NL1025305C2 - Telecommunication digital transmission system uses first transmission multiplexer for multiplexing first set of bit-streams to second set of bitstreams - Google Patents

Abstract

The telecommunication digital transmission system uses a first transmission multiplexer (22) for multiplexing a first set of bitstreams (8) to a second set of bitstreams (24). A distribution device (20) is connectable with the first transmission multiplexer and distributes the second set of bitstreams to a third set of bitstreams (12). The distribution device has a second transmission multiplexer (26) for multiplexing the second set of bitstreams to a fourth set of bitstreams (32). It also distributes the fourth set of bitstreams to the third set of bitstreams. The first and second multiplexers are so arranged that the number of bitstreams from the second set is smaller than the number from the third set.

Description

Digital transmission system with multiplexer in distribution device

The invention relates to a digital transmission system comprising: - a multiplexer device comprising a first transmission multiplexer arranged for multiplexing a first set of bitstreams to a second set of bitstreams, and - a distribution device connectable to the first transmission multiplexer and arranged to distribute the second set of bitstreams to a third set of bitstreams.

Such systems are known and are used in practice by, for example, telephone companies for connecting end users to a Metro-10 ring such as a 2.5 Gbps Synchronous Digital Hierarchy (SDH) or a Synchronous Optical NetWork (SONET) telecommunication network. It is noted that the term "multiplexer" refers to both a multiplexer and a demultiplexer, depending on the direction and distribution of the bitstreams.

A telephony company typically uses a transmission system whose multiplexer device, such as a device rack with one or more transmission multiplexers, is on a transmission department, and a distribution device is on a distribution department. The transmission department and the distribution department are normally physically separate rooms. Coax cables are used for communication between a transmission multiplexer and a distribution device. The number of cables depends on the bitstreams that are sent between the transmission multiplexer and the distribution device. For example, an SDH multiplexer with a capacity of 155 Mbps (63xEl) is connected to the distribution device with the aid of 63 pairs of coaxial cables. Each pair of coaxial cables provides a single El bitstream in both directions. In the distribution device 25, the 63 bitstreams are distributed (patched) to 63 outputs of the distribution device which in turn are connected to 63 end-user connections. STP cabling is often used instead of coaxial cables.

Due to the increasingly compact construction of the multiplexers, more and more multiplexers can be placed in a device rack. The smaller dimensions of the 30 multiplexers and the number of multiplexers in a single device rack cause cabling problems. This applies in particular to "El / Tl" connection cables, where plugs and cables limit the capacity of the equipment. Often a huge amount of cables must be concealed in a single device rack. device cabinet. Cable ducts to 1 025305 I 2 the distribution space become overcrowded and its installation costs a lot of money for both maintenance work and the material itself. | The object of the present invention is to reduce the number of cables necessary to connect a transmission multiplexer in a multiplexer device to a distribution device.

This object is achieved with a digital transmission system as described in the introduction, characterized in that the distribution device comprises a second transmission multiplexer for multiplexing the second set of bitstreams to a fourth set of bitstreams, the distribution device being arranged for distributing From the fourth set of bitstreams to the third set of bitstreams, the first and second transmission multiplexers being arranged such that the number of bitstreams of the second set of bitstreams is smaller than the number of bitstreams of the third set of bitstreams.

By using a second transmission multiplexer that is placed in the distribution device and efficiently arranging the first transmission multiplexer, the number of bit streams going to the distribution device can be reduced.

I As a result, fewer cables are required than with known systems.

In one embodiment, the digital transmission system is arranged for a I Synchronous Digital Hierarchy (SDH) telecommunications network. In this case, the second set of bitstreams, for example, consists of STM1 bitstreams, and the third set of bitstreams, for example, consists of E1 bitstreams. For example, if the distribution device divides 63 E1 bitstreams over 63 E1 user connections, then the fourth I set of bitstreams will consist of 63 E1 bitstreams. The second transmission multiplexer is then an STMloE1 multiplexer that multiplexes 1 STM1 bitstream to 63 E1 bitstreams.

The first multiplexer will now be arranged such that it has one or more STM1 outputs. has connections. Such multiplexers are commercially available, such as, for example, a multiplexer with an 8xSTM1 tributary unit. Such a "unit" can be connected to the second transmission multiplexer via, for example, one pair of optical fiber optic cables. This configuration therefore provides a cable reduction from 63 pairs of coaxial cables to one pair of fiber optic cables.

The second transmission multiplexer preferably comprises a connection panel which is adapted for connecting conventional distribution cabling. Because the I connection panel is suitable for conventional cabling, I 1 025305 3 staff will be able to easily connect or patch the transmission multiplexer to a distribution space that is normally not trained to handle multiplexers.

In one embodiment, the second transmission multiplexer comprises a removable cassette in which at least a part of the functionality of the transmission multiplexer 5 is stored. For repair of the second transmission multiplexer, a housing of the second transmission multiplexer can now remain in the distribution device, read distribution rack. The cassette can simply be pushed back into the housing when it is replaced, without the distribution room operator having to do any connection work to the distribution cabling.

Preferably, the second transmission multiplexer comprises a remote control module, for remote control and / or management of the second transmission multiplexer. The transmission multiplexer can then be managed by the staff of a multiplex space, and furthermore there is no need for additional cabling.

In another embodiment, the digital transmission system is arranged for a Synchronous Optical NetWork (SONET) telecommunications network. In this case, the second set of bitstreams, for example, consists of OC3 bitstreams, and the third set of bitstreams, for example, consists of T1 bitstreams. The second transmission multiplexer is then an OC30 T1 multiplexer that multiplexes 1 OC3 bitstream to multiple T1 bitstreams.

The invention also relates to a transmission multiplexer adapted for use in a distribution device of the above-described system.

Finally, the invention relates to a method as described in claim 10. In the distribution device, the second set of bitstreams is multiplexed to a fourth set of bitstreams, which in the distribution device is again distributed to the third set of bitstreams. The multiplexing in the multiplexer device and in the distribution device is performed such that the number of bitstreams of the second set of bitstreams is smaller than the number of bitstreams of the third set of bitstreams. In this way the number of bitstreams between the multiplexer device and the distribution device can be reduced. This results in a saving of the number of cables between the two devices compared to the known systems.

1 025305

Further advantages and features of the present invention will become apparent on the basis of a description of some embodiments, with H being referred to the accompanying drawings, in which: FIG. 1 is a schematic block diagram of a prior art system;

FIG. 2 is a schematic block diagram of a system according to an embodiment of the invention; FIG. 3 is a cross-sectional view of a transmission multiplexer according to an embodiment of the invention, and FIG. 4 is a front view of an apparatus rack for transmission multiplexers in an embodiment of a system according to the invention.

Figure 1 shows a digital transmission system from the prior art. The digital transmission system consists of a multiplexer device 2 and a distribution device 4. The multiplexer device 2 comprises at least one transmission multiplexer 6 which is arranged to disable a bitstream 8, such as, for example, a 2.5 / 10 Gbps SDH. multiplexing to a set of E1 bitstreams 10. The set of bitstreams 10 is distributed in the distribution device 4 one-on-one over a set of bitstreams 12. For realizing this distribution, the distribution device 4 comprises a primary terminal block I14 and a secondary terminal block 16. Each terminal block 14, 16 comprises a number of I terminal points. Cables can be attached between the two terminal blocks so that a particular terminal of the primary terminal block 14 is connected to a specific terminal of the secondary terminal block 16. This interconnection, also referred to as patching, is shown in Figure 1 by a large cross.

The set of bitstreams 12 is, for example, 63 E-bit streams that go to end users I of the digital transmission system. In this case, the number of bitstreams of the I set of bitstreams 10 will also be 63. Each E1 bitstream is routed via a cable, such as a coaxial cable. Thus, in the example described above, 63 pairs of coaxial cables I 30 are required between the multiplexer device 2 and the distribution device 4. This high number of coaxial cables causes space and maintenance problems in the multiplexer

device 2 and the transmission multiplexer 6 itself. If the multiplexer device 2 I

If several transmission multiplexers are included, this problem will be even greater.

I 1025305 5

Figure 2 shows a digital transmission system according to an embodiment of the invention. The digital transmission system comprises a multiplexer device 18 and a distribution device 20. The multiplexer device 18 comprises at least one transmission multiplexer 22 which is arranged to multiplex a bitstream 8, such as for example a 2.5 / 10 Gbps SDH / SONET, to a set of STM1 Bitstreams 24. According to an aspect of the invention, the distribution device 20 comprises a transmission multiplexer 26 which is adapted to multiplex the set of STM1 bitstreams 24 into a set of E1 bitstreams. In this embodiment, the transmission multiplexer 26 comprises a multiplex module 28 and a connection panel 30. The multiplex module 28 is adapted to multiplex the set of STM1 bitstreams to a set of E1 bitstreams 32. Via the connection panel 30, the set is supplied in the distribution device 20. E1 bitstreams 32 distributed one-on-one over a set of bitstreams 12. For realizing this distribution, the distribution device 20 comprises a standard secondary terminal block 16. The terminal panel 30 comprises the same number of terminals as a primary terminal block from the prior art. See connection block 14 of figure 1. The connection panel 30 preferably has the same layout as the connection block 14 of figure 1. Operating staff working in a distribution room will therefore be able to operate the distribution device 20 of the new system easily and without any additional training. .

Figure 3 shows a cross-section of the transmission multiplexer 26 according to an embodiment of the invention. The transmission multiplexer 26 comprises a housing 29 into which a cassette 31 can be inserted. The cassette 31 contains at least a large part of the electronics of the transmission multiplexer 26. The cassette 31 comprises at one end a front panel 33 on which one pair of fiber optic cable connections 34 sits and two LEDs 36 and 38. The LED 36 is an indicator for the operational of the transmission multiplexer 26 and the LED 8 is an indicator indicating that the cassette 31 must be replaced. At a different end of the cassette 28 there is a 'male' connection 40 which fits into a 'female' connection 42 of the transmission multiplexer 26. The transmission multiplexer 26 comprises a connection panel 44 which is connected via internal connections 46 to the 'female' connection 42. The transmission multiplexer 26 also comprises a power connection 48 for receiving and transmitting electrical power which is connected to the 'female' connection 42. If the cassette 31 is slid into the housing 29 such that the 'male' connection 1 025305 Η 40 and the 'female' connection 42 are coupled, the cassette 31 will be supplied with voltage from the output via power connection 48 power. The terminal panel 44 comprises terminals whose number and layout correspond to a conventional primary terminal block such as the terminal block 14 of Figure 1.

Thus, after implementation of the invention, operating personnel will hardly see an H change in the distribution device. Preferably, the cassette 31 comprises an H remote-controlled control module, not shown, for remote control and / or management of the transmission multiplexer 26.

Figure 4 shows a front view of a multiplexer device 60, for example H 10, a device rack 60, in which at least two transmission multiplexers 22, 23 H are placed. In this embodiment of the invention, the transmission multiplexer 22 comprises a plurality of line cards 62.63 (also called tributary units) wherein line card 62 is connected via a fiber optic cable connection to a distribution device, not shown, via fiber optic cable 64. This fiber optic cable 64 becomes an STM1 I 15 bitstream sent. Between the multiplexer device 60 and the distribution device I is a cable duct 66 in which the cable 64 is concealed. As already noted, a significant reduction in the number of cables is obtained by sending STM1 bitstreams to the distribution space instead of E1 bitstreams.

It will be understood that when reading the above, variants I immediately come up with the person skilled in the art. Instead of STM1, STM4 (620Mbps) can also be used; similarly, for a SONET network, the second set of bitstreams may consist of OC12 bitstreams instead of OC3. Such variants are considered to fall within the scope of the application as described in the appended claims.

I 1025305

Claims (12)

A digital transmission system comprising: - a multiplexer device (2) comprising a first transmission multiplexer (6; 22) adapted to multiplex a first set of bitstreams (8) to a second set of bitstreams (10; 24), and - a distribution device (4; 20) connectable to the first transmission multiplexer (6; 22. and arranged to distribute the second set of bitstreams (10; 24) to a third set of bitstreams (12), characterized in that the distribution device (20 ) comprises a second transmission multiplexer (26) for multiplexing the second set of bitstreams (24) to a fourth set of bitstreams (32), the distribution device (20) being adapted to distribute the fourth set of bitstreams (32) to the third set of bitstreams (12), wherein the first and second transmission multiplexers (22, 26) are arranged such that the number of bitstreams of the second set of bitstreams (24) is smaller than the number of bitstreams of the third set of bitstreams (12). 2. Digital transmission system according to claim 1, wherein the digital transmission system is adapted for a Synchronous Digital Hieraichy (SDH) telecommunications network. The digital transmission system according to claim 1, wherein the digital transmission system is adapted for a Synchronous Optical NetWork (SONET) telecommunications network. 25 The digital transmission system according to any of the preceding claims, wherein the first transmission multiplexer (22) and the second transmission multiplexer (26) are arranged to communicate via optical connection cables. A digital transmission system according to any of the preceding claims, wherein the second transmission multiplexer (26) comprises a connection panel (44) adapted to connect conventional distribution cabling. 1025305 The digital transmission system of claim 5, wherein the terminal panel (44) is adapted to connect E1 / T1 cables. A digital transmission system according to claim 5 or 6, wherein the second transmission multiplexer (26) comprises a removable cassette (31) in which at least a part of the functionality of the second transmission multiplexer (26) is stored. A digital transmission system according to any one of the preceding claims, wherein the second transmission multiplexer (26) comprises a remote control module I10 for remote control and / or management of the second I transmission multiplexer (26). A digital transmission system according to any one of the preceding claims, wherein the distribution device (4; 20) comprises a patch device. I 15 A transmission multiplexer (26) adapted for use in a distribution device (20) of the digital transmission system according to one of the preceding claims. A method for digital transmission comprising the steps of: I - multiplexing a first set of bitstreams (8) in a multiplexer device (2) to I a second set of bitstreams (10; 24), and I - it in a distribution device (4; 20) distributing the second set of bitstreams (10; 24) to a third set of bitstreams (12), characterized by: - multiplexing the second set of bitstreams (24) in the distribution device (20) to I a fourth set of bitstreams (32), and - distributing in the distribution device (20) the fourth set of bitstreams (32) to the third set of bitstreams (12), the number of bitstreams of the second set of bitstreams (24) ) is smaller than the number of I bitstreams of the third set of bitstreams (12). I 1025305 The method of claim 11, wherein the distribution device (4; 20) comprises a patch device. 1025305