DE1005581B - Device for maintaining a certain minimum modulation for multiple transmission systems with pulse modulation - Google Patents

Description

GERMAN

The invention relates to a modulation limiter device, those in transmission devices for multiple transmission systems with pulse modulation and time division is used.

In the description, transmission devices for multiple transmission systems are also understood Pulse modulation Devices that serve to generate staggered and recurring pulses that are transmitted in a sequence and in a certain order, based on special pulses, so-called synchronization pulses, are transmitted, emitted and modulated, each pulse with a specific Position in the pulse sequence is assigned to a specific transmission channel and according to a specific Modulation type depending on the message signals to be transmitted through this channel, ζ. B. telephony signals is modulated. These signals are referred to below as modulation signals.

The modulation characteristic changes regardless of the type of pulse modulation Amplitude, length or phase modulation, depending on the modulation signal between two Extreme values, and this can occur in the event of modulation overdrive or the failure of the channel modulation elements it can happen that the channel pulses fail to appear. This occurs when the modulation signal has too great an eye amplitude has that polarity which tends to reduce the amplitude of the pulses. In the in the Practice very common case in which the amplitude-modulated pulses in the transmitting device of the multiple transmission system and these pulses are converted into phase modulated pulses before being sent onto a transmission line, it can occur with the usual use of simple modulation converter circuits for modulation it can happen that an amplitude-modulated pulse of amplitude zero is the defect of a phase-modulated Impulse instead of one with a maximum time deviation from its central position.

In particular, this omission has a significant change in that given by the pulse train Frequency spectrum by introducing low frequency components into this spectrum. This results in a disruption of the operation of the general organs of the transmitting and receiving devices for multiple transmission systems and especially poor functioning of the organs for the Passing on of the signaling signs in the case where this sign is e.g. B. by using components be transmitted with the mean pulse repetition rate.

It has already been proposed to maintain the aforementioned post-installation

a certain minimum modulation

for multiple transmission systems

with pulse modulation

ίο applicant:

Andre Eugene Pinet,
Maisons Alfort, Seine (France)

^χ 5 representatives: Dipl.-Ing. E. Prinz, patent attorney,

Graefelfing near Munich, Aribostr. 14th

Claimed priority:
France October 16, 1952

Andre Eugene Pinet, Maisons Alfort, Seine

(France),
has been named as the inventor

partly to remedy this by limiting the amplitude of the modulating signal in both directions, for example with the help of a threshold device consisting of two pre-tensioned against each other Diodes. However, this arrangement has the disadvantage that each channel has its own limiting device must be built in.

According to the invention, on the other hand, there is only a single device for prevention that is common to all channels the failure of an amplitude-modulated pulse is required. The facility does its job both in the event of an overload or accidental failure of a channel modulator.

The subject of the invention is a modulation limiter device that is used in transmission devices for multiple transmission systems with pulse modulation, in which length or phase modulated Pulses are generated by converting amplitude-modulated pulses, is applicable, so that in the event of modulation override or interruption of the channel modulation circuits Channel pulse cannot be completely suppressed.

Another purpose of the invention is the use of a multi-channel provided for a given number of channels.

609 867/296

The transmission system has pulse modulation in one temporarily restricted number of channels without the pulses belonging to the temporarily suppressed channels miss.

According to the invention, as in the known systems, the various channel modulators are operated in sequence controlled by probe pulses, and the amplitude-modulated pulses generated by these modulators before they are fed to the modulation converter circuits, to the probe pulses so adds that the amplitude of the modulated pulses without this addition in the case of modulation overdrive or the interruption of the modulators could be zero, in which case it retains an amplitude, which is not zero, but equal to the amplitude of the appropriately set probe pulses.

Exemplary embodiments of the invention are shown in the drawing, namely FIG

Fig. 1 shows the transmission part of a multiple transmission device with pulse modulation, which the invention Contains modulation limiter device and the circuit diagram (partly in the block diagram) is shown

Fig. 2 shows the waveform of the signals at various points in the circuit of Fig. 1, the time as The abscissas and the amplitudes of the signals are plotted as ordinates.

In Fig. 1, 1 denotes a tactile pulse generator. The pulses 60 shown in diagram α in FIG. 2 as a function of time appear at output 2 of this generator. They have a positive polarity, a duration τ and a return period T, this period determining the cycle in which the pulses are emitted one after the other corresponding to the different channels intended for multiple transmission.

Terminal 2 is connected to the input of a time division circuit 3, which is in the form of a delay line 4 is shown. This delay line is terminated with an impedance of 5, whose size is equal to their wave resistance and which have a series of evenly staggered branches 6, 7, 8 and 9 contains.

The stages labeled 10, 20, 30 and 40 are channel modulators for amplitude modulation. Their number is assumed to be four. Each of them contains an input terminal 11 or 21, 31 and 41 to which the modulation signal is fed. In addition, they are connected to the taps 6 and 7, 8 and 9 of the delay line 4 via connections 12 and 22, 32 and 42, respectively. In this way, the modulator stages 10 or 20, 30 and 40 receive the corresponding probe pulses 61 or 62, 63 and 64, which are shown in diagram b of FIG. These pulses have positive polarity.

The modulator circuit 10 for the first channel is formed by a pentode 13 which receives the touch pulse 61 belonging to the first channel on its control grid 15 and the modulation signal supplied to the terminal 11 on its braking grid 16. During the entire duration of the touch pulse 61, the tube 13 will conduct current, and the current intensity of its anode 17 is controlled by the modulation signal. In the circuit of the anode 17 negative pulses are taken, which are shown at 65 in diagram c of FIG. 2 and whose duration is the same as that of the probe signal, while their amplitude lies between the straight lines 66 and 67 corresponding to the size of the modulation signal amplitude. The straight line 66, which represents the maximum amplitude, corresponds to a positive retarder grid polarization voltage, which is equal to the polarization voltage of the cathode 14, while the straight line 67, which represents the minimum amplitude of the pulse 65, corresponds to a strongly negative retarder grid polarization voltage. In addition, the polarization of the cathode 14 is regulated in such a way that, in the absence of a signal at the grid 16, the pulse 65 has an amplitude represented by the straight line 68.

In the case of modulation overdrive, i. H. when the potential applied to the braking grid 16 is related to the potential of the cathode 14 is strongly negative, so the amplitude of the pulse 65 is zero, so that this pulse disappears.

The modulator circuits of the second, third and fourth channels correspond to the modulator circuit 10, and the pulses belonging to these different channels correspond to pulse 65 and have an amplitude which depends on the modulation signals of the respective channels.

The outputs of the channel modulator circuits 10, 20, 30 and 40 are connected to a common terminal 18, on the other hand, a first modulation converter 19 is connected to which a second Modulation converter 23 connects. The converter circuit 19 converts the amplitude-modulated pulses into length-modulated ones Pulse around and the converter circuit 23 converts the length-modulated pulses into phase-modulated ones.

The converter circuit 19 contains the pentode 25, the control grid 26 of which is connected to the terminal 18 via a differentiating Circuit, which is formed by the capacitor 27 and the resistor 28, connected is. The cathode of this tube is connected to ground, and the resistor 28 is not connected to his the end connected to the grid 26 at a point which has a positive potential with respect to the cathode.

The mode of operation of the modulation converter circuit 19 is as follows:

The time constant of the differentiating network 27-28 is chosen so that the potential increase of the grid 26 takes place in time - = - which is equal to half The duration of the channel pulse 65 is when it has the mean amplitude caused by the absence of the modulation signal corresponding straight line 68 is shown.

As diagram d of FIG. 2 shows, a sawtooth-shaped signal 69 is fed to the grid 26, the steep edge 70 of which coincides in time with the leading edge of the pulse 65 and the inclined edge of which is displaced parallel to the straight line 71, which corresponds to the amplitude 68 of the pulse 65 is equivalent to. The straight line 72 corresponds to the amplitude represented by the straight line 66, apparently no signal is fed to the grating 26 during the modulation peaks which suppress the pulse 65 by limiting it to the zero amplitude represented by the straight line 67.

The grid bias of the tube 25 is selected so that the abscissa axis 73 in diagram d of FIG Anode 29 positive channel pulses, length-modulated on their trailing edge, are taken, of which only the pulse 75 associated with the first channel is shown. This pulse has a trailing edge 76 when the amplitude of the pulse 65 has the height 66. It has a trailing edge 78 when the amplitude of the pulse 65 has the size 68, and finally the pulse 75 has the duration zero,

when the amplitude of the pulse 65 is zero (Fig. 2, diagram e).

The converter circuit 23 contains two pentodes 34 and 43. The control grid 35 of the tube 34 is connected to the Converter circuit 19 via coupling capacitor 33. The anode circuit 36 of this tube is through the resistor 37 and the inductance 38 connected in parallel to this are formed. The anode 36 is over the coupling capacitor 39 is connected to the control grid 44 of the tube 43. The anode circle 45 of these Tube contains the resistor 46, this anode via the coupling capacitor 47 to the output terminal 24 of the transmitter of the multiple transmission system is connected.

The mode of operation of the converter circuit 23 is as follows: The length-modulated pulses, such as 75, are differentiated by the differentiation circuit 37-38 according to the time, and those at the anode 36 of the Pulses appearing in tube 34 are shown at 79 in the diagram / FIG. 2. Everyone creates Impulse, such as B. 75, two short pulses 80 which coincide with its leading or trailing edge and 81 of opposite polarity.

The tube 43 acts as a limiter and only the positive pulses 81 of the diagram / are amplified and reversed in polarity. The phase-modulated pulses 82 (FIG. 2, diagram g) are taken from the output terminal 24. Each of these pulses 82 appears, depending on the amplitude of the modulation signal, at a different point in time and is shifted in time between the limit positions marked by the pulses 82 ′ and 82 ″.

As can be seen, the modulation peaks can suppress the channel pulse 65 for a moment. Apparently In this case, no pulse 82 is supplied by the tube 43, so that in the system described above the phase-modulated pulses taken from the terminal 24 can disappear for a moment instead of to shift only temporally between two borders. In particular, the pulse 82 in FIG the layer 82 ', which corresponds to a negative modulation peak.

The purpose of the modulation limiter 48 is to prevent this disappearance.

All taps 6, 7, 8 and 9 of the delay line 4, at which the key signals 61 to 64 appear and which are connected to the channel modulator circuits 10, 20, 30 and 40, are also connected to the modulation limiter device 48.

This circuit contains addition resistors 49 to 52, one end of which is connected to the grid 54 of the limiter tube 53 and the other end to the corresponding taps 6 to 9. In this way, a signal is obtained at the anode 55 of the tube 53 which is nothing other than the signal according to diagram b of FIG. 2, but with reversed polarity and a suitably dimensioned amplitude.

This signal is fed to the terminal 18 via the coupling capacitor 56 and is thus added to the signal composed of the pulses 65, which is shown in diagram c (FIG. 2). It follows from this that the signal fed to the converter circuit 19 is no longer the signal according to diagram c consisting of the pulses 65, but consists of the pulses 83 which are shown in diagram h . In the absence of the modulation signal, the pulse 83 has an amplitude represented by the straight line 84 and, depending on the size of the modulation signal, an amplitude lying between the straight lines 85 and 86, this amplitude never being smaller than that represented by the straight line 86, the corresponds to the amplitude of the pulse originating from the modulation limiter device 48.

The new sawtooth-shaped signal which is fed to the grid 26 of the tube 25 is shown at 87 in diagram i of FIG. The steep front flank 88 of this sawtooth curve coincides in time with the front flank of the pulse 83. The inclined flank of the sawtooth curve is an inclined straight line which assumes position 89 in the absence of a modulation signal and position 90 or 91 in the case of the modulation peaks.

The new length-modulated signal is represented by the pulses 92 in the diagram; of Fig. 2 shown. His The leading edge 94 coincides in time with the leading edge of the pulse 83. His trailing edge is increasing In the absence of the modulation signal, position 95 and, for the modulation peaks, one of positions 96 or 97.

The new phase-modulated signal is represented by the pulses 98 in diagram k in FIG. These pulses shift in time between the limit positions marked by the pulses 98 'and 98 ". In contrast to the process in the case of the pulse 82 in diagram g , however, the pulse 98 does not disappear in its position 98', while the pulse 82 in its position 82 'disappeared.

It should be noted that the total time excursion τ 'of the pulse 98 is less than the duration τ of a probe pulse. If you want to make the total time excursion τ of the pulse 98 (Fig. 2, diagram k) equal to the total time excursion of the pulse 82 (Fig. 2, diagram g) , you have to choose a time duration Θ of the probe pulses that has the value r by the amount which is equal to the time interval between the edges 94 and 96 of the length-modulated pulse 92 with the minimum time duration.

With the help of the modulation limiter device according to the invention is therefore every time a channel modulation circuit, be it by modulation overdrive or by accidental or deliberate Suspend, deliver no signal, the corresponding pulse 98 will always be present and assume the position 98 '.

Claims (3)

Patent claims: 1. Device for maintaining a certain minimum modulation for the transmitter of a Multiple transmission systems working with length or position modulated pulses are included which the pulses in channel amplitude modulators, which successively through periodic Control pulses are put into action, amplitude-modulated and then length- or position-modulated Pulses are converted and at which the amplitude modulated pulses as a result Overmodulation by modulation signals with excessive amplitude of a certain polarity can disappear, characterized in that the amplitude-modulated pulses from the individual channel modulators come, the outputs of which are interconnected at a common point (18) are, at this point auxiliary pulses are added to the control pulses are proportional in such a way that the length or position modulated pulses do not fail, if the corresponding amplitude-modulated pulses are due to modulation overload temporarily absent. 2. Device according to claim 1, characterized in that all the amplitude modulus lated impulses as well as the auxiliary impulses to the control grid of a single electron tube (25) are fed. 3. Device according to claim 1 or 2, in which auxiliary pulses are obtained from the control pulses the taps of a delay line, each corresponding to one channel, which the periodic synchronization pulses supplied by a local generator are supplied, occur, thereby ge ίο indicates that the auxiliary pulses are obtained by in a common circle (48) Voltages, which are derived from the control pulses, the grid one for pulse generation serving electron tube are supplied. Considered publications:
Austrian patents No. 166 891,
558 1 sheet of drawings © 609 867/296 3.57