DE3937737C2 - Connection circuit to the network of a digital message transmission system with multiple access in time division multiplex - Google Patents

Description

The invention is based on a connection circuit to connect Subscriber terminals with the network of a digital Multiple access messaging system in Time division multiplex according to the preamble of claim 1.

Such a connection circuit for a Time division multiple access system, also TDMA system is from "Frequency" 25 (1971) Issue 10, pages 316 to 321 known. The connection circuit described is part of a telecommunications satellite system and is located himself in an earth station that is a group of Participants. At the described Despite its modular structure, the earth station is (see 3.1.2) only, in contrast to using a Real-time encoder, an indication of the use of small buffers with two halves of the same size specified. Half is for the sending side and the other half for the reception side.  

A more precise representation of such buffers is in "Frequency" 25 (1971) Issue 11, pages 324 to 328 specified, the storage concept shown there only provides a fixed storage capacity that is guaranteed by several buffers is realized. Everyone is there Buffer has its own clock supply and Level conversion assigned.

The disadvantage of this connection circuit is that that the storage capacity is always as large as possible Is designed, even if because of a only a small number of subscriber terminals the maximum storage capacity would be necessary.

The invention is based on the object, a To create inexpensive connection circuit.

The task is by the features specified in claim 1 solved.

Advantageous embodiments of the invention are the other claims.

A particular advantage of the invention is that not ready for operation Memory allocated to subscriber terminals by means of a Control and monitoring device during the Shutdown can be disconnected and thus the Energy consumption is reduced. Another advantage is that terminals are a group of terminals added, or that terminals from the group of Terminals can be removed without the The other end devices in the group are ready for operation is affected.

An embodiment is described below with reference to FIGS. 1 to 3. Show it:

Fig. 1 is a block diagram of the interface circuit,

Fig. 2 shows the frame structure of the TDMA system,

Fig. 3 is a block diagram of a digital optical transmission system with the connection circuit according to the invention on the subscriber side.

In Fig. 1 an embodiment of a connection circuit 1 according to the invention is shown as a block diagram. FIG. 1 is divided into three lines. In the upper line, a control and monitoring device 2 is shown, which is connected to a burst circuit 3 . In the middle line, an intermediate memory 4 is shown, which is made up of two individual partial memories 5 and 6 and three coupled partial memories 7-9 . In the third line there are the adaptation circuits 10-13 , 15 , 16 , 18 with different interfaces for the intended subscriber terminals, not shown. The matching circuits 10-13 are connected via a first basic bus 14 to the partial memory 5, the matching circuits 15 and 16 are connected via a second basic bus 17 to the partial memory 6 and the matching circuit 18 is connected via a third basic bus 18 with the sub-memories 7-9. The partial memories 5-9 are connected to the burst circuit 3 via a TDMA bus 20 .

The input and output of the connection circuit 1 in the direction of the transmission center 22 takes place via the control and monitoring device 2 , which is coupled to the burst circuit 3 . In the case of incoming data bundles, the burst is divided into the group of subscriber terminals in burst circuit 3 .

In FIG. 2, the frame is ready for transmission in downlink and uplink direction. On the left is the subframe for the downlink transmission and on the right is the subframe for the uplink transmission. The subframe for the transmission in the downward direction is subdivided into a preceding preamble P and into the data bundle ONT which can be addressed to individual groups of subscribers and which are provided for the actual message transmission.

There are several data bundles, e.g. B. ONT 0 to ONT 15 are provided. To simplify matters, we will only speak of the ONT data bundle below. The preamble P, which only receives data on the system organization, is permanently assigned a data bundle ONT to each group of participants in the system. The connection circuits 1 identify the data bundle ONT intended for them on the basis of the information from the preamble P. All connection circuits 1 are thus equal and it is therefore not necessary that a special connection circuit works as a reference circuit.

The control and monitoring device 2 evaluates the information from the preamble P and forwards it to the corresponding functional units.

The preamble contains a synchronization part Sync, a start part start, a monitoring part CRC and a control part O & M. Contain the data bundle ONT also a monitoring part CRCO and one Data part data.

The synchronization part Sync synchronizes the clock of the control and monitoring devices 2 of the individual connection circuits 1 to the clock specified by the transmission center. The clock is passed on via the TMDA bus 20 to the partial memories 5-9 of the intermediate memory 4 and from there via the base buses 14 , 17 , 19 to the adaptation circuits 10-18 , as a result of which all the above-mentioned units are synchronized to the same clock.

The meaning of the start part will be discussed later in the Connection with the signal transmission in Upward direction explained in more detail.

The monitoring part CRC (cyclic redundancy check) is used for the detection of errors and is Fault localization information.

Via the control part O & M (operating and maintenance) control signals to the connection circuits 1 , z. B. with respect to the start of the transmission of messages in the upward direction.

The monitoring part CRCO monitors the on the subscriber terminals directed data.  

The individual data bundles ONT are sent without a gap from the transmission center 22 to the groups of subscriber terminals after the common preamble P. The number of data bundles ONT corresponds to the number of groups of participants, the length of the individual data bundles ONT depends on the number and type of subscriber terminals of the individual groups. It is limited by the overall length of the frame.

During the transmission in the downward direction, the data of the preamble P are supplied to the control and monitoring device 2 present in each group of subscribers. With regard to the starting part, each connection circuit 1 is informed via the control channel O & M which data bundle ONT contains the information intended for it. The data Dat of the corresponding data bundle ONT are now offered to each partial memory 5-9 via the TDMA bus 20 . At the same time, each partial memory 5 to 9 receives a synchronization signal from the control and monitoring device 2 via the TDMA bus 20 and, in relation to the start part Start, the time of the start of the readiness for storage and, in connection with the control part O & M, the duration of the readiness for storage. In this way, each partial memory stores the data Dat which are intended for the subscriber terminals assigned to it.

The data are read out in the downward direction in a predetermined sequence, with each adaptation circuit 10-13 ; 15 , 16 ; 18 the entire data Dat of the corresponding partial memory 5 ; 6 ; 7-9 concerns. At the same time, each matching circuit receives 10-13 ; 15 , 16 ; 18 via the corresponding base bus 14 ; 17 ; 19 , and the TDMA bus 20 from the control and monitoring device 2, the synchronization signal and, in relation to the start part Start, the time of the start of the transmission readiness and in connection with the control part O & M the duration of the transmission readiness communicated, whereby the data to the desired subscriber terminal are forwarded.

In the upward direction, data to be sent (Dat) are first transmitted from the subscriber terminals to the matching circuit 10-13 ; 15 , 16 ; 18 transmitted, provided with an address and to the corresponding partial memory 5 ; 6 ; 7-9 forwarded. The data Dat are temporarily stored there. Each partial memory forwards the data Dat from the individual subscriber terminal devices to the burst circuit 3 in a predetermined sequence. There, the data Dat are provided with a preamble P and transmitted in the upward direction.

The subframe for the transmission in the upward direction is shown in Fig. 2, right half of the picture. It is made up of nothing but individual data bursts ONT that come from individual groups of participants.

Protection times are provided between the individual data bursts ONT, which prevent the individual data bursts ONT from overlapping. The time at which the data bursts ONT of the individual groups are transmitted, such as the maximum permissible length of the data bursts ONT, is the burst circuit of each individual group by the start part Start and by the control part O & M of the previous downward transmitted preamble P via the control and monitoring device 2 communicated. The preamble P of the data bursts ONT in the upward direction is composed like the preamble P of the data bursts in the downward direction and contains the corresponding information. The only difference is that the preamble in downward transmitted data bundles contains information from the transmission center to the connection circuit of the individual groups of subscribers and the preamble of the data bursts in the upward direction contains information from the individual groups of subscribers to the transmission center.

So z. B. the start part start of an upward transmitted data burst ONT can be used to determine the position of the data burst ONT in relation to the frame and, if necessary, a changed start time from the transmission center via the control part O & M of the next downward preamble to the control and monitoring device 2 of the corresponding Connection circuit 1 can be communicated.

Furthermore, newly added or dropped subscriber terminals can be communicated to the transmission center via the control channel O & M of an upward data burst ONT in a group of subscribers. This can then z. B. reduce the data burst ONT for the corresponding group of participants and assign the gained time range to another group of participants. A corresponding change would be noted for the relevant connection circuit 1 via the control channel O & M of the downward transmitted data bursts ONT. The assignment of the preambles P is a process which is fundamentally known to the person skilled in the art and is therefore not explained further. It should now be pointed out that especially the second application example of preamble information represents an advantageous integration of the preamble in the design of the transmission systems with flexibly designed connection circuits.

To ensure this, the connection circuit 1 is not only provided with the control and monitoring device 2 for monitoring the data transmission, but it is this addition via the base bus 14 , 17 , 19 and when adding or removing existing partial memory including the associated connection circuits communicated the TDMA bus 26 to the control and monitoring device 2 . This information is then forwarded to the transmission center 22 via the preamble.

The frame according to FIG. 2 shows a special multiplexing method, in which the message transmission is carried out on a carrier, whereby transmission is carried out alternately only in the up or down direction. The transmission in the downward direction takes place as TDM (time division multiplex) transmission and the transmission in the upward direction as TDMA (time division multiple access) transmission.

However, the use of the connection circuit 1 according to the invention is not restricted to the use of the above-mentioned frame.

The partial stores are to go up and down To be able to separate directed data, in the simplest case divided into two parts, which alternate periodically be read in and out. More complex dynamic Memories allow multiple assignments of individual Memory locations during a transmission cycle whose Use a smaller storage capacity makes.  

The partial memories 5 , 6 , 7-9 are each constructed identically; they are each assigned a clock circuit and a partial control function which, for. B. the correct writing and reading of the two parts of a partial memory 5 ; 6 , 7-9 causes, or the removal of a matching circuit 10-13 , 15 , 16 , 19 forwards to the control and monitoring unit 2 .

The adaptation circuits 10-13 , 15 , 16 , 18 convert a digital message signal present at all base buses 14 , 17 , 19 with a transmission rate of z. B. 2 Mbit / s in a signal adapted to the respective subscriber terminals. A change in the transmission rate and, if necessary, a digital-to-analog conversion can be regarded as an adaptation. The adjustment takes place accordingly in the upward direction. For this purpose, the adaptation circuits have the necessary units known to the person skilled in the art, such as clock circuit, buffer memory and, if appropriate, a serial-parallel converter if the base bus 14 , 17 , 19 is designed as a parallel bus.

As subscriber terminals z. B. Devices with 2 Mbit / s, 256 kbit / s, or 64 kbit / s connections are provided. As a representative of a device with a 2 Mbit / s connection is a digital private branch exchange, as a representative of a 256 kbit / s connection is a computer and as a representative for a 64 kbit / s connection is an analog telephone set. In relation to the exemplary embodiment, the adaptation circuits 10-13 and 16 are provided for analog telephone sets, the adaptation circuits 10 to 13 being connected only to a partial memory 5 via the base bus 14 . The adaptation circuit 15 is provided for a computer. The adaptation circuits 15 and 16 are connected to the partial memory 6 via the base bus 17 . The matching circuit 18 is provided for a digital PBX, here the matching circuit 18 is connected via the basic bus 19 simultaneously with three sub-memories 7-9.

The size of a partial memory 5 , 6 , 7-9 depends on the average need for memory capacity based on the transmission rates of the subscriber terminals. It is advantageous to design the partial memory 5 , 6 , 7-9 so that they can be used for several telephone connections , but for a 2 Mbit / s connection of a digital private branch exchange several partial memories 7-9 are necessary. The optimal size of a partial memory 5 , 6 , 7-9 will also depend on the distribution of end devices with different transmission rates. It can also be advantageous to use partial memories with different storage capacities.

It is envisaged to apply the partial memories 5 , 6 , 7-9 and the adaptation circuits 10-13 , 15 , 16 , 18 to plug-in cards which make the addition or removal of a partial memory or an adaptation circuit technically simple.

256 kBit / s are provided in the base bus 14 , 17 , 19 and 20 12 Mbit / s in the TDMA bus 20 . Other transmission rates can also be selected. The nominal transmission rate between a connection circuit 1 and the transmission center 22 is 12 Mbit / s. This means that due to the above-mentioned periodically alternating data flow in the downward and upward direction and the necessary protection times, the actual transmission rate is higher. In the specified frame, the preamble P contains 64 bits in each direction, 23 bits being allocated to the synchronization part Sync, 1 bit to the start part Start, 4 bits to the control part CRC and 36 bits to the control part O & M. 12288 bits are provided for the data part and the monitoring part CRCO of a data bundle in the downward direction comprises 64 bits.

At z. B. 16 groups of participants result from this taking into account the protection periods between the Data bursts in the upward direction have a total number of bits 30720 bits. With a total frame length of 1 ms means this is an effective transfer rate of 30.72 Mbit / s.

A first possibility of arranging the connection circuit 1 in a digital optical bidirectional message system 21 is shown in FIG. 3. FIG. 3 shows a transmission center 22 with optical connectors 23 in the direction of the groups of participants 24 and electrical connections 25 in the direction of the switching point 26. Since the transmission center 22 is not the subject of the invention, its structure and mode of operation are not explained in detail.

Only an optical connection 23 with an optical transmission path 27 , which is connected to a front-end device in the form of a passive optical coupler 28 , is considered as representative. In turn, only one connection 29 in the direction of a group of subscribers 24 of the optical coupler 28 will be considered as a representative.

A group of subscribers 24 has an optical-to-electrical converter 30 in that the optical signal is converted into an electrical signal. Furthermore, the conversion of the signal into a binary code takes place in an encoder / decoder 31 , which is then fed to the connection circuit 1 . In the upward direction, the transmission path runs in the opposite order. The transmission center 22 requires a TDM / TDMA device on the optical connector 23 side.

Another possibility of arranging the connection circuit in a bidirectional digital message transmission system arises if adaptation circuits are not connected to subscriber terminals, but rather to connections of one or more switching centers or fixed connections (not shown). Here, the connection circuit 1 is used to adapt different outputs of exchanges 26 or fixed connections 33 , such as. B. Datex-P connections, to a transmission center 22 , with z. B. 2 Mbit / s connections. With this arrangement of the connection circuit 1 on the side of the electrical outputs 25, the transmission center requires a TDM / TDMA device.

It is also conceivable to use both of the above. Arrangement options a connection circuit together in one Arrange message transmission system.

The use of the connection circuit 1 is not limited to use in optical transmission systems, but can also be used in wired electrical communication systems or in radio or satellite systems.

Claims (8)

1. Connection circuit for connecting subscriber terminals to a network of a digital message transmission system that works with multiple access in time-division multiplex, the connection circuit having a buffer and adaptation circuits connected to the buffer for one or more subscriber terminals, characterized in that

• 1. that the intermediate memory ( 4 ) consists of several partial memories ( 5 , 6 , 7-9 ), which are each provided for the intermediate storage of downward and upward transmitted data, and the number of partial memories ( 5 , 6 , 7-9 ) can be changed is, whereby the total storage capacity can be adapted to the type and number of subscriber terminals,
• 2. that one or more sub-memories ( 5 , 6 , 7-9 ) are assigned one or more user-specific adaptation circuits ( 10-13 , 15 , 16 , 18 ),
• 3. that the connection circuit ( 1 ) has a control and monitoring device ( 2 ) which synchronizes the partial memories ( 4 , 5 , 6 , 7-9 ) and the adaptation circuits ( 10-13 , 15 , 16 , 18 ) that each partial memory ( 5 , 6 , 7-9 ) is ready to be written precisely when the matching circuit assigned to it is ready to receive in the upward direction and is ready to be read out precisely when the matching circuit associated with it is ready to send in the downward direction.

2. Connection circuit according to claim 1, characterized in that each partial memory ( 5 ; 6 , 7-9 ) has two areas, one for the data sent in the downward direction and one for the data sent in the upward direction. 3. Connection circuit according to claim 1, characterized in that a partial memory ( 5 ; 6 ) a plurality of matching circuits ( 10-13 ; 15 , 16 ) are assigned. 4. Connection circuit according to claim 3, characterized in that a partial memory ( 6 ) is assigned a plurality of different matching circuits ( 15 , 16 ). 5. Connection circuit according to claim 1, characterized in that a plurality of partial memories ( 7-9 ) is assigned an adaptation circuit ( 18 ). 6. connection circuit according to claim 1, characterized in that the control and monitoring device (2) is coupled to a burst circuit (3). 7. Connection circuit according to claim 6, characterized in that partial memory ( 5 , 6 , 7-9 ), which are not assigned to operating subscriber terminals, can be switched off by the control and monitoring device ( 2 ). 8. Connection circuit according to claim 1, characterized in that it is arranged between the switching center ( 26 ) and transmission center ( 22 ).