JP5019234B2 - Communication system and fault isolation test method - Google Patents

Description

The present invention relates to a communication system and a fault isolation test method for isolating a location where a fault has occurred.

  In FTTH (Fiber To The Home) or the like, a UTP (Unshielded Twist Pair) cable or the like and an optical cable can be connected via an optical media converter device that performs medium conversion between different transmission media. That is, when an optical media converter device is used, a local area network (LAN) on the side that distributes information (hereinafter referred to as the center side) and a side that receives information distribution (hereinafter referred to as the remote side). A LAN can be connected via an optical communication line.

  In a communication system in which optical media converter devices are installed on both sides of an optical cable, an optical media converter device used on the center side is called a center device, and an optical media converter device used on the remote side is called a remote device. In general, the center device and the remote device facing each other often have different installation locations, and are often physically separated (several kilometers to several tens of kilometers). Therefore, when a failure occurs in the optical media converter device or the optical communication line, it is necessary to perform a failure isolation test to isolate the location of the failure.

  The line quality confirmation method (see Patent Document 1) of the optical subscriber line interface TS-1000 established by the TTC (The Telecommunication Technology Committee) includes the state of the line and the opposing optical media converter. A loop test is included to check the operating state of the device.

  Patent Document 2 describes a communication system including a media converter device, which improves the reliability of a loopback test. In the communication system described in Patent Document 2, the subscriber-side media converter device starts self-diagnosis in response to a turn-back test start request maintenance signal from the station-side media converter device, and the self-diagnosis result together with the turn-back test signal is stored in the station. It is transmitted to the building side media converter device. By performing self-diagnosis during the loopback test, it is possible to check each part in the subscriber-side media converter device where it is difficult to confirm an abnormality with the loopback test signal alone. Can be improved.

Japanese Patent Laying-Open No. 2004-228771 (paragraphs 0004-0005) JP 2004-15217 A (paragraph 0022, paragraph 0106, abstract)

  However, in the loop test in the line quality confirmation method of TS-1000, a failure in the optical communication section between the center device and the remote device and a failure in the LAN side interface unit of the remote device can be detected. A failure in the side interface unit cannot be detected. Furthermore, even if a failure is detected, it cannot be determined whether the center device or the remote device has an abnormality, or whether the uplink or the downlink has an abnormality.

  Also, the media converter device described in Patent Document 2 cannot detect a failure in the LAN side interface unit of the center device, and cannot determine whether there is an abnormality in the uplink or the downlink.

  For this reason, if any failure occurs in FTTH or the like, if the center device, the remote device, the uplink or the downlink does not know where the failure has occurred, the center can be used for quick failure recovery. A lot of money is required, such as investigating both the device and the remote device at the same time.

Therefore, an object of the present invention is to provide a communication system and a fault isolation test method that can easily isolate a location where a fault has occurred.

Communication system according to the present invention is a first communication system and optical media converter device and a second optical media converter device communicate via the optical communication line, the first optical media converter apparatus, the main signal a first signal switching unit for generating a data path for flowing the test data by switching a path, a first device-side interface unit for transmitting and receiving equipment and the data, and the test control signal transmission unit which transmits a test control signal, a plurality of first transmission unit that transmits the test data, a plurality of first matching portion for matching the contents of the test data transmitted and the contents of the received test data, and an output section for outputting a test result the provided second optical media converter apparatus, the second device performing the second signal switching unit for generating a data path for flowing the test data by switching a main signal path, the transmission and reception equipment and data An interface unit, a test control response transmitter for transmitting a test control response, a plurality of second transmitters for transmitting test data, and a plurality of collations for comparing the content of the received test data with the content of the transmitted test data A second verification unit, and the first device-side interface unit generates a data path for switching the main signal path provided in the first device-side interface unit to flow test data . The device-side interface unit switches a main signal route provided inside the second device-side interface unit to generate a data path for flowing test data, and the test control response transmitting unit is configured to transmit the test signal to the first optical media converter device. and receiving a test control signal transmitted from the test control signal transmission unit transmits a test control response, the first transmission portion a plurality of receives the test control response, the first signal switching unit Preliminary first transmits test data to the generated data path to the device-side interface unit, the second transmission section plurality of receives the test control signal, the second signal switching unit and the second device-side interface sending test data to the generated data path section, the output section to output the collation result in the plurality of first matching unit, a test result based on the comparison result in the second matching unit of the multiple It is characterized by.

A communication system according to another aspect of the present invention is a communication system in which a first optical media converter device and a second optical media converter device communicate with each other via an optical communication line, and the first optical media converter device. includes a first transmission unit for transmitting a first signal switching unit for generating a data path for flowing the test data by switching a main signal path, and the test control signal transmission unit which transmits a test control signal, test data, comprising a plurality of first matching portion for matching the contents of the received test data and contents of the transmitted test data, and an output unit for outputting a test result, the second optical media converter apparatus, the main signal A second signal switching unit for generating a data path for switching the path and flowing test data; a test control response transmitting unit for transmitting a test control response; a plurality of second transmitting units for transmitting test data; and reception And a plurality of second matching unit for matching the contents of the test data transmitted and the contents of the test data, test control response transmission unit is transmitted from the test control signal transmitting unit of the first optical media converter device When the test control signal is received, the test control response is transmitted. When the first transmission unit receives the test control response, the first transmission unit transmits the test data to the data path generated by the first signal switching unit . When the transmission unit receives the test control signal, the transmission unit transmits the test data to the data path generated in the second signal switching unit, and the output unit outputs the verification result in the first verification unit and the second verification unit. A test result is output based on the collation result.

Fault isolation testing method according to the invention, the first optical media converter apparatus generates a data path for flowing the test data by switching a main signal path, the inside of the first device-side interface unit for transmitting and receiving apparatus and data generating a data path for flowing the test data by switching a main signal path provided, it transmits a test control signal, receives the test control response, transmits the test data to the generated data path of the plurality first transmitted from part collates a plurality of first matching portion for matching the contents of the test data transmitted and the contents of the received test data, the second optical media converter device switches the main signal path A data path for passing test data is generated, and data for flowing test data is switched by switching the main signal path provided in the second equipment-side interface unit that transmits and receives data to and from the equipment. When a path is generated and a test control signal is received, a test control response is transmitted. When a test control signal is received, test data is transmitted to the generated data path from a plurality of second transmission units. against a plurality of second matching unit for matching the contents of the test data transmitted to the content, the first optical media converter apparatus, a collation result in the plurality of first matching portion, the number of the second double characterized in that you output a test result based on the matching result in the matching unit.

  According to the present invention, by providing a plurality of test data transmission and verification locations in the optical media converter device, it is possible to easily identify the location where the failure has occurred.

It is a block diagram which shows the structure of one Embodiment of the optical media converter apparatus by this invention. It is a block diagram which shows the structure of the communication system in which communication is performed between the two optical media converter apparatuses shown by FIG. FIG. 3 is a sequence diagram illustrating an operation during a separation test of the optical media converter device in the communication system illustrated in FIG. 2. It is explanatory drawing which shows an example of the path | route of test data. FIG. 3 is a sequence diagram showing an operation example of the optical media converter device when the separation test in the communication system shown in FIG. FIG. 10 is a sequence diagram illustrating another operation example of the optical media converter device when the separation test in the communication system illustrated in FIG. 2 ends abnormally. It is explanatory drawing which shows an example of a test control signal and a test control response. It is explanatory drawing which shows an example of the frame format of the test control signal and test control response which are shown in FIG. It is a sequence diagram which shows the operation | movement in 2nd Embodiment of the segmentation test implemented with the communication system containing the optical media converter apparatus by this invention. It is explanatory drawing which shows the path | route of the test data in 2nd Embodiment. It is explanatory drawing which shows an example of the test control signal containing the production | generation pattern information of the data path | route of test data. It is a block diagram which shows the principal part of the optical media converter apparatus by this invention.

  FIG. 1 is a block diagram showing a configuration of an embodiment of an optical media converter device according to the present invention. With reference to FIG. 1, the structure of the optical media converter apparatus by this invention is demonstrated. FIG. 1 shows two optical media converter devices, a center device 100 and a remote device 200.

  The center apparatus 100 includes a LAN side interface unit 110, an L2 (Layer 2) switch 120, a WAN (Wide Area Network) side conversion unit 130, a test control unit 141, a test control signal transmission unit 142, a test control response detection unit 143, a transmission Unit 144, transmission unit 145, verification unit 146, verification unit 147, signal switching unit 148, and signal switching unit 149.

  The LAN side interface unit 110 realizes a LAN interface with the center side, and performs data transmission / reception with the center side LAN by a main signal. The LAN side interface unit 110 switches the connection (c, n, t) of two switches provided inside, and controls the data path provided inside. Usually, when the signal passing through the main signal line is the main signal, the switch is in a state where the contact c and the contact n are connected (hereinafter, cn is connected). The L2 switch 120 determines the destination of the packet from the MAC address included in the destination of the received packet and transfers the packet data. Note that when the L2 switch 120 receives a frame different from the MAC frame, the L2 switch 120 discards the frame.

  The WAN side conversion unit 130 realizes a WAN interface and performs mutual conversion between an optical signal and an electrical signal. The WAN side conversion unit 130 transmits and receives data via the optical communication line 500. When data is transmitted from the center apparatus 100 to the remote apparatus 200, the downlink in the optical communication line 500 is used, and when data is transmitted from the remote apparatus 200 to the center apparatus 100, the uplink in the optical communication line 500 is used. Is used.

  The test control unit 141 controls various operations related to the carving test in the center apparatus 100 according to the test start trigger. The test control part 141 will perform the display (test result display) which shows a test result, when a carving test is complete | finished. Further, the test control unit 141 controls a timer X (not shown) and a timer Z (not shown) used in the separation test. The test control signal transmission unit 142 generates and transmits a test control signal. The test control response detection unit 143 detects the test control response transmitted from the remote device 200. Details of the test control signal and the test control response will be described later with reference to FIGS.

  The transmission units 144 and 145 generate and transmit test data. When the verification units 146 and 147 receive the test data transmitted from the transmission units 144 and 145 of the center device 100 or the transmission units 244 and 245 of the remote device 200, the contents of the received test data and the content of the transmitted test data Is matched. The signal switching units 148 and 149 change the data path by switching the connection (c, n, t) of the switch according to the loop control signal transmitted by the test control unit 141. Normally, when the signal passing through the main signal line is the main signal, the switch is in a state where cn is connected. When the signal switching units 148 and 149 switch the connection of the switches to generate a loop path including the main signal line, the signal passing through the loop path is switched from the main signal to the test signal.

  The remote device 200 includes a LAN side interface unit 210, an L2 switch 220, a WAN side conversion unit 230, a test control unit 241, a test test control response transmission unit 242, a control signal detection unit 243, a transmission unit 244, a transmission unit 245, and a verification unit. 246, a verification unit 247, a signal switching unit 248, and a signal switching unit 249.

  The LAN-side interface unit 210 implements a LAN interface with the remote side, and transmits and receives data with the remote side LAN using main signals. The LAN side interface unit 110 switches the connection (c, n, t) of two switches provided inside, and controls the data path provided inside. Normally, when the signal passing through the main signal line is the main signal, the switch is in a state where cn is connected. The L2 switch 220 determines the destination of the packet from the MAC address included in the destination of the received packet and transfers the packet data. Note that when the L2 switch 220 receives a frame different from the MAC frame, the L2 switch 220 discards the frame.

  The WAN conversion unit 230 realizes a WAN interface and performs mutual conversion between an optical signal and an electrical signal. The WAN side conversion unit 230 transmits and receives data via the optical communication line 500.

  The test control unit 241 controls various operations related to the separation test in the remote device 200 in accordance with the test control signal transmitted from the center device 100. The test control unit 241 performs display (display during test) indicating that the test is being performed while performing the separation test. Further, the test control unit 241 controls a timer Y (not shown) used in the separation test. The test control signal detection unit 243 detects the test control signal transmitted from the center device 100. When the test control signal detector 243 detects the test control signal, the test control response transmitter 242 generates and transmits a test control response signal.

  The transmission units 244 and 245 generate and transmit test data. When the verification units 246 and 247 receive the test data transmitted from the transmission units 144 and 145 of the center device 100 or the transmission units 244 and 245 of the remote device 200, the verification units 246 and 247 Is matched. The signal switching units 248 and 249 change the data path by switching the connection (c, n, t) of the switch according to the loop control signal transmitted by the test control unit 241. Normally, when the signal passing through the main signal line is the main signal, the switch is in a state where cn is connected. When the signal switching units 248 and 249 switch the connection of the switches to generate the loop path including the main signal line, the signal passing through the loop path is switched from the main signal to the test signal.

  FIG. 2 is a block diagram illustrating a configuration of a communication system in which communication is performed between the two optical media converter apparatuses illustrated in FIG. As shown in FIG. 2, the center device 100 and the remote device 200 are connected so as to be able to communicate via an optical cable (optical communication line) 500.

Embodiment 1. FIG.
A first embodiment (embodiment 1) of a separation test performed in a communication system including the optical media converter device shown in FIG. 2 will be described.

  FIG. 3 is a sequence diagram showing an operation at the time of the separation test of the optical media converter device in the communication system shown in FIG. FIG. 3 shows the operation when the carving test ends normally. With reference to FIG. 3, the operation when the carving test ends normally will be described.

  Whether the carving test has ended normally or abnormally is determined by whether the process in the carving test has been completed without delay. Specifically, when the test result is obtained before the time measured by the timer X and the timer Y reaches the expiration time, it is regarded as normal termination. Even if the carving test is normally completed, if there is a collation result determined to be abnormal in each collation unit, the test result is regarded as abnormal.

  When the test control unit 141 of the center apparatus 100 detects a test start trigger (step S11), it starts a timer X (step S12). The expiration time of the timer X is set to a time when it is considered that the separation test process is sufficiently completed. The test start trigger is, for example, a signal transmitted from a control terminal or a switch operated by an administrator who performs a carving test.

  When the timer X is started in step S12, the test control unit 141 starts preparation for flowing test data in the data path. The test control unit 141 transmits a loop control signal to the signal switching units 148 and 149. The signal switching units 148 and 149 are connected to the contacts c and t in the respective switches in accordance with the loop control signals (hereinafter referred to as “c−t”), and the signals in the main signal line. A signal that passes through the WAN side conversion unit 130 rather than the switching units 148 and 149 is switched from the main signal to the test signal (step S13). The test control unit 141 transmits a loop control signal to the LAN side interface unit 110. The LAN-side interface unit 110 sets the two switches in the LAN-side interface unit 110 to the state where ct is connected according to the loop control signal (step S14). By switching the switches in the signal switching units 148 and 149 and the LAN side interface unit 110, a loop path including the LAN side interface unit 110 as a path is generated inside the center apparatus 100 (step S15).

  When the loop control signal is transmitted to the LAN side interface unit 110 in step S14, the test control unit 141 causes the test control signal transmission unit 142 to generate a first test control signal (test start request) that requests the start of the test. . The test control signal transmission unit 142 generates and transmits a first test control signal in accordance with the control of the test control unit 141 (step S16).

  The first test control signal transmitted from the test control signal transmission unit 142 is converted into an optical signal by the WAN side conversion unit 130. The first test control signal converted into the optical signal is transmitted to the remote device 200 via the optical communication line 500 and converted into an electrical signal by the WAN side conversion unit 230. In the following description, when the communication between the center apparatus 100 and the remote apparatus 200 is performed, the description that the WAN side conversion units 130 and 230 are performing the conversion process is omitted.

  The test control signal detection unit 243 detects the first test control signal transmitted by the test control signal transmission unit 142 via the optical communication line 500. When the test control signal detection unit 243 detects the first test control signal, the test control unit 241 recognizes the start of the test and activates the timer Y (step S17). The expiration time of the timer Y is set to a time at which the processing from the reception of the first test control signal at the remote device 200 until the cancellation of the display during the test (step S38) is sufficiently completed.

  When the timer Y is started in step S17, the test control unit 241 displays a test in progress (step S18). The test control unit 241 transmits a loop control signal to the signal switching units 248 and 249. The signal switching units 248 and 249 pass through the WAN conversion unit 230 side of the main signal line from the signal switching units 248 and 249 in a state where the respective switches are connected to ct according to the loop control signal. The signal to be switched is switched from the main signal to the test signal (step S19). The test control unit 241 transmits a loop control signal to the LAN side interface unit 210. The LAN side interface unit 210 sets the two switches in the LAN side interface unit 210 to ct connected in response to the loop control signal (step S20). By switching the switches in the signal switching units 248 and 249 and the LAN side interface unit 210, a loop path including the LAN side interface unit 210 as a path is generated in the center device 200 (step S21).

  When the loop control signal is transmitted to the LAN-side interface unit 210 in step S20, the test control unit 241 sends a first test control response (test start response indicating that preparation for starting the test is completed to the test control response transmission unit 242. ) Is generated. The test control response transmission unit 242 generates a first test control response according to the control of the test control unit 241 and transmits the first test control response to the center apparatus 100 (step S22).

  The test control response detection unit 143 detects the first test control response transmitted by the test control response transmission unit 242 via the optical communication line 500. When the test control response detection unit 143 detects the first test control response, the test control unit 141 starts the timer Z (step S23). The expiration time of the timer Z is set to a time at which the processing from when the center device 100 receives the first test control response until the center device 100 and the remote device 200 collate all the test data is sufficiently completed. The

  When the timer Z is started in step S23, the transmission unit 144 and the transmission unit 145 of the center apparatus 100 transmit test data (steps S24 and S25). The test data transmitted from the transmission unit 144 is referred to as test data A-1, and the test data transmitted from the transmission unit 145 is referred to as test data A-2. On the other hand, the transmission unit 244 and the transmission unit 245 of the remote device 200 also transmit test data (steps S26 and S27). The test data transmitted from the transmission unit 244 is referred to as test data B-1, and the test data transmitted from the transmission unit 245 is referred to as test data B-2.

  FIG. 4 is an explanatory diagram illustrating an example of a route of test data. With reference to FIG. 4, the flow of test data A-1, A-2, B-1, and B-2 will be described. When test data is transmitted in steps S24 to S27, three loop paths are generated by the center apparatus 100, the remote apparatus 200, and the optical communication line 500. The test data A-1 and B-1 are transmitted to a loop path including the WAN side conversion unit 130 and the WAN side conversion unit 230. The test data A-2 is transmitted to a loop path including the LAN side interface unit 110. The test data B-2 is transmitted to a loop path including the LAN side interface unit 210.

  As shown in FIG. 4, the test data A-1 is transmitted from the transmission unit 144 and received by the verification unit 246 through the WAN side conversion unit 130, the downlink in the optical communication line 500, and the WAN side conversion unit 230. The The test data B-1 is transmitted from the transmission unit 244 and received by the collation unit 146 through the WAN side conversion unit 230, the uplink in the optical communication line 500, and the WAN side conversion unit 130. The test data A-2 is transmitted from the transmission unit 145, and is received by the verification unit 147 through the L2 switch 120 and the LAN side interface unit 110. The test data B-2 is transmitted from the transmission unit 245, and is received by the verification unit 247 through the L2 switch 220 and the LAN side interface unit 210.

  Each collator collates the content of the received test data with the content of the transmitted test data (steps S28 to S31). If the received test data has a data content different from that at the time of transmission, it can be estimated that a failure has occurred on the data path on the way. Then, the collation unit 146 and the collation unit 147 of the center apparatus 100 notify the test control unit 141 of the collation result of either normal or abnormal. The collation unit 246 and the collation unit 247 of the remote device 200 notify the test control unit 241 of the collation result of either normal or abnormal. FIG. 3 shows an example in which test data is received by the verification units 146, 147, 246, and 247, and verification is performed in each verification unit.

  When the time measured by the timer Z expires (step S32), the test control unit 141 requests the test control signal transmission unit 142 to notify the test result in the remote device 200 (second test control signal). Is generated. The test control signal transmission unit 142 generates and transmits a second test control signal in accordance with the control of the test control unit 141 (step S33).

  The test control signal detection unit 243 detects the second test control signal transmitted by the test control signal transmission unit 142 via the optical communication line 500. When the test control signal detection unit 243 detects the second test control signal, the test control unit 241 transmits a loop control signal to the LAN side interface unit 210. The LAN side interface unit 210 sets the two switches in the LAN side interface unit 210 to be connected to cn in accordance with the loop control signal (step S34). When cn in the switch is connected in step S34, the loop path is released (step S35). The test control unit 241 transmits a loop control signal to the signal switching units 248 and 249. In response to the loop control signal, the signal switching units 248 and 249 return the main signal lines switched in step S19 to the state in which the main signal is flowed by setting the respective switches to be connected to cn (step S36). ).

  The test control unit 241 causes the test control response transmission unit 242 to generate a second test control response (test result response) for notifying the test result in the remote device 200. The test control response transmission unit 242 generates a second test control response in accordance with the control of the test control unit 241 and transmits the second test control response to the center apparatus 100 (step S37). When the second test control response is transmitted, the test control unit 241 cancels the display during the test (step S38) and stops the timer Y (step S39).

  The test control response detection unit 143 detects the second test control response transmitted by the test control response transmission unit 242 via the optical communication line 500. When the test control response detection unit 143 detects the second test control response, the test control unit 141 transmits a loop control signal to the LAN side interface unit 110. The LAN side interface unit 110 sets the two switches in the LAN side interface unit 110 to the state where cn is connected in accordance with the loop control signal (step S40). In step S40, when cn in the switch is connected, the loop path is released (step S41). The test control unit 141 transmits a loop control signal to the signal switching units 148 and 149. In response to the loop control signal, the signal switching units 148 and 149 return the main signal lines switched in step S13 to the state in which the main signal flows through the respective switches being connected to cn (step S42). ).

  The test control unit 141 stops the timer X (step S43). Then, the test control unit 141 acquires the test result in the center device 100 and the test result in the remote device 200. The test control unit 141 outputs the acquired test results together (step S44). The test result by the operation of the segmentation test shown in FIG. 3 includes, for example, the collation results in the collation units 146, 147, 246, and 247. The test result may include whether the timers X, Y, and Z are started and expired. The test result may be displayed, for example, on a monitor of a control terminal operated by an administrator. If the carving test is completed normally and the collation result in each collation unit is normal, it means that no failure has occurred.

  The verification result notified from each verification unit indicates whether a failure has occurred in the data path from the source of the test signal received by each verification unit to the verification unit. For example, in the separation test in the communication system shown in FIG. 2, the collation result notified from the collation unit 146 is transmitted from the transmission unit 244 to the WAN side conversion unit 230, the uplink in the optical communication line 500, and the WAN side conversion unit 130. It indicates whether or not a failure has occurred in the data path that passes through to the verification unit 146. The collation result notified from the collation unit 147 indicates whether or not a failure has occurred in the data path from the transmission unit 145 to the collation unit 147 via the L2 switch 120 and the LAN side interface unit 110. The collation result notified from the collation unit 246 indicates that there is a failure in the data path from the transmission unit 144 to the collation unit 246 via the WAN side conversion unit 130, the downlink in the optical communication line 500, and the WAN side conversion unit 230. Indicates whether it has occurred. The collation result notified from the collation unit 247 indicates whether or not a failure has occurred in the data path from the transmission unit 245 to the collation unit 247 via the L2 switch 220 and the LAN side interface unit 210.

  By combining the collation results from each collation unit, it is possible to estimate the occurrence location of the failure. For example, when the collation results in the collation unit 146, the collation unit 147, and the collation unit 246 indicate normality, and the collation result in the collation unit 247 indicates abnormality, the upper and lower lines of the center device 100 and the optical communication line 500 are normal. However, it can be estimated that an abnormality has occurred in the remote device 200. Further, for example, when the collation results in the collation unit 146, the collation unit 147, and the collation unit 247 indicate normality, and the collation result in the collation unit 246 indicates abnormality, the center side device 100, the remote device 200, and the optical communication line 500 It is possible to estimate that the uplink in the optical communication line 500 is normal, but the downlink in the optical communication line 500 is abnormal.

  That is, in the communication system shown in FIG. 2, when the separation test is normally completed, the collation result of the test data performed in a plurality of loop paths is collected, so that the location where the failure has occurred The communication line 500 can be divided into an uplink or downlink, or a remote device 200.

  FIG. 5 is a sequence diagram showing an operation example of the optical media converter device when the separation test in the communication system shown in FIG. 2 ends abnormally. FIG. 5 shows an example in which the remote device 200 cannot recognize the first test control signal and the separation test ends abnormally. With reference to FIG. 5, an example of an operation when the carving test ends abnormally will be described.

  Processing from when the test control unit 141 of the center apparatus 100 detects a test start trigger until the test control signal transmission unit 142 generates and transmits a first test control signal (test start request) (steps S51 to S51). S56) is the same as the processing shown in steps S11 to S16 in FIG.

  In the example shown in FIG. 5, since the remote device 200 cannot recognize the first test control signal, the first test control signal transmitted from the test control signal transmission unit 142 in step S56 is the test control signal of the remote device 200. It is not detected by the detection unit 243. Since the test control signal detector 243 does not detect the first test control signal, the test control response transmitter 242 transmits the first test control response (test start response) (shown in step S22 of FIG. 3). Process), the test control response detector 143 of the center apparatus 100 detects the first test control response, and the test controller 141 starts the timer Z (the process shown in step S23 of FIG. 3). ) And the process in which each transmitting unit transmits test data (the process shown in steps S24 to S27 in FIG. 3) does not occur.

  When the time counted by the timer X in the center device 100 expires (step S57), the test control unit 141 transmits a loop control signal to the LAN side interface unit 110. The LAN-side interface unit 110 sets the two switches in the LAN-side interface unit 110 to the state where cn is connected in accordance with the loop control signal (step S58). In step S58, when cn in the switch is connected, the loop path is released (step S59). The test control unit 141 transmits a loop control signal to the signal switching units 148 and 149. In response to the loop control signal, the signal switching units 148 and 149 return the main signal lines switched in step S53 to the state in which the main signal flows through the respective switches being connected to cn (step S60). . And the test control part 141 outputs a test result (step S61). Since transmission of the test data is not performed by the center apparatus 100 and the remote apparatus 200, the test result in this example indicates that determination is not performed in the collating units 146, 147, 246, 247, and the timer X Contains information indicating that the timed time has expired since is started. In addition, when collation is not performed, you may show by making a collation result abnormal.

  When the carving test ends abnormally, it is possible to narrow down the location of the failure in a wider range than when the carving test ends normally. In addition, by considering the execution status of each timer together, there are cases where the location where a failure occurs can be estimated in a narrower range. From the test result by the operation of the separation test shown in FIG. 5, it can be seen that the first test control response was not received even though the first test control signal was transmitted. It can be estimated that a failure has occurred outside the interface unit 110.

  FIG. 6 is a sequence diagram showing another operation example of the optical media converter device when the separation test in the communication system shown in FIG. 2 ends abnormally. FIG. 6 shows an example in which the center device 100 cannot recognize the first test control response and the carving test ends abnormally. With reference to FIG. 6, another example of the operation when the carving test ends abnormally will be described.

  Processing from when the test control unit 141 of the center apparatus 100 detects the test start trigger until the test control response transmission unit 242 generates and transmits the first test control response (test start response) (steps S71 to S71). S82) is the same as the processing shown in steps S11 to S22 of FIG.

  In the example shown in FIG. 6, since the center apparatus 100 cannot recognize the first test control response, the first test control response transmitted from the test control response transmission unit 242 in step S82 is the test control response of the center apparatus 100. The detection unit 143 does not detect it. Since the test control response detector 143 does not detect the first test control response, the test control response detector 143 does not generate a process for starting the timer X (the process shown in step S23 in FIG. 3), and the center device The processing in which the transmission units 144 and 145 of 100 transmit test data (the processing shown in steps S24 and S25 in FIG. 3) does not occur.

  Test data is transmitted in the transmission unit 244 and the transmission unit 245 of the remote device 200 (steps S83 and S84). The test data transmitted from the transmission unit 244 is referred to as test data B-1, and the test data transmitted from the transmission unit 245 is referred to as test data B-2.

  The test data B-1 transmitted from the transmission unit 244 is transmitted to a loop path including the WAN side conversion unit 130 and the WAN side conversion unit 230, but the test data is not transmitted on the center device 100 side. Therefore, the test data is not verified in the verification units 146 and 147.

  The test data B-2 transmitted from the transmission unit 245 is transmitted to the loop path including the LAN side interface unit 210, and is received by the verification unit 247 through the L2 switch 220 and the LAN side interface unit 210. The collation unit 247 collates the received test data B-2 (step S85) and notifies the test control unit 241 of the collation result.

  The collation unit 246 waits for reception of test data that should be transmitted from the transmission unit 144 of the center apparatus 100. However, since the test data is not transmitted in the center apparatus 100, the collation unit 246 performs test data transmission. Are never matched. That is, only the verification result in the verification unit 247 is notified to the test control unit 241, and the test result in the remote device 200 always becomes abnormal in the verification unit 246.

  When the time counted by the timer Y in the remote device 200 expires (step S86), the test control unit 241 transmits a loop control signal to the LAN side interface unit 210. The LAN side interface unit 210 sets the two switches in the LAN side interface unit 210 to the state where cn is connected in accordance with the loop control signal (step S87). In step S87, when cn in the switch is connected, the loop path is released (step S88). The test control unit 241 transmits a loop control signal to the signal switching units 248 and 249. In response to the loop control signal, the signal switching units 248 and 249 return the main signal lines switched in step S79 to the state in which the main signal flows through the respective switches being connected to cn (step S89). ).

  The test control unit 241 notifies the test control response transmission unit 242 of the comparison result in the remote device 200 and the fact that the test in the remote device 200 has ended due to the expiration of the time measured by the timer Y. Generate a response (end of test indication). The test control response transmission unit 242 generates a third test control response according to the control of the test control unit 241, and transmits the third test control response to the center apparatus 100 (step S90). When the third test control response is transmitted, the test control unit 241 cancels the display during testing (step S91).

  The test control response detector 143 detects the third test control response transmitted by the test control response transmitter 242 via the optical communication line 500. When the test control response detection unit 143 detects the third test control response, the test control unit 141 transmits a loop control signal to the LAN side interface unit 110. The LAN-side interface unit 110 sets the two switches in the LAN-side interface unit 110 to be connected to cn in accordance with the loop control signal (step S92). In step S92, when cn in the switch is connected, the loop path is released (step S93). The test control unit 141 transmits a loop control signal to the signal switching units 148 and 149. In response to the loop control signal, the signal switching units 148 and 149 return the main signal lines switched in step S73 to the state in which the main signal flows through the respective switches being connected to cn (step S94). ).

  The test control unit 141 stops the timer X (step S95). Then, the test control unit 141 acquires the test result in the center device 100 and the test result in the remote device 200. Actually, since test data is not transmitted and verified in the center apparatus 100, normal test results in the center apparatus 100 are not acquired. And the test control part 141 outputs a test result (step S96). Since the test data is not transmitted by the center apparatus 100, the test result in this example indicates that the collation units 146 and 147 are not collated, the collation unit 246 is abnormal, the collation unit Information indicating that the time is normal at 247 and that the timer Y has been started and the measured time has expired is included.

  If the carving test ends abnormally as in this example, the failure location can be narrowed down in a wider range than when the carving test ends normally, as in the example shown in FIG. it can. From the test result of the separation test operation shown in FIG. 6, in the loop path including the LAN side interface unit 210 of the remote device 200 that the first test control response was not received even though it was transmitted. Since it can be seen that the data test has been collated normally, it can be estimated that a failure has occurred outside the downlink in the optical communication line 500 and the LAN side interface unit 110 of the remote device 200.

  Next, the test control signal and the test control response will be described in detail. FIG. 7 is an explanatory diagram illustrating an example of a test control signal and a test control response. FIG. 8 is an explanatory diagram showing an example of a frame format of the test control signal and test control response shown in FIG.

  The test control signal is a signal that the center device 100 transmits to the remote device 200. The test control response is a signal transmitted from the remote device 200 to the center device 100. As the test control response for notifying the test result in the remote device 200, a different test control response is selected depending on whether the time measured by the timer Y has expired and the test has ended. Note that there may be a test control signal or a test control response other than the signals shown in FIG. 7 (for example, the third test control signal in the second embodiment in the example shown in FIG. 9).

  The test control signal and the test control response are formed by a frame different from a normal MAC frame. For example, as shown in FIG. 8, the frame lengths of the test control signal and the test control response are set to less than 64 bytes. Since the frame length of a normal MAC frame is 64 bytes or more, the L2 switches 120 and 220 discard as a frame abnormality when receiving a test control signal and a test control response. As a result, the test control signal and the test control response are not transmitted to the LAN side interface units 110 and 210. That is, the test control signal and the test control response have an influence on other devices connected to the LAN side interface units 110 and 210 without adding special processing for discarding the test control signal and the test control response. Don't give it.

Embodiment 2. FIG.
FIG. 9 is a sequence diagram showing an operation in the second embodiment (embodiment 2) of the separation test performed in the communication system including the optical media converter device according to the present invention. In the isolation test of the second embodiment, the loop path including the LAN side interface unit 110 and the loop path including the LAN side interface unit 210 are not generated. Further, a third test control signal is transmitted from the test control signal transmission unit 142 of the center apparatus 100 instead of the first test control signal. With reference to FIG. 9, the operation | movement in the carving test of 2nd Embodiment is demonstrated. Note that the configuration of the communication system of the second embodiment is the same as the configuration shown in FIG.

  When the test control unit 141 of the center apparatus 100 detects a test start trigger (step S101), it starts the timer X (step S102).

  When the timer X is started in step S102, the test control unit 141 starts preparation for flowing test data on the data path. The test control unit 141 transmits a loop control signal to the signal switching units 148 and 149. The signal switching unit 148 causes the switch to be connected to ct according to the loop control signal, and the signal switching unit 149 maintains the switch to the state where cn is connected (step S103). By switching the switches of the signal switching units 148 and 149, the main signal does not flow in the direction from the center device 100 to the remote device 200. The test control unit 141 transmits a loop control signal to the LAN side interface unit 110. The LAN-side interface unit 110 maintains the two switches in the LAN-side interface unit 110 in a state where cn is connected according to the loop control signal (step S104). With the processing in steps S103 and S104, generation of the loop path on the center device 100 side is completed (step S105).

  When the loop control signal is transmitted in step S14, the test control unit 141 causes the test control signal transmission unit 142 to generate a third test control signal (test start request) that requests the start of the test. The test control signal transmission unit 142 generates and transmits a third test control signal according to the control of the test control unit 141 (step S106). The third test control signal incorporates information that a data path from the transmission unit 144 to the verification unit 246 is generated.

  The test control signal detection unit 243 detects the third test control signal transmitted by the test control signal transmission unit 142 via the optical communication line 500. When the test control signal detection unit 243 detects the third test control signal, the test control unit 241 recognizes the start of the test and activates the timer Y (step S107).

  When the timer Y is started in step S107, the test control unit 241 displays a test in progress (step S108). The test control unit 241 transmits a loop control signal to the signal switching units 248 and 249. The signal switching unit 248 keeps the switch connected to cn in accordance with the loop control signal, and the signal switching unit 249 sends the main signal with the switch connected to ct. The main signal line is switched to a state in which test data flows (step S109). With the processing in step S109, generation of the loop path on the remote device 200 side is completed.

  When the data path is switched in step S109, the test control unit 241 causes the test control response transmission unit 242 to generate a first test control response (test start response) indicating that the preparation for starting the test is completed. The test control response transmission unit 242 generates a first test control response according to the control of the test control unit 241, and transmits the first test control response to the center apparatus 100 (step S110).

  The test control response detection unit 143 detects the first test control response transmitted by the test control response transmission unit 242 via the optical communication line 500. When the test control response detection unit 143 detects the first test control response, the test control unit 141 starts the timer Z (step S111).

  When the timer Z is started in step S111, the transmission unit 144 of the center apparatus 100 transmits the test data A-1 (step S112).

  FIG. 10 is an explanatory diagram showing a route of test data in the second embodiment. With reference to FIG. 10, the flow of the test data A-1 transmitted from the transmission unit 144 will be described. When test data is transmitted in step S112, one loop path is generated by the center apparatus 100, the remote apparatus 200, and the optical communication line 500. As shown in FIG. 10, the test data A-1 transmitted from the transmission unit 144 is received by the verification unit 246 through the WAN side conversion unit 130, the downlink in the optical communication line 500 and the WAN side conversion unit 230. The

  The collation unit 246 collates the content of the received test data A-1 with the content of the transmitted test data (step S113). Then, the verification unit 246 of the remote device 200 notifies the test control unit 241 of the verification result.

  When the time counted by the timer Z expires (step S114), the test control unit 141 requests the test control signal transmission unit 142 to notify the test result in the remote device 200 (second test control signal). Is generated. The test control signal transmission unit 142 generates and transmits a second test control signal in accordance with the control of the test control unit 141 (step S115).

  The test control signal detection unit 243 detects the second test control signal transmitted by the test control signal transmission unit 142 via the optical communication line 500. When the test control signal detection unit 243 detects the second test control signal, the test control unit 241 transmits a loop control signal to the signal switching units 248 and 249. The signal switching unit 248 maintains the switch with the cn connected in accordance with the loop control signal, and the signal switching unit 249 sets the switch with the cn connected (step S116). By the processing in step S116, the loop path on the remote device 200 side is released.

  The test control unit 241 causes the test control response transmission unit 242 to generate a second test control response (test result response) for notifying the test result in the remote device 200. The test control response transmission unit 242 generates a second test control response according to the control of the test control unit 241 and transmits the second test control response to the center apparatus 100 (step S117). When the second test control response is transmitted, the test control unit 241 cancels the display during the test (step S118) and stops the timer Y (step S119).

  The test control response detection unit 143 detects the second test control response transmitted by the test control response transmission unit 242 via the optical communication line 500. When the test control response detection unit 143 detects the second test control response, the test control unit 141 transmits a loop control signal to the signal switching units 148 and 149. The signal switching unit 148 causes the switch to be connected to cn according to the loop control signal, and the signal switching unit 149 maintains the switch to the state where cn is connected. (Step S120). The loop path on the center device 100 side is released by the processing in step S120.

  The test control unit 141 stops the timer X (step S121). And the test control part 141 acquires the test result in the remote apparatus 200, and outputs the acquired test result (step S122). The test results in the second embodiment include, for example, information indicating the collation result in the collation unit 246 and whether the timers X, Y, and Z are activated and the time measurement has expired.

  In such an optical media converter device, test data is transmitted only in the direction from the center device 100 to the remote device 200. Therefore, when an abnormality occurs in the collating unit 246, the transmission from the center device 100 to the optical communication line 500 is performed. It can be estimated that a failure has occurred before reaching the remote device 200 via the line. In the communication system according to the second embodiment, the data path of the main signal in the direction from the remote device 200 to the center device 100 is not changed, so that the test is performed without stopping the transmission of the main signal from the remote device 200 to the center device 100. Can be implemented. Furthermore, the test can be performed even when the LAN side interface unit does not have a function of generating a loop path.

  If a plurality of types of test data data path generation patterns are prepared, in addition to the transmission of test data in the data path of the remote apparatus 200 from the center apparatus 100 in the second embodiment, tests in various data paths are performed. Data can be transmitted. For example, a data path from the remote device 200 toward the center device 100, within the center device 100 including the LAN side interface unit 110, or within the remote device 200 including the LAN side interface unit 210 is conceivable.

  Information indicating the generation pattern of the data path of the test data to be selected is incorporated in the test control signal and the test control response. FIG. 11 is an explanatory diagram illustrating an example of a test control signal including data pattern generation pattern information of test data. The test control signal shown in FIG. 11 is a maintenance signal conforming to TS-1000. As shown in FIG. 11A, since the frame length is 12 bytes and less than 16 bytes, the test control signal received by the L2 switches 120 and 220 is discarded.

  The generation pattern information of the data path of the test data is shown at signal positions C12 to C15 in the detailed format content diagram of FIG. The generation pattern of the data path of the test data can be determined depending on how the four bits C12 to C15 are set. For example, in the case of the third test control signal transmitted in step S106, information that the value of the C12-C15 bit is “1000” and a data path from the transmission unit 144 to the verification unit 246 is generated is incorporated. .

  In this way, by generating various data paths alone or in combination and transmitting test data, the optical media converter device performs various types of separation tests according to the failure occurrence status, the function of the optical media converter device, etc. It is possible to reduce the influence of the main signal on the data path.

  In the communication systems of the first embodiment and the second embodiment, the center apparatus 100 may include a test control response transmission unit 242 and a test control signal detection unit 243. The remote device 200 may include a test control signal transmission unit 142 and a test control response detection unit 143. Further, the test control unit 141 controls various operations related to the carving test in the center device 100 according to the test control signal transmitted from the remote device 200, and the test control unit 241 controls the remote device according to the test start trigger. Various operations related to the carving test may be controlled at 200. In the communication system including the optical media converter device configured as described above, for example, a test start trigger can be sent to the remote device 200 to perform the separation test.

  FIG. 12 is a block diagram showing the main part of the optical media converter device according to the present invention. As shown in FIG. 12, the optical media converter device 1 (for example, equivalent to the center device 100 shown in FIG. 2) is connected to the other via the optical communication line 2 (for example, equivalent to the optical communication line 500 shown in FIG. 2). An optical media converter device that communicates with the optical media converter device 3 (for example, equivalent to the remote device 200 shown in FIG. 2), and switches the main signal path (for example, equivalent to the main signal line in the first embodiment). A signal switching unit 4 (for example, corresponding to the signal switching units 148, 149, 248, and 249 shown in FIG. 2) and a device-side interface unit 5 (for example, that transmits and receives data to and from the device). 2 and corresponding to the LAN side interface units 110 and 210 shown in FIG. 2) and a test control signal transmission unit 6 for transmitting a test control signal (for example, the test control signal shown in FIG. 2). A test control response transmitter 7 (e.g., equivalent to the test control response transmitter 242 shown in FIG. 2) and a plurality of transmitters 8 (e.g., equivalent to the test control response transmitter 242 shown in FIG. 2). 2) and a plurality of collating units 9 (for example, collating units 146 shown in FIG. 2) that collate the contents of the received test data with the contents of the transmitted test data. , 147, 246, 247) and an output unit 10 (for example, equivalent to the test control unit 141 shown in FIG. 2) that outputs the test results. A data path for flowing test data is generated by switching the main signal path provided inside, and the test control response transmitter 7 transmits from the test control signal transmitter 6 of the other optical media converter device 3. When the received test control signal is received, a test control response is transmitted. When the plurality of transmission units 8 receive the test control signal or the test control response, the plurality of transmission units 8 transmit data to the data paths generated in the signal switching unit 4 and the device-side interface unit 5. The test data is transmitted, and the output unit 10 is configured to output the test result based on the collation results in the plural collation units 9 and the collation results in the plural collation units 9 of the other optical media converter devices 3. ing.

  In each of the above embodiments, optical media converter devices as shown in the following (1) to (6) are also disclosed.

(1) It includes a timer for measuring the time for holding the data path generated in the signal switching unit and the device side interface unit, and the time for transmitting the test data, and when the timer time expires, the output unit tests An optical media converter device that outputs the result (for example, realized by the processing in steps S57 to S61 or the processing in steps S86 to S96). In such an optical media converter device, when the separation test does not proceed normally, an abnormal end can be output upon expiration of the timer.

(2) The output unit outputs the collation result in the plural collation units and whether or not the timer is started or the time is expired (for example, realized by outputting the test result in step S44). .

(3) The optical media converter device in which the test control signal and the test control response have a frame length different from that of the MAC frame (for example, realized by the test control signal and the test control response shown in FIG. 8). In such an optical media converter device, since the test control response and the test control response are discarded by the L2 switches 120 and 220, the test control signal and the test control are transmitted to other devices connected to the LAN side interface units 110 and 210. The response is not affected.

(4) The test control signal includes information for specifying one or more data paths (for example, realized by the test control signal shown in FIG. 11), and the signal switching unit and the device-side interface unit perform the test. An optical media converter device that generates a data path according to information specifying a data path when generating a data path after receiving a control signal. In such an optical media converter device, it is possible to limit the range for performing the separation test, and to perform the separation test while reducing the influence on the main signal path.

(5) An optical media converter that communicates with another optical media converter via an optical communication line, a signal switching unit that generates a data path for switching test signal and switching a main signal path, and a test control signal A test control signal transmitter for transmitting test data, a test control response transmitter for transmitting test control responses, a transmitter for transmitting test data, and a verification unit for comparing the content of received test data with the content of transmitted test data And an output unit for outputting a test result, and the test control response transmission unit transmits a test control response when receiving the test control signal transmitted from the test control signal transmission unit of another optical media converter device, and transmits the test control response. When receiving the test control signal or the test control response, the unit transmits the test data to the data path generated in the signal switching unit, and the output unit receives the verification result in the verification unit. Other verification result and optical media converter device for outputting a test result based on the matching portion of the optical media converter device.

(6) The signal switching unit switches the main signal path while maintaining the state in which the main signal can pass in one direction on the main signal path (for example, realized by the processing in steps S103 and S109). An optical media converter device that generates a data path to be sent (for example, realized by the optical media converter device in the second embodiment). In such an optical media converter device, test data can be transmitted without stopping communication of the unidirectional main signal, so that it is possible to perform a separation test with reduced influence on the main signal path.

  The present invention can be applied to an optical media converter device used by a telecommunication carrier or the like.

DESCRIPTION OF SYMBOLS 1,3 Optical media converter apparatus 2 Optical communication line 4 Signal switching part 5 Apparatus side interface part 6 Test control signal transmission part 7 Test control response transmission part 8 Transmission part 9 Verification part 10 Output part 100 Center apparatus 110,210 LAN side interface Unit 120,220 L2 switch 130,230 WAN side conversion unit 141,241 test control unit 142 test control signal transmission unit 143 test control response detection unit 144,145,244,245 transmission unit 146,147,246,247 verification unit 148 , 149, 248, 249 Signal switching unit 200 Remote device 242 Test control response transmission unit 243 Test control signal detection unit 500 Optical communication line

Claims (16)

A communication system in which a first optical media converter device and a second optical media converter device communicate via an optical communication line,
The first optical media converter device includes:
A first signal switching unit for switching the main signal path to generate a data path for flowing test data;
A first device-side interface unit that transmits and receives data to and from the device;
A test control signal transmission unit which transmits a test control signal,
A plurality of first transmitters for transmitting test data;
A plurality of first matching portion for matching the contents of the received test data and contents of the transmitted test data,
An output unit for outputting test results,
The second optical media converter device includes:
A second signal switching unit for switching the main signal path and generating a data path for flowing test data;
A second device-side interface unit that transmits and receives data to and from the device;
A test control response transmitter for transmitting a test control response;
A plurality of second transmitters for transmitting test data;
A plurality of second verification units for verifying the content of the received test data and the content of the transmitted test data;
The first device side interface unit generates a data path for flowing test data by switching a main signal path provided inside the first device side interface unit,
The second device-side interface unit generates a data path for flowing test data by switching a main signal path provided inside the second device-side interface unit,
The test control response transmission unit transmits the test control response to receiving the test control signal transmitted from said test control signal transmitting unit of the first optical media converter device,
The first transmission unit of the plurality transmits upon receiving a pre-Symbol test control response, the test data to said first signal switching unit and the first device-side interface unit to generate the data path,
When the plurality of second transmission units receive the test control signal, the plurality of second transmission units transmit test data to the data path generated in the second signal switching unit and the second device-side interface unit,
Communication system and the output unit, characterized in that the output and collation result in the plurality of first matching unit, a test result based on the comparison result in the second matching unit of the multiple. Time for maintaining the first signal switching unit and the first device-side interface generated data path unit, and includes a timer for measuring the time of transmitting the test data,
The communication system according to claim 1, wherein the output unit outputs a test result when a time measured by the timer expires. The communication system according to claim 2, wherein the output unit outputs a collation result in the plurality of first collation units and the plurality of second collation units and whether or not the timer is started or the time is expired. The communication system according to any one of claims 1 to 3, wherein the test control signal and the test control response have a frame length different from that of the MAC frame. The test control signal includes information identifying one or more data paths,
The second signal switching unit and the second device-side interface unit generate a data path according to information specifying the data path when generating the data path after receiving the test control signal. The communication system according to any one of claims 1 to 4. A communication system in which a first optical media converter device and a second optical media converter device communicate via an optical communication line,
The first optical media converter device includes:
A first signal switching unit for switching the main signal path to generate a data path for flowing test data;
A test control signal transmission unit which transmits a test control signal,
A first transmitter for transmitting test data;
A plurality of first matching portion for matching the contents of the received test data and contents of the transmitted test data,
An output unit for outputting test results,
The second optical media converter device includes:
A second signal switching unit for switching the main signal path and generating a data path for flowing test data;
A test control response transmitter for transmitting a test control response;
A plurality of second transmitters for transmitting test data;
A plurality of second verification units for verifying the content of the received test data and the content of the transmitted test data;
The test control response transmission unit transmits the test control response to receiving the test control signal transmitted from said test control signal transmitting unit of the first optical media converter device,
The first transmission unit transmits upon receiving a pre-Symbol test control response, the test data to the generated data path to said first signal switching unit,
When the second transmission unit receives the test control signal, the second transmission unit transmits test data to the data path generated by the second signal switching unit,
The said output part outputs a test result based on the collation result in a said 1st collation part, and the collation result in a said 2nd collation part. The communication system characterized by the above-mentioned. The first signal switching unit generates a data path through which test data flows by switching the main signal path while maintaining a state in which the main signal can pass in one direction on the main signal path ,
The communication system according to claim 6, wherein the second signal switching unit generates a data path through which test data flows by switching the main signal path while maintaining a state in which the main signal can pass in one direction on the main signal path . A timer for measuring the time for holding the data path generated in the first signal switching unit and the time for transmitting the test data;
The communication system according to claim 6 or 7, wherein the output unit outputs a test result when a time measured by the timer expires. The communication system according to claim 8, wherein the output unit outputs a collation result in the first collation unit and the second collation unit, and whether or not a timer is started or a time is expired. The communication system according to any one of claims 6 to 9, wherein the test control signal and the test control response have a frame length different from that of the MAC frame. The test control signal includes information identifying one or more data paths,
The second signal switching unit generates a data path according to information specifying the data path when generating the data path after receiving the test control signal. The communication system according to any one of the above. A fault isolation test method in a communication system in which a first optical media converter device and a second optical media converter device communicate via an optical communication line,
The first optical media converter device comprises:
Generating a data path for flowing the test data by switching a main signal path,
A data path for flowing test data is generated by switching a main signal path provided inside the first apparatus-side interface unit that transmits and receives data to and from the apparatus,
It transmits a test control signal,
Upon receiving the test control response, and transmits the test data to the generated data path from a plurality of first transmission unit,
Against a plurality of first matching portion for matching the contents of the received test data and contents of the transmitted test data,
The second optical media converter device comprises:
Generate a data path that flows the test data by switching the main signal path,
A data path for flowing test data is generated by switching a main signal path provided in the second apparatus side interface unit that transmits and receives data to and from the apparatus,
When the test control signal is received, the test control response is transmitted,
Upon receiving the test control signal, the test data is transmitted from the plurality of second transmission units to the generated data path,
A plurality of second verification units that collate the content of the received test data with the content of the transmitted test data,
The first optical media converter device, characterized in that the collation result in said plurality of first matching unit, you output a test result based on the comparison result of the second matching unit of the multiple Fault isolation test method. The first optical media converter device outputs a test result when a time for holding a generated data path and a timer for measuring time for transmitting test data have expired. Fault isolation test method. First optical media converter apparatus, failure according to claim 13 for outputting a collation result in the plurality of first matching unit and a plurality of second matching unit, and whether the expiration of the timer start or measurement time Carving test method. The fault isolation test method according to any one of claims 12 to 14, wherein the test control signal and the test control response have a frame length different from that of the MAC frame. The test control signal includes information identifying one or more data paths,
The second optical media converter device, when generating the data path after receiving the test control signal, generates the data path according to information specifying the data path. The fault isolation test method according to any one of the above.

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