DE975509C - Arrangement for demodulation for time division multiplex transmission systems with pulse phase modulation - Google Patents

Description

ISSUED DECEMBER 14, 1961

Li2i86IXd / 2ia *

with pulse phase modulation

Achieved in multi-channel systems with pulse phase modulation and alternating transmission the receiver a series of impulses, which consist of the channel impulses (message impulses) nested in one another. and a synchronization or marking pulse at the beginning of each scanning cycle contains. The channel pulses represent the messages to be transmitted by their relative, temporal position in relation to a fixed point in time. They also have a constant length and amplitude. Each channel pulse represents an instantaneous value (sample value) of the message wave of the associated channel.

A double task arises at the recipient: Once the interleaved pulse series must be disentangled, and the individual pulses must be distributed to their associated channels, on the other hand, the channel pulses must be demodulated be, d. H. are transformed in such a way that their sequence gives rise to the original successor straightening shaft can be restored with sufficient accuracy.

This is known to be achieved z. B. by converting the phase modulated pulses into length-modulated pulses, which are then fed to the channel output circuits via a suitable filter will.

Another arrangement works on the principle as a demodulation circuit in such a way that the time-modulated or phase-modulated im-

109 744/5

pulse are fed to a normally blocked electron tube. The ones to be demodulated phase modulated pulses alone are not able to overcome the bias of the tube and initiate the formation of length-modulated pulses. From the separated synchronization pulses of the recorded pulse train, gate pulses are now generated for the corresponding Channel periods are fed to the channel's own demodulator circuits. The real one Demodulationsanordmmg is a flip-flop which, with the simultaneous presence of channel gate impulses and channel pulse is tilted and after the channel pulse has disappeared only at the end of the channel gate pulse goes back to its starting position. In other words, decisive for education the leading edge of the resulting length-modulated pulse is the time of occurrence of the phase-modulated channel pulse, while the trailing edge of the trailing edge of the channel gate pulse is equivalent to. The decisive factor for the good and reliable operation of this arrangement is the exactness Adjustment of the different voltage levels on the multivibrator. So here is the danger that in the case of inaccurate adjustment or changing operating conditions, the output pulse of the multivibrator persists despite the disappearance of the gate impulse.

Other known arrangements therefore work in such a way that the leading edge of the gate pulse marks the beginning of the length modulus to be generated - defined pulse, while the incoming phase-modulated pulse determines the trailing edge, d. H. terminates the length-modulated pulse. In one of these known arrangements is z. B. a gate pulse fed to a normally locked gate tube, but can The gate tube can only be unlocked if at the same time a mostly somewhat distorted channel gate impulse and a square clock pulse is applied to the gate tube. Then a square output pulse begins at the anode of the gate tube. Furthermore, there is a normally blocked so-called channel selector tube provided, on which the channel impulses lie, which also do not unlock this tube alone can. The negative output pulse of the gate tube that occurs when Channel gate pulse and clock pulse begins, is now fed to the cathode of the channel selector tube and reduces their bias so far that the next positive channel pulse that occurs The corresponding channel's dial tube is unlocked. This creates at the anode of the voter tube a short, negative impulse which is fed to the retarding grille of the gate tube and blocks it, d. H. terminates the length-modulated pulse occurring at the anode of the gate tube. The one upon termination of the length-modulated pulse at the anode of the gate tube is then used to lock the channel selector tube, i. H. used to increase their cathode potential, so that afterwards the whole demodulation circuit is at rest again. If there is no modulation output pulses of constant duration arise. The effort with two pentodes and In addition, the required two diodes per channel demodulator is relatively high. Will If a delay chain is used as the distribution element, a separate clock pulse generator must also be used be provided that gives the gate pulses coming from the distributor the required sharp, rectangular shape.

So it is all of these solutions - if you look at the multitude of channels as a whole - in principle, to the received sequence of phase-modulated pulses an unmodulated Add sequence of the same repetition frequency, so that either pulse pairs arise from which then the length-modulated pulses are obtained, or length-modulated pulses directly.

It is now also known to carry out the actual modulation conversion for a large number of channels by means of a common device and to apply the resulting sum channel of length-modulated pulses to the channel's own gate stages, at the output of which only when a length-modulated pulse and an individual gate pulse serving as a distributor pulse are applied desired length-modulated pulse arises. In this known solution, the separated sync pulses are fed to one of a band filter and a frequency multiplier existing pulse center, on the one hand emits the unmodulated sum channel to a common modulation transforming means, on the other hand, pulses to form - a \ of the required Torimpülse for the channel own port stage ^r issuer supplied will.

With regard to crosstalk risks that are otherwise obviously difficult to control, the known Arrangement two modulation conversion devices provided, each of which has half the total number fed by 24 channels.

The invention seeks to improve such an arrangement once that actually all (e.g. 24) channels in a single common modulation conversion device can be treated without hesitation, on the other hand with regard to the effort caused by the special Impulse center is still given in the known proposal. Finally there should also be one increased security against unwanted opening of the channel's own gate steps - z. B. by glitches - be achieved.

The invention thus relates to an arrangement for demodulation for time division multiplex transmission systems with pulse phase modulation, in which the received, phase-modulated pulses are converted into length-modulated pulses, that in each case the leading edge of the length-modulated pulse through one of a central Distributor, in particular a transit time chain, incoming door impulse and the rear edge through the Arrival of the phase-modulated pulse defl-

are ned, and in which a central, length-modulated sum channel is common for all channels Pulse-delivering modulation conversion device is provided, as well as the channel's own S Gate steps to which this sum channel and the gate pulses are applied in such a way that they are on their output only when a gate pulse and a length-modulated one are applied at the same time Pulse of the sum channel deliver a length-modulated pulse.

The intended objects are achieved according to the invention in that this device, as for the modulation conversion in the individual channel is known per se, contains a bistable tube circuit, which in one of its two stable states all channel own gate steps by an ab ^ conducted blocking potential blocks in such a way that these stages do not even when the gate pulse is applied can be opened, but by short impulses derived directly from the gate impulses in the other stable state is brought, which is until the arrival of the next phase-modulated Impulse causes an opening potential, which when the door impulse is applied at the same time the length-modulated pulses can arise at the output of the gate steps.

The channel's own gate stage, which is used to form the length-modulated pulse, speaks first then on when two conditions are met: The central, bistable tube circuit must be in their (all channels!) "unlocking" state. It is in this state through occurrence brought each gate pulse coming from the distributor, as will be explained later. This The »unlocking« state alone does not, however, result in the opening of any of the channel's own door steps, but only prepares the unlocking of all these door steps. Only that is actually opened Gate step on which the gate impulse delivered by the distributor is located at the same time.

The invention will now be explained in more detail with reference to the drawings.

Fig. Ι shows schematically the block diagram of a Receive circuit for a PPM system with

+5 any number of channels;

FIG. 2 shows the central, bistable tube circuit 11 with the elements 10 and 12 (in FIG. 1 outlined by dashed lines) in detail and in cooperation with elements 6 and 8 of

so Fig. i.

In Fig. Ι the nested pulse sequence occurs at ι in a pulse shaper stage 2 a. 3 is a Gate circuit that sifts out only the synchronization pulses from the combined pulse series and the synchronizing pulse amplifier 4 supplies. From here the synchronization pulses are sent to the runtime chain 5 given. The parts 2, 3, 4, 5 can be of a known design and their function and correspond to their interaction according to the state of the art.

The time-shifted synchronization pulse, which is now called the gate pulse, is tapped from suitable tapping points of the delay chain 5 in a time interval assigned to the respective channel and fed to the channel-specific parts via the line designated by the identifier B. Three channels are indicated. The number of channels is of course arbitrary within the usual limits. The task of the gate pulse shaping stages 6 is to turn the distorted pulse coming from the delay chain into an exactly square pulse of approximately the width of a channel period and of suitable amplitude. The gate pulses are now fed via lines 7 to the actual demodulation stage 8, which is also to be regarded as the first LF stage. These demodulation stages 8 are blocked in the normal state as a result of their high cathode potential, which is impressed by the blocking stage 12. This will be explained later. At the moment when the front edge of the gate impulse is formed, a further short impulse is created in step 6, which, like the gate impulse itself, occurs at fixed times and is called the "normal impulse". It is fed to the tube combination 10, 11, 12 via the lines 8 a and 9. Its main element is the flip-flop circuit 11. 10 is an amplifier for the normal impulses, 12 a powerful blocking tube. The flip-flop 11 can assume two stable states. In one, the "unlocking" state, the cathode potential of the demodulation stage 8 is lowered (it is connected to the blocking tube 12 via the line 13). The flip-flop is brought into this state by the "normal pulse" that is generated in pulse shaper stage 6 at the same time as the gate pulse. This means that the two conditions set out above (unlocking from the bistable tube circuit and gate pulse) are met for the deniodulator stage 8 of the channel to which the relevant gate pulse is assigned: Stage 8 is opened.

It remains open until the next modulated pulse coming from the former stage 2 via the line marked A throws the flip-flop 11 into its second state. By means of the blocking tube 12, this causes the cathodes of all demodulation stages 8 to be brought to a higher potential, so that the gate pulse at the stage in question is no longer able to keep the stage open.

The length-modulated pulses are then fed to a second LF stage 14 via the lines marked with C in a manner which is not of interest here. The restored signal wave then occurs at output 15.

On the basis of the circuit example in FIG. 2, some details should now be given of Fig. ι roughly explained principle shown will. Fig. 2 is divided into three fields by dash-dotted lines. In the big field on the left is the part outlined in dashed lines in FIG. 1 with the components 10, 11, 12. The upper right field shows one of the pulse shaping stages 6, the lower right field the associated one

Demodulation stage 8. The letters A ₁ B and C entered in circles make it possible to understand the detail of FIG. 2 within the diagram of FIG. 1 in a simple manner. Only those switching elements are provided with reference numerals, the explanation of which appears necessary for an understanding of the invention. All other switching elements (resistors, capacitors, rectifiers) whose intended purpose is familiar from similar circuits or which is obvious to a person skilled in the art are entered for the sake of completeness, but without reference symbols. To simplify the designation, the reference symbols of the "stages" in FIG. 1 are identical to those of their main elements, namely the tubes in FIG sharply defined pulse of the desired duration via the line 7 to the grid of the demodulation tube 8. The tube 6 normally operates in the grid current range. If a negative pulse arrives at the grid from the delay chain (connection B), the anode current is blocked. The resonant circuit located in the anode circuit (coil 16 with a switching capacitance (not shown) that is located in parallel) swings out positively. The oscillation is limited to a certain amplitude by the rectifier 17, while the rectifier 18 cuts off the negative half-wave. The upwardly limiting potential is made somewhat flexible by a series resistor 19 (a few hundred ohms), so that a short pulse (normal pulse) is produced when it is hit. At the same point in time at which the gate pulse is generated and reaches the grid of the tube 8 via the line 7, a normal pulse reaches the braking grid of the right tube 11 belonging to the flip-flop circuit via the two normal pulse amplifier tubes 10 and 10 '"Currentleft" brought (tube 11 '). The anode of the tube 11 'is connected to the grid of the barrier tube 12 via the line 20. Due to the "current left" position, the blocking tube 12 is de-energized and thus does not supply a positive blocking potential via the line 13 to the cathode of the demodulation tube 8. The negative voltage - GV of this tube 8 is dimensioned so that the via the line 7 ans In the absence of this blocking potential, the gate pulse placed on the grid causes the tube to respond, so that the length-modulated pulse is created in its anode circuit. It is passed through point C to the next NF stage (14, in FIG. 1).

If the phase-modulated pulse arrives at A , the toggle switch (tubes 11, 11 ') is switched to the "current right" position. Current now flows in the blocking tube 12, so that the cathode of the demodulator tube 8 is brought to a higher potential via the line 13 as a result. As a result, the tube is also blocked if the gate impulse occurs on the grille, as this is then no longer sufficient to maintain the passage of current.

If multi-grid tubes are used instead of triodes for the tube 8, these can also be used are blocked by the fact that the central, bistable tube circuit is blocking the channel's own The tube-causing state supplies a voltage that corresponds to the potential of one of the grids of the channel's own The tube is lowered so far that this tube is in spite of the gate impulse from another grid is blocked.

Claims (2)

Patent claims: i. Arrangement for demodulation for time division multiplex transmission systems with pulse phase modulation, in which the received, phase-modulated pulses are length-modulated Pulses are converted that in each case the leading edge of the length-modulated pulse by a gate pulse coming from a central distributor, in particular a transit time chain and the trailing edge is defined by the arrival of the phase modulated pulse are, and where a central, length-modulated sum channel is common for all channels Pulse-delivering modulation conversion device is provided, as well as the channel's own Gate steps (8) to which this sum channel and the gate pulses are applied in such a way that they are only available at their exit when a gate pulse and a length-modulated pulse of the sum channel deliver a length-modulated pulse, thereby characterized in that this device, as for the modulation conversion in the single channel known per se, contains a bistable tube circuit (11) which is stable in one of its two States of all channel-own gate steps by a derived (blocking tube 12) blocking potential blocks in such a way that these steps are not opened even when the gate pulse is applied can, however, by short impulses derived directly from the gate impulses in the other stable state is brought, which will remain until the next xio phase-modulated pulse caused an opening potential, which with simultaneous concern of the gate impulse the length-modulated impulses arise at the output of the gate steps leaves. 2. Arrangement according to claim i, wherein between the channel's own gate step (8) and the central distributor (5) switched to a step (6) is, characterized in that in this stage from the gate pulses coming from the distributor the short pulses are derived from the central modulation conversion device (ii, 12) in the unlocking of the canal's own Bring gate steps (8) with simultaneous application of the gate impulse.