JP4291715B2 - WDM apparatus and optical communication system - Google Patents

Description

  The present invention relates to a WDM apparatus and an optical communication system. In particular, the present invention relates to a WDM apparatus that relays an optical signal using an optical division multiplexing system, and an optical communication system including the WDM apparatus.

  Recent optical communication systems have been developed with the aim of increasing capacity and extending distance. In order to realize a large capacity, a WDM apparatus that relays optical communication using a wavelength division multiplexing (WDM) system that transmits a plurality of optical signals having different wavelengths using a single optical fiber cable. Has been developed. Further, in order to realize a long distance, an optical amplifier capable of collectively amplifying light in a wide wavelength range for compensating for propagation loss of an optical fiber cable has been developed.

  Since the existence of the prior art document is not recognized at the present time, the description regarding the prior art document is omitted.

  As the distance of an optical communication system increases, two WDM devices respectively provided in each network for connecting two networks existing in remote locations will be arranged in remote locations. For this reason, when it is necessary to connect each management device directly to each WDM device and set each WDM device, the system administrator must move long distances when setting each WDM device. It is difficult to respond quickly.

  Accordingly, an object of the present invention is to provide a WDM apparatus and an optical communication system that can solve the above-described problems. This object is achieved by a combination of features described in the independent claims. The dependent claims define further advantageous specific examples of the present invention.

  According to the first aspect of the present invention, there is provided a WDM apparatus that relays an optical signal using a wavelength division multiplexing method, having a local communication port to which an external communication device is connected, and receiving an optical signal from the communication device. A plurality of local communication units that receive and convert optical signals into electrical signals and remote communication ports to which other WDM devices are connected, and each of the plurality of electrical signals converted by the plurality of local communication units, respectively. A remote communication unit that converts and multiplexes into a plurality of optical signals with different wavelengths and transmits them to other WDM devices, and a plurality of electrical signals supplied from a plurality of local communication units to the remote communication unit, A control unit that interrupts setting data including setting information of another WDM device and causes the remote communication unit to transmit the setting data to the other WDM device.

  Any of a plurality of transmission lines connecting each of the plurality of local communication units and the remote communication unit, and an electric signal provided from each of the plurality of transmission lines and a setting data supplied from the control unit And a plurality of switching units that are supplied to the remote communication unit and transmitted to other WDM devices, and the control unit selects one switching unit from among the plurality of switching units and performs one switching. By supplying setting data to the unit, the setting data may be interrupted by an electric signal supplied from the local communication unit by one switching unit.

  The control unit selects two or more switching units among the plurality of switching units, and supplies the same setting data to the two or more switching units, whereby each of the two or more local communication units is performed by the two or more switching units. The setting data may be interrupted to two or more electrical signals supplied from.

  The control unit may transmit the setting data to the other WDM device by using a packet in the data link layer of the OSI reference model with the MAC address of the other WDM device as the destination.

  Each of the plurality of switching units has a counter that measures the amount of communication in each of the plurality of switching units, and the control unit refers to the amount of communication measured by each of the plurality of switching units, and By selecting the switching unit and supplying the setting data to one switching unit, the setting data may be interrupted by an electric signal supplied from the local communication unit by one switching unit.

  Whether the control unit can normally communicate with a plurality of optical signals having different wavelengths by supplying a loopback test packet to each of the plurality of switching units and causing the remote communication unit to transmit the packet to another WDM device. May be selected, one switching unit corresponding to the wavelength determined to be normally communicable based on the test result may be selected, and setting data may be supplied to one switching unit.

  The control unit may cause the remote communication unit to transmit setting data including identification information of an SNMP manager that manages the WDM device as setting information to another WDM device.

According to the second aspect of the present invention, there is provided a WDM device that relays an optical signal using a wavelength division multiplexing method, and has a local communication port to which an external communication device is connected. A plurality of local communication units that receive signals and convert optical signals into electrical signals and remote communication ports to which other WDM devices are connected, and a plurality of electrical signals converted by the plurality of local communication units, respectively. Either a remote communication unit that converts and multiplexes each into a plurality of optical signals having different wavelengths and transmits them to other WDM devices, or a plurality of electrical signals supplied from a plurality of local communication units to a remote communication unit By interrupting the setting request data for requesting acquisition of the setting information of the other WDM apparatus and transmitting the setting request data to the other WDM apparatus by the remote communication unit. And a control unit that acquires setting information from the M unit.
The control unit may set the setting information acquired from another WDM device in the WDM device.

  According to the third aspect of the present invention, there is provided an optical communication system including a first WDM apparatus and a second WDM apparatus that communicate with each other using a wavelength division multiplexing method, and the first WDM apparatus is connected to an external communication device. A plurality of first local communication units that receive the optical signal from the communication device and convert the optical signal into an electrical signal, and a second remote communication port to which the second WDM device is connected A first remote communication unit that converts each of the plurality of electrical signals converted by the plurality of first local communication units into a plurality of optical signals having different wavelengths, multiplexes the signals, and transmits the multiplexed signals to the second WDM device; The setting data including the setting information of the second WDM device is interrupted to any of the plurality of electrical signals supplied from the plurality of first local communication units to the first remote communication unit, and the setting data is set. And a first control unit that transmits the second WDM device to the second WDM device by the first remote communication unit. The second WDM device has a second remote communication port to which the first WDM device is connected and is multiplexed from the first WDM device. A second remote communication unit that receives a plurality of optical signals and converts the plurality of optical signals into a plurality of electrical signals, and a second local communication port to which an external communication device is connected. From the plurality of second local communication units that convert the electrical signals converted by the unit into optical signals and transmit them to an external communication device, and the plurality of electrical signals converted by the second remote communication unit, from the first WDM device A second control unit that acquires the transmitted setting data and sets the setting information included in the setting data in the second WDM apparatus;

  According to a fourth aspect of the present invention, there is provided an optical communication system comprising a first WDM device and a second WDM device that communicate with each other using a wavelength division multiplexing method, and the first WDM device is connected to an external communication device. A first remote communication port having a plurality of first local communication ports that receive an optical signal from a communication device and convert the optical signal into an electrical signal, and a second WDM device. A first remote communication unit that converts each of the plurality of electrical signals converted by the plurality of first local communication units into a plurality of optical signals having different wavelengths, multiplexes the signals, and transmits the multiplexed signals to the second WDM device; The setting request data for requesting the acquisition of the setting information of the second WDM device is interrupted to any one of the plurality of electric signals supplied from the plurality of first local communication units to the first remote communication unit. A first control unit that transmits the setting request data to the second WDM device by the first remote communication unit, and the second WDM device has a second local communication port to which an external communication device is connected, and A plurality of second local communication units for receiving an optical signal from the device and converting the optical signal into an electrical signal; a second remote communication port to which the first WDM device is connected; Each of the converted electrical signals is converted into a plurality of optical signals having different wavelengths, multiplexed, and transmitted to the first WDM device, and the setting request data transmitted from the first WDM device. In response, the setting data including the setting information of the second WDM device is interrupted to one of the plurality of electric signals supplied from the plurality of second local communication units to the second remote communication unit. , And a second control unit for transmitting the configuration data to the 1WDM device by the second remote communication unit.

  Note that the above summary of the invention does not enumerate all the necessary features of the present invention, and sub-combinations of these feature groups can also be the invention.

  According to the present invention, even if the distance of an optical communication system is increased and two WDM devices are arranged at a distant place, a system administrator can set a long distance for setting the two WDM devices. It is not necessary to move and can respond quickly.

  Hereinafter, the present invention will be described through embodiments of the invention. However, the following embodiments do not limit the claimed invention, and all combinations of features described in the embodiments are inventions. It is not always essential to the solution.

  FIG. 1 shows an example of the configuration of an optical communication system 100 according to an embodiment of the present invention. The optical communication system 100 includes WDM devices 102a to 102d, WDM devices 104a to 104d, and a management terminal 106. The management terminal 106 is directly connected to the management port of the WDM device 102a or the WDM device 104a via a metallic cable such as a serial cable or an Ethernet (registered trademark) cable, and the WDM devices 102a to 102d and the WDM devices 104a to 104d. Make various settings.

  The WDM device 102a and the WDM device 102b are connected via an optical fiber cable 132a between a remote communication unit 110a included in the WDM device 102a and a remote communication unit 110b included in the WDM device 102b. The WDM device 102c and the WDM device 102d are connected between the remote communication unit 110c included in the WDM device 102c and the remote communication unit 110d included in the WDM device 102d via the optical fiber cable 132b.

  The WDM devices 102a, 102b, 102c, and 102d are a control unit 114a included in the WDM device 102a and a control unit included in the WDM device 102b via metallic cables 136a, 136b, and 136c such as Ethernet (registered trademark) cables. 114b, the control unit 114c included in the WDM device 102c, and the control unit 114d included in the WDM device 102d are connected in series.

  In the WDM apparatus 102a, the local communication unit 112a is connected to the network NW1 via the optical fiber cable 134a, and the local communication unit 112b is connected to the network NW2 via the optical fiber cable 134b. In the WDM apparatus 102b, the local communication unit 112c is connected to the network NW3 via the optical fiber cable 134c, and the local communication unit 112d is connected to the network NW4 via the optical fiber cable 134d. Similarly, in the WDM apparatuses 102c and 102d, the local communication units 112e to 112h are connected to the networks NW5 to NW8 via the optical fiber cables 134e to 134h, respectively.

  Here, the control unit 114a included in the WDM device 102a includes a CPU, and each of the control units 114b to 114d included in each of the WDM devices 102b to 102d may not include a CPU. The control unit 114a included in the WDM apparatus 102a controls communication and settings of the WDM apparatus 102a by the function of the CPU, and performs communication and settings of the WDM apparatuses 102b to 102d via the metallic cables 136a, 136b, and 136c. Control.

  Note that the connection forms of the WDM apparatuses 104a to 104d are except that the management terminal 106 is not connected to the WDM apparatus 104a and that each of the WDM apparatuses 104a to 104d is connected to the networks NW1 ′ to NW8 ′. Since it is the same as the connection form of the WDM apparatuses 102a to 102d, description thereof will be omitted.

  The WDM device 102a and the WDM device 104a are connected via an optical fiber cable 130a between a remote communication unit 110a included in the WDM device 102a and a remote communication unit 120a included in the WDM device 104a. The WDM device 102c and the WDM device 104c are connected via an optical fiber cable 130b between a remote communication unit 110c included in the WDM device 102c and a remote communication unit 120c included in the WDM device 104c. The distance between the WDM device 102a and the WDM device 104a and the distance between the WDM device 102c and the WDM device 104c are, for example, a long distance of about several tens of kilometers.

  The WDM apparatus 102a receives optical signals from the networks NW1 and NW2. Further, the WDM apparatus 102a receives an optical signal obtained by electro-optically converting the optical signal received by the WDM apparatus 102b from each of the networks NW3 and NW4 from the WDM apparatus 102b via the optical fiber cable 132a. Then, the WDM apparatus 102a generates an optical signal obtained by wavelength division multiplexing signals received from the networks NW1 to NW4, and transmits the optical signal to the WDM apparatus 104a via the optical fiber cable 130a.

  Further, the WDM apparatus 102a receives an optical signal obtained by wavelength division multiplexing of signals received from the networks NW1 'to NW4' by the WDM apparatus 104a from the WDM apparatus 104a via the optical fiber cable 130a. Then, the WDM apparatus 102a demultiplexes the wavelength division multiplexed optical signal received from the WDM apparatus 104a. Then, the WDM device 102a transmits the signals transmitted from the networks NW1 'and NW2' to the networks NW1 and NW2, respectively. In addition, the WDM apparatus 102a transmits the signals transmitted from the networks NW3 'and NW4' to the networks NW3 and NW4 via the optical fiber cable 132a and the WDM apparatus 102b, respectively.

  The WDM apparatus 102c receives optical signals from the networks NW5 and NW6. Also, the WDM apparatus 102c receives an optical signal obtained by electro-optically converting the optical signal received by the WDM apparatus 102d from each of the networks NW7 and NW8 from the WDM apparatus 102d via the optical fiber cable 132b. Then, the WDM apparatus 102c generates an optical signal obtained by wavelength division multiplexing signals received from the networks NW5 to NW8, and transmits the optical signal to the WDM apparatus 104c via the optical fiber cable 130b.

  Also, the WDM apparatus 102c receives an optical signal obtained by wavelength division multiplexing signals received from the networks NW5 'to NW8' by the WDM apparatus 104c from the WDM apparatus 104c via the optical fiber cable 130b. Then, the WDM apparatus 102c demultiplexes the wavelength division multiplexed optical signal received from the WDM apparatus 104c. Then, the WDM apparatus 102c transmits signals transmitted from the networks NW5 'and NW6' to the networks NW5 and NW6, respectively. The WDM apparatus 102c transmits signals transmitted from the networks NW7 'and NW7' to the networks NW7 and NW8 via the optical fiber cable 132b and the WDM apparatus 102d, respectively.

  Note that the configuration and function of each of the WDM devices 104a to 104d are the same as the configuration and function of each of the WDM devices 102a to 102d, and thus description thereof is omitted.

  Normally, as described above, each of the WDM devices 102a and 102b communicates with each of the WDM devices 104a and 104b via the optical fiber cable 130a, and each of the WDM devices 102c and 102d passes through the optical fiber cable 130b. It communicates with each of the WDM devices 104c and 104d. On the other hand, when a failure occurs in the optical fiber cable 130a, for example, by connecting the remote communication unit 110a of the WDM device 102a and the remote communication unit 110d of the WDM device 102d with an optical fiber cable, the WDM devices 102a to 102d are connected. Each communicates with each of the WDM apparatuses 104a to 104d via the optical fiber cable 130b. When a failure occurs in the optical fiber cable 130b, for example, the remote communication unit 110b of the WDM apparatus 102b and the remote communication unit 110c of the WDM apparatus 102c are connected by an optical fiber cable, so that the WDM apparatuses 102a to 102d are connected. Each communicates with each of the WDM apparatuses 104a to 104d via the optical fiber cable 130a. Thus, a stable communication environment can be ensured by multiplexing optical fiber cables.

  The management terminal 106 manages the WDM apparatuses 102a to 102d and the WDM apparatuses 104a to 104d based on an instruction input from the system administrator. For example, the WDM apparatus 102 a performs setting of the WDM apparatus 102 a based on setting information input from the management terminal 106. Further, the WDM apparatus 102a transmits the setting information held by the WDM apparatus 102a to the WDM apparatus 104a, and causes the WDM apparatus 104a to be set based on the transmitted setting information. Also, the WDM apparatus 102a transmits setting request data to the WDM apparatus 104a, receives setting information held by the WDM apparatus 104a from the WDM apparatus 104a, and sets the WDM apparatus 102a based on the received setting information.

  As described above, according to the optical communication system 100 according to the present embodiment, the system administrator can set the WDM devices 102a to 102d using the management terminal 106 directly connected to the WDM device 102a. The WDM devices 104a to 104d can be set. Therefore, even if the optical communication system 100 is increased in distance and the WDM device 102a and the WDM device 104a are arranged at distant locations, the system administrator is required to set the WDM devices 102a and 104a. It is not necessary to move the distance and can respond quickly.

  FIG. 2 shows an example of the configuration of the WDM apparatuses 102a and 102b and the WDM apparatuses 104a and 104b according to the present embodiment. In the present embodiment, as will be described below, the WDM devices 102a and 102b and the WDM devices 104a and 104b each have two local communication units. However, the WDM device according to the present invention includes the WDM device 102a and the WDM device. The device 102b may be integrated, or the WDM device 104a and the WDM device 104b may be integrated into one WDM device having four or more local communication units. Note that the configuration and function of the WDM apparatus 104a are the same as the configuration and function of the WDM apparatus 102a, and thus description thereof is omitted.

  The WDM apparatus 102a includes a remote communication unit 110a, a plurality of local communication units 112a and 112b, a control unit 114a, a plurality of switching units 200a and 200b, and a plurality of transmission paths 202a and 202b. The WDM apparatus 102b includes a remote communication unit 110b, a plurality of local communication units 112c and 112d, a plurality of switching units 200a and 200b, and a plurality of transmission paths 202a and 202b.

  Each of the local communication units 112a to 112d has a local communication port 210a to 210d connected to an external communication device arranged in each of the networks NW1 to NW4, and is connected to each of the local communication ports 210a to 210d. The optical signals are received from the communication devices arranged in each of the networks NW1 to NW4. In addition, each of the local communication units 112a to 112d has photoelectric conversion units 208a to 208d, respectively, and converts the optical signal received via each of the local communication ports 210a to 210d into an electric signal, thereby switching the switching units 200a to 200d. 200d is supplied respectively.

  In addition, each of the local communication units 112a to 112d converts the electrical signal supplied from each of the switching units 200a to 200d into an optical signal by each of the photoelectric conversion units 208a to 208d. Then, each of the local communication units 112a to 112d supplies the optical signals converted by the photoelectric conversion units 208a to 208d to the networks NW1 to NW4 via the local communication ports 210a to 210d, respectively.

  The remote communication unit 110a receives each of the plurality of electrical signals converted by the plurality of local communication units 112a and 112b via the switching units 200a and 200b. The remote communication unit 110a includes a photoelectric conversion unit 206a, and converts each of the received plurality of electrical signals into a plurality of optical signals having different wavelengths. In addition, the remote communication unit 110b receives the plurality of electric signals converted by the plurality of local communication units 112c and 112d, respectively, via the switching units 200c and 200d. The remote communication unit 110b has a photoelectric conversion unit 206b, converts each of the received plurality of electrical signals into a plurality of optical signals having different wavelengths, and transmits the converted signals to the remote communication unit 110a via the cascade port 205. Supply. The remote communication unit 110a has a remote communication port 204 connected to the WDM device 104a, and transmits the optical signal multiplexed by the photoelectric conversion units 206a and 206b to the WDM device 104a.

  In addition, the remote communication unit 110 a receives an optical signal from the WDM device 104 a via the remote communication port 204. The remote communication unit 110a demultiplexes the optical signal received via the remote communication port 204, and converts the demultiplexed optical signals into a plurality of electrical signals by the photoelectric conversion unit 206a. Then, the remote communication unit 110a supplies the electrical signal converted by the photoelectric conversion unit 206a to each of the switching units 200a and 200b. Also, the remote communication unit 110b receives an optical signal from the remote communication unit 110a via the cascade port 205. Then, the remote communication unit 110b demultiplexes the optical signal received via the cascade port 205, and converts the demultiplexed optical signals into a plurality of electrical signals by the photoelectric conversion unit 206b. Then, the remote communication unit 110b supplies the electrical signal converted by the photoelectric conversion unit 206b to each of the switching units 200c and 200d.

  Each of the switching units 200a to 200d is provided on a plurality of transmission paths 202a to 202d that connect each of the plurality of local communication units 112a to 112d and the remote communication unit 110a or 110b, respectively. Then, each of the switching units 200a to 200d selects either the electrical signal supplied from the local communication units 112a to 112d and the setting data or setting request data supplied from the control unit 114a, and the remote communication unit 110a. To the WDM apparatus 104a. In addition, each of the switching units 200a to 200d includes counters 201a to 201d that measure the amount of communication in the switching units 200a to 200d, respectively. In addition, it is preferable that switching part 200a-200d is comprised with a switch chip.

  Based on an instruction input from the management terminal 106, the control unit 114a requests setting data including setting information of the WDM apparatus 102a, setting data including setting information of the WDM apparatus 104a, and setting information of the WDM apparatus 104a. Various data such as setting request data is generated and supplied to at least one of the switching units 200a to 200d. Then, the control unit 114a interrupts setting data including setting information for setting the WDM device 104a to any one of the plurality of electric signals supplied from the plurality of local communication units 112a to 112d to the remote communication unit 110a. The setting data is supplied to the WDM apparatus 104a by the remote communication unit 110a. In addition, the control unit 114a interrupts setting request data for requesting acquisition of setting information of the WDM device 104a to any one of a plurality of electrical signals supplied from the plurality of local communication units 112a to 112d to the remote communication unit 110a. Then, setting information is acquired from the WDM apparatus 104a by supplying the setting request data to the WDM apparatus 104a by the remote communication unit 110a. Then, the control unit 114a sets the setting information acquired from the WDM device 104a in the WDM device 102a.

  Here, the control unit 114a refers to the communication amount in the switching units 200a to 200d measured by each of the counters 201a to 201d of the plurality of switching units 200a to 200d, and selects one switching unit with the smallest communication amount. By selecting and supplying the setting data or the setting request data to the one switching unit, the setting data or the setting request data may be interrupted to the electric signal supplied from the local communication unit by the one switching unit. Further, the control unit 114a refers to the communication amount in the switching units 200a to 200d, selects two or more switching units with a small communication amount, and supplies the same setting data or setting request data to the two or more switching units. By doing so, the setting data or the setting request data may be interrupted to the electrical signal supplied from the local communication unit by the two or more switching units.

  Further, prior to transmission of the setting data or setting request data, the control unit 114a performs a loopback for testing whether or not the WDM device 104a can normally communicate with each of the plurality of switching units 200a to 200d. A test packet may be supplied and transmitted to the WDM apparatus 104a. The control unit 114a communicates normally in a plurality of optical signals having different wavelengths by supplying a loopback test packet to each of the plurality of switching units switching units 200a to 200d and transmitting the packet from the remote communication unit 110a to the WDM device 104a. One or two or more switching units corresponding to the wavelength determined to be normally communicable based on the test result are selected, and the one or more switching units are selected. Setting data or setting request data may be supplied.

  In this way, by selecting the switching unit that supplies the setting data or the setting request data based on the communication state of the optical signal corresponding to the plurality of switching units 200a to 200d, the setting data or the setting request data is reliably transmitted to the WDM device. 104a. In addition, by supplying the same setting data or setting request data to two or more switching units, the setting data or setting request data can be reliably transmitted by multiplexing the setting data or setting request data and transmitting it to the WDM device 104a. Can be supplied to the WDM device 104a.

  As another example, one of a plurality of optical signals having different wavelengths may be used as a dedicated channel for transmitting setting data or setting request data. In this way, setting data or setting request data can be transmitted without affecting other normal communications, and settings of the WDM apparatuses 102a and 104a can be performed.

  FIG. 3 shows an example of the configuration of the control unit 114a according to the present embodiment. The control unit 114a includes a packet reception monitoring unit 300, a packet analysis unit 302, a packet generation unit 304, a central processing unit 306, a communication processing unit 308, a setting information storage unit 310, and a management port 312. Note that the configuration and function of the control unit 124a are the same as the configuration and function of the control unit 114a, and thus description thereof is omitted.

  The packet reception monitoring unit 300 is connected to the switching units 200a to 200d, monitors the packet received by the remote communication unit 110a from the WDM device 104a, and the control unit 114a acquires the destination packet. Then, the packet analysis unit 302 analyzes the packet acquired by the packet reception monitoring unit 300 and notifies the central processing unit 306 of it. The central processing unit 306 performs various operations according to the analysis content notified by the packet analysis unit 302. Specifically, when the packet analysis unit 302 notifies the central processing unit 306 that the packet received by the packet reception monitoring unit 300 includes setting data, the central processing unit 306 sends the setting data to the setting information storage unit 310. The WDM apparatus 102a is set based on the setting data. Further, when the packet analysis unit 302 notifies the central processing unit 306 that the packet received by the packet reception monitoring unit 300 includes the setting request data, the central processing unit 306 stores the setting data stored in the setting information storage unit 310. Is generated by the packet generation unit 304 and transmitted to the WDM device 104a.

  The management terminal 106 is connected to the management port 312 via a metallic cable such as a serial cable or an Ethernet (registered trademark) cable. The communication processing unit 308 notifies the central processing unit 306 of the instruction input input from the management terminal 106 via the management port 312. Specifically, the management terminal 106 has an instruction to transmit the setting data of the WDM device 102a to the WDM device 104a, an instruction to acquire the setting data of the WDM device 104a and set it to the WDM device 102a, A loopback test packet is transmitted to the WDM apparatus 104a, and an instruction or the like indicating that a loopback test should be performed is input.

  Based on an instruction input from the management terminal 106, the central processing unit 306 causes the packet generation unit 304 to generate a packet including setting data or setting request data or a loopback test packet, and at least one of the switching units 200a to 200d. By selecting and supplying one, it is transmitted to the WDM apparatus 104a.

  The control unit 114a transmits a packet including setting data or setting request data or a loopback test packet to the WDM device 104a by a packet in the data link layer of the OSI reference model, with the MAC address of the WDM device 104a as a destination. .

  FIG. 4 shows an example of the configuration of a packet 400 including setting data or setting request data according to the present embodiment. The packet 400 includes a source address (DA), a destination address (SA), a data length (Length), data (Data), and an error correction code (CRC).

  The source address (SA) and the destination address (DA) are MAC addresses (AA ...) that are identification information of the WDM device 102a or WDM device 104a. The data length (Length) indicates the size (LL ...) of the packet 400. The error correction code (CRC) is a code (CC ...) for detecting a burst error of data.

  Data (Data) includes packet ID (FF), model ID (MM), version (VV...), Patch level (PP), build ID (BB), hardware revision ID (HH...), Loop. Back test number (NN ...), loop back test total number (TT ...), unit status (UU), module status (MM ...), spot status (SS ...), setting data or setting Request data (RR ...) is included.

  The packet ID is identification information of the packet 400, and indicates which packet is a packet including setting data, a packet including setting request data, a packet notifying completion of setting by setting data, a loopback test packet, or the like. . The model ID is model identification information of the WDM apparatus 102a. The version indicates the version of the WDM apparatus 102a. The patch level indicates the patch level of the WDM apparatus 102a. The build ID indicates the build ID of the WDM apparatus 102a. The hardware revision ID is identification information of the hardware revision of the WDM apparatus 102a.

  The loopback test number indicates a sequence number of the loopback test. The loopback test total number indicates the total number of times that the loopback test has been performed. The unit status indicates the state of each of the WDM apparatuses 102a to 102d. The module status indicates the state of each of the plurality of remote communication units, the plurality of local communication units, and the plurality of control units. The spot status indicates a state of a chip included in the WDM apparatuses 102a to 102d.

  The setting data is data including setting information stored in the setting information storage unit 310 of the WDM apparatus 102a. The setting request data is data indicating that acquisition of setting information of the WDM apparatus 104a is requested. Note that the setting data may include, as setting information, identification information of a management apparatus that is a transmission destination of a trap by SNMP, that is, identification information of an SNMP manager that manages the WDM apparatus 102a or 104a as an SNMP agent. The SNMP manager identification information is, for example, an IP address. In addition, the setting information storage unit 310 is, for example, a MIB (Management Information Base), and the setting information may be information stored in the MIB.

  FIG. 5 shows an example of a communication sequence of the optical communication system 100 according to the present embodiment. First, the management terminal 106 inputs an instruction to the WDM apparatus 102a so as to transmit setting data or setting request data to the WDM apparatus 104a (S500). Upon receiving an instruction input from the management terminal 106, the WDM apparatus 102a interrupts a loopback test packet to each of a plurality of optical signals having different wavelengths and transmits the packet to the WDM apparatus 104a (S502). By receiving a loopback test packet transmitted from the WDM device 104a (S504), a channel that can be normally communicated is selected (S506). Then, the WDM apparatus 102a interrupts a packet including setting data or setting request data into the channel selected in S506, and transmits the packet to the WDM apparatus 104a (S508).

  When the WDM device 104a receives a packet including setting data or setting request data from the WDM device 102a, the WDM device 104a analyzes the received packet (S510) and determines which of the setting data and the setting request data includes the packet (S510). S512). If it is determined that the packet includes setting data, the WDM apparatus 104a sets the WDM apparatus 104a based on the setting information of the WDM apparatus 102a included in the setting data (S514). On the other hand, if it is determined that the packet includes the setting request data, the WDM apparatus 104a interrupts the loopback test packet to each of the channels of a plurality of optical signals having different wavelengths and transmits them to the WDM apparatus 102a (S516). In response to this, a loopback test packet transmitted from the WDM apparatus 102a is received (S518), thereby selecting a normally communicable channel (S520). Then, the WDM apparatus 104a interrupts the packet including the setting data into the channel selected in S520, and transmits the packet to the WDM apparatus 102a (S522). Note that the WDM apparatus 104a does not select a channel that can be normally communicated by transmitting a loopback test packet, and the setting data is transmitted to the channel through which the packet including the setting data or the setting request data is transmitted from the WDM apparatus 102a. May be interrupted and transmitted to the WDM apparatus 102a.

  When the WDM apparatus 102a receives a packet including setting data from the WDM apparatus 104a, the WDM apparatus 102a analyzes the received packet (S524), and sets the WDM apparatus 102a based on the setting information of the WDM apparatus 104a included in the setting data ( S526).

  As described above, according to the optical communication system 100 according to the present embodiment, the WDM device 104a can be set with the setting information of the WDM device 102a using the management terminal 106 directly connected to the WDM device 102a. In addition, the WDM apparatus 102a can be set with the setting information of the WDM apparatus 104a. Therefore, even when the WDM device 102a and the WDM device 104a are arranged at distant locations, the system administrator does not need to move over a long distance in order to change the settings of the WDM devices 102a and 104a. The setting can be changed quickly.

  As mentioned above, although this invention was demonstrated using embodiment, the technical scope of this invention is not limited to the range as described in the said embodiment. Various modifications or improvements can be added to the above embodiment. It is apparent from the scope of the claims that the embodiments added with such changes or improvements can be included in the technical scope of the present invention.

1 is a diagram illustrating an example of a configuration of an optical communication system 100. FIG. It is a figure which shows an example of a structure of WDM apparatus 102a and 102b and WDM apparatus 104a and 104b. It is a figure which shows an example of a structure of the control part 114a. It is a figure which shows an example of a structure of the packet 400 containing setting data or setting request data. 2 is a diagram illustrating an example of a communication sequence of the optical communication system 100. FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 100 Optical communication system 102 WDM apparatus 104 WDM apparatus 106 Management terminal 110 Remote communication part 112 Local communication part 114 Control part 120 Remote communication part 124 Control part 130 Optical fiber cable 132 Optical fiber cable 134 Optical fiber cable 136 Metallic cable 200 Switching part 201 Counter 202 Transmission path 204 Remote communication port 205 Cascade port 206 Photoelectric conversion unit 208 Photoelectric conversion unit 210 Local communication port 220 Switching unit 221 Counter 222 Transmission path 224 Remote communication port 225 Cascade port 226 Photoelectric conversion unit 228 Photoelectric conversion unit 230 Local communication port 300 Packet reception monitoring unit 302 Packet analysis unit 304 Packet generation unit 306 Central processing unit 308 Communication processing unit 310 Setting Information Storage Unit 312 Management Port 400 Packet

Claims (13)

A WDM device that relays an optical signal using wavelength division multiplexing,
A plurality of local communication units having a local communication port to which an external communication device is connected, receiving an optical signal from the communication device, and converting the optical signal into an electrical signal;
A remote communication port to which another WDM device is connected, each of the plurality of electrical signals converted by the plurality of local communication units is converted into a plurality of optical signals having different wavelengths, and multiplexed; A remote communication unit that transmits to other WDM devices;
Setting data including setting information of the other WDM device is interrupted to any of the plurality of electrical signals supplied from the plurality of local communication units to the remote communication unit, and the setting data is transmitted by the remote communication unit. A control unit for transmitting to the other WDM device;
A plurality of transmission lines connecting each of the plurality of local communication units and the remote communication unit;
Select each of the electrical signal provided from the local communication unit and the setting data supplied from the control unit provided on each of the plurality of transmission paths, and supply the remote communication unit to the other A plurality of switching units to be transmitted to the WDM device;
With
The control unit is supplied from the local communication unit by the one switching unit by selecting one of the plurality of switching units and supplying the setting data to the one switching unit. And a WDM device for interrupting the setting data into the electrical signal . Each of the plurality of switching units includes a counter that measures the amount of communication in each of the plurality of switching units.
The control unit refers to the communication amount measured by each of the plurality of switching units, selects the one switching unit with the smallest communication amount, and supplies the setting data to the one switching unit The WDM apparatus according to claim 1 , wherein the setting data is interrupted to the electrical signal supplied from the local communication unit by the one switching unit. The control unit can normally communicate with the plurality of optical signals having different wavelengths by supplying a loopback test packet to each of the plurality of switching units and causing the remote communication unit to transmit the packet to the other WDM device. We tested whether it is the one to select the switching unit, according to claim supplies the setting data to the one of the switching unit to the wavelength is determined that communication is possible successfully on the basis of the test results 2. The WDM apparatus according to 1 . The control unit selects two or more switching units of the plurality of switching units, and supplies the same setting data to the two or more switching units, so that the two or more switching units can perform two or more. 4. The WDM apparatus according to claim 1 , wherein the setting data is interrupted to two or more electric signals supplied from each of the local communication units. 5. Wherein the control unit, the MAC address of the other WDM apparatus as a destination, according the packet in the data link layer of the OSI reference model claims 1 to transmit the configuration data to the other WDM apparatus in any one of the 4 WDM device. Wherein, according to any of the identification information of the SNMP manager that manages the WDM apparatus of claims 1 to be transmitted to the other WDM apparatus the setting data by the remote communication unit including as said setting information 5 WDM device. A WDM device that relays an optical signal using wavelength division multiplexing,
A plurality of local communication units having a local communication port to which an external communication device is connected, receiving an optical signal from the communication device, and converting the optical signal into an electrical signal;
A remote communication port to which another WDM device is connected, each of the plurality of electrical signals converted by the plurality of local communication units is converted into a plurality of optical signals having different wavelengths, and multiplexed; A remote communication unit that transmits to other WDM devices;
The setting request data for requesting acquisition of setting information of the other WDM device is interrupted to any of the plurality of electrical signals supplied from the plurality of local communication units to the remote communication unit, and the setting request data is A control unit that acquires the setting information from the other WDM device by causing the remote communication unit to transmit to the other WDM device ;
A plurality of transmission lines connecting each of the plurality of local communication units and the remote communication unit;
Select one of the electrical signal provided from the local communication unit and the setting request data supplied from the control unit, which is provided on each of the plurality of transmission paths, and supplies the selected selection request data to the remote communication unit. A plurality of switching units to be transmitted to the WDM apparatus
With
The control unit is supplied from the local communication unit by the one switching unit by selecting the switching unit of the plurality of switching units and supplying the setting request data to the one switching unit. A WDM device for causing the setting request data to be interrupted to the electrical signal . 8. The WDM apparatus according to claim 7 , wherein the control unit sets the setting information acquired from the other WDM apparatus in the WDM apparatus.   The control unit can normally communicate with the plurality of optical signals having different wavelengths by supplying a loopback test packet to each of the plurality of switching units and causing the remote communication unit to transmit the packet to the other WDM device. And selecting the one switching unit corresponding to the wavelength determined to be normally communicable based on the test result, and supplying the setting request data to the one switching unit. Item 9. The WDM device according to Item 7 or 8. An optical communication system comprising a first WDM device and a second WDM device that communicate with each other using wavelength division multiplexing,
The first WDM device includes:
A plurality of first local communication units having a first local communication port to which an external communication device is connected, receiving an optical signal from the communication device, and converting the optical signal into an electrical signal;
A second remote communication port to which the second WDM device is connected; and the plurality of electrical signals converted by the plurality of first local communication units are converted into a plurality of optical signals having different wavelengths, respectively. A first remote communication unit that multiplexes and transmits to the second WDM device;
Setting data including setting information of the second WDM device is interrupted to any of the plurality of electrical signals supplied from the plurality of first local communication units to the first remote communication unit, and the setting data is transmitted to the first signal. A first control unit for transmitting to the second WDM device by one remote communication unit ;
A plurality of transmission lines connecting each of the plurality of first local communication units and the first remote communication unit;
Select one of the electrical signal provided from the first local communication unit and the setting data supplied from the first control unit, which is provided on each of the plurality of transmission paths, and the first remote communication unit A plurality of switching units for supplying and transmitting to the second WDM device;
Have
The first controller selects one of the plurality of switching units and supplies the setting data to the one switching unit, whereby the first local communication is performed by the one switching unit. The setting data is interrupted to the electric signal supplied from the unit,
The second WDM device includes:
A second remote communication port connected to the first WDM device; receiving the plurality of optical signals multiplexed from the first WDM device; and converting the plurality of optical signals into a plurality of electrical signals. Two remote communication units;
A plurality of second locals having a second local communication port to which an external communication device is connected, converting the electrical signal converted by the second remote communication unit into an optical signal, and transmitting the optical signal to the external communication device; A communication department;
The setting data transmitted from the first WDM device is acquired from the plurality of electrical signals converted by the second remote communication unit, and the setting information included in the setting data is set in the second WDM device. An optical communication system having two control units.   The first control unit supplies a loopback test packet to each of the plurality of switching units and transmits the loopback test packet from the first remote communication unit to the second WDM device, so that the plurality of optical signals having different wavelengths are normal. The one switching unit corresponding to the wavelength determined to be normally communicable based on the test result is selected, and the setting data is supplied to the one switching unit. The optical communication system according to claim 10. An optical communication system comprising a first WDM device and a second WDM device that communicate with each other using wavelength division multiplexing,
The first WDM device includes:
A plurality of first local communication units having a first local communication port to which an external communication device is connected, receiving an optical signal from the communication device, and converting the optical signal into an electrical signal;
A first remote communication port to which the second WDM device is connected; and the plurality of electrical signals converted by the plurality of first local communication units are converted into a plurality of optical signals having different wavelengths, respectively. A first remote communication unit that multiplexes and transmits to the second WDM device;
The setting request data for requesting acquisition of setting information of the second WDM device is interrupted to any of the plurality of electrical signals supplied from the plurality of first local communication units to the first remote communication unit, and the setting is performed. A first control unit for transmitting request data to the second WDM device by the first remote communication unit ;
A plurality of transmission lines connecting each of the plurality of first local communication units and the first remote communication unit;
The first remote communication unit is provided on each of the plurality of transmission paths, and selects either the electrical signal supplied from the first local communication unit or the setting request data supplied from the first control unit. A plurality of first switching units that are supplied to and transmitted to the second WDM device;
Have
The first control unit selects one of the plurality of first switching units and supplies the setting request data to the one first switching unit, whereby the one first switching unit is selected. The setting request data is interrupted to the electrical signal supplied from the first local communication unit by one switching unit,
The second WDM device includes:
A plurality of second local communication units having a second local communication port to which an external communication device is connected, receiving an optical signal from the communication device, and converting the optical signal into an electrical signal;
A second remote communication port to which the first WDM device is connected; and the plurality of electrical signals converted by the plurality of second local communication units are converted into a plurality of optical signals having different wavelengths, respectively. A second remote communication unit for multiplexing and transmitting to the first WDM device;
In response to the setting request data transmitted from the first WDM device, the second WDM device receives one of the plurality of electrical signals supplied from the plurality of second local communication units to the second remote communication unit. A second control unit that interrupts the setting data including the setting information and transmits the setting data to the first WDM device by the second remote communication unit ;
A plurality of transmission lines connecting each of the plurality of second local communication units and the second remote communication unit;
Select one of the electrical signal provided from the second local communication unit and the setting data supplied from the second control unit, which is provided on each of the plurality of transmission paths, and sends to the second remote communication unit A plurality of second switching units for supplying and transmitting to the first WDM device;
Have
The second control unit selects one second switching unit from the plurality of second switching units, and supplies the setting data to the one second switching unit, whereby the one second switching unit is selected. An optical communication system in which the setting data is interrupted to the electric signal supplied from the second local communication unit by a switching unit .   The first control unit supplies a loopback test packet to each of the plurality of first switching units and transmits the loopback test packet from the first remote communication unit to the second WDM device, thereby the plurality of optical signals having different wavelengths. The first switching unit corresponding to the wavelength determined to be normally communicable based on the test result is selected, and the one first switching unit is selected. Supply the setting request data to
  The second control unit supplies a loopback test packet to each of the plurality of second switching units and transmits the loopback test packet from the second remote communication unit to the first WDM device, thereby the plurality of optical signals having different wavelengths. The first switching unit corresponding to the wavelength determined to be normally communicable based on the test result, and the one second switching unit is selected. The optical communication system according to claim 12, wherein the setting data is supplied to the optical communication system.

Images