DE10101092A1 - Packet-oriented data transmission method provides additional redundancy for coded data segments of each data packet only as required - Google Patents

Abstract

The transmission method has the data packets (DP) to be transmitted divided into data segments (DS1,.Also included are Independent claims for the following: (a) a transmission unit for packet-oriented transmission of data; (b) a reception unit for packet-oriented transmission of data; (c) a communications terminal with a transmitter and receiver for packet-oriented transmission of data; (d) a communications network with transmitters and receivers for packet-oriented transmission of data

Description

The invention relates to a method for packet-oriented transmission of data from a transmitting unit to a receiving unit via a transmission medium with a data channel and a response channel with the following method steps:

• - Segmentation of a data packet to be transmitted into several Data segments,
• - Redundancy generation by coding the data segments with an error-detecting code and / or an error correction rendering code,
• - Transmission of the coded data segments from the transmitter unit to the receiving unit in several steps by incr mental sending of successive coded data segments over the data channel.

With the packet-oriented transmission of data it comes in general for various reasons about packet loss There are packet losses in packet-oriented fixed networks all caused by overload at network nodes. this happens for example as a result of a buffer overflow and queue Overflows in data packet brokers or routers. A router evaluates the addressing information contained in the data packets ons and determines the güns based on routing tables further path. Based on this information, ent decided what will continue to happen to the data packet.

With mobile transmission channels (e.g. packet switched modes at Global System for Mobile Communication GSM, General Pa cket Radio Service GPRS or Universal Mobile Telecommunica tion system UMTS), the transmitted data is based on atmospheric disturbances and multipath propagation strongly ge  disturbs. The multipath propagation creates a send out ter pulse multiple echoes. By overlaying several such signal components or multi-way components with jewei phase shift compared to direct propagation path leads to extinctions, the so-called quick Cause fading. These and other multi-way Signs of fading lead to swans, some of which are considerable of the reception field strength. In addition to frequency selective Disappearance also occurs with a temporal dispersion with the result that individual symbols of the transferred data over partially several symbol durations "ver lubricate "and bit errors in digital transmission data to step.

The most widely used transmission protocols at the moment at transport level (layer or layer 4 of the OSI reference models), namely the user datagram protocol UDP and that Transmission Control Protocol TCP is very critical such bit errors in received data packets.

TCP is a connection-oriented transport protocol that enables a logical full-duplex point-to-point connection light. It ensures that data is error-free and in the desired order via an underlying one IP network are transmitted. It extends the underlying IP (Internet Protocol) for functions for data backup and Call control.

As soon as a bit error within a packet by a wrong recognizing code is detected, the affected Pa ket discarded or erased (Erasure). In other words, packet loss also occurs. So called reliable transport protocols such as TCP use repeat mechanisms (Automatic Repeat Request procedure) to get lost or dropped packets safely to the emp to be able to transport catchers. Faulty or lost past data are requested again from the sender. This is  however, with a very significant increase in transmission Delay connected, but that of many applications cannot be tolerated (e.g. communication users fertilize).

This is why unreliable transport protocols such as B. UDP used. Compared to the much more common use TCP waives UDP error detection and correction. UDP therefore works faster and has one smaller header, which is why the ratio of the number of user data (in bits) to data packet length (in bits) is better. UDP is special It is suitable for applications that send short messages and can repeat this completely if necessary, or at An Applications that need to be done in real time (Voice or video transmission).

The entire error correction is therefore carried out within the An turn. This affects not only bit errors, but also the Total loss of data packets, since routers with high network load Discard UDP datagrams immediately. The application can be at spe zial applications, e.g. B. in real time, in the event of a mistake ler detection and error correction of further, special Higher layer protocols are supported, e.g. B. the RTP (Real-time Protocol). The basic principle of RTP is Use of Forward Error Control. This is through a he extended header, in which additional information is possible hen. These are e.g. B. the type of user data transmitted (Language, image data etc.) or the time of generation of the data, which makes the data easier in a certain cor in the correct order or after a certain order Time can be discarded.

Due to the necessity of repeating After completely straighten in case of errors requires the use of UDP in one However, the network also has larger bandwidths than TCP and he demands a more complex bandwidth management of the network operator.  

UDP alone does not cause an increase in transmissions Delay, but does not offer any Mechanisms to compensate for packet losses. That's why there is intensive efforts, procedures for forward error correction (Forward Error Correction, FEC) and packet-oriented transmission with unreliable transport protocols such as B. UDP to ver tie.

Ideally, the resulting procedures should follow the Adjust properties of the transmission channel to no more To need bandwidth than is absolutely necessary. That applies especially when transmitting via mobile channels, since there the resource bandwidth is particularly valuable, d. H. for the Subscriber is very expensive.

Conventionally, this adaptation of the error protection to the transmission channel is mainly realized through the use of hybrid ARQ methods. ARQ stands for Automatic Repeat Request and represents a method for data transmission in which a transmitting unit sends data and waits for the correct acknowledgment by the receiving unit. If necessary, the sending unit sends the data again. This process is repeated until the data has been transferred correctly. There are two main types of processes:

• - Stop-and-Wait-ARQ for character-oriented protocols, for those after each transmitted character on its acknowledgment is waiting
• - Continuous ARQ for bit-oriented protocols where the acknowledgment is regulated by a window mechanism, so that with the correct dimensioning of the window size can only be sent (e.g. with High Level Data Link Control HDLC, a bit-oriented synchronous control prototype coll on layer 2 of the OSI reference model).

The information to be transmitted is initially in the frame a channel coding with an error-detecting code co diert. A well-known representative of such error-detecting Co is CRC (Cyclic Redundancy Check). It is about to certain set of algorithms that consist of a bit pattern a control according to a certain mathematical rule form bit patterns (usually 16 or 32 bits long) and Add it to the user data. Then follows encoding with a very powerful error correction valid code, d. H. a lot of redundancy is added.

The transmission of the coded sequence over the disturbed Ka nal then takes place incrementally in several steps. First only part of the encoded data is transmitted. The receivers unit performs decoding based on what it has data and evaluated using error detection the codes as to whether the amount of data received is correct Reconstruction is sufficient or not.

If an error-free decoding is possible, the Sen communicated via a return channel (e.g. via a Acknowledgment or confirmation, also as ACK acknowledgment referred to) and the transmission of the next information pa kets is being prepared. On the other hand is an error-free decode not possible, the receiving unit requests via the Back channel additional redundancy (often referred to as NACK) and does another de after their arrival coding attempt, in which the receiving unit the already emp caught data with the newly added redundancy combi ned. Additional redundancy is requested until error-free decoding is possible. A detailed one A description of hybrid ARQ methods can be found in Lin, S./Costello, D .: "Error Control Coding: Fundamentals and Ap plications, "Prentice-Hall Inc., Englewood Cliffs, N.J., 1,983th  

The advantage of this procedure is that it is actually just that much redundancy is transferred as actually needed becomes. However, this known method in packet ver channels also have serious disadvantages.

So the return channel must guarantee a secure transmission ren, d. H. ARQ processes must also be used there men. This requires the implementation of complex proto koll stacks (e.g. timers). Depending on the number of Repetitions and the round trip delay (the time between the transmission of information by the transmission unit and the arrival of a reaction of the receiving unit there via the return channel) is especially important for mobile transmission scenarios very high delays can be expected. With multimedia applications such as B. Streaming video, it means that in Receiver must have a very large buffer. This also leads to increased complexity in the reception window minal.

The object of the present invention application is therefore in the transfer compared to the known state of the art Simplify technology and still adapt to the Achieve transmission channel.

According to the present invention, this object is achieved by the procedure described above according to the Oberbe gripped by being trained by the sender unit as long as coded data segments with additional redundancy in are sent incrementally until the sending unit either a message about the successful message via the reply channel error-free decoding of the data packet to be transmitted received by the receiving unit or until all redundancy of the coded data segments was transmitted.

According to a first advantageous embodiment of the method According to the invention, the coding is carried out in such a way that User data of a data packet to be transmitted in one another  following data segments of the same length are divided, the around the respective redundancy symbols of an error-correcting Codes are added to the respective code words, whereby the Co words are arranged for transmission such that each Codeword to transmit one column of all consecutively the encoded data segments.

It has proven to be advantageous if sol che coded data segments are transmitted, which exclude Lich contain user data of the data packet to be transmitted, before encoded data segments are transmitted, the Redun include dance information.

The principle on which the invention is based is as follows be briefly outlined. To be transferred in a plurality of present information packets or data packets Data packet for data packet are transmitted. Doing so first segment each data packet into individual data segments tated and also with an error-detecting and connecting with a powerful error correcting code co diert. Then the transmission also begins with the incrementally sending the encoded segmented data. so soon the receiving unit receives the information package or data pair ket error-free based on the data segments already received can decode, it sends this to the transmission unit via the Response channel in the form of an ACK confirmation or acknowledgment. If the sending unit receives the ACK message, it stops the current transmission and starts transmitting the next data packet. The ACK message goes on the reply channel is lost or there is no response channel, then the Sending unit continues the transmission until the entire Redundancy is sent and then begins transmission a new data packet.

In comparison to known hybrid ARQ methods, it can considerably reduces the complexity of a receiving unit become. However, it can lead to a total information  want to come if the error protection used is not sufficient appropriately high. However, this can largely ver be avoided if the error correcting code is appropriate the long-term characteristics of the transmission channel, in particular of the data channel, and the QoS parameters (Quality of Ser vie, QoS) of Bearer Services is selected.

To eliminate the possibility of a total loss of information close, therefore, after another advantageous off design of the method of the invention of error correction Code based on information from a long-term character Statistics of the data channel selected so that even with the poor test the assumed transmission quality of the data channel there is sufficient error protection.

This can be done, for example, with the help of the Real-time Control Pro tocol (RTCP), which is part of RTP evaluates the statistics about the current connection (miss rate, delay etc.) and thus a review of QoS possible (but not a high QoS itself).

A particularly advantageous embodiment of the invention sets a Reed-Solomon code as the error-correcting code on. Examples of such error correcting codes are above work by Lin, S./Costello, D.

According to the invention described above can be Achievement of the listed advantages also a transmission unit or create a receiving unit that has appropriate Means for performing the inventive method for packet-oriented transmission of data.

Such transmission units and Receiving units in communication terminals or communica use networks.  

The best results are achieved if for a com communication network Transmission channels with the lowest possible Round trip time are provided.

A key advantage is that unlike conventional ARQ procedures only require a single response (ACK) is and not several. This reply can also be sent via transmit a less complex reverse link or response channel be. For the answer channel is therefore not also an additional ARQ procedure is necessary.

Further details and advantages of the invention follow hand of an advantageous embodiment shown below Example and in connection with the figures. Are there Elements with the same functionality with the same reference characters marked. In principle it shows:

Fig. 1 a through a noisy transmission channel verbun dene transmitting and receiving unit,

Fig. 2 is a block diagram of a transmitter unit with the sen derseiten measures of the invention and

Fig. 3 is a block diagram of a receiving unit with the receiving side measures of the invention.

The principle of the invention will now be clarified using an exemplary embodiment. The illustration in Fig. 1 shows this, the scenario of a communication between a transmitting unit and a receiving unit 5 via an E gestör th transmission channel (indicated by a lightning-shaped arrow) to a data channel and a response channel DK AK. Since the response channel AK can be technically simpler than the data channel DK, which is indicated by the arrow DK which is thicker than AK.

Streaming multimedia is to be considered as an example Application over a mobile packet loss channel DK (i.e. wi  reless IP scenario). The QoS parameters of the "packet switched bearer service "are known from the max. packet erasu re / loss rate. The required error protection for the worst of all cases, d. H. a transmission at the Max. packet erasure / loss rate. So can error-free decoding DC can always be achieved.

First of all, the measures of the invention to be carried out on the part of the transmission unit S will be explained with reference to the basic illustration of a transmission unit S shown in FIG . The multimedia information D to be transmitted at specific intervals in the form of individual information packets is transmitted data packet DP for data packet DP. The data packet DP currently to be transmitted is addressed, for example, by a pointer P pointing to this data packet. For transmission, each selected data packet DP is first segmented 1 and coded 2 with an error-correcting systematic code designed for the worst case transmission 2.

In the present example, the information block or the Data packet DP with the user data N in the payload part of m successive transmission packets of the same length, in hereinafter referred to as data segments DS1 to DSm, distributed. With payload one generally refers to this ultimately User available and payable by him Data volume in data packets that are transmitted for a fee be.

The length of the payload part is assumed to be l symbols (e.g. bytes) given. In the payload part of the other data segments DSm + 1 bis DSn are the redundancy symbols R of the error-correcting Co of, in this case for example a Reed-Solomon (RS) Codes above Gabi's field GF (2 '\ 8) included. The Co dation in such a way that the entire transmission block (n data segments DS1 to DSn with payload length l) there are exactly 1 RS code words CW1 to CW1 of length n bytes.  

The i-th code word CW in the transmission block is thus composed from top to bottom in FIG. 2 of the i-th byte of the payload part of each data segment DS1 to DSn and is therefore systematic (1 = <i = <1).

The reason for this particular type of coding is as follows the: goes a data segment DS1 to DSn of the transmission block is lost, so in all 1 code words CW1 to CWl only a single symbol (here: 1 byte) on the same (be known) position deleted. By means of known "erasure Decoding algorithms can now use this symbol in any code word CW1 to CWl using the added redundancy R again be reconstructed separately, and thus ultimately the In halt of the entire transmission block DS1 to DSn or DP. Due to the special property of RS codes, which be known as "maximum-distance-separable" works this type of reconstruction as long as the number of lost NEN data segments less than or equal to the number of speeches Danzsegmente R or DSm + 1 to DSn (in this case n-m) is. This explanation may help to understand the following Ab runs are enough.

After redundancy R has been added by the coding 2 or C as described above, the data segments DS1 to DSn are transmitted 3 in accordance with their sequence via the data channel DK (from the view of the illustration in FIG. 2 "from top to bottom"). This advantageously takes place in such a way that first the data segments DS1 to DSm, which contain the useful data N, and only then such data segments DSm + 1 to DSn with redundancy R are transmitted. This can be done, for example, by means of a shift register SH into which a data segment is loaded and then sequentially output byte by byte via the data channel DK until all l bytes of a data segment have been output. Then the next data segment is loaded into the shift register and so on.

In this case, packets or data segments are lost in accordance with the statistical properties of the transmission channel DK. Since the mobile radio channel is time-variant, there are time sections in which the packet loss rate is significantly lower than that for the "worst case". Then the receiver unit E also shown in FIG. 3 as a schematic diagram does not need all data segments DS1 to DSn for an error-free reconstruction of the multimedia data of the data packet DP to be transmitted, but only a small proportion. The reception can also take place via a shift register SH, into which the arriving symbols are read sequentially and then output as a complete data segment for decoding 4 or DC.

In the present example with the RS coding 2 or C can the content of the information packets or data packets DP is full come reconstructed as soon as at least m data segments te of the n available data segments (no matter which) of the transfer blocks were successfully received.

In the following it is assumed that due to a mistake lerbursts (e.g. as a result of a fading hole on the mobile radio channel) the second and third data segments DS2 and DS3 lost, all other data segments, however, errors can be freely transferred. After receiving the first two speeches Danzsegmente DSm + 1 and DSm + 2 are on the receiver unit E. the minimum m data required for decoding 4 or DC segments before.

After successful decoding DC of the user data N of a da tenpakets DP now sends the receiver unit E over the Ant word channel AK an ACK message to the sending unit S. die due to the delay on channel AK (expressed by the so-called round trip time) on the sending unit 5, for example only arrives at the point in time at which this (n-x) - te data segment (with x <n-m) in the sequence of data segments ten (i.e. the (n-x-m) th redundancy packet). The  Transmission 3 is stopped immediately at this point, and with the sending of the next data packet DP or transmission blocks can be started by incrementing the pointer P is tiert and then the next data packet DP addressed with which is handled in the same way. The savings be in this case carries x full data segments.

In the event that n = 19 and m = 7 and the transmission unit 5 When the ACK receipt arrives, the 12th data segment transfers (i.e. the 5th redundancy segment), the savings are nis 8 data segments. So there is as little bandwidth as possible wasted, and the less the shorter the round- Trip time of the channels DK and AK is.

An adaptation of the error protection to the transmission channel DK with AK is therefore relatively easy even during transmission feasible (so-called adaptive error protection). Go the ACK If the message is lost, the x that are no longer required are also lost Redundancy segments sent. In this case, these will be when they reach the receiver unit E, discarded there. Then although more redundancy R is transmitted than required, all However, the terminal complexity is much lower than with the well-known hybrid ARQ processes, which is why parts compared to the known state of the art. There the ACK message is usually very small (a few Byte), can be at the level of the physical layer (layer 1 of the OSI Reference model) a very powerful error protection ver applied to the probability of a loss minimize.

Claims (10)

1. Method for packet-oriented transmission of data (D) from a transmitting unit (S) to a receiving unit (E) via a transmission medium with a data channel (DK) and a response channel (AK) with the following method steps:

• - Segmentation (1) of a data packet (DP) to be transmitted into several data segments (DS1... DSm),
• - Redundancy generation (R) by coding (2; C) the data segments (DS1... DSm) with an error-detecting code and / or an error-correcting code,
• - Transmission (3) of the coded data segments (DS1... DSn) from the transmitting unit (S) to the receiving unit (E) in several steps (n) by successive transmission of the coded data segments over the data channel (DK),

characterized in that
from the transmitter unit (S) as long as coded data segments (DS1... DSn) with additional redundancy (R) are sent until the transmitter unit (S) either via the response channel (AK) a message (ACK) about the successful error-free decoding (4; DC) of the data packet to be transmitted (DP) received by the receiving unit (E) or until all redundancy (R) of the coded data segments (DS1... DSn) has been transmitted. 2. Procedure for packet-oriented transmission of data after Claim 1 characterized in that the coding (2) takes place in such a way that to be transmitted User data (N) of a data packet (DP) in successive Data segments (DS1... DSm) of equal length (1) who are divided the one around the respective redundancy symbols (R) of an error correcting codes for respective code words (CW1... CW1) are supplemented, the code words (CW1... CWl) for the transfer be arranged in such a way that each code word (CW1... CWl) a column of all consecutive to be transmitted encoded data segments (DS1 ... DSn) forms.   3. Procedure for packet-oriented transmission of data after Claim 1 or 2, characterized in that first transmit such coded data segments (DS1 ... DSm) the only user data of the data to be transmitted ten packets before encoded data segments (DSm + 1.... DSn) are transmitted, which includes redundancy information (R) hold. 4. Procedure for packet-oriented transmission of data after Claim 1, 2 or 3, characterized in that the error correcting code based on information from one Long-term characteristic of the data channel (DK) is selected so that even with the worst transmission to be assumed quality of the data channel (DK) adequate error protection consists. 5. Procedure for packet-oriented transmission of data after one of the preceding claims, characterized in that a Reed-Solomon Code (RS) as the error-correcting code is set. 6. Sending unit (S) to carry out the procedure for pa chain-oriented transmission of data (D) according to one of the vo priority claims. 7. receiving unit (E) for performing the method for packet-oriented transmission of data (D) according to one of the preceding claims 1 to 5. 8. Communication terminal with a transmission unit (S) according to An saying 6 and / or a receiving unit (E) according to claim 7.   9. Communication network with at least one transmitter unit (S) according to claim 6 and a plurality of receiving units (E) according to claim 7. 10. Communication network according to claim 9, characterized in that Transmission channels (DK, AK) with the lowest possible round Trip time are provided.