EP1849253A1

EP1849253A1 - Method for determining an optimal data transfer rate via a transfer medium

Info

Publication number: EP1849253A1
Application number: EP06701282A
Authority: EP
Inventors: Josef Forster
Original assignee: Nokia Siemens Networks GmbH and Co KG
Current assignee: Nokia Solutions and Networks GmbH and Co KG
Priority date: 2005-02-15
Filing date: 2006-01-24
Publication date: 2007-10-31
Also published as: WO2006087255A1; US20080183923A1; CN101120533B; CN101120533A; KR101296728B1; DE102005006890A1; KR20070103477A; DE102005006890B4

Abstract

According to the method, sequences (TS1, ..., TSn) that respectively comprise different data (DR1, ..., DRm) are transmitted via a transfer medium, the transfer quality being detected in accordance with said transmitted sequences (TS1, ..., TSn). According to the invention, the sequences to be transmitted (TS1, ..., TSn) are assigned to several chronologically sequential stages (stage 1, stage 2, stage 3), the sequences (TS1, ..., TSn) that are assigned to one stage (stage 1, stage 2, stage 3) having a predefinable interval (I11, ..., I34) in terms of the data transfer rate (DR1, ..., DRm). In said method, the following steps are executed cyclically: a) transmission of at least part of the sequences (TS1, ..., TSn) that are assigned to the first stage (stage 1, stage 2, stage 3) and selection of an interval (l11, ..., l34) that is situated between two transmitted sequences (TS1, ..., TSn), in accordance with the determined transfer quality; b) transmission of at least part of the sequences (TS1, ..., TSn) that lie in the selected interval (l13, l23) and that are assigned to the subsequent stage (stage 2, stage 3). The advantage of the invention is that an optimal data transfer rate (DR1, ..., DRm) can be accurately determined for the transmission of information via the transfer medium.

Description

Method for determining an optimal data transmission rate over a transmission medium

In current transmission method, such as the SHDSL transmission method ( "Single pair high bit rate digital subscriber line"), when a connection is automatically determines the optimal communication between the participants and their communications equipment data transfer rate Festge ^¬. This will, among other things in In a so-called training phase ("test probing" line test) various baud rates or bit rates have been tested. Baud rate is the number of characters or symbols per unit of time.

During this training phase, a certain previously negotiated number of test sequences are transmitted from a communication device (e.g., modem) associated with a subscriber at, for example, different baud rates received from another communication device connected to the sending communication device via the transmission medium.

The test sequences are ter by predetermined Testmus ^¬ which are known to the communication devices. On the side of the receiving communication device, the respective transmission quality or signal quality is subsequently determined for each received test sequence. For example, the received test pattern is compared with the known original pattern. Upon completion of the training phase, the compound can be delivered Since ^¬ tenübertragungsrate be continued with the identified in the training phase, the optimal transmission quality.

Since in most transmission methods, however, a relatively high number of possible data transmission rates can be used, but the training phase should be kept relatively short, ie the number of test sequences can be emitted is limited, often can not all possible Datenübertragungsra ^¬ th with specially designed test sequences tested. For untested data transfer rates, the signal quality is therefore, for example, by interpolation he ^¬ averages. However, these data transmission rates determined in the context of the interpolation are inaccurate, which may result, on the one hand, in transmission errors during the subsequent transmission of information or, on the other hand, as a result of inadequate utilization of the transmission link.

The invention has the object of fibers, the method for determining an optimum data transfer rate to verbes ^¬. This object is achieved on the basis of a method according to the features of the preamble of patent claim 1 by its characterizing features.

In the inventive method for determining the optimum data rate via a transmission medium having different data transmission rates Se ^¬ are respectively frequencies transmitted via the transmission medium and determines the transmission quality as a function of the sequences in each case transmitted. The essential aspect of the invention be ^¬ is the fact that the associated information to be several sequences chronologically successive stages. Furthermore, the sequences assigned to a stage have a predefinable distance with regard to the data transmission rate. The following steps are carried out: a) transmitting at least a portion of one stage zugeord ^¬ Neten sequences and selecting one arranged between two transmitted sequences interval in dependence on the determined transmission quality, and b) transmitting at least a portion of the in-selected interval and the subsequent Stage assigned sequences. The essential advantage of the invention is that the assignment of the test sequences to a plurality of chronologically successive stages allows a more accurate determination of the data transmission rate which is optimal for the transmission of information.

Advantageously, the above-mentioned steps a) and b) can be ^¬ the run several times cyclically - claim. 2

The sequences can further advantageously with different transmission methods, are transmitted eg also different modulation methods and / or different transmit power - claims 2 and 3. Since ^¬ by optimizing the data transfer rate is further improved.

According to an advantageous development, the above-mentioned steps can also be carried out until either a maximum number of test sequences has been transmitted or until a predefined number of stages have been passed through - claims 4 and 5.

According to an additional advantageous embodiment of the method according to the invention, the number of stages can be chosen so that two adjacent in the last stage test sequences with respect to their data transfer as close as possible distance - claim 7. Advantageously, this smallest possible distance also has the value one on - claim 8. These advantageous developments, the accuracy in the determination of the optimum for the transmission data transmission rate can be increased.

According to a further advantageous development of the method according to the invention, the distances between the test sequences assigned to one stage become lower in the chronologically succeeding stages. Claim 9 Advantageously, the distances between test sequences of the same stage can be reduced. hernd have the same value - claim 10. The essential characteristic of these enhancements is a speedier Ver ^¬ ringerung the distances between adjacent test sequences with each succeeding stage, whereby the exact determination of the optimal data transmission rate is achieved more quickly.

Further advantageous embodiments of the method according to the invention as well as a communication device and a communication arrangement for determining an optimal data transmission rate over a transmission medium are to be taken from the further claims.

In the following the invention will be explained with reference to several drawings. Show

1 is a schematic representation of the time sequence of ^taking place between two communication units in the context of the connection setup training ^¬ phase according to the prior art,

2 is a schematic representation of the exemplary determination of the optimal transmission rate in the context of the training phase according to FIG. 1, FIG.

Fig. 3 is a schematic representation of the timing of the training phase as part of the invention ^shown SEN method, and

4 shows a detailed schematic illustration of the exemplary determination of the optimum transmission rate in the context of the method ^{according to} the invention.

Fig. 1 shows a schematic representation of the known timing of the training phase during the connection ^¬ structure in a prior art attributable telecommunications arrangement, which in this embodiment configured according to the SHDSL method. In this example, while the quality of test sequences is compared with USAGE ^¬ dung different baud rates.

During the test phase, n predetermined test sequences (TS 1,..., TSn), each having different, increasing baud rates, are transmitted from one communication device to another communication device to determine the optimum baud rate when establishing a connection by means of a handshake method, the quality of the received ^¬ recorded and determined. Handshake procedure generally means that the parameters for data transmission are negotiated between the two communication devices by means of so-called two-way handshake signals (HS) and transmission or readiness for reception are displayed.

It is known that the quality of the received signals is detected by the receiver, for example, based on a comparison of the genes are received, ^¬ test pattern with the predetermined original pattern. The results of this quality tests are then communicated to the sen ^¬ Denden communication device.

At the end of the test phase, the transmitter determines the optimum baud rate for the subsequent transmission of the user data based on the test results. For this purpose, the highest baud rate is selected at which sufficient quality of the information to be transmitted is still achieved. Subsequently, the transmission of the actual user data (data) begins.

For example, since the SHDSL process frequencies up to ten Testse ^¬ stand for the training phase are available, in contrast, however, up to 67 different baud rates for the transmission of information are available, the signal quality can adversely not be tested accurately for all baud rates. For untested baud rates the signal quality can be therefore only be determined by interpolation. This particular during the interpolation baud rates are, however, as already explained inaccurate, which at too low Emp ^¬ catch quality transmission error in the subsequent transmission of information and at a high quality non-optimal utilization of the resources of the transmission ^¬ stretch consequence has.

Fig. 2 shows an exemplary sequence of generally Moegli m ^¬ chen baud rates (DRL, ... DRm). In a communication according to the SHDSL transmission method according to the known prior art, during the training phase, each n is an ^¬ be agreed baud rate (DRL, ... DRm) representing Testsequen zen ^¬ (, ..., TSn TSL) transmitted. By way of example, the following assignment is assumed: n = 10 and m = 67. To determine the optimum baud rate, the test sequences TS1 to TS10 are assigned the baud rates DR3, DR9, DR15, DR22, DR29, DR36, DR43, DR50, DR57 and DR64. In the transmission of these ten test sequences (TSl, ..., TSLO) whose signal quality is detected in ger receptions and seminars ^¬ and determined. The signal quality is present at ^¬ play, in the lower-valued baud rate DR43 still larger than a required minimum Signalqua ^¬ notes, wherein a higher value having baud rate DR50, however, already lower than said minimum quality so must be the exact value of the optimum, for the transmission of information Baud rate can be determined by interpolation of the values for DR43 and DR50 (here eg DR47). The optimal baud rate is thus approximated but not exactly verified.

3 shows a schematic representation of the time sequence of the training phase between two communication devices (not shown) connected to one another via a transmission medium in the context of the method according to the invention. In this case, a communication device for example, as a mapped to the subscriber modem out ^¬ forms be the corresponding communication device may for example be a central switch be assigned. In the emerging from Fig. 3 embodiment, information is transmitted as part of the SHDSL transmission method, again 67 schiedliche under ^¬ baud rates are available for the transmission of information, but as part of the training phase, a maximum of ten test sequences (TS, ..., TSLO) are emitted can.

During the connection set-up within the Trai ^¬ the transmission parameters beginnings phase using a Handsha ^¬ set ke process. However, according to the invention, the test sequences used (TS1,..., TSn) are assigned to several stages (stage, stage 2, stage 3). In the first stage (Stufel), for example, only three test sequences (TS1, TS2, TS3) are transmitted, ie transmitted by the modem and received in the switching device or vice versa. After detecting the signal qualities of the three received test sequence (TSl, TS2, TS3), the detection result or test result by means of a further handshake signal (HS) to the transmitting ^¬ is transmitted page. Depending on the results of transmitted Tester ^¬ (Fe3 Stufe2 study programs,) are then transmitted in subsequent stages respectively, some other test sequences (TS4, TS5, TS6 and TSn-2, TSn-I, TSn) and the respective Signalqua ^¬ litäten detected.

The detection of the transmission quality or signal quality as a function of the transmitted sequences or test sequences (TS,..., TSn) can take place in different ways. In ^¬ play, the amplitude and / or the bit error rate of the received signals can be detected, but it is usual to determine the signal-to-noise ratio (SNR) from a comparison of the known original test pattern with the received sequence (TS, ..., TSn ).

In this case, in the received communication device for each received sequence (TS, ..., TSn) whose amplitude or signal-to-noise ratio is respectively detected or measured and an information representing the detection result, for example in Frame of the handshake method to the sending communication ^¬ tion device transmitted.

Alternatively, the amplitude or signal-to-noise ratio of exemplary meh ^¬ received sequences (TS, ..., TSn) is detected and closing at ^¬ transmits a summary of the detection results of information representing the emitting Kommunikati ^¬ onseinrichtung.

The transmission quality can be determined from the data transmitted to the originating communication device detection results (for example, values for signal-to-noise ratio) or abge ^¬ passes are.

Alternatively, at the receiving communication device from the detection results (for example, values for signal-to-noise ratio) are determined, the transmission quality and the transmission quality representing Informati ^¬ on or derived from the transmission quality Steuerinfor ^¬ mation to the emitting communication device be transmitted.

Depending on the derived transmission quality, the transmission of further test sequences (TS, ..., TSn) is controlled.

The selection of the baud rates (DRI, ..., DRm) for the individual test sequences (TS, ..., TS n) and the erfindungsge ^¬ Permitted assignment of test sequences (TS, ..., TS n) to the individual stages (Stufel , Stage 2, Stage 3) is shown schematically in FIG. 4. Here, the Testse ^¬ sequences (TS, ..., TS n) n = 9, and it is assumed for the number of the In ^¬ formation transfer usable baud m = 67 for the number. For example, in the first stage test sequences (TS1, TS2, TS3) with the baud rates DR16, DR33 and DR50 are tested. The span of all baud rates (DR1,..., DR67) possible in this example is thus divided into intervals of the same size (111, 112, 113, 114). Based on the signal qualities The first three test sequences (TS1, TS2, TS3) of the first stage (Stufel) are then determined at which interval

(111, 112, 113, 114), the optimum for the connection baud rate must be located: in this example, the Signalqua ^¬ is formality at baud rate DR33 still larger than the required mini ^¬ male signal quality at the higher baud rate DR50, however, the quality is already less than the minimum quality. The further test, ie those in the subsequent stages

(Stage 2, Stage 3) test sequences (TS4, ..., TS9), focuses on the interval (113) between baud rates DR33 and DR50.

In the second stage (stage 2) of the method according to the invention, the signal qualities of the test sequences TS4, TS5 and TS6 with the corresponding baud rates DR38, DR42 and DR46 are then tested. Again, the Inter ^¬ vall is previously determined (113) or this interval (113) associated baud rates ^¬ (DR33 DR50 up) in approximately equal sub-intervals (121, 122, 123, 124) divided. The test results of the two ^¬ th stage (step 2) are transmitted by handshake signals and it is determined again, in which the new sub-interval (123), the optimal baud rate must be located. As can be seen in Figure 4, the new subinterval (123) is located between baud rates DR42 and DR46.

In a final third stage (stage3), the signal qualities of the test sequences TS7, TS8 and TS9 with the appropriate baud rates DR43, DR44 detected DR45 and determined and depending on the determination result is true, the optimum for the current connection baud rate finally be ^¬ (or in this case be: DR45). The detected signal qualities are examined, for example, as of which baud rate

(here: DR45) the signal quality of a test sequence transmitted and received in the third stage (stage 3)

(TS7, TS8, TS9) the required minimum quality first un ^¬ terschreitet. The payload data following the training phase Transmission is then this phase during the beginnings Trai ^¬ certain baud rate (here: DR45) is performed.

Furthermore, it is possible in the process according to the invention (not further erläu in this embodiment ^¬ t) test sequences using different modulation methods (about PAML 6 or PAM32 or PPM or QAM) to generate and transmit at multiple power levels. It would also be possible to provide for the implementation of the method according ^¬ proper test sequences with other different transmission parameters.

By using the method according to the invention made it possible ^¬ precise determination of an optimal Datenübertra ^¬ transmission rate can be obtained at the transmission of information or data transmission in comparison with the current method of determining the data transmission rate of up to 7dB. For SHDSL systems, for example, this corresponds to a range increase of 0.5 km.

Claims

claims

1. A method for determining an optimal data transmission rate (DRl, ..., DRm) via a transmission medium, at the respective different data transmission rates (DRl, ..., DRm) having sequences (TSl, ..., TSn) via the Ü transmission medium can be transmitted and in which the transmission quality as a function of übermit ^¬ telten sequences (TSl, ..., TSn) is determined, characterized in that the sequences to be transmitted (TSl, ..., TSn) a plurality of chronologically successive stages ( Stufel, Stufe2, Stufe3) are assigned, that the one stage (Stufel, Stage2, Stage3) associated sequences (TSl, ..., TSn) with respect to the Datenübertragungs ^¬ rate (DRl, ..., DRm) a predetermined distance (111 , ..., 134), and in that the following steps are performed: a) transmission of at least part of the sequences (TS1, ..., TSn) assigned to a stage (step, stage2, stage3) and selection of a sequence transmitted between two (TS1, ..., TSn) disposed interval (111, ..., 134) in depen ^¬ dependence on the determined transmission quality and b) transmitting at least a portion of the selected interval (113, lying 123) and the subsequent step

(Stage 2, Stage 3) associated sequences (TSl, ..., TSn).

2. The method according to claim 1, characterized in that the steps a) and b) are cycled several times.

3. The method according to claim 1 or 2, characterized in that the sequences are transmitted at least partially with different transmission methods.

4. The method according to claim 3, characterized in that the sequences are generated at least partially with different modulation methods and / or transmitted different transmission power.

5. The method according to any one of claims 1 to 4, characterized in that the steps a) and b) are cycled through to a predeterminable maximum number of sequences (TSl, ..., TSn) is transmitted.

6. The method of any one of claims 1 to 4, characterized in that the steps a) and b) are cycled until a predetermined number of stages (step, stage 2, stage 3) is passed through.

7. The method according to any one of claims 1 to 6, characterized in that so many stages are provided that in the last stage two adjacent sequences (TSl, ..., TSn) with respect to the data transmission rate as close as possible to have a distance last step c) the optimal transmission rate is determined by interpolation of the selected adjacent sequences (TS1, ..., TSn).

8. The method according to any one of claims 1 to 6, characterized in that so many stages (Stufel, stage 2, stage 3) are provided, that in the last stage (stage 3) the distance (131, 132, 133, 134) between two adjacent Sequences (TS7, TS8, TS9) have the value one with respect to the data transfer rate (DR43, DR44, DR45).

9. The method according to any one of claims 1 to 8, characterized that the data transmission rate is smaller the distance between a step (Stufel, step 2, step 3) associated sequences (TSl, ..., TSn) into the chrono ^¬ logically subsequent steps (step 2, step 3) with respect to.

10. The method according to any one of claims 1 to 9, characterized in that the distances between two adjacent and ei ^¬ ner stage (Stufel, stage 2, stage 3) associated sequences (TSl, ..., TSn) have approximately the same value.

11. The method according to any one of claims 1 to 10, characterized in that the transmission medium is formed as a wireless transmission medium or as a wired transmission medium or as opti ^¬ cal transmission medium.

12. The method according to any one of claims 1 to 11, characterized in that the transmission quality with the aid of the amplitude and / or with the aid of the bit error rate and / or with the aid of the signal-to-noise ratio of the received sequences (TSl, ..., TSn ) is detected.

13. The method according to any one of claims 1 to 12, characterized in that the optimum data transmission rate (DRl, ..., DRm) is determined in the context of an xDSL transmission method.

14, communication means for determining the highest possible data transfer rate (DRL, ... DRm) over a thereto at ^¬ closable transmission medium, comprising transmitting means for transmitting each different data transmission rates (DRL, ... DRm) having sequences (TSl, ... , TSn) over the transmission medium and with detection means for detecting the transmission quality as a function of the transmitted sequences (TSl, ..., TSn) representing information, characterized in that allocation means are provided, through which the sequences to be transmitted (TSl, ..., TSn) several chronological successive the stages (Stufel, Stufe2, Stufe3) assigned to one of the stages (Stufel, Stufe2, Stufe3) (TSl, ..., TSn) with respect to the data transmission rate (DRl, ..., DRm) a predetermined distance ( 111, ..., 134), and in that the transmission means and the detection means are configured such that: a) at least a part of the sequences (TS1, ..., TSn.) Assigned to a stage (stage, stage 2, stage 3) ) and an interval (111,..., 134) arranged between two transmitted sequences (TS1,..., TSn) is selected as a function of the determined transmission quality, and b) at least a portion of the data determined in a selected interval (111, ..., 134) and the subsequent stage (stage 2, stage 3) assigned sequences (TSl, ..., TSn) is transmitted.

15. Communication device according to claim 14, characterized in that the transmission means and the detection means are designed such that the steps a) and b) are repeated cyclically ^¬ cally.

16. Communication device according to claim 14 or 15, characterized in that the transmission means and the detection means are designed such that the steps a) and b) are cycled until a maximum number of sequences (TSl, ..., TSn) is transmitted ,

17. Communication device according to claim 14 or 15, characterized in that the transmission means and the detection means are designed in such a way that steps a) and b) are cycled until a predetermined number of stages (stage, stage 2, stage 3) have passed.

18. Communication device according to one of claims 14 to 17, characterized in that the transmission means, the assignment means and the detection means are designed such that so many Stu ^¬ fen are provided that in the last stage two adjacent sequences (TSl, ... , TSn) have in terms of data transfer rate as low as possible distance, where it is determined at c ^¬ in a last step) the optimal transfer rate by interpolation of selected adjacent sequences (TSl, ..., TSn).

19. Communication device according to one of claims 14 to 17, characterized in that the transmission means, the assignment means and the detection means are designed such that so many Stu ^¬ fen (Stufel, Stage2, Stage3) are provided that in the last stage (Stage3 ) the distance (131, 132, 133, 134) Zvi ^¬ rule two adjacent sequences (TS7, TS8, TS9) in terms of data transfer rate (DR43, DR44, DR45) has the value one.

20. Communication device according to one of claims 14 to 19, characterized in that the communication device is configured as the subscriber side associated decentralized communication device or is assigned to a central switching device.

21. A communication arrangement for determining an optimal data transmission rate via a transmission medium with transmission means for transmitting respectively different data transmission rates (DRl, ..., DRm) having sequences (TSl, ..., TSn) via the transmission medium and Erfas ^¬ sungsmitteln for detecting the transmission quality as a function of the transmitted sequences (TS1,..., TSn), characterized in that assignment means are provided, by which the sequences (TS1,..., TSn) to be transmitted are arranged in several chronologically successive stages (step, step2, step3) The sequences (TS1,..., TSn) assigned to one stage (step, stage2, stage3) have a predefinable distance (111,..., 134) with regard to the data transmission rate (DR1,..., DRm) , and that the transmission means and the detection means are designed such that: a) at least a part of a stage (stage, stage 2, stage 3) is assigned dneten sequences (TSl, ..., TSn) transmitted and a between two transmitted sequences (TSl, ..., TSn) arranged interval (111, ..., 134) is selected depending on the determined transmission quality, and b) at least a part of the sequences (TS1,..., TSn) lying in the selected interval (111,..., 134) and assigned to the subsequent stage (Level2, Level3) is transmitted.