JP2003333210A - xDSL relay method - Google Patents

Abstract

(57) Abstract: The present invention relates to an xDSL relay method, and relates to ATU-
XD which can efficiently perform the procedure when a repeater is inserted between C and ATU-R while eliminating the influence of noise
It is intended to provide an SL relay method. SOLUTION: This is a relay method of an xDSL system having a telephone line in which the amount of crosstalk noise changes periodically at a timing determined by a station and having a repeater, wherein the repeater is located between a station and a repeater section. (Step 1), and perform initial training and data communication between the repeater and the subscriber using the crosstalk noise timing extracted from the communication with the station (Step 2). Features.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to xDSL (xDigi) which realizes high speed data transmission using an existing telephone line.
tal Subscriber Line) system, in particular, because the distance between the accommodation station and the subscriber's house across the telephone line is too long, the conventional method and the apparatus using the method cannot obtain the required transmission rate. In the case of a repeater.

X of xDSL represents non-target transmission and target transmission of a transmission rate between a station → subscriber (downlink) and a subscriber → station (uplink), and a non-target transmission system is ADSL (Asym).
metric Digital Subscriber
Line). Hereinafter, although ADSL will be described as an example, the content of the present invention is not limited to ADSL.

[0003]

2. Description of the Related Art (a) Outline of ADSL At present, ADSL is beginning to attract attention as a technique for realizing high-speed data transmission at a relatively low cost. Compared with conventional analog modems and ISDN, although ADSL is capable of orders of magnitude higher speed transmission, it is possible to use the Internet etc. at a price that is not inferior to analog modems etc. That is the reason.

One of the reasons that ADSL can realize high-speed and high-speed data transmission at a relatively low cost is that ADSL is a technology that uses an existing telephone line. Data can be transmitted at higher speed than ADSL by using the optical fiber, but the optical fiber is newly installed from the accommodation station (hereinafter referred to as the station side) to the subscriber's house (hereinafter referred to as the subscriber side). To do so requires enormous amount of time and cost.

Therefore, ultrahigh-speed data transmission using an optical fiber has not yet come to a realizable time. For this reason, ADSL, which realizes high-speed data transmission at low cost in a short period of time by using an existing telephone line, has started to attract attention.

FIG. 8 is a conceptual diagram of a conventional ADSL system. In the figure, 1 is an office-side ADSL device (ATU-
C) and 2 are subscriber side ADSL devices (ATU-R). ATU-C and ATU-R are connected via signal lines 3 and 4, and ATU-C and ATU-R exchange data (data transmission) via these signal lines 3 and 4.

Here, when the distance between ATU-C and ATU-R is long, it is considered that a repeater is provided in the middle of the signal line to prevent signal attenuation. FIG. 9 is a conceptual diagram of a conventional ADSL transmission system having a repeater. In the figure, 5 is a repeater for amplifying a signal connected between ATU-C1 and ATU-R. 6, 7,
Signal lines 8 and 9 are connected between the ATU-C1, the repeater 5, and the ATU-R2. Thus, ATU-C and A
By providing the repeater 5 between the TU and R2, signal attenuation can be prevented. (B) Overview of Annex C ITU-T Recommendation G.1, which is an international standard of ADSL. 99
2.1, G.I. In 992.2, Annex C describes the ADSL standard that is considered to be practically intended for Japan. In addition, ITU-T Recommendation G. 992.1, G992.2,
Standards are full rate ADSL and simplified version ADSL, respectively. In Annex C, TC is connected to the adjacent line of ADSL.
M (Time Compressed Multipl)
ex) -ISDN is used (usually there are many such wirings), the standard is to avoid periodic crosstalk noise generated between the TCM-ISDN and TCM-ISDN.
The outline will be described below with reference to FIG.

FIG. 10 is a diagram showing an outline of Annex C. In ISDN, TTR (TCM-ISDN Ti
ming Reference: cycle 2.5 ms) 11
In synchronization with 0, the station side transmits a downlink signal in the first half cycle of the TTR 110, and the subscriber side transmits an uplink signal after receiving the downlink signal.

Therefore, in the ADSL on the office side, TTR1
The first half cycle of 10 is affected by the near-end crosstalk (hereinafter, referred to as NEXT) 120 from the ISDN downlink signal, and the second half cycle is affected by the far-end crosstalk (hereinafter, referred to as FEXT) 130 from the subscriber-side ISDN upstream signal. Receive.

In the subscriber side ADSL, the TT is contrary to the station side.
The first half cycle of R110 is affected by FEXT140, and the second half cycle is affected by NEXT150.
Such time regions affected by NEXT and FEXT are called a NEXT interval and a FEXT interval, respectively. In addition,
FIG. 10 shows the NEXT section and the FEXT section on the subscriber side.

In Annex C, the above-mentioned N
A sliding window is defined in which ADSL symbols are transmitted in correspondence with the EXT period and the FEXT period. That is, as shown in FIG. 10, the transmitted ADSL symbol 160 is the FEX on the subscriber side.
If it is completely included in the T section, the sliding window 170 allows the station side ADSL device (hereinafter referred to as ATU).
-C) sends the symbol as a FEXT symbol.

If a part of the transmission symbol is included in the NEXT period on the subscriber side, the ATU-C transmits the symbol as the NEXT symbol. Also in the upstream, the subscriber-side ADSL device (hereinafter referred to as ATU-R) transmits the ADSL symbol in the same manner as in the downstream. Note that such a communication system is called a dual bit map system.

On the other hand, in the downstream direction, ATU-C has N
In the EXT period, only the timing synchronization tone may be transmitted and other data may not be transmitted. At this time, in the upstream direction, the ATU-R transmits nothing in the NEXT interval. This kind of transmission method is
This is called a bitmap (FEXT Bitmap) method. (C) Overview of initialization In order to perform data transmission between ATU-C and ATU-R, it is necessary to perform handshake and initialization. The detailed handshake and initialization method are described in ITU-T Recommendation G.264. 9
As described in G.94.1, G992.1, and G992.2, the outline thereof will be described here.

FIG. 11 is a timing chart of handshaking and initialization. According to this figure, the initialization at the start of communication first starts with the handshake 210. Here, the handshake means ATU-C and A as described in ITU-T Recommendation G994.1.
TU-R refers to an exchange performed for exchanging capability lists (transmission capability), which means a list of functions that can be realized, and for determining a communication method.

Whether to use Annex C for data transmission, and if Annex C is used,
In this handshake 210, a communication method such as whether to use the dual bitmap method or the flexible bitmap method is determined. Even when Annex C is used, handshaking 210 exchanges capability lists and determines communication methods without distinction between the NEXT section and the FEXT section.

Next, ITU-T Recommendation G. 992.1, G
The initialization described in 992.2 is performed. The initialization is performed in three stages of training 220, channel analysis 230, and exchange 240. In the training 220 and the channel analysis 230, the line characteristics and the like of both ATU-C and ATU-R are investigated and recognized to set the coefficient of the equalizer and determine the data transmission rate.

Here, when Annex C is selected in the above handshake 210, as soon as the training 220 is started, the ADSL symbol 160 (see FIG.
0 (see 0) is synchronized with the timing of the TTR 110. Then, in consideration of the NEXT section and the FEXT section determined in synchronization with the timing of the TTR 110, the coefficient setting of the equalizer, the data transmission rate, etc. are performed. Then, in the next exchange 240, the other party is notified of the previously determined data transmission rate, performance margin, and the like.

[0018] In ADSL, 10 ^-7 or less of the BER (Bi
t Error Rate) is required to be maintained. On the other hand, the various noises received by the received ADSL symbol are not constant and are constantly changing. Therefore, it is necessary to decide the data transmission rate with a margin so that the BER of 10 ⁻⁷ or less is maintained no matter how the noise changes. The performance margin means the margin at this time.

The performance margin is a margin to be taken into consideration when allocating transmission bits during initialization in consideration of fluctuations in the transmission path during communication. For example, if BER is 10 ⁻⁷ and SN = 15 dB, and 2 bits can be allocated, and the performance margin is set to 6 dB, the actual bit allocation is 21.
Two bits will be allocated in dB. In this way, if the setting is made during initialization, 2-bit data transmission can be secured even if some SN deterioration occurs during actual communication. (D) Transmission rate As described above, in ADSL, the transmission rate of data is determined by the initialization performed before data transmission. In other words, in ADSL, the data transmission rate is undetermined until the initialization is completed. Factors that determine the transmission rate include various noise magnitudes received by the received ADSL symbol, setting of reliability of data transmission by performance margin, performance of the ADSL transmitter / receiver, and ATU-C and A.
There is a distance from the TU-R.

FIG. 12 is a diagram showing transmission speed-distance characteristics. The figure shows an example of the data transmission rate in the downlink direction. The horizontal axis is distance [km], and the vertical axis is transmission rate [Mbps]
Is. In this example, the maximum transmission rate of 8 Mbps is maintained until the distance between ATU-C and ATU-R is close to 2 km, but the transmission rate thereafter gradually decreases to 1 Mbps at 4 km. in this way,
The transmission rate of ADSL depends on the distance between ATU-C and ATU-R, and in general, the longer the distance, the lower the transmission rate.

The numbers shown in FIG. 12 as percentages are ITU-T recommendation G.264. Introduced in 996.1, it means the coverage rate of users at that distance. According to this, about 60% of users can perform data transmission near the maximum transmission rate of 8 Mbps. However, the remaining 40% of users are ATU
-The transmission speed varies greatly depending on the distance from C,
About 10% of users can perform data transmission only at a speed of 2 Mbps or less.

As described above, if the distance from the ATU-C is too long, data cannot be transmitted at a satisfactory speed. Therefore, in such a case, ATU-C and ATU
Data may be transmitted via an ADSL repeater (repeater) placed between the R and -R. However, the above-mentioned An
Future studies are expected for the ADSL relay system compatible with nex C.

In ADSL, data transmission is performed in the high frequency band above the voice band. On the other hand, since the existing telephone line is developed for telephones, it has excellent voice band characteristics, but has poor high frequency characteristics required for ADSL data transmission. Therefore, in ADSL, as described above, the transmission rate thereof largely depends on the distance between ATU-C and ATU-R. (E) Spectrum Management As mentioned above, by using Annex C,
ADSL can avoid the relatively large NEXT of the periodic crosstalk noise received from the TCM-ISDN. Especially if you use the fixed bitmap method,
The NEXT from ADSL to TCM-ISDN can also be avoided.

Further, the plurality of ADSLs are not affected by NEXT. Thus, N
EXT has been evaded with great care.
Thus, avoiding a relatively large NEXT is
This is important because it does not affect each data transmission.

By the way, recently, various kinds of DS
The L method is emerging. ITU-T Recommendation G.3, which performs data transmission in perfect synchronization with TCM-ISDN. 99
2.1 SSDS specified by Annex H
L (Synchronized Symmetrica)
1 DSL), VDSL (Very-high-spe) that performs data transmission at a speed of several tens of Mbps over a short distance.
ed DSL) is an example.

The NEXT generated between the ADSL and the TCM-ISDN can be avoided as described above, but the NEXT generated between the ADSL and the SSDSL.
This is not the case with respect to the above. Also, ADSL and VD
Not only NEXT but also a relatively large NEXT is generated between the SL and the other cases, but the same applies to these. Therefore, even for these crosstalk noises,
It must be avoided so as not to affect the data transmission of each other. This workaround is mainly referred to as spectrum management because it mainly controls the power of the target band of the transmitted signal.

FIG. 13 shows an example of spectrum management. The figure is an illustration of FEXT that occurs between ADSL and VDSL. In general, NEXT is larger than FEXT, and in many cases FEXT has less influence on data transmission. However, in the example shown in FIG. 13, the situation is different.

In FIG. 13, the VDSL and ADSL lines are adjacent to each other in the same cable, and the OND side VD
SL (hereinafter referred to as VTU-O) 410 and subscriber side V
The distance between the DSL device (hereinafter, referred to as VTU-R) 420 is much shorter than the distance between the ATU-C430 and the ATU-R440.

At this time, VTU-O410 to VTU-R
The VDSL symbol transmitted to 420 is superimposed on the ADSL line as crosstalk noise and becomes FEXT450 for the ADSL symbol transmitted from ATU-C430 and received by ATU-R440. At this time, the power of the received ADSL symbol is greatly attenuated due to the long distance transmission, and is extremely small. Therefore, the influence of FEXT450 on the received ADSL symbol cannot be ignored.

As it stands, ADSL cannot realize high-speed data transmission due to FEXT from VDSL. Therefore, spectrum management is required. What is spectrum management here?
Specifically, only the frequency band that affects ADSL is V
This is to reduce the DSL transmission signal to a level that does not affect ADSL.

[0031]

As described above, ATU-C and ATU are affected by periodic noise.
In order to realize high-speed data transfer by ADSL in an environment where the distance from -R is too long, an ADSL relay system that performs data transmission in synchronization with the timing of TTR 110 is required. However, an optimum method has not been proposed for the ADSL relay method under this periodic noise environment.

Also, in ADSL, the capability (transmission capability) list is exchanged and the communication method is determined during the handshake.
-It is not possible to directly handshake between C and ATU-R. Therefore, it is necessary to define the handshake procedure between the ATU-C and the repeater and between the repeater and the ATU-R.

Further, in the setting of the transmission speed in the ADSL relay system and the "transmissible capacity at the minimum transmission delay" described in Japanese Patent Laid-Open No. 2000-151742, the set values between ATU-C and repeater are set to repeater and ATU- If the capacity is set to be larger than the possible capacity between Rs, data communication becomes impossible due to the bottleneck between the repeater and the ATU-R. Therefore, A
It is necessary to set the transmission speed in the DSL relay system and the “transmissible capacity with the minimum transmission delay”.

The invention described in JP-A No. 2000-151742 will be described below. ITU-T Recommendation G. 99
In ADSL defined in 2.1, a path (hereinafter referred to as Fast Pa) with a small transmission delay is sent as shown in FIG.
and a path for increasing the data quality by increasing the transmission delay (hereinafter, Interleaved Pas).
s), and a mode for transmitting the data of the two paths together (hereinafter, referred to as a dual latency mode) and a mode for transmitting only one of the data (hereinafter, referred to as a single latency mode). ) Is supported. In dual latency mode, user data is sent on both paths (ie Fast Path and Inter
Leaved Pass)
In the latency mode, all user data is stored in one path (that is, Fast Path or Interleaved).
Pass).

In the case of Fast Path, user data becomes transmission data through a CRC encoder → scrambler → FEC encoder → rate converter. Int
In the case of erased Pass, the user data is
CRC encoder → scrambler → FEC encoder →
It becomes transmission data through the interleaver → rate converter.

Environment coexisting with TCM-ISDN (ITU
-T Recommendation G. F in Annex C) of 992.1
In ast Path, data is transmitted in subframe units. Sub-frame consists of 10 consecutive DMT symbols (excluding sync symbols) according to TTR timing.
Consists of. Therefore, 34 subframes form one hyperframe.

From this, as shown in FIG. 15, there are cases where the subframe has three FEXT sections and cases where the subframe has four FEXT sections. Figure 15
FIG. 3 is an explanatory diagram of a hyperframe structure. In FIG. 15, (a) shows TTR, (b) shows ATU-R crosstalk, and (c) shows ATU-C transmit DMT symbol. The hyperframe is composed of 345 symbols, and if 69 symbols are one superframe, they are composed of five superframes SPF # 0 to SPF # 4. Subframes are SS, I
Consists of 10 consecutive DMT symbols excluding SS, 4 Fs
There are cases where it has an EXT section and cases where it has three FEXT sections.

In the rate converter shown in FIG. 14, since the bit rate is converted to an integral multiple of 32 kbit / sec, dummy bits are inserted, but Fast Pat is used.
The dummy bit is inserted into h at the end of each subframe in the dual latency mode, and in the fourth FEXT period in the single latency mode. The transmission capacity of the transmission amount delay minimum logical channel referred to in the present invention means the maximum transmission capacity when all the transmission data is assigned to Fast Path.

Further, in the conventional ADSL transmission system, the transmission signal power of the repeater which becomes FEXT noise is
From the viewpoint of spectrum management as well, it is desired to reduce as much as possible.

The present invention has been made in view of the above problems, and in order to solve the above problems in the ADSL relay system, an initialization procedure for synchronizing with the timing of the TTR 110 and a repeater are used. It is an object of the present invention to provide a handshake procedure, a transmission rate for satisfying a possible capacity between a repeater and an ATU-R, a procedure for setting "transmissible capacity with minimum transmission delay", and a method for reducing the transmission signal power of a repeater. That is, ATU-
XD that can efficiently perform the procedure when a repeater is inserted between C and ATU-R by eliminating the influence of noise
It is intended to provide an SL relay method.

[0041]

(1) FIG. 1 is a flow chart showing the principle of the method of the present invention. The present invention is a relay method for an xDSL system, which uses a telephone line, whose crosstalk noise amount periodically changes at a timing determined by the station side, as a transmission line, and has a relay, wherein the relay is between the station side and the relay. Initial training and data communication in step 1) are performed first, and initial training and data communication between the repeater and the subscriber are performed using the crosstalk noise timing extracted from the communication with the station side (step 2). Characterize.

With this configuration, ATU-C and AT
It is possible to provide an xDSL relay method capable of efficiently performing a procedure when a repeater is inserted between U and R by reducing the influence of noise.

(2) The invention according to claim 2 is the ITU-T.
G. When performing the handshake specified in the 994.1 Recommendation, the repeater first performs the handshake between the repeater and the subscriber to hold the capability list of the subscriber side device, and then communicates with the subscriber side. 2. The xDSL relay method according to claim 1, wherein the capability list of the subscriber side device is transmitted to the station side by performing a handshake between the relay side and the station side after disconnecting.

According to this structure, first, the handshake between the repeater and the subscriber side is performed, and then the handshake between the repeater and the station side is performed, so that the handshake between the station side and the subscriber side is performed as a whole. be able to.

(3) In the invention according to claim 3, after the communication between the repeater and the station is established, the handshake between the repeater and the subscriber is performed again, and the repeater performs the handshake between the repeater and the station. It is characterized in that the communication method determined in step 1 is held and the same communication method is selected as the communication method between the repeater and the subscriber.

According to this structure, the same communication method can be set between the repeater and the station and between the repeater and the subscriber. (4) The invention according to claim 4 is the ITU-TG. 992.
1 and G992.2 Recommendation, the repeater holds the data transmission capacity determined by the initialization between the repeater and the station, and the initialization between the repeater and the subscriber. If the transmissible capacity calculated by the localization is larger than the transmission capacity between the repeater and the station, apply the transmission capacity between the repeater and the station between the repeater and the subscriber, and If the transmission capacity of the relay is smaller than the transmission capacity between the repeater and the station, hold the transmission capacity between the repeater and the subscriber and then perform communication between the repeater and the subscriber and between the repeater and the station. In the initialization between the repeater and the station, which is once disconnected and performed again, the transmission capacity between the repeater and the station is limited to less than the transmittable capacity between the repeater and the subscriber.

According to this structure, it is possible to balance the transmission capacity between the stations and the repeaters, and the transmission capacity between the repeaters and the subscribers. (5) The invention according to claim 5 is the ITU-TG. 992.
1 and G.I. When the initialization specified in the 992.2 Recommendation is performed, the transmission capacity with the minimum transmission delay calculated by the initialization between the repeater and the subscriber is the minimum transmission delay logical channel between the repeater and the station. If it is less than the transmission capacity of the relay, hold the transmission capacity with the minimum transmission delay between the repeater and the subscriber, then temporarily disconnect the communication between the repeater and the subscriber and between the repeater and the station, and perform the relay again In the initialization between the repeater and the station, the transmission capacity of the minimum transmission delay logical channel between the repeater and the station is limited to less than the transmission capacity at the minimum transmission delay between the repeater and the subscriber.

With this configuration, it is possible to limit the transmission capacity of the logical channel with the minimum transmission delay between the repeater and the station to less than the transmittable capacity with the minimum transmission delay between the repeater and the subscriber.

The present invention is also characterized in that the signal power transmitted from the repeater to the subscriber is varied based on the signal power received by the repeater from the subscriber unit at the start of the initial training.

With this configuration, the signal power between the repeater and the subscriber unit can be optimally varied. Further, in the present invention, the performance margin value capable of maintaining the required BER (bit error rate) is notified from the station side to the repeater at the time of initialization between the station side and the repeater and held. The above-mentioned value held at the time of initialization between the repeater and the subscriber thereafter is notified from the repeater to the subscriber side.

With this configuration, the value of the performance margin can be set from the station side so that a predetermined BER between subscribers can be maintained.

[0052]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described in detail below with reference to the drawings. (A) Initialization procedure for TTR synchronization An example of an embodiment of an initialization procedure of an ADSL relay system under a periodic noise environment will be described with reference to FIG. FIG. 2 is a diagram showing an initialization procedure for TTR synchronization. The same parts as those in FIG. 9 are designated by the same reference numerals. In the figure, 1 is ATU-C, 5
Is a repeater (repeater) connected to the ATU-C1
Is an ATU-R connected to the repeater 5.

In the ADSL relay system of the present invention, first the ATU-C1 and the repeater 5 are activated. And A
Initialization is performed between the TU-C1 and the repeater 5. The TTR held by the station side is extracted by the repeater 5 in the initialization training sequence, and at the end of the initialization, data communication in synchronization with the TTR is possible between the ATU-C1 and the repeater 5 ().

After the TTR information is held in the repeater 5, the repeater 5 and the AT are synchronized with the TTR held in the station side.
Initialization between U-R2 can be performed. Therefore, ATU-R2 is started, and repeater 5 and AT
Initialize between U and R2. In the training sequence of initialization, the TTR held by the station side is extracted to ATU-R2, and at the end of initialization, data communication synchronized with TTR between the repeater 5 and ATU-R2 becomes possible ().

By the above two-step initialization procedure, data communication in synchronization with TTR can be realized between ATU-C and ATU-R. That is, ATU-C
The procedure when the repeater is inserted between the ATU and the ATU-R can be efficiently performed by reducing the influence of noise. (B) Handshake procedure via repeater The communication method determined after the capability list exchange by handshake is ATU-C and ATU-R.
It is decided by the station side from the communication methods allowed by both capability lists. Therefore, in order to determine the communication method, the ATU-R capability list A
It is necessary to relay to TU-C.

In the present invention, the signal power used in the handshake is small, and T is used for spectrum management.
Utilizing the fact that there is no problem even if it is not synchronized with the TR phase, the repeater and ATU-R side handshake is performed first.

FIG. 3 is a diagram showing a handshake execution procedure via a repeater. The same parts as those in FIG. 2 are designated by the same reference numerals. At the beginning of the handshake procedure, repeater 5 and ATU-R2 perform a handshake, and
The repeater 5 extracts the TU-R capability list (). Since the handshake here is only for extracting the capability list, it does not transit to the subsequent initialization sequence and disconnects the communication with the ATU-R. Since the handshake does not require TTR synchronization, this processing is performed before the initialization procedure for TTR synchronization described above is started.

After the capability list of the ATU-R2 is extracted and held in the repeater 5, the ATU-C1 and the repeater 5 are handshaked (). In this handshake, first, the ATU- held and relayed by the repeater 5
The capability list of R2 is extracted to ATU-C1.

Next, on the station side, the extracted ATU-R2
The communication system that can be selected is determined from the capability list of ATU-C1 and the capability list of ATU-C1, and the communication system is determined. The communication method thus determined is extracted by the repeater 5, and the handshake between the station side and the repeater 5 is completed. Next, the repeater 5 connects to the ATU-R2 ().

With this configuration, first the repeater 5
By performing handshaking with the subscriber side and then handshaking with the repeater 5 and the station side, the handshaking with the station side and the subscriber side can be performed as a whole.

FIG. 4 shows a state transition diagram when the initialization is performed in consideration of the initialization procedure for TTR synchronization and the handshake procedure described above. FIG. 4 is an initialization state transition diagram. First, after the communication method is decided on the station side, the ATU-C and the repeater transit to the initialization as they are, and when the initialization is completed, the communication state is established between the ATU-C and the repeater.

After the communication between the ATU-C and the repeater is established, the handshake between the repeater and the ATU-R is performed again, and a transition is made to the initialization between the repeater and the ATU-R. In the handshake between the repeater and the ATU-R, the communication method determined by the handshake between the station side and the repeater held by the repeater is determined as the communication method between the repeater and the ATU-R.

With this configuration, between the repeater and the station,
The same communication method can be set between the repeater and the subscriber. (C) Transmission Rate Setting Procedure An exemplary embodiment of a setting procedure for determining the transmission capacity between the repeater and the ATU-C and between the repeater and the ATU-R will be described with reference to FIG. FIG. 5 is a diagram showing a transmission rate determination flowchart. In the initialization procedure for TTR synchronization described above, the repeater is ATU-C.
And the data transmission capacity determined by the initialization between the repeater and the repeater is held (S1). Next, repeater and AT
The transmittable capacity is calculated by the initialization between U and R (S2).

Next, rate judgment is performed (S3). In the rate judgment, if the calculated transmission capacity is larger than the transmission capacity between the ATU-C and the repeater, the ATU-
The transmission capacity between C and repeater is applied between the repeater and ATU-R.

On the other hand, when the transmission capacity between the repeater and the ATU-R is smaller than the transmission capacity between the ATU-C and the repeater, the transmission capacity between the repeater and the ATU-R is held in the repeater and then The communication between ATU-R and between ATU-C and the repeater is once disconnected.

After that, re-initialization between the ATU-C and the repeater is performed. At this time, the transmittable capacity held between the repeater and the ATU-R is notified to the ATU-C during the handshake, and the transmission capacity between the ATU-C and the repeater is re-initialized by the re-initialization. The limit is set to be less than the transmittable capacity during the period (S4). After the communication between the ATU-C and the repeater is established, re-initialization between the repeater and the ATU-R is performed (S5), and a transition is made to data communication (S).
6).

The transmission capacity between the repeater and the ATU-R includes the "transmission capacity with the minimum transmission delay" described in JP-A-2000-151742, and the transmission capacity between the repeater and the ATU-R at the time of the rate judgment. When the “transmissible capacity at the minimum transmission delay” is less than the transmission capacity at the minimum transmission delay determined between the ATU-C and the repeater, retraining is similarly performed.

According to this embodiment, the transmission capacities between the stations and between the repeaters (repeaters) and between the repeaters and the subscribers can be balanced. If the transmission capacity with the minimum transmission delay calculated by the initialization between the repeater and the subscriber is less than the transmission capacity of the logical channel with the minimum transmission delay between the repeater and the station, the transmission between the repeater and the subscriber is performed. In the initialization between the repeater and the station, the communication between the repeater and the subscriber and the communication between the repeater and the station are temporarily disconnected after maintaining the transmission capacity with the minimum delay, and the minimum transmission delay logic between the repeater and the station is used. It is possible to limit the transmission capacity of the channel to less than the transmission capacity at the minimum transmission delay between the repeater and the subscriber.

With this configuration, the transmission capacity of the logical channel with the minimum transmission delay between the repeater and the station can be limited to less than the transmission capacity with the minimum transmission delay between the repeater and the subscriber. (D) Method of reducing transmission signal power of repeater FIG. 6 shows an example of an embodiment of a method of reducing transmission signal power of a repeater.
Will be explained. FIG. 6 is an explanatory diagram of determining the downlink transmission power of the repeater. The same parts as those in FIG. 2 are designated by the same reference numerals. In the figure, 1 is ATU-C, 2 is ATU
-R and 5 are repeaters.

The downlink transmission signal of the repeater is the conventional ADS.
A of adjacent line (line connecting ATU-C1 'and ATU-R2') using L transmission system or other transmission method
It becomes a FEXT noise source to the TU-R side. Therefore, in the present invention, the repeater 5 determines by the downlink transmission power determination procedure so that the FEXT noise to the ATU-R side of the adjacent line becomes less than the noise amount specified by spectrum management.

The repeater 5 measures the level of the received signal power from the ATU-R2 at the start of initialization with the ATU-R2, and determines the downlink transmission power based on this level. When the level of the received signal power from the ATU-R2 is high, the repeater 5 and the ATU-R
It is determined that the distance between them is short, and the downlink transmission power level from the repeater 5 is lowered.

In this way, the signal power between the repeater and the subscriber unit (ATU-R) can be optimally varied. Then, it is possible to achieve spectrum management in the ADSL relay system and reduce the influence of noise on adjacent lines. (E) Performance Margin Determination and Notification Method As described above, in the normal station side (ATU-C) and subscriber side (ATU-R) ADSL, the ATU-R maintains a BER of 10 ^-7 or less. Is required, and a performance margin commensurate with that is set. A
Maintaining a BER of 10 ⁻⁷ or less between TU-C and ATU-R is required even when data transmission is performed via a repeater. At this time, ATU-C and ATU
-To reduce the BER between R and 10 ^-7 or less, ATU
-C and repeater, and B between repeater and ATU-R
It is necessary to set ER to an appropriate value less than 10 ^-7 in advance.

However, considering that the common ATU-R is used in the case where the repeater is used and the case where the repeater is not used, the ATU-R has a conventional specification of maintaining the BER of 10 ⁻⁷ or less. desirable. That is, AT
It is desirable not to be aware of the presence of repeaters between UC and ATU-R.

Therefore, ATU-R has BE of 10 ^-7 or less.
While maintaining the conventional specifications of maintaining R, AT
In order to reduce the BER between UC and ATU-R to 10 ^-7 or less, the performance margin required for ATU-R is increased. At this time, BE at the repeater
The specification of R may be 10 ^-7 or less as usual, or 10
^It may be set to an appropriate value less than ^-7, but that value must be recognized in advance by the station side.

The increase in the performance margin required of the ATU-R when the insertion of the repeater is detected is taken into consideration in consideration of the BER specifications of the repeater held on the station side, and the ATU-C Between ATU and ATU-R
The station decides that R is 10 ^-7 or less. And
As shown in FIG. 7, the value is notified from the station side to the repeater 5 at the time of initialization between the station side and the repeater and held, and is held at the time of initialization between the repeater 5 and the subscriber performed thereafter. The above value is notified from the repeater to the subscriber side.

By doing so, an AD having a repeater
In SL, the value of the performance margin can be set so that a predetermined BER between subscribers can be maintained from the station side.

In the above-described embodiment, the case of ADSL as the DSL system has been described, but the present invention is not limited to this and can be applied to xDSL in general. (Supplementary Note 1) A relay method for an xDSL system, which uses a telephone line whose crosstalk noise amount periodically changes at a timing determined by the station side as a transmission line and has a relay, wherein the relay is a station side and a relay section. Initial training and data communication in the first step, and initial training and data communication between the repeater and the subscriber are performed using the crosstalk noise timing extracted from the communication with the station side.
L relay method.

(Supplementary Note 2) In an xDSL system having a repeater and a telephone line whose crosstalk noise amount periodically changes at a timing determined by the station side, the ITU-
TG. When performing the handshake specified in the 994.1 Recommendation, the repeater first performs the handshake between the repeater and the subscriber, maintains the capability list of the subscriber side device, and then disconnects the communication with the subscriber side. Then, the capability list of the subscriber side device is transmitted to the station side by performing handshake between the relay station and the station side, and then the xDSL relay method according to appendix 1.

(Supplementary Note 3) After the communication between the repeater and the station is established, the handshake between the repeater and the subscriber is performed again, and the repeater performs the communication method determined by the handshake between the repeater and the station. Note 2 characterized by holding and selecting the same communication method as the communication method between the repeater and the subscriber
The described xDSL relay method.

(Supplementary Note 4) In the xDSL system having the repeater, ITU-TG. 992.1 and G99
When carrying out the initialization specified in 2.2 Recommendation, the repeater retains the data transmission capacity determined by the initialization between the repeater and the station, and the initialization between the repeater and the subscriber is performed. When the calculated transmission capacity is larger than the transmission capacity between the repeater and the station, the transmission capacity between the repeater and the station is applied between the repeater and the subscriber, and the transmission between the repeater and the subscriber is possible. If the capacity is smaller than the transmission capacity between the repeater and the station, the transmission capacity between the repeater and the subscriber is maintained, and then the communication between the repeater and the subscriber and between the repeater and the station is temporarily disconnected. The xDSL relay method according to appendix 1, wherein the transmission capacity between the repeater and the station is limited to less than the transmittable capacity between the repeater and the subscriber when the initialization between the repeater and the station is performed again.

(Supplementary Note 5) ITU-TG. 992.1 and G.I. When the initialization specified in the 992.2 Recommendation is performed, the transmission capacity with the minimum transmission delay calculated by the initialization between the repeater and the subscriber is the minimum transmission delay logical channel between the repeater and the station. If it is less than the transmission capacity of the relay, hold the transmission capacity with the minimum transmission delay between the repeater and the subscriber, then temporarily disconnect the communication between the repeater and the subscriber and between the repeater and the station, and perform the relay again. In the initialization between the repeater and the station, the transmission capacity of the logical channel with the minimum transmission delay between the repeater and the station is limited to less than the transmission capacity with the minimum transmission delay between the repeater and the subscriber. The xDSL relay method described in 1.

(Supplementary Note 6) In the xDSL system having a repeater, the signal power transmitted from the repeater to the subscriber is varied based on the signal power received by the repeater from the subscriber unit at the start of initial training. The xDSL relay method described in Appendix 1.

(Supplementary Note 7) In the xDSL system having the repeater, the value of the performance margin capable of maintaining the required BER (bit error rate) is set at the station side at the time of initialization between the station side and the repeater. From the relay to the subscriber side, and notifies the subscriber of the above value held at the time of initialization between the relay and the subscriber performed thereafter. XDSL relay method.

[0084]

As described above, according to the present invention, the following effects can be obtained. (1) According to the invention of claim 1, ATU-C and AT
It is possible to provide an xDSL relay method capable of efficiently performing the procedure when a repeater is inserted between U and R by eliminating the influence of noise. (2) According to the invention of claim 2, the handshaking between the repeater and the subscriber side is performed first, and then the handshaking between the repeater and the station side is performed, so that the station side and the subscriber side as a whole. A handshake can be performed. (3) According to the invention described in claim 3, the same communication method can be set between the repeater and the station and between the repeater and the subscriber. (4) According to the invention described in claim 4, it is possible to balance the transmission capacities between the stations and the relays and between the relays and the subscribers. (5) According to the invention of claim 5, the transmission capacity of the minimum transmission delay logical channel between the repeater and the station can be limited to less than the transmission capacity at the minimum transmission delay between the repeater and the subscriber. .

Thus, according to the present invention, the ATU-C
XDS that can efficiently perform the procedure when a repeater is inserted between the ATU-R and the ATU-R by reducing the influence of noise
An L relay method can be provided.

[Brief description of drawings]

FIG. 1 is a flow chart showing the principle of the method of the present invention.

FIG. 2 is a diagram showing an initialization procedure for TTR synchronization.

FIG. 3 is a diagram showing a handshake execution procedure via a repeater.

FIG. 4 is an initialization state transition diagram.

FIG. 5 is a diagram showing a transmission rate determination flowchart.

FIG. 6 is an explanatory diagram of determining downlink transmission power of a repeater.

FIG. 7 is a diagram showing a method of notifying a performance margin.

FIG. 8 is a conceptual diagram of a conventional ADSL transmission system.

FIG. 9 is a conceptual diagram of a conventional ADSL transmission system having a repeater.

FIG. 10 is a diagram showing an outline of Annex C.

FIG. 11 is a timing chart of handshake and initialization.

FIG. 12 is a diagram showing transmission speed-distance characteristics.

FIG. 13: FEXT between ADSL and VDSL
FIG.

FIG. 14 is an explanatory diagram of a dual latency mode.

FIG. 15 is an explanatory diagram of a hyperframe structure.

[Explanation of symbols]

1 Station side ADSL device (ATU-C) 2 Subscriber side ADSL equipment (ATU-R) 5 repeaters

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Nobukazu Koizumi             4-1, Kamiodanaka, Nakahara-ku, Kawasaki-shi, Kanagawa             No. 1 within Fujitsu Limited (72) Inventor Kazutomo Hasegawa             4-1, Kamiodanaka, Nakahara-ku, Kawasaki-shi, Kanagawa             No. 1 within Fujitsu Limited F term (reference) 5K034 AA02 AA06 DD01 EE12 FF05                       FF10 FF11 HH06 KK03 LL01                       LL02                 5K101 LL01 MM01 SS04 TT08

Claims (5)

[Claims] 1. A relay method for an xDSL system, which uses a telephone line whose crosstalk noise amount periodically changes at a timing determined by the station side as a transmission line and has a relay, wherein the relay is the station side and the relay. Initial training and data communication between terminals (step 1), and initial training and data communication between the repeater and the subscriber using the crosstalk noise timing extracted from communication with the station side (step 2) An xDSL relay method characterized by: 2. The ITU-TG. When performing the handshake specified in the 994.1 Recommendation, the repeater first performs the handshake between the repeater and the subscriber to hold the capability list of the subscriber side device, and then communicates with the subscriber side. 2. The xDSL relay method according to claim 1, wherein the capability list of the subscriber side device is transmitted to the station side by performing a handshake between the relay side and the station side after disconnecting. 3. After the communication between the repeater and the station is established,
The handshake is performed again between the repeater and the subscriber, the repeater holds the communication method determined by the handshake between the repeater and the station, and selects the same communication method as the communication method between the repeater and the subscriber. The xDSL relay method according to claim 2, wherein 4. ITU-TG. 992.1 and G99
When performing the initialization specified in 2.2 Recommendation, the repeater holds the data transmission capacity determined by the initialization between the repeater and the station, and the initialization between the repeater and the subscriber is performed. If the transferable capacity calculated in step 1 is larger than the transfer capacity between the repeater and the station, apply the transfer capacity between the repeater and the station between the repeater and the subscriber to transfer between the repeater and the subscriber. When the available capacity is smaller than the transmission capacity between the repeater and the station, the transmission capacity between the repeater and the subscriber is maintained, and then the communication between the repeater and the subscriber and between the repeater and the station are temporarily disconnected. The xDSL relay according to claim 1, wherein the transmission capacity between the repeater and the station is limited to less than the transmittable capacity between the repeater and the subscriber in the initialization between the repeater and the station which is performed again. Method. 5. ITU-TG. 992.1 and G.I. 99
2.2 When performing the initialization specified in the Recommendation, the transmittable capacity with the minimum transmission delay calculated by the initialization between the repeater and the subscriber is the minimum transmission delay logical channel between the repeater and the station. If it is less than the transmission capacity of the relay, hold the transmission capacity with the minimum transmission delay between the repeater and the subscriber, then temporarily disconnect the communication between the repeater and the subscriber and between the repeater and the station, and perform the relay again In the initialization between the repeater and the station, the transmission capacity of the logical channel with the minimum transmission delay between the repeater and the station is limited to less than the transmission capacity with the minimum transmission delay between the repeater and the subscriber. The xDSL relay method according to Item 1.