JP3717460B2 - Network, network center and network device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a network, a network center, and a network device that are configured in a loop shape and capable of high-speed transmission.
[0002]
[Prior art]
The configuration of the network is in various forms depending on the line medium used. For example, networks using optical fibers as lines can be classified into the following three types.
1. In the single star type single star type configuration, one or two optical fiber cables are installed in a star shape in a one-to-one correspondence between the equipment center and each user, and an optical access system is installed in each user's home. It is a form and has a simple configuration.
2. The active double star type active double star type configuration is a configuration in which an active device (active element) having an optical / electrical conversion function and a demultiplexing function is installed between an equipment center and a user. The wiring is a metallic cable or a coaxial cable. Since the optical / electrical conversion function (active element) and the optical fiber can be shared by a plurality of users, the network can be constructed at a low cost, but the bandwidth for each user is limited. In addition, it is necessary to prepare an installation environment for operating the active device, to secure a driving power source, and to provide a backup battery.
3. The passive double star type passive double star type configuration is substantially the same as the active double star type described above, but an optical passive device such as an optical splitter (passive device) instead of an active device that performs optical / electrical conversion and multiplex transmission. ) For branching / multiplexing optical signals. Between the equipment center and the passive element, an optical transmission line in which user signals are multiplexed is configured. From the passive element to the user, an optical fiber is laid for each user as in the single star type. With this configuration, it is possible to construct an economical network by sharing the optical fiber with the subscriber corresponding part on the equipment center side and not using the active element.
[0003]
[Problems to be solved by the invention]
Here, an example of the current network configuration in the mobile telephone network is shown in FIG.
In FIG. 6, a base station BS3 and a base station BS4 that perform communication control of mobile stations in the area are accommodated in a telephone station 104, a base station BS2 is accommodated in a telephone station 103, and a base station BS1 and a base station BS8 are It is accommodated in the telephone station 102. Further, the base station BS5 and the base station BS6 are accommodated in the telephone station 106, and the base station BS7 is accommodated in the telephone station 105. The telephone station 104 is connected to the telephone station 103, the telephone station 106 is connected to the telephone station 105, and the telephone station 103 and the telephone station 105 are connected to the telephone station 102. Further, the telephone station 102 is connected to a network center 101 that performs network communication control. The line between the telephone stations is made of an optical fiber, and the line between the telephone station and the base station is made of an optical fiber or metallic / coaxial. In such a network, although the transmission speed of the line made of optical fiber can be increased, there is a problem that the line having the high transmission speed is not effectively used. Further, for example, when a failure occurs on the line between the telephone station 104 and the base station BS3, there is a problem that communication between the base station BS3 and the network center 101 becomes impossible. Further, for example, when a failure occurs in the line between the telephone station 105 and the telephone station 106, there is a problem that communication between the base station BS5 and the base station BS6 and the network center 101 becomes impossible.
[0004]
Therefore, the present invention effectively utilizes a high-speed transmission line constituting the network, and can prevent communication from being disabled even if a failure occurs on the line constituting the network. An object of the present invention is to provide a network center and a network device.
[0005]
[Means for Solving the Problems]
In order to achieve the above object, the network of the present invention is a network in which a high-speed transmission line is configured in a loop shape, and a multiplexed transmission line in which transmission lines as transmission units are multiplexed is transmitted. The uplink signal of the multiplexed transmission line inserted into the loop-shaped line and transmitted through the line is passed to the exchange and the downlink signal received from the exchange is sent to the multiplexed transmission line The network center that is multiplexed and sent to the line through both the clockwise route and the counterclockwise route, and is inserted into the loop-configured line and transmitted through the line. A plurality of network devices for extracting a specific transmission path from the multiplexed transmission path, multiplexing the specific transmission path to the multiplexed transmission path, and transmitting the multiplexed transmission path to the line; and connected to the network apparatus A base that receives the downlink signal of the specific transmission path extracted by the network apparatus and transmits the downlink signal to the mobile station, and sends the uplink signal received from the mobile station to the network apparatus as the signal of the specific transmission path The network device transmits the multiplexed transmission path to the network center through both a clockwise route and a counterclockwise route, and is assigned to each of the plurality of network devices. The transmission lines that are different from the transmission path of the clockwise route and the transmission route of the counterclockwise route are allocated, and each of the network devices has a counterclockwise route that has been transmitted through the line. Extracting a specific transmission path assigned counterclockwise from the multiplexed transmission path and multiplexing the specific transmission path on the multiplexed transmission path of the counterclockwise path A specific transmission line that is assigned in a clockwise direction from the multiplexed transmission line of the clockwise route that has been transmitted through the line, and is routed clockwise through the specific transmission line. Multiplexed to the multiplexed transmission path of the route of the route and sent to the line, the network center in the two multiplexed transmission lines that have been transmitted by the clockwise route and the counterclockwise route, Selection means for selecting and outputting a transmission path in a good transmission state for each transmission path, and correcting a delay time of the multiplexed transmission path based on a difference in path length between the clockwise path and the counterclockwise path And a delay correcting means for aligning the timings of the transmission paths sent through the clockwise route and the counterclockwise route, and a line connecting the network devices, or the network device And the above By detecting a failure of the line connecting the network center by sequentially performing a loopback test between the network center and each network device, the section where the line is disconnected is detected, and the network center is detected based on the detection result. The selection means provided is configured to select a transmission path that has been transmitted through a path in which no failure has occurred.
[0012]
According to the present invention as described above, since the network composed of loop-shaped lines capable of high-speed transmission is a network having a sufficient transmission band, the network is routed clockwise and / or counterclockwise on the network. It is possible to transmit multiplexed transmission lines. For this reason, when a failure occurs on a line, switching to a clockwise or counterclockwise route so that the route where the failure occurs is bypassed, so that the multiplexed transmission line can be connected without using the failure line. It can be transmitted. Therefore, communication between the base station and the network center can be ensured even if a failure occurs on the track. Also, the multiplexed transmission line can be transmitted clockwise and counterclockwise on the network, and a transmission line with a good transmission state can be selected for each transmission line. In this case, when a failure occurs on the line, it is possible to avoid the failure of the line by selecting a transmission path that has been transmitted clockwise or counterclockwise without being affected by the failure. .
[0013]
DETAILED DESCRIPTION OF THE INVENTION
FIG. 1 shows a schematic configuration of a network according to an embodiment of the present invention.
As shown in FIG. 1, the network of the present invention is configured by configuring a line made of an optical fiber 10 capable of transmission at a high transmission rate in a loop shape. The network configured in a loop by the optical fiber 10 accommodates a base station BS1, a base station BS2, a base station BS3, a base station BS4, a base station BS5, a base station BS6, a base station BS7, and a base station BS8. Yes. A network center 2 that controls communication of the network is inserted into a network that is configured in a loop shape by the optical fiber 10. Note that the base station BS1 to the base station BS8 are inserted between the optical fibers 10 via a network device to be described later.
[0014]
Next, FIG. 2 shows a specific configuration of the network according to the embodiment of the present invention. However, FIG. 2 shows an example in which base station 4, base station 6, and base station 8 are connected to the network.
The network center 2 and the network device 7 are connected by a two-core optical fiber 10, and a clockwise route 1 and a counterclockwise route 8 can be configured by the optical fiber 10. Similarly, the network device 7 and the network device 5 are connected by an optical fiber 10 that can form a clockwise route 2 and a counterclockwise route 7, and the network device 5 and the network device 3 are clockwise. The path 3 and the counterclockwise path 6 are connected by an optical fiber 10 that can be configured. Further, the network device 3 and the network center 2 are connected by an optical fiber 10 that can form a clockwise route 4 and a counterclockwise route 5. As described above, in the loop network shown in FIG. 2, a clockwise route 1 and a counterclockwise route 8 can be configured by the optical fiber 10.
[0015]
The network center 2 is connected to the exchange 1 of the telephone office, sends a signal received from the network to the exchange 1 through a predetermined interface, and uses the signal received from the exchange 1 as a multiplexed transmission line having a transmission rate necessary for the network. It is sent out on a network composed of optical fibers 10 connected in a loop. A base station 4 is connected to the network device 3 via a two-core optical fiber 11. Similarly, a base station 6 is connected to the network device 5 via an optical fiber 11, and a base station 8 is connected to the network device 7. Are connected by an optical fiber 11. The base stations 4, 6, and 8 receive the signals destined for the base stations 4, 6, and 8 extracted by the network devices 3, 5, and 7 from the network devices 3, 5, and 7, to the mobile stations that are located in the respective stations Are transmitted to the mobile station.
[0016]
Further, the uplink signals transmitted by the mobile station are received by the base stations 4, 6 and 8 located in the respective areas. The upstream signals from the base stations 4, 6, 8 are received by the network devices 3, 5, 7 via the optical fiber 11, respectively. In the network devices 3, 5, and 7, this uplink signal is multiplexed on the multiplexed transmission path and transmitted onto the optical fiber 10. The multiplexed transmission path for the upstream signal is sent to the network center 2, and the network center 2 sends the transmission path for the upstream signal to the exchange 1. The exchange 1 is connected to another exchange to which another network is connected, and thereby a mobile communication network is configured.
[0017]
Here, the transmission path means a transmission path of a predetermined band, for example, 1.5 Mbps, and this transmission path includes a plurality of communication channels. As this transmission path, a different transmission path is assigned in advance to each of the network devices 3, 5, and 7. Also, the transmission paths assigned to the network devices 3, 5, and 7 are assigned transmission paths having different transmission path numbers between the clockwise transmission path and the counterclockwise transmission path. For example, as shown in FIG. 5, when the multiplexed transmission line in the optical fiber 10 is an n transmission line of transmission line 1, transmission line 2,... Transmission path 1, counterclockwise is assigned transmission path (n-2), network apparatus 5 is assigned clockwise transmission line 2, transmission counterclockwise is assigned transmission path (n-1), and network apparatus 7 is clockwise transmission line. 3. The counterclockwise direction can be assigned transmission line n. Further, the transmission path 1 to the transmission path n are composed of m channels of channel 1 to channel m as shown in FIG. In the case of an ATM interface, the assigned transmission path can be a transmission path in units of VP (virtual path) or VC (virtual channel). Note that the transmission speed of the optical fiber 10 is a transmission speed with a margin that can assign a counterclockwise transmission path and a clockwise transmission path to a plurality of network devices on the network.
[0018]
The first transmission form in the network according to the present invention will be described below assuming that the transmission path is assigned to the network devices 3, 5, and 7 as described above. In the first transmission form, the network devices 3, 5, and 7 transmit the multiplexed transmission path to the network center 2 through either the clockwise or counterclockwise path. For example, the network device 5 and the network device 3 transmit the multiplexed transmission line obtained by multiplexing the assigned transmission line 1 and the transmission line 2 to the network center 2 through the clockwise route of the route 3 and the route 4, respectively. The network device 7 is configured to transmit a multiplexed transmission line obtained by multiplexing the assigned transmission line n to the network center 2 through the counterclockwise route of the route 8. The network center 2 transmits the downlink multiplexed transmission path to the network devices 3, 5, and 7 through clockwise and counterclockwise paths.
[0019]
In the first transmission mode, communication between the network devices 3, 5, 7 and the network center 2 can be performed without using a line between the network device 5 and the network device 7. Therefore, even when a failure occurs in the optical fiber 10 between the network device 5 and the network device 7, a communication path between the network devices 3, 5, and 7 and the network center 2 can be secured. Further, when a failure occurs in the optical fiber 10 between the network device 3 and the network device 5, the network device 5 switches from the route 3 to the route 7 and multiplexes the assigned transmission line (n-1). By sending the multiplexed transmission path in the counterclockwise direction, the path between the network devices 3, 5, 7 and the network center 2 can be secured.
[0020]
The second transmission form of the network according to the present invention will be described below assuming that the transmission path is assigned as described above. In the second transmission mode, the network apparatuses 3, 5, and 7 transmit the multiplexed transmission path obtained by multiplexing the transmission paths 1, 2, and 3 assigned in the clockwise path to the network center 2, and the counterclockwise A multiplexed transmission line obtained by multiplexing transmission lines (n−2), (n−1), and n assigned by the path is transmitted to the network center 2. However, the uplink signal contents of the transmission lines that are transmitted through the clockwise and counterclockwise paths in the network devices 3, 5, and 7 are common. Then, the network center 2 transmits, in the multiplexed transmission lines sent clockwise and counterclockwise, a transmission line with a good transmission state among the common counterclockwise and clockwise transmission lines for each transmission line. To select. In this case, the network center 2 also sends out multiplexed transmission paths for the network through clockwise and counterclockwise paths.
[0021]
In this second transmission mode, for example, when a failure occurs in the optical fiber 10 between the network device 5 and the network device 7, the network center 2 transmits the network device 7 along the counterclockwise route by the route 8. The multiplexed transmission path in which the transmission path n that has been multiplexed can be received, and the transmission paths 1 and 2 sent from the network devices 3 and 5 along the clockwise path through the paths 3 and 4 are multiplexed. Multiplexed transmission lines can be received. When a failure occurs in the optical fiber 10 between the network device 3 and the network device 5, the network center 2 transmits the transmission sent from the network devices 5 and 7 along the counterclockwise route by the routes 7 and 8. Multiplexed transmission in which a multiplexed transmission path in which the paths (n−1) and n are multiplexed can be received, and the transmission path 1 sent from the network device 3 through the clockwise route by the path 4 is multiplexed. The road can be received. In this way, the path between the network devices 3, 5, 7 and the network center 2 can be secured even in the event of a failure.
[0022]
Next, FIG. 3 shows a detailed configuration of the network center 2 according to the present invention.
The network center 2 receives the optical signal of the multiplexed transmission path of the counterclockwise path received from the optical fiber 10 by the light receiving / emitting element 2a, converts it into an electrical signal, and outputs it to the first selection unit 2c. Further, the optical signal of the multiplexed transmission path in the clockwise direction received from the optical fiber 10 is converted into an electric signal by the light receiving / emitting element 2b and output to the first selection unit 2d. In the following description, it is assumed that the transmission path shown in FIG. 5 is allocated to the network devices 3, 5, and 7 as described above. In the first transmission mode, the first selection units 2c and 2d respectively extract a plurality of transmission lines multiplexed on a high-speed (155 Mbps / 600 Mbps) multiplexed transmission line, and extract, for example, 1.5 Mbps or A plurality of transmission paths in units of VP / VC are output to the delay correction unit 2e. In the delay correction unit 2e, the delay time of the multiplexed transmission path is corrected based on the difference between the counterclockwise and clockwise path lengths, and the timings of the transmission paths sent through the counterclockwise and clockwise paths are aligned. It is output to the part 2f.
[0023]
The switch unit 2f selects an effective transmission line from among the plurality of transmission lines supplied from the delay correction unit 2e and outputs the selected transmission line to the second selection unit 2h. In this case, the effective transmission path means a transmission path including a significant signal. That is, in the network devices 3, 5, and 7, when there is no signal to be transmitted, a transmission path in which, for example, zero signals indicating that there is no significant signal is continuous is transmitted. In the second selection unit 2h, for example, a transmission path in units of 1.5 Mbps or VP / VC is multiplexed so as to match the interface with the exchange 1, and only a necessary line is output to the light receiving / emitting element 2i. ing. The light receiving / emitting element 2 i converts the supplied multiplexed transmission path into an optical signal and sends it to the optical fiber between the switch 1. The control unit 2g monitors and controls all devices in the network, and the control unit 2g performs a loopback test between the network center 2 and the network device 3 when one of the lines is disconnected. A section in which the line is disconnected is detected by sequentially performing a loopback test between the network center 2 and the network device 5 and a loopback test between the network center 2 and the network device 7. And based on this detection result, the transmission line selected in the switch part 2f is controlled.
[0024]
In the case of the second transmission mode, the transmission path 1 extracted by the first selection section 2c in the switch section 2f, and the transmission path (n-2) extracted by the first selection section 2d A transmission path with a good transmission state is selected. Similarly, the transmission path 2 and the transmission path (n-1), the transmission path 3 and the transmission path n are compared, and a transmission path in a good transmission state is selected. Then, when one of the lines is disconnected, the control unit 2g performs the loopback test as described above to detect the section where the line is disconnected, and based on the detection result, the switch unit 2f Controls the selected transmission path.
[0025]
Next, a detailed configuration of the network devices 3, 5, and 7 according to the present invention is shown in FIG. The network devices 3, 5, and 7 have the same configuration, and the light receiving / emitting element a-1 converts the multiplexed transmission line transmitted clockwise to an optical signal and sends it to the optical fiber 10. At the same time, the optical signal of the multiplexed transmission line transmitted counterclockwise is converted into an electrical signal and output to the first selection unit b-1. The light receiving / emitting element a-2 converts the multiplexed transmission path transmitted counterclockwise into an optical signal and sends it to the optical fiber 10 and also transmits the optical signal of the multiplexed transmission path transmitted clockwise. It converts into a signal and outputs it to the 1st selection part b-2. In the following description, it is assumed that the transmission path shown in FIG. 5 is allocated to the network devices 3, 5, and 7 as described above. In the first selection units b-1 and b-2, transmission lines assigned to the network device are extracted from a plurality of transmission lines multiplexed in a high-speed (155 Mbps / 600 Mbps) multiplexing transmission line. For example, the extracted transmission path of 1.5 Mbps or VP / VC is output to the switch unit c.
[0026]
The switch unit c selects an effective transmission line from the transmission lines supplied from the first selection units b-1 and b-2 and outputs the selected transmission line to the second selection unit d. In this case, the effective transmission path is a transmission path that includes a significant downlink signal in the first transmission form, and is a transmission line that has a good transmission state in the second transmission form. In the second selection unit d, for example, a transmission path in units of 1.5 Mbps or VP / VC is multiplexed so as to match the interface between the base stations 4, 6, and 8, and only necessary lines are optically received and transmitted. It outputs to the element a-3. The light receiving / emitting element a-3 converts the supplied multiplexed transmission line into an optical signal and sends it out onto the optical fiber 11.
[0027]
Further, the upstream optical signal transmitted from the base stations 4, 6, and 8 is converted into an electrical signal by the light receiving / emitting element a-3 and output to the second selection unit d for the second selection. In part d, the transmission path is 1.5 Mbps or VP / VC units. This transmission path is supplied to the switch section c, and in the case of the first transmission form, is output to the first selection section b-1 or the first selection section b-2 according to the set path. That is, when a clockwise route is set, it is output to the first selection unit b-1, and when a counterclockwise route is set, it is output to the first selection unit b-2. In the first selection unit b-1 or the first selection unit b-2 to which the transmission path is supplied, the supplied transmission path is multiplexed on the multiplexed transmission path and output. For example, in the case of the network device 3, the transmission path 1 {transmission path (n-2)} is demultiplexed by the first selection unit b-2 (first selection unit b-1), and transmission paths 2 and 3 {transmission Along with the paths (n−1), n}, the first selection unit b-1 (first selection unit b-2) multiplexes the multiplexed transmission path. The light receiving / emitting element a-1 or the light receiving / emitting element a-2 supplied with the multiplexed transmission path output from the first selecting section b-1 or the first selecting section b-2 uses the multiplexed transmission path as an optical signal. And sent to the optical fiber 10 in the clockwise or counterclockwise path.
[0028]
In the case of the second transmission mode, the transmission path output from the switch unit c is output to the first selection unit b-1 and the first selection unit b-2. Then, the first selection unit b-1 and the first selection unit b-2 to which the transmission path is supplied multiplex and output the multiplexed transmission path. For example, in the case of the network device 3, together with the transmission paths 2 and 3 demultiplexed by the first selection unit b-2, the transmission path 1 is multiplexed by the first selection unit b-1 to be a multiplexed transmission path, The transmission path (n-2) is multiplexed by the first selection section b-2 to be a multiplexed transmission path together with the transmission paths (n-1) and n demultiplexed by the first selection section b-1. become. The light receiving / emitting element a-1 and the light receiving / emitting element a-2 supplied with the multiplexed transmission lines output from the first selecting unit b-1 and the first selecting unit b-2 use the multiplexed transmission line as an optical signal. And sent to the optical fiber 10 in the clockwise or counterclockwise path.
[0029]
Further, the control unit e monitors the multiplexed transmission lines received by the light receiving and emitting elements a-1 and a-2, and in the first transmission mode, the control unit e has received the multiplexed light received so far. When the transmission line is no longer detected, it is detected that the line to which the light receiving and emitting elements a-1 and a-2 are connected is disconnected. Then, based on the detection result, the selection of the switch section c is switched so as to be reversed, and if it is clockwise (counterclockwise) up to now, a counterclockwise (clockwise) path is selected.
[0030]
In the network of the present invention described above, an arbitrary number of network devices can be inserted into the optical fiber 10 configured in a loop shape. Further, the transmission speed of the optical fiber 10 is not limited to 155 Mbps / 600 Mbps, and may be any transmission speed that can assign a counterclockwise transmission path and a clockwise transmission path to all network devices on the network.
In the above description, the optical fiber 10 and the optical fiber 11 are described as having two cores, but may be one core. In this case, the wavelengths of the counterclockwise route and the clockwise route, and the wavelengths of the uplink and the downlink may be changed. Further, a metal line may be used instead of the optical fiber 11.
[0031]
By the way, the network according to the present invention can construct a large-scale network composed of a plurality of unit networks with the network shown in FIG. 1 or 2 as a unit network. In this case, the network centers 2 in the unit network are connected to each other. Therefore, when it is desired to further increase the scale of the network, a new unit network is added and the network center 2 in the unit network is connected to the network center 2 of the existing unit network, so that the scale of the network can be easily increased. Will be able to.
[0032]
【The invention's effect】
As described above, the network consisting of loop-shaped lines capable of high-speed transmission is a network with a sufficient transmission band, so multiplexed transmission is performed on the network in the clockwise and / or counterclockwise directions. It is possible to transmit the route. For this reason, when a failure occurs on a line, switching to a clockwise or counterclockwise route so that the route where the failure occurs is bypassed, so that the multiplexed transmission line can be connected without using the failure line. It can be transmitted. Therefore, communication between the base station and the network center can be ensured even if a failure occurs on the track. Also, the multiplexed transmission line can be transmitted clockwise and counterclockwise on the network, and a transmission line having a good transmission state can be selected for each transmission line. In this case, when a failure occurs on the line, it becomes possible to avoid the failure of the line by selecting a transmission path that has been transmitted clockwise or counterclockwise without being affected by the failure. .
[Brief description of the drawings]
FIG. 1 is a diagram showing a schematic configuration of a network according to an embodiment of the present invention.
FIG. 2 is a diagram showing a specific configuration of a network according to the embodiment of the present invention.
FIG. 3 is a diagram showing a configuration of a network center according to an embodiment of a network according to the present invention.
FIG. 4 is a diagram showing a configuration of a network device according to an embodiment of a network according to the present invention.
FIG. 5 is a diagram showing a configuration of a multiplexed transmission line in the network according to the embodiment of the present invention.
FIG. 6 is a diagram showing a configuration of a conventional network.
[Explanation of symbols]
1 switch, 2 network center, 2a light receiving / emitting device, 2b light receiving / emitting device, 2c first selection unit, 2d first selection unit, 2e delay correction unit, 2f switch unit, 2g control unit, 2h second selection unit, 2i light receiving and emitting element, 3 network device, 4 base station, 5 network device, 6 base station, 7 network device, 8 base station, 10 optical fiber, 11 optical fiber, 101 network center, 102 telephone station, 103 telephone station, 104 telephone office, 105 telephone office, 106 telephone office, a-1, a-2, a-3 light receiving and emitting element, b-1, b-2 selection section, c switch section, d selection section, e control section

Claims (1)

A network in which a transmission line capable of high-speed transmission is configured in a loop shape and a multiplexed transmission line that is a transmission unit multiplexed is transmitted,
The multiplexed signal is inserted into the loop-shaped line, and the uplink signal of the multiplexed transmission line transmitted through the line is passed to the exchange, and the downlink signal received from the exchange is sent to the multiplexed transmission line. A network center that multiplexes and sends to the line by both the clockwise and counterclockwise paths;
A specific transmission line is extracted from the multiplexed transmission line inserted into the loop-shaped line and transmitted through the line, and the specific transmission line is multiplexed on the multiplexed transmission line. A plurality of network devices for sending to the line;
Connected to the network apparatus, receives the downlink signal of the specific transmission path extracted by the network apparatus and transmits it to the mobile station, and transmits the uplink signal received from the mobile station to the signal of the specific transmission path A base station for sending to the network device,
The network device transmits the multiplexed transmission path to the network center through both a clockwise path and a counterclockwise path,
The transmission path assigned to each of the plurality of network devices is assigned a different transmission path between a clockwise transmission path and a counterclockwise transmission path. A specific transmission path assigned in a counterclockwise direction is extracted from the multiplexed transmission path of the counterclockwise path that has been transmitted, and the specific transmission path is multiplexed on the multiplexing transmission path of the counterclockwise path. And extracting a specific transmission line assigned in a clockwise direction from the multiplexed transmission line of the clockwise route that has been transmitted through the line and moving the specific transmission line to the right. Multiplexed to the multiplexed transmission path of the route around and sent to the line,
The network center includes
In the two multiplexed transmission lines transmitted by the clockwise route and the counterclockwise route, selection means for selecting and outputting a transmission line in a good transmission state for each transmission line;
The timing of the transmission path sent through the clockwise path and the counterclockwise path by correcting the delay time of the multiplexed transmission path based on the difference in path length between the clockwise path and the counterclockwise path And delay correction means for aligning,
The line is formed by sequentially performing a loopback test between the network center and each network device for a failure in the line connecting the network devices or the line connecting the network device and the network center. The section that has been disconnected is detected, and based on the detection result, the selection means provided in the network center selects a transmission path that has been transmitted through a path in which no failure has occurred. A network characterized by

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