DE3805632C1 - Circuit arrangement for maintaining an emergency operation in a broadband transmission link - Google Patents

Abstract

When the power supply fails, for example in a broadband connection, it should be possible to maintain an emergency operation over a relatively long time via assemblies fed by local batteries and a basic access multiplex channel should be available for voice and narrowband data at a reduced bit rate. The circuits needed for the highest frequencies (approx. 140 MHz) which have a high current consumption, are disabled when the power supply fails. A number of switching multiplexers are provided which are activated by an emergency signal which is generated when the power supply fails. The switch-over of the clock supply to a clock generator operating at a lower frequency and the switch-over of the datastream is thus effected in such a manner that the disabled circuits are bypassed or replaced. The circuit arrangement should be used in broadband data connections, existing circuit sections which have a low current consumption also being used in emergency operation so that this emergency operation can be maintained over a relatively long time, the additional expenditure for switch-over measures being extremely low.

Description

The invention relates to an upright circuit arrangement maintaining an emergency operation in a broadband transmission route according to the preamble of claim 1.

Because very high frequencies when transmitting broadband data of, for example, 140 MHz are required for the multiplexing circuits are used, the one have extremely high switching speeds. Such switching circles are relative because of their high switching speed designed low-resistance, so that a high power consumption inevitably arises. If such assemblies their Lei power requirement from the main power supply of an intermediary system or from the mains power supply of a connection can cover no problems. Are ever but to maintain an emergency operation local independent pending power supply devices provided so whose capacity is not chosen to be of any size. Who which, for example, batteries are used to turn off emergency operation in the event of normal power supply their capacity would be exhausted in a short time, if circuits are connected from it, which are very  have high power consumption.

From DE-OS 30 44 605 is a "service-integrated digital Transmission system "known, subscriber facilities are supplied with mains power, if they fail the over is carried out with a reduced bit rate. This will only the energy-saving components for the narrowband signal operated. The narrowband data are in emergency mode directly to the transmitter and from this to the transmission given management. So the texture of the narrow tape data have a direct influence on the lower limit frequency for which a receiving device must be designed. This can lead to either emergency operation additional recipients are required, or that the before existing recipient must be more complex.

The object of the invention is a circuit order to specify what is possible with a width tape transmission route an emergency operation with reduced Maintain bandwidth, with the lower Grenzfre sequence of the recipient is of the same order of magnitude, like the clock frequency intended for narrowband operation.

Features are provided for solving this task, such as they are specified in claim 1. In the subclaims Chen are advantageous developments of the invention ben.

It is advantageously achieved that the reception devices are not designed for low limit frequencies must be, so that no changes in the circuits for emergency operation is required, and clock recovery is facilitated at the receiving location.

An embodiment of the invention is as follows explained in more detail with reference to drawings. It shows  

Fig. 1 is a block diagram of the transmit side of a path set up for emergency broadband transmission,

Fig. 2 shows the block diagram of the receiving side of a broadband transmission line set up for emergency operation.

In Fig. 1 it is shown that a transmission multiplexer SMUX and clock divider TT TT 1 and 2 are provided for the transmission of a wideband channel BBK. These devices are controlled by a clock T 1 , which is designated 139 MHz (more precisely: 139.264). This clock T 1 could, for example, be generated by a clock generator TG 1 in FIG. 2. This clock generator TG 1 as well as the connected clock divider TT 1 and TT 2 and also the transmit multiplexer SMUX belong to the assemblies that have a very high power consumption and are no longer supplied with power in an emergency.

In the event of an emergency, two switchover multiplexers UMUX 1 and UMUX 2 are provided on the transmission side, which are activated by an emergency operating signal NB which is generated when the power supply fails .

In normal operation, 4 H12 channels of 2.048 MB / s each are transmitted in a narrowband multiplex as well as a basic multiplex channel BMK with a speed of 512 kBits / s. For this, the broadband channel BBK comes with a speed of 139.264 Mbit / s, which is added in the transmission multiplexer SMUX to be given along with the narrow-band data on the transmission line UL. A plurality of shift registers SR are provided for multiplexing the narrowband data and are shown in a block in FIG. 1. The data from the individual channels H 12/1 to H 12/4 are taken over serially in normal operation with a 2 MHz clock (exact value 2.048 MHz) and output in 4-bit fashion in parallel to a parallel-serial converter PSW . The parallel-to-serial converter PSW thus receives a total of 16 bits in parallel, which originate from said H 12 channels. A 17th input is provided in the parallel-to-serial converter PSW , to which a basic multiplex channel BMK is connected. Thus, a total of 17 bits are converted in parallel-serial and sent to the transmission multiplexer SMUX at a speed of 8.7 Mbit / s (exact value 8.704). At the send multiplexer SMUX there is also a synchronization signal SY of 8 kHz, which is also inserted into the data stream and reaches the transmission line ÜL .

In normal operating mode, that is to say when the emergency operating signal NB is not present, the switching multiplexers UMUX 1 and UMUX 2 are switched so that input B is effective in each case. Thus, the control clock reduced to 8.704 MHz by the clock divider TT 1 reaches the parallel-serial converter PSW which is generated from 139.264 MHz. The serial output from the parallel-to-serial converter PSW takes place with this clock pulse, so that a narrow-band data stream of 8.704 Mbit / s arrives at the transmission multiplexer SMUX . A further clock divider TT 3 is used to obtain a control clock of 512 kHz from the 8.704 MHz clock, with which the data originating from the shift registers SR and the one bit from the base multiplex channel BMK are transferred in parallel to the parallel-serial converter PSW .

The switching multiplexer UMUX 2 connected to the transmission line ÜL receives the data stream emitted by the transmission multiplexer SMUX including the broadband channel BBK at its input B in normal operation and transfers it to the transmission line ÜL . This transmission line UL leads to the receiving side shown in FIG. 2, so that FIGS . 1 and 2 show a complete direction of the transmission path.

The broadband data coming from the transmission line ÜL are received in a reception demultiplexer EDEMUX and passed on in such a way that the individual data channels can be tapped separately. The broadband channel BBK is picked up directly by the reception demultiplexer EDEMUX . The narrowband data go into a serial-parallel converter SPW and from there into several receive shift registers ESR ( not shown individually). The data belonging to the basic multiplex channel BMK are taken in the form of a bit directly at the serial-parallel converter SPW . The outputs of the shift register ESR offer channels H 12/1 to H 12/4 of the narrowband multiplex in normal operation. In normal operation, the clock generator TG 1 is in operation for the generation of 139.264 MHz, to which the clock dividers TT 4 and TT 5 are connected. The EDEMUX receive multiplexer is of course also in operation.

If an emergency occurs because the supply voltage at the sending point has failed, the last-mentioned modules TG 1 , TT 4 , TT 5 and EDEMUX are taken out of operation, as will be described later. The clock supply is then maintained by a further clock generator TG 2 , which generates 8.7 MHz (exact value 8.704).

In normal operation, the switching multiplexers UMUX 3 , UMUX 4 and UMUX 5 shown in FIG. 2 are active at their inputs B. The narrowband data received by the reception demultiplexer EDEMUX thus arrive at the input of the serial-parallel converter SPW via the switching multiplexer UMUX 3 . The switching multiplexer UMUX 4 responsible for the clock supply passes the clock received at its input B on to the serial-parallel converter SPW and to another clock divider TT 6 , at the output of which a frequency of 512 kHz appears.

Another switching multiplexer UMUX 5 is provided for switching the synchronization signal SY . In the case of normal operation, this signal SY is received by the reception demultiplexer EDEMUX and placed over the input B of the Umschaltmultiplexers UMUX 5 at the output thereof, whereby the clock divider TT 4, TT 5 and TT are brought 6 each in a defined position by the synchronization signal SY.

In the following, it is first described how the transmitting side ( FIG. 1) behaves in an emergency operation. By the appearance of the emergency operating signal NB , the switching multiplexers UMUX 1 and UMUX 2 are controlled on the transmission side so that only their respective input A is still active. The clock supply is directly from another clock generator, e.g. B. TG 2 in Fig. 2, taken over, the frequency of 8.704 MHz via input A of the switching multiplexer UMUX 1 directly to the sliding input of the parallel-serial converter PSW . The further switching multiplexer UMUX 2 connected to the transmission line ÜL receives the data stream emitted by the parallel-serial converter PSW directly at its input A and forwards it to the transmission line ÜL . This bypasses the route leading via the out-of-operation transmit multiplexer SMUX .

The Notbetriebssignal NB is also connected to the transmission-side shift register SR, and causes a voltage applied to the inputs of these shift register SR bit combination is loaded into this shift register SR. This bit combination appears in the same way at the respective outputs of the shift register SR and is adopted directly by the parallel-serial converter PSW . As already described, the BMK basic multiplex channel is adopted there as an additional 17th bit. The parallel loading of the parallel-serial converter PSW is done by a 512 kHz clock, which is output by a clock divider TT 3 . This clock is obtained by dividing the 8.704 MHz clock appearing on the first switching multiplexer UMUX 1 . The shift registers SR on the transmission side are therefore only loaded in parallel in emergency operation because the 2 MHz clock responsible for serial reception is no longer available. This means that data pending at the serial inputs cannot be sent for the data pending in the context of the 4 × H 12 narrowband multiplex in emergency operation.

For the transmission of the synchronization signal SY in emergency mode, a bit, for. B. the penultimate, selected, which is taken over by the relevant shift register SR . This bit then reaches the 8.704 M-Bit / s data stream via the parallel-serial converter PSW and is sent to the transmission line ÜL .

With the help of filters, not shown, the emergency operation is recognized on the receiving side by the fact that a significantly lower bit rate arrives on the transmission line ÜL . An emergency operating signal NB is then also formed on the receiving side in a manner not shown. With this emergency operating signal NB , the switching multiplexers UMUX 3 , UMUX 4 and UMUX 5 are switched so that only the respective input A is now effective.

In this case, the data stream arriving via the transmission line ÜL is directed past the receiving demultiplexer EDEMUX which is out of operation and reaches the input of the serial-parallel converter SPW directly via the switching multiplexer UMUX 3 . The outputs of the serial-parallel converter SPW are directly connected to the inputs of receive shift registers ESR . As a result, the information arriving in parallel, which contains no useful data in the event of an emergency, is received by the receive shift registers ESR , but is not output at the outputs H 12/1 to H 12/4 . A serial output of the narrow-band multiplex data cannot take place because the control clocks coming from the out-of-operation clock divider TT 5 are not available. However, the bit for the base multiplex channel BMK , which is picked up by a flip-flop FF , is tapped at the serial-parallel converter SPW . This flip-flop is clocked with a clock of 512 kHz, so that the base multiplex channel is available with a bit rate of 512 kbits / s.

In the event of an emergency, the clock supply is taken over by a clock generator TG 2 , which generates 8.704 MHz, the clock of which reaches the serial-parallel converter SPW via the switching multiplexer UMUX 4 and is divided down to 512 kHz by a clock divider TT 6 .

Another switchover multiplexer UMUX 5 ensures that, in the event of an emergency, the synchronization signal SY is no longer obtained from the receive demultiplexer EDEMUX but from the outputs of the serial-parallel converter SPW . As shown in FIG. 1, the penultimate bit of the channel available in normal operation for the transmission of the 4 × H 12 channels in narrow-band multiplex is used for the transmission of the synchronization signal SY . As can be seen from FIG. 1, the bit combination is selected at this point in such a way that it can be recognized on the reception side ( FIG. 2) with a simple AND operation UG . A synchronization signal SY is emitted by this logic gate UG whenever the penultimate and third-last bits are the same in the example shown. This synchronization signal SY then passes via input A of the switching multiplexer UMUX 5 to the clock dividers TT 4 , TT 5 and TT 6 , only the latter clock divider TT 6 being effective in the event of an emergency. In this way, the receiving side has adjusted itself to the emergency operating case and is able to receive a data stream with a reduced bit rate and to recognize the synchronization signal in a different way than in the normal operating state.

As has already been described, only the basic multiplex channel BMK with a bit rate of 512 kbit / s is available in the emergency area state.

However, essential parts of the total Circuit arrangement shared, so that the additional Effort for maintaining an emergency operation is very low.

Claims (3)

1.Circuit arrangement for maintaining an emergency operation in a broadband transmission link, in addition to a broadband data channel, in addition, several fast channels, primarily for non-linguistic data and standardized voice data and signaling channels, are exchanged between the transmitting and receiving station using a standardized transmission method, the for the highest frequencies required circuits in the event of a power supply failure Be put out of operation and the remaining circuits for a narrowband operation are powered by a local battery, characterized in that by an emergency generated in the event of a power failure signal (NB) a bit combination present at the transmission-side shift register (SR) in a parallel-serial converter (PSW) taken over and constantly transmitted in the data stream together with the base multiplex channel (BMK) , and that the receiving side recognizes from the resulting frequency that on the transmitting side of the emergency operation is set, whereupon an emergency operating signal (NB) is generated on the receiving side and an operation with the low bit rate begins, and that a synchronization signal (SY) is contained in the bit combination. 2. Circuit arrangement according to claim 1, characterized in that a special bit is provided for the transmission of the synchronization signal (SY) in the context of narrowband multiplex, which is compared on the receiving side by a simple link (UG) with a neighboring bit, and that if the two bits are identical, the synchronization signal (SY) is recognized. 3. Circuit arrangement according to claim 2, characterized in that a further Umschaltmulti plexer (UMUX 5 ) is provided on the reception side, which is caused by the emergency operating signal (NB) to switch the reception of the syn chronization channel (SY) so that this now is formed by the output signal of a link (UG) .