DE676205C - Arrangement for switching through the carrier frequency channels of a message transmission system - Google Patents

Description

Arrangement for switching through the carrier frequency channels of a communication system A news posting system. by means of carrier waves z. B. from high-frequency transmission lines, which connect the individual remote offices to each other, and medium or low frequency Feeder lines. Such a system is supposed to keep the traffic flowing smoothly in the individual switching points, i.e. in the end and intermediate offices, the administrative institutions for simplicity and adaptability Not inferior to the official facilities in low-frequency systems.

To achieve this object, it is proposed according to the invention that in the final i or intermediate offices means, e.g. B. Filters and /, or modulation devices, to provide that make it possible to use the channels, e.g. B. medium frequency channels, the incoming Management to make cables individually accessible and on any channels, e.g. B. radio frequency channels to transpose the outgoing line or lines.

In the case of the direct connection from the medium frequency signal to the I-1, o-chä-equ # enzkanal, a distinction can be made between two methods: group connection and individual channel connection. In the case of group switching, the high-frequency line is connected to the medium-frequency feeder lines in such a way that the medium-frequency channels are transposed as a unit into the band of the high-frequency system by a group modulator and, at the end of the high-frequency line, are also medulated back into a medium-frequency band as a group. This way turns out to be very inexpedient if you use it z. 13. Applies to a network according to Fig. I. The stationaj. is connected to the FernamtF1 by a medium frequency line. Likewise, the statIonsa2, b. and e2 connected to the remote exchange F # by such a line. If a conversation from a: L nacli b. if required, this can be established in the manner just described; but then because of the group principle, all channels, for example io, of the medium-frequency line a., to F, are switched through to b2 and paralyzed for traffic in any other direction. The same applies to the neighboring group channels, for example 9, in the high-frequency system and in the medium-frequency line F !, to b2. This method is generally only acceptable if between a1 and b. always like that. There is a lively traffic relationship that the permanent provision of io channels is justified.

A more complete solution in terms of traffic engineering is only possible if the carrier frequency bands are broken down into individual channels at each switching point. This is done by installing filters and at least one modulation stage in the remote exchange.

There are various possibilities for the transition from the medium-frequency feeder lines to the high-frequency long-distance line and vice versa, which can be used depending on the operating situation at hand.

According to the further invention, exi channels are obtained from the ones obtained by the separation a series of frequency adjacent channels, e.g. io, die, all, or to Part can come from different medium-frequency cables, in per se known Way given to a common modulator. You kgmmt with a lower one Number of modulators whose lower ends are equal to the number of available ones standing high-frequency channels divided by the number of medium-frequency channels of one Feeder line is.

A circuit arrangement of this type is shown in Fig. 2. . The medium-frequency channels arriving in the remote office F, are passed through filters S1, which have the bandwidth of a single channel, to group modulators in which the medium-frequency channels, for example ten from different medium-frequency cables but arranged in the order of the frequency, are transposed together into the high-frequency band will. In the remote office F, the neighboring high-frequency bands are correspondingly down-modulated into medium-frequency bands by FilterS. separated into individual channels and distributed in the desired exit directions. With sufficient elasticity of the operation, a reduction of the effort is achieved by this measure.

However, if all high-frequency channels in the FernamtF1 originate from the same medium-frequency band, for example 12kHz, of the individual medium-frequency cables, also in the FernamtF, to end on the same medium-frequency band, for example 24kHz, there would be the risk of a large traffic density Number of strongly requested connections cannot be established. Should z. B. two with 12 kHz on the Kabelnal. and bl. incoming talks were to be performed by a #, su would 24kI-1z-B, and mia. be occupied twice. So it could. only one connection can be established at a time. In order to remedy this deficiency, it is proposed according to the further invention that all calls be made in the same medium frequency band. Office F, in Office F. on from the original # * unlikely. different center frequencies ## 4: end. to let, so that z. B. the ten high-frequency channels that arrive in office F, with 12 1, -I-Iz, end in office F2 with 12, 1 6 ... 48 1,: Hz. The same also applies in the direction from office F2 to office F, .. In this case, there is a multiple selection option for a connection, in the selected example tenfold, so that each from office F ,. The conversation offered can be picked up by a medium-frequency cable going out from Office F., for example to a2, on any currently free frequency band between 12 and 481zHz. In this method, a group modulation, as described above, can also be used in a manner known per se on an office side, ie on the sending / receiving side.

A circuit of this case is shown in Fig. 3. The medium-frequency channels are shifted over the high-frequency system, so that, for example, an outgoing Ges radl with i21, -Hz .in Fernamt F, appears on p 24kHz behind the first demodulator ini FernamtF2. If one chooses the entanglement so-that each of the IT center frequency channels is in each case once converted into any other medium-frequency channels, so stealing for all the toll office F, -ankommenden center frequency channel every ten output channels from the remote office F, after Stationa2 for selection.

If even higher demands are made on the transmission system with regard to the interchangeability of the connections, then according to the further invention the modulators, of which in this case one is to be provided on both sides for each high-frequency channel, are not permanently connected to specific medium-frequency filters, but rather each modulator -'can be connected as required to each of the medium-frequency filters, which are arranged, for example, at the ends of the medium-frequency cables. The channels of the radio frequency line then form a perfect bundle with regard to the incoming and outgoing traffic, i. H. all high-frequency channels can be reached in the same way by all incoming calls and vice versa. In this case there is no detrimental occupied influence of the medium frequency channels on the high frequency system. Fig. 4 shows how this promotion of mutual freedom of choice can be achieved. The medium-frequency cables lead to filter S, for channel separation. The high-frequency system is equipped with m M # oJulators M and second filters S on each side. The ioo required carrier frequencies lie on a Vialfacliveiteile.i, each has the ioo generators # G to be able, n, for example, ten 'Mo # Dulat, o, reindeer simultaneously to feed. For switching the center frequency call is / at the frequency "to the modulator of any of any free Hachfiequenzkanals f the frequency set. At the same time from the Trägerfr # equenzverteiler that Trägerfrequ enz, it applied to the modulator, after the modulation (f" = ft ± / ") leads into the free high-frequency channel. - In the same way, a completely arbitrary distribution of the high-frequency channels to the medium-frequency channels can be achieved at the output of the high-frequency channel.

This method can also be used in the case that several high-frequency cables meet in an office and distribute them to a plurality of medium frequency cables are.

Urn. a Deppel occupancy of the high-frequency channels in any case avoid, are according to the further invention simultaneously with the switchover the filters that are located at the entrances and exits of the modular doors Carrier frequencies changed appropriately. If you choose the conversation distance in Medium frequency and the same in the high frequency range, e.g. B. 4 kHz, so you come for all conceivable connections with a total of 100 lobes at a distance of 4 kHz. The number of carrier waves is therefore no greater than the number of high frequency channels. A multiple distributor for these carrier frequencies that exists once in the office can so. always; all modulat [who supply the desired frequency.

In the case of the hocl-ifrequenteii connection just discussed, it was assumed that that all the feeder traffic is medium-high. However, there are also often there are cases in which only part of the feeder traffic is on carrier waves, while the rest flows in and out at low frequencies. So it's in the remote offices Provide facilities for complete demodulation of the high-frequency channels. If the offices are dominated by the low-frequency channels, then, according to the other Invention all incoming channels were switched through at low frequencies. To have to therefore derodulators are provided for the existing medium-frequency channels. This measure has the advantage that all support channels in the offices can be traced back to two-wire connections via low-frequency forks, which in terms of circuitry do not differ in any way from the usual connections. This method of derodulation on the low-frequency band can also be used the cases are used in which only carrier frequency channels arrive in the office; because the advantage of the connection via low-frequency two-wire forks remains in this case too. The transposition of the low frequency channel in the high-frequency band is expedient in itself bel, -, annter way by means of a Multiple modulation.

With this type of connection, you are completely free to choose the high-frequency carrier wave, see above. that even with the heaviest traffic congestion everyone high-frequency channel can be exploited.

Which type of connection is used in the individual case in the remote exchange depends largely on the local operating conditions. Furthermore it is it is not necessary to use the same procedure in the FernaintF2 as in the FeinamtFl, so that the transmission system is largely adaptable to the operating conditions.

Claims (2)

PATENT REQUESTED: i. Arrangement for switching through the channels of a message transmission system working with carrier waves, in which the transmission of the calls to and from the end or intermediate offices also takes place wholly or partially at carrier frequency, characterized in that means in the end or intermediate offices 7. g. Filters and / or the module, atignereinrichtungen, are provided that allow the channels, z. B. to make medium frequency channels, the incoming line or lines individually accessible and to any channels, z. B. Hüchfr #frequenzkanäle to transpose the outgoing line folder lines. 2. Arrangement according to claim i, characterized in that the through-.Switching takes place in the medium frequency range. 3. Arrangement according to claim 2, characterized dadurcli that between the ends of the medium-frequency feeder lines and the transposition into the I-fochfrequenzband effecting modulators and vice versa filter arrangements are switched on such that a separation of the different channels fed on a common medium-frequency line into individual medium-frequency bands he follows. 4. Arrangement according to claim -, characterized in that on the transmitting and /, o # of the receiving remote office several frequency adjacent medium-frequency channels, which .all or partly from different medium-frequency lines can be displaced in a known manner by common modulator to the high-frequency band . 5. Arrangement according to claim 3, characterized in that from all high-frequency channels which transmit calls in the same medium-frequency band, medium-frequency bands different from one another are obtained on the opposite remote exchange after demodulation. 6. Arrangement according to claim 3, characterized in that the modulators and DernodulatDren belonging to the individual high-frequency channels can optionally be connected to any medium-frequency filters. 7. Arrangement according to claim 3, characterized in that the modulators and demodulators belonging to the individual high frequency channels are each charged with a carrier frequency assigned to the connected medium frequency filter and the location of the high frequency channel. I 8. Anardnung according to claim 3, characterized in that the distance between the communication channels in the high and medium frequency range is the same. G. Arrangement according to Claim 3, characterized in that the various optionally switchable carrier frequencies are taken from a frequency multiple distribution system which comprises as many carrier frequencies as there are high-frequency channels. ok Arrangement according to Claim i, characterized in that the switching takes place in the low-frequency range. i i. Arrangement according to claim 10, characterized in that every incoming medium-frequency, #quent call is demodulated onto the original voice band and every outgoing call is transported from this frequency band by modulation to its final place in the high-frequency range. 12. The arrangement according to claim ii, characterized in that each outgoing call is transposed from the low frequency hand by Mehrfachmodulatlon to its express place in the high frequency range.