FI87123C - System for securing the trunk frequency central channels in a digital transmission device - Google Patents

Description

The present invention relates to a system for combining two mutually securing transmission devices, such as a radio link or the like, with substantially identical main channel connections so that only one of them is active at a time.

Certified transmission devices, which typically use two identical and parallel transmitters and receivers, e.g. a radio link, and a baseband coupler connected to them (so-called 1 + 1 authentication), operate in both the input and output directions of the telecommunication network. The choice of the radio device to be used in each case is usually based on which device receives the best signal.

In known solutions, the switching device branching function between two transmission devices is integrated as part of one of the two authentication devices, e.g. a radio link. In this case, the branching device includes and is dependent on the second transmission device 20 and its active components, the fault frequency of which directly affects the fault frequency of the branching device. In this case, disconnecting the damaged device for repair may disconnect the entire connection while the device is being replaced or repaired. In addition, the structure of the devices may be different in different environments and modes of use and cumbersome in terms of production.

The object of the invention is to provide a method and a device by which the above-mentioned disadvantages are avoided. To achieve this, the system 30 according to the invention is characterized in that the system comprises a separate branch in which the main channel connections of the transmission devices are connected, the main channel is branched in the input direction by at least one transformer, and in the output direction galvanically or by at least one transformer.

35 In the event of a fault, the reciprocal radio links / transmission devices may decide to transfer traffic to a functional device under mutual control. Only 2 87123 baseband splitters are common to the devices. In this way, considerably better reliability is achieved, which is the main object of the invention. In current solutions, large parts of the device are not certified.

5 The improvement of the reliability of the transmission connection against equipment is implemented in the invention in a manner almost independent of the basic radios. The transfer devices can be identical in structure and independent of the mode of operation, i.e. they can be the same as those used in non-certified systems. A separate branching device makes the system simpler than known systems in terms of production and customer equipment selection.

Other preferred embodiments of the invention are characterized by what is set forth in the claims below.

The invention will now be described in more detail by way of example with reference to the accompanying drawings, in which Figure 1 shows a pair of certified transmission devices using prior art, Figure 2 shows a certified radio link station implemented according to the invention, Figure 3 shows a branch according to an embodiment of the invention, Figure 4 shows another embodiment of the invention. 25 shaped branches.

In the known solution according to Figure 1, two transmission devices are connected to the main digital channel, i.e. the telecommunication network A, in this example radio link 1 and 2. In addition to the actual link device 5, the second radio link 1 also contains the necessary interface, G.703 interface 3 and changeover switch 4. both against device failures in the link devices 2.5 and against propagation disturbances of the signal received by the devices, by changing the link device e.g. 35 when the quality of the received signal is poor. The G.703 interface t: 3 87123 is a standard interface for telecommunication networks, the specifications and features of which are obvious to a person skilled in the art. On the transmission path B side, when the transmission devices are radio links as in this example, the antenna cables 5 of the radio links can e.g. be connected to an antenna splitter 6 for retransmission via the antenna 7.

In conventional solutions, the branch device is thus an intelligent changeover switch 4 implemented from active components and the necessary connection 3 built in connection with the second radio link 5 10.

Fig. 2 shows a certified radio link station according to the invention, corresponding to Fig. 1, comprising a baseband coupling device 8 according to the invention, two radio links 9 and 10 and, as above, an antenna coupler 6 and an antenna 7. The radio links 9 and 10 consist of actual transmission devices 11 and 12 and modified G.703 terminals 13 and 14 with improved input attenuation tolerance, inactive output switching to a suitable sleep mode, output direction 20 adaptation to baseband coupler 8, and the portion of the program of the radio link processor that controls the G.703 interface when the changeover command arrives outputs to the correct state. The radio link connection parts 13, 14 must be designed to co-operate with the baseband coupler 8. Since the transformer at the 25 inputs (see Figures 3 and 4) attenuates the signal, it must be taken into account in the design of the corresponding input of the transmission device so that the the input tolerates the attenuation caused by the branch in addition to the normal attenuation.

Since the baseband coupler 8 can galvanically connect the outputs of the transmission device 30 (see Fig. 3), the outputs 13,14 of the transmission device 11,12 must be designed so that it is possible. The transfer device's own control unit directs the outputs to a suitable state according to which of the devices are in use. Since only one of the outputs is in the active state 35, the control units of the transmission devices must have a communication connection 15 to each other 87123 4. This is also necessary for signal propagation verification, since this function has been removed from the baseband branch 8 for radio links 9 and 10 in the solution according to the invention.

5 The device verification switch 17a, 17b directs the signal to the current propagation verification switch 18a or 18b, which switches the signal to the second link of the path whenever necessary, e.g. when the signal received from the transmission path B is weak. Switches 17a, 17b, 18a and 18b are electronic switches 10 controlled by transmission control units (not shown). In general, only one of the connections 13 and 14 is active at a time, i.e. the signal passes only through the connection of the second radio link through the baseband coupler until a fault or the like gives reason to replace the second connection 15.

As devices, the radio links 9 and 10 are identical, and the branch 8 is a completely separate device, which only takes care of the device verification of the link station, i. in the event of a fault, disconnecting the faulty link (9 or 10) from the traffic-20 road. As data now travels to and from the radio links in the telecommunication network A, the common, unsecured parts in the secured pair formed by the links 9 and 10 are minimized by forming only a branch 8 built of very far passive parts. This arrangement according to the invention considerably increases the reliability of the radio link station.

Figure 3 shows a splitter according to an embodiment of the invention, which is a splitter operating at a speed of 2 Mbit / s. This branch is completely passive, 30 in which the input direction is realized by a secondary winding transformer 21 on the secondary side and the output direction by simply galvanically (22) connecting the wires of the transmission devices.

Figure 4 shows a splitter according to another embodiment of the invention, designed to operate at a speed of 35 34 Mbit / s. At these speeds, amplifiers 19,20 active in the input direction of the branch 5 87123 are needed, which amplify the signals from the transformer 21, and in the output direction generally also an impedance matching transformer 23. The active parts of the 34 Mbit / s branch must have a secured power supply 16 (Fig. 2).

It will be apparent to those skilled in the art that the various embodiments of the invention are not limited to the examples set forth above, but may vary within the scope of the claims below. Thus, the telecommunication network connected to the branch can be a fixed network, e.g. a telephone network, a radio path or a telecommunication terminal, such as a PAD computer. The transmission path used by the transmission devices can also be as well a fixed network or an optical transmission path as a radio path. Without departing from the invention, the signal shared by the baseband splitter may also travel a geographically different path, e.g.

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Claims (2)

6 87123 1. A system for the simultaneous transmission of data transmission data, including radio links (9,10) or multiple data transmission and other identical central channel transmission (13,14), which is not associated with activation, kännetecknat därav, det account 25 is a system for separating the mains (8), and for the mains of the mains of the transformer (21), and of the mains of the transformer (21) av ätminstone en transformator (23). A system for connecting two mutually securing transmission devices, such as a radio link (9, 10) or the like, substantially identical main channel connections (13, 14) so that only one of them is active at a time, characterized in that the system comprises a separate branch (8) in which the main channel connections of the transmission devices are connected, the main channel 10a (A) is branched in the input direction by means of at least one transformer (21), and in the output direction galvanically (22) or by means of at least one transformer (23). System according to Claim 1, characterized in that active amplifiers (19, 20) are connected to the secondary side of the transformer (21) which divides the main channel 15 (A) of the branch (8) in the input direction. A system according to claim 1, which comprises a secondary device (8) and a transformer (21) in the form of a central channel (A) and an active circuit (35, 20).