DE1135971B - Time division multiplex system - Google Patents

Description

Time division multiplex system The invention relates to a time division multiplex system, in which the pulses recurring at intervals of a sampling period with regard to their order at the interval of a sampling period or one. Multiples of it in time are scrambled.

In time division multiplex systems, the channels assigned to the individual channels return Pulses within the pulse frame, d. H. within a sampling period, always in same order again. Procedures are known to keep the messages secret, which are based on a temporal scrambling of the transmitted pulses; the chronological order the impulse is permuted according to a certain key in such a way, that at the distance of a sampling period or a multiple thereof repeating pulses never belong to the same channel, unless this time interval is very large. A reverse permutation on the receiving side can change the normal sequence the impulses are restored.

Known circuit arrangements use to solve this problem Runtime chains, which temporally change the impulses to be permuted by different amounts delay. Such an arrangement contains z. B. a delay chain at the input and one or more output delay chains whose taps match certain taps the first maturity chain via threshold value organs depending on the specified key are connected. In another arrangement, the pulses run through a transit time chain, whose taps are connected to the output via electronic switches. For controlling the electronic switches are used in the order given by the key Switching impulses that are obtained with the help of further delay chains. With such Circuit arrangements it causes great difficulties, which are generally required Realize crosstalk attenuation in the range of seven to eight nepers. These difficulties are primarily due to the numerous. Maturity chains conditional, in which the impulses are strongly distorted when passing through. The pulse distortions can be avoided by appropriately broadband maturity chains, but then the manufacturing effort is so great that the economy such systems is in question.

Another known arrangement for pulse code modulation used for transcoding is used by at least two chronologically interlocking code-modulated pulse trains, uses storage capacitors to delay the pulses. There are two storage systems provided with individual memories for each step of a code character and switching means, the individual steps of the code characters in any order on the individual memory to be distributed and to be taken from the memory in a different order, whereby the removal of a recoded pulse sequence from one storage system during the distribution of the steps of another pulse train to the individual memories of the other storage facility. The effort for such an arrangement is very high great.

The invention is based on the object of a time division multiplex system especially for pulse phase modulation to create an effective in a simple manner Encryption of the pulse train allowed and the disadvantages of the aforementioned Avoids arrangements.

According to the invention this object is achieved in that for each channel on the sending and receiving side, one each with a special circuit for pulse code modulation for recoding at least two code-modulated ones that are temporally one inside the other Pulse trains of known memories and synchronized switching means are provided, on the sending side, the message voltages in all channels at the same time periodically sample and feed these samples to the memories from which they are under control by an encryption program in an order that can be changed over time are removed, and the receiving side the amplitude-modulated pulses after corresponding decryption on the memory assigned to the individual channels to distribute, of which they are periodically in all channels simultaneously be removed.

The invention is intended to be based on the exemplary embodiments shown in the drawings are explained in more detail. The drawings show in Fig. 1 a block diagram of the Transmitting part, FIG. 2 a block diagram of the receiving part, FIG. 3 the basic circuit a line interchanger, Fig. 4 the temporal processes in the transmitting and receiving part, 5 shows a preferred embodiment of the transmitting part.

The exemplary embodiments include a time division multiplex system for pulse phase modulation with six channels of 4 kHz bandwidth each. The sampling frequency that at least twice as large as the highest frequency contained in the message must be 8 kHz.

In the case of the transmitter part shown in FIG. 1, an electronic switch S 1 to S 6 (feed switch) is located at the input of each of the six channels K1 to K6. The six switches sample the message signals at the rate of the sampling frequency (f " = 8 kHz), simultaneously in all channels. The samples are fed to six storage capacitors C 1 to C 6, which retain their voltage until they reach the next Sampling after 125 [s. In this way, staircase voltages with the same step lengths of 125 us each arise at the storage capacitors C 1 to C 6.

The time processes can be seen from FIG. 4. In the lines a and b are two message signals s1 and s 2 in the two channels K 1 and K 2 shown. The samples indicated by small circles are with the signal s1 with 1, with signal .s2 with 2. The at the capacitors C 1 and C 2 occurring staircase voltages in the rows a and b are shown.

The samples stored in capacitors C 1 to C 6 become now over the electronic switches S11 to S16 (acceptance switch) in a timed manner changeable order removed (Fig. 1). The impulses picked up are in 4 marked by small crosses, namely the one removed from the capacitor C 1 Pulse with 11 (line a), the pulse taken from capacitor C 2 with 12 (line b) referred to. The pulses picked up are at the output of the electronic switch S 11 to S16 combined (Fig. 4, line c) and the modulation converter W (Fig. 1) supplied, if. the amplitude modulated pulses into phase modulated pulses should be converted.

A particularly effective encryption results when the order of the channels is permuted after each sampling period - in the exemplary embodiment every 125 Is. This case is shown in FIG. The removed channel pulses 11 and 12 take a different place in the pulse frame within each sampling period; so they are no longer equidistant.

In the case of the time division multiplex system with six channels yourself 6! = 720 permutations. The frequent switching option is a special one Advantage of time division multiplex systems. It should be noted here that in frequency division multiplex systems scrambling of sub-frequency bands is known as a means of secrecy. the Switching is done roughly in rhythm with the syllable frequency. The at Rapid switching sequence possible with time-division multiplex systems would be due to the too long settling time the filters fail.

The electronic switches in the transmitter part of FIG. 1 are of a 8 kHz auxiliary pulse train controlled, which a generator G 1 supplies. The auxiliary impulses the feed switches S 1 to S 6 and the take-off switches Sll at the same time to S1.6 staggered in time via a pulse distributor L and an interposed line exchanger A. supplied: The pulse distributor L can be implemented as a transit time chain with six taps be; the running time between two taps is 20.8 #ts, the total running time 125 js ..

A basic circuit diagram of the line interchanger A is shown in FIG. 3. Each of the six inputs e 1 to e 6 can be connected to any of the six outputs a 1 to a 6 ; only one switch may be closed in each column and row. Depending on the required switching frequency, mechanical or electronic switches can be used as switching means, which are controlled by mechanical, magnetic, photoelectric or other signal carriers (e.g. punched tape, magnetic tapes, film tapes).

In the receiving part (Fig. 2) the same path as in the transmitting part is backwards trodden. The incoming phase-modulated pulses are processed in the modulation converter W 'converted into amplitude modulated pulses by the electronic switches S11 'to S16' (feed switch) at the correct time on the assigned to the individual channels Storage capacitors C 1 'to C 6' are distributed. This creates on the storage capacitors C 1 'to C6' Staircase voltages with unequal step lengths, since the individual ones Pulses assigned to channels do not arrive equidistantly.

In FIG. 4, lines d and e show the voltage forms occurring in channels 1 and 2 in the receiving section. The transit time between the input of the transmission-side modulation converter W and the output of the reception-side modulation converter W, which essentially depends on the transit time of the path, is neglected. The pulses II 'to 12' in the output of W thus occur in FIG. 4 at the same time as the pulses 11 and 12 at the input of W on.

The pick-up switches S 1 'to S 6' sample the staircase voltages of unequal step length occurring at the capacitors C 1 'to C 6', in all channels at the same time. Neglecting the term which AbnahmeschalterSl close 'to S6' on the receiving side simultaneously with the feed switches S 1 to S 6 on the transmitting side; however, mutually corresponding sampling times are delayed by one sampling period. The samples (e.g. 1 'in channel 1, 2' in channel 2, etc.) are fed to channel amplifiers V 1 to V 6 which contain a low-pass filter which only allows frequencies below 4 kHz to pass. How out. 4, the original message signals s 1 and s 2 are obtained back, which are delayed by one sampling period with respect to the transmission side; the encryption does not cause any distortion.

The devices for controlling the electronic switches in the receiving section correspond to the devices in the transmitting section. The generator G l 'supplies an 8 kHz auxiliary pulse train, which are fed to the pick-up switches S1' to S6 'at the same time and to the feed switches S 11' to S16 ' staggered in time via the pulse distributor L' and the interconnected line exchanger A '.

A clock pulse is used to synchronize the generators G 1 and G 1 'and the line exchangers A and A' on the transmission and reception side, which is inserted into the pulse frame at the output of the modulation converter W on the transmission side. To distinguish it from the channel pulses, the clock pulse has a different shape, e.g. B. a longer duration. On the receiving side, the clock pulse is separated from the incoming pulses with the help of a clock pulse filter T and fed to the generator G 1 'and the line exchanger A'.

In the transmitting and receiving part according to FIGS. 1 and 2, capacitors C 1 to C 6 and C 1 'to C6' are used as memory. So that a voltage source with a small internal resistance is available for sampling the stored voltage, it is expedient to connect a cathode amplifier with a high input resistance and a low output resistance to each storage capacitor.

In the following, a preferred embodiment of a time division multiplex system according to the invention is described, of which the transmission part is shown in FIG. The difference compared to the system according to FIGS. 1 and 2 consists essentially in the control of the electronic acceptance switches S 11 to S 16 on the transmitting side and the electronic feed switches S11 'to S16' on the receiving side. The switching pulses for actuating these switches are generated in a manner known per se. a common 48 kHz auxiliary pulse train, on which a sinusoidal 8 kHz voltage is superimposed. The pulse repetition frequency 48 kHz is given by the number of channels (n = 6) and the sampling frequency (tu = 8 kHz). The correct switching times are achieved in that the sinusoidal voltages are applied to diaphragm circuits B 11 to B 16 with a phase step of 60 ° each. The pulse on the apex of the sinusoidal voltage exceeds a certain threshold value and serves as a switching pulse for the electronic switch.

In the transmitting part shown in FIG. 5, the 48-k1z auxiliary pulse sequence is supplied by a generator G 2. An 8 kHz auxiliary pulse train and an 8 kHz sinusoidal oscillation are obtained in a frequency divider F. The auxiliary pulses with the repetition frequency of 8 kHz simultaneously control the feed switches S1 to S 6, the auxiliary pulses with the repetition frequency of 48 kHz are fed to the diaphragm circuits B 11 to B 16. From the 8 kHz sinusoidal oscillation, six sinusoidal oscillations, each phase shifted by 60 °, are generated in a phase shifter P. These are distributed to the diaphragm circuits B 11 to B 16 via a line exchanger A according to FIG. 3.

The receiving part is structured according to the transmitting part. The synchronization can be done in the same way as described in the first example became.

In times of low traffic there is a risk that only a single channel is occupied. This could then be monitored by demodulating the sum pulse sequence will. This can be avoided by leaving the free channels with noise, Babble or the like can be occupied.

Claims (5)

PATENT CLAIMS: 1. Time division multiplex system in which the one at a distance Sampling period recurring pulses with regard to their sequence in the distance a sampling period or a multiple thereof are scrambled in time characterized that for each channel on the sending and receiving side one at a special circuit for pulse code modulation to recode at least two code-modulated pulse sequences of known memories lying one inside the other and synchronized switching means are provided, which transmit the message voltages periodically sample in all channels simultaneously and store these samples feed, of which they are under the control of an encryption programmer are removed in a time-variable sequence, and the receiving side the amplitude-modulated pulses after appropriate decoding to the distribute memory allocated to individual channels, of which they are distributed in all channels be removed periodically at the same time. 2. Time division multiplex system according to claim 1, characterized in that a capacitor is used as a memory, which is preferably a cathode amplifier is connected downstream. 3. Time division multiplex system according to claim 1 or 2, characterized in that each memory has two electronic Switches for the supply and removal of the message pulses are assigned, the send and controlled by synchronized auxiliary pulse trains at the receiving end. 4. Time division multiplex system according to claim 3, characterized in that generators are provided on the transmitting and receiving sides, which supply auxiliary pulses with a repetition frequency equal to the sampling frequency, which the feed switches (S1 to S6) of the transmitting side and the acceptance switches (S 1 'to S6') the receiving side at the same time and the acceptance switches (S11 to S16) of the transmitting side and the feed switches (S 11 'to S 16') of the receiving side staggered in time via a delay chain with taps (L or L ') and an interconnected line exchanger controlled by the encryption programmer ( A or A ') are supplied. 5. Time division multiplex system according to claim 3, characterized in that the transmitting and receiving side generators are provided which deliver auxiliary pulses with a repetition frequency equal to a multiple of the sampling frequency, from which a pulse train and sinusoidal oscillations of different phases are obtained, the frequency of which is equal to the sampling frequency, that the supply switches (S1 to S6) of the transmitting side and the receiving switches (S1 'to S6') of the receiving side, the auxiliary pulses are simultaneously supplied with the repetition frequency and that the receiving switches (S11 to S1.6) of the transmitting side and the supply switches (S 11 'to S16 ') the receiving side is preceded by diaphragm circuits, to which the auxiliary pulses with the repetition frequency (nf j simultaneously and the respectively assigned sinusoidal oscillation of a certain phase for masking out switching pulses with the repetition frequency (f ") via a line exchanger (A or A') controlled by the encryption programmer to be supplied. Considered ene publications: German Patent Specifications No. 836 046, 945 036.