JP2008252208A - Communication network system, communication trouble detecting method, and node device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To specify a node device to which communication trouble occurs by speedily detecting the communication trouble occurring in a VLAN. <P>SOLUTION: It is decided whether a node device connected to a ring-shaped or linear transmission line receives a frame for diagnosis at predetermined time intervals (step S12), and a frame for adjacent communication having incorporated data representing "normal" when the frame for diagnosis is received or incorporated data representing "communication trouble" when not is sent out to adjacent upstream and downstream node devices (steps S13, S14). Further, when no frame for diagnosis is received and the frame for adjacent communication from the upstream-side adjacent node device includes data representing "normal", a frame for state notification including information showing that there is trouble between the node device itself and the upstream-side adjacent node device is sent out by multicasting to other node devices (step S17). <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a communication network system suitable for a VLAN (Virtual Local Area Network), a communication failure detection method, and a node device.

  There is a VLAN as a technique for constructing a plurality of LANs (Local Area Networks) on the physically same communication network. When constructing the VLAN, a node device called a LAN switch (switching hub or the like) is often used. A LAN switch is a MAC address (Media Access Control Address) or IP address (Internet Protocol Address) of a terminal (such as a personal computer) connected to the LAN switch. The transmission path of the communication frame is controlled based on information set according to (communication).

  In the case of using a LAN switch, the VLAN is realized by setting a VLAN group for each port of the LAN switch, for example. In such a LAN, even if the VLAN group to which the terminal connected to the port of the LAN switch belongs is changed, it is not necessary to change the physical connection form in the communication network and the LAN switch, and the VLAN for the port in the LAN switch. You can respond to the change by simply changing the group settings. That is, it is possible to easily set or change the VLAN group of the terminal in the communication network. Therefore, in a communication network of a business office such as a company, for example, VLANs grouped by department can be easily constructed without considering the arrangement state of communication cables.

Conventionally, for example, Patent Document 1 discloses an example of a technique for detecting a VLAN setting error in a switching hub in the VLAN using the switching hub as described above. Patent Document 2 discloses an example of a switching hub capable of setting a VLAN even when domain names are different.
JP 2000-165430 A JP 2003-318937 A

  By the way, when a VLAN is configured using the switching hub disclosed in the prior art, a plurality of VLAN groups are usually set in one switching hub. In such a case, when a failure that depends on communication of a specific VLAN group occurs in the switching hub, the failure is not revealed unless new communication is performed in that VLAN group. In the meantime, when communication in other VLAN groups is performed correctly, the network as a whole seems to operate normally. That is, these conventional techniques have a problem that when a failure that depends on communication of a specific VLAN group occurs, detection of the failure is delayed.

  In view of the above problems of the prior art, an object of the present invention is to quickly detect a communication failure that has occurred in a specific VLAN group in a communication network system in which a VLAN group is set, and the node in which the failure has occurred It is an object of the present invention to provide a communication network system, a communication failure detection method, and a node device that can specify a device.

  The present invention is a communication network system configured by connecting a plurality of node devices to a ring-shaped or linear trunk transmission line, and (1) a first node connected to one end of the trunk transmission line The apparatus comprises means for transmitting a diagnostic frame at predetermined time intervals toward a node apparatus connected to the other end opposite to the one end of the trunk transmission line, and (2) the transmitted diagnosis A second node device, which is a node device connected to the trunk transmission line on the downstream side of the first node device along the direction in which the transmission frame is transmitted, (2-1) the predetermined time interval; First determination means for determining whether or not the diagnostic frame is received every second time interval that is equal to or longer than the predetermined time interval; and (2-2) the first determination means. The diagnostic frame To the upstream node device adjacent to the upstream side and the downstream node device adjacent to the downstream side along the trunk transmission line, information indicating that “communication is normal” Is transmitted to the upstream node device and the downstream node device when it is determined that the diagnostic frame has not been received. Means for transmitting the included inter-adjacent communication frame; and (2-3) receiving the inter-adjacent communication frame transmitted from the upstream node device, and receiving the information included in the received inter-adjacent communication frame. (2-4) The first determination means determines that the diagnostic frame has not been received, and (2-4) the second determination means determines that the diagnostic frame has not been received. When it is determined that the information indicating that “communication is normal” is included in the inter-communication frame, the other communication device is directed to other node devices included in the communication network system. And a means for transmitting a status notification frame including information indicating that there is a failure in communication between them.

  In a communication network system in which a VLAN group is set, it is possible to quickly detect a communication failure that has occurred in a specific VLAN and to identify a node device in which the failure has occurred.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

  FIG. 1 is a diagram showing an example of the configuration of a communication network system according to an embodiment of the present invention. In FIG. 1, a communication network system 1 is configured by connecting a plurality of node devices 2 (2a to 2d) to ring-type bidirectional transmission paths 4a and 4b, and each node device 2 further includes: One or more computers 3 such as personal computers are connected as terminals. At this time, it is assumed that one or more VLANs are set in the communication network system 1 and each computer 3 belongs to one of the groups. Although four node devices 2 are connected to the communication network system 1 in FIG. 1, the number of node devices 2 included in the communication network system 1 is not limited to “4”.

  Communication such as TCP (Transmission Control Protocol) / UDP (User Datagram Protocol) is performed between each node device 2 and each computer 3 of such a communication network system 1. In FIG. 1, the transmission lines 4a and 4b are configured in a ring type. In this case, in order to prevent a communication frame from being transmitted a plurality of times through the transmission lines 4a and 4b, A blocking BL is provided between the node device 2a and the node device 2d.

  That is, even if the transmission lines 4a and 4b in the part where the blocking BL is provided are physically connected, they block the passage of communication frames transmitted and received between users, that is, the computers 3. Actually, the transmission paths 4a and 4b do not pass the communication frame, but the communication frames received by the node devices 2a and 2d adjacent to the blocking BL are sent to the transmission paths 4a and 4b provided with the blocking BL. Blocking is realized by not (terminating). Note that the node devices 2a and 2d adjacent to the blocking BL are called terminal stations, and the node devices 2b and 2c that are not terminal stations are called intermediate stations.

  In the present embodiment, apart from normal communication performed by the user of the computer 3 (hereinafter referred to as user communication), as a communication frame for detecting a VLAN communication failure, every predetermined time interval between the node devices 2. A VLAN diagnostic frame and an inter-adjacent communication frame transmitted and received are prepared. Although details of functions and configurations of these communication frames will be described later, here, first, a range in which these communication frames are transmitted by the node device 2 will be described with reference to FIG.

  FIG. 2 is a diagram illustrating a range in which communication frames are transmitted in the communication network system 1. As shown in FIG. 2, the VLAN diagnosis frame is sent from the A terminal station (node device 2a) and the B terminal station (node device 2d) in opposite directions (direction A and direction B in FIG. 1). It is relayed by the intermediate stations (node devices 2b and 2c) and transmitted to the B terminal station (node device 2d) and the A terminal station (node device 2a), respectively. That is, the B terminal station and the A terminal station (node devices 2d and 2a) that have received the VLAN diagnosis frame terminate the received VLAN diagnosis frame there.

  On the other hand, the inter-adjacent communication frames are communication frames that the node devices 2a to 2d transmit only to the adjacent node devices 2a to 2d, respectively. That is, the node devices 2a to 2d only transmit the inter-adjacent communication frames to the adjacent node devices 2a to 2d, or receive the inter-adjacent communication frames transmitted from the adjacent node devices 2a to 2d. The received inter-adjacent communication frame is not sent to the further transmission lines 4a and 4b (see FIG. 1). Note that the inter-adjacent communication frame is adjacent to the transmission paths 4a and 4b between the A terminal station (node device 2a) and the B terminal station (node device 2d) where blocking BL is provided. Inter-frame communication frames are transmitted and received.

  Similarly to the VLAN diagnosis frame, the user communication frame used for communication between the computers 3 is terminated at the A terminal station and the B terminal station (node devices 2a and 2d). That is, neither the VLAN diagnostic frame nor the user communication frame goes around the transmission paths 4a and 4b.

  FIG. 3 is a diagram illustrating an example of a block configuration of the node device 2 used in the communication network system 1. As shown in FIG. 3, the node device 2 includes ports A and B and ports C to F as external interfaces. Here, the ports A and B are connected to a transmission path (hereinafter referred to as a trunk line) between the node devices 2, and the ports C to F are transmission paths (a transmission path between the node device 2 and the computer 3 ( Hereinafter referred to as a branch line). Here, although the number of ports C to F on the branch line side is “4”, it is not limited to “4”.

  The node device 2 controls the communication line transmitted / received via the branch line side ports C to F and the trunk line port control unit 26 that controls the communication frame transmitted / received via the ports A and B on the trunk line side. And a branch port control unit 25. Further, the node device 2 includes a VLAN individual buffer 21, a VLAN individual frame control unit 22, a VLAN diagnosis buffer 23, and a VLAN diagnosis frame control unit 24 for detecting a failure of the VLAN, and a control for controlling them. MPU (Micro Processing Unit) 27 is provided.

  Here, in the trunk port control unit 26, the ports A and B on the trunk line side are set so as to belong to all VLAN groups, and unless there are special settings such as blocking BL, all types of communication frames are transmitted and received. be able to. In addition, VLAN groups are set for the ports 261 to 264 connected from the trunk port control unit 26 to the branch port control unit 25, respectively. When the trunk port control unit 26 receives a communication frame from the ports A and B on the trunk line side, it identifies the VLAN group based on the tag added to the communication frame, and the same VLAN group as the identified VLAN group is set. The received communication frame is relayed to the received ports 261 to 264. The trunk port control unit 26 relays all communication frames input from the ports 261 to 264 to the ports A and B.

  On the other hand, in the branch port control unit 25, VLAN groups are set in the branch line side ports C to F and the ports 251 to 254 connected to the trunk port control unit 26 from the branch line port control unit 25, respectively. When the branch port control unit 25 receives the communication frame transmitted from the computer 3 through the ports C to F, the same VLAN group as the VLAN group set for the received ports C to F is received. Relay to other set ports C to F or ports 251 to 254. Further, the branch port control unit 25 converts the communication frames input from the ports 251 to 254 to the ports C to F in which the same VLAN group is set as the VLAN group set in the ports 251 to 254 to which the communication frame is input. Relay to.

  In FIG. 3, the ports 261 to 264 of the trunk port control unit 26 and the ports 251 to 254 of the branch port control unit 25 are connected to each other in which the same VLAN group is set. That is, in FIG. 3, the same VLAN group is set for each of the ports 251 and 261, the ports 252 and 262, the ports 253 and 263, and the ports 254 and 264.

  The ports 252 to 254, the ports 262 to 264, and the ports A and B add a VLAN tag to which the port belongs (hereinafter referred to as a VLAN tag) to the frame when the frame is transmitted from the port. Such a port is hereinafter referred to as a tag port. In FIG. 3, the tag port is marked with a “T” to distinguish it from other ports.

  FIG. 4 is a diagram illustrating an example of a communication frame configuration used for detecting a failure of the node device 2 in the communication network system 1. As shown in FIG. 4, in the communication network system 1, in order to detect a failure of the node device 2, (a) an inter-adjacent communication frame, (b) a VLAN diagnosis frame, and (c) a status notification frame Is used.

  The configuration of these communication frames conforms to the IEEE 802.1Q standard, and basically, a VLAN tag or a management tag is attached to an Ethernet (registered trademark) frame. Here, the Ethernet (registered trademark) frame portion is a portion including a destination address, a transmission source address, a frame length / type, a data portion, and a CRC (Cyclic Redundancy Check Code), and the destination address and the transmission source address are: It is represented by a MAC (Media Access Control) address. Further, since the VLAN diagnostic frame is transmitted / received by UDP / IP, an IP header and a UDP header are added.

  Note that the VLAN diagnosis frame is separately transmitted in the opposite direction from the two terminal stations (node devices 2a and 2d) to the other terminal stations (node devices 2d and 2a) for VLAN diagnosis. . Therefore, a unique diagnostic pattern for identifying the VLAN group to be diagnosed and the transmission direction is set in the data portion of the VLAN diagnostic frame. Accordingly, the diagnostic pattern is not only different depending on the VLAN group, but the VLAN diagnostic frame is transmitted from the A terminal station (node device 2a) or from the B terminal station (node device 2d). It depends on what.

  Next, an outline of VLAN failure diagnosis processing performed by the node device 2 will be described with reference to FIGS. FIG. 5 is a diagram illustrating an example of a timing chart of transmission and reception of an inter-adjacent communication frame in the node device 2.

  As shown in FIG. 5 (a), each node device 2 has a predetermined time interval T0 (for example, T0 = 1 second) with respect to the adjacent upstream node device 2up and downstream node device 2dw. Sends an adjacent communication frame. As will be described later, in the data portion of the inter-adjacent communication frame, data indicating whether communication is normally performed in the own node device 2 or a failure has occurred in communication is embedded.

  Further, as shown in FIG. 5B, each node device 2 receives an inter-adjacent communication frame transmitted at a predetermined time interval T0 from the adjacent upstream node device 2up and downstream node device 2dw. Accordingly, each node device 2 can know whether communication is normally performed or a failure has occurred in the adjacent upstream node device 2up and downstream node device 2dw.

  Next, with reference to FIGS. 6 and 7, an outline of processing executed when each node device 2 transmits an inter-adjacent communication frame and processing executed when an inter-adjacent communication frame is received will be described. To do. Here, FIG. 6 is a diagram showing the relationship between the reception of the VLAN diagnosis frame and the transmission process of the inter-adjacent communication frame in the node device 2, and FIG. 7 is for the detection of the failure state and the status notification in the node device 2. It is the figure which showed the relationship with a frame transmission process.

  The VLAN diagnosis frame is transmitted from the terminal stations (node devices 2a and 2d) at predetermined time intervals T1 and sequentially transmitted to adjacent downstream node devices. That is, as shown in FIGS. 6A and 6B, the node device 2 receives the VLAN diagnostic frame transmitted from the upstream node device 2up, and uses the received VLAN diagnostic frame as the downstream node device 2dw. Send to. Here, the time interval T1 is equal to or shorter than the time interval T0 (that is, T1 ≦ T0).

  Here, the upstream and downstream are determined according to the direction in which the VLAN diagnostic frame is transmitted. Accordingly, the upstream node device 2up is the node device 2 connected to the side that transmits the VLAN diagnosis frame to the node device 2, and the downstream node device 2dw is the VLAN transmitted from the node device 2. The node device 2 is connected to the side that receives the diagnostic frame.

  On the other hand, each node device 2 receives the VLAN diagnostic frame at least once when it transmits the inter-adjacent communication frame, that is, after transmitting the adjacent inter-adjacent communication frame every predetermined time interval T0. It is determined whether or not. At this time, since T1 ≦ T0, if the VLAN diagnostic frame is correctly transmitted from the upstream node device 2up, the VLAN diagnostic frame should be received at least once.

  Therefore, as a result of the determination, when the VLAN diagnosis frame has been received at least once, the node device 2 stores data indicating that communication is normally performed in the data portion of the inter-adjacent communication frame (“ Normal ”) is embedded and sent to the adjacent upstream node device 2up and downstream node device 2dw (see FIG. 6A). When no VLAN diagnosis frame has been received, the node device 2 embeds data indicating that a communication failure has occurred in the data portion of the inter-adjacent communication frame (“failure occurrence”) and The data is sent to the node device 2up and the downstream node device 2dw (see FIG. 6B).

  As described above, the node device 2 that is actually causing the failure cannot be located only by detecting that the node device 2 does not receive the VLAN diagnosis frame. Therefore, the node device 2 considers the data included in the inter-adjacent communication frame transmitted from the adjacent upstream node device 2up and the downstream node device 2dw, and locates the node device 2 that actually causes the failure. . In this case, the node device 2 that actually causes the failure is adjacent to the node device 2 that has not received the VLAN diagnosis frame first, or upstream of the node device 2 along the path through which the VLAN diagnosis frame is transmitted. It is assumed that it is one of the node devices 2.

  Therefore, as shown in FIG. 7, when the node apparatus 2 has not received the VLAN diagnosis frame to be received, the node apparatus 2 receives the inter-adjacent communication frame transmitted from the node apparatus 2 adjacent on the upstream side. Then, it is determined whether the data embedded in the data portion is “normal” or “failure occurs”. If the data is “normal” as a result of the determination, it means that the node device 2 adjacent to the upstream side has received the VLAN diagnosis frame, so that the node device 2 first performs the VLAN diagnosis. That is, the node apparatus 2 that has received no use frame. Thus, the node device 2 that actually causes the failure is detected.

  That is, when it is detected that the node device 2 has not received the VLAN diagnostic frame, the adjacent upstream node device 2up and the downstream node device 2dw receive the inter-adjacent communication frame in which the “failure occurrence” data is embedded. Send it out. At this time, when the node device 2 is the node device 2 that has not received the VLAN diagnosis frame for the first time, the adjacent upstream node device 2up receives the “normal” data embedded in the adjacent communication. The frame is transmitted, and the inter-adjacent communication frame in which the “failure occurrence” data is embedded is transmitted from the downstream node device 2dw.

  Therefore, when the node device 2 does not receive the VLAN diagnosis frame itself and receives the inter-adjacent communication frame in which “normal” data is embedded from the adjacent upstream node device 2up, the node device 2 itself Alternatively, it is determined that the upstream node device 2up adjacent to itself is in a failure state, and the upstream node device 2up adjacent to itself or itself is transmitted to the other node device 2 of the communication network system 1 by multicast. The status notification frame including the data (status notification information) indicating that it exists in the

  As described above, each node device 2 can detect that the node device 2 itself or the upstream node device 2up adjacent to it is in a fault state at least for the VLAN to be diagnosed. The node node 2 can be notified of information indicating the failure state.

  In the above description, the node device 2 or the upstream node device 2up being in a failure state does not mean that the node device 2 or the upstream node device 2up is completely in a failure state, but the node device 2 or the upstream node device. 2up means that there is a failure in a part of the VLAN group communication subject to diagnosis.

  Further, in the above description, when the node device 2 has not received the VLAN diagnostic frame even once, the inter-adjacent communication frame in which “normal” data is embedded from the adjacent upstream node device 2up. However, if the VLAN diagnosis frame is not received a plurality of times, for example, three times, “normal” data is embedded from the adjacent upstream node device 2up. It may be determined whether an inter-adjacent communication frame is received.

  Alternatively, the time interval T1 at which the VLAN diagnostic frame is transmitted is made sufficiently smaller than the time interval T0 for determining reception of the VLAN diagnostic frame (for example, T1 = 20 milliseconds, T0 = 2 seconds), and the time interval T0 is set. The number of VLAN diagnostic frames received during the period is counted, and when the number does not reach a predetermined number (for example, 7 times), “normal” data is embedded from the adjacent upstream node device 2up It may be determined whether an inter-adjacent communication frame is received. In such a case, it is possible to prevent the case where the VLAN diagnostic frame is not transmitted from the upstream node device 2up to the node device 2 due to an intermittent communication failure from being determined as a failure.

  FIG. 8 is a diagram showing a flowchart of VLAN diagnosis processing in the node device 2 described above.

  As shown in FIG. 8, the terminal stations (node devices 2a and 2d in FIG. 1) perform diagnosis specific to the VLAN group toward the other terminal stations (node devices 2d and 2a) at predetermined time intervals T1. A diagnostic communication frame in which the pattern for use is embedded in the data part is transmitted (step S11). The diagnostic communication frame is independently transmitted separately from the terminal stations (node devices 2a and 2d) along the A direction or the B direction (see FIG. 1), and the processing described below is also independently performed. To be executed.

  When a VLAN diagnosis frame is transmitted from the terminal station (node devices 2a and 2d), the intermediate stations (node devices 2b and 2c and other terminal stations (node devices 2d and 2a)) located downstream of the terminal station Whether or not a VLAN diagnostic frame is received is determined at predetermined time intervals T0 (step S12). When the intermediate station has received the diagnostic communication frame at least once during the time interval T0 as a result of the determination (Yes in step S12), the intermediate station notifies the adjacent upstream and downstream node devices to “normal”. ”Is embedded (step S13), and the process ends. When the intermediate station has not received any diagnostic communication frame within the predetermined time T0 (No in step S12), the intermediate station transmits “communication failure” data to the adjacent upstream and downstream node devices. Is sent out the communication frame between adjacent communication (step S14).

  Next, the intermediate station determines the content of data embedded in the inter-adjacent communication frame transmitted from the adjacent upstream node device (step S15). As a result of the determination, if the embedded data is data indicating “normal” (Yes in step S16), the intermediate station is in the “failure state” (adjacent to itself as described above). The other node device 2 is notified by multicasting (including that the node device to be able to be in the “failure state”) (step S17). If the data does not indicate “normal” (No in step S16), the process ends.

  Next, the internal operation of the node device 2 during the VLAN diagnosis process will be described in detail with reference to FIGS. Here, FIG. 9, FIG. 10 and FIG. 11 show the transmission path from when the VLAN diagnostic frame sent from the A terminal station is transmitted to the B terminal station via the intermediate station and terminated at the B terminal station. It is the figure which showed the example of transmission operation.

  As shown in FIG. 9, in the node equipment 2A which is the A terminal station, the control MPU 27 generates a VLAN diagnosis frame in which a management tag is added to the VLAN diagnosis buffer 23 every predetermined time interval T1. The generated VLAN diagnostic frame is sent to port A via the VLAN diagnostic frame control unit 24 and the trunk port control unit 26. At this time, the port A recognizes from the management tag in the frame that the communication frame sent from the VLAN diagnosis frame control unit 24 is a VLAN diagnosis frame, and sets the management tag as the VLAN group to be diagnosed. It is sent to the transmission line of the trunk line 4 after being replaced with the tag.

  Here, it is assumed that the port 265 of the trunk port control unit 26 belongs to a VLAN group different from the VLAN group to which the ports 261 to 264 belong. However, by the function of changing from the management tag to the VLAN tag in the port A, A communication frame transmitted from the port 265 can be transmitted to another VLAN group across VLAN groups. Further, since the trunk port control unit 26 logically blocks the transmission of the VLAN diagnosis frame from the port B, the trunk line control unit 26 does not transmit the VLAN diagnosis frame from the port B.

  Next, as shown in FIG. 10, in the node device 2C, which is an intermediate station, the VLAN diagnostic frame transmitted from the upstream trunk line 4 is received by the port B, and the VLAN group is determined based on the VLAN tag. According to the identified VLAN group, it is appropriately sent to the port 261 and further stored in the VLAN individual buffer 21 via the VLAN individual frame control unit 22. The VLAN diagnostic frame received by the port B is also sent to the downstream trunk line 4 via the port A.

  Next, as shown in FIG. 11, in the node equipment 2B which is the B terminal station, the VLAN diagnosis frame transmitted from the upstream trunk line 4 is received by the port B, and the VLAN group is based on the VLAN tag. Is identified and sent to the port 261 as appropriate according to the identified VLAN group, and further stored in the VLAN individual buffer 21 via the VLAN individual frame control unit 22. Further, the trunk port control unit 26 logically blocks the transmission of the VLAN diagnosis frame from the port A, and therefore does not transmit the VLAN diagnosis frame from the port A. The VLAN diagnostic frame is terminated at the B terminal station.

  12, 13, and 14 show the transmission path and transmission operation until the VLAN diagnosis frame transmitted from the B terminal station is transmitted to the A terminal station via the intermediate station and terminated at the A terminal station. It is the figure which showed the example. However, the transmission path and the transmission operation are only the reverse of the transmission path and the transmission operation described with reference to FIGS. 9, 10 and 11, and the transmission operation is almost the same. I will omit the explanation. In the description of FIGS. 9, 10, and 11, if “A” is replaced with “B” and “B” is replaced with “A”, the description of FIGS. 12, 13, and 14 is obtained.

  FIG. 15 is a diagram illustrating an example of a transmission path and a transmission operation when an intermediary station transmits an adjacent communication frame. As shown in FIG. 15, in the node device 2C as an intermediate station, the control MPU 27 accesses the VLAN individual buffer 21 at every predetermined time interval T0 and receives a new VLAN diagnostic frame in the VLAN individual buffer 21. It is determined whether or not it is performed (corresponding to step S12 in FIG. 8).

  As a result of the determination, when a new VLAN diagnostic frame is received, the control MPU 27 generates an inter-adjacent communication frame in the VLAN diagnostic buffer 23, and displays “normal” in the data portion of the inter-adjacent communication frame. Is sent to port A and port B via the VLAN diagnosis frame control unit 24 and the trunk port control unit 26. Port A and port B attach the VLAN tag of the VLAN group to be diagnosed to the sent inter-adjacent communication frame and send it to the upstream and downstream trunk lines 4 (corresponding to step S13 in FIG. 8). ). At this time, the control MPU 27 clears the VLAN individual buffer 21.

  On the other hand, when a new VLAN diagnostic frame has not been received in the VLAN individual buffer 21, an inter-adjacent communication frame is generated in the VLAN diagnostic buffer 23, and "communication failure" is added to the data portion of the inter-adjacent communication frame. And the inter-adjacent communication frame is sent to port A and port B via the VLAN diagnosis frame control unit 24 and the trunk port control unit 26. Port A and port B attach the VLAN tag of the VLAN group to be diagnosed to the inter-adjacent communication frame that has been sent, and transmit the inter-adjacent communication frame with the VLAN tag to the upstream and downstream trunks 4. Send out (corresponding to step S14 in FIG. 8).

  FIG. 16 is a diagram illustrating an example of a transmission path and a transmission operation when an intermediary station receives an adjacent communication frame. As illustrated in FIG. 15, in the node device 2 </ b> C that is an intermediate station, the port A and the port B each receive an inter-adjacent communication frame transmitted from the adjacent node device 2 via the trunk line 4. The received inter-adjacent communication frame is stored in the VLAN diagnosis buffer 23 via the trunk port control unit 26 and the VLAN diagnosis frame control unit 24.

  At this time, the control MPU 27 accesses the VLAN diagnosis buffer 23 at every predetermined time interval T0 and is used for adjacent communication transmitted from the upstream node apparatus 2 stored in the VLAN diagnosis buffer 23. The contents of the data embedded in the data part of the frame are determined (corresponding to step S15 in FIG. 8).

  Based on the determination, the control MPU 27 determines that the data indicating “normal” is embedded in the inter-adjacent communication frame transmitted from the upstream node device 2, and the VLAN individual buffer in the previous determination. If it is determined at 21 that no new VLAN diagnostic frame has been received, it is determined that a failure has occurred in the communication of the VLAN group to be diagnosed between the node device 2 and the upstream node device 2. (Equivalent to the case of Yes in FIG. 8, step S16).

  The control MPU 27 generates a status notification frame in the VLAN diagnosis buffer 23, and as the status notification information (see FIG. 4) of the data portion of the status notification frame, the device identification number of the node device 2, the node device 2, information identifying the node device 2 such as a device identification number of the adjacent node device 2 is embedded. Then, the control MPU 27 sends the status notification frame to the port A and the port B via the VLAN diagnosis frame control unit 24 and the trunk port control unit 26 according to the route shown in FIG. Port A and port B attach the VLAN tag of the VLAN group to be diagnosed to the sent status notification frame, and send the status notification frame with the VLAN tag to the upstream and downstream trunks 4. (Corresponding to FIG. 8, step S17).

  At this time, since the status notification frame is transmitted by multicast, the other node device 2 included in the communication network system 1 receives the status notification frame to identify the node device 2 in the fault state. Information can be acquired. In other words, you can know where the obstacle is.

  As can be understood from the description with reference to FIGS. 9 to 16, among the ports connecting the branch port control unit 25 and the trunk port control unit 26, the port 252 and the port 262, the port 253 and the port 263, Further, the VLAN individual frame control unit 22 is not provided in the VLAN group of the port 254 and the port 264. In this case, the control MPU cannot monitor the reception of the VLAN diagnosis frame or determine the content of data embedded in the data portion of the inter-adjacent communication frame. Therefore, VLANs in groups in which the VLAN individual frame control unit 22 is not provided cannot be a target of failure diagnosis.

  That is, the VLAN individual frame control unit 22 must be provided in the VLAN of the group to be diagnosed, but conversely, the VLAN individual frame is not included in the VLAN of the group that does not require much reliability. There is no need to provide the controller 22.

  This is the end of the description of the present embodiment, but the present invention can be implemented without being limited to the above embodiment. For example, in the above embodiment, the transmission path 4 that connects the node devices 2 has a ring shape. However, in FIG. 1, for example, the node device 2a and the node device 2d are physically connected by the transmission paths 4a and 4d. It may be a straight transmission line that is not connected to the.

The figure which showed the example of the structure of the communication network system which concerns on embodiment of this invention. The figure which showed the range in which a communication frame is transmitted in the communication network system which concerns on this embodiment. The figure which showed the example of the block configuration of the node apparatus used with the communication network system which concerns on this embodiment. The figure which showed the example of the communication frame structure used for the failure detection of a node apparatus in the communication network system which concerns on this embodiment. The figure which showed the example of the timing chart of transmission and reception of the frame for adjacent communication in the node apparatus which concerns on this embodiment. The figure which showed the relationship between reception of the frame for VLAN diagnosis in the node apparatus which concerns on this embodiment, and transmission processing of the frame for adjacent communication. The figure which showed the relationship between the detection of the failure state in the node apparatus which concerns on this embodiment, and the frame transmission process for a status notification. The figure which showed the flowchart of the VLAN diagnostic process in the node apparatus which concerns on this embodiment. The figure which showed the example of the transmission path | route of the VLAN diagnostic frame sent out from A terminal station, and transmission operation | movement. The figure which showed the example of the transmission path | route and transmission operation | movement when the VLAN diagnostic frame sent out from A terminal station is relayed by an intermediate station. The figure which showed the example of the transmission path | route and transmission operation | movement when the frame for VLAN diagnosis sent out from A terminal station is received by B terminal station, and is terminated by B terminal station. The figure which showed the example of the transmission path | route of the VLAN diagnostic frame sent out from B terminal station, and transmission operation | movement. The figure which showed the example of the transmission path | route when the VLAN diagnostic frame sent out from the B terminal station is relayed by an intermediate station, and transmission operation | movement. The figure which showed the example of the transmission path | route and transmission operation | movement when the frame for VLAN diagnosis sent out from the B terminal station is received by the A terminal station, and is terminated by the A terminal station. The figure which showed the example of the transmission path | route at the time of transmission of the frame for adjacent communication in an intermediate station, and transmission operation | movement. The figure which showed the example of the transmission path | route at the time of the frame for adjacent communication communication in an intermediate station, and transmission operation | movement.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Communication network system 2 Node apparatus 3 Computer 4 Main line 4a Transmission path 21 VLAN separate buffer 22 VLAN individual frame control part 23 VLAN diagnosis buffer 24 VLAN diagnosis frame control part 25 Branch line port control part 26 Main line port control part 27 Control MPU

Claims (8)

A communication network system configured by connecting a plurality of node devices to a ring-shaped or linear trunk transmission line,
A first node device connected to one end of the trunk transmission line;
Means for sending a diagnostic frame at predetermined time intervals toward a node device connected to the other end of the main transmission line opposite to the one end;
A second node device that is a node device connected to the trunk transmission line downstream of the first node device along a direction in which the transmitted diagnostic frame is transmitted;
First determination means for determining whether or not the diagnostic frame is received every second time interval equal to or longer than the predetermined time interval;
When it is determined by the first determination means that the diagnostic frame has been received, an upstream node device adjacent to its upstream side along the trunk transmission line and a downstream node device adjacent to the downstream side thereof On the other hand, when it is determined that the inter-adjacent communication frame including information indicating “communication is normal” is transmitted and the diagnostic frame is not received, the upstream node device and the downstream node device , Means for sending an inter-adjacent communication frame including information indicating “communication failure”;
Second determination means for receiving an inter-adjacent communication frame sent from the upstream node device and determining the content of information included in the received inter-adjacent communication frame;
The first determination unit determines that the diagnostic frame has not been received, and the second determination unit includes information indicating that “communication is normal” in the received adjacent communication frame. When it is determined that it is included, a status notification frame including information that “the communication failure is in itself or the upstream node device” is sent to another node device included in the communication network system. Means for sending out;
A communication network system characterized by comprising: The node device further includes a plurality of ports connected to a terminal,
A VLAN group is set in at least one of the plurality of ports,
The first node device, when transmitting the diagnostic frame, includes the information for designating a VLAN group to be diagnosed in the diagnostic frame and transmits the diagnostic frame. The communication network system described in 1. The trunk transmission line is composed of two independent transmission lines in the transmission direction facing each other.
2. Each of the node devices connected to both ends of the main transmission line independently sends the diagnostic frame toward the node devices connected to the other end. The communication network system described in 1. A communication failure detection method in a communication network system configured by connecting a plurality of node devices to a ring-shaped or linear trunk transmission line,
A first node device connected to one end of the trunk transmission line;
Sending a diagnostic frame at predetermined time intervals toward a node device connected to the other end opposite to the one end of the trunk transmission line;
A second node device that is a node device connected to the trunk transmission line downstream of the first node device along a direction in which the transmitted diagnostic frame is transmitted;
A first determination step of determining whether or not the diagnostic frame has been received for each second time interval that is equal to or longer than the predetermined time interval;
In the first determination step, when it is determined that the diagnostic frame has been received, the upstream node device adjacent to its upstream side along the trunk transmission line and the downstream node device adjacent to the downstream side On the other hand, when it is determined that the inter-adjacent communication frame including information indicating “communication is normal” is transmitted and the diagnostic frame is not received, the upstream node device and the downstream node device Sending an inter-adjacent communication frame including information indicating “communication failure”;
A second determination step of receiving an inter-adjacent communication frame transmitted from the upstream node device and determining the content of information included in the received inter-adjacent communication frame;
In the first determination step, it is determined that the diagnostic frame has not been received, and in the second determination step, information indicating that “communication is normal” is included in the received adjacent communication frame. When it is determined that it is included, a status notification frame including information that “the communication failure is in itself or the upstream node device” is sent to another node device included in the communication network system. Sending step;
The communication failure detection method characterized by performing this. The node device further includes a plurality of ports connected to a terminal,
A VLAN group is set in at least one of the plurality of ports,
The first node device, when transmitting the diagnostic frame, includes the information for designating a VLAN group to be diagnosed in the diagnostic frame and transmits the diagnostic frame. The communication failure detection method described in 1. The trunk transmission line is composed of two independent transmission lines in the transmission direction facing each other.
5. Each of the node devices connected to both ends of the main transmission line independently send out the diagnostic frame toward the node devices connected to the other ends. The communication failure detection method described in 1. A node device used in a communication network system configured by connecting a plurality of node devices to a ring-shaped or linear trunk transmission line,
When the node device is connected to one end of the main transmission line, a diagnostic frame is provided at predetermined time intervals toward the node device connected to the other end opposite to the one end of the main transmission line. Means for sending out;
When the node device is connected to the trunk transmission line downstream of the one end along the transmission direction of the diagnostic frame, a second time that is equal to or longer than the predetermined time interval First determination means for determining whether or not the diagnostic frame is received at each time interval;
When it is determined by the first determination means that the diagnostic frame has been received, an upstream node device adjacent to its upstream side along the trunk transmission line and a downstream node device adjacent to the downstream side thereof On the other hand, when it is determined that the inter-adjacent communication frame including information indicating “communication is normal” is transmitted and the diagnostic frame is not received, the upstream node device and the downstream node device , Means for sending an inter-adjacent communication frame including information indicating “communication failure”;
Second determination means for receiving an inter-adjacent communication frame sent from the upstream node device and determining the content of information included in the received inter-adjacent communication frame;
The first determination unit determines that the diagnostic frame has not been received, and the second determination unit includes information indicating that “communication is normal” in the received adjacent communication frame. When it is determined that it is included, a status notification frame including information that “the communication failure is in itself or the upstream node device” is sent to another node device included in the communication network system. Means for sending out;
A node device characterized by comprising: A plurality of ports connected to the terminal;
A VLAN group is set in at least one of the plurality of ports,
The node device according to claim 7, wherein when transmitting the diagnostic frame, the diagnostic frame is transmitted by including information for designating a VLAN group to be diagnosed in the diagnostic frame.

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