JP2004015217A - Media converter and communication system employing the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a media converter capable of enhancing the reliability of a loopback test. <P>SOLUTION: A subscriber side media converter starts self-diagnosis (S13) on the basis of a loopback test start request maintenance signal (S31) from a station office side media converter (MC) and transmits the result of self-diagnosis to the station office side media converter together with a loopback test signal (S17). <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a media converter and a communication system using the same.
[0002]
[Prior art]
A media converter is a device that connects different transmission media (for example, an optical fiber and a metal cable) and converts signals transmitted through these media into each other.
[0003]
As a specific example of the media converter, for example, an Ethernet (registered trademark) signal of 10BASE-T or 100BASE-TX standard of IEEE802.3 using a metal twisted pair cable and an Ethernet (registered trademark) of 100BASE-FX system using an optical fiber are used. There are devices to convert to signals.
[0004]
By using such a media converter, for example, a signal that can only flow about 100 m using a local area network (hereinafter, referred to as a LAN) using a metal twisted pair cable is transmitted to an optical fiber through a media converter. By flowing, it is possible to transmit up to several tens km.
[0005]
Practical examples of such a media converter include practical use of optical communication using an optical fiber cable such as FTTH (Fiber to the home), and a WAN in which a plurality of LANs are connected by an optical fiber cable. it can.
[0006]
For example, in FTTH, an optical fiber cable is laid between an accommodation station and a telephone pole near a subscriber, and one end of the optical fiber cable is drawn into a subscriber's residence and connected to an indoor communication terminal. At this time, the connection of the peripheral equipment including the indoor communication terminal is left as a metal cable, and a media converter that converts an electric signal to an optical signal is connected between the optical fiber cable and the communication terminal, so that the optical fiber is connected. It enables high-speed communication by cable. In such FTTH, media converters are provided on the office side and on the subscriber side, respectively.
[0007]
The media converter is provided with a mechanism for confirming the status of one from the other. For example, SNMP (Simple Network Management Protocol) is one of them. SNMP is a network management protocol for remotely monitoring and setting the operating status of network devices such as media converters, routers, and switches.
[0008]
The media converter also uses this SNMP to send a signal of a format different from the data signal called a maintenance signal from the office side media converter to the subscriber side media converter, and to operate the subscriber side media converter, for example, a link. Status, power on / off, etc. can be monitored.
[0009]
Using this maintenance signal, a normal operation confirmation test called a loopback test may be performed between the office-side media converter and the subscriber-side media converter.
[0010]
In the loopback test, data of only the frame portion of the Ethernet (registered trademark) signal is transmitted as a loopback test signal from the central office side media converter to the subscriber media converter, and this loopback test signal is transmitted inside the subscriber side media converter. In this test, the line to the loopback point in the subscriber-side media converter is checked by comparing the data of the test signal received and transmitted by the building-side media converter with the data of the received loopback test signal.
[0011]
FIG. 6 is a sequence diagram showing the procedure of the loopback test.
[0012]
First, a maintenance signal for a loopback test start request is transmitted from the station side media converter (station side MC) to the subscriber side media converter (S301).
[0013]
When the subscriber-side media converter (subscriber-side MC) receives and detects the maintenance signal of the loopback test start request (S101), it sets the internal circuit to the loopback state (S102), and then transmits the start response. The maintenance signal is transmitted to the office side media converter (S103).
[0014]
After receiving the maintenance signal of the start response (S302), the station side media converter transmits a test signal (S303).
[0015]
The loopback test signal transmitted from the office side media converter is looped back by the circuit in the subscriber side media converter in which the loopback is set, and received by the office side media converter (S304).
[0016]
After that, a maintenance signal of a termination request is transmitted from the office side media converter to the subscriber side media converter (S305), and the subscriber side media converter receives the termination request and detects this (S104). It is released (S105), and the maintenance signal of the end response is transmitted.
[0017]
The office-side media converter receives the end response and ends the loopback test (S306).
[0018]
In this way, it is possible to confirm on the station side the failure of the station side media converter, the subscriber side media converter, the optical fiber cable existing between them, and the subscriber side media converter installed remotely.
[0019]
[Problems to be solved by the invention]
However, the loopback test is based on the principle, and confirms whether or not the transmission path until the test signal transmitted from the office side media converter is looped back at the loopback point inside the subscriber side media converter is normal. I can only do it. That is, it is impossible to verify and confirm a portion that is not related to the transmission path of the loopback test signal.
[0020]
In particular, in the subscriber side media converter, there is a circuit in which the loopback test signal does not flow, and there is a problem that it is not possible to confirm whether such a circuit has a failure. This is a problem in that the more parts that cannot be confirmed by the loopback test, the lower the reliability of the loopback test.
[0021]
The present invention has been made in view of the above, and has as its object to provide a media converter capable of improving the reliability of a loopback test performed by a media converter, and a communication system using the media converter. It is.
[0022]
[Means for Solving the Problems]
According to a first aspect of the present invention, there is provided a media converter for mutually converting a signal flowing through a first transmission medium and a signal flowing through a second transmission medium. Means, and a diagnostic result transmitting means for transmitting a diagnostic result diagnosed by the diagnostic means to the second transmission medium when a loopback test signal is input from the second transmission medium. I do.
[0023]
According to a second aspect of the present invention, in the media converter according to the first aspect, the diagnosing unit diagnoses each unit in a range where the loopback test signal does not reach.
[0024]
The invention according to claim 3 is a first media converter for mutually converting a signal flowing through a first transmission medium and a signal flowing through a second transmission medium, the first media converter and the second transmission medium. And a second media converter for mutually converting a signal flowing through a first transmission medium and a signal flowing through the second transmission medium, wherein the first media converter comprises: Diagnosing means for diagnosing each unit in the media converter, and transmitting a diagnostic result to the second media converter when receiving a loopback test signal from the second media converter. Means, the second media converter comprising: transmitting means for transmitting a loopback test signal to the first media converter; A diagnostic result receiving means for receiving the diagnosis result from the first media converter, that with the gist.
[0025]
According to a fourth aspect of the present invention, in the communication system of the third aspect, the diagnosing unit diagnoses each unit in a range where the loopback test signal does not reach.
[0026]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[0027]
(First Embodiment)
FIG. 1 is a diagram showing a communication system in which a media converter according to the present invention is used as a media converter for a central office and a media converter for a subscriber.
[0028]
The illustrated communication system includes a subscriber-side media converter 1 and a station-side media converter for connecting LANs 121 and 123 formed of a metal twisted pair cable (first transmission medium) by an optical fiber cable 110 (second transmission medium). 3 is used.
[0029]
Here, the LANs 121 and 123 perform communication using the 100BASE-TX standard using a metal twisted pair cable, and the optical fiber cable 110 performs communication using the 100BASE-FX standard. The optical fiber cable 110 is a two-core fiber or a one-core optical fiber when a multiplexing / demultiplexing device (not shown) is used for a media converter.
[0030]
Hereinafter, the configuration of the media converter according to the present embodiment will be described.
[0031]
First, the subscriber side media converter 1 has a LAN side transmitting / receiving section (PHY) 11 for transmitting / receiving data to / from the LAN 121 and an optical fiber side transmitting / receiving section 15 for transmitting / receiving data to / from the optical fiber cable 110.
[0032]
The LAN-side transmission / reception unit 11 includes a transmission unit (Tx) 11a and a reception unit (Rx) 11b, and performs signal transmission / reception processing with the LAN 121 using a physical layer level protocol.
[0033]
On the other hand, the optical fiber side transmission / reception unit 15 includes a transmission unit (Tx) 15a and a reception unit (Rx) 15b, and performs a signal transmission / reception process with the optical fiber cable 110 using a physical layer level protocol. An electrical / optical converter (E / O) 16 is connected between the transmitting unit 15a and the optical fiber cable 110, and an optical / electrical converting unit between the transmitting unit 15a and the optical fiber cable 110. (O / E) 17 is connected.
[0034]
The electrical / optical conversion unit 16 modulates an optical signal output from a laser diode (not shown) with a data signal output from the transmission unit 15a, and converts the modulated optical signal into an optical fiber cable 110 of the 100BASE-FX standard. Output to Conversely, the optical / electrical conversion unit 17 demodulates the optical signal input from the optical fiber cable 110 and generates a data signal (electric signal).
[0035]
There is a maintenance sublayer 12 and a MAC switch 13 between the LAN side transmitting / receiving section 11 and the optical fiber side transmitting / receiving section 15 of the subscriber side media converter 1.
[0036]
The maintenance sub-layer 12 has a function of transmitting a maintenance signal other than a data signal for local information transmission and a function of detecting the maintenance signal, and is a media independent interface (MII) that is an interface independent of a transmission medium (media). The transmission / reception processing unit 15 is connected to the transmission / reception processing unit 11 via the MAC switch 13 by a media independent interface (Data Independent Interface), and a data interface, a transmission error signal (TX-ER), a reception error signal (RX-ER signal), and the like are provided. Signal is transmitted and received.
[0037]
The MAC switch 13 converts a communication speed (such as 10BASE-T or 100BASE-TX), a communication mode (such as Half-duplex or Full-duplex), and a transmission mode. The MAC switch 13 has a packet buffer 14 for a packet memory.
[0038]
In the media converter 1, there is a control unit 19 for controlling each of the above units. The control unit 19 includes an SNMP agent 18 that receives an instruction from an SNMP manager (described later) by a command specified by the SNMP protocol, notifies the SNMP manager of stored information, and changes a set value. I have.
[0039]
Further, the control unit 19 has a self-diagnosis function for self-diagnosing the function of each unit in the media converter.
[0040]
The control unit 19 sends a maintenance signal (details described later) assigned to each signal by the function of the SNMP agent 18 based on the input local information, for example, a signal such as a loopback test start request or a termination request. The maintenance sublayer 12 is controlled so as to perform the maintenance.
[0041]
Note that the subscriber side media converter 1 is usually provided with an external AC adapter 50 for converting alternating current from a commercial power supply (AC 100 V) to DC of 12 V, and DC power from this AC adapter is required for each unit. The power supply unit 20 includes a power supply unit 20 that converts the power to a required voltage and supplies the converted voltage.
[0042]
Next, the configuration of the office-side media converter will be described.
[0043]
The office-side media converter 3 is basically the same as the subscriber-side media converter, and transmits and receives data to and from the LAN-side transmission / reception unit 31 that transmits and receives data to and from the office-side LAN 123 and the optical fiber cable 110. An optical fiber side transmitting / receiving unit 33, an electric / optical converting unit (E / O) 34 for converting an electric signal into an optical signal, and an optical / electric converting unit (O / E) 35 for converting an optical signal into an electric signal. , A LAN-side transmission / reception unit 31 and an optical fiber-side transmission / reception unit 33 connected by a media independent interface (MII), and a maintenance sublayer 32 for generating and detecting a maintenance signal, a control unit 37 for controlling these, and a control unit 37 And an SNMP unit 41 having an SNMP manager 43 connected thereto.
[0044]
Here, the LAN side transmission / reception unit 31 and the optical fiber side transmission / reception unit 33 are the same as those in the subscriber side media converter 1, and include a transmission unit (Tx) 31a, a reception unit (Rx) 31b, and a transmission unit ( The transmission unit (Tx) 31a and the reception unit (Rx) 31b of the LAN-side transmission / reception unit 31 perform transmission / reception processing between the LAN 123 and the Tx) 33a and the reception unit (Rx) 33b. The transmission unit (Tx) 33a and the reception unit (Rx) 33b perform transmission / reception processing via the optical fiber cable 110 and the electric / optical converter 34 and the optical / electric converter 35, respectively.
[0045]
The maintenance sub-layer 32 is also the same as the one in the subscriber side media converter, and performs generation and detection of a maintenance signal, data interface, transmission and reception of an error signal (TX-ER, RX-ER signal, etc.) and the like.
[0046]
The SNMP unit 41 connected to the control unit 37 is connected to the office-side media converter 3, and the SNMP manager application is executed on a personal computer connected to the SNMP unit 41, whereby the control unit 37 is connected. , And sends a maintenance signal detected by the maintenance sublayer 32. Output devices such as a display and a printer are connected to the personal computer, and display and output the results of a folding test and the like performed according to the procedure described later.
[0047]
Hereinafter, the operation of the media converter according to the first embodiment will be described.
[0048]
First, the operation of the subscriber-side media converter 1 and the office-side media converter 3 in normal communication will be described.
[0049]
Here, a case where a signal from the LAN 123 on the office side is transmitted to the LAN 121 on the subscriber side will be described as an example. In the opposite case, that is, when transmitting a signal from the LAN 121 on the subscriber side to the LAN 123 on the office side, the operation is the reverse of the above description, and the description is omitted.
[0050]
A signal from the LAN 123 on the office side is input to the receiving unit 33b of the LAN transmitting / receiving unit 31 via the connector 38. Since the input signal is flowing in the LAN 123 as a ternary signal of MLT-3 (Multi-Level Transmission-3), the receiving unit 33b converts the signal into a data signal independent of the medium (a data signal by MII). To compound.
[0051]
The combined data signal is input to the transmission unit 33a of the optical fiber transmission / reception unit 33 via the maintenance sublayer 32.
[0052]
The transmitting unit 33a performs 4B / 5B code conversion on the input data signal, which expresses 4-bit information with a 5-bit code, and encodes the data signal using the NRZI method. The transmitting unit 33a further performs a scrambling operation on the encoded signal to convert the coded signal into an MLT-3 ternary signal, and outputs the ternary signal to the electrical / optical conversion unit 34.
[0053]
The electrical / optical converter 34 modulates an optical signal with the input electrical signal and outputs the modulated optical signal to the optical fiber cable 110.
[0054]
The output optical signal passes through the optical fiber cable 110 and is input to the optical / electrical converter 17 of the media converter 1 on the subscriber side, is converted into an electrical signal, and is input to the receiver 15b of the transmitter / receiver 15 on the optical fiber side. .
[0055]
The receiving unit 15b combines the signals. The combined data signal is input to the transmission section 11a of the LAN-side transmission / reception section 11 via the maintenance sublayer 12 and the MAC switch 13.
[0056]
The transmitting unit 11a converts the input data signal into a 4B / 5B code, encodes the data signal according to the NRZI method, performs a scramble operation to convert the data signal into a MLT-3 ternary signal, To the local LAN 121.
[0057]
Next, a return test in the media converter will be described.
[0058]
FIG. 2 is a diagram for explaining a turning point in the subscriber-side media converter at the time of performing a loop test, and FIG. 3 is a diagram illustrating an operation sequence of the loop test.
[0059]
In the first embodiment, as shown in FIG. 2, a maintenance sublayer 12 is set as a turning point set in the subscriber-side media converter 1.
[0060]
When the maintenance sublayer 12 is used as a return point, for example, a return switch 10 that directly connects a signal (electrical signal) from the reception unit 15b of the optical fiber side transmission / reception unit 15 directly to the transmission unit 15a in the maintenance sublayer 12 is used. By setting the folding switch 10 on and off under the control of the control unit 19, the signal is folded only at the time of the folding test.
[0061]
When the maintenance sublayer 12 is used as a return point, the return test signal is returned without passing through the MAC switch 13, the packet buffer 14, the connector 21, and the transmission / reception processing unit 11, so that these parts are normal. Cannot be confirmed by a folding test.
[0062]
Therefore, in the first embodiment, the SNMP agent 18 uses the self-diagnosis function built into the control unit 19 to make it possible for the return test signal not to reach, that is, the transmission / reception processing unit 11 and the MAC switch 13. Is diagnosed when a return test start request is received, and the diagnosis result is transmitted to the station side media converter 3 which transmitted the return test signal.
[0063]
This folding test is performed according to the procedure shown in FIG.
[0064]
First, the SNMP manager 43 in the office-side media converter 3 instructs the control unit 37 to transmit a maintenance signal for a loopback test start request to the subscriber-side media converter 1. As a result, the control unit 37 controls the maintenance sub-layer 32 so as to transmit the maintenance signal of the return test start request. Then, a maintenance signal for a loopback test start request is transmitted from the maintenance sublayer 32 to the subscriber side media converter 1 (S31).
[0065]
In the subscriber-side media converter 1 that has received the maintenance signal of the return test start request, the maintenance sublayer 12 detects this maintenance signal and passes the detected maintenance signal to the SNMP agent 18 (S11).
[0066]
The SNMP agent 18 uses the received loopback test start request as a trigger to instruct the control unit 19 to set a loopback point in a predetermined position in the subscriber-side media converter 1, here, the maintenance sublayer 12 ( S12). At the same time, the SNMP agent 18 instructs the control unit 19 to start self-diagnosis (S13).
[0067]
As a result, the control unit 19 turns on the return switch 10 in the maintenance sublayer 12, sets a return point, and starts self-diagnosis. The self-diagnosis performed at this time only needs to be performed for each unit in a range where the return signal does not reach. Here, the function diagnosis of the MAC switch 13, the packet buffer 14, and the LAN-side transmission / reception unit 11 is performed.
[0068]
Then, when the SNMP agent 18 confirms the end of the self-diagnosis (S14), the SNMP agent 18 instructs the control unit 37 to transmit a maintenance signal of a return test start response to the station side media converter 3. Thereby, the control section 37 transmits a maintenance signal of a return test start response from the maintenance sublayer 12 to the office side media converter 3 (S15).
[0069]
In the station side media converter 3 receiving the maintenance signal of the return test start response, the maintenance sub-layer 32 detects this maintenance signal and passes it to the SNMP manager 43 via the SNMP unit 41 (S32).
[0070]
Upon receiving the maintenance signal of the loopback test start response, the SNMP manager 43 uses this as a trigger to instruct the control unit 37 to transmit a loopback test signal. Thereby, the control unit 37 instructs the maintenance sub-layer 32 to transmit a loopback test signal, and the maintenance sub-layer 32 generates a test signal including only the Ethernet (registered trademark) frame portion, and adds the test signal. Is transmitted to the media converter 1 on the user side (S33).
[0071]
The transmitted loopback test signal is received by the subscriber-side media converter 1, looped back at the loopback point (maintenance sublayer 12), and returned to the office-side media converter 3.
[0072]
At this time, the maintenance sublayer 12 of the subscriber-side media converter 1 detects the loopback test signal, and the information is passed to the SNMP agent 18 (S16). Thereby, the SNMP agent 18 collects the result of the self-diagnosis performed earlier, and transmits the result of the diagnosis to the office side media converter 3 (S17). For example, if the transmitted diagnostic result signals are all normal, data indicating that fact is transmitted, and if there is an abnormality, data for identifying an abnormal device is transmitted.
[0073]
The office-side media converter 3 receives the returned loopback test signal and the self-diagnosis result of the subscriber-side media converter 1 (S34). The maintenance sublayer 32 detects the received return test signal and the signal of the diagnosis result, and passes the detected signal to the SNMP manager 43.
[0074]
Thereafter, the SNMP manager 43 transmits a maintenance signal for a return test end request (S35).
[0075]
When the subscriber-side media converter 1 receives the return test end request, the maintenance sublayer 12 detects this signal (S18) and passes it to the SNMP agent 18. The SNMP agent 18 cancels the setting of the return. As a result, the control unit 19 turns off the return switch 10 (S19). Then, the SNMP agent 18 instructs the control unit 19 to transmit a maintenance signal of an end response. Thereby, the control unit 19 transmits a maintenance signal of an end response from the maintenance sublayer 12 (S20).
[0076]
In the station side media converter 3 which has received the maintenance signal of the end response, this maintenance signal is passed to the SNMP manager 43, and the return test ends (S36).
[0077]
Then, the SNMP manager 43 analyzes and displays the loopback test and the self-diagnosis result of the subscriber-side media converter by the SNMP unit 41 as necessary (for example, a user instruction).
[0078]
As described above, according to the first embodiment, at the time of the loopback test for the subscriber-side media converter 1, the state of the portion where the loopback test signal does not reach can also be obtained from the office side media converter 3. Becomes possible.
[0079]
(Second embodiment)
In the second embodiment, the return point of the test signal at the time of the return test in the subscriber side media converter is changed. Therefore, the configurations of the subscriber-side media converter 1 and the office-side media converter 3 as the communication system, and the normal communication operation are the same as those in the first embodiment, and the description thereof will be omitted.
[0080]
FIG. 4 is a drawing showing turning points in the second embodiment.
[0081]
As shown in the figure, in the second embodiment, the return point of the return test signal is set in the LAN side transmitting / receiving section 11 of the subscriber side media converter 1.
[0082]
Thus, the portion where the loopback test signal does not reach is only the packet buffer 14.
[0083]
Since the packet buffer 14 temporarily stores the data signal by the operation of the MAC switch 13, data is read and written by the return test signal flowing to the MAC switch 13. In the data of the loopback test signal as described above, only a small part of the memory area is used. For this reason, it is not possible to find an abnormality in most parts of the packet buffer 14 only by the loopback test.
[0084]
Therefore, in the second embodiment, at the time of the loopback test, a read / write test of the memory constituting the packet buffer 14 is performed on the packet buffer 14 so that an abnormality of the packet buffer 14 can be detected.
[0085]
FIG. 5 is a diagram showing an operation sequence of the loopback test according to the second embodiment.
[0086]
The loopback test operation according to the second embodiment is basically the same as the loopback test operation according to the first embodiment described above. Therefore, steps that perform the same processing as the steps in the operation sequence diagram shown in FIG. 3 are given the same step numbers.
[0087]
In the loopback test operation according to the second embodiment, similarly to the first embodiment, first, a maintenance signal of a loopback test start request is transmitted from the office side media converter 3 according to an instruction of the SNMP manager 43 ( S31).
[0088]
Then, in the subscriber-side media converter 1 that has received the maintenance signal of the return test start request, the maintenance sub-layer 12 detects this maintenance signal (S11) and passes it to the SNMP agent 18. The SNMP agent 18 uses the loopback test start request as a trigger to instruct the control unit 19 to set a loopback state in a predetermined position in the subscriber side media converter 1, here, the LAN side transmitting / receiving unit 11, and loopback. Points are set (S12).
[0089]
The setting of the return point may be the same as that set in the maintenance sublayer. For example, a signal (electric signal) previously output from the transmission unit 11a in the LAN-side transmission / reception unit 11 is directly input to the reception unit 11b. A turn-back switch 10 is provided, which is turned on and off according to an instruction from the control unit 19, so that a signal is turned back.
[0090]
Then, the SNMP agent 18 instructs the control unit 19 to execute a read / write test on the packet buffer 14 (S21). As a result, the MAC switch 13 performs a read / write test on the packet buffer 14 under the control of the control unit 19.
[0091]
When confirming the end of the read / write test for the packet buffer 14 (S22), the SNMP agent 18 transmits a maintenance signal of a loopback test start response to the office side media converter 3 (S15).
[0092]
Thereafter, in the same manner as in the first embodiment, in the station side media converter 3 which has received the maintenance signal of the loopback test start response, the loopback test signal is converted into the subscriber side media converter 1 by the instruction of the SNMP manager 43. Is transmitted to (S33).
[0093]
At this time, the maintenance sublayer 12 of the subscriber side media converter 1 detects the loopback test signal, and the information is passed to the SNMP agent 18. Then, the SNMP agent 18 collects the read / write test result of the packet buffer 14, and transmits the collected read / write test result to the station side media converter 3 separately from the loopback test signal (S23). As the transmitted read / write test result signal, for example, when the signal is normal, data indicating the fact is transmitted, and when there is an abnormality, data indicating the abnormality is transmitted.
[0094]
When the office-side media converter 3 receives the self-diagnosis result of the subscriber-side media converter 1 together with the returned loopback test signal, the maintenance sub-layer 32 detects this and passes it to the SNMP manager 43 (S34). The SNMP manager 43 transmits a maintenance signal for a return test end request (S35).
[0095]
The subscriber side media converter 1 receives the return test end request (S18), the SNMP agent 18 releases the return setting (turnback switch 10 off) (S19), and transmits a maintenance signal of the end response (S20). .
[0096]
Upon receiving the maintenance signal of the end response, the office side media converter 3 passes this maintenance signal to the SNMP manager 43 and ends the loopback test (S36).
[0097]
Thereafter, the SNMP manager 43 analyzes and displays the results of the loopback test and the read / write test by the SNMP unit 41 as necessary (for example, a user instruction).
[0098]
As described above, in the second embodiment, the return point of the loopback test signal is set to the LAN side transmission / reception unit 11 of the subscriber side media converter 1 and only the packet buffer 14 that cannot be checked only by the loopback test signal is stored in the memory. By performing the read / write test, the abnormality of the packet buffer 14 can be determined at the time of the loopback test.
[0099]
In particular, in the second embodiment, the return point is set to the LAN-side transmission / reception unit 11 of the subscriber-side media converter 1, so that the return test signal input from the optical-fiber-side transmission / reception unit 15 does Since most parts in the media converter 1 can be used as a path of the loopback test signal, a medium having no self-diagnosis function for the LAN-side transmitting / receiving unit 11 and the MAC switch 13 as in the first embodiment described above. The converter can be easily implemented as long as it can perform a read / write test on the memory of the packet buffer 14.
[0100]
The embodiment to which the present invention is applied has been described above, but the present invention is not limited to the above-described embodiment, and various modifications are possible.
[0101]
For example, the SNMP manager 43 for executing the loopback test is executed by the SNMP unit 41 provided in the station side media converter 3, but instead, the SNMP manager 43 is connected to the LAN 123 of the station side media converter 3. The return test signal according to the SNMP may be transmitted from the LAN 123 to the subscriber side media converter via the optical fiber cable 110 via the office side media converter 3 via the office side media converter 3. Even in such a case, by using the subscriber-side media converter to which the present invention is applied, the self-diagnosis result in the subscriber-side media converter can be executed at the time of the loopback test, and the result can be received.
[0102]
In the above-described embodiment, the loopback test and the self-diagnosis control are performed using the SNMP. However, the present invention may be executed without using the SNMP according to the above-described operation procedure. In particular, the SNMP agent provided in the subscriber side media converter 1 may be incorporated in the control unit as one function of the control unit.
[0103]
When the self-diagnosis result and the read / write test result of the packet buffer are looped back to the test signal, the subscriber-side media converter 1 transmits the result to the office-side media converter 3. It may be transmitted any time after the self-diagnosis or the reading / writing test is completed.
[0104]
In addition, the self-diagnosis and the read / write test of the packet buffer are to be executed at the time of the return test request, but the result of the self-diagnosis and the read / write test executed in advance is transmitted after the return test request. Is also good. Specifically, for example, in some media converters, a self-diagnosis or a memory test is automatically performed when the power is turned on, and the result at that time is transmitted at the time of the loopback test. is there.
[0105]
Furthermore, although the return point in the subscriber-side media converter is illustrated as being set in the maintenance sublayer and the LAN-side transmitting / receiving unit, it may be set in another part. Further, as a function of the media converter itself, the 100BASE-TX standard using a metal twisted pair cable (first transmission medium) and the 100BASE-FX standard using an optical fiber cable 110 (second transmission medium) are mutually converted. However, it is needless to say that the present invention can be applied to a media converter that performs mutual conversion using a transmission medium other than these.
[0106]
【The invention's effect】
As described above, according to the present invention, at the time of the loopback test, the self-diagnosis is executed in the media converter that has received the loopback test signal, and the result is transmitted. Can be performed simultaneously with the loopback test, and the reliability of failure diagnosis in the loopback test can be improved.
[Brief description of the drawings]
FIG. 1 is a diagram showing a communication system in which a media converter according to the present invention is used as a media converter at a central office with a media converter at a subscriber side.
FIG. 2 is a drawing for explaining a turning point in the subscriber side media converter in the first embodiment.
FIG. 3 is a diagram illustrating an operation sequence of a loopback test according to the first embodiment.
FIG. 4 is a diagram showing a turning point in a subscriber side media converter according to a second embodiment.
FIG. 5 is a diagram showing an operation sequence of a loopback test in the second embodiment.
FIG. 6 is a diagram showing an operation sequence of a conventional loopback test.
[Explanation of symbols]
1. Subscriber-side media converter
3 Media converter on the office side
10. Return switch
11 LAN side transmission / reception unit in subscriber side media converter
11a Transmission unit
11b Receiver
12 Maintenance sublayer in the subscriber media converter
13 MAC switch
14 Packet buffer
15 Optical fiber transmitting / receiving unit in subscriber media converter
15a transmission unit
15b receiver
16 Electric / optical converter in media converter for subscriber
17 Optical / electrical conversion unit in subscriber media converter
18 SNMP Agent
19 Control part in subscriber side media converter
20 Power supply part in subscriber side media converter
21 Connector in subscriber side media converter
31 LAN side transmission / reception unit in office side media converter
32 Maintenance sublayer in the media converter on the office side
33 Optical Fiber Transmitter / Receiver Unit in Office Media Converter
33a transmission unit
33b receiving unit
34 Electric / optical converter in the media converter on the office side
35 Optical / electrical conversion unit in the media converter on the office side
37 Control unit in the media converter on the office side
38 Connector in Media Converter at Office
41 SNMP unit
43 SNMP Manager
110 Optical fiber cable
121, 123 LAN

Claims (4)

In a media converter for mutually converting a signal flowing through a first transmission medium and a signal flowing through a second transmission medium,
Diagnostic means for diagnosing each part in the media converter;
Diagnostic result transmitting means for transmitting a diagnostic result diagnosed by the diagnostic means to the second transmission medium when a loopback test signal is input from the second transmission medium;
A media converter comprising: 2. The media converter according to claim 1, wherein the diagnosis unit diagnoses each unit in a range where the loopback test signal does not reach. A first media converter for mutually converting a signal flowing through a first transmission medium and a signal flowing through a second transmission medium, and a first transmission medium connected by the first media converter and the second transmission medium; A communication system comprising: a signal flowing through a medium; and a second media converter that mutually converts a signal flowing through the second transmission medium.
The first media converter includes: a diagnostic unit that diagnoses each unit in the media converter; and a second diagnostic unit that, when receiving a loopback test signal from the second media converter, transmits a diagnostic result diagnosed by the diagnostic unit to the second media converter. Diagnostic result transmitting means for transmitting to the media converter,
The second media converter includes a transmitting unit that transmits a loopback test signal to the first media converter, and a diagnostic result receiving unit that receives the diagnostic result from the first media converter. Communication system. 4. The communication system according to claim 3, wherein the diagnosis unit diagnoses each unit in a range where the loopback test signal does not reach.

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