NO143555B - PROCEDURE AND DEVICE FOR AA REGENERATE IT FOR TRANSFER ORING USED SIDE BANDS OF A SUSTAINABLE DIGITAL SIG - Google Patents

Description

The invention relates to a method for regenerating the sideband used for transmission of a carrier-frequency digital signal that exists in a pseudo-ternary code, and which is produced using a carrier oscillation with a frequency equal to an entire multi-

plume of half the bit sequence frequency of the digital signal, and whose phase is shifted by 90° in relation to the phase of an oscillation which occurs in the digital signal with a frequency equal to half the bit sequence frequency and also relates to devices for carrying out this method.

Investigations of transmission lines for low-frequency and carrier-frequency signals have shown that digital signals can also be transmitted over these transmission lines. To avoid disturbing

In view of the low-frequency and carrier frequency transmission, the digital signals are additionally amplitude modulated with a carrier oscillation of a suitable frequency and thereby converted to a higher frequency range. With a view to better utilization of the transmission capacity of the transmission line, only a single sideband of the carrier-frequency digital signal that occurs during the modulation is transmitted, namely, as a rule, the upper sideband. During the transmission over the transmission path, the energy level of the carrier frequency digital signals drops due to the path attenuation, and at the same time the noise level rises due to incoming disturbances. It is therefore necessary to regenerate the carrier frequency digital signals at regular intervals in order to bring the signal-to-noise ratio to an optimal value.

It is now conceivable to convert the carrier frequency digital signal back from the transmission layer to the baseband layer and regenerate the resulting digital signal with respect to time and amplitude in a regenerator of a known type. For the conversion to the base rent, a carrying fluctuation is needed which is not transmitted with, and which therefore has to be produced on the receiving side. To ensure the pulse transmission, not only the frequency, but also the phase of the carrier oscillation of the carrier oscillation produced on the receiving side must agree with that of the transmitting carrier oscillation. For derivation of the carrier oscillation, use has been made of the digital signal that appears in the regenerator. But in that connection, when certain pulse sequences are transmitted, several stable phase positions and thus ambiguities can occur which can lead to missynchronization of the carrier oscillation. The ambiguity arises from the fact that the signal form of the converted signal is dependent on the phase position of the carrier oscillation used for the conversion. If this carrier oscillation is derived from the converted signal, however, different pulse sequences lead to different carrier oscillation phases and thus to erroneously regenerated bits. Preventing missynchronization of the carrier oscillation with certain pulse sequences is certainly possible by using special catch couplings, but these become very expensive.

Also in the case of the carrier-frequency digital signal being regenerated in the transmission layer, which is also possible if the digital signal is in a pseudo-ternary code and where, in the carrier-frequency modulation, a carrier oscillation is used with a frequency that is an integer multiple of the digital signal's half the bit sequence frequency, and whose phase is shifted by 90° in relation to the phase of an oscillation that appears in the digital signal with a frequency equal to half the bit sequence frequency, one encounters difficulties when it comes to synchronizing the phase of the carrier oscillation.

It is therefore a task for the invention to develop a method of the kind indicated at the outset, with which it becomes possible to achieve a clear synchronization with all pulse sequences and at the same time dispense with special catch couplings. According to the invention, this task is solved by the received sideband being subjected to distortion correction and amplification and at the same time adding a modulation device and a device for beat and carrier oscillation derivation, in which beat and carrier oscillations whose frequencies are whole multiples of the half bit sequence frequencies, are derived from the received and corrected sideband, and where a first clock oscillation with the lowest frequency is supplied to the modulation device and another clock oscillation with a frequency doubled in relation to the first is supplied to a time regenerator, that the received and corrected sideband in the modulation device is converted into a regenerable digital signal and supplied to an amplitude regenerator, and that the amplitude-wise regenerated signal is supplied to the time regenerator and regenerated with regard to time.

The invention is based on the realization that ambiguities in the carrier oscillation synchronization can be avoided if the beat and carrier oscillations are derived from the received and corrected sideband, i.e. in the signal path before a signal turnover by means of a carrier oscillation.

The main advantages of the method according to the invention lie in the fact that the individual method steps involve relatively little expense,

and that because missynchronizations are safely prevented, there is no need to take extra precautions that exclude certain unfavorable pulse sequences, e.g. a 1-0-1-0... sequence.

In the preferred embodiments of the method according to the invention which will be described in the following, the upper sideband of the carrier frequency digital signal is used in any case for the transmission, as this results in a lower noise level in parallel-running lines for low-frequency and the carrier frequency transmission.

A first preferred variant of the method according to the invention results from the fact that the received, corrected and amplified upper sideband is converted into a regenerable digital signal into the baseband in the modulation device. This preferred variant has the advantage that the digital signal converted to the baseband can be regenerated with regard to amplitude and time with the known baseband regenerators.

Another preferred variant of the method according to the invention results from the fact that the received, corrected and amplified upper sideband, in order to be converted into a regenerable digital signal, is converted into an intermediate layer which is shifted by an integer multiple of half the bit sequence frequency in relation to the digital signal's baseband layer. This method has the advantage that, with the selection of the intermediate layer, it is possible to select the frequency plane for the digital signal within certain limits and thereby adapt it better to other transmission devices, e.g. radio devices.

A third advantageous variant of the method according to the invention, where the signal remains in the transmission bed and where no renewed conversion to the transmission bed is therefore required after the regeneration, is obtained by the fact that a lower sideband is produced in the modulation device from the received, corrected and amplified upper sideband which is combined with the upper sideband to form a regenerable digital signal. In order to produce the lower sideband in the modulation device, a carrier oscillation produced on the receiving side is also needed in this case, so there must also be a derivation of a carrier oscillation from the received and corrected sideband.

For many application cases, it is appropriate that there

for beat and carrier oscillation derivation, an oscillation is produced which is synchronized with the received sideband.

In a particularly simple variant of the method according to the invention, it is possible to save the oscillator for oscillatory generation, since for clock and carrier oscillation derivation from the received, corrected and rectified sideband, an oscillation with a double bit sequence frequency is filtered out.

A device in accordance with the invention for carrying out the method according to the invention appears in that a first correction element is connected to the signal input via a first bandpass filter, the output of which is connected both to the input to a modulation device and to the input to a device for clock and carrier oscillation derivation, that the output of the modulation device is connected to the input of a regenerator known in and of itself, containing a first amplitude regenerator directly connected to the input and a time regenerator which is directly connected to its two outputs, and which with its two outputs emits regenerated pulses each with its own polarity of the regenerator's input signal as a unipolar pulse sequence to the output connections, that the device for clock and carrier oscillation derivation contains a series connection of another correction element, which is connected to the output of the first correction element via the input, a first time delay element, a rectifier, another amplitude control nerator with only one output, a phase discriminator, a generator, a first pulse shaper and a frequency divider, and where the output of the first correction element is additionally connected to a first output, the output of the first pulse shaper connected to the frequency divider is additionally connected to a second output, a further output from the first pulse shaper is connected to the phase discriminator's clock input, and the frequency divider's output is connected to a third output from the device for clock and carrier oscillation derivation, while this output is also connected to a carrier oscillation input to the modulation device and to a carrier oscillation output, that the other, output from the device for clock and carrier oscillation diversion via a clock input to the regenerator is connected to a clock input to the time regenerator and to a clock output, that a first amplifier is arranged whose output is connected to the control input of the first correction link, and whose input after choice is associated with the output of the first correction link, with the output of the modulation device or with the first output from the device for beat and carrier oscillation diversion, while another input to the modulation device can also be connected to this output.

A particular advantage of this device according to the invention lies in the defined initial conditions, which ensure a quick take-up of operation after switching on.

A modulation device which between its signal input and its signal output contains a series connection of a first modulator, a first low-pass filter and another amplifier, and to whose carrier input the first modulator's carrier input is connected via a series connection, is useful for converting the carrier frequency digital signal to the base layer of another band-pass filter, a third amplifier and another time step.

With this arrangement, the conversion to the baseband is therefore carried out by modulation with a single carrier oscillation, i.e. with only a small expense. In this connection, particularly strict requirements must be placed on the first low-pass filter, including e.g. the requirement for the possibility of a post-vote.

The conversion of the carrier-frequency digital signal to the baseband layer can also take place by a double conversion with two modulators and two different carrier frequencies. A modulation device is thus obtained which requires somewhat more equipment, but in return is less critical, and which between its signal input and its signal output contains a series connection of another modulator, a third band-pass filter, a third modulator, a third low-pass filter and a fourth amplifier, and where the modulation device's carrier input is connected to the second modulator's carrier input via a second pulse shaper and a series connection of a fourth bandpass filter, a fifth amplifier and a third time delay stage, and is connected to the third modulator's carrier input via a further output from the second pulse shaper and a further series connection of a fifth bandpass filter, a sixth amplifier and a fourth delay stage.

For the regeneration of the carrier-frequency digital signal in the transmission layer, the lower sideband can be produced by means of a carrier oscillation generated in addition, in a modulation device where the signal input is connected to the first input of a coupling link via a fifth step-stage link and the signal input is connected to the second input to the coupling link via a fourth modulator, if the signal output of the coupling link via a fourth low-pass filter is connected to the input of a seventh amplifier, at the same time as the output of an amplifier is connected to the signal input and the modulation device's carrier oscillation input is connected to the fourth modulator's carrier oscillation input via a sixth time delay link.

In the following, the invention will be explained in more detail by means of execution examples which are illustrated in the drawing. Fig. 1 shows a device according to the invention for regenerating carrier frequency digital signals. Fig. 2 shows a modulation device according to the invention for individual conversion of the carrier frequency digital signal to the baseband layer. Fig. 3 shows a modulation device according to the invention for double conversion of the carrier frequency digital signal to the baseband layer, and

fig. 4 shows a modulation device according to the invention

to produce the lower sideband of the carrier frequency digital signal in the transmission layer.

The device shown in fig. 1, serves to regenerate the upper sideband used for the transmission of a carrier frequency digital signal. This upper sideband comprises the frequency range 0.5 > U < 1.5, where fi denotes the frequency ratio f:fT referred to the bit sequence frequency fT. This frequency range also corresponds to the pass-through range of the first bandpass filter BP1, which is connected to the signal input 1 and in particular keeps the low-frequency disturbances away from the input of the subsequent first automatic correction element El. On the basis of the attenuation increasing with frequency in the cable, which in the present case is a cable of type 17a, the attenuation characteristic of the first correction term El was set so that the attenuation decreases with increasing frequency and where all in all a linear transmission of the signal amplitudes in the frequency range of interest. From the output of the first correction element El, the corrected and additionally amplified signal is supplied to both the signal input A of a modulation device M and the signal input E of a device TA for beat and carrier oscillation derivation. In the modulation device M, the received, corrected and amplified upper sideband is transformed into a regenerable digital signal. Possibilities for carrying out this transformation are visualized in more detail in Figures 2-4.

From the output D of the modulation device M, the now regenerable digital signal is supplied to the signal input K of the actual pulse regenerator R, which in a known manner consists of a first amplitude regenerator ARI and a time regenerator ZR. In the first amplitude regenerator ARI, the supplied signal, which is in a pseudoternary code, and whose amplitude values can thus be +1 and -1, is split into two unipolar pulse sequences and the amplitude of these pulse sequences is simultaneously regenerated. The first unipolar pulse sequence is composed of the input pulses with positive amplitude, and the second pulse sequence is composed of the input pulses with negative amplitude. These two pulse sequences are separately fed from each of the two outputs of the first amplitude regenerator ARI to each of the two inputs to the time regenerator ZR. This time regenerator, which in a known manner e.g. can consist of two D flip-flops connected to each of the two inputs, receives a clock oscillation supplied from the clock input L to the regenerator R and emits at its two outputs in accordance with this clock oscillation respectively the first and the second unipolar pulse sequence regenerated with respect to time . From these outputs, the unipolar pulse sequences are led to the outputs 2, 3 of the regenerator R, so that a corrected unipolar pulse sequence can be taken out at the first output 2, which has been regenerated with respect to amplitude and time, and which corresponds to the sequence of input pulses with positive amplitude, while the analog pulse sequence corresponding to the negative input pulses is taken out at output 3.

The outputs 2, 3 from the regenerator R can, depending on whether it is used as an intermediate or as an end regenerator, be connected either to the two inputs of a modulator with a connected bandpass filter or with a fork connection with a connected bandpass filter or additional parts of a line termination device.

As far as the first correction term El is concerned, it turns

refers to an automatic correction element whose degree of attenuation controls depending on the level of the reception signal. For this purpose, the control input of the first silencer El is connected to the output of an amplifier VI, whose input in the exemplary embodiment is connected to the output of the automatic correction link. In order to save amplifier stages, however, one can also connect the input of the first amplifier VI to connection points where the signal has a higher level, e.g. the output D from the modulation device M or a first output N from the device TA for beat and carrier oscillation derivation.

The device TA for beat and carrier fluctuation diversion consists of

a series connection of another correction element E2, a time delay element Tl,

a rectifier GR, another amplitude regenerator AR2, a phase discriminator PD, a generator G, a pulse shaper RF and a frequency divider FT. The input to the second correction element E2 is directly connected to the input E of the device TA for beat and carrier oscillation diversion. In the present case, the second noise attenuator E2 is implemented as a high-pass filter with a connected amplifier.

The output from the second correction section is connected to the input to the first running time section t1 and also to a first output N from the device for beat and carrier oscillation diversion. This output N can also optionally be connected to another input B to the modulation device M.

The first step link t1 is realized in the form of a push chain and serves to bring the transit time of the signal in the device TA to beat and carrier oscillation derivation in accordance with the transit time of the signal to be regenerated in the modulation device M and the regenerator R, i.e. to accurately set the phase of the produced clock and carrier oscillations and of the signal to be regenerated.

A rectifier GR connected to the input from the first time stage xl causes a folding of the received, corrected and amplified upper sideband, so that the connected second amplitude regenerator AR2 instead of pseudoternary pulses gets a unipolar pulse sequence. In this second amplitude regenerator AR2, amplitude regeneration takes place of this unipolar pulse sequence, which is then supplied to one input of a phase discriminator PD. The output P from a pulse shaper RF is connected to the other input of the phase discriminator PD, whereby the latter receives the produced clock and carrier oscillation for phase comparison. As a comparison result, the phase discriminator PD produces a pulsating DC voltage, which is supplied to the control input of the generator G.

In the case of the device which consists of the generator G, the pulse shaper RF and the phase discriminator PD, it is thus a so-called phase-lock-loop connection to produce a delayed oscillation. The generator G contains capacity diodes, the capacity of which changes corresponding to the supplied regulation voltage and, thanks to the connection to the frequency-determining oscillation circuit, leads to a frequency change in the oscillations produced. Since the generator G is a sine generator, the connected pulse shaper RF converts the sine oscillations into rectangular pulses in a known manner. The rectangular pulses emitted by the pulse shaper RF form the clock pulse or bit clock, which is fed to the clock input L of the regenerator R and the clock output 5 via the second output H from the device TA for clock and carrier oscillation diversion. From the clock output 5, when used as a final generator, it is possible to feed further parts of the wire termination apparatus with the bite stroke.

From the output of the pulse shaper RF, the produced clock pulse is also supplied to a frequency divider FT which, from the clock pulse by frequency division in the ratio 2:1, produces the carrier oscillation, which from the connected third output F from the device TA for clock and carrier oscillation diversion is fed to the carrier oscillation input of the modulation device M as well as a carrier oscillation output 4. The carrier oscillation output 4 is, in the case of the application of the described regeneration device as an intermediate regenerator when regenerating the pulses in the baseband bed or in an intermediate band bed, connected to a modulator, while the connection 4 remains free when regenerating the pulses in the transfer bed. When using the described device as an end regenerator, when regenerating the pulses in an intermediate band bed or in the transmission bed, the carrier oscillation output 4 is connected to a modulator, while when regenerating the pulses in the base bed, no additional modulator is needed and the carrier oscillation output 4 remains free.

In the event of a turnover of the received upper sideband, which is transferred

in the frequency range 0.5 < Q < 1.5, to the baseband, the modulator device M supplies the regenerator R with a regenerable digital signal in the frequency range 0 < fi < 1. For the regeneration, i

in this case a bit rate with frequency fl = 1, which is produced with the generator G, which oscillates with this frequency, in connection with the pulse shaper RF. With the help of the frequency divider FT, the necessary carrier oscillation with frequency fl = % is produced and transmitted to the modulator M. The output signal emitted at the output P from the pulse shaper RF is fed to the second input of the phase discriminator PD, where phase comparison can take place on the frequency plane fl = 1 or fl = 2 or between these.

In the case of a regeneration of the carrier frequency digital signal in the transmission layer or in an intermediate layer, the generator G produces an oscillation with frequency fl = 2, since it can oscillate directly with this frequency or it can also oscillate with frequency fl = 1, from which the first harmonic after distortion is filtered out and supplied to the pulse shaper RF. This pulse shaper RF then produces a clock oscillation with frequency fl = 2 which is supplied to the regenerator R and the frequency divider FT. In this case, the regenerator R receives a signal to be regenerated, which occurs in the frequency range 0 < fl < 1.5. From the frequency divider FT, a carrier oscillation with frequency fl = 1 is supplied to the modulation device M. The frequency of the necessary carrier oscillation is thus in this case half as high as the frequency of the clock pulse required for the regeneration.

In fig. 2, 3, 4, which will be discussed in more detail in the following, there are shown some modulation devices M which ensure a universal applicability of the device for regeneration shown in

fig. 1.

In fig. 2 shows a modulation device M which, with just one modulator, converts the received, corrected and amplified upper sideband to the baseband and thereby produces a regenerable digital signal. For this purpose, there is connected to the input A of the modulation device M an input to the first modulator Ml, which modulates the upper sideband received in the frequency range 0.5 <'fl < 1.5 with a carrier oscillation which is supplied to the d^'s carrier oscillation input and has frequency fl = \, thereby producing a digital signal in the frequency range 0 < fl < 1. A first low-pass filter TP1 is connected to the output of the first modulator Ml, whose blocking range begins at fl = 1, and which keeps residues of the reception signal away from the output. Another amplifier V2 is connected to the output of the first low-pass filter TP1 for level setting, which emits the digital signal to the signal output D from the modulation device M. The carrier oscillation input of the first modulator Ml receives from the modulation device's carrier oscillation input C the carrier oscillation necessary for the modulation supplied via another band-pass filter BP2 with cut-through range fl = \, a third amplifier V3 and another time delay term x2. This second timing section x 2 serves for fine-tuning the phase of the carrier oscillation, it also consists of a timing chain and supplements the first timing section ri of the device TA for beat and carrier oscillation derivation.

In fig. 3 shows a modulation device M for double conversion where the connection points A, D and C correspond to those in fig. 1 and 2. As already discussed, the necessary equipment for the connection to double conversion according to fig. 3 somewhat more extensive than in the case of the connection to single turnover according to fig. 2, but in return stricter requirements can be placed on the accuracy of the transfer, or the same requirement can be used to reduce the requirements for the individual components. Thus, with strict requirements for transmission quality, it is necessary to arrange the first low-pass filter TP1 1 the connection in fig. 2 to be able to be tuned, while this is not necessary with the comparable low-pass filter TP3 in the connection in fig. 3. According to the connection shown, the received, corrected and amplified upper sideband from the signal input A is supplied to another modulator M2, which by modulation with a carrier oscillation with frequency fl = 3.5 causes a first conversion of the received upper sideband.

The output from the first modulator is followed by the third bandpass filter BP3, which closes off the rest of the modulating input signal, the carrier oscillation and the upper sideband produced by the modulation, so that only the lower sideband with frequency range 2 < fl < 3 is transmitted to the following third modulator M3 . This lower sideband is modulated in this third modulator M3 with another carrier oscillation with frequency fl = 3.

The third modulator M3 is followed by a third low-pass filter TP3 with cut-through range 0 < fl < 1, which closes all modulation products on the lower sideband near. This lower sideband is the regenerable digital signal, which is brought to the desired level in a connected fourth amplifier V4 and is led to the signal output D from the modulation device M.

The generation of the carrier oscillation for the second modulator with frequency fl = 3.5 and for the third modulator with frequency fl = 3 takes place based on an oscillation which has frequency fl = h, and which the device TA for clock and carrier oscillation derivation transmits to the carrier oscillation input C. The oscillation with frequency fl = \ is supplied to a <11 >pulse shaper PF, which, based on the rectangular oscillations with frequency fl = , produces very narrow and therefore over-wave-rich triangular oscillations, from which the sixth and fifth harmonic frequencies respectively fl = 3.5 and fl = 3 are filtered out using a fourth and a fifth bandpass filter, respectively. To the fourth band-pass filter BP4 there ends in the signal path a fifth amplifier V5, a third

term x3 as well as the carrier oscillation input of another modulator M2, while the carrier oscillation from the fifth bandpass filter BP5 via a sixth amplifier V6 and a fourth time-time term x4 is led to the carrier oscillation input of the third modulator M3.

The connection for the modulation device M shown in fig.

4, contains, in addition to the signal input A, the signal output D and the carrier oscillation input C, a further signal input B. At the connection between the signal input A and the output from the first correction link El and at the connection between the signal input B and the output from the second correction link E2, two signal paths are obtained in the modulation device M to the connecting link Z. The first signal path goes from the signal input A via a fifth time step t5 to a first input to the connecting link Z, while the second signal path goes from the input B via the fourth modulator M4 to the second input of the connecting link Z. Over the first signal path the received, corrected and amplified upper sideband is led to the one input of the coupling junction Z, while in addition the corrected upper sideband is modulated by means of the fourth modulator M4, located in the second signal path, with a carrier oscillation of frequency fl = 1 , whereby the lower side band is produced. The connecting link Z is realized in the form of a known fork link. If no feedback can occur from the fifth time step t5 to the output of the modulator M4, the fork coupling can also be used instead; an ohmic connection between the two signal paths. The carrier-frequency digital signal, consisting of the two sidebands, is already present at the output of the coupling connector Z, and is routed via a fourth low-pass filter TP4 and a seventh amplifier V7 to the signal output D. The supply of the carrier oscillation with frequency fl = 1 to the carrier oscillation input of the fourth modulator M4 occurs from the modulation device's carrier oscillation input

C over a sixth time step t6, which serves for precise phase setting. This walking time link is also realized as a sliding chain.

Claims (11)

1. Method for regenerating the sideband used for transmission of a carrier-frequency digital signal that exists in a pseudo-ternary code and is generated using a carrier oscillation with a frequency equal to an integer multiple of the digital signal's half-bit sequence frequency, and whose phase is shifted by 90° in relation to the phase of an oscillation which occurs in the digital signal with a frequency equal to half the bit sequence frequency, characterized in that the received sideband is distortion-corrected and amplified and a modulation device and a device for clock and carrier oscillation derivation are added at the same time, in which from the received and corrected sidebands are derived clock and carrier oscillations whose frequencies are integer multiples of the half bit sequence frequencies, and of which a first clock oscillation with the lowest frequency is supplied to the modulation device and a second clock oscillation with a frequency doubled in relation to the first is supplied to a time regenerator, that the received and corrected sideband in the modulation device is converted into a regenerable digital signal and supplied to an amplitude regenerator, and that with respect to amplitude regenerated signal is supplied to the time regenerator and regenerated with respect to time. 2. Method as stated in claim 1, where the upper sideband" of the carrier frequency digital signal is used for the transmission, characterized in that the received, corrected and amplified upper sideband for the conversion into a regenerable digital signal is converted to the baseband bed in the modulation device. 3. Method as stated in claim 1, where the upper sideband of the carrier frequency digital signal is used for the transmission, characterized in that the received, corrected and amplified upper sideband for the conversion into a regenerable digital signal in the modulation device is converted into an intermediate layer which is shifted in relative to the digital signal's baseband with a frequency value equal to an integral multiple of half the sequence frequency. 4. Method as stated in claim 1, where the upper sideband of the carrier frequency digital signal is used for the transmission, characterized in that from the received, corrected and amplified upper sideband in the modulation device, a lower sideband is produced which is combined with the upper sideband to form of a regenerable digital signal. 5. Method as stated in one of the claims 1-4, characterized in that for beat and carrier oscillation derivation an oscillation is produced which is synchronized with the received sideband. 6. Method as stated in one of the claims 1-4, characterized in that, for beat and frame oscillation derivation from the received, corrected and rectified sideband, an oscillation with a double bit sequence frequency is filtered out. 7. Device for carrying out a method as stated in one of claims 1-5, characterized in that a first correction element (El) whose output is connected to the input (1) is connected via a first bandpass filter (BPl) A) to a modulation device (M) as with the input (E) of a device (TA) for beat and carrier oscillation derivation, that the output (D) of the modulation device (M) is connected to the input (K) of an i and for known regenerator (R), containing a first amplitude regenerator (ARI) directly connected to the input (K) and a time regenerator (ZR) which is directly connected to its two outputs, and which at its two outputs emits the respective regenerated pulses with each polarity of the regenerator's input signal as unipolar pulse sequences to the output connections (2, 3), that the device (TA) for clock and carrier oscillation derivation contains a series connection of another correction link (E2) which is connected to the first correction link s (El) output via the input (E), a first delay time element (il), a rectifier (GR), another amplitude regenerator (AR2) with only one output, a phase discriminator (PD), a generator (G), a first pulse shaper (RF) and a frequency divider (FT), and where the output from the second correction link (E2) :L is additionally connected to a first output (N), the output connected to the frequency divider (FT) from the first pulse shaper (RF) in addition is connected to another output (H), a further output (P) from the first pulse shaper (RF) is connected to the phase discriminator (PD) clock input, and the output from the frequency divider (FT) is connected to a third output time (F) from the device (TA) to clock and carrier oscillation derivation, which latter output is also connected to a carrier oscillation input (C) of the modulation device (M) and to a carrier oscillation output (4), that the other output (H) from the device ( TA) for clock and carrier oscillation derivation via a first clock input (L) to the regenerator (R) is connected to a clock input to the time regenerator (ZR) and to a clock output (5), and that a first amplifier (yl) is arranged, if output is connected to the control input of the first correction element (El), and whose input is optionally connected to the output of the first correction element (El), the output of the modulation device (M) or the first output (N) of the device (TA) to beat - and carrier oscillation diversion, and where another input (B) to the modulation device can also be connected to this output. 8. Device as stated in claim 7, characterized by a modulation device (M) which between its signal input (A) and its signal output (D) contains a series connection of a first modulator (Ml), a first low-pass filter (TP1) and another amplifier (V2), and to whose carrier input (C) the first modulator's (Ml) carrier input is connected via a series connection of a second bandpass filter (BP2), a third amplifier (V3) and a second delay stage (t2). 9. Device as stated in claim 7, characterized by a modulation device (M) which between its signal input (A) and its signal output (D) contains a series connection of another modulator (M2), a third bandpass filter (BP3), a third modulator (M3), a third low-pass filter (TP3) and a fourth amplifier (V4), and whose carrier input (C) is connected to the second modulator's carrier input via another pulse shaper (PF) and a series connection of a fourth bandpass filter (BP4), a fifth amplifier (V5) and a third delay stage (x3) and is connected to the third modulator's (M3) carrier input via a further output from the second pulse shaper (PF) and a further series connection of a fifth bandpass filter (BP5), a sixth amplifier ( V6) and a fourth gait term (x4). 10. Device as stated in claim 7, characterized by a modulation device (M) where the signal input (A) via a fifth time step (x5) is connected to the input of a combined guide coupling (Z), and where the signal input (B) via a fourth modulator (M4) is connected to the second input of the coupling coupling (Z), whose signal output via a fourth low-pass filter (TP4) is connected to the input of a seventh amplifier ( V7), whose output is connected to the signal output (D), while the carrier oscillation input (C) of the modulation device (M) is connected to the carrier oscillation input of the fourth modulator (M4) via a sixth time delay stage (x6). 11. Device as specified in claim 7, characterized in that the second correction element (E2) has a high-pass characteristic.