JP2007306157A - Route detecting device, route detecting system, route detecting method, and route detecting program - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To improve reliability of a wide-area communication network by easily detecting a communication route on the wide-area communication network. <P>SOLUTION: A route detecting device 33 which detects the communication route on the wide-area communication network 3 comprises a detection signal generating means of generating a route detection signal for detecting the communication route on the basis of a test signal output from a transmitting device 11 connected to the wide-area communication network 3, a transmitting means of transmitting the route detection signal together with the test signal, and a route information generating means of gathering answer signals to the route detection signal from respective devices through which the test signal passes and generating route information indicating the communication route of the test signal. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a technique for detecting a communication path in a wide area communication network.

  There is a WAN (Wide Area Network) service for connecting LANs (Local Area Networks) existing in remote places or between a terminal and a host computer. Current mainstream WAN services include wide-area Ethernet (registered trademark) services and IP-VPN (Internet Protocol-Virtual Private Network) services.

The wide area Ethernet (registered trademark) service is an inter-LAN connection service that transparently transfers Ethernet (registered trademark) frames. The IP-VPN service is a virtual closed network service in which the transmission protocol is limited to IP. The IP-VPN service is described in Patent Document 1, for example.
JP2005-151021

  In the WAN service, in order to ensure the reliability of the network, the transmission path between the nodes is often provided with two routes, a normal route and a backup route.

  Here, as shown in FIG. 9A, the wide area Ethernet (registered trademark) service provides the user with a service in layer 2 based on the data link layer. Further, as shown in FIG. 9B, the IP-VPN service provides a service in layer 3 based on the network layer.

  In layers 2 and 3, the protocol is not affected by the optical fiber of layer 1 (physical layer), which is a lower layer, and therefore the configuration of the optical fiber cannot be acquired. That is, in layer 2 and layer 3, even if the transmission route is changed from the normal route to the backup route, the change of the transmission route cannot be detected.

  Therefore, it is difficult to confirm which optical fiber is the currently used transmission route, and it is difficult to detect even if the normal route and the backup route pass through the same route. Therefore, there is a risk that reliability may be lowered, such as an increase in the risk of total interruption when one transmission route is cut, and difficulty in identifying the cause at the time of failure.

  The present invention has been made in view of the above circumstances, and an object of the present invention is to easily detect a communication path in a wide area communication network and further improve the reliability of the wide area communication network.

  In order to solve the above-mentioned problem, for example, the present invention is a path detection device for detecting a communication path in a wide area communication network, based on a test signal output from a transmission apparatus connected to the wide area communication network, The test signal has passed a detection signal generation means for generating a route detection signal for detecting a communication path, a transmission means for transmitting the route detection signal together with the test signal, and a response signal to the route detection signal. Path information generating means for generating path information that is collected from each of the devices and indicates a communication path of the test signal.

  The present invention is also a path detection method for detecting a communication path in a wide area communication network, the route for detecting the communication path based on a test signal output from a transmission device connected to the wide area communication network. A detection signal generation step for generating a detection signal, a transmission step for transmitting the route detection signal together with the test signal, and a response signal for the route detection signal are collected from each device through which the test signal has passed, and the test is performed. And a route information generation step of generating route information indicating a signal communication route.

  In addition, the present invention is a path detection program for detecting a communication path in a wide area communication network, which is executed by the information processing apparatus, and a test output from the transmission apparatus connected to the wide area communication network to the information processing apparatus A detection signal generation step for generating a route detection signal for detecting a communication path based on the signal, a transmission step for transmitting the route detection signal together with the test signal, and a response signal for the route detection signal, A path information generation step of generating path information indicating the communication path of the test signal collected from each device through which the test signal has passed is executed.

  According to the present invention, it is possible to more easily detect a communication path in a wide area communication network and further improve the reliability of the wide area communication network.

  Embodiments of the present invention will be described below.

  FIG. 1 is an overall configuration diagram of a route detection system to which an embodiment of the present invention is applied.

  In the illustrated route detection system, a system of a first user base 1 and a system of a second user base 2 are connected by a WAN (Wide Area Network) 3. It is conceivable to use wide area Ethernet (registered trademark), IP-VPN (Internet Protocol-Virtual Private Network), etc. for WAN3. In the present embodiment, a case where wide area Ethernet (registered trademark) is used for WAN 3 will be described below as an example.

  In the first user site 1, a test signal transmission device 11 and a business device (server, client, printer, etc.) 12 used in a predetermined business are connected to a LAN 13. The devices 11 and 12 connected to the LAN 13 are connected to the WAN 3 via the access line termination device 14.

  The test signal transmitting device 11 generates a test signal and transmits the generated test signal to the test signal receiving device 21 at the second user site 2 via the WAN 3. The test signal is transmission data (transmission information) for detecting a communication path (transmission route) in WAN 3. The test signal will be described later.

  In the second user site 2, a test signal receiving device 21 and a business device (server, client, printer, etc.) 22 used in a predetermined business are connected to a LAN 23. The devices 21 and 22 connected to the LAN 23 are connected to the WAN 3 via the access line termination device 24. The test signal receiving device 21 receives the test signal transmitted by the test signal transmitting device 11.

  The WAN 3 includes an edge switch 31 and a relay switch 34 at the entrance of the network, a transmission device 32 arranged to face the switch 31, 34, and a path detection device 33 arranged to face the transmission device 32. Have In addition, the communication cable 35 of the present embodiment is an optical fiber and is duplexed.

  When the WAN 3 is an IP-VPN, an edge router is used instead of the edge switch 31, and a relay router is used instead of the relay switch 34.

  Each path detection device 33 detects the communication path of the optical fiber 35 laid in the transmission section with the path detection device 33 arranged to face the path detection device 33. Each of the path detection devices 33 is connected to the management apparatus 4 through a channel different from the communication path of the WAN 3, and writes the detected communication path information in the path information DB 42 of the management apparatus 4.

  The management device 4 centrally manages the route information generated by each route detection device 33. The management apparatus 4 illustrated includes a control unit 41, a path information DB 42, and a device management table 43. The control unit 41 writes the route information received from the route detection device 33 in the route information DB 42 and provides the test signal transmission device 11 (or the test signal reception device 21) with a test signal transmission route. The device management table 43 is a table in which various types of information about the path detection device 33 and the optical wavelength filter device are stored. The route information DB 42 and the device management table 43 will be described later.

  Next, the device configuration between the switches 31 and 34 of the WAN 3 will be described in more detail.

  FIG. 2 shows an example of a device configuration between the edge switch 31 on the first user site 1 side shown in FIG. 1 and the relay switch 34. In the illustrated example, the edge switch 31 and the relay switch 34 are connected via a transmission device 32, a path detection device 33, an optical wavelength filter device 37, and an optical cross connect 39. Further, it is assumed that the transmission section between the opposing transmission apparatuses 32 has a plurality of transmission paths in preparation for a failure. That is, two optical fibers 35 are connected from each transmission device 32, and a path detection device 33 is connected to each optical fiber 35. Further, it is assumed that an optical cross-connect 39 is installed at a predetermined point in the transmission section, and the output destination of the optical signal input from the predetermined optical fiber 35 can be switched to an arbitrary optical fiber 35.

  In addition, since the optical fiber 35 generally connects and extends a plurality of optical fibers, an optical wavelength filter device 37 is installed at each optical fiber connection connector location or at a predetermined optical fiber connection connector location.

The optical wavelength filter device 37 is a device that reflects only a specific wavelength and transmits other wavelengths in an optical signal transmitted through the optical fiber 35. It is assumed that at least one optical wavelength filter device 37 is installed in the optical fiber 35 between the path detection device 33 and the optical cross connect 39 and in the optical fiber 35 between the optical cross connect 39. The optical wavelength filter device 37 will be described later.
The device configuration between the other switches 31 and 34 of the WAN 3 is the same as that in FIG.

  Next, the route detection device 33 will be described.

  FIG. 3 is a functional block diagram of the route detection device 33. The illustrated path detection device 33 includes an optical copying unit 81 that copies a signal received from the transmission device 32, an E / O conversion unit 82 that converts the optical signal into an electrical signal and generates a route detection signal, and the received signal. A determination unit 83 for determining whether the test signal is a test signal, a detection condition setting unit 84 for setting the condition of the test signal to be processed, and a wavelength multiplexing unit 85 for optically multiplexing and transmitting the test signal and the route detection signal. An optical connect unit 86 connected to the optical fiber 35, an optical wavelength filter unit 95 provided in the optical connect unit 86, a signal analysis unit 91 that analyzes a signal received from the optical fiber 35, and a path information generation unit that generates path information. 92 and a connection unit 93 connected to the management apparatus 4.

  The test signal transmission device 11, the test signal reception device 21, the path detection device 33, and the management device 4 described above are all general-purpose devices including a CPU, a memory, an external storage device, and a communication control device. A typical computer system can be used. In this computer system, each function of each device is realized by the CPU executing a predetermined program loaded on the memory.

  For example, the functions of the test signal transmission device 11, the test signal reception device 21, the path detection device 33, and the management device 4 are such that the CPU of the test signal transmission device 11 receives the test signal in the case of a program for the test signal transmission device 11. In the case of the program for the device 21, the CPU of the test signal receiving device 21, the CPU of the route detection device 33 in the case of the program for the route detection device 33, and the management device 4 in the case of the program for the management device 4. This is realized by the CPU executing each.

  Next, a process in which the test signal transmission device 11 transmits a test signal to the test signal reception device 21 will be described.

  FIG. 4 is a flowchart of a process in which the test signal generated by the test signal transmission device 11 is transmitted in a predetermined transmission section.

  First, the test signal transmitting device 11 at the first user base generates a test signal (S11). Note that the test signal transmitter 11 periodically generates and transmits a test signal at a predetermined timing. Moreover, the test signal transmission apparatus 11 is good also as receiving a user's instruction | indication and producing | generating and transmitting a test signal.

  FIG. 5 is a diagram illustrating an example of the data format of the test signal. The test signal includes a test identification flag 41, a service ID 42, a user ID 43, a transmission source ID 44, a destination ID 45, and other information (extended information, preliminary information, etc.) 46. In the test identification flag 41, a flag for identifying a test signal is set. In the service ID 42, the type of WAN service provided to the user (for example, wide area Ethernet (registered trademark), IP-VPN, etc.) is set.

  In the user ID 43, a user ID of a user who uses the WAN 3 is set. In the transmission source ID 44, identification information of an installation location of the test signal transmission device 11 or identification information of a user base where the test signal transmission device 11 is installed is set. In the destination ID 45, the identification information of the installation location of the test signal receiving device 21 that is the destination of the test signal or the identification information of the user base where the test signal receiving device 21 is installed is set.

  Then, the test signal transmitter 11 transmits the generated test signal to the WAN 3 with the test signal receiver 21 as a destination (S12). Note that the test signal is transmitted to the WAN 3 through the same interface (in-channel) as normal data (data transmitted by each business device 12) at the first user base. Further, the edge switch 31 and the transmission device 32 of the WAN 3 transmit a test signal to the transmission-side path detection device 33 through the same route as that of normal data.

  The transmission-side path detection device 33 receives various signals including a test signal and normal data from the transmission device 32 in-channel, and detects the communication path when the received signal is a test signal. A route detection signal is generated. That is, the optical copying unit 81 of the path detection device 33 optically copies the signal (optical signal) received from the transmission device 32, and separates the received signal and the copied signal (S13). ). Then, the E / O converter 82 converts the copied optical signal into an electric signal (S14).

  Then, the determination unit 83 determines whether or not the converted electric signal is a test signal to be detected (S15). The determination unit 83 refers to detection conditions set in a storage device such as a memory of the path detection device 33 to determine whether the test signal is present. The detection condition setting unit 84 receives an instruction from the system administrator (or user) and sets the received detection condition in the storage device in advance. In addition, as a detection condition, the case where all the test signals (refer FIG. 5) with which the test identification flag is set is made into the test signal of detection object can be considered. In addition, it is conceivable to set detection conditions for filtering (extracting) only test signals set with a predetermined user ID as test signals to be detected using each item set in the test signal as an extraction parameter.

  When it is determined that the test signal is a detection target (S15: YES), the E / O converter 82 converts the electrical signal into an optical signal having a predetermined gentle wavelength different from the wavelength of the test signal (hereinafter, “route detection”). Signal ") (S16). Then, the wavelength multiplexing unit 85 optically multiplexes the optical signal of the test signal received from the transmission device 32 in S13 and the optical signal of the route detection signal converted in S16 (S17). Then, the wavelength multiplexing unit 85 sends the optical signals of a plurality of different wavelengths that are optical wavelength multiplexed to the connected optical fiber via the optical connecting unit 86 (S18).

  FIG. 6 is a wavelength distribution diagram of the test signal and the route detection signal. The signal 6a before passing through the path detection device 33 is only a test signal 61 having a predetermined wavelength as shown in the figure. Then, when the route detection device 33 performs the processes of S16 and S17, the signal 6b after passing through the route detection device 33 has two signals of the original test signal 61 and the route detection signal 62. The route detection signal 62 is an optical signal having a wavelength different from that of the test signal and having a predetermined gentle wavelength.

  On the other hand, if it is determined that the test signal is not a detection target (S15: NO), the E / O converter 82 discards the converted electrical signal (S19). Then, the wavelength multiplexing unit 85 sends the optical signal received from the transmission device 32 in S13 through the optical connect unit 86 to the optical fiber as it is (S18). Through the above processing, the transmission-side route detection device 33 generates a route detection signal from the test signal and sends it to the optical fiber.

  Each of the optical wavelength filter devices 37 installed at a predetermined connection point of the optical fiber reflects only light of a specific wavelength among optical signals input from the optical fiber, and transmits other optical signals to output destinations. Output to the optical fiber.

  Each of the optical wavelength filter devices 37 of the present embodiment is a device using an optical fiber grating (FBG) technology, and each has a unique wavelength within the range of the route detection signal (see FIG. 6). It is assumed that it is set in advance so that only other wavelengths are reflected and other wavelengths are transmitted. Each of the optical wavelength filter device 37 and the path detection device 33 is arranged to face each other and is assigned a unique wavelength within the transmission section (see FIG. 2) between the transmission devices 32, and only the wavelength assigned to the own device is used. It is set to reflect.

  Further, each optical wavelength filter device 37 of the present embodiment does not require a power source. That is, since it is not necessary to secure a power source for the optical wavelength filter device 37, the installation location of the optical wavelength filter device 37 can be freely selected, and the optical wavelength filter device 37 can be easily installed.

  The optical fiber grating is obtained by changing the refractive index of the core portion of the optical fiber, and can arbitrarily reflect light of a specific wavelength (Bragg wavelength) by changing the grating length, period, and refractive index increase amount.

  Accordingly, each optical wavelength filter device 37 transmits the test signal among the optical signals transmitted by the path detection device 33 by optical wavelength multiplexing, and relays it to the next optical wavelength filter device 37 via the optical fiber. Each of the optical wavelength filter devices 37 reflects only the optical signal portion of the specific wavelength assigned to the own device for the route detection signal among the optical signals transmitted by optical wavelength multiplexing, The optical signal is transmitted and relayed to the next optical wavelength filter device 37 through the optical fiber (S20). Each optical wavelength filter device 37 transmits normal data transmitted from the business device 12 as it is.

  FIG. 7 is a sequence diagram showing transmission processing of an optical signal transmitted by optical wavelength multiplexing. In the illustrated sequence diagram, the optical cross connect 39 is omitted.

  First, the transmission-side path detection device 33 s sends the test signal received from the transmission device 32 and the generated route detection signal to the optical wavelength filter device A 37 a via an optical fiber.

  The optical wavelength filter device A37a transmits the test signal as it is and sends it to the optical wavelength filter device B37b via an optical fiber. Further, the optical wavelength filter device A37a reflects only the specific wavelength A assigned to the optical wavelength filter device A37a and sends the reflected wave A (response signal) to the transmission-side path detection device 33s. The route detection signal obtained by removing the wavelength A from the route detection signal is sent to the optical wavelength filter device B37b.

  Similar to the optical wavelength filter device A37a, the optical wavelength filter device B37b transmits the test signal as it is and sends it to the optical wavelength filter device C37c, and the route detection signal has the wavelength B assigned to the optical wavelength filter device B. The reflected wave B (response signal) is transmitted to the path detector 33s on the transmission side via the optical wavelength filter device A. The optical wavelength filter device B37b sends a route detection signal obtained by removing the wavelength B from the route detection signal transmitted by the optical wavelength filter device A to the optical wavelength filter device C37c. The optical wavelength filter device C37c also performs the same processing as the optical wavelength filter device A and the optical wavelength filter device B.

  Then, the path detection device 33r on the receiving side transmits the test signal as it is and transmits it to the transmission device 32. That is, the signal analysis unit 91 of the reception-side path detection device 33r determines that the signal received via the optical connection unit 86 is a test signal, and the transmission device 32 connected to the reception-side path detection device 33r. Send a test signal to.

  Further, the path detection device 33r on the receiving side reflects only the wavelength D assigned to the path detection device for the route detection signal, and reflects the reflected wave D (response signal) to each of the optical wavelength filter devices 37c, 37b, 37a. To the path detector 33s on the transmission side. Note that the optical wavelength filter unit 95 of the optical connect unit 86 in the path detection device 33r on the receiving side has the same function as the optical wavelength filter device, and transmits the reflected wave D. However, unlike the optical wavelength filter device, the optical wavelength filter unit 95 does not transmit a route detection signal excluding the wavelength D.

  The reflected wave transmitted by each device is transmitted to the path detection device 33s on the transmission side without being re-reflected by each optical wavelength filter to be relayed.

  The transmission-side path detection device 33 receives (collects) each reflected wave (response signal) from the optical wavelength filter device 37 and the reception-side path detection device 33, and generates path information (S21). In other words, the signal analysis unit 91 of the path detection device 33 on the transmission side receives various signals (reflected wave, test signal, normal data, etc.) from the optical fiber via the optical connection unit 86. Then, the signal analysis unit 91 analyzes the received signal, and in the case of a reflected wave, sends the reflected wave to the path information generation unit 92.

  Then, the route information generation unit 92 generates route information in the transmission section based on the reflected wave of each device through which the test signal has passed. Specifically, the path information generation unit 92 sets the test signal information set in the test signal received in S13, each received reflected wave, the apparatus ID of the path detection apparatus on the transmission side, and time (for example, path information). Route information including the time when ( The device ID is stored in advance in the storage device of the route detection device 33.

  Then, the route information generation unit 92 transmits a write request for writing the generated route information to the route information DB 42 to the management device 4 via the connection unit 93. The control unit 41 of the management apparatus 4 receives the write request and writes the route information in the route information DB 42 (S22).

  FIG. 8 is a diagram illustrating an example of the route information DB 42 of the management device 4. The illustrated path information DB 42 includes test signal information 421, received reflected waves 422, device ID 423, and time 424.

  The test signal transmission process in the predetermined transmission section of WAN 3 has been described above. In other transmission sections, as in the process of FIG. 4, the transmission-side path detection device 33 arranged in the transmission section receives a test signal from the transmission device 32 and generates a route detection signal from the test signal. To do. Then, the transmission-side path detection device 33 collects reflected waves from each device through which the test signal and the route detection signal have passed in the transmission section, generates path information of the transmission section, and writes the path information in the path information DB 42.

  Therefore, in the route information DB 42 of the management device 4, the communication route of the test signal to be detected is stored in units of transmission sections. The test signal transmitting device 11 (or the test signal receiving device 21) accesses the route information DB 42 at a predetermined timing or as necessary, and acquires the communication route of the test signal. That is, the test signal transmission device 11 requests route information from the management device 4 using the test signal information of the test signal generated by itself as a search key.

  The control unit 41 of the management device 4 accepts a request from the test signal transmission device 11 and extracts a record having the test signal information designated as a search key from the route information DB 42. And the control part 41 produces | generates the transmission route information of a test signal with reference to the apparatus management table 43 about each extracted record.

  The device management table 43 includes, for every path detection device 33 and optical wavelength filter device 37 installed in the WAN 3, the device ID of the device, the specific wavelength assigned to the device, and the installation of the device. The location (for example, the laying location of the optical fiber to which the device is connected) is stored.

  The control unit 41 specifies the corresponding device ID and installation location from the device management table 43 for each reflected wave set in the record extracted from the route information DB 42. The control unit 41 then identifies each device ID and each installation location identified as the transmission route of the transmission section corresponding to the device ID of the route detection device 33 set in the extracted record, and the time set in the extracted record. The transmission route information of the test signal including is generated. Then, the control unit 41 transmits the transmission route information generated for each extracted record to the test signal transmission device 11.

  The test signal transmission device 11 outputs the received transmission route information to an output device such as a display or a printer. Thereby, the user or the system administrator can easily grasp what communication path is used for transmitting the test signal in the WAN 3. In addition, since the transmission route information includes time, when the communication path to be used is changed by the test signal transmission device 11 periodically transmitting the test signal, the communication path is changed and The changed time zone can be detected.

  In the present embodiment described above, the transmission-side path detection device 33 arranged in each transmission section generates a route detection signal from the received test signal, and each of the test signal and the route detection signal passed through the transmission section. The reflected wave is collected from the device, and the route information of the transmission section is generated. Thereby, the communication path of the signal in WAN3 can be detected more easily, and the reliability of WAN3 can be improved more.

  In the present embodiment, the test signal and the route detection signal are optical signals having different wavelengths. As a result, the test signal and the route detection signal can be transmitted by optical wavelength multiplexing. Further, the test signal is transmitted to the test signal receiving device 21 via the WAN 3 through the same transmission route as normal data. Thereby, it is possible to detect a more accurate communication path through which normal data is actually transmitted.

  In the present embodiment, each of the optical wavelength filter device 37 and the path detection device 33 reflects only a specific wavelength of the route detection signal. Then, the transmission-side route detection device 33 generates route information including the reflected wave (response signal) collected from each device. Thereby, the communication path of the signal in WAN3 can be detected more easily.

  In the present embodiment, the route information generated by the route detection device 33 is centrally managed in the route information DB 42 of the management device 4. As a result, the user can easily grasp what communication path is used to transmit the test signal in the WAN 3. In addition, since the transmission route information includes time, when the communication path to be used is changed by the test signal transmission device 11 periodically transmitting the test signal, the communication path is changed and The changed time zone can be easily detected.

  Further, each optical wavelength filter device 37 of the present embodiment does not require a power source. That is, since it is not necessary to secure a power source for the optical wavelength filter device 37, the installation location of the optical wavelength filter device 37 can be freely selected, and the optical wavelength filter device 37 can be easily installed.

  In addition, this invention is not limited to said embodiment, Many deformation | transformation are possible within the range of the summary. For example, the path detection system according to the embodiment includes the test signal transmission device 11 and the test signal reception device 21. However, without providing these devices 11 and 21, the access line termination devices 14 and 24 may have the functions of the test signal transmitting device 11 and the test signal receiving device 21.

1 is a diagram illustrating an overall configuration of a route detection system to which an embodiment of the present invention is applied. It is a figure which shows an example of the apparatus structure between each switch. It is a functional block diagram of a route detection apparatus. It is a flowchart of the transmission process of a test signal. It is a figure which shows an example of the data format of a test signal. It is a wavelength distribution diagram of a test signal and a route detection signal It is a sequence diagram which shows the transmission process of the optical wavelength multiplexed signal. It is a figure which shows an example of route information DB. It is explanatory drawing for demonstrating the layer on the network in WAN service.

Explanation of symbols

  1: first user base, 11: test signal transmission device, 12: business device, 13: LAN, 14: access line termination device, 2: second user base, 21: test signal reception device, 22: business device , 23: LAN, 24: access line termination device, 3: WAN, 31: edge switch, 32: transmission device, 33: path detection device, 34: relay switch, 35: optical fiber, 37: optical wavelength filter device, 39: Optical cross connect, 4: management device, 41: control unit, 42: path information DB, 43: device management table

Claims (9)

A route detection device for detecting a communication route in a wide area communication network,
Detection signal generating means for generating a route detection signal for detecting a communication path based on a test signal output from a transmission device connected to the wide area network,
A transmission means for transmitting the route detection signal together with the test signal;
A path information generating unit that collects response signals for the route detection signal from each of the devices through which the test signal has passed, and generates path information indicating a communication path of the test signal. . The route detection device according to claim 1,
The test signal and the route detection signal are optical signals,
The detection signal generation means generates a route detection signal having a wavelength different from that of the test signal,
The path detecting device, wherein the transmitting means transmits the test signal and the route detection signal by wavelength multiplexing. The route detection device according to claim 2,
Each of the response signals is a reflected wave that reflects only light of any wavelength of the route detection signal. The route detection device according to claim 3,
The route detection device, wherein the route information generation unit generates route information including reflected waves of each of the collected response signals. The route detection device according to claim 2,
The route information generating unit writes the generated route information in a route information storage unit. A route detection system for detecting a communication route in a wide area communication network,
A transmission device connected to the wide area communication network, and a route detection device for detecting a communication route,
The transmitter is
Generate a test signal, send the test signal to the wide area network,
The route detection device includes:
Detection signal generating means for generating a route detection signal for detecting a communication path based on the test signal output from the transmission device;
A transmission means for transmitting the route detection signal together with the test signal;
Path information generating means for collecting response signals for the route detection signal from each of the devices through which the test signal has passed, and generating path information indicating a communication path of the test signal. . A route detection system for detecting a communication route in a wide area communication network,
A transmission device connected to the wide area communication network, a route detection device for detecting a communication route, and at least one filter device;
The transmitter is
Generate a test signal, send the test signal to the wide area network,
The route detection device includes:
Detection signal generating means for generating a route detection signal for detecting a communication path based on the test signal output from the transmission device;
A transmission means for transmitting the route detection signal together with the test signal;
Path information generating means for collecting response signals for the route detection signal from each of the filter devices through which the test signal has passed, and generating path information indicating a communication path of the test signal;
Each of the filter devices includes:
A route detection system, wherein a response signal reflecting only light of any wavelength of the route detection signal is sent to the route detection device. A route detection method for detecting a communication route in a wide area communication network,
A detection signal generating step for generating a route detection signal for detecting a communication path based on a test signal output from a transmission device connected to the wide area communication network;
A transmission step of transmitting the route detection signal together with the test signal;
A route information generating step of collecting response signals for the route detection signal from each device through which the test signal has passed and generating route information indicating a communication route of the test signal. . A path detection program for detecting a communication path in a wide area communication network executed by an information processing apparatus,
In the information processing apparatus,
A detection signal generating step for generating a route detection signal for detecting a communication path based on a test signal output from a transmission device connected to the wide area communication network;
A transmission step of transmitting the route detection signal together with the test signal;
A route information generation step of collecting response signals for the route detection signal from each of the devices through which the test signal has passed and generating route information indicating a communication route of the test signal. program.