JP3656743B2 - Communication network and communication device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a high-speed and large-capacity optical network and a node device constituting the same, and in particular, a network having a redundant function in a transmission line, and a node device that separates a signal from the transmission line and inserts a signal into the transmission line About.
[0002]
[Prior art]
With the spread of the Internet, it is desired to realize an optical network that efficiently accommodates packet data, not voice data, has a high transmission speed, a large transmission capacity, and high reliability at a low cost.
[0003]
An optical ring network is known as a high-speed and large-capacity network with high reliability. The optical ring network is a ring network in which a plurality of node devices are connected by optical fibers. A node device constituting an optical ring network is an Add / Drop multiplexer (hereinafter referred to as an ADM device) having a function of inserting a signal such as packet data into a transmission line and separating a signal from the transmission line. .
[0004]
In order to ensure reliability against failures, an optical ring network can be used to detect failure points by looping back transmission paths or switching routes when various types of failures such as optical fiber breaks, optical transmitter failures, and optical receiver failures occur. It has the function (henceforth a protection function) which isolate | separates and restores communication.
[0005]
An example of a physical layer of an optical ring network is one using a SONET / SDH frame. In SONET / SDH, since a protection function for a transmission line failure is defined, communication can be restored by this function when a transmission line failure occurs.
[0006]
Specifically, the transmission side ADM device adds information for network management (information such as transmission path failure and quality, automatic switching control (APS), etc.) to the specific field of the SONET / SDH frame overhead and transmits it. Then, the overhead is analyzed by the SONET / SDH termination circuit of the ADM device on the receiving side to detect a transmission path failure and quality deterioration, and the path is automatically switched.
[0007]
Many SONET / SDH ADM apparatuses perform switching at an electric signal portion after an optical signal is converted into an electric signal. However, there is also an ADM device that performs path switching in an optical signal portion using an optical switch.
[0008]
Another example of the physical layer of the optical ring network is 10 Gbps Ethernet WAN-PHY, which is being standardized by IEEE (The Institute and Electronics Engineers) 802.3ae. This is based on a SONET / SDH frame and aims to realize a low-cost network by using only the minimum function of the overhead. Therefore, the 10 Gbps Ethernet WAN PHY does not include a path switching function defined as SONET / SDH and relies on higher layer functions for path switching for a transmission path failure.
[0009]
[Problems to be solved by the invention]
In a SONET / SDH network, since automatic switching control is performed between ADM devices using the overhead of a SONET / SDH frame, it is possible to restore communication by switching the path in a short time from the occurrence of a transmission path failure.
[0010]
However, a SONET / SDH ADM device having a function of adding overhead information to network management and transmitting it, analyzing overhead and detecting transmission path failures and quality degradation, and automatically switching the path In order to realize those functions, it is expensive.
[0011]
Further, when an optical switch is used for path switching, the optical signal is looped back, so that the distance over which the optical signal is transmitted is longer than that during normal operation. As the transmission distance becomes longer, the degradation of the S / N ratio due to dispersion and loss in the optical fiber becomes larger. For this reason, an electro-optical converter (hereinafter referred to as E / O) is required to have high output and high dispersion resistance, and an opto-electric converter (hereinafter referred to as O / E) is required to have high reception sensitivity. The cost of the ADM device is further increased.
[0012]
On the other hand, a device with a reduced overhead processing function, such as an ADM device using 10 Gbps Ethernet WAN-PHY, is less expensive than a SONET / SDH ADM device. Such an apparatus relies on higher layer functions for path switching in response to a transmission path failure. For example, a faulty route is not used as a result of the route selection function of the LAN-connected device located in the upper layer.
[0013]
However, the route selection function based on the upper layer function does not directly switch the route by detecting the failure of the transmission path, so it takes time until the route is not used after the failure occurs. The time during which communication is not possible increases.
[0014]
An object of the present invention is to provide a network and a node device that are low in cost and have a short time from the occurrence of a failure to the restoration of communication.
[0015]
[Means for Solving the Problems]
In order to achieve the above object, the communication network of the present invention is a communication network in which three or more nodes are connected in a double ring shape with an active transmission line and a backup transmission line,
The high-speed signal from the working transmission line on the receiving side is separated into a plurality of low-speed signals, and a plurality of low-speed signals are multiplexed and transmitted to the working transmission line on the transmitting side as high-speed signals. When a failure is detected, an active demultiplexing unit that stops each low-speed signal that has separated the high-speed signal of the reception-side active transmission path, and a high-speed signal from the standby-side transmission path of the reception side are separated into a plurality of low-speed signals. When the low-speed signal from the standby demultiplexing unit stops and the spare demultiplexing unit that multiplexes the low-speed signal and transmits it to the transmission line on the transmission side stops, the low-speed signal from the standby demultiplexing unit is addressed to itself A switch unit for capturing a signal and stopping transmission of a high-speed signal to the working transmission line on the transmitting side by stopping transmission of the low-speed signal multiplexed on the working transmission line on the transmitting side to the working demultiplexing unit; A first node;
The high-speed signal from the working transmission line on the receiving side is separated into a plurality of low-speed signals, and a plurality of low-speed signals are multiplexed and transmitted to the working transmission line on the transmitting side as high-speed signals. When the received high-speed signal is stopped, the working demultiplexing unit that stops each low-speed signal obtained by separating the high-speed signal of the receiving-side active transmission path, and the high-speed signal from the receiving-side backup transmission path is converted into a plurality of low-speed signals. When the low-speed signal from the standby demultiplexing unit stops and the low-speed signal from the active demultiplexing unit stops, the low-speed signal from the standby demultiplexing unit A switch for stopping transmission of a high-speed signal to the working transmission line on the transmitting side by capturing a signal addressed to itself from the mobile station and stopping transmission of the low-speed signal multiplexed on the working transmission line on the transmitting side to the working demultiplexing unit Have a part It has a second node.
[0016]
Therefore, when the first node detects a failure in the transmission path, the first node changes its own path, stops transmission of signals to the second node, and causes the second node to change the path.
[0017]
Further, when the node has the functions of the first node and the second node, and a failure occurs in any of the working transmission lines, the node that detected the failure operates as the first node, and the other It is preferable that all of the nodes operate as the second node so that communication between all of the nodes is performed on the backup transmission path.
[0018]
Another communication network according to the present invention is a double ring communication network in which three or more nodes are connected by active transmission lines and backup transmission lines in which the sections between the nodes are different in the direction of signal flow. There,
The high-speed signal from the working transmission line on the receiving side is separated into a plurality of low-speed signals, and a plurality of low-speed signals are multiplexed and transmitted to the spare transmission line on the transmitting side as a high-speed signal. When a failure is detected, a first demultiplexing unit that stops each low-speed signal obtained by separating the high-speed signal on the reception-side active transmission line, and a high-speed signal from the standby-side transmission line on the reception side are separated into a plurality of low-speed signals, A second demultiplexing unit that multiplexes a plurality of low-speed signals and transmits them as high-speed signals to the transmission transmission line on the transmission side, and when the low-speed signals from the first demultiplexing unit stop, Stop transmission of the low-speed signal multiplexed on the transmission path to the first demultiplexing unit, capture the signal addressed to itself from the low-speed signal from the second demultiplexing unit, A switch unit that turns back to the second demultiplexing unit as a low-speed signal Make A first node;
A first demultiplexer that separates a high-speed signal from a reception-side active transmission path into a plurality of low-speed signals, multiplexes the plurality of low-speed signals, and transmits the result as a high-speed signal to a transmission-side backup transmission path; The high-speed signal from the auxiliary transmission line on the side is separated into a plurality of low-speed signals, and a plurality of low-speed signals are multiplexed and transmitted to the active transmission line on the transmission side as a high-speed signal. When the high-speed signal to be stopped is stopped, the second demultiplexing unit that stops each low-speed signal that has separated the high-speed signal of the reception-side spare transmission path, and when the low-speed signal from the second demultiplexing unit is stopped, A switching unit that folds back a signal other than the address of the low-speed signal from the first demultiplexing unit to the first demultiplexing unit as a low-speed signal; It has a second node.
[0019]
Further, when the node has the functions of the first node and the second node, and a failure occurs in any of the working transmission lines, the node that detects the failure operates as the first node, When a node that has transmitted a signal to the working transmission line in which the failure has occurred operates as the second node, communication is performed on the working transmission line and the standby transmission line other than the section in which the failure has occurred. It is preferable.
[0020]
Still another communication network of the present invention is a communication network in which three or more nodes are connected in a double ring shape with an active transmission line and a standby transmission line, and transmits and receives a wavelength-multiplexed signal.
The high-speed signal from the working transmission line on the receiving side is separated into a plurality of low-speed signals, and a plurality of low-speed signals are multiplexed and transmitted to the working transmission line on the transmitting side as high-speed signals. When a failure is detected, an active demultiplexing unit that stops each low-speed signal that has separated the high-speed signal of the reception-side active transmission path, and a high-speed signal from the standby-side transmission path of the reception side are separated into a plurality of low-speed signals. When the low-speed signal from the standby demultiplexing unit stops and the spare demultiplexing unit that multiplexes the low-speed signal and transmits it to the transmission line on the transmission side stops, the low-speed signal from the standby demultiplexing unit is addressed to itself Each of the switch unit that captures a signal and stops transmission of a high-speed signal to the working transmission line on the transmitting side by stopping transmission of the low-speed signal multiplexed on the working transmission line on the transmitting side to the working demultiplexing unit Multiple for each wavelength A first node;
The high-speed signal from the working transmission line on the receiving side is separated into a plurality of low-speed signals, and a plurality of low-speed signals are multiplexed and transmitted to the working transmission line on the transmitting side as high-speed signals. When the received high-speed signal is stopped, the working demultiplexing unit that stops each low-speed signal obtained by separating the high-speed signal of the receiving-side active transmission path, and the high-speed signal from the receiving-side backup transmission path is converted into a plurality of low-speed signals. When the low-speed signal from the standby demultiplexing unit stops and the low-speed signal from the active demultiplexing unit stops, the low-speed signal from the standby demultiplexing unit A switch for stopping transmission of a high-speed signal to the working transmission line on the transmitting side by capturing a signal addressed to itself from the mobile station and stopping transmission of the low-speed signal multiplexed on the working transmission line on the transmitting side to the working demultiplexing unit For each wavelength Multiple Yes It has a second node.
[0021]
Therefore, when the first node detects a failure of a specific wavelength in the transmission path, it switches its own internal path for that wavelength, and stops the transmission of signals to the second node to change the path.
[0022]
In addition, when the node has the functions of the first node and the second node and a failure of at least one wavelength occurs in any of the active transmission lines, the node that has detected the failure is the first node. It is preferable that all the other nodes operate as the second node, so that the wavelength communication between all the nodes is performed on the backup transmission path.
[0023]
In still another communication network of the present invention, three or more nodes are connected by active transmission lines and backup transmission lines having different signal flow directions in each section between the nodes, and transmit / receive wavelength-multiplexed signals. A double ring communication network,
The high-speed signal from the working transmission line on the receiving side is separated into a plurality of low-speed signals, and a plurality of low-speed signals are multiplexed and transmitted to the spare transmission line on the transmitting side as a high-speed signal. When a failure is detected, a first demultiplexing unit that stops each low-speed signal obtained by separating the high-speed signal on the reception-side active transmission line, and a high-speed signal from the standby-side transmission line on the reception side are separated into a plurality of low-speed signals, A second demultiplexing unit that multiplexes a plurality of low-speed signals and transmits them as high-speed signals to the transmission transmission line on the transmission side, and when the low-speed signals from the first demultiplexing unit stop, Stop transmission of the low-speed signal multiplexed on the transmission path to the first demultiplexing unit, capture the signal addressed to itself from the low-speed signal from the second demultiplexing unit, A switch unit that folds back as a low-speed signal to the second demultiplexing unit; A plurality have a respective each wavelength A first node;
A first demultiplexer that separates a high-speed signal from a reception-side active transmission path into a plurality of low-speed signals, multiplexes the plurality of low-speed signals, and transmits the result as a high-speed signal to a transmission-side backup transmission path; The high-speed signal from the auxiliary transmission line on the side is separated into a plurality of low-speed signals, and a plurality of low-speed signals are multiplexed and transmitted to the active transmission line on the transmission side as a high-speed signal. When the high-speed signal to be stopped is stopped, the second demultiplexing unit that stops each low-speed signal that has separated the high-speed signal of the reception-side spare transmission path, and when the low-speed signal from the second demultiplexing unit is stopped, There are a plurality of switch units for each wavelength that fold signals other than the self addressed among the low-speed signals from the first demultiplexing unit to the first demultiplexing unit as low-speed signals. It has a second node.
[0024]
In addition, when the node has the functions of the first node and the second node and a failure of at least one wavelength occurs in any of the active transmission lines, the node that has detected the failure is the first node. And the wavelength of the wavelength in the active transmission line and the standby transmission line other than the faulty section is that the node transmitting the signal to the faulty active transmission line operates as the second node. It is preferable that communication is performed.
[0025]
The communication device of the present invention is a communication device that is connected in a double ring shape on the active and backup transmission lines to form a communication network,
The high-speed signal from the working transmission line on the receiving side is separated into a plurality of low-speed signals, and a plurality of low-speed signals are multiplexed and transmitted to the working transmission line on the transmitting side as high-speed signals. An active demultiplexing unit that stops each low-speed signal that has separated the high-speed signal of the reception-side active transmission line when a failure is detected and when the high-speed signal received from the reception-side active transmission line is stopped;
A demultiplexing unit that separates a high-speed signal from a reception-side spare transmission path into a plurality of low-speed signals, multiplexes a plurality of low-speed signals, and transmits the multiplexed signals to the transmission-side spare transmission path;
When the low-speed signal from the working demultiplexing unit stops, the working demultiplexing of the low-speed signal that is taken in from the low-speed signal from the backup demultiplexing unit and is multiplexed on the transmission transmission line on the transmission side A switch unit for stopping transmission to the unit.
[0026]
Therefore, when a failure in the working transmission line is detected, the signal transmitted through the transmission line is stopped at the working demultiplexing unit that has detected the failure, the switching unit is changed, and the switching unit The signal transmitted to the working transmission line is stopped, and the other communication apparatus is caused to change the path.
[0027]
Further, a plurality of the active demultiplexing unit, the backup demultiplexing unit, and the switch unit may be provided for each wavelength, and a wavelength-multiplexed signal may be transmitted and received.
[0028]
Another communication device according to the present invention is a communication device that forms a communication network by being connected in a double ring shape with active and standby transmission paths having different signal flow directions, and is connected to the receiving-side active transmission path. A high-speed signal is separated into a plurality of low-speed signals, and a plurality of low-speed signals are multiplexed and transmitted as a high-speed signal to a spare transmission path on the transmission side. A first demultiplexing unit that stops each low-speed signal obtained by separating the high-speed signal of the current transmission line;
The high-speed signal from the standby transmission line on the reception side is separated into a plurality of low-speed signals, and a plurality of low-speed signals are multiplexed and transmitted to the active transmission line on the transmission side as a high-speed signal. When the received high-speed signal is stopped, a second demultiplexing unit that stops each low-speed signal obtained by separating the high-speed signal of the reception side spare transmission path;
When the low-speed signal from the first demultiplexing unit stops, transmission of the low-speed signal multiplexed on the transmission side backup transmission path to the first demultiplexing unit is stopped, and the second demultiplexing unit When the low-speed signal from the second demultiplexing unit stops, the signal destined for itself is taken in from the low-speed signal of the other, the signal other than the self-addressed signal is turned back to the second demultiplexing unit as a low-speed signal. A switching unit that folds back a signal other than the one addressed to itself among the low-speed signals from the demultiplexing unit to the first demultiplexing unit as a low-speed signal.
[0029]
Therefore, when a failure in the working transmission line is detected, the signal transmitted through the transmission line is stopped at the working demultiplexing unit that has detected the failure, the switching unit is changed, and the switching unit The signal transmitted to the backup transmission path is stopped, and the other communication apparatus is caused to change the path.
[0030]
Further, a plurality of the first demultiplexing unit, the second demultiplexing unit, and the switch unit may be provided for each wavelength, and a wavelength-multiplexed signal may be transmitted and received.
[0033]
DETAILED DESCRIPTION OF THE INVENTION
When an Add / Drop multiplexer (hereinafter referred to as an ADM device) of the present invention detects a transmission path failure such as an optical signal disconnection, it immediately disconnects the link multiplexed on the transmission path. In addition, a path switching in the adjacent ADM apparatus is generated by actively disconnecting the link of the transmission path whose path is to be switched to another.
[0034]
(First embodiment)
A first embodiment of the present invention will be described in detail with reference to the drawings.
[0035]
FIG. 1 is a block diagram illustrating a configuration of an optical ring network according to the first embodiment. Referring to FIG. 1, the optical ring network includes nodes 110-1, 110-2, 110-3, 110-4 and lines 201a, 201b, 202a, 202b, 203a, 203b, 204a, 204b.
[0036]
Lines 201a, 201b, 202a, 202b, 203a, 203b, 204a, and 204b are optical fiber cable lines that connect nodes and transmit data.
[0037]
The line 201a transmits data from the node 110-1 to the node 110-2, and the line 201b transmits data from the node 110-2 to the node 110-1. The line 202a transmits data from the node 110-2 to the node 110-3, and the line 202b transmits data from the node 110-3 to the node 110-2. The line 203a transmits data from the node 110-3 to the node 110-4, and the line 203b transmits data from the node 110-4 to the node 110-3. The line 204a transmits data from the node 110-4 to the node 110-1, and the line 204b transmits data from the node 110-1 to the node 110-4.
[0038]
The lines 201a, 202a, 203a, and 204a are working (working), and the lines 201b, 202b, 203b, and 204b are reserved (protection).
[0039]
The nodes 110-1, 110-2, 110-3, and 110-4 are ADM devices that transmit / receive data to / from each other by inserting a signal such as packet data into the optical network and separating the signal from the optical network. All have the same configuration.
[0040]
The node 110-1 includes demultiplexing units (MUX / DEMUX) 10a and 10b and a switch unit 120-1.
[0041]
As an example, the demultiplexing units 10a and 10b perform 8: 1 multiplexing and 1: 8 separation. The demultiplexing unit 10a separates the signal from the line 204a into eight signals, transmits the signals from the eight channels of the port 11a, and multiplexes the signals of the eight channels of the port 12a and transmits them to the line 201a. The demultiplexing unit 10b demultiplexes the signal from the line 201b and transmits it from the eight channels of the port 11b, and multiplexes the signals of the eight channels of the port 12b and transmits them to the line 204a.
[0042]
When the demultiplexing unit 10a detects the disconnection of the optical signal on the line 204a, the demultiplexing unit 10a stops sending the signal to the port 11a in order to detect the link disconnection in the subsequent stage. When the demultiplexing unit 10b detects an optical signal input interruption on the line 201b, the demultiplexing unit 10b stops sending a signal to the port 11b.
[0043]
The switch unit 120-1 has an Add port 22 and a Drop port 21 connected to an upper layer communication device (not shown), and is connected to the demultiplexing unit 10a through the ports 11a and 12a. And ports 11b and 12b.
[0044]
Since the switch unit 120-1 is configured by a 24 × 24 switch, an input signal of an arbitrary channel of an arbitrary port can be output as an output signal of an arbitrary channel of an arbitrary port. Since the active line 204a is active, a signal addressed to itself (that is, a signal to be passed to a higher-level communication apparatus connected to itself) is output from the port 11a to the drop port 21, and a signal other than the address itself and the add port 22 are output. Is output to the port 12a. In addition, the switch unit 120-1 outputs a signal input from the port 201b other than itself and a signal from the Add port 22 to the port 12b.
[0045]
When the switch unit 120-1 detects that the signal of the port 11a is disconnected while the active lines 204a and 201a are active and outputs a signal addressed to the port 11a to the drop port 21, the switch unit 120-1 The switch is switched so that a signal addressed to itself is output to the drop port 21, and output of the signal to the port 12a is stopped. The switch unit 120-1 performs the same switching operation even if it detects a link break in the signal of the port 11a.
[0046]
If the signals of the ports 11a, 11b, 12a, and 12b are optical signals, light transmission to the port 12a may be stopped. Here, as an example, if the signal on the line is Gbps Ethernet, the optical signal to the port may be stopped in order to generate Link Down. However, as long as Link Down can be generated immediately, other methods may be used instead of stopping the optical signal.
[0047]
Further, the ports 11a, 11b, 12a, and 12b may be electrical signals. In this case, it is only necessary to detect a link break at a later stage by stopping transmission of a frame.
[0048]
The node 110-2 has the same configuration as the node 110-2, and includes demultiplexing units 10c and 10d and a switch unit 120-2.
[0049]
FIG. 2 is a block diagram illustrating the configuration of the demultiplexing units 10a, 10b, 10c, and 10d. The demultiplexing units 10a, 10b, 10c, and 10d all have the same configuration, and are shown as the demultiplexing unit 10 in FIG.
[0050]
Referring to FIG. 2, the demultiplexing unit 10 includes a termination unit 13, a multiplexing unit 14, an electro-optical conversion unit (EO) 15, an electro-optical conversion unit (OE) 16, and a demultiplexing unit 17.
[0051]
The termination unit 13 is provided for each channel, terminates the low-speed signal of each channel obtained by separating the optical signal of the line and converting it into electricity, and is connected to the host 11 through the switch unit 120-1. Signals to be transmitted / received to / from a layer communication device (not shown) are terminated, and interface conversion between these signals is performed.
[0052]
The termination unit 13 stops sending a signal to the port 11 and generates a link break when detecting a link break on the line side or when receiving an optical signal input break notification from the photoelectric converter 16. .
[0053]
The multiplexing unit 14 multiplexes signals from the termination unit 13 of each channel.
[0054]
The electro-optical conversion unit 15 converts the signal multiplexed by the multiplexing unit 14 from electricity to light, and transmits it to the line.
[0055]
The photoelectric conversion unit 16 converts an optical signal from the line into electricity. When the photoelectric conversion unit 16 detects the disconnection of the optical signal, the photoelectric conversion unit 16 notifies the termination unit 13 of this and stops sending the signal to the port 11.
[0056]
The separation unit 17 separates the high-speed signal converted into electricity by the photoelectric conversion unit 16 into a low-speed signal for each channel.
[0057]
In this example, the line is a Gbps Ethernet frame format based on SONET / SDH, and only the minimum fields such as A1 byte and A2 byte for synchronization, B1 byte for error monitoring, and B2 byte are included in the SONET / SDH frame. Are used, and the E1 byte, E2 byte, etc. of the protection function are not used.
[0058]
FIG. 3 is a diagram for explaining the operation of the node of this embodiment.
[0059]
As shown in FIG. 3, it is assumed that a failure such as an optical power loss occurs in the line 204a of the optical ring network, and communication is interrupted. The failure of the line 204a is detected by the demultiplexing unit 10a, and the node 110-1 stops the signal of the port 11a. As a result, a link break occurs in the link that used the port 11a.
[0060]
When the signal of the port 11a stops, the switch unit 120-1 that has detected the signal stops the signal of the port 12a. As a result, the link using the port 12a is disconnected. Then, the switch unit 120-1 changes the connection to the drop port 21 from the port 11a to the port 11b. By this port change, as the node 110-1 recognizes, the working lines 204a and 201a are changed from the active state to the standby lines 204b and 201b.
[0061]
The stop of the signal of the port 12a is transmitted to the node 110-2 via the line 201a via the demultiplexing unit 10a.
[0062]
Since the link disconnection is detected by the demultiplexing unit 10c, the node 110-2 stops the signal similarly to the node 110-1, and switches the switch unit 120-2. Thereby, as the recognition of the node 110-2, the active lines 201a and 202a are changed from the active state to the standby lines 201b and 202b.
[0063]
In this way, the backup lines are sequentially activated between the nodes, and finally, all the spare lines are in an active state and communication is restored.
[0064]
Therefore, when the node of the first embodiment detects a failure in the transmission path, the link transmitted through the transmission path is disconnected at the position where the failure is detected, and the path is changed by the switch unit. Since links to other nodes are disconnected and the paths are changed to other nodes, each part can perform a simple operation to switch the path at a high speed. Based on the failure information collected from the entire device There is no need to have complicated means for controlling the route, and the cost is low.
[0065]
(Second Embodiment)
A second embodiment of the present invention will be described in detail with reference to the drawings.
[0066]
FIG. 4 is a block diagram illustrating a configuration of the optical ring network according to the second embodiment. Referring to FIG. 4, the optical ring network includes nodes 210-1, 210-2, 210-3, 210-4 and lines 201a, 201b, 202a, 202b, 203a, 203b, 204a, 204b.
[0067]
Lines 201a, 201b, 202a, 202b, 203a, 203b, 204a, and 204b are optical fiber cable lines that connect nodes and transmit data.
[0068]
The line 201a transmits data from the node 210-1 to the node 210-2, and the line 201b transmits data from the node 210-2 to the node 210-1. The line 202a transmits data from the node 210-2 to the node 210-3, and the line 202b transmits data from the node 210-3 to the node 210-2. The line 203a transmits data from the node 210-3 to the node 210-4, and the line 203b transmits data from the node 210-4 to the node 210-3. The line 204a transmits data from the node 210-4 to the node 210-1, and the line 204b transmits data from the node 210-1 to the node 210-4.
[0069]
The lines 201a, 202a, 203a, and 204a are working (working), and the lines 201b, 202b, 203b, and 204b are reserved (protection).
[0070]
The nodes 210-1, 210-2, 210-3, and 210-4 are ADM devices that insert a signal such as packet data into the optical network and separate the signal from the optical network, and all have the same configuration.
[0071]
The node 210-1 includes demultiplexing units (MUX / DEMUX) 10a and 10b and a switch unit 220-1.
[0072]
The demultiplexing units 10a and 10b have the same configuration as that of the first embodiment, and perform 8: 1 multiplexing and 1: 8 separation. In the second embodiment, the demultiplexing unit 10a separates the signal from the line 204a into eight signals, transmits the signals from the eight channels of the port 11a, and multiplexes the signals of the eight channels of the port 12a. Transmit to line 204b. The demultiplexing unit 10b separates the signal from the line 201b into eight signals, transmits the signals from the eight channels of the port 11b, and multiplexes the signals of the eight channels of the port 12b and transmits them to the line 201a.
[0073]
In addition, when the demultiplexing unit 10a detects the disconnection of the optical signal on the line 204a, the demultiplexing unit 10a stops the transmission of the signal to the port 11a in order to detect the link disconnection in the subsequent stage. When the demultiplexing unit 10b detects an optical signal input interruption on the line 201b, the demultiplexing unit 10b stops sending a signal to the port 11b.
[0074]
The switch unit 220-1 includes an Add port 22 and a Drop port 21 connected to a communication device (not shown) in an upper layer, and is connected to the demultiplexing unit 10a through the ports 11a and 12a. And ports 11b and 12b.
[0075]
Since the switch unit 220-1 is configured by a 24 × 24 switch, it can output an input signal of an arbitrary channel of an arbitrary port as an output signal of an arbitrary channel of an arbitrary port. Since the active lines 204a and 201a are active, a signal addressed to itself is separated from the port 11a and output to the drop port 21, and a signal other than the address itself and a signal from the add port 22 are output to the port 12b. In addition, the switch unit 220-1 outputs a signal input from the port 11b other than itself and a signal from the Add port 22 to the port 12a.
[0076]
When the active line 204a, 201a is active and the switch unit 220-1 outputs the signal of the port 11a to the drop port 21, the switch unit 220-1 detects that the signal of the port 11a is not input and is addressed to itself from the port 11b. The switch is switched so that the above signal is output to the drop port 21, the signal other than the address addressed to itself from the port 11b is returned to the port 12b, and the output of the signal to the port 12a is stopped.
[0077]
The switch unit 220-1 performs the same switching operation even if it detects a link break in the signal of the port 11a.
[0078]
Here, if the line signal is Gbps Ethernet, the optical signal to the port may be stopped in order to generate Link Down. However, as long as Link Down can be generated immediately, other methods may be used instead of stopping the optical signal.
[0079]
The node 210-2 has the same configuration as the node 210-1, and includes demultiplexing units 10c and 10d and a switch unit 220-2. The node 210-4 has demultiplexing units 10g and 10h and a switch unit 220-4.
[0080]
FIG. 5 is a diagram for explaining the operation of the opposing demultiplexing units in the second embodiment. The demultiplexing unit 10-1 and the demultiplexing unit 10-2 included in different nodes face each other. As shown in FIG. 5, when a failure occurs in the line from the demultiplexing unit 10-2 to the demultiplexing unit 10-1, the demultiplexing unit 10-1 detects it. When detecting the failure, the demultiplexing unit 10-1 stops the signal to the port 11-1. When the signal to the port 11-1 is stopped, a switch unit (not shown) connected thereto stops the signal to the port 12-1.
[0081]
When the signal of the port 12-1 is stopped, the information is transmitted to the demultiplexing unit 10-2 of the opposite node. Then, the demultiplexing unit 10-2 that detects the link break stops the signal of the port 11-2. When the signal of the port 11-2 is stopped, the switch unit (not shown) connected thereto stops the signal of the port 12-2.
[0082]
FIG. 6 is a diagram for explaining the operation of the node according to the second embodiment.
[0083]
Referring to FIG. 6, it is assumed that a failure such as an optical power loss occurs on the line 204a of the optical ring network, and communication is interrupted. The failure of the line 204a is detected by the demultiplexing unit 10a, and the node 210-1 stops the signal of the port 11a.
[0084]
When the signal of the port 11a stops, the switch unit 220-1 that detects the signal stops the signal of the port 12a, changes the connection to the drop port 21 from the port 11a to the port 11b, and signals other than those addressed to itself. Is returned from the port 11b to the port 12b.
[0085]
The stop of the signal of the port 12a is transmitted to the node 210-4 via the line 201a through the demultiplexing unit 10a. Since the link disconnection is detected by the demultiplexing unit 10h, the node 210-4 stops the signal and performs the return by the switch unit 220-4 similarly to the node 210-1.
[0086]
In this way, the communication is restored by disconnecting the fault location from the loop and forming a new loop.
[0087]
(Third embodiment)
A third embodiment of the present invention will be described in detail with reference to the drawings.
[0088]
FIG. 7 is a block diagram illustrating a configuration of a node constituting the optical ring network according to the third embodiment. In FIG. 7, only one node is shown, but the network has a ring configuration with the same node.
[0089]
The optical network is a WDM (Wavelength Division Multiplexing) network in which optical signals of four wavelengths are multiplexed. The node 1000-1 is a WDM ADM device that inserts a signal such as packet data into an arbitrary wavelength among the four wavelengths of the optical network and separates the signal.
[0090]
The node 1000-1 includes wavelength demultiplexing units 41a and 41b, wavelength multiplexing units 42a and 42b, wavelength nodes 110-1A, 110-1B, 110-1C, and 110-1D, and a wavelength node switch 130-1.
[0091]
The wavelength demultiplexers 41a and 41b separate and extract four signals with different wavelengths multiplexed on a line between nodes. As an example, the wavelengths are λA = 1539.77 nm, λB = 1546.12 nm, λC = 1552.52 nm, and λD = 1558.98 nm.
[0092]
The wavelength multiplexing units 42a and 42b multiplex four signals having different wavelengths on one line.
[0093]
The wavelength nodes 110-1A, 110-1B, 110-1C, and 110-1D have the same configuration as that of the node 110-1 in FIG. 1, and each signal separated by the wavelength demultiplexing units 41a and 41b is input thereto. . The wavelength nodes 110-1A, 110-1B, 110-1C, and 110-1D perform signal separation and multiplexing for each wavelength. The signals multiplexed by the wavelength nodes 110-1A, 110-1B, 110-1C, and 110-1D are wavelength multiplexed by the wavelength multiplexing units 42a and 42b.
[0094]
The wavelength nodes 110-1A, 110-1B, 110-1C, and 110-1D have the same configuration as that of the node 110-1 in FIG. 1, but the wavelengths of the optical signals handled are different. The wavelength of the generated optical signal is different.
[0095]
The wavelength node switch 130-1 is connected to the Add port and the Drop port of the switch units 120-1A, 120-1B, 120-1C, and 120-1D, and is connected to a communication device (not shown) in the upper layer. Add port 132 and Drop port 131 are provided. The wavelength node switch 130-1 can output the input of any channel of the switch units 120-1A to 120-1D to any channel.
[0096]
By combining the wavelength node switch 130-1 and the switch units 120-1A, 120-1B, 120-1C, and 120-1D, signals from higher layer devices are multiplexed on an arbitrary channel of an arbitrary wavelength, and an arbitrary wavelength Can be separated and transmitted to an upper layer communication apparatus. Similarly, it is possible to switch channels between wavelengths.
[0097]
FIG. 8 is a diagram for explaining the operation of a node according to the third embodiment when a failure occurs in a line between nodes.
[0098]
As shown in FIG. 8, it is assumed that a failure such as an optical power loss occurs in the line 204a of the optical ring network, and communication of all wavelengths is interrupted. The failure of the line 204a is detected by the demultiplexing unit 10a of all the wavelength nodes 110-1A, 110-1B, 110-1C, and 110-1D of the node 1000-1, and the nodes 110-1A, 110-1B, and 110- Each of 1C and 110-1D stops the signal of its own port 11a.
[0099]
When the signal at the port 11a stops, the switch unit 120-1 that detects the signal stops the signal at the port 12a and changes the connection to the drop port 21 from the port 11a to the port 11b. When all the wavelength nodes 110-1A, 110-1B, 110-1C, and 110-1D change the ports, as a recognition of the node 1000-1, the active lines 204a and 201a are changed from the active state to the standby line. 204b and 201b become active.
[0100]
The stoppage of the signal at the port 12a of each wavelength node is transmitted to each wavelength node of the adjacent node via the line 201a via the respective demultiplexing unit 10a, and switching occurs in all nodes in order from the adjacent node. In this case, all the backup lines become active and communication is restored.
[0101]
FIG. 9 is a diagram for explaining the operation of the node according to the third embodiment when a failure occurs in a line of one wavelength.
[0102]
As shown in FIG. 9, it is assumed that a failure has occurred in the line of wavelength λA = 1539.77 nm separated by the wavelength separation unit 41a, and communication of signals multiplexed there has been interrupted. The failure is detected by the demultiplexing unit 10a of the wavelength node 110-1A, and the wavelength node 110-1A stops the signal of the port 11a.
[0103]
When the signal of the port 11a stops, the switch unit 120-1A that detects the signal stops the signal of the port 12a and changes the connection to the drop port 21 from the port 11a to the port 11b. When the wavelength node 110-1A changes the port, for the wavelength λA = 1539.77 nm, as the node 000-1 recognizes, the working lines 204a and 201a are active and the protection lines 204b and 201a are active. It becomes the state of.
[0104]
The stop of the signal of the port 12a of the wavelength node 110-1A is transmitted to the wavelength node of the same wavelength of the adjacent node through the line 201a via the demultiplexing unit 10aA, and switching occurs in all the nodes in order from the adjacent node. Eventually, all the backup lines of that wavelength become active and communication is restored. In this way, when a failure occurs at only one wavelength, the backup line is activated only for that wavelength by the same operation as that of the first embodiment for that wavelength.
[0105]
(Fourth embodiment)
A fourth embodiment of the present invention will be described in detail with reference to the drawings.
[0106]
FIG. 10 is a block diagram illustrating a configuration of a node configuring the optical ring network according to the fourth embodiment. In FIG. 10, only one node is shown, but the network is a ring configuration with the same node.
[0107]
The optical network is a WDM network in which signals of four wavelengths are multiplexed.
The node 2000-1 is a WDM ADM apparatus that inserts a signal such as packet data into a signal of an arbitrary wavelength among signals of four wavelengths of the optical network and separates the signal.
[0108]
The node 2000-1 includes wavelength demultiplexing units 41a and 41b, wavelength multiplexing units 42a and 42b, wavelength nodes 210-1A, 210-1B, 210-1C, and 210-1D, and a wavelength node switch 230-1.
[0109]
The wavelength separation units 41a and 41b are the same as those in the third embodiment, and separate and extract signals of four wavelengths multiplexed on a line between nodes. As an example, the wavelengths are λA = 1539.77 nm, λB = 1546.12 nm, λC = 1552.52 nm, and λD = 1558.98 nm.
[0110]
The wavelength multiplexing units 42a and 42b are the same as those in the third embodiment, and multiplex four signals having different wavelengths onto one line.
[0111]
The wavelength nodes 210-1A, 210-1B, 210-1C, and 210-1D have the same configuration as the node 210-1 in FIG. 4, and the signals separated by the wavelength demultiplexing units 41a and 41b are input thereto. The wavelength nodes 210-1A, 210-1B, 210-1C, and 210-1D perform signal separation and multiplexing for each wavelength. The signals multiplexed by the wavelength nodes 210-1A, 210-1B, 210-1C, and 210-1D are wavelength multiplexed by the wavelength multiplexing units 42a and 42b.
[0112]
The wavelength nodes 210-1A, 210-1B, 210-1C, and 210-1D have the same configuration as that of the node 210-1 in FIG. 4, but the wavelengths of the optical signals handled are different. The wavelength of the generated optical signal is different.
[0113]
FIG. 11 is a diagram for explaining the operation of a node according to the fourth embodiment when a failure occurs in a line between nodes.
[0114]
As shown in FIG. 11, it is assumed that a failure such as an optical power loss occurs in the line 204a of the optical ring network, and communication of all wavelengths is interrupted. The failure of the line 204a is detected by the demultiplexing unit 10a of all the wavelength nodes 210-1A, 210-1B, 210-1C, 210-1D of the node 2000-1, and the nodes 210-1A, 210-1B, 210-1C are detected. , 210-1D stops the signal of the port 11a.
[0115]
When the signal of the port 11a stops, the switch unit 220-1 that detects the signal stops the signal of the port 12a, changes the connection to the drop port 21 from the port 11a to the port 11b, and signals other than those addressed to itself. Is returned from the port 11b to the port 12b.
[0116]
The stop of the signal of the port 12a of each wavelength node is transmitted to each wavelength node of the node 2000-4 through the line 201a via the demultiplexing unit 10a. Similarly to the node 2000-1, the node 2000-4 stops the signal and performs the return at the switch unit.
[0117]
In this way, the communication is restored when the fault location is separated from the loop for all wavelengths and a new loop is formed.
[0118]
FIG. 12 is a diagram for explaining the operation of the node according to the fourth embodiment when a failure occurs in a line of one wavelength.
[0119]
As shown in FIG. 12, it is assumed that a failure has occurred in the line of wavelength λA = 1539.77 nm that is separated from the line 204a of the optical ring network by the wavelength demultiplexing unit 41a, and communication of signals multiplexed there has been interrupted. The failure is detected by the demultiplexing unit 10a of the wavelength node 210-1A of the node 2000-1, and the wavelength node 210-1A stops the signal of the port 11a.
[0120]
When the signal of the port 11a stops, the switch unit 220-1A that detects the signal stops the signal of the port 12a, changes the connection to the drop port 21 from the port 11a to the port 11b, and signals other than those addressed to itself. Is returned from the port 11b to the port 12b.
[0121]
The signal stop of the port 12a is transmitted to the wavelength node of the same wavelength of the node 2000-4 via the line 201a via the demultiplexing unit 10aA, and the node 2000-4 stops the signal similarly to the node 2000-1. In addition, folding is performed at the switch section.
[0122]
As described above, when a failure occurs only at one wavelength, the failure point is separated from the loop only for that wavelength and a new loop is configured by the same operation as that of the second embodiment. Communication is restored.
[0123]
【The invention's effect】
According to the communication network of the present invention, a node that detects a failure in a transmission path changes its own internal route, stops sending signals to other nodes, and causes other nodes to change routes. It is not necessary to provide a complicated procedure for controlling the route between them, and it is possible to realize a highly reliable communication network that can switch the route at a low cost and at high speed.
[0124]
In addition, the node that detects the failure of a specific wavelength on the transmission path switches its internal path for that wavelength and stops the transmission of signals to other nodes to change the path. Therefore, it is possible to realize a highly reliable communication network having a high transmission capacity and capable of switching between routes at a low cost at a low cost.
[0125]
Further, according to the communication device of the present invention, when a failure in the working transmission line is detected, the signal transmitted through the transmission line is stopped by the working demultiplexing unit that has detected the failure, and the route is sent to the switch unit. In addition, the signal transmitted to the working transmission line is stopped by the switch unit, and the other communication device changes the route, so that each unit can perform a simple operation to switch the route at high speed. This eliminates the need for complicated means for controlling the path based on the failure information collected from the entire apparatus, and is low cost.
[0126]
When a failure in the working transmission line is detected, the working demultiplexing unit that detects the failure stops the signal transmitted on the transmission line, causes the switch unit to change the route, and Since the signal to be transmitted to the standby transmission line is stopped and the other communication device changes the route, each part can perform a simple operation, so that the route can be switched at high speed, and failure information collected from the entire device It is not necessary to have a complicated means for controlling the route based on the cost, and the cost is low.
[Brief description of the drawings]
FIG. 1 is a block diagram illustrating a configuration of an optical ring network according to a first embodiment.
FIG. 2 is a block diagram illustrating a configuration of a demultiplexing unit.
FIG. 3 is a diagram for explaining an operation of a node according to the first embodiment;
FIG. 4 is a block diagram showing a configuration of an optical ring network according to the second embodiment.
FIG. 5 is a diagram for explaining the operation of opposing demultiplexing units in the second embodiment.
FIG. 6 is a diagram for explaining an operation of a node according to the second embodiment;
FIG. 7 is a block diagram illustrating a configuration of a node configuring an optical ring network according to the third embodiment.
FIG. 8 is a diagram for explaining an operation of a node according to the third embodiment when a failure occurs in a line between nodes;
FIG. 9 is a diagram for explaining the operation of a node according to the third embodiment when a failure occurs in a line of one wavelength.
FIG. 10 is a block diagram illustrating a configuration of a node configuring an optical ring network according to the fourth embodiment.
FIG. 11 is a diagram for explaining an operation of a node according to the fourth embodiment when a failure occurs in a line between nodes;
FIG. 12 is a diagram for explaining an operation of a node according to the fourth embodiment when a failure occurs in a line of one wavelength.
[Explanation of symbols]
10, 10-1, 10-2, 10a, 10aA, 10bA, 10b, 10c, 10d, 10g, 10h Demultiplexer (MUX / DEMUX)
11, 11-1, 11-2, 11a, 11b, 12, 12-1, 12-2, 12a, 12b Port
13 Terminal
14 Multiplexer
15 Electro-optical converter (EO)
16 Electro-optical converter (OE)
17 Separation part
21, 131, 231 Drop port
22, 132, 232 Add ports
41a, 41b wavelength separation unit
42a, 42b Wavelength multiplexing section
110-1, 110-2, 110-3, 110-4, 210-1, 210-2, 210-3, 210-4, 1000-1, 2000-1 to 2000-4 nodes
110-1A to 110-1D, 210-1A to 210-1D Wavelength node
120-1, 120-1A to 120-1D, 120-2, 220-1, 220-1A to 220-1D, 220-2, 220-3, 220-4 Switch unit
130-1, 230-1 Wavelength node switch
201a, 201b, 202a, 202b, 203a, 203b, 204a, 204b

Claims (12)

A communication network in which three or more nodes are connected in a double ring shape with a working transmission line and a backup transmission line,
The high-speed signal from the working transmission line on the receiving side is separated into a plurality of low-speed signals, and a plurality of low-speed signals are multiplexed and transmitted to the working transmission line on the transmitting side as high-speed signals. When a failure is detected, an active demultiplexing unit that stops each low-speed signal that has separated the high-speed signal of the reception-side active transmission path, and a high-speed signal from the standby-side transmission path of the reception side are separated into a plurality of low-speed signals. When the low-speed signal from the standby demultiplexing unit stops and the spare demultiplexing unit that multiplexes the low-speed signal and transmits it to the transmission line on the transmission side stops, the low-speed signal from the standby demultiplexing unit is addressed to itself A switch unit that captures a signal and stops transmission of the high-speed signal to the working transmission line on the transmitting side by stopping transmission of the low-speed signal multiplexed on the working transmission line on the transmitting side to the working demultiplexing unit ; 1 node,
The high-speed signal from the working transmission line on the receiving side is separated into a plurality of low-speed signals, and a plurality of low-speed signals are multiplexed and transmitted to the working transmission line on the transmitting side as high-speed signals. When the received high-speed signal is stopped, the working demultiplexing unit that stops each low-speed signal obtained by separating the high-speed signal of the receiving-side active transmission path, and the high-speed signal from the receiving-side backup transmission path is converted into a plurality of low-speed signals. When the low-speed signal from the standby demultiplexing unit stops and the low-speed signal from the active demultiplexing unit stops, the low-speed signal from the standby demultiplexing unit A switch for stopping transmission of a high-speed signal to the working transmission line on the transmitting side by capturing a signal addressed to itself from the mobile station and stopping transmission of the low-speed signal multiplexed on the working transmission line on the transmitting side to the working demultiplexing unit second placement with the department Communication network with de.   When the node has the functions of the first node and the second node and a failure occurs in any of the working transmission lines, the node that detects the failure operates as the first node, 2. The communication network according to claim 1, wherein communication between all of the nodes is performed on the backup transmission path by operating as the second node. Three or more nodes are double ring communication networks in which each section between the nodes is connected by a working transmission line and a backup transmission line having different signal flow directions,
The high-speed signal from the working transmission line on the receiving side is separated into a plurality of low-speed signals, and a plurality of low-speed signals are multiplexed and transmitted to the spare transmission line on the transmitting side as a high-speed signal. When a failure is detected, a first demultiplexing unit that stops each low-speed signal obtained by separating the high-speed signal on the reception-side active transmission line, and a high-speed signal from the standby-side transmission line on the reception side are separated into a plurality of low-speed signals, A second demultiplexing unit that multiplexes a plurality of low-speed signals and transmits them as high-speed signals to the transmission transmission line on the transmission side, and when the low-speed signals from the first demultiplexing unit stop, Stop transmission of the low-speed signal multiplexed on the transmission path to the first demultiplexing unit, capture the signal addressed to itself from the low-speed signal from the second demultiplexing unit, A switch unit that turns back to the second demultiplexing unit as a low-speed signal A first node,
A first demultiplexer that separates a high-speed signal from a reception-side active transmission path into a plurality of low-speed signals, multiplexes the plurality of low-speed signals, and transmits the result as a high-speed signal to a transmission-side backup transmission path; The high-speed signal from the auxiliary transmission line on the side is separated into a plurality of low-speed signals, and a plurality of low-speed signals are multiplexed and transmitted to the active transmission line on the transmission side as a high-speed signal. When the high-speed signal to be stopped is stopped, the second demultiplexing unit that stops each low-speed signal that has separated the high-speed signal of the reception-side spare transmission path, and when the low-speed signal from the second demultiplexing unit is stopped, A communication network having a second node having a switch unit for returning a signal other than the address of the low-speed signal from the first demultiplexing unit to the first demultiplexing unit as a low-speed signal .   When the node has the functions of the first node and the second node and a failure occurs in any of the working transmission lines, the node that detects the failure operates as the first node, and The node that transmitted the signal to the generated working transmission line operates as the second node, so that communication is performed on the working transmission line and the standby transmission line other than the section in which the failure has occurred. Item 4. The communication network according to item 3. A communication network in which three or more nodes are connected in a double ring shape with an active transmission line and a backup transmission line, and transmit and receive wavelength-multiplexed signals,
The high-speed signal from the working transmission line on the receiving side is separated into a plurality of low-speed signals, and a plurality of low-speed signals are multiplexed and transmitted to the working transmission line on the transmitting side as high-speed signals. When a failure is detected, an active demultiplexing unit that stops each low-speed signal that has separated the high-speed signal of the reception-side active transmission path, and a high-speed signal from the standby-side transmission path of the reception side are separated into a plurality of low-speed signals. When the low-speed signal from the standby demultiplexing unit stops and the spare demultiplexing unit that multiplexes the low-speed signal and transmits it to the transmission line on the transmission side stops, the low-speed signal from the standby demultiplexing unit is addressed to itself Each of the switch unit that captures a signal and stops transmission of a high-speed signal to the working transmission line on the transmitting side by stopping transmission of the low-speed signal multiplexed on the working transmission line on the transmitting side to the working demultiplexing unit the first of multiple perforated for each wavelength And over de,
The high-speed signal from the working transmission line on the receiving side is separated into a plurality of low-speed signals, and a plurality of low-speed signals are multiplexed and transmitted to the working transmission line on the transmitting side as high-speed signals. When the received high-speed signal is stopped, the working demultiplexing unit that stops each low-speed signal obtained by separating the high-speed signal of the receiving-side active transmission path, and the high-speed signal from the receiving-side backup transmission path is converted into a plurality of low-speed signals. When the low-speed signal from the standby demultiplexing unit stops and the low-speed signal from the active demultiplexing unit stops, the low-speed signal from the standby demultiplexing unit A switch for stopping transmission of a high-speed signal to the working transmission line on the transmitting side by capturing a signal addressed to itself from the mobile station and stopping transmission of the low-speed signal multiplexed on the working transmission line on the transmitting side to the working demultiplexing unit For each wavelength Communication network having a second node of the plurality Yes.   The node has the functions of the first node and the second node, and when a failure of at least one wavelength occurs in any of the active transmission lines, the node that detects the failure operates as the first node The communication network according to claim 5, wherein all the other nodes operate as the second node, whereby the wavelength communication between all the nodes is performed on the backup transmission path. Three or more nodes are double ring communication networks in which each section between the nodes is connected by active transmission lines and backup transmission lines having different signal flow directions, and transmits and receives wavelength-multiplexed signals. And
The high-speed signal from the working transmission line on the receiving side is separated into a plurality of low-speed signals, and a plurality of low-speed signals are multiplexed and transmitted to the spare transmission line on the transmitting side as a high-speed signal. When a failure is detected, a first demultiplexing unit that stops each low-speed signal obtained by separating the high-speed signal on the reception-side active transmission line, and a high-speed signal from the standby-side transmission line on the reception side are separated into a plurality of low-speed signals, A second demultiplexing unit that multiplexes a plurality of low-speed signals and transmits them as high-speed signals to the transmission transmission line on the transmission side, and when the low-speed signals from the first demultiplexing unit stop, Stop transmission of the low-speed signal multiplexed on the transmission path to the first demultiplexing unit, capture the signal addressed to itself from the low-speed signal from the second demultiplexing unit, A switch unit that folds back as a low-speed signal to the second demultiplexing unit; A first node to a plurality chromatic for each wavelength respectively,
A first demultiplexer that separates a high-speed signal from a reception-side active transmission path into a plurality of low-speed signals, multiplexes the plurality of low-speed signals, and transmits the result as a high-speed signal to a transmission-side backup transmission path; The high-speed signal from the auxiliary transmission line on the side is separated into a plurality of low-speed signals, and a plurality of low-speed signals are multiplexed and transmitted to the active transmission line on the transmission side as a high-speed signal. When the high-speed signal to be stopped is stopped, the second demultiplexing unit that stops each low-speed signal that has separated the high-speed signal of the reception-side spare transmission path, and when the low-speed signal from the second demultiplexing unit is stopped, A communication network having a second node having a plurality of switch units for each wavelength, each of the low-speed signals from the first demultiplexing unit returning to the first demultiplexing unit as a low-speed signal. .   The node has the functions of the first node and the second node, and when a failure of at least one wavelength occurs in any of the active transmission lines, the node that detects the failure operates as the first node Then, the node transmitting the signal to the failed working transmission line operates as the second node, so that the communication of the wavelength is performed in the working transmission line and the standby transmission line other than the failed part. The communication network according to claim 7, wherein: A communication device that is connected in a double ring shape on the active and backup transmission lines to form a communication network,
The high-speed signal from the working transmission line on the receiving side is separated into a plurality of low-speed signals, and a plurality of low-speed signals are multiplexed and transmitted to the working transmission line on the transmitting side as high-speed signals. An active demultiplexing unit that stops each low-speed signal that has separated the high-speed signal of the reception-side active transmission line when a failure is detected and when the high-speed signal received from the reception-side active transmission line is stopped;
A demultiplexing unit that separates a high-speed signal from a reception-side spare transmission path into a plurality of low-speed signals, multiplexes a plurality of low-speed signals, and transmits the multiplexed signals to the transmission-side spare transmission path;
When the low-speed signal from the working demultiplexing unit stops, the working demultiplexing of the low-speed signal that is taken in from the low-speed signal from the backup demultiplexing unit and is multiplexed on the transmission transmission line on the transmission side A communication device having a switch unit that stops transmission to the unit.   The communication apparatus according to claim 9, wherein a plurality of the active demultiplexing unit, the backup demultiplexing unit, and the switch unit are provided for each wavelength, and a wavelength-multiplexed signal is transmitted and received. A communication device that forms a communication network by being connected in a double ring shape in a working transmission line and a backup transmission line having different signal flow directions,
The high-speed signal from the working transmission line on the receiving side is separated into a plurality of low-speed signals, and a plurality of low-speed signals are multiplexed and transmitted to the spare transmission line on the transmitting side as a high-speed signal. When detecting a failure, a first demultiplexing unit that stops each low-speed signal obtained by separating the high-speed signal of the working transmission line on the receiving side;
The high-speed signal from the standby transmission line on the reception side is separated into a plurality of low-speed signals, and a plurality of low-speed signals are multiplexed and transmitted to the active transmission line on the transmission side as a high-speed signal. When the received high-speed signal is stopped, a second demultiplexing unit that stops each low-speed signal obtained by separating the high-speed signal of the reception side spare transmission path;
When the low-speed signal from the first demultiplexing unit stops, transmission of the low-speed signal multiplexed on the transmission side backup transmission path to the first demultiplexing unit is stopped, and the second demultiplexing unit When the low-speed signal from the second demultiplexing unit stops, the signal destined for itself is taken in from the low-speed signal of the other, the signal other than the self-addressed signal is turned back to the second demultiplexing unit as a low-speed signal. A communication device having a switch unit that turns back a signal other than the one addressed to itself among the low-speed signals from the demultiplexing unit to the first demultiplexing unit as a low-speed signal.   The communication apparatus according to claim 11, comprising a plurality of the first demultiplexing unit, the second demultiplexing unit, and the switch unit for each wavelength, and transmitting and receiving a wavelength-multiplexed signal.

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