CH675646A5 - - Google Patents

Description

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The invention relates to a transmission device in accordance with CCITT recommendation 1.430 with a network termination unit and with a plurality of terminals which are connected by an S-bus. The invention further relates to a method for operating this transmission device.

The international CCITT recommendation 1.430 defines the physical properties of an ISDN subscriber / network interface (ISDN = integrated services digital network). With this interface, several end devices are connected to a network termination unit via an S-Bus. The S-Bus consists of a 4-wire line, with two wires forming a forward and a return line.

The network termination unit continuously sends a bit stream on the forwarding line, which is structured by a frame structure of 48 bits each. The end devices receive this bit stream from the forwarding line, synchronize themselves with regard to the bit and the frame clock and extract the data intended for them.

Each terminal continuously sends out a corresponding bit stream on the return line, the frame structure being delayed by a phase of 2 bits compared to the received frame. The bit streams and frames of all end devices overlap on the return line and are received by the network termination unit.

Due to the length of the S-Bus line and the spatial distribution of the end devices, the different transit times of the signals to the network termination unit play an important role in the superposition of the bit streams. These transit times cause phase differences between the different bit streams, which make reception by the network termination unit difficult or even impossible. The maximum tolerable phase difference thus limits the maximum length of the S-Bus line.

Based on this situation, it is the object of the invention to provide a method of how the described phase differences can be reduced and thus the length of the S-bus line can be increased.

The solution to this problem is characterized by the independent claims. The dependent claims provide embodiments of the invention.

The invention is described in more detail below with reference to five figures, for example. Show it:

Fig. 1 Schematic representation of a transmission device

Fig. 2 frame structure of a bit stream

Fig. 3 timing diagram with extension of the shift time T

Fig. 4 timing diagram with shortening the shift time T

Fig. 5 block diagram of a terminal

Fig. 1 shows schematically a transmission device, the described CCITT recommendation

Corresponds to 1,430. The transmission device comprises a single network termination unit NT and several, e.g. B. four terminals (terminal equipment) TE 1 to TE 4. These units or devices are connected by an S-Bus, which is composed of an outgoing line 11 and a return line 12. The maximum number of terminal devices TE is approximately eight devices. To avoid reflections, the S-Bus is terminated on both sides by resistors 13.

The network termination unit NT continuously sends a bit stream on the forward line 11, which is divided by a frame structure. This is shown in FIG. 2. The bits are transmitted in a three-value transmission code, in particular the AMI code. Every 48th bit violates the coding rules and serves as a frame detection bit F. It is immediately followed by a DC equalization bit L, which ensures that there is no direct current. The allocation or allocation of the remaining 46 bits of each frame is irrelevant for the rest and is therefore not further described here.

The terminals TE independently receive the above-mentioned bit stream via the forward line 11. They synchronize themselves with the bit clock BT and the frame clock RT and extract the data intended for them or the information intended for them from the content of the frames.

Each terminal TE continuously sends a bit stream to the return line 12 independently of the other terminal devices. With regard to the coding rules for the frame formation, this corresponds to the bit stream on the forward line 11 and comprises at least the frame detection bit F and the DC equalization bit L. However, its frame structure is delayed by a duration of 2 bits. This is shown in FIG. 2 with a delay of 2 bits in its lower part. This is shown in Fig. 2 in its lower part for a single terminal, for. B. TE 3.

In Fig. 1, the signal transit times for the respective route sections between the network termination unit NT and the terminal TE 1 or between the terminals TE with each other are indicated by lowercase letters a to d. Depending on the position of the devices and the conditions of the lines 11, 12, these transit times can be negligibly short or also have values that are comparable with the duration of a bit of the bit streams. The runtimes are approximately the same for the forward line 11 and the return line 12.

In order to compensate for the different signal transit times and their effect at the return line input 15 of the network termination unit NT, each terminal TE comprises an individually adjustable time shift unit. These units cause an individual time shift T in each terminal TE for the transmission of the frames and bits. The time shift T can preferably extend or shorten the time required for said delay by 2 bits.

3 shows a time diagram, the time being indicated by arrows and plotted in two opposite directions. In a first column, the local arrangement is the. Network 5

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terminal unit NT and the terminals TE 1 to TE 4 indicated. The assigned terms a, b, c, d are given in a second column. The third column indicates the times at which a signal, e.g. a frame recognition bit F, which is sent out by the network termination unit NT at time 0, arrives at the various terminals TE 1 to TE 4. The fourth column indicates the shift times T in the terminals TE 1 to TE 4 by which the transmission of the respective signal is delayed. The last column finally shows the times at which the various terminals TE 1 to TE 4 send the signal assigned to the received signal, additionally delayed by 2 bits, to the return line 12.

The shift times T each correspond to twice the total transit time from the respective terminal to that terminal (TE 4) which is the greatest distance from the network termination unit NT. As a result, all the signals on the return line 12 overlap in the phase in the direction toward the network termination unit NT, so that all signals reach the return line input 15 of the network termination unit NT together and in phase. This can detect the signals properly.

The signal components running on the return line 12 in the other direction do not disturb the described superimposition. Appropriate training of the bus termination prevents them from being reflected.

FIG. 4 shows a second time diagram which largely corresponds to that of FIG. 3. In the fourth column, however, the shift times T are given, by which the transmission of the respective signal is delayed less than the time of 2 bits. The times at which the various terminals TE 1 to TE 4 transmit the signal assigned to the received signal, less than 2 bits delayed, to the return line 12 are correspondingly indicated in the last column.

In this case, the shift times T each correspond to twice the total running time from the network termination unit NT to the respective terminal TE. The superimposed signals on the return line 12 arrive exactly delayed by the time of 2 bits at the return line input of the network termination unit NT.

5 shows the block diagram of a terminal TE. This is connected to the outgoing line 11 via its main entrance 21. The received signals are regenerated in an input amplifier 22 and fed in parallel to a clock and frame synchronization unit 24 and a buffer memory and logic unit 26. The latter (26) receives the necessary clock information from the former (24) unit via the connection 25, detects the address and / or data information of the received frames and passes the information intended for the respective terminal TE or the received data to a downstream data unit 28 from.

The bit clock BT and the frame clock RT are further fed to a delay unit 30, which causes the delay corresponding to the CCITT recommendation by 2 bits. This delay unit 30 is followed by a controllable time shift unit 32, the shift time T of which can be individually adjusted by a control unit 34.

A second data unit 36 generates data to be sent. These are buffered in a second buffer memory and logic unit 38, formatted and sent in a delayed bit and frame clock via an output amplifier 40 to the return line 12.

In addition to the above-mentioned receiving and transmitting units of the terminal TE, the latter has an input stage 42, which has one input connected to the return line 12 and the other input to the output amplifier 40. This input stage 42 emits a signal at its output 43 which is proportional to the respective signal on the return line 12 minus the signal portion emitted by the respective assigned output amplifier 40. A unit with this property can be designed, for example, in the manner of a circulator circuit, as used for. B. from N. Tietze, Ch. Schenk, semiconductor circuit technology, Springer Verlag, is known. The output 43 of the input stage 42 is connected to the control unit 34.

The input stage 42, the control unit 34 and the time shift unit 32 are used to set the aforementioned individual shift time T of the respective terminal TE.

The form and type of the signals at the output 43 of the input stage 42 of each terminal TE serves as a criterion for a correct setting of all delay times T corresponding to FIGS. 3 and 4. If the setting is correct, then these signals are properly correlated with the general bit clock BT.

The control unit 34 is designed such that it adjusts the correct or optimal shift time T from the signals described at the output 43 of the input stage 42 by means of an adaptive setting process. The adaptive setting process can take place while the respective terminal TE is in operation. In this case, all controls 34 or terminals TE continuously readjust and optimize their shift time T. The signals are basically phase or position signals which indicate whether the frame detection bits F and the DC compensation bits L, which delimit the frames, are in are in the correct phase or not.

In another embodiment, the setting process takes place during a relatively short switch-on phase. The shift times T determined here are then saved at the end of the setting process and then apply for the further operating period.

The transmission device described complies with the CCITT recommendation mentioned. Because of the additional, individually adjustable displacement times T, the S-bus or the outgoing line 11 and return line 12 can, however, be considerably longer than in the case of a device according to the pure recommendation. This enables an expanded spatial extension of the transmission device, which e.g. in a factory site can be critical.

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The version of the transmission device according to FIG. 3 works with positive shift times T, which extend the respective total delay time. This has advantages for the aforementioned adaptive setting process, which is built up from the terminal (TE 4) that is furthest away from the network termination unit NT. The time shift unit 32 is a delay unit in this case.

The version of the transmission device according to FIG. 4, on the other hand, works with negative shift times T, which shorten the respective total delay time. This has the advantage that the signals arrive at the return line input 15 of the network termination unit NT exactly shifted by 2 bits, ie at the theoretically correct point in time when the transit times are neglected. This allows the S-Bus to be divided into two or more arms, which has practical advantages. The time shift unit 32 is a time shortening unit in this case.

The circuit arrangement of a terminal TE according to FIG. 5 allows various variations. In particular, the delay unit 30 and the displacement unit 32 can be combined, e.g. to a shift register with variable, adjustable delay.

Claims (10)

Claims 1. Transmission device according to the CCITT recommendation 1.430 with a network termination unit (NT) and with a plurality of terminals (TE), which are connected by an S-bus, with on the outgoing line (11) and on the return line (12) of the S -Bus flows an uninterrupted bit stream structured by frames away from or towards the network termination unit (NT), the frames on the return line (12) being delayed by two bits in relation to those on the forward line (11), and the Bit stream on the return line (12) is fed by all end devices (TE), identified in each end device (TE) - By a time shift unit (32) which feeds into the return line (12) by the duration of the two bits of delayed frames or bits shifted by a respective shift time (T) assigned to the respective terminal (TE) into the return line (12 ) feeds - And by a control unit (34) which sets the respective shift time (T) of the time shift unit (32). 2. Transmission device according to claim 1, characterized in that the time shifting unit (32) is a delay unit which delays the frames or bits to be fed into the return line (12) in addition to the duration of the two bits by the shifting time (T) into the return line ( 12) feeds. 3. Transmission device according to claim 1, characterized in that the time shifting unit (32) is a time shortening unit which reduces the frames or bits to be fed into the return line (12) by the shifting time (T) to the duration of the two bits in the return line (12 ) feeds. 4. Transmission device according to claim 1, characterized in that - That in each terminal (TE) an input stage (42) is provided, which emits a position signal at its output (43), which corresponds to the respective position signal on the return line (12) at the location of the respective terminal (TE) minus the this terminal (TE) itself on the return line (12) transmitted position signal, - And that the control unit (34) is connected downstream of the input stage (42) and is designed to analyze the position signal present at the output (43) of the input stage (42). 5. Transmission device according to claim 4, characterized in that the position signal corresponds to the frame detection bit (F) and the direct current bit (L) of the frames. 6. Transmission device according to claim 4, characterized in that the input stage (42) is a circulator circuit, one input of which is connected to the return line (12) and the other input of which is connected to the output amplifier (40) of the terminal (TE). 7. The method for operating the transmission device according to claim 1, characterized in that in each terminal (TE) the control unit (34) sets the shift time (T) of the time shift unit (32) so that this time (T) is twice that Total running time of the bits of the bit stream from the respective terminal (TE) to the terminal (TE) whose distance from the network termination unit (NT) is greatest, and that this shift time (T) extends the time period for the 2-bit delay. 8. The method for operating the transmission device according to claim 1, characterized in that in each terminal (TE) the control unit (34) sets the shift time (T) of the time shift unit (32) so that this time (T) is twice that Total running time of the bits of the bit stream from the network termination unit (NT) to the respective terminal (TE), and that this shift time (T) reduces the time period for the 2-bit delay. 9. The method according to claim 7 or 8, characterized in that in each terminal (TE) the control unit (34) analyzes the signals at the output (43) of the input stage (42) and the respective shift time (T) changes adaptively until the correct shift time (T) has been reached. 10. The method according to claim 9, characterized in that the control unit (34) adaptively changes the shift time (T) during a switch-on phase of the transmission device and then stores the correct shift time and fixes the time shift unit (32) accordingly. 5 10th 15 20th 25th 30th 35 40 45 50 55 60 65 4th