DE3719670A1 - Method for the transmission of information, in particular for telecommunications systems - Google Patents

Abstract

Simultaneous outgoing and incoming transmission of information via a 2-wire line is possible only at great cost. In the case of long-distance connections, feedback circuits should also be avoided, which in particular is possible in 4-wire mode only. These disadvantages are avoided in the invention by coding the information in both directions using the amplitudes of the half-waves or cycles in each case of an alternating current of the same frequency, the two alternating currents being phase-shifted through 90 degrees in relation to each other. In the case of common electric circuits, the two alternating currents are then added together in the manner of quadrature amplitude modulation so that the information is retained.

Description

The present invention is concerned with a method for the transmission of information, especially for long distance alarm systems.

For the transmission of information such as data, voice, etc. a variety of methods are already known. So z. B. DC data for duplex data transmission GDN system known. Disadvantages of this system are that transmission via sealed lines is not possible is that the management has great demands regarding the Symme trie be put and that nevertheless a considerable effort z. B. is required by the replicas. There is still the QAM and the PSK. These modulations require a considerable amount effort as well as a wide range.

In telephone technology, for. B. in TF technology the Ge separating and the equality procedure known. Except for one he Significant bandwidth is still available in the separation process additional sieve means and 4-wire operation in the same process required. PCM technology is also very expensive necessary. In the connection technology, the cable effort is enormous; the bandwidth is hardly used.

The object of the present invention is narrowband and oh ne great effort 2-wire or quasi-4-wire more to enable compartment utilization and / or duplex operation. this will achieved by the teaching disclosed in claim 1.

In the invention, an alternating coding current for each going and intended for the coming direction. Both are thereby out of phase with each other by 90 degrees, so that these can be added together. So you can only with one Carry out frequency duplex traffic. In the connection this frees up a lot of bandwidth. Time will multiplex technology used, so you can z. B. Install the selector switch or also in the local or remote return a variety of channels and duplex operation carry out. A transfer to other sections is without Decoding possible.

The invention can also be used in radio, e.g. B. turned on the radio relay be set.

The invention is explained in more detail below with reference to the drawings. In Fig. 1, a principle of the invention is Darge. The voice transmission takes place with a coding alternating current, in which the amplitudes of the half-waves or periods represent the code elements. The code can be digital, e.g. B. a binary code with the two characteristic states large and small amplitude value, be, according to the patent DE 30 10 938, or also analog, in which the sampling men are also transmitted to the amplitudes of the half-waves or periods of an alternating current, or analog as with the PAM (Canadian Patent 12 14 277). If half-waves are provided as code elements, the frequency is 32 KHz for digital, i.e. PCM coding, and 4 KHz for analog coding. The same coding alternating current is provided for both transmission directions, but are phase-shifted by 90 degrees relative to one another. In Fig. 1, S 1 is the microphone and E 2 the listener of one participant and S 2 and E 1 of the other participant. In S 1 is still an encoder in which the coding alternating current is obtained from the language. From S 1 , the coding change current goes through a fork G , the connecting or connecting line RL to the fork G of the opposite party and to the listener E 1 . In this is also a decoder, which uses the coding alternating current to restore the original language. The coding alternating current of S 1 is the synchronous alternating current. From E 1 this is branched off via a phase shifter 90 degrees to S 2 , in which it may be amplified. If S 2 speaks, a coding alternating current which is phase-shifted by 90 degrees is transmitted via G, RL, G to E 2 , decoded there and transmitted to the listener as speech. If e.g. B. is spoken briefly at the same time, arises on the transmission path RL an addition AC, as shown in FIGS. 9 to 12, which will be described later. This principle can also be used for duplex traffic in data transmission. Since normally only one subscriber speaks in voice traffic, only 2 calling and 2 called subscribers can be connected on this basis via a line RL .

In Fig. 2, the principle of such a two-port connection is Darge. The following microphones and earphones belong together. S 2 / E 1 , S 4 / E 3 , S 1 / E 2 and S 3 / E 4 . The language of the participants S 1 and S 2 are e.g. B. with an alternating current and the language of the participants S 3 and S 4 with the 90 degree phase shifted alternating current of the same frequency. Speak straight S 2 and S 4 , so both Co dier alternating currents go through their amplifier V to the common fork, via the connecting line RL , possibly via coupler, over the fork of the opposite side to the evaluator AW. In this, the amplitudes of the two alternating currents are evaluated and assigned to the corresponding listeners, the samplings or PCM code now recorded being converted back into speech. Corresponding PCM / analog or PAM / analog converters are thus arranged in the evaluation device AW. With one alternating current of one frequency, two calls can be held simultaneously. The free bandwidth is available for other purposes.

The forks provided in FIGS . 1 and 2 need not have extreme properties.

In the Fig. 3 1 of the invention is a different arrangement as shown in Fig. Pursuant shown. This creates branch circuits for each connection, as shown in FIGS. 4 and 5. A coding alternating current is assigned to the subscriber S 1 and the same alternating current, but out of phase by 90 degrees, is assigned to the subscriber S 2 . The microphone alternating current is quantized in S 1 and to a PCM encoding alternating current according to FIG. 14a, or to a PAM alternating current z. B. uman delt according to FIG. 15b. This coding alternating current goes via the amplifier V via the line RL , the resistor R 1 to the receiver or receiver E 1 . The samples are recovered in E 1 and the speech is restored in the PAM / analog converter. A portion of the alternating coding current is branched off from E 1 via a phase shifter of 90 degrees for S 2, thereby synchronizing the two alternating coding currents. FIGS. 4 and 5 show the two week directions. The branch circuits go into the range of the respective connection. The resistors R 1 and R 2 must be adapted to the line loss RL . The arrangement of FIG. 1 is simpler in this regard.

One can of course have a central synchronization of the two Carry out alternating coding currents.  

In FIG. 6, the principle of application of the invention is shown in a switching system for a remote connection. In Fig. 1 the speech is quantized and converted into a digital or analog code alternating current. The connection then goes through the connecting line via switching matrix, the opponent was R 1 to the receiving point E 1 . With digital coding, the code alternating current is regenerated in Re . With a binary code, it is only necessary to distinguish between large and small amplitudes. Since the alternating current, which is phase-shifted by 90 degrees, also generates a return flow via R 1 , compensation can be made possible by passing a possibly existing code alternating current to the receiver E 1 via the connection KO . Since the phases of the coding alternating currents are known, the interference coding alternating current can also be compensated for using phase comparators. The phase-correct coding alternating current is connected via transmitter SF , amplifier V, fork G to the long-distance line. If a fork is also provided on the top floor , no compensation is required at all with digital binary coding. The coming from the long-distance coding alternating current of the other phase goes via the fork to the receiver EF to the regenerator Re , transmitter S 2 , amplifier V via the switching matrix of the switching center K , connecting line, subscriber R 2 , E 2 . In E 2 is a PAM analog or a PCM / analog converter, which converts the coding alternating current into speech, and feeds the listener. A coding alternating current is branched off from the receivers in each case via 90 degree phase shifters for the transmitters. As already mentioned, the coding alternating currents can also be supplied centrally by the switching center. The subscriber's coding alternating current can also be synchronized from the exchange. There is always a controlling side in the transmission line section. The far end transmitter must then be powered by the far end receiver. The total alternating current will change somewhat in phase on the long-distance line, depending on the resistance, i.e. the damping for the individual coding alternating currents.

For long-distance lines, time multiplexers will be used for bundling. A time step is not necessary. It is assumed that the digital coding alternating current has 32 KHz, the half-waves representing the code elements, then the negative half-waves are rectified. A DC pulse is then generated from the half-waves by means of a limiter. If 10 channels were to be combined, 320 KHz would be necessary as coding alternating current. Since there are still pauses between the half-wave direct current pulses, it is useful, for. B. to choose the frequency of 11 outgoing channels, ie 352 KHz. A blind tap is also provided at the beginning or end of the multiplexer. As can be seen from FIG. 8, the other circuits for the trunk line are exactly as already described in FIG. 6. Only the multiplexers and demultiplexers Mu and DMu are inserted.

In Fig. 7 is a subscriber circuit in principle according to the invention is shown. As usual, the connection is initiated by closing the current loop. The supply and loop monitoring are carried out via SP . The choice could be made by direct current pulses, with the multi-frequency method or else with the alternating coding current. This could e.g. B. happen by a predetermined number of large and small NEN amplitudes of the coding alternating current. This would be just as secure as the DTMF . Since only one frequency with low bandwidth is required for the speech connection, the frequencies of the bandwidth not used are filtered out with filter Fi , ie are provided for other purposes. Denoted in Fig. 7 with ff . The call current can be switched to the line via SK as before and fed to the subscriber under "Call". You can also encode the call with the coming coding alternating current. The outgoing coding alternating current is sent via S 1 , V, Ltg, ÜV and the incoming via ÜV, Ltg, VL, ÜE, E 2 .

In FIGS. 9, 10, 11 and 12, the coding alternating currents are described in greater detail. In Fig. 9, the two surrounded by 90 degrees phasenverscho coding alternating order and Vm are shown. If they are interconnected on the transmission path, a total alternating current Um occurs. If both coding alternating currents are equal, the phase of the total alternating current is 45 degrees away from each. In FIG. 11, the summation of the two coding alternating U and V is now represents the sum alternating current Ü Darge. It can be seen from this that at the zero crossing of U 180 , V passes through the greatest value and, conversely, at the zero crossing of V 270 , U assumes the greatest value. If U or V is used as the reference alternating current, the amplitudes of the coding alternating currents can be determined from the total alternating current.

FIG. 12 shows an overview of all 3 alternating currents U, V and Ü . It is important for the present invention that the two coding alternating currents on the transmission path do not influence or cancel one another. From Fig. 10 it can still be seen that the phase position of the Summenwechselstro mes is determined by the size of the two Co dier alternating currents U and V. If both are never smaller than UK and VK , the phase change from Ü is very small. In such a case, the values of U and V are easy to determine. With a binary digital code there are no problems at all. When using forks ( Fig. 1), both coding alternating currents never come to the receiving devices.

In Fig. 14 a Digitalbinärcode is shown, in which the Pe rioden used as code elements. The characteristic states, as can be seen from FIG. 14a, are a large and a small amplitude value. This code alternating current is divided into 4 coding alternating currents which is in phase against each other ver 90 degrees (Fig. 14b, c, d, e) and each of which is only _^1/4 of the frequency of Fig. 14a has (see also European Patent Application 01 10 427).

In FIG. 15 a, a speech vibration is sampled P 1, 2, 3 . . . taken (PAM) and transferred to the half-waves in Fig. 15c or Perio that of a coding alternating current ( Fig. 15b). The principle is dealt with in detail in European patent application 01 10 427.

It is of course also possible to combine several channels in a time-multiplexed manner and transmit them with only one coding alternating current. In Fig. 13 4 channels are tapped time-multiplexed, so that a tapping frequency of 4 × 8 KHz = 32 KHz is required. If the periods according to FIG. 15b are used as code elements for the transmission, then a coding alternating current of 32 kHz is required for the transmission. In FIG. 8 such Zusammenfassun are used gen. You could z. B. also use the selector switch.

When using a PAM code it is with connecting lines  appropriate a resistance compensation for each line to create or from the participant from the coding alternating current a largest and smallest amplitude value for comparison to be sent during the evaluation. Acknowledgment pulses are also necessary if the coding alternating currents are used for the sign can be used.

Even with radio z. B. for radio relay can the invention Method should be provided if the Fresnel zone is observed.

Claims (7)

1. A method for the transmission of information, in particular for telecommunications systems, characterized in that for the multiple use and / or duplex traffic in the transmission of analog and / or digital information, an alternating current of only one frequency is provided by the information to be transmitted by both Directions (coming, going) is coded by the amplitudes of the half-waves or periods of only one alternating current and sent in an uninterrupted sequence of positive and negative half-waves, the alternating coding currents in both directions are phase-shifted by 90 degrees to one another, and are still AC circuits of both directions dimensioned ( Fig. 4, Fig. 5) or such separating means provided ( Fig. 1, G) that a reliable evaluation of the coding alternating current assigned to him takes place in the respective receiver. 2. The method according to claim 1, characterized in that in order to avoid larger phase jumps, the amplitudes of the smallest value to be transmitted never reach the value zero ( Fig. 10, smallest value UK , largest value UK + U) . 3. The method according to claim 1, characterized in that phase comparators are provided in the receiver, which, if necessary, to compensate for the coding alternating current of the opposite direction ( Fig. 6, S 2 ) make a continuous counter-switching of a phase-shifted alternating current of the same frequency. 4. The method according to claims 1 to 3, characterized in net that the synchronization or generation of the coding alternating currents from a central point, in particular from from the exchange. 5. The method according to claims 1 to 4, characterized in that in long-distance traffic, a terminal is set as a controlling Festge, the other terminal is from the receiving AC current ( Fig. 6, EF) and a 90 degree phase shifter ( Fig . 6, 90 °) produces Sendecodierwechselstrom. 6. The method according to claims 1 to 5, characterized in that two channels are summarized on both sides time-multiplexed together ( Fig. 8, Mu, DMu) . 7. The method according to claims 1 to 6, characterized in net that digital codes are provided for the criteria,  which are formed from the code elements of the coding alternating currents , where necessary, receipt signs are provided.