JPWO2005036782A1 - Expandable wavelength division multiplexing transmission equipment - Google Patents

Abstract

Provided is a WDM transmission apparatus that can flexibly cope with changes in system specifications, improves expandability and operability, and achieves effective use of network resources. An uplink module slot 11 is provided in the WDM transmission apparatus main body housing 10, and one uplink module selected from a plurality of uplink modules 101 and 210 having different transmission distances is detachably attached to the uplink module slot 11. The uplink module 101 includes a stacking port 103 in addition to the WDM port 102, and can be cascaded with other uplink modules 201.

Description

  The present invention relates to a wavelength division multiplexing (hereinafter referred to as WDM) transmission apparatus that enables long-distance and high-speed transmission by wavelength multiplexing of a plurality of channels, and particularly has a plurality of local ports and at least one remote port. The present invention relates to a WDM transmission apparatus.

2. Description of the Related Art In recent years, various WDM transmission apparatuses have been provided that enable long-distance transmission by wavelength multiplexing a plurality of gigabit Ethernet (Ethernet is a registered trademark, the same applies hereinafter) to a single mode optical fiber. As a commercially available product, for example, there is a WDM transmission apparatus that can connect up to eight Gigabit Ethernet and can transmit a maximum of 20 Gbps / 2 cores (Full Duplex). Such a WDM transmission apparatus is an indispensable communication device such as a wide-area LAN (local-area network) and an FTTH (fiber-to-the-home), for constructing a future broadband network.
Japanese Patent Application Laid-Open No. 2000-324050 (hereinafter referred to as Patent Document 1) has a plurality of local modules, at least one remote module, and one management module, and combines general-purpose modules in a single slot into one cage. A WDM transmission apparatus to be incorporated is described. The general-purpose module is compatible with various media such as ATM, FDDI, and Ethernet (registered trademark) (paragraphs 0003, 0014, FIGS. 1 and 2).
Japanese Patent Application Laid-Open No. 11-095060 (hereinafter referred to as Patent Document 2) discloses a cascade type optical multiplexing apparatus as an example of an optical WDM transmission apparatus. In this conventional WDM transmission apparatus, all channels are separated and multiplexed by cascading optical blocks capable of wavelength separation and multiplexing. For example, when 8-channel wavelength division multiplexed light is input to a remote port, channels 1 to 4 are sequentially separated by one optical block, and the remaining channels 5 to 8 are cascaded to another optical block. Are similarly separated. Conversely, the optical signals of 8 channels are sequentially multiplexed through these optical blocks and transmitted from the remote port as wavelength multiplexed light (paragraphs 0024 to 27, FIGS. 1, 8, and 9).
However, although the WDM transmission apparatus of Patent Document 1 describes increasing the number of remote modules, there is no mention of changing the WDM transmission distance. The change of the transmission distance often occurs when the installation location changes or the in-house circumstances change, and it is very practically important that the transmission distance can be easily changed.
As a structure of the WDM transmission apparatus, generally, a large number of slots are provided in the vertical direction on the front surface or the rear surface of the housing of the WDM transmission apparatus, and necessary modules are mounted therein. However, Patent Document 1 does not disclose a specific cage configuration that incorporates a general-purpose module. Further, in the cage configuration of Patent Document 1, it is necessary to prepare a large number of slots in one housing, and if a local port corresponding to the number of slots is used, the resources of the WDM network can be effectively used. Yes, but not enough on a small network.
Similarly, the WDM transmission apparatus disclosed in Patent Document 2 accommodates 4 channels or 8 channels in one apparatus housing. Therefore, if the same number of LANs are connected, resources can be used effectively, but only one or two LANs may be connected depending on the scale of the LAN, the installation location, or in-house circumstances.
Thus, if there is a local port that is not connected, the WDM characteristic of high-speed and large-capacity transmission cannot be fully utilized. Conversely, if the 4-channel WDM transmission apparatus was initially considered sufficient, but the situation changed and 6 channels were required, in this example, it is necessary to purchase and replace an 8-channel WDM transmission apparatus. There is. The need for such a transmission device replacement not only impairs flexibility as a WDM transmission system and increases costs, but also wastes resources because two of the eight channels are not used. . In the WDM transmission apparatus described in Patent Document 2, it is assumed that optical blocks are cascade-connected in one housing to perform channel separation and multiplexing, and the same problem occurs.
Therefore, an object of the present invention is to provide a WDM transmission apparatus that can flexibly cope with changes in system specifications.
Another object of the present invention is to provide a WDM transmission apparatus that can easily expand the system and can achieve effective use of network resources.

According to the first aspect of the present invention, in a wavelength division multiplexing transmission apparatus having a plurality of local ports and at least one remote port, a housing having at least a remote module slot and a plurality of remote ports having different transmission distances. Remote module, and one remote module selected from the plurality of remote modules is detachably attached to the remote module slot.
At least one of the plurality of remote modules is optically connected to the remote port, performs multiplexing and demultiplexing of light of a predetermined wavelength, and passes optical signal of other wavelengths, and the optical multiplexing And a stacking port for optically connecting to the demultiplexing means, emitting the signal light that has passed through the optical multiplexing / demultiplexing means to the outside, and receiving the signal light from the outside.
Preferably, the housing further includes a management module slot, and an internal state of the wavelength division multiplexing transmission apparatus is remotely monitored by a management module mounted in the management module slot.
According to a second aspect of the present invention, in a system including at least a first wavelength division multiplexing transmission device and a second wavelength division multiplexing transmission device,
The first wavelength division multiplexing transmission device includes a first remote module selected from a plurality of remote modules having remote ports with different transmission distances, and a first remote module slot in which the first remote module is detachably attached. The first remote module is optically connected to the remote port of the first remote module, performs multiplexing and demultiplexing of the light of the first wavelength group, and sets the second wavelength group other than the first wavelength group. First optical multiplexing / demultiplexing means for allowing light to pass through, optically connected to the first optical multiplexing / demultiplexing means, emitting signal light that has passed through the first optical multiplexing / demultiplexing means to outside, and receiving signal light from outside A first stacking port for
The second wavelength multiplexing / demultiplexing device includes a second remote module selected from the plurality of remote modules, and a second remote module slot in which the second remote module is detachably attached, and the second remote module Comprises second optical multiplexing / demultiplexing means for optically connecting to the remote port of the second remote module and performing multiplexing and demultiplexing of the light of the second wavelength group,
The first wavelength demultiplexing transmission apparatus and the second wavelength demultiplexing transmission apparatus are accommodated in one unit, and the first stacking port of the first wavelength demultiplexing transmission apparatus and the second wavelength demultiplexing transmission apparatus The second remote port is optically connected by an optical cable.
The first wavelength division multiplexing transmission device further includes a first management module mounted in a management module slot, and the second wavelength division multiplexing transmission device further includes a second management module mounted in the management module slot, It is preferable that the internal state of the first wavelength division multiplexing transmission device and the second wavelength division multiplexing transmission device is remotely monitored by connecting the first and second management modules.
As described above, according to the present invention, since one remote module selected from a plurality of remote modules having different transmission distances is detachably attached to the remote module slot of the housing, it is most suitable for the required transmission distance. A remote module can be selected and arrived, and a change in transmission distance can be easily handled.
Further, since the stacking port optically connected to the remote port is provided in the remote module, it is possible to cascade another WDM transmission device and easily expand the number of local ports. Furthermore, it becomes possible to connect the remote port and the stacking port to separate WDM transmission apparatuses, respectively, and the expandability and flexibility of the system configuration can be greatly improved.

FIG. 1 is a perspective view showing a schematic configuration and functions of a WDM transmission apparatus according to an embodiment of the present invention.
FIG. 2 is a perspective view of a WDM transmission apparatus system in which two WDM transmission apparatuses according to the present embodiment are unitized.
FIG. 3 is a perspective view of a WDM transmission apparatus system in which two WDM transmission apparatuses according to the present embodiment are cascade-connected.
4 is a schematic block diagram showing an internal circuit of the WDM transmission apparatus system shown in FIG.
FIG. 5 is a front view showing a WDM transmission apparatus system in which the units of FIG. 2 are stacked in two stages.
FIG. 6 is a diagram showing a connection form of the two-stage WDM transmission apparatus system shown in FIG.
FIG. 7A is a schematic system configuration diagram for explaining a loopback test operation when a system using the WDM transmission apparatus according to the present embodiment is constructed.
FIG. 7B is a schematic system configuration diagram for explaining a loopback test operation from the SNMP manager.
FIG. 8A is a configuration diagram of a WDM transmission system for explaining a missing link function when the local port side is disconnected.
FIG. 8B is a configuration diagram of the WDM transmission system for explaining the missing link function when the remote port side is disconnected.
FIG. 9 is a network configuration diagram showing an example of a WDM transmission network using the WDM transmission apparatus according to the present invention.
FIG. 10 is a network configuration diagram showing another example of a WDM transmission network using a WDM transmission apparatus according to the present invention.

In FIG. 1, a main body housing 10 of the WDM transmission apparatus according to the present embodiment has a rectangular parallelepiped shape with a thickness of 1U (about 44 mm), and has one uplink module slot 11, one management module slot 12 and a plurality of modules on the front surface thereof. Local port slots 13 are provided.
An uplink module 101 or an uplink module 201 prepared in advance can be mounted in the uplink module slot 11. As will be described later, the uplink module 101 has a WDM port 102 which is a remote port (RP) and a stacking port (SP) 103 for cascade connection, and the WDM transmission apparatus is cascade-connected using the stacking port 103. can do. The uplink module 201 is provided with a WDM port 202 and is not provided with a stacking port. The user may select the uplink module 101 when expansion is required by cascade connection, and may select the uplink module 201 when expansion is not necessary.
As the uplink module 101 and the uplink module 201, modules having different transmission distances are prepared. Here, uplink modules 201.1, 201.2 and 201.3 with transmission distances of 50 km, 80 km and 120 km, respectively, are shown. The user can select an uplink module having a transmission distance most suitable for the distance to the partner WDM transmission apparatus.
A management module 104 or a management module 203 prepared in advance can be selectively attached to the management module slot 12. The management modules 104 and 203 in this embodiment are SNMP (Simple Network Management Protocol) management modules. The management module 104 is provided with an SNMP connection port 105 and SNMP stacking ports 106 and 109. The SNMP connection port 105 is connected to the SNMP manager via a network such as Ethernet, for example, and can remotely monitor the link state and power state of the WDM transmission apparatus. The management module 203 is provided with an SNMP connection port 204 and an SNMP stacking port 205.
Furthermore, in this embodiment, two local port slots 13 are provided, and optical transceiver modules corresponding to GBIC (Gigabit Interface Converter) are respectively mounted.
FIG. 2 is a perspective view of a WDM transmission apparatus system in which two WDM transmission apparatuses according to the present embodiment are unitized. Here, it is assumed that the uplink module 101 and the management module 104 are attached to the WDM transmission apparatus 1, and the uplink module 201 and the management module 203 are attached to the WDM transmission apparatus 2.
As shown in FIG. 2, the WDM transmission apparatuses 1 and 2 are accommodated in a unit frame 20 having a thickness of 1 U, arranged side by side. The compact 1U size allows it to be mounted on a 19-inch rack. Further, the WDM transmission apparatuses 1 and 2 can function as a single WDM transmission apparatus by cascade connection as described below. Therefore, it is meaningful to accommodate the WDM transmission apparatuses 1 and 2 in the unit frame 20 as shown in FIG.
In FIG. 3, the WDM transmission apparatus 1 according to the present embodiment can function as one WDM transmission apparatus by cascading another WDM transmission apparatus 2. Each of the WDM transmission apparatus 1 and the WDM transmission apparatus 2 has a module configuration as shown in FIG. 1, and here, as shown in FIG. 2, an uplink module 101 and a management module 104 are attached to the WDM transmission apparatus 1. It is assumed that the uplink module 201 and the management module 203 are attached to the WDM transmission apparatus 2.
In the WDM transmission apparatus 1, the uplink module 101 includes a WDM port 102 which is a remote port (RP) and a stacking port (SP) 103 for cascade connection. The management module 104 is an SNMP management module, and includes an SNMP connection port 105 and SNMP stacking ports 106 and 109. The SNMP connection port 105 is connected to the SNMP manager via a network such as Ethernet, for example, and can remotely monitor the link state and power state of the WDM transmission apparatus 1. Further, the WDM transmission apparatus 1 has two local ports 107 and 108, both of which are composed of optical transceiver modules corresponding to GBIC.
In the WDM transmission apparatus 2, the uplink module 201 has a WDM port 202 which is a remote port (RP). The management module 203 is an SNMP management module, and has an SNMP connection port 204 and a stacking port 205. Further, the WDM transmission apparatus 2 is also provided with two local ports 206 and 207, both of which consist of optical transceiver modules corresponding to GBIC.
According to this embodiment, the WDM port 102 of the WDM transmission apparatus 1 is connected to the single mode optical fiber cable 301, and the stacking port 103 is connected to the WDM port 202 of the WDM transmission apparatus 2 through the optical fiber cable 302. Further, the SNMP stacking port 106 of the management module 104 is connected to the SNMP connection port 204 of the WDM transmission apparatus 2 through the optical fiber cable 303.
By cascading in this way, the uplink module 101 and the uplink module 201 function as one uplink module, and the management module 104 and the management module 203 are also one management module for managing the WDM transmission apparatuses 1 and 2. Function. Therefore, the WDM transmission apparatus 1 that accommodates two GBIC ports can be upgraded to a WDM transmission apparatus that accommodates four GBIC ports by simply cascading the WDM transmission apparatus 2 that also accommodates two GBIC ports. Can do.
Although not shown in FIG. 3, the WDM transmission apparatuses 1 and 2 are each provided with a link test button for starting a loopback test.
4 is a schematic block diagram showing an internal circuit of the WDM transmission apparatus system shown in FIG. The components described in FIG. 3 are denoted by the same reference numerals.
In FIG. 4, the uplink module 101 of the WDM transmission apparatus 1 includes multiplexers / demultiplexers 110 and 111. The multiplexer / demultiplexer 110 separates the optical signal of the specific wavelength (λ _R11 ) from the wavelength multiplexed light received through the WDM port 102, reflects the other wavelength light, and multiplexes the transmitted light of the specific wavelength (λ _T11 ). And sent to the WDM port 102. Similarly, the multiplexer / demultiplexer 111 separates an optical signal having a specific wavelength (λ _R12 ) from the wavelength multiplexed light that has passed through the multiplexer / demultiplexer 110, reflects other wavelength light, and also has a specific wavelength (λ _T12 ). Are multiplexed and transmitted to the WDM port 102. The wavelength multiplexed light that has passed through the multiplexers / demultiplexers 110 and 111 is sent to another WDM transmission apparatus 2 through the stacking port 103 and the optical cable 302.
The received light separated by the multiplexer / demultiplexer 110 is transferred to the local port 107 through the physical layer device 112. Transmission light received from the local port 107 from the gigabit LAN is multiplexed by the multiplexer / demultiplexer 110 through the physical layer device 112 and transmitted from the WDM port 102. Similarly, the received light separated by the multiplexer / demultiplexer 111 is transferred to the local port 108 through the physical layer device 112. The transmission light received at the local port 108 is multiplexed by the multiplexer / demultiplexer 111 through the physical layer device 113 and transmitted from the WDM port 102.
Further, the WDM transmission apparatus 1 is provided with a control unit 114, a link test button 115, and an LED (light emitting diode) 116 as an indicator. The control unit 114 controls the physical layer devices 112 and 113, and from the management module 104. Necessary information (link status, power status, etc.) is collected and returned to the management module 104. As will be described later, the link test button 115 is provided for performing a link test when a WDM communication system is constructed.
The uplink module 201 of the WDM transmission apparatus 2 has the same configuration as the uplink module 101 except that the transmission / reception wavelength is different and the stacking port 103 is not provided. In addition, physical layer devices 210 and 211 similar to the WDM transmission apparatus 1 and local ports 206 and 207 are provided. Further, the WDM transmission apparatus 2 is similarly provided with a control unit 212, a link test button 213, and an LED 214 as an indicator. The control unit 212 controls the physical layer devices 210 and 211, and receives instructions from the management module 203. Accordingly, necessary information (link status, power status, etc.) is collected and returned to the management module 203.
The management module 104 attached to the WDM transmission apparatus 1 is connected to the management module 203 of the WDM transmission apparatus 2 through the cable 303 and further connected to the SNMP manager through the network. The SNMP manager can monitor the status of the WDM transmission apparatuses 1 and 2 through the network.
As a specific example, in the uplink module 101, the reception wavelength λ _R11 = 1290 nm, the transmission wavelength λ _T11 = 1310 nm, the reception wavelength λ _R12 = 1330 nm, and the transmission wavelength λ _T12 = 1350 nm. In the uplink module 201, the reception wavelength λ _R11 = 1510 nm, the transmission wavelength λ _T11 = 1530 nm, the reception wavelength λ _R12 = 1570 nm, and the transmission wavelength λ _T12 = 1550 nm. Further, as the uplink modules 101 and 201, necessary modules can be selected from modules having different transmission distances (for example, 50 km, 80 km, 120 km, etc.).
FIG. 5 is a front view showing a WDM transmission apparatus system in which the units of FIG. 2 are stacked in two stages, and FIG. 6 is a diagram showing a connection form of the two-stage WDM transmission apparatus system. Here, four WDM transmission apparatuses 1, 2, 3 and 4 are used, and the WDM transmission apparatuses 1 and 2 are cascade-connected by an optical cable 302 as shown in FIG. 3, and the WDM transmission apparatuses 3 and 4 are also cascade-connected in the same manner. Has been. That is, the stacking port 103.3 of the WDM transmission apparatus 3 and the WDM port 202.4 of the WDM transmission apparatus 4 are connected by the optical cable 302.3.
The SNMP stacking port 106 of the management module 104 is connected to the SNMP connection port 204 of the WDM transmission apparatus 2 through the cable 303, and similarly, the SNMP stacking port 106.3 of the WDM transmission apparatus 3 is connected to the SNMP of the WDM transmission apparatus 4. It is connected to the connection port 204.4 through the cable 303.3. Further, the SNMP connection port 105.3 of the WDM transmission apparatus 3 is connected to the SNMP stacking port 109 of the WDM transmission apparatus 1 through the cable 305.
By connecting in this way, the uplink modules 101 and 201 function as one uplink module as described above, and similarly, the uplink modules 101.3 and 201.4 also function as one uplink module. . Furthermore, the management modules 104, 203, 104.3, and 203.4 can also function as management modules that manage the WDM transmission apparatuses 1 to 4, respectively. Therefore, the SNMP manager can monitor the status of the WDM transmission apparatuses 1 to 4 through the network. In this way, by connecting four WDM transmission apparatuses that accommodate two GBIC ports, it is possible to upgrade to a WDM transmission apparatus that accommodates eight GBIC ports.
(Link test function)
FIG. 7A is a schematic system configuration diagram for explaining a loopback test operation when a system using the WDM transmission apparatus according to the present embodiment is constructed, and FIG. 7B explains a loopback test operation from the SNMP manager. It is a typical system block diagram for doing.
In the WDM transmission system shown in FIG. 7A, the WDM transmission apparatus 401 according to the present embodiment is connected to the WDM transmission apparatus 402 through an optical fiber cable 403. The WDM transmission apparatus 401 in this example only needs to have the link test button in this embodiment, and may be either the WDM transmission apparatus 1 or the WDM transmission apparatus 2 in FIG. 2, but here the configuration of the WDM transmission apparatus 1 is Shall have.
First, when the optical fiber cable 403 is attached to the WDM port of the WDM transmission apparatus 401 and the system connection is completed, the system installer presses the link test button 115 of the WDM transmission apparatus 401. When detecting that the link test button 115 is pressed, the control unit 114 controls the physical layer device 112 or 113 to generate an optical signal having a predetermined wavelength for link test. The generated test signal is sent from the WDM port 102 of the uplink module 101 to the optical fiber cable 403 and reaches the WDM transmission apparatus 402 on the other side as long as the cable 403 is normal. The received test signal is looped back by the physical layer device of the WDM transmission apparatus 402 and returned to the original WDM transmission apparatus 401. When the returned test signal is received by the physical layer device 112, the control unit 114 turns on the LED indicator indicating the link to notify the installer that the link is normal. In this way, the normality of the link can be confirmed when the system is installed.
In the WDM transmission system shown in FIG. 7B, the WDM ports of the WDM transmission apparatuses 1 and 2 shown in FIGS. 3 and 4 are separately connected to the optical fiber cables 404 and 405, respectively, and the management modules 104 and 203 are connected by the cable 303. ing. The SNMP manager 407 controls the management modules 104 and 203 of the WDM transmission apparatuses 1 and 2 through the switch 406, and performs the above loopback test through the optical fiber cables 404 and 405, respectively. As described above, after the system is operated, a loopback test can be performed by the SNMP manager 407 to periodically monitor the link state.
(Missing ring function)
FIG. 8A is a configuration diagram of the WDM transmission system for explaining the missing link function when the local port side is disconnected, and FIG. 8B is a configuration of the WDM transmission system for explaining the missing link function when the remote port side is disconnected. FIG.
In FIG. 8A, when the local port LP2 of the WDM transmission apparatus 401 and the local port LP3 of the WDM transmission apparatus 402 are communicating, it is assumed that the transmission line of the local port LP2 is disconnected. When the physical layer device PHY corresponding to the local port LP2 detects disconnection of the transmission line of the local port LP2, it also disconnects the link of the corresponding WDM transmission wavelength. As a result, the physical layer device PHY of the WDM transmission apparatus 402 that has received the optical signal of the corresponding transmission wavelength disables the output of the corresponding local port LP3. In this way, the reception side can know the occurrence of link disconnection on the transmission side.
In FIG. 8B, when the optical fiber cable between the WDM transmission apparatus 401 and the WDM transmission apparatus 402 is disconnected, as described above, the physical layer devices PHY corresponding to the local ports of the WDM transmission apparatus 401 and the WDM transmission apparatus 402 are Activates the missing link function and disables the corresponding local port output.
(Example of network connection)
FIG. 9 is a network configuration diagram showing an example of a WDM transmission network using the WDM transmission apparatus according to the present invention. Here, among the WDM transmission apparatuses 601 to 604, the WDM transmission apparatuses 601 and 602 are under common management, and the remote port (RP) of the WDM transmission apparatus 601 is connected to the remote port of the WDM transmission apparatus 603 with an optical fiber. The remote port (RP) of the WDM transmission apparatus 602 is connected to the remote port of the WDM transmission apparatus 604 with an optical fiber cable.
The WDM transmission apparatuses 601 and 602 are obtained by separately connecting the WDM ports of the WDM transmission apparatuses 1 and 2 shown in FIGS. 3 and 4 to optical fiber cables, and the management modules 104 and 203 are connected by a cable 303. ing. That is, the management modules of the WDM transmission apparatuses 601 and 602 are controlled via the layer 3 switch.
FIG. 10 is a network configuration diagram showing another example of a WDM transmission network using a WDM transmission apparatus according to the present invention. Here, among the WDM transmission apparatuses 701 to 704, the WDM transmission apparatuses 701 and 702 are cascade-connected in the same manner as the WDM transmission apparatuses 1 and 2 shown in FIGS. That is, the remote port PR of the WDM transmission apparatus 702 is connected to the stacking port SP of the WDM transmission apparatus 701, and the management modules 104 and 203 are connected by the cable 303 and managed via the layer 3 switch. The WDM transmission apparatus 703 has the same configuration as the WDM transmission apparatus 1 in FIGS. 3 and 4, and the remote port (RP) of the WDM transmission apparatus 701 is connected to the remote port of the WDM transmission apparatus 703 with an optical fiber cable. Yes. Further, the stacking port (SP) of the WDM transmission apparatus 703 is connected to the remote port of the WDM transmission apparatus 704 with an optical fiber cable.
As described above, the WDM transmission apparatus according to the present embodiment has a stacking port that enables stack connection in addition to the remote port, so that the number of local ports can be easily expanded by cascading another WDM transmission apparatus. can do. Furthermore, it becomes possible to connect the remote port and the stacking port to separate WDM transmission apparatuses, respectively, and the expandability and flexibility of the system configuration can be greatly improved.

Claims (6)

In a wavelength division multiplexing transmission apparatus having a plurality of local ports and at least one remote port,
A housing having at least a remote module slot;
A plurality of remote modules having remote ports with different transmission distances;
A wavelength division multiplexing transmission apparatus, wherein one remote module selected from the plurality of remote modules is detachably attached to the remote module slot. At least one of the plurality of remote modules is
Optically connected to the remote port, and combines and demultiplexes light of a predetermined wavelength, and optical multiplexing / demultiplexing means for passing signal light of other wavelengths;
A stacking port that is optically connected to the optical multiplexing / demultiplexing means, emits the signal light that has passed through the optical multiplexing / demultiplexing means, and receives the signal light from the outside;
The wavelength division multiplexing transmission apparatus according to claim 1, comprising: At least one of the plurality of remote modules is
Optically connected to the remote port, and combines and demultiplexes light of a predetermined wavelength, and optical multiplexing / demultiplexing means for passing signal light of other wavelengths;
The wavelength division multiplexing transmission apparatus according to claim 1, comprising: The wavelength division multiplexing according to claim 1, wherein the housing further includes a management module slot, and an internal state of the wavelength division multiplexing transmission apparatus is remotely monitored by a management module mounted in the management module slot. Separate transmission equipment. In a system including at least a first wavelength demultiplexing and transmitting apparatus and a second wavelength demultiplexing and transmitting apparatus,
The first wavelength division multiplexing transmission device is
A first remote module selected from a plurality of remote modules having remote ports with different transmission distances; and a first remote module slot in which the first remote module is detachably attached. 1st optical multiplexing / demultiplexing means for optically connecting to a remote port of one remote module, performing multiplexing and demultiplexing of light of the first wavelength group, and passing light of the second wavelength group other than the first wavelength group When,
A first stacking port that is optically connected to the first optical multiplexing / demultiplexing means, emits the signal light that has passed through the first optical multiplexing / demultiplexing means, and receives the signal light from the outside;
Have
The second wavelength division multiplexing transmission device is
A second remote module selected from the plurality of remote modules; and a second remote module slot in which the second remote module is detachably attached. The second remote module is a remote port of the second remote module. Second optical multiplexing / demultiplexing means for optically connecting and multiplexing and demultiplexing the light of the second wavelength group;
The first wavelength demultiplexing transmission apparatus and the second wavelength demultiplexing transmission apparatus are accommodated in one unit, and the first stacking port of the first wavelength demultiplexing transmission apparatus and the second wavelength demultiplexing transmission apparatus A wavelength division multiplexing transmission apparatus system, wherein the second remote port is optically connected by an optical cable. The first wavelength division multiplexing transmission device further includes a first management module mounted in a management module slot, and the second wavelength division multiplexing transmission device further includes a second management module mounted in the management module slot,
6. The internal state of the first wavelength demultiplexing transmission device and the second wavelength demultiplexing transmission device is remotely monitored by connecting the first and second management modules. Wavelength multiplex separation transmission system.

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