JP2002353981A - Media converter, fault detection system and fault detection method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a fault detection system and method for facilitating detection of faults of a link, including a media converter and identifying a faulty location. SOLUTION: In a link, including a plurality of media converters which connect a UTP (unshielded twisted pair cable) and an optical cable, when a test manager detects broken state of the link, test mode is started and the test manager transmits a prescribed trigger packet to a plurality of the media converters. The trigger packet starts a response test for each media converter, and each media converter returns the response packet to the test manager. The test manager discriminates whether it is to receive the response packet within a prescribed time, and identifies the fault occurrence location on the basis of the response packet.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a failure detection technique in a network, and more particularly to a failure detection system, a failure detection method, and a medium used for a link via a media converter for connecting different types of transmission media. About converter.

[0002]

2. Description of the Related Art In recent years, FTTH (Fiber To The Home), which allows an optical fiber line to be extended to homes and freely exchange music, moving images, medical data, and the like via a high-speed line, has been attracting attention. When such FTTH is realized,
A media converter for connecting an optical fiber line to a computer in an office or home is indispensable.

Generally, a media converter is provided with a physical layer device at each of a port for connecting an optical cable and a port for connecting a UTP cable, and each physical layer device is defined by the IEEE802.3 standard. MII (Media Independent Interfac
e) support.

Further, due to the nature of the media converter, those having a missing ring function for automatically disconnecting one link when one link is disconnected are generally used. For example, when an optical fiber cable is disconnected due to a failure, the media converter automatically disconnects the link on the other UTP cable side.

[0005] Utilizing such a media converter, U
When the TP cable is connected to the optical cable, it is necessary to test whether the cable is normally connected to the other party. The conventional media converter is provided with a link test changeover switch, and the link test function can be used to check whether or not a link can be established by lighting an LED or the like for each port.

On the other hand, various link test techniques for networks have been proposed. For example, JP-A-8-3
In the link test method disclosed in Japanese Patent No. 31126,
The special control code is transmitted to the link destination switch, and the switch receiving the control code returns a response message. The source switch can determine whether the network link is functioning normally by analyzing the response message or detecting the presence or absence of a response.

However, this conventional link test technique is based on a network switch (exchange), and is basically different from a media converter having a missing link function mainly for conversion of a transmission medium in terms of configuration and functions. Are different.

[0008]

As described above, in the media converter, the test mode is set by operating the link test switch. For this reason, the link test cannot be started from the cable side (UTP cable side or optical cable side), and there has been a problem that the link test cannot be executed quickly and easily. In other words, such a media converter
Due to its nature, it is not designed to be controlled from the network side.

Further, when the missing link function of the media converter is activated, the host computer cannot monitor the status of the media converter at all even if the media converter is normal. For this reason, if the link via the media converter fails, whether the link to the media converter has failed on the host side, the media converter itself has failed, or the link beyond the media converter has failed Can not be specified.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a failure detection method and system which can easily detect a failure in a link including a media converter and can specify a failure position.

[0011]

According to the present invention, there is provided a fault detecting method comprising: a) sending a special data block having a block length different from a predetermined standard to each of the plurality of media converters; A) determining whether or not a response data block to the special data block is received within a predetermined time from the media converter; and c) specifying a failure location based on a result of the determination step. It is characterized by the following.

Further, a failure detection method according to another aspect of the present invention includes: a) trigger data having an address of the media converter as a destination address and an address of a specific management device as a source address for an arbitrary media converter; Sending a block; b) determining whether or not a response data block to the trigger data block is received within a predetermined time from the media converter; and c) a fault location based on a result of the determination step. And a step of specifying

For example, when a special data block having a block length outside the IEEE 802.3 standard is used, only a media converter having a function of detecting the non-standard packet can receive the packet, and other ordinary network devices automatically receive the packet. Destroyed. Therefore, the response test of the plurality of media converters can be efficiently executed without complicating the control.

When a trigger data block in which an address of a target media converter is written in a destination address and an address of a specific management device is written in a source address is used, a target media converter of an arbitrary form can be used in a network. A response test can be performed. In addition, by appropriately switching the nodes in the middle according to the destination address, the trigger data block does not flow to another port, the network can be used efficiently, and traffic can be reduced.

[0015]

DESCRIPTION OF THE PREFERRED EMBODIMENTS (Media Converter) FIG. 1 is a block diagram showing an example of a media converter used in an embodiment of a fault detection system according to the present invention. Here, in order to simplify the explanation, the media converter 10 is connected to the host computer or the management switch 20 through a 100BASE-TX: UTP cable.
And a system connected to the other host computer or the management switch 30 via an optical cable.

A pair of ports of the media converter 10 have physical layer devices (PHY) 101 and 10 respectively.
2, one physical layer device 101 is connected to a UTP cable, and the other physical layer device 102 is connected to an optical cable. As described above, each of the physical layer devices 101 and 102 is an IEEE 80
MII (Media Independent) defined by 2.3
Interface).

Physical layer device 101 and physical layer device 1
In addition, a FIFO (First in First out) memory 103 is provided between the transmission and reception devices 02 and 02 so that a frequency deviation between transmission and reception can be absorbed. Data received by one physical layer device is sequentially written to the FIFO memory 103, read out in the written order, and sent to the other physical layer device.

Further, in the FIFO memory 103, a PLD (Programmable Logic) in which a predetermined logic function is written.
Device 104 is connected. The PLD 104 is designed to identify a predetermined packet as a test mode start packet (trigger packet). Here, the length of the received packet is not specified or the MAC address of the destination indicates its own address, and the enable signal E _LB is transmitted to the microprocessor only when it is determined that the packet is a trigger packet. Output to 105. Details will be described later.

The microprocessor 105 includes a PLD 10
When the enable signal _ELB is received from the control unit 4, the control unit 10 controls the physical layer device to generate a predetermined response packet and return it to the transmission source of the received packet.

Further, the microprocessor 105 includes an I
In accordance with the physical layer MII of the EEE802.3 standard, the farEF (far En
Various internal registers such as d Fault) register and Force Link register can be accessed. Thereby, for example, link information indicating whether link establishment is possible or half-duplex / full-duplex can be acquired from the physical layer device. Also, by accessing the forced link register, it is possible to forcibly set the physical layer device in the link disconnected state to the transmission enabled state.

The management switch 20 also has I
Physical layer device (PHY) 201 supporting EEE802.3 standard MII, MAC (Media Access Control)
Layer device 202 and a microprocessor (CP
U) 203 is provided. The physical layer device 20
1 is connected to the physical layer device 101 of the media converter through a UTP cable. The microprocessor 203 complies with the IEEE 802.3 standard MII.
Various internal registers provided in the physical layer device 201 can be accessed. This allows U
It is possible to acquire link information indicating whether or not a link can be established by a TP cable, and to forcefully set the physical layer device 201 in a link disconnected state to a transmission enabled state by accessing a forced link register.

The management switch 30 has the same configuration as that of the management switch 20, and its physical layer device is connected to the physical layer device 102 of the media converter through an optical cable, and also supports the MII defined by IEEE802.3.

When a normal Ethernet (registered trademark) packet is transmitted / received, the media converter only performs a normal media conversion operation. That is, the ordinary Ethernet packet transmitted from the management switch 20 is converted into optical data by the media converter 10 and transmitted to the destination host computer or the management switch 30 via the optical cable. vice versa,
The normal optical data transmitted from the management switch 30 is converted into a normal Ethernet packet by the media converter 10 and received by the management switch 20 through the UTP cable.

When the response test is started, the management switch 20 generates a predetermined packet (hereinafter, referred to as a trigger packet _PTRG ) and sends it to the media converter 10.

(Trigger Packet) FIGS. 2A and 2B are format diagrams showing two examples of the trigger packet.

As shown in FIG. 2A, a packet that is not defined by the network standard IEEE802.3 can be used as a trigger packet. Here, the packet length is set outside the standard. That is, IEEE802.3
According to the standard, the packet length is defined as a minimum of 60 bytes and a maximum of 1514 bytes. By setting the packet length to less than 60 bytes or more than 1515 bytes, a packet having a special instruction (here, a test mode start-up Trigger packet).

This trigger packet is IEEE802.3.
Due to having a non-standard packet length, only network devices (here, media converters) having a function of detecting this non-standard packet can receive,
Other normal devices discard them. Therefore, even if a trigger packet is sent to a network consisting of links via a plurality of media converters, only the media converter in the middle shifts to the test mode in response to the trigger packet and returns a response packet as described later. Can be. Even if the host computer receives the trigger packet, it automatically discards the trigger packet because it is out of the standard.

As shown in FIG. 2B, a normal Ethernet packet can be used. In this example, the trigger packet is, like a normal Ethernet packet, an 8 byte preamble, a 6 byte destination address field, a 6 byte source address field, a 48 to 1502 byte data field, and a 4 byte FCS field. Consists of However, in the case of a trigger packet, the MAC address of the target media converter is written in the destination address, and the address of the network management device is written in the source address.

In the case of this example, as described later, each media converter in the network is provided with IEEE802.3.
MAC addresses conforming to the standard are individually assigned.
By using normal Ethernet packets, it is possible to execute a response test of the target media converter in an arbitrary form of network.

(Media Converter with Test Manager) FIG. 3 is a block diagram showing an embodiment of a media converter with a test manager according to the present invention. The media converter 300 with a test manager includes a media converter 301 and a test manager 302 connected to the microprocessor 105 of the media converter 301 via a unique bus 303. Since the media converter 301 has almost the same configuration as the media converter 10 shown in FIG. 1, the same reference numerals are given to the respective circuit blocks and the description is omitted.

The test manager 302 controls the microprocessor 105 of the media converter 301 via the bus 303.
Has a microprocessor 304 and a network interface card (NIC) 305. The network interface card 305 is connected to a network management rule (not shown) through a UTP cable.

As will be described later, the test manager 302
Monitors a link disconnection, issues a test start instruction, sorts and determines collected information, and the like. The media converter 301 basically operates in the same manner as the above-described media converter 10, except that control signals and data are exchanged with the microprocessor 304 of the test manager 302 via the unique bus 303.

Hereinafter, a test operation of the system using the media converter 300 with the test manager will be described in detail.

(Test Sequence) FIG. 4 is a block diagram showing a schematic configuration of a network system for explaining an embodiment of a fault detection method according to the present invention. Here, for simplicity of explanation, the media converter 300 with a test manager is connected to the management switch 2.
0 through the UTP cable UTP1, the other media converter 40 through the optical fiber cable FO, and the media converter 40 connected to the UTP cable UTP2.

Here, the UTP cable UTP2
Assume that a failure has occurred. In this case, in the media converter 40 and the media converter 301 of the media converter 300 with the test manager, the missing link function operates, and all the links are disconnected.

FIG. 5 is a sequence diagram showing a test operation according to the present embodiment. The test manager 302 monitors the link function through the media converter 301, and when a link disconnection is detected (step S501).
The link disconnection is notified to the network management tool (step S502). Upon receiving the link disconnection notification, the network management tool instructs the test manager 302 to start a test (Step S503).

Upon receiving the test start instruction, the test manager 302 activates the test mode (step S50).
4) The media converter 301 is shifted to the test mode (step S505). As a result, the media converter 301 releases the missing link function (step S506), and sets the physical layer device 102 to a forced transmission enabled state (ForceLink Enable) (step S506).
507), a trigger packet addressed to the media converter 40 is transmitted to the media converter 40. After the trigger packet is transmitted, the forcible transmission enabled state is released (ForceLink Disa
ble) (step S508), and returns to the normal mode after notifying the link information to the test manager 302 (step S509), and waits for reception of a response packet corresponding to the trigger packet.

On the other hand, a predetermined trigger packet (FIG. 2A)
The media converter 40 that has received the trigger packet addressed to itself (see FIG. 2B) shifts to the test mode (step S510), releases the missing link function (step S511), and transmits the response packet to the media converter. Return to 301. Thereafter, the process returns to the normal mode (step S512). Media converter 40
Media converter 3 receives a response packet from
01 reads out the link information and notifies the test manager 302 of it.

The test manager 302 sorts out the link information received from the media converters 301 and 40 and determines the location of the failure (step S51).
3) Notify the network management tool of the test result.

FIG. 6 is a flowchart showing a test operation of the media converter 301 in this embodiment.

When the test mode is started by the test manager 302 (YES in step S601), the microprocessor 105 of the media converter 301 releases the missing link function (step S602), and the physical layer device 102 can be forcibly transmitted. Status (ForceLink
Enable) (step S603). Then, after transmitting the trigger packet addressed to the adjacent media converter 40 (step S604), the forcible transmission enabled state is canceled (ForceLink Disable) (step S60).
5). Subsequently, the microprocessor 105 acquires link information of each physical layer device (step S606), and notifies the test manager 302 via the unique bus 303 (step S607).

Thereafter, the microprocessor 105 returns to the normal mode (step S608), and waits for reception of a packet which is a response to the transmitted trigger packet (step S608).
609). Upon receiving the response packet (step S60)
9), the microprocessor 105 reads out the written link information and transmits it to the test manager 30.
2 is notified (step S610). When a packet other than the response packet is received (N in step S609)
O), transfer as it is (step S611).

If the test mode is not activated (NO in step S601), the microprocessor 105 determines whether a trigger packet has been received (step S601).
612), if no trigger packet has been received (NO in step S612), the control proceeds to step S608. Specifically, the physical layer device 101 or 102
, The PLD 104 determines whether the data written in the FIFO memory 103 at a predetermined timing is a predetermined trigger packet (see FIG. 2).

A predetermined trigger packet (see FIG. 2A)
Alternatively, when a trigger packet addressed to itself (see FIG. 2B) is received (YES in step S612), the microprocessor 105 of the media converter 301 cancels the missing link function (step S613), and the physical layer device Acquire link information (step S61)
4). As described above, the microprocessor 105 generates a response packet in which the acquired link information is written at a predetermined position, and transmits the response packet to the transmission source of the trigger packet (Step S615). After transmitting the response packet, step S60
The control is shifted to 8.

FIG. 7 is a flowchart showing a test operation of the test manager 302 in this embodiment.

The microprocessor 304 of the test manager 302 monitors the link status through the microprocessor 105 of the media converter 301 (step S702) unless there is a test instruction from the network management tool (NO in step S701), and determines whether the link is disconnected. Is determined (step S703). If the link is normal (NO in step S703), steps S701 and S702 are repeated.

When the link disconnection is detected (step S7)
03 (YES), a link disconnection is notified to the network management tool (step S704), and a test start instruction from the network management tool is waited. When a test start instruction is received from the network management tool (step S701)
YES), the microprocessor 304 activates the test mode of the media converter 301 (step S70).
5) The media converter (here, MC301 and MC40) until the timer of the predetermined time has timed out.
Wait for the notification from (steps S706 to S708).

When there is a notification from the media converter (YES in step S706), the information is organized (step S707), and a determination is made based on the information acquired after a predetermined time has elapsed (step S709). For example, when information is obtained from the media converter 301 but is not obtained from the media converter 40 within a predetermined time, it is determined that a failure has occurred in the media converter 40 or the optical fiber cable therebetween. be able to. Alternatively, even when both the media converter 301 and the media converter 40 notify within a predetermined time, the presence or absence of a failure can be determined based on the link information from the media converter 40 (see FIG. 4). The determination result is notified to the network management tool (step S710).

As described above, in a network including a plurality of media converters, a trigger packet can be sequentially transmitted to a plurality of media converters, and a failure can be detected based on the response packets. Also,
It is not necessary to provide a special function in the management switch 20, and the media converter 300 with the test manager
The failure detection described above can be performed simply by using
The system configuration is simplified.

FIG. 8 is a flowchart showing a test operation of the media converter 40. The microprocessor 403 determines whether or not a trigger packet has been received (step S801), and a predetermined trigger packet (FIG. 2A)
When a trigger packet addressed to itself (see FIG. 2B) is received (YES in step S801), the microprocessor 403 releases the missing link function (step S802), and links information of each physical layer device. Is acquired (step S803). As mentioned above,
The microprocessor 403 generates a response packet in which the acquired link information is written at a predetermined position, transmits the response packet to the source of the trigger packet (step S804), and shifts to the normal mode (step S805). When the trigger packet is not received (NO in step S801), the mode shifts to the normal mode.

When a packet whose packet length is out of the standard shown in FIG. 2A is used as a trigger packet, the received trigger packet is transferred downstream in the normal mode (step S805) as described later. I do. Thus, even when a plurality of media converters are connected, a response test can be performed one after another by sequentially transferring the trigger packets. On the other hand, when the trigger packet shown in FIG. 2B is used, it is not transferred downstream because it is a trigger packet addressed to itself.

FIG. 9 is a block diagram showing another embodiment of a media converter with a test manager according to the present invention. The test manager with media converter 300 of this embodiment includes a port P ₀ to be connected to the network management roots, N pieces of media converters MC ₁ ~
N pairs of ports P _i1 and P corresponding to each of the MC _N
i2 (i = 1, 2, 3,..., N). The network manager 302 manages the _N media converters MC _{1 to} MC _N as described above.

(Fault Detection System) A case where a packet whose packet length is less than 60 bytes or 1515 bytes or more, as shown in FIG. 2A, will be described as a trigger packet.

FIG. 10 is a network configuration diagram for explaining an example of a response test operation using the trigger packet shown in FIG. Here, the hosts 20 and 30
Are connected by a link via a plurality of media converters 10, and each media converter 10 is provided with a function of detecting a trigger packet _PTRG having a data length shorter or longer than the standard as shown in FIG. I have.

The test mode is started in the host 20.
And, as described above, the trigger packet P_TRGGenerate and send
Put out. Trigger packet P_TRGIs Media Converter 1
0, it is transferred one after another and reaches host 30 and breaks
Discarded. Trigger packet P_TRGEach media that received
The converter 10 activates the test mode and has already described
A response packet is returned to the host 20 as described above. for example
For example, Media Converter MC ₁Is the trigger packet P_TRGTo
Response packet P when received_PRL1And then the media
Aconverter MC_TwoIs the trigger packet P_TRGWhen you receive
Response packet P_PRL2Will be returned. The same applies hereinafter.

The response packet P thus returned
_By examining _PRL1 , _PRL2, ..., The host 20 can monitor the status of the link and the media converter, and when a failure occurs, can identify the location of the failure.

Next, the case where the trigger packet shown in FIG. 2B is used will be described. The MAC address of the target media converter is written in the destination address of the trigger packet, and the address of the network management device is written in the source address.

FIG. 11 is a network configuration diagram for explaining an example of a response test operation using the trigger packet shown in FIG. 2B. A plurality of nodes N ₁ , N ₂ ,... Are radially connected, and the nodes are connected by links via a plurality of media converters MC as necessary. MAC addresses conforming to the IEEE 802.3 standard are individually assigned to all media converters MC in the network.

The network management device 901 is connected to the node N ₁
And a response test targeting a desired media converter can be executed using the trigger packet shown in FIG. 2 (B). For example, when performing the response test of the media converter 902 connected to the node N ₁₁ is the media converter 90 to the destination address
A trigger packet _{PTRG in} which the MAC address of the network management device 901 is written in the source address and the MAC address of the network management device 901 is generated and transmitted to the network.

Each node (here, N ₁ and N ₄ ) receiving the trigger packet _{PTRG transfers the} packet to an output port according to its destination address, and reaches the target media converter 902. Since the trigger packet flows only through the necessary route and does not flow through the entire network, useless data flows are eliminated, and the network can be used efficiently.

The media converter 902 that has received the trigger packet _PTRG activates the test mode and, as described above, sends the response packet _PPRL to the network management device 9.
Return to 01.

The response packet P thus returned
By examining the _PRL , the network management device 901
Can monitor not only the state of the media converter 902 but also the state of the link leading to it. In this way, a plurality of media converters can be tested sequentially, and thereby the location of a fault in the event of a fault can be identified.

When the connection information of the media converter on the network is stored in the network management device 901, a response test can be executed for each of the plurality of connected media converters. For example, when there is connection information MC905-MC904-MC903 as the route information to the media converter 902, these media converters 905, 90
By transmitting the trigger packets having the respective destinations also to 4 and 903, it is possible to sequentially perform a response test on them, and thereby it is possible to specify the position of a failure when a failure occurs. .

[0064]

As described above in detail, according to the fault detection system and method according to the present invention, a trigger packet is sequentially transmitted to a plurality of media converters, and fault detection is performed based on those response packets. it can. In particular, when a response packet is not received from a certain media converter within a predetermined time, it can be determined that a failure has occurred beyond the media converter. Therefore, it is easy to detect a failure in a link including a media converter, and it is also possible to identify a failure position to some extent.

As a trigger packet, IEEE802.
When a packet having a packet length outside the standard 3 is used, only a media converter having a function of detecting the packet outside the standard can receive the packet, and other ordinary network devices automatically discard the packet. Therefore, the response test of the plurality of media converters can be efficiently executed without complicating the control.

Further, if a trigger packet in which the MAC address of the target media converter is written in the destination address and the address of a specific management device is written in the source address is used, the target media converter of the target media converter can be used in an arbitrary network. A response test can be performed. In addition, by appropriately switching the nodes in the middle according to the destination MAC address, the trigger packet does not flow out to another port, the network can be used efficiently, and traffic can be reduced.

In each media converter, a test mode is activated by receiving a predetermined trigger packet or a trigger packet including its own identification data, and returns a response packet. Therefore, the test can be started from the cable side, and by receiving the response packet, it can be confirmed that not only the link to the media converter but also the media converter itself is operating normally.

Further, when each of the media converters receives a trigger packet other than the trigger packet addressed to itself in the missing link state, the media converter shifts to the normal mode and transfers the received packet. As a result, a packet that is not subjected to a response test through the media converter passes, and a link test beyond that can be performed.

The media converter with a test manager according to the present invention can execute a failure detection test by activating a test mode when a link disconnection is detected, transmitting a trigger packet, and receiving a response packet in response to the trigger packet. it can. Since it is not necessary to provide a special function for the management switch, the system configuration can be simplified.

[Brief description of the drawings]

FIG. 1 is a block diagram showing one embodiment of a media converter according to the present invention.

FIG. 2 is a format diagram showing an example of a trigger packet.

FIG. 3 is a block diagram showing one embodiment of a media converter with a test manager according to the present invention.

FIG. 4 is a block diagram showing a schematic configuration of a network system for explaining an embodiment of a failure detection method according to the present invention.

FIG. 5 is a sequence diagram illustrating a response test operation according to the embodiment.

FIG. 6 is a flowchart showing test control in a media converter with a test manager.

FIG. 7 is a flowchart showing test control of a test manager.

FIG. 8 is a flowchart showing test control in the media converter.

FIG. 9 is a block diagram showing another embodiment of a media converter with a test manager according to the present invention.

FIG. 10 is a network configuration diagram for explaining an example of a response test operation using the trigger packet shown in FIG.

FIG. 11 is a network configuration diagram for explaining an example of a response test operation using the trigger packet shown in FIG. 2 (B).

[Explanation of symbols]

 10 Media Converter 20 Management Switch 30 Management Switch 40 Media Converter 101 Physical Layer Device 102 Physical Layer Device 103 FIFO Memory 104 PLD Device 105 Microprocessor 300 Media Converter with Test Manager 301 Media Converter 302 Test Manager 303 Own Bus 304 Microprocessor 305 Network Interface Card 401 Physical layer device 402 Physical layer device 403 Microprocessor

 ──────────────────────────────────────────────────続 き Continued on the front page F-term (reference) CC03 EE02 EE07 FF01 GG02 JJ02 JJ03

Claims (20)

[Claims] 1. A method of detecting a link failure via a plurality of media converters connecting different types of transmission media, comprising: a) setting a block length different from a predetermined standard for each of the plurality of media converters; Sending out the special data block having the same; b) determining whether a response data block corresponding to the special data block is received from the media converter within a predetermined time; and c) based on a result of the determining step. A failure detection method, comprising: identifying a failure occurrence location. 2. In the step (c), when a response data block to the special data block is not received from the media converter within a predetermined time, it is determined that a failure has occurred beyond the media converter. The fault detection method according to claim 1, wherein 3. Each of the media converters comprises: first physical layer interface means for connecting a first transmission medium; second physical layer interface means for connecting a second transmission medium; Memory means connected between the second physical layer interface means for temporarily storing data transferred between them, wherein the received data block stored in the memory means is an ordinary data block. Determining whether the received data block is the special data block, generating a response data block corresponding to the received data block, and receiving the received data block. Means for returning the response data block to the source of the received data block. Fault detection method of claim 1, wherein that. 4. The fault detecting method according to claim 3, wherein said first and second physical layer interface means respectively support MII (Media Independent Interface) defined by IEEE802.3 standard. 5. When each of the media converters determines that the received data block is the special data block, each of the media converters accesses each of the first and second physical layer interface means to access each of the physical layer interface means. 5. The failure detection method according to claim 4, wherein the link information is obtained, and the response data block is generated according to the link information. 6. Each of the media converters may be a MII (Me) defined by the IEEE 802.3 standard.
dia Independent Interface) and a first physical layer interface means for connecting a first transmission medium, and MII defined by the IEEE 802.3 standard
And a second physical layer interface means for connecting a second transmission medium, and is connected between the first and second physical layer interface means and temporarily stores data transferred between them. And determining whether the received data block stored in the memory means is the special data block, and determining that the received data block is the special data block. Generating a response data block for the received data block, releasing the missing link state in which when one of the physical layer interface units is in the link disconnected state, the other physical layer interface unit is also in the link disconnected state; 2. The fault according to claim 1, wherein the block is returned to a source of the received data block. Way out. 7. Each of the media converters further releases the missing link state when the determination unit determines that the received data block is the special data block in the missing link state. The fault detection method according to claim 6, wherein 8. A fault detection system comprising: a link via a plurality of media converters connecting different types of transmission media; and a test manager connected to an arbitrary media converter of the plurality of media converters. Each of the media converters comprises: first physical layer interface means for connecting a first transmission medium; second physical layer interface means for connecting a second transmission medium; and the first and second physical layer interfaces. Memory means connected between the means for temporarily storing data transferred between them; special data having a block length different from a predetermined standard, wherein the received data block stored in the memory means has a different block length. It is determined whether the received data block is a special data block. Media converter control means for generating a response data block corresponding to the received data block, and returning the response data block from the physical layer interface means having received the received data block to the transmission source of the received data block. The test manager sends the special data block to the link to the media converter to which the test manager is connected, and determines whether a response data block to the data block is received from each media converter within a predetermined time. And a test manager control means for making a determination and identifying a location where a failure has occurred based on the result of the determination. 9. The test manager control means, when a response data block corresponding to the data block is not received from a media converter within a predetermined time, determines that a failure has occurred beyond the media converter. The fault detection system according to claim 8, wherein: 10. A method for detecting a failure in a network including a plurality of media converters for connecting different types of transmission media, comprising the steps of: (a) for a given media converter, using the address of the media converter as a destination address and a specific management device; Sending a trigger data block having the source address as a source address; b) determining whether or not a response data block corresponding to the trigger data block is received from the media converter within a predetermined time; A step of specifying a failure occurrence location based on a result of the determination step. 11. In the step (c), when a response data block to the trigger data block is not received from the media converter within a predetermined time,
11. The failure detection method according to claim 10, wherein it is determined that a failure has occurred beyond the media converter. 12. Each of the media converters comprises: first physical layer interface means for connecting a first transmission medium; second physical layer interface means for connecting a second transmission medium; Memory means connected between the second physical layer interface means for temporarily storing data transferred between them, wherein the received data block stored in the memory means is an ordinary data block. Determining whether the received data block is the trigger data block, generating a response data block corresponding to the received data block, and receiving the received data block. Returning the response data block from the means to the source of the received data block; Fault detection method according to claim 10 wherein features. 13. The failure detection method according to claim 12, wherein said first and second physical layer interface means respectively support MII (Media Independent Interface) defined by IEEE802.3 standard. 14. When each of the media converters determines that the received data block is the trigger data block, each of the media converters accesses each of the first and second physical layer interface units to access each of the physical layer interface units. The failure detection method according to claim 13, wherein the link information is obtained, and the response data block is generated according to the link information. 15. Each of the media converters is provided with a MII (Me
first physical layer interface means for supporting a first transmission medium, and MII defined by the IEEE 802.3 standard.
And a second physical layer interface means for connecting a second transmission medium, and is connected between the first and second physical layer interface means and temporarily stores data transferred between them. And a memory unit for determining whether the received data block stored in the memory unit is the trigger data block, and it is determined that the received data block is the trigger data block. Generating a response data block for the received data block, releasing the missing link state in which when one of the physical layer interface means is in the link disconnected state, the other physical layer interface means is also in the link disconnected state; The block is returned to the transmission source of the received data block. Fault detection method. 16. When each of the media converters further determines that the received data block is not the trigger data block in the missing link state by the determination unit, the media converter cancels the missing link state,
The failure detection method according to claim 15, wherein the received data block is transferred. 17. A failure detection system for a network including a plurality of media converters for connecting different types of transmission media and a management device, wherein each of the media converters includes a first physical connection for connecting a first transmission medium. Layer interface means, second physical layer interface means for connecting a second transmission medium, and data connected between the first and second physical layer interface means for temporarily transferring data transferred therebetween. A memory unit for storing, and whether or not the received data block stored in the memory unit is a trigger data block having an address of an arbitrary media converter as a destination address and an address of the management device as a source address. And if the received data block is determined to be the trigger data block, Media converter control means for generating a response data block for the received data block, and returning the response data block from the physical layer interface means having received the received data block to the transmission source of the received data block; A failure detection system, wherein the device determines whether or not a response data block to the trigger data block is received from the media converter within a predetermined time, and identifies a failure location based on the determination result. 18. The management device has media converter connection information in the network, and has the respective addresses as destinations for each media converter connected on the path from the management device to the media converter. The failure detection system according to claim 17, wherein the trigger data block is transmitted and a response test is performed. 19. A media converter for connecting different types of transmission media, comprising: first physical layer interface means for connecting a first transmission medium; and second physical layer interface means for connecting a second transmission medium. A memory means connected between the first and second physical layer interface means for temporarily storing data transferred between them, and a reception data block stored in the memory means is It is determined whether or not the received data block is a special data block having a block length different from the standard. If the received data block is determined to be a special data block, a response data block for the received data block is generated. The response data block is transferred from the physical layer interface unit that has received the data block to the received data block. Tsu media converter, characterized in that it comprises a control means for returning click to source, the. 20. A media converter for connecting different types of transmission media, comprising: first physical layer interface means for connecting a first transmission medium; and second physical layer interface means for connecting a second transmission medium. A memory means connected between the first and second physical layer interface means for temporarily storing data to be transferred therebetween, and a reception data block stored in the memory means is optional. It is determined whether the received data block is the trigger data block is determined whether the address of the media converter is the destination address and the address of the specific management device as the source address and the trigger data block. Generate a response data block for the received data block and receive the received data block. Media converter and having a media converter control means for returning from the physical layer interface means the response data block to the transmission source of the received data block.