JP2005184389A - Subscriber telephony system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To avoid interference between ISDN and xDSL caused by difference in line length between an ISDN subscriber and a subscriber for receiving xDSL service, even if DSLAM is set outside a station office. <P>SOLUTION: An ONC14 and a 0.4 kHz extraction circuit 20 are provided in the same feeder point B as DSLAM34 which is a digital circuit terminal installed outside, in a subscriber telephony system equipped with ISDN and xDSL. The ONC14 is a subscriber line terminal dedicated for 0.4 kHz extraction that branches ISDN data from an ONU12 in the feeder point B. The 0.4 kHz extraction circuit 20 extracts 0.4 kHz clock of ISDN reference signal from the ISDN data supplied from the ONC. The DSLAM transmits xDSL data to a xDSL circuit 35 in synchronous with the 0.4 kHz clock from the 0.4 kHz extracting circuit. Since, with this system, the distance between the feeder point and an ISDN subscriber house C and the distance between the feeder point and an xDSL subscriber house D are short, the clock with small phase difference is supplied. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a subscriber telephone system provided with ISDN and xDSL.

  In Annex C, which is Japan's original ADSL, in order to avoid interference between ISDN and xDSL, transmission is performed in synchronization with ISDN using DBM (Dual Bit Map). The frequency of the clock is 0.4 kHz of TCM (Time Compression Multiplexing) adopted by ISDN in Japan. However, since the transmission distance of ADSL is about several kilometers due to signal attenuation and attenuation in the ADSL line, there is a problem that the signal does not reach the subscriber's house if the clock supply device is installed in the station.

  In order to solve this problem, conventionally, in a communication system using ISDN and AnnexC or AnnexH system xDSL, the arrangement of the xDSL station apparatus is moved outside the station (for example, see Patent Document 1). In other words, in a system that transmits and receives digital signals using an xDSL line between a station building that uses both ISDN and xDSL and a subscriber's house, the xDSL station device is installed outside the station, and between the xDSL station device and the station A digital signal transmission data line and an ISDN line were provided, and the clock was supplied to the xDSL station apparatus via the ISDN line.

  In addition, in an optical VDSL node (ONU) in a VDSL (high-speed data transfer digital subscriber line) system, the reference signal source in a GPS or the like (SDH network or terrestrial transmission TV) is used to perform ONU synchronization and phase correction. There are known devices that eliminate near-end crosstalk based on the difference in distance between the ONU and the VDSL terminal (see, for example, Patent Document 2).

  In the VDSL system, the phase information of the 2 kHz clock signal extracted from the optical line and the identification information for reproducing the same frequency as this clock signal are incorporated into the STM-1 frame and transferred to each interface converter for interface conversion. There is also known a device that prevents a near-end crosstalk in a metallic cable connecting a VDSL modem by reproducing a clock signal from identification information and correcting the phase by phase information to synchronize the clock (for example, And Patent Document 3).

JP 2002-353948 (first page-fourth page, FIG. 2) Special Table 2002-506591 (1st page-8th page, Fig. 1) JP 2001-345773 (first page-second page, FIG. 1)

  However, in the clock supply system described in Patent Document 1, when a DSLAM (Digital Subscriber Line Access Multiplexer) is installed outside the station building at the feeder line, the ISDN station device in the station building is connected to the DSLAM installed outside the station building. 0.4kHz clock, but between the ISDN station equipment in the station and the ISDN subscriber, and between the ISDN station equipment in the station and the subscriber receiving xDSL service. Therefore, there is a problem in that there is a phase difference between 0.4 kHz supplied from the ISDN device in the station and 0.4 kHz that should be synchronized.

  Therefore, the object of the present invention is to prevent interference between ISDN and xDSL based on the difference in line length between an ISDN subscriber and a subscriber receiving xDSL service, even when a DSLAM is installed outside the office. It is an object of the present invention to provide a subscriber telephone system that can avoid the above problem.

  The invention described in Patent Document 2 reduces near-end crosstalk due to a difference in routes from different optical VDSL nodes to a common part of a cable in a VDSL system by clock phase correction. The present invention realizes simplification of the supply of a clock signal used to prevent near-end crosstalk in a metallic cable between an interface converter and a VDSL modem in a VDSL system. Is different.

  The invention described in Patent Document 2 and the invention described in Patent Document 3 are both for preventing near-end crosstalk between existing communication devices, but the present invention solves the problems up to that point. In order to solve this problem, the new problem caused by moving the arrangement of the xDSL station apparatus outside the office building is solved.

  In the subscriber telephone system in which ISDN and xDSL are provided side by side, the invention according to claim 1 is located within the same feeder line (B in FIG. 1) as the digital circuit terminating device (34 in FIG. 1) installed outdoors. A subscriber line terminator dedicated to 0.4 kHz extraction (14 in FIG. 1) for branching ISDN data from the ISDN terminator in the same feeder line (12 in FIG. 1), and ISDN data supplied from the subscriber line terminator And a 0.4 kHz extraction circuit (20 in FIG. 1) that extracts the 0.4 kHz clock of the ISDN reference signal from the digital line terminator, and the digital line terminator transmits xDSL data in synchronization with the 0.4 kHz clock from the 0.4 kHz extraction circuit. This is a subscriber telephone system characterized by the following.

  The present invention does not supply a 0.4 kHz clock from the ISDN station equipment in the station to supply a 0.4 kHz clock to the DSLAM installed outdoors, but on the same line point as the DSLAM installed outdoors. Use 0.4kHz extraction circuit from OCU for 0.4kHz extraction, and extract 0.4kHz. The DSLAM installed outdoors transmits xDSL data in synchronization with the 0.4 kHz clock from the 0.4 kHz extraction circuit.

  In the subscriber telephone system in which ISDN and xDSL are provided together, the invention according to claim 2 is the same as the same line point as the digital line terminator installed outdoors (34-1 in FIG. 2). Subscriber line termination device (14 in FIG. 2) dedicated to 0.4 kHz extraction for branching ISDN data from the ISDN termination device (12 in FIG. 2), and ISDN reference signal from ISDN data supplied from the subscriber line termination device The first 0.4 kHz extraction circuit (20 in FIG. 2) for extracting the 0.4 kHz clock of the digital circuit is provided, and the digital line terminator is an optical line (31 in FIG. 2) from the ATM-terminal equipment (30 in FIG. 2). ) To extract a 0.4 kHz clock from the second 0.4 kHz extraction circuit (32 in FIG. 2) and an adjustment phase adjustment circuit to adjust the phase of the clock to the phase of the clock extracted by the first 0.4 kHz extraction circuit (FIG. 2) 33) and send xDSL data in synchronization with the phase-adjusted clock Subscriber telephone system according to claim Rukoto.

  The present invention does not supply a 0.4 kHz clock from the ISDN station equipment in the station to supply a 0.4 kHz clock to the DSLAM installed outdoors, but on the same line point as the DSLAM installed outdoors. Use 0.4kHz extraction circuit from OCU for 0.4kHz extraction, and extract 0.4kHz. Then, the DSLAM installed outdoors has a phase adjustment circuit, and the 0.4kHz clock extracted from the OCU for 0.4kHz extraction using the extraction circuit and the 0.4kHz clock phase of the DSLAM installed outdoors. It adds the function of adjusting with the phase adjustment circuit of the DSLAM installed outdoors.

  The first effect of the present invention is that even when a DSLAM is installed outside a station, the ISDN and xDSL are based on the difference in line length between the ISDN subscriber and the subscriber receiving the xDSL service. Interference can be avoided.

  The reason is that the same clock or the phase-adjusted 0.4 kHz clock is supplied to the ISDN subscriber house and the xDSL subscriber house in the DSLAM installed outdoors at the feeder line.

  The second effect of the present invention is that when a DSLAM is installed outside a building, it is possible to easily extract 0.4 kHz which is an ISDN reference clock that is essential for Annex C and Annex H xDSL. is there.

  The reason is that when a DSLAM is installed outside the station building, there is no need to lay an ISDN line from the ISDN station device installed inside the station building to the DSLAM installed outside the station building. This is because by using an OCU dedicated to 0.4 kHz clock extraction and a 0.4 kHz extraction circuit, it is possible to easily extract 0.4 kHz, which is an ISDN reference clock, which is essential for Annex C and Annex H xDSL.

  The subscriber telephone system of the present invention is a subscriber telephone system in which ISDN and xDSL are provided side by side, within the same feeder line as the digital circuit terminator installed outdoors, and from the ISDN terminator in the same feeder line. A digital line terminator is provided with a subscriber line terminator dedicated to 0.4 kHz extraction for branching data and a 0.4 kHz extraction circuit for extracting a 0.4 kHz clock of the ISDN reference signal from ISDN data supplied from the subscriber line terminator. Transmits xDSL data in synchronization with the 0.4 kHz clock from the 0.4 kHz extraction circuit.

  Next, an embodiment of the subscriber telephone system of the present invention will be described with reference to the drawings.

  FIG. 1 shows an embodiment of a subscriber telephone system according to the present invention. The optical lines 11 and 31 are connected between the station A and the feeder line B, and the feeder line B and the ISDN subscriber's house C are ISDN lines. 15. The feeder line B and the xDSL subscriber house D are connected by an xDSL line 35. ISDN data on the ISDN line 15 is transmitted in synchronization with a 0.4 kHz clock.

  The optical line 11 on the ISDN side is terminated at a station A by a terminating device (referred to as OSU) 10 and at a feeder line B by an ISDN terminating device (referred to as ONU (Optical Network Unit)) 12. The ONU 12 is connected to the terminating device (denoted as DSU (Digital Service Unit)) 16 of the xDSL subscriber home D via the ISDN line 15 through the subscriber line terminating device (denoted as OCU (Office Channel Unit)) 13. The DSU 16 is connected to a PC 18 via a TA (Terminal Adapter) 17. The PC 18 can be used for internet connection. Thereby, the ISDN subscriber home C can receive an Internet service using ISDN.

  On the other hand, the optical line 31 on the xDSL side is terminated by an ATM-terminal station device 30 at the station A and by a DSLAM 34 which is an ADSL line termination device at the feeder line B. The DSLAM 34 is connected to a POTS SPLITTER 36 which is a data / voice separator in the subscriber's house D through an xDSL line 35. The POTS SPLITTER 36 is connected to the PC 38 and the telephone 39 directly via a CPE 37 such as a modem.

  When the xDSL subscriber home D receives the Internet service using the xDSL using the PC 38, the arrangement of the xDSL station device (here, the DSLAM 34 which is the ADSL line termination device) is moved out of the station. The limitation of the transmission distance due to the noise and attenuation of the signal in the xDSL line 35 can be eliminated. However, interference from the ISDN service implemented at the ISDN subscriber's home C causes the xDSL subscriber's home D, which is trying to receive an Internet service using xDSL, to be greatly affected.

  Therefore, in order to prevent ISDN interference in the XDSL subscriber's house D, 0.4 kHz is extracted from the OCU 14 in the feeder line B by the 0.4 kHz extracting circuit 20 and is located at the feeder point B through the clock supply line 21. Supplied to DSLAM 34. The DSLAM 34 transmits xDSL data to the xDSL line 35 in synchronization with this clock. Since the distance between feeder line B and ISDN subscriber house C and the distance between feeder point B and xDSL subscriber house D are small, ISDN received at ISDN subscriber house C and xDSL subscriber house D are received. The phase difference of xDSL data to be performed is very small. Thereby, in the xDSL subscriber house D, it is possible to avoid ISDN interference of the ISDN subscriber house C.

  FIG. 2 shows another embodiment of the subscriber telephone system of the present invention. In this embodiment, the DSLAM 34 in the embodiment shown in FIG. 1 is replaced with a DSLAM 34-1, and other configurations are not different from those in FIG.

  The DSLAM 34-1 includes a 0.4 kHz extraction circuit 32 and a phase adjustment circuit 33. The 0.4 kHz extraction circuit 32 extracts a 0.4 kHz clock from the optical line 31. The phase adjustment circuit 33 adjusts the phase of this clock to the phase with the clock from the 0.4 kHz extraction circuit 20, and transmits xDSL data to the xDSL line 35 in synchronization with the clock. As a result, the ISDN interference of the ISDN subscriber home C can be avoided in the xDSL subscriber home D as in the embodiment of FIG.

The block diagram which shows one Example of the subscriber telephone system of this invention The block diagram which shows the other Example of the subscriber telephone system of this invention

Explanation of symbols

10 OSU
11, 31 Optical line 12 ONU
13, 14 OCU
15 ISDN line 16 DSU
17 TA
18,38 PC
20, 32 0.4 kHz extraction circuit 21 Clock supply line 30 ATM-terminal station device 33 Phase adjustment circuit 34,34-1 DSLAM
35 xDSL line 36 POTS SPLITTER
37 CPE
39 Telephone

Claims (2)

In the subscriber phone system with ISDN and xDSL,
In the same line point as the digital circuit terminator installed outdoors,
A subscriber line terminator dedicated to 0.4 kHz extraction that branches ISDN data from the ISDN terminator in the same feeder line,
A 0.4 kHz extraction circuit that extracts a 0.4 kHz clock of an ISDN reference signal from ISDN data supplied from the subscriber line termination device;
A subscriber telephone system, wherein the digital line terminator transmits xDSL data in synchronization with a 0.4 kHz clock from a 0.4 kHz extraction circuit. In the subscriber phone system with ISDN and xDSL,
In the same line point as the digital circuit terminator installed outdoors,
A subscriber line terminator dedicated to 0.4 kHz extraction that branches ISDN data from the ISDN terminator in the same feeder line,
A first 0.4 kHz extraction circuit that extracts a 0.4 kHz clock of an ISDN reference signal from ISDN data supplied from the subscriber line termination device;
The digital line terminator includes a second 0.4 kHz extraction circuit that extracts a 0.4 kHz clock from an optical line from an ATM terminal device, and a clock phase extracted by the first 0.4 kHz extraction circuit. A subscriber telephone system comprising a phase adjustment circuit for adjusting to a phase and transmitting xDSL data in synchronization with a phase adjusted clock.

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