DE4205623B4 - line terminal - Google Patents

Abstract

Line terminal for a useful signal, which may optionally be one of a plurality of signals of a digital signal hierarchy, characterized by a transmitting part with
a) at least one coder (3, 4) which is provided to code the useful signal (2a) with a code of prescribed redundancy,
b) at least one device (12, 13, 14, 15, 11) for providing at least one clock signal (13a, 14a, 15a),
c) at least one switching means (S1, S2, S3), which is provided, the useful signal (2a) or the redundantly coded useful signal (3a, 4a) together with associated clock signals (13a, 14a, 15a) the at least one coder (3 , 4) and a transmitting device (5, 6, 7), wherein
the at least one switching means (S1, S2, S3) is switched as a function of the hierarchy level of the useful signal (2a) in the digital signal hierarchy.

Description

The The invention relates to a line terminal for a useful signal, optionally one of several signals of a digital signal hierarchy.

Line terminals of said Be kind in digital transmission technology used to connect switches or via multiplexers bundled Establish digital signal connections. They match the digital signals to the properties of the transmission networks at. Depending on the multiplexing process, digital signals - here useful signals named - according to the CCITT hierarchy levels (CCITT recommendation G.702) of 2 Mbps, 8 Mbps and 34 Mbps for transmission e.g. B. on fiber optic cables modified in the appropriate line terminals.

Out DE 38 35 338 C2 Furthermore, a method for the transmission of additional signals in digital data transmission is known. In the described method, for example, four digital data signals of the same bit rate are transmitted via four data channels. The 4-bit code word resulting from in each case one bit of the four data channels is converted by means of a transcoder into a 5-bit code word and supplied to a parallel / serial converter to the output of which a serial multiplex signal is output. Control criteria supplied to the transcoder cause the transmission of an additional signal.

As z. B. an article (Lampe, G. and Ortinau R .: fiber optic transmission system for 34 Mbps between Nuremberg and Schwabach. TE KA DE TECH. MITT. 1982, pages 14 to 19), is in a line terminal a 34 Mbps payload from the HDB3 code into a binary code decoded, then scrambled, 5B / 6B coded and over an electro-optical converter as an optical line signal to disposal posed. Accordingly, for the bit rates of 2 or 8 Mbit / s proceeded. The disadvantage is that for each of the three bit rates three different line terminals must be developed.

Becomes about that addition, an additional channel transmission performed in such a way that at the usual applied 5B / 6B block coding inserting a bit of an extra channel into the output block (5B / 6B + 1B), such is the bitrate of this additional channel to the bit rate of the useful signal bound. This bond means that again three variants of Additional facilities available have to be asked. These additional features include, for. B. additional channel multiplexer, with which subchannels be combined to an additional channel with the prescribed total bit rate.

Of the Invention has for its object to provide a line terminal, that take over the function of all three variants of line terminals and, in the case of ancillary equipment, only a single embodiment instructed.

• a) mindestens einem Coder, der dafür vorgesehen ist, das Nutzsignal mit einem Code vorgeschriebener Redundanz zu codieren,
• b) Schaltmitteln, die dafür vorgesehen sind, das Nutzsignal oder das redundant codierte Nutzsignal zusammen mit zugehörigen Taktsignalen dem oder den Codern und einer Sendeeinrichtung zuzuführen.

This object is achieved by a line terminal of the type mentioned, which contains a transmitting part with

• a) at least one coder, which is intended to code the useful signal with a code of prescribed redundancy,
• b) switching means which are provided for supplying the useful signal or the redundantly coded useful signal together with associated clock signals to the coder and a transmitting device.

Should the line terminal according to the invention z. B. for useful signals the hierarchy level 2 or 8 or 34 Mbit / s are used, so the switching means are set and the redundancy is set, that yourself when applying one of these signals always an output signal with about same bit rate. This z. B. only one embodiment of Additional equipment required.

Around in the redundant coding and the associated shortening of the Bit width to reduce the risk of false sampling is provided the useful signal before its redundant coding by an elastic Memory (dejitterizer) of its phase noise largely to to free.

When Redundant code can also be an error-detectable or an error-correctable one Code to be used. The use of error-correctable codes balances the disadvantage of higher Noise bandwidth (due to transmission with higher Bitrate) by error correcting measures on the receiver side out again.

• a) mindestens einem Decoder, der dafür vorgesehen ist, im Falle eines redundanten Nutzsignales dieses in ein nichtredundantes Nutzsignal zu decodieren,
• b) Schaltmittel, die dafür vorgesehen sind, das Nutzsignal und die zugehörigen Taktsignale den Decodern zuzuführen.

A line terminal with a receiving part according to the invention contains

• a) at least one decoder, which is intended to decode this in the case of a redundant useful signal, this in a non-redundant useful signal,
• b) switching means which are provided to supply the useful signal and the associated clock signals to the decoders.

It is particularly advantageous that of the per se known transmitting and receiving devices for line terminals only one embodiment is required, and that is because of them to processing signals have approximately the same bit rate in all applications. For optical transmission, for example, only one optical transmitter and only one optical receiver need to be used. This shortens the manufacturing and test times for the devices. Finally, almost all components of the line terminal according to the invention can be implemented in integrated switching technology.

Based The figures will be described in more detail the invention become.

It demonstrate

1 the transmitting part of a line terminal with features of the invention and

2 a corresponding receiving part.

In the transmission part 1 is at a pinch 1a an HDB3 signal (payload) is applied, which has either a bit rate of 2, 8 or 34 Mbit / s. Which of these three signals is transmitted must be agreed prior to commissioning and according to this agreement positions of three switches S1, S2 and S3 must be set. An automatic detection of the bit rate and a corresponding setting of the switches S1, S2 and S3 is not provided in the embodiment, but without further possible.

Of the For simplicity, the following is for a line whose connections and for the signal that over transmit this line the same reference number is used.

The circuit after 1 is basically divided into two branches. In the first branch, the signal branch, consisting of building blocks 1 to 7 and the switch S3 is the at the terminal 1a applied useful signal prepared for a transmission. In the second branch, the clock branch, consisting of building blocks 8th to 19 and the switches S1 and S2, the necessary clocks are generated.

The signal change in the signal branch consists essentially in that the useful signal 1a by coder 3 and or 4 to a bitrate of the order of magnitude 34 Mbps is brought. By the coder 3 and 4 is the bitrate of the payload 1a each increased by a factor of 4. According to this bitrate increase, the frequencies of the clocks for the 2 and 8 Mbit / s signals in the clock branch are increased.

In the signal branch is the useful signal 1a through a HDB3 decoder 1 converted to a binary code. The binary coded useful signal in this way 1b then passes through an elastic memory (dejitterizer) 2 which largely frees it from jitter. It is known to those skilled in the art that four cycles are required for this purpose. A bit clock and a clock (word clock) with 6 times the period, both of which are so strongly affected by phase noise, as the useful signal itself. These input clocks are the dejitterizer 2 on lines 9a and 10a fed. Two more bars, which differ from the first two only by a lower phase noise, become the dejitterizer 2 via lines 11a and 14a fed. On a wire 2a is then the phase noise almost freed (binary coded) useful signal. The reduction of the phase noise is necessary for greater safety, because otherwise bit errors could occur in the subsequent increase of the bit rate.

The useful signal 2a first goes through a convolutional encoder 3 , whose output signal compared to its input signal has a four times higher bit rate. The necessary bars are given to the convolutional encoder 3 - Depending on the position of the switches S1 and S2 - via lines 13a or 15a as well as over 13a or 14a ,

On the convolutional encoder 3 follows an oversampling unit 4 ; also through this unit 4 the bit rate is again increased by a factor of four.

About a 3-way switch S3 is the useful signal 2a or one of the redundant useful signals 3a or 4a to a scrambler 5 passed, the pseudo-randomly swapped the bits of its input signal. This allows the reception-side synchronization of a 5B / 6B decoder.

Through a converter 6 are each five bits of the output signal 5a of the scrambler 5 coded in 6-bit words and added one bit of a supplemental channel (5B / 6B + 1B coding). The required clocks receives the 5B / 7B converter 6 via lines 13a . 16a . 18a and 19a , The output signal 6a of the converter 6 eventually becomes an electro-optical converter 7 supplied, the output signal is transmitted via a glass fiber cable to a receiver.

In the clock branch passes through the useful signal 1a first a nonlinear member 8th to the frequency spectrum of the useful signal 1a so that it is useful for the recovery of the Bittaktes. The useful signal 1a itself has no spectral component at the frequency of the bit clock. Through a phase locked loop 9 this component is the output of the limb 8th filtered out and as a recovered Bittakt on the line 9a given. Because of the special requirements for the dejitterizer 2 must the Bittakt in the ratio 1: 6 by a divisor 10 be divided down. For the Namely, phase noise reduction becomes six bits of the signal 1b into a shift register of the dejitterizer 2 pushed and then with a beat 10a transferred in parallel to a buffer.

With the phase locked loop 12 . 13 . 14 . 15 . 11 , S1, S2 are clocks that are almost freed from any existing phase noise and the conversion of the useful signal are used in a redundantly coded signal. The phase-locked loop consists of a mixer with a downstream low-pass filter 12 , a crystal-tipped oscillator 13 and a divider chain 11 . 14 . 15 , their dividers 14 and 15 can be activated or deactivated by the switches S1 and S2. The single dividers 14 and 15 each have the division ratio 1: 4 and the divider 11 has the division ratio 1: 6.

Has the useful signal 1a a bit rate of 2.048 Mbit / s, the switches S1 and S2 must be set so that at the output of the oscillator 13 the 16-fold bit clock frequency, namely a clock with 32.768 MHz occurs. If the payload has a bit rate of 8.448 Mbps, the switches are set to give a 33.792 MHz clock. In the case of a useful signal with 34.368 Mbit / s, a clock with 34.368 MHz should result, so one with the bit clock frequency of the desired signal 1a , The dividers 14 and 15 are then ineffective.

Through a second phase-locked loop 16 to 19 becomes the 5B / 7B coder 6 and the electro-optical converter 7 supplied with clocks. The frequency of bit clocks for the input and output of the 5B / 78 encoder 6 behave like 5: 7. Therefore, the clock becomes 13a through a 1: 5 divider 16 divided and one bar 18a an oscillator 18 in the ratio 1: 7 by a divider 19 divided down before both beats a mixer 17 be supplied with downstream low-pass filter.

In the reception part after 2 a line terminal, all changes that has experienced the useful signal in the transmitting part, reversed again. Also the reception part after 2 is divided into a signal branch and a clock branch.

In the signal branch passes through the optical useful signal 1a first an opto-electrical converter 1 , then a 5B / 7B decoder 2 , a descrambler 3 and finally - depending on the position of two switches S1 and S2 - a majority decision maker 4 and a convolutional decoder 5 or just the decoder 5 or none of the building blocks 4 and 5 , The position of the switches S1 and S2 is set prior to commissioning of the transmission system. In the 5B / 7B decoder 2 are means of synchronization and means for blanking bits 2 B an additional channel included.

The last step in the signal branch is an HDB3 coder 6 go through, which converts the binary signal into a HDB3 signal.

Parallel to the conversion of the useful signal in the signal branch in the clock branch the necessary clocks are generated for it. Through a phase locked loop 8th with an upstream nonlinear member (in the module 8th included) becomes the bit clock of the wanted signal 1a recovered.

The recovered bittakt is through the 1: 7 divider 9 and divided down another phase locked loop in the ratio 5: 7. The further phase-locked loop consists of a quartz-equipped oscillator 12 , a mixer with filter 10 and a 1: 5 divider 11 in the feedback loop. At the output of the oscillator is a clock with the clock frequency 34.368 MHz or 33.792 MHz or 32.768 MHz, depending on whether the useful signal 1a originated from a signal at 32 or 8 or 2 Mbit / s in the transmission direction. Depending on these three cases, the switches S3 and S4 are also set, their input or output signals as clocks for the decoder 4 . 5 and 6 serve.

The possible switch positions are symbolized by letters x, y and z. The x position must be selected if the original signal was a 2 Mbit / s signal. The y position must be selected for an 8 Mbps signal and the z position for a 34 Mbps signal. The same applies to the switch in 1 ,

In 1 and in 2 All switches are set so that an 8-Mbit / s signal is processed according to the invention.

Claims (5)

Line terminal for a useful signal, which may optionally be one of a plurality of signals of a digital signal hierarchy, characterized by a transmitting part with a) at least one coder ( 3 . 4 ), which is intended to receive the useful signal ( 2a ) with a code of prescribed redundancy, b) at least one device ( 12 . 13 . 14 . 15 . 11 ) for providing at least one clock signal ( 13a . 14a . 15a ), c) at least one switching means (S1, S2, S3), which is provided to the useful signal ( 2a ) or the redundantly coded useful signal ( 3a . 4a ) together with associated clock signals ( 13a . 14a . 15a ) the at least one coder ( 3 . 4 ) and a transmitting device ( 5 . 6 . 7 ), wherein the at least one switching means (S1, S2, S3) in Ab dependence of the hierarchy level of the useful signal ( 2a ) is switched in the digital signal hierarchy. Terminal according to claim 1, characterized in that an elastic memory ( 2 ) is provided for the phase noise of the useful signal ( 1a ) before its redundant coding. Line terminal according to one of the preceding claims, characterized by a scrambler ( 5 ), which is intended to receive the useful signal ( 2a ) or the redundantly coded useful signal ( 3a . 4a ) to scramble. line terminal according to one of the preceding claims, characterized that it is at least with a redundant code around an error-detectable one or an error-correctable code. Line terminal according to claim 1, characterized by a receiving section with a) at least one decoder ( 4 . 5 ; 2 ), which is provided in the case of a redundant useful signal ( 2a ; 2 ) this into a non-redundant useful signal ( 5a ; 2 ) to decode b) switching means (S1, S2, S3, S4; 2 ) which are intended to receive the useful signal ( 2a ; 2 ) and the associated clock signals ( 12a . 13a . 14a ; 2 ) the decoders ( 4 . 5 . 6 ; 2 ).