JP2000224211A - Sdh network - Google Patents

Abstract

PROBLEM TO BE SOLVED: To attain connection to a PDH network. SOLUTION: A PDH network consists of a loop PDH device 1, two connection loop PDH devices 3, 4 that are connected to the PDH device 1 via common interfaces, convert a multiplex signal in the unit of an HG path received from the loop type PDH device 1 into a multiplex signal in the unit of VC path, and a loop PDH device that switches the multiplex signal received from each of the connection loop PDH devices 3, 4 in the unit of an HG path on the basis of an HG alarm of the multiplex signal received from each of the connection loop PDH devices 3, 4 in the unit of the VC path to select a normal system.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to an SDH (Synchronous
ous Digital Hierarchy) network and PDH (Presi
ochronous Digital Hierarchy).

[0002]

2. Description of the Related Art Existing PDH networks have been constructed as loop-type systems, but have recently been shifting to SDH networks. However, in the conventional SDH network,
There are the following problems due to the difference in path management from the PDH network. That is, as shown in FIG. 1, the line management unit and the switching unit of the conventional loop-type PDH network are HG path units, whereas the path management unit and the path management unit of the SDH network conforming to ITU-T are used. The switching unit is a VC-2 path unit or a VC-11 path unit as shown in FIG.

[0003] Since the PDH network and the SDH network do not have path affinity as described above, the PDH network and the SDH network cannot be connected. When the PDH network is shifted to the SDH network, FIG. As shown in the figure, it is necessary to replace the entire system in units of loops, so that the initial cost is large and the relocation work is prolonged.

[0004] The present invention has been made in view of the above-mentioned problems, and has the following objects. (1) The PDH network and the SDH network can be connected or mixed. (2) The initial cost for replacing the PDH network with the SDH network is suppressed. (3) Relocation work when replacing the PDH network with the SDH network is shortened.

[0005]

In order to achieve the above-mentioned object, in order to achieve the above object, H connected to a loop type PDH device constituting a PDH network via a common interface and received from each loop type PDH device via the common interface.
Two connection loop-type PDH devices for converting a multiplexed signal for each G path into a multiplexed signal for each VC path and transmitting the multiplexed signal;
Based on the HG alarm of the multiplexed signal in VC path units received from each connection loop type PDH device, the multiplexed signal received from each connection loop type PDH device is switched in HG path units to establish a normal system. A means including a loop type PDH device to be selected is adopted. Further, in the above means, TTC G.G703 is used as a common interface.
It is preferable to employ a 6M electrical interface conforming to the standard.

[0006]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, an embodiment of an SDH network according to the present invention will be described with reference to the drawings.

FIG. 1 is a schematic diagram for explaining the present embodiment. In this figure, reference numeral 1 denotes a conventional loop type PDH.
Transmission device, 2 is a loop type SDH transmission device, 3 and 4 are 6M
Connection loop type PDH transmission devices having electric interfaces 3a and 4a, and connection loop type SDH transmission devices 5 and 6 also having 6M electric interfaces 5a and 6a. These 6M electrical interfaces 3a, 4a, 5
a and 6a are common interfaces having the same specifications, for example, 6M electrical interfaces conforming to TTC JT-G703.

The loop type PDH transmission apparatus 1 and the connection loop type PDH transmission apparatuses 3 and 4 constitute a PDH network, and the loop type PDH transmission apparatus 2
And the connection loop type SDH transmission device constitute an SDH network.

The loop type PDH transmission apparatus 1 is a connection loop type PDH transmission apparatus having a 6M electrical interface.
4, while the loop type SDH transmission device 2 is connected to connection loop type SDH transmission devices 5 and 6, respectively. The connection loop-type PDH transmission device 3 and the connection loop-type SDH transmission device 5 are interconnected via a 6M electrical interface provided in each of the connection loop-type PDH transmission device 4 and the connection loop-type PDH transmission device 4. The SDH transmission devices 6 are also connected to each other via a 6M electrical interface.

Further, the connection loop type PDH transmission devices 3 and 4 are provided with an HG alarm (HG REC, HG AIS or HG BAIS).
HG path switching function by detecting the The connection loop-type SDH transmission devices 5 and 6 multiplex and convert the lower-order data into duplex VC-2 or VC-1.
1 path VC path alarm (REC, FE detected with V5Byte of POH)
In addition to the conventional function of detecting and switching between RF and AIS, the dual HG path has a function of detecting and switching an HG alarm (HG REC, HG AIS or HG BAIS).

In such a configuration, the loop type PDH
When transmitting data from the network to the loop-type SDH network, the loop-type PDH transmission device 1 multiplexes lower-order data in units of HG paths and parallels the data to the connection loop-type PDH transmission devices 3 and 4 at a communication speed of 32 Mbps. Send. The connection loop type PDH transmission device 3 transmits the multiplexed signal multiplexed in units of HG paths to the connection loop type SDH transmission device 5 via the 6M electrical interface. Transmits the multiplexed signal multiplexed for each HG path to the connection loop type SDH transmission device 6 via the 6M electrical interface.

[0012] The connection loop type SDH transmission devices 5 and 6 that have received the multiplexed signal multiplexed in units of HG paths via the 6M electrical interface as described above extract the HG path from the multiplexed signal and convert it to the SDH. The data is converted into a network-compliant STM-0 path (50 Mbps) or an STM-1 path (150 Mbps) and transmitted to the loop type SDH transmission apparatus 2.

[0013] The loop type SDH transmission apparatus 2 receives an HG path HG alarm (HG REC, HG AIS or HG BAI) in the multiplexed signal received from each of the connection loop type SDH transmission apparatuses 5 and 6.
S) is monitored to select a normal system, and when the occurrence of an HG alarm of the selected system is detected, the selection is switched to another system.

On the other hand, when transmitting from the loop type SDH network to the loop type PDH network, the STM-0 path (50 Mbps) or the STM-1 path (150 Mbps) multiplexed in the HG path unit in the loop type SDH transmission apparatus 2. ) Is transmitted from the connection loop type SDH transmission device 5 to the connection loop type PDH transmission device 3 via the 6M electrical interface, and similarly from the connection loop type SDH transmission device 6 via the 6M electrical interface. The data is transmitted to the PDH transmission device 4.

The connection loop PDH transmission devices 3 and 4 respectively extract and multiplex HG paths, and
The multiplexed signal is transmitted to the loop type PDH transmission device 1 at a communication speed of bps. The loop-type PDH transmission apparatus 1 detects a HG alarm (HG REC, HG AIS, or HG BAIS), selects a normal HG path, and outputs it to a lower interface.

According to the present embodiment, the existing PDH network employs the HG path unit as the line management unit.
Even after the transfer to the H device, the line management of the SDH network becomes possible based on the same concept as the PDH network, and the system administrator can easily introduce the SDH network and make the transition.

Moreover, the loop-type PDH devices 3 and 4 and the loop-type SDH devices 5 and 6 communicate with each other using a common 6M electrical interface conforming to the TTC standard, so that the HG path in the PDH network can be connected to the SDH network. It is possible to connect to the HG path in the PDH
Line management across a network and an SDH network can be performed.

Until now, when replacing an existing loop-type PDH network with a loop-type SDH network, it is necessary to change all loop-type PDH devices to loop-type SDH devices, and the operation is suspended during a long construction period. However, it is necessary to replace a part of the existing loop-type PDH network with a loop-type SDH network, and gradually create a loop-type SDH network while utilizing the existing loop-type PDH transmission device. This makes it possible to shorten the network operation suspension period.

Further, even when a loop-type SDH network is extended to an existing loop-type PDH network, HG is performed more than path switching in units of VC paths.
Since the number of switching lines is smaller in the path unit, the influence range of the instantaneous interruption of data generated at the time of switching is smaller than in the VC unit.

Further, even after the transition to the SDH network as well as the coexistence with the PDH network, the line management for each HG path managed by the PDH network becomes possible. In addition, the HG path can relay a plurality of VC paths.

[0021]

As described above, according to the present invention, S
The DH network is connected to a loop type PDH device constituting the PDH network via a common interface, and multiplexes a HG path unit multiplex signal received from each loop type PDH device via the common interface in a VC path unit. Two connection loop-type PDH devices that convert the signals into signals and transmit the signals, and the respective connection loop-type PDH devices based on an HG alarm of a multiplex signal per VC path received from each connection loop-type PDH device. And a loop-type PDH device for selecting a normal system by switching the multiplexed signal received from the HG path unit, thereby enabling connection or coexistence with a PDH network. Therefore,
When the PDH network is switched to the SDH network, the PDH network can be gradually converted to the SDH network, so that the initial cost for replacing the PDH network with the SDH network can be suppressed and the relocation work can be shortened.

[Brief description of the drawings]

FIG. 1 is a schematic diagram showing a functional configuration of a conventional PDH network and generation of a multiplexed signal.

FIG. 2 is a schematic diagram showing a functional configuration of a conventional SDH network and generation of a multiplexed signal.

FIG. 3 is a schematic diagram for explaining a conventional problem.

FIG. 4 is a schematic diagram showing a functional configuration of an SDH network and generation of a multiplexed signal according to an embodiment of the present invention.

[Explanation of symbols]

1 Loop PDH transmission device 2 Loop SDH transmission device 3, 4 Loop PDH transmission device for connection 3a, 4a, 5a, 6a 6M electrical interface (common interface) 5, 6 Connection Loop Type SDH Transmission Equipment

────────────────────────────────────────────────── ───

[Procedure amendment]

[Submission date] April 19, 2000 (2004.1.
9)

[Procedure amendment 1]

[Document name to be amended] Statement

[Correction target item name] Claim 1

[Correction method] Change

[Correction contents]

[Procedure amendment 2]

[Document name to be amended] Statement

[Correction target item name] 0005

[Correction method] Change

[Correction contents]

[0005]

In order to achieve the above-mentioned object, in order to achieve the above object, H connected to a loop type PDH device constituting a PDH network via a common interface and received from each loop type PDH device via the common interface.
Two connection loop type SDH devices for converting a multiplexed signal per G path into a multiplexed signal per VC path and transmitting the multiplexed signal;
Based on the HG alarm of the multiplexed signal in VC path units received from each connection loop type SDH device, the multiplexed signal received from each connection loop type SDH device is switched in HG path units to establish a normal system. Means for selecting a loop type SDH apparatus . Further, in the above means, TTC G.G703 is used as a common interface.
It is preferable to employ a 6M electrical interface conforming to the standard.

[Procedure amendment 3]

[Document name to be amended] Statement

[Correction target item name] 0010

[Correction method] Change

[Correction contents]

Further, the loop type PDH transmission apparatus 1
It has a function of switching HG paths by detecting a G alarm (HG REC, HG AIS or HG BAIS). Loop type S
The DH transmission apparatus 2 multiplexes the lower-order data and performs a VC path alarm (POH) of a duplicated VC-2 or VC-11 path.
In addition to the conventional function of detecting and switching the REC, FERF or AIS detected by V5Byte of HG, a function of detecting and switching the redundant HG path by detecting the HG alarm (HG REC, HG AIS or HG BAIS) is provided.

[Procedure amendment 4]

[Document name to be amended] Statement

[Correction target item name] 0021

[Correction method] Change

[Correction contents]

[0021]

As described above, according to the present invention, S
The DH network is connected to a loop-type PDH device constituting the PDH network via a common interface, and multiplexes an HG path unit multiplex signal received from each loop-type PDH device via the common interface in VC path units. Two connection loop-type SDH devices that convert the signals into signals and transmit the signals, and each connection loop-type SDH device based on an HG alarm of a multiplex signal per VC path received from each connection loop-type SDH device. And a loop type SDH device for selecting a normal system by switching a multiplexed signal received from the HG path unit, thereby enabling connection or coexistence with a PDH network. Therefore,
When the PDH network is switched to the SDH network, the PDH network can be gradually converted to the SDH network, so that the initial cost for replacing the PDH network with the SDH network can be suppressed and the relocation work can be shortened.

 ──────────────────────────────────────────────────続 き Continuing from the front page (72) Inventor Yoshiyasu Abe Fukuda term in Miyagi NEC Co., Ltd. 2nd address, Yoshioka character, Yamato-cho, Kurokawa-gun, Miyagi Prefecture 5K028 AA07 CC06 KK05 5K031 AA06 AA12 CA08 CB05 CB12 DA06 DA12 DB14 EA12 EC04

Claims (2)

[Claims] 1. A loop type PDH device (3, 4) constituting a PDH network and a common interface (5a, 6)
a) and the common interface (5a,
6a) Two connection loop-type PDHs for converting the multiplexed signal for each HG path received from each of the loop-type PDH devices (3, 4) into a multiplexed signal for each VC path and transmitting the converted signal.
Based on the HG alarm of the multiplex signal for each VC path received from each of the connection loop type PDH devices (5, 6). And a loop-type PDH device (2) for selecting a normal system by switching the multiplexed signal received from the multiplexed signal in units of HG paths. 2. The common interface (5a, 6a)
The SDH network according to claim 1, wherein the SDH network is a 6M electrical interface compliant with TTC G.703.