch into the working position. The synchronization pulse and the character pulses bring the flip-flop which is in the working position, into the resting state. In addition, the flip-flop that has been put into the idle state to the following flip-flop -a so-called @ annt @ er step change impulse sent over a step change, el connection, which brings this Kippscha'tung into the working state. Between the last and the However, no step change connection is provided for the first toggle switch of the device.

The mode of operation of the arrangement is the Iolgellde: The reset pulse puts the first flip-flop in the working state. The first Zei ', cnimpuls puts this first flip-flop in the idle state. At the same time, a step change pulse puts the second flip-flop in the working state. At the first output of the device a derived signal of constant amplitude is picked up, the duration of which is equal to the time interval which separates the reset pulse from the first symbol pulse.

The second character pulse offsets the second flip-flop that is was in the working state, in the idle state. At the same time, a step change impulse displaces the third toggle switch in the working state. At the second output of the device a derived signal of constant amplitude is taken, the duration of which corresponds to Time interval is equal to which the first character pulse from the second character pulse separates. The working method continues s: I in the same way with the. other tilt positions away. If, however, the it-th character pulse the n-t @ e flip-flop switch to the 'idle state offset, no step change is made: impulse is given to the first flip-flop, and this soot wait for the arrival of the reset pulse to get into the working state to pass over.

Counting selectors such as 120 are for example written by L. L. R a u c h in an essay "Etectronic eommutation for telemetering" which was published in the magazine "Electronics" in February 1947 is.

In the case of a system with a small number of channels, 120 could also be used Use a selection device whose mode of operation depends on the shape of the character pulses is based, which accordingly depends on its ordinal number when it is sent Would get shape ..

The second inputs of 122, 123, 12.1 are derived through the Signals fed which come from the outputs of 12o. The duration of the one These outgoing signals is equal to the time that your impulse of this The output of the corresponding channel and the immediately preceding pulse, and consequently equal to the instantaneous value of the modulation signal corresponding to this channel. The measuring and storage devices 122, 123, 124 measure and store accordingly, in form of voltages occurring at their outlets, quantities that affect the duration of the signals, which come from the corresponding departure of 12o, and consequently the instantaneous Amplitude of the corresponding modulation signal are proportional. As with the The broadcast will be the Measuring and storage devices 122, 123, 124 periodically put to rest by the reset pulse, which is her third Input is supplied and delayed somewhat by the delay network 125. This The purpose of the delay network is to avoid that the measuring and storage devices in be put to sleep before their output voltage by the following Devices could be exploited with auxiliary pulses generated by the synchronization pulse are derived, are fed.

The output voltages of 122, 123, 124 are then the input of Modulators 126, 127 or 128 supplied, which the pulses in amplitude or Modulate duration and on the other hand be fed with periodic auxiliary pulses, derived from the delayed synchronization pulse emanating from i i 9 are. The signals received at the output of 126, 127, 128 are therefore proportional modulated to the original modulation signals and can then use the demod: u'iat-oren 129, 13o and 131, respectively, where they are demodulated according to the amp'.itude or duration and finally to the useful circuits 132, 133 and 134, respectively.

The mode of operation of a measuring and storage device is illustrated in Fig. 5 explains, which shows this device schematically, as well as on the basis of the diagram of Fig.6, which shows the change over time at various points in the transmission system shows occurring tensions.

As mentioned, the measuring and storage device shown schematically in Fig. 5 has three inputs and one output. If its first input a time-varying Voltage and its second input a periodic decomposition pulse is supplied a voltage occurs at its output terminals that corresponds to the value of this over time change the voltage at the moment of the application of this disintegration: impuls.es is proportional. This voltage at the output terminals of the device is saved until the moment when the third input of the device receives a reset pulse; see chap is fed to return to the rest position.

The measuring and storage device essentially consists of e: ii: he pentode tube 5oi, a diode 502 and a triode 5o3. The first input of the device is formed by the terminal 504, which is connected to the braking grid of the tube 5o i through the capacitor 5o5. The second input is formed by the Wemmae 5o6, which is connected through the capacitor 507 to the control grid of the tube 5ot. The third input is terminal 5o8, which is connected to the grid of triode 503 through capacitor 5o9. The braking grid of the tube 503 and the grid of the tube 503 are connected by resistors 5io and 511, respectively, to the negative pole 512 of a high-voltage direct current source 5t3 which feeds the entire arrangement. The control grid of the tube 50 i is connected through a resistor 514 to the cathode of the same tube. The voltages fed to the various inputs are between 50.1, 506 or 508 on the one hand and 512 on the other.

The cathode of the tube 5o i is connected to 512 by a resistor 515 with a parallel connection of a capacitor 516 to the Fntkopp ', uiig and also by a resistor 51; connected to the positive pole of the current source 513 in order to give this cathode a suitable permanent polarization. The screen grid of the tube 5o1 is fed by the same positive pole through a resistor 518 and decoupled from 512 by a capacitor 519. The anode of the tube 5o i is connected through a capacitor 520 to the positive pole of the current source 513 and also to the cathode of the diode 502 , the anode of which is connected directly to the anode of the triode 503 and via a resistor 521 to the positive pole of 513 . The output terminals of the device are terminals 522, 523 of this capacitor 52o.

The mode of operation is as follows: If at 506 control pulses, s, e are supplied with a sufficiently large positive amplitude, the control grid of the tube takes 507, fa: If the arrangement 507 to 5 t 4 has a time constant which is related to the return period This pulse is sufficiently large to have a mean voltage such that the apex of the pulses corresponds to a metal voltage which approaches the potential of the cathode, while the cathode current is zero in the time separating the pulses. Under these circumstances, the tube 5oi works in a linear part of its anode current / braking grid characteristics at the time of the apex of the control impulses, and a voltage occurs at the terminals 522, 523 of the coil 52o, which corresponds to the instantaneous value is proportional to the voltage applied at 5o4. This voltage is stored until the moment when the capacitor 52o is discharged via 502 under the action of a pulse of negative polarity which is fed at 508 to the grid of the tube 503 via the capacitor 509 for restoration.

For use in the broadcast, the device is set up so that the decomposition pulse, which from the generator i io after the through a section delay caused by i t t is obtained a little after the reset pulse which is none other than the synchronization pulse supplied by i io. The amplitude of the from toi, 102 or toi and through 104, 105 or io6 changed mod; ation: ssiignals is then periodically a little after the occurrence each decomposition pulse and at the output terminals of i o; , i o8 hzw. i o9 to stored for the occurrence of the following decomposition pulse.

If the device is used for reception, no signal is fed to the first input, while the second input receives the Sigiia'c coming from the counter i 2o. The charge accepted by the capacitance 52o is then proportional to the duration of these signals, ie ultimately proportional to the: lugenh1icl; s value of the modulation: gn; ils. The way in which a measuring and storage device works when sending or receiving is explained with the aid of Dep. 6; this shows on line A as a function of time the diagram of the pulses that are fed as reset pulses to the third input of a measuring and storage device for the shipment, line B as a function of time the diagram of a reduced modulation signal, as it is the first input this measuring and storage device is supplied during the shipment, line C as a function of time the diagram of the dismantling elements that are fed to the second input of this measuring and storage device for shipment, line 1? Depending on the time, the diagram of the signals that are picked up at the output of this measuring and storage device for transmission, their amplitude counting from the upper horizontal line, Liiliie E as a function of time the diagram of the pulse groups, di, e am Input of the receiver 2, send of the transmission system are received, where pi, p2, p;,. .. diic control pulses, a ", a,. .. the pulses corresponding to the first connection channel and the first, second ... group and a = ,, a. =., ... those of the second connection channel and the first, impulses corresponding to the second ... group are etc. 'Her @ c1-ätcs 122, the duration of these signals is equal to the Zrit, which is the reset pulse of the selection device 120 (pulse of the line H, which is also the reset pulse of the measuring and S1 cichcrgci-ätes 122) from the first character pulse with other - \ advantages, the duration of the Sin -al fed to the second input of 122 is not equal to the duration which separates the synchronization pulse (such as p, indicated on the line F at x1) from the first symbol pulse, it is rather by circumcised a constant time, the derjeni which separates the synchronization impulse from the reset impulse of the selection device 120, db equals the delay introduced by the device c25. and storage device 123 for receiving input signals; the duration of these signals is equal to the time that separates the first character pulse (how old) from the second character pulse (.a "), line H as a function of the time the diagram of the reset pulses, which the third input of the various measuring and storage devices line I as a function of time is the diagram of the voltage obtained at the output of the measuring and storage device 122, the amplitude of which is counted from the upper horizontal line, line I as a function of time is the diagram the voltage obtained at the output of the measuring and storage device 123, the amplitude of which is counted from the upper horizontal line.

The lines A, B, C, D of Fig. 6 show the working sequence of the system for measuring and storing the instantaneous amplitudes of the modulation signals during transmission.

The lines E to l in Fig. 6 illustrate the operation of the receiving system.

The one taken from the output of the measuring and storage devices 122 and 123 Tension is shown on lines I and J of Figure 6, with those on line H shown reset pulses against the synchronization pulses delayed so that the auxiliary pulses acting on the modulators 126, 127 and 128 are temporal do not coincide with the reset pulses, which would result in: ß the voltage obtained at the output of the measuring and storage device at the moment would be reduced to zero wherever you want to use them.

The invention is not limited to the exemplary embodiments described limited, rather other circuit arrangements could be used, to realize the basic idea of the invention. i

Claims (1)

PATENT CLAIM: Method for multiple transmission through interlocking, Time-divided pulse trains using consecutive pulse groups, each of which has at least one periodic sync pulse and symbol pulses in the same number as the connection channels, the character pulses in the position and the time interval between two successive ones Pulses proportional to the instantaneous amplitude of the modulation signal of the channel is to which the second of these pulses is assigned, and this amplitude before is changed by adding a direct current component to the modulation signal to make unipolar, characterized in that periodically when the broadcast instantaneous amplitude of each changed modulation signal measured and that measurement result thus obtained is stored for a time which is approximately the Duration of a pulse group is the same; the amplitude stored in this way is used for the control a pulse position modulator is used, and this is controlled by a synchronization pulse fed, which is delayed by such an amount that the Lagemodulatiion . takes place only after the end of the measurement in the measuring and storage device and this Pulse for the first channel from the generator for the periodic synchronization pulses and for the other channels from the output of the position modulator of the relevant one Channel immediately in time previous channel is delivered; Upon reception, signals are generated, the amplitude of which corresponds to the time intervals between is proportional to two consecutive received pulses; these signals will be depending on the atomic number of the impulses, they are fed to different circles, and they are used to generate periodic auxiliary pulses resulting from the received synchronization pulses derived «> ground, to modulate in amplitude or duration, and the modulated in this way Auxiliary pulses are demodulated so that signals are obtained which correspond to the original, modulation signals corresponding to each connection channel are proportional.