DE19737897C2 - Data transmission system - Google Patents

Description

The invention relates to a data transmission system for digital transmission of data for which u. a. also language heard.

DE 33 37 648 C2 is a decentralized data transfer supply network with numerous distributed stations NEN known in which a direct data transfer only between neighboring stations. Through a spe Target routing is the transmission path from one Source station set to a target station and on then the data opens up in both directions different channels from station to station forwarded. The stations each send on a channel that is only used to connect exactly two Stations is used. However, here is an ent appropriately adjusted data rate necessary.

In this data transmission system, they are Stations with relay and switching functions out and synchronous transpa annuity connections according to the channel switching procedure between neighboring stations and between end stations any stations can be set up / dismantled. This is where the Data transmission in time-division multiplex operation, where number rich channels are combined into a frame. Also Here, the conversion from one broadcast channel to one Receive channel only after the on the Em incoming data packet completely received has been.

There is also a packet-wise data transmission between the stations of a data transmission network from the Internet known. Here, data on packages are ge  bundles and these packages are gün transmitted transmission separately. At a Such packet transmission is subject to significant delays conditions that are at least those for the transfer of a Package time required. For a phone system stem is such a packet transmission because of that associated delays unfavorable. Especially at a decentralized data transmission network, in which the Transmission from station to station, the delays would be according to the number of the stations involved in the transmission add up.

The invention has for its object a decent to create the digital data transmission system that the use of different transmission channels enabled between two stations and doing so keeps the delays extremely low.

This object is achieved with the invention the features specified in claim 1.

The data transmission system according to the invention draws is characterized in that the implementation in each station of the received signals from the receiving channels at least one of the different transmission channels sym done in batches. This means that everyone is on one Receive channel incoming symbol stream on the send channels is implemented. Here, so to speak Information packets formed from just one Symbol exist. In the simplest case, a symbol is a Bit. But it can also consist of a plurality of belonging bits exist, such as. B. a letter Symbol is represented by 8 bits. Within a  Subchannel is the number of during a transmission Bits per symbol position constant. At the beginning of the transfer depending on the required or desired degree of transmission quality the number of Bits per symbol set. The symbolic implementation means that there is only one delay at each station in the order of one symbol position of the Symbol stream is required. This delay depends along with that a synchronization of the symbol follow on the incoming and outgoing channels the channels are usually not present, so some waiting time is required before that starts outgoing signal in synchronization with the transmission channels can be sent. However, this delay is minimal. In practice, it is about one to two Symbols. The delay of each station add up. Because of the slight delay everyone Single station is the resulting total delay still acceptable on the transmission path.

According to a preferred embodiment of the invention the transmission channels are divided into subchannels, each of which is used to transmit a symbol stream is suitable, with the symbols of all subchannels one Transmission channel are transmitted synchronously. This means that each station receives incoming signals in all Can receive channels. The outgoing subchannels can in a single or a few selected channels be sent out in a concentrated manner. In every channel that consists of a predetermined number of subchannels, the symbol positions of all subchannels become time transmitted synchronously. Each subchannel is for one university directional data flow. The data arrives  the station in each subchannel of the entire channel system in a continuous data stream without a zerle in "frames" or "packages". Hence the data stream does not need any headers or others Organizational elements. Rather, every symbol of the data electricity after receiving it within a very short time implemented the subchannel selected for transmission and broadcast in synchronization with the broadcast channel.

Allocation of the subchannels to a transmission channel between two stations in such a way that the Transmission frequency range dynamic to be transmitted appropriate information content is adjusted. This means, that the number of subchannels per channel can vary.

The allocation for the transmission preferably takes place before seen channels at a station in such a way that all transmitting subchannels of this station within a few channels. Thus the number of to be used channels significantly reduced. This has to be taken into account realize that in the event that a station on a Channel sends, this channel from neighboring stations must not be used to avoid interference or others Avoid interference. If only in one channel if a subchannel is used by a station, the entire channel reserved for this station. Hence who which preferably all connections that have a be agreed to run station, distributed on subchannels that are all included in the same channel.

To reduce the probability of error of the data connection reduce, will be in a preferred embodiment form of the invention the content of the synchronous over  symbol positions of the subchannels of a channel Talking error correction bits added, where in the receiving station has an error correction. Known methods can be used as error correction methods are used, such as the FEC (Forward Error Correction) or the ARQ (Automatic Re-trans mission request). The peculiarity is in the present case in which the In keep the time-synchronously transmitted symbol positions of the Subchannels of a channel are used, whereby in the Subchannels completely independent information content flow. This means that the error correction is performed using bits that differ belong to information and are only coincidental lig at the simultaneous positions in the channel are located.

The use of an error correction method only makes sense if the value ^falls below a bit error rate of approximately 10 ^-3 . For higher bit error rates, mere error detection is sufficient to at least obtain information about the quality of the connection between the two stations involved. Such an error detection can be carried out by a redundant fuse attachment (e.g. parity bit), this attachment being added to the symbol locations of all subchannels of a channel that are transmitted synchronously. As an alternative to this or in addition, it is possible to generate an error detection bit for each subchannel after transmission of a predetermined number of symbol positions in a subchannel, which bit corresponds to the successive information contents of this subchannel, an error detection taking place in the receiving station.

The following is with reference to the drawings an embodiment of the invention explained in more detail.

Show it:

Supply system functions Fig. 1 is an illustration of a portion of the Datenübertra arranged distributed Sta,

Fig. 2 shows an example for a connection from a source station to a destination station,

Fig. 3 shows a switching matrix for the frequency conversion in each station,

Fig. 4 shows an example of data streams that pass through the coupling matrix of Fig. 3, and

Fig. 5 shows the temporally consecutive symbol locations in a channel with error correction bits and error detection bits.

The data transmission system consists of numerous distributed stations S, each station represents a subscriber position. Each station contains a transmitting and receiving device. For the radio operator The data are carried in two frequency bands each because 12.8 MHz is available. Both frequency bands are separated by a duplex spacing. The one frequency band is called the uplink and the other is called  Called downlink. For establishing a connection for the connection in one direction a channel in the Uplink and in the connection in the other direction a channel in the downlink is used so that both directions are completely decoupled in terms of frequency.

In this embodiment, the two are frequency bands of 12.8 MHz bandwidth each divided into a total of 1,280 channels with a spacing of 20 kHz. Of these channels, some channels are called informa tion channel for connection establishment and other purposes used. Each of the stations can be used on any of the channels and on each of the available channels Send channels.

Referring to FIG. 1, it is assumed that a connection rule Zvi a source station and a destination station S61 S65 is to be produced. This connection runs via the stations S60 and S63, which act as relay stations. In addition, a connection from a station S62 to a station S64 is also transmitted via station S60.

The example of an established connection shown in FIG. 2 provides that the information transfer from S61 takes place in channel C1, the information transfer from S60 to S63 in channel C25 and the information transfer from S63 to the target station S65 in channel C12. The station S60 that is particularly considered here also transmits in the channel C25 for the stations S61 and S64.

The routing, i.e. H. the choice of stations via which the connection should be made and the selection the channels take place through a dialogue, the carry out the stations involved among themselves. The Routing (the way finding) and the connection establishment are not the subject of the present invention.

In Fig. 3 a switching matrix KM is shown, which is included in each station. In this exemplary embodiment, for the sake of simplicity, each symbol position shown as a box is assumed to consist of one bit.

Each station contains a channel register CR-1 ... CR-n for each channel C1 ... Cn. The channel register CR-1 contains eight information symbol positions 1 ... 8 , each of these symbol positions corresponding to a subchannel SC. Channel C1 is thus divided into eight subchannels 1 ... 8 . Each subchannel has a bandwidth of 20 kHz, with the frequencies of all subchannels 1-8 immediately following one another. A unidirectional data connection can run via a subchannel SC.

In Fig. 3 of the channel are represented C1 the time pattern in which symbols are transmitted in the channel register 1 for the subchannels 4 and 5. The transmission takes place at the frequency of 20 kHz in an uninterrupted symbol stream.

The time-synchronously received symbols (here: bits) of the subchannels of a channel reach a receive register ER1 ... ERn and are transferred from there to the respective channel register CR-1 ... CR-n with a delay of two symbol times. The channel registers CR-1 ... CR-n are each connected to the columns of the coupling matrix. The coupling matrix contains n rows and m columns, each row and each column being assigned to a different subchannel or a different frequency. The lines of the coupling matrix KM each correspond to a subchannel or a transmission frequency. A channel register CR-1 ... CR-n is provided for each channel, which contains a symbol position for each subchannel 1 ... 8 . The symbols in all of the transmission-side channel registers are connected to the lines of the coupling matrix KM. A transmitter register SR1 ... SRn is assigned to each transmit-side channel register CR-1 ... CR-n.

The coupling matrix KM is in an integrated circuit technology nik trained, with appropriate control gnale the nodes at the junctions of a Row and a column can be switched. The node in question remains during a connection point switched through.

In the illustrated embodiment, it is assumed that the information that is on the sub-channel No. 1 received from channel C1 on subchannel No. 2 are to be retransmitted from channel 25 . At the intersection of the coupling matrix in question there is a through-connected node KP, so that this at position No. 1 of the receiving channel register CR- 1 in position No. 2 of the sending channel register CR-25 is transmitted for channel C25.

In the same way, those in subchannel No. 4 of the Ka Signals received as C2 on subchannel No. 6 of Channel C25 transmitted and transmitted in this channel.

In FIG. 4, an example of the time profile is given of signals le in the subchannels of the Kanae C1 C2 received, and C3. At the station in question, for example station S60 from FIGS. 1 and 2, the signals received there and intended for forwarding are implemented on channel C25. For the station S60 it was previously determined in dialog with the neighboring stations that channel C25 is available for data transmission.

As can now be seen in the selected exemplary embodiment from FIG. 2, station S60 receives from station S61 in channel C1 the data which it is to pass on to station S63. Accordingly, this data is converted to channel C25 in station S60. In station S63, the same data is converted to another channel, for example C12, and transmitted to target station S65.

The station S60 considered here receives in the selected one Example from station S62 signals in channel C2. This Signals are to be passed on to station S64. Channel C25 is also selected for this. Finally, signals from station S60 are also to be received the station S61 are transmitted, for which another Subchannel of channel C25 is selected. Everything that Station S60 transmits, takes place on channel C25, namely in different subchannels.  

In FIG. 4 the implementation of the data is shown in the station S60, received from the stations S61 and S62 in the channels C1 and C2. This data is converted to channel C25 in different subchannels. The time axis is designated t in each case. From the top line in Fig. 4 it can be seen that the symbol positions, which are transmitted in the channels C1, C2 and C3, are offset against each other, and at most up to the duration of a symbol bolstelle. Therefore, the data is held in the channel register CR-1 ... CR-n ( Fig. 3) until the symbol position in question has been received for all channels. This is followed by a conversion in the coupling matrix KM to the outgoing channels.

In addition to the symbol positions of subchannels 1 ... 8 , which transmit the information, three further bit positions for error correction bits A, B, C are added to each channel. The contents of these further bit positions are evaluated in the receive register ER1 ... ERn and used for error correction of the information bits that were received simultaneously within a channel. Only the corrected information bits are entered into the corresponding channel register CR-1 ... CR-n.

In the transmission registers SR1 ... SRn the eight information Mation symbols of a channel error detection bits A, B, C added before the entire bit set is sent. These error detection bits are corresponding to the In hold the information symbol locations after an error detection algorithm generated. In the same way he  the error correction follows after receipt of the overall signal using the algorithm.

In Fig. 5 for a channel, the individual symbols represent Darge represents with respect to their temporal profiles, the numbers 1 ... 8 denote the information Sym bolstellen and represent subchannels. These subchannels have different frequencies. The frequency f increases with increasing atomic number in Fig. 5 from left to right. The three error correction bit positions A, B, C are added to the last subchannel (channel "8").

In the embodiment shown in FIG. 5, a further symbol position P is added in the channel after a total of eight consecutive symbols, which also contains a parity bit for each subchannel that serves for error detection. The addition of the error detection bits and the error correction bits and the evaluation of these bits on the basis of the information content takes place separately for each transmission link. These additional bits do not participate in the frequency conversion.

Alternatively to the above embodiment, in which the assignment of subchannels to the frequencies the subchannels can be assigned to the frequencies be changed after each symbol step. So that will achieved that an interferer does not make a subchannel permanent can disturb.

Claims (5)

1. Data transmission system with distributed stations (S), each of which can carry out direct data traffic on selectable transmission channels only with neighboring stations, a symbol stream consisting of successive symbols being transmitted over the channel and with stations lying between a source station and a destination station have the function of relay stations, wherein in each station (S) the received signals are converted from the respective reception channel to a different transmission channel thereof, characterized in that the implementation of the symbol stream arriving on the reception channel takes place symbol-wise on the transmission channel. 2. Data transmission system according to claim 1, characterized characterized in that the individual receiving channels in front of received symbol positions the implementation on a broadcast channel as long as will hold until the relevant symbol position for all reception channels have been received. 3. Data transmission system according to claim 1 or 2, characterized in that the transmission channels are divided into subchannels (SC), each of which is suitable for the transmission of a symbol stream, and that the symbols of all subchannels (SC1 ... SC8) of a transmission channel transmitted synchronously  and in a station in parallel symbol by symbol from one or more reception channels to one or several transmission channels are transmitted. 4. Data transmission system according to claim 3, characterized characterized that the time synchronously transmitted Symbol positions of the subchannels (SC1 ... SC8) of a Ka nals according to the information content of this Symbol positions bits (A, B, C) are added, an error in the receiving station detection and / or error correction. 5. Data transmission system according to claim 3 or 4, characterized in that an error detection and / or error correction via a predefined one Number of symbol positions in each individual sub channel is done.