JP4237166B2 - Multi-channel network device and MAC address assignment method - Google Patents

Description

  The present invention relates to a multi-channel network device on which a plurality of LAN (Local Area Network) cards are mounted.

  As a network device, a multi-channel Ethernet device on which a plurality of LAN cards are mounted is known. In this type of multi-channel Ethernet device, each LAN card is given a MAC (Media Access Control) address that can be uniquely identified on the network (see Patent Document 1).

  FIG. 10 shows an example of a multi-channel Ethernet device. This multi-channel Ethernet device is configured so that a plurality of LAN cards 101 and a control card 110 can be mounted. The control card 110 controls the operation of the attached LAN card 101 and monitors its state.

  The LAN card 101 has a media conversion function between optical Ethernet and metal Ethernet, can transmit and receive data using a MAC frame specified in IEEE 802.3, and terminates a LAN (Ethernet) network. This LAN card 101 includes an optical interface 104 connected to a WAN (Wide Area Network) side communication network (private line network) 102, a data conversion unit 105, and a LAN (Local Area Network) 103 which is a local side communication network. A LAN interface 106, a console interface 107, and a MAC address storage unit 108.

  The optical interface 104 includes an optical / electrical conversion unit, converts data (electrical signal) from the data conversion unit 105 into an optical signal and transmits it to the WAN 102, and converts data (optical signal) from the WAN 102 into an electrical signal. Then, the data is supplied to the data conversion unit 105. The LAN interface 106 supplies data from the local LAN 103 to the data converter 105, and sends data from the data converter 105 to the local LAN 103. The data exchange unit 105 has a function of replacing data from the optical interface 104 and the LAN interface 106 with packets corresponding to the WAN and the LAN. The console interface 107 can be connected to an external address registration device 112, and stores the MAC address supplied from the external address registration device 112 in the MAC address storage unit 108.

In the multi-channel Ethernet device shown in FIG. 10, by mounting the LAN card 101, data can be transmitted between different networks. Further, by installing a plurality of LAN cards 101, multi-channel communication becomes possible.
JP 2004-173315 A

  However, in the multi-channel Ethernet device shown in FIG. 10, since the MAC address is directly registered in each LAN card at the time of card manufacture, there are the following problems.

  (1) When registering a MAC address in a LAN card, it is necessary to connect the LAN card to the address registration device 112, and performing such connection work for a large number of LAN cards is very laborious. It becomes.

  (2) When a LAN card is exchanged with another LAN card, it cannot be used with another LAN card in which the MAC address registered in the LAN card before exchange is exchanged. As described above, since MAC addresses cannot be inherited between LAN cards, MAC address resources are wasted.

  (3) Since the same MAC address cannot be used by a plurality of LAN cards, for example, in a system having a redundant structure such as an operation system using the first LAN card and a standby system using the second LAN card. When switching from the active system to the standby system, the router installed on the local communication network may be disconnected until the routing table is updated for the MAC address of the second LAN card. .

  In Patent Document 1, an address storage unit that stores a MAC address is provided in a control device (control card), and the control device refers to the MAC address stored in the address storage unit and stores the MAC address in the LAN card. A system is disclosed that is adapted to assign the. However, in this case, since the control device itself includes an address storage unit, when the control device fails and the failed control device is replaced with another control device, the address storage unit provided in the failed control device. Cannot be used by other control devices. As described above, since the MAC address cannot be inherited between the failed control device and another control device exchanged, the MAC address resource is wasted.

  An object of the present invention is to solve the above problems and provide a multi-channel network device having a high degree of freedom in MAC address setting, which can take over MAC addresses between LAN cards and between control cards.

In order to achieve the above object, the multi-channel network device of the present invention provides:
A plurality of LAN cards for connecting to a network;
An apparatus main body having a plurality of slots into which the plurality of LAN cards are respectively inserted;
A removable control card mounted on the apparatus body,
The apparatus main body includes a MAC address storage unit in which MAC addresses used as unique addresses of the plurality of LAN cards on the network are stored in advance for each slot ID that can identify the plurality of slots,
The control card, for each of said plurality of LAN card, the LAN card based on the slot ID of the inserted slot obtains the MAC address from the MAC address storage unit, the LAN MAC addresses that the acquired This is assigned to the card,
Each of the plurality of LAN cards is
Another MAC address storage unit for storing the MAC address;
A control card interface connected to the control card and storing the MAC address supplied from the control card in the another MAC address storage unit.
The control card supplies the slot ID of the slot in which the LAN card is inserted to each of the plurality of LAN cards.
Each of the plurality of LAN cards is based on an interface for sending out a packet to which a MAC address stored in the other MAC address storage unit is added to the network, and a slot ID supplied from the control card. A comparison unit that acquires a MAC address from a MAC address storage unit and determines whether or not the acquired MAC address matches a MAC address stored in the other MAC address storage unit; and the comparison unit A packet control unit that permits transmission of packets by the interface only when it is determined that the MAC addresses match.

  According to the above configuration, the control card refers to the MAC address stored in the MAC address storage unit and assigns the MAC address to the LAN card inserted in the slot. There is no need to register a MAC address in each LAN card.

  Further, the MAC address is registered in the MAC address storage unit of the apparatus body when the multi-channel network apparatus is manufactured. Since the number of device bodies is smaller than the number of LAN cards, the MAC address registration work is greatly reduced.

  Further, when the LAN card is replaced, the control card refers to the MAC address stored in the MAC address storage unit and assigns the MAC address to the replaced LAN card. Thus, MAC addresses can be inherited between LAN cards within the range of MAC addresses stored in the MAC address storage unit.

  Furthermore, since the control card and the MAC address storage unit are provided independently, it is not necessary to replace the MAC address storage unit when the control card fails and is replaced with another control card. Thus, the MAC address can be inherited even when the control card is exchanged.

  In the MAC address storage unit, the MAC address is stored for each slot ID. Therefore, when one slot among a plurality of slots is used as the active system and the other slots are used as the standby system, if the same MAC address is stored in the column corresponding to the ID of these slots, the active system and the standby system are used. The same MAC address is assigned to each.

  According to the present invention, since the MAC address is registered in the MAC address storage unit provided in the apparatus main body, the MAC address is registered at the time of manufacture as compared with the case of registering the MAC address in the LAN card. The accompanying work can be reduced.

  In addition, since MAC addresses can be inherited between LAN cards and between control cards, waste of MAC address resources can be suppressed.

  Further, when the same MAC address is assigned to a plurality of LAN cards, the MAC address storage unit need only store the same MAC address for the slot ID of the slot into which the LAN card is inserted. In this way, the application to a device having a high degree of freedom in MAC address setting and a line backup function is simple.

  Next, embodiments of the present invention will be described with reference to the drawings.

(First embodiment)
FIG. 1 is a block diagram showing a schematic configuration of a multi-channel Ethernet device according to the first embodiment of the present invention. Referring to FIG. 1, the multi-channel Ethernet device of this embodiment includes a plurality of LAN cards 20, a device main body 1 having slots into which the LAN cards 20 are respectively inserted, and a detachable mounted on the device main body 1. Control card 10 and a MAC address storage unit 30 in which a MAC address to be assigned to each LAN card 20 is stored in advance. Each of the control card 10, each LAN card 20, and the MAC address storage unit 30 is connected to the bus 40.

  Similar to the LAN card 101 shown in FIG. 10, the LAN card 20 has a media conversion function between optical Ethernet and metal Ethernet, and can transmit and receive data using MAC frames defined in IEEE802.3. The (Ethernet) network is configured to terminate, but is different from the LAN card 101 in that a MAC address is assigned by the control card 10. FIG. 2 shows the configuration of the LAN card 20.

  Referring to FIG. 2, the LAN card 20 includes an optical interface 21 connected to a WAN-side communication network (private line network) 102, a data conversion unit 22, and a LAN interface connected to a LAN 103 that is a local-side communication network. 23, a control card interface 24 capable of communicating with the control card 10, and a MAC address storage unit 25 in which a MAC address assigned by the control card 10 is stored. The optical interface 21 and the data converter 22 are basically the same as those shown in FIG.

  When receiving the MAC address from the control card 10, the control card interface 24 stores the received MAC address in the MAC address storage unit 25. Further, when the MAC address received from the control card 10 is stored in the MAC address storage unit 25, the control card interface 24 stores the MAC address already stored in the MAC address storage unit 25. After erasing the MAC address, the MAC address received from the control card 10 is stored. Thereby, the MAC address storage unit 25 always stores the MAC address assigned by the control card 10 when the LAN card 20 is inserted into the slot.

  The LAN interface 23 supplies data from the local LAN 103 to the data converter 105 and sends data from the data converter 22 onto the local LAN 103. When the data from the data conversion unit 22 is transmitted on the local LAN 103, the LAN interface 23 uses the MAC address stored in the MAC address storage unit 25 as a source address. FIG. 3 shows a schematic configuration of the LAN interface 23.

  Referring to FIG. 3, the LAN interface 23 includes a MAC processing unit 230, a PHY (Physical Layer) unit 231, and a MAC address setting unit 232. The MAC address setting unit 232 reads the MAC address from the MAC address storage unit 25 and notifies the MAC processing unit 230 of the read MAC address as a source address. The MAC processing unit 230 embeds the source address notified from the MAC address setting unit 232 in the data from the data conversion unit 22 as an address value. The PHY unit 231 is a physical layer that defines mutual conversion between data and electric signals.

  The control card 10 includes a control unit 11 connected to each of the control card interface 24 of the LAN card 20 and the MAC address storage unit 30 via the bus 40. The control unit 11 has a MAC address management function, a MAC address assignment function, a LAN card operation control function, a status monitoring function, and the like.

  The MAC address management function is a function for managing an assigned MAC address and an unused MAC address for the MAC address stored in the MAC address storage unit 30. More specifically, the control unit 11 can set a flag indicating that the MAC address has been assigned to each MAC slot in the MAC address storage unit 30 for each slot ID.

  The MAC address assignment function is a function for referring to the MAC address stored in the MAC address storage unit 30 and writing the MAC address in the LAN card 20. When the multi-channel Ethernet device is activated and when the LAN card is replaced, a MAC address is assigned to the LAN card by this MAC address assignment function. The assignment of the MAC address to the LAN card 20 is preferably performed in the order of the slot number (ID) in which the LAN card 20 is inserted.

  FIG. 4 shows an example of information stored in the MAC address storage unit 30. Referring to FIG. 4, MAC address values are assigned in advance for each slot ID. In each slot ID column, a flag setting column is provided. The control unit 11 acquires a MAC address from the MAC address storage unit 30 based on the slot ID of the slot, and assigns the acquired MAC address to the LAN card inserted in the slot. Further, when the MAC address is assigned to the LAN card inserted in the slot, the control unit 11 stores flag information “present” in the flag setting column provided in the corresponding slot ID column, and sets the MAC address. When the assigned LAN card is removed from the slot, flag information “None” is stored in the flag setting column provided in the corresponding slot ID column. Further, the control unit 11 checks the slot in which the LAN card is currently inserted by polling, determines that the LAN card is inserted at the previous polling, and inserts the LAN card at the current polling. Based on the result of comparison with the slot determined to be present, insertion into the slot of the LAN card and removal from the slot of the LAN card are determined.

  The LAN card has a setting mode register for determining a setting mode and a status display register for displaying the status, and the operation is determined by the values of these registers. The operation control / status monitoring function writes / reads register values in the setting mode register and status display register.

  In addition to the above, the control card 10 also performs activation setting of the LAN card 20 inserted in the slot. Here, the activation setting is a setting of the operation mode (communication speed, flow control, etc.) of the LAN interface. The flow control includes a pause frame transmission process described later.

  In the present embodiment, the LAN card has a setting confirmation register for confirming whether or not a MAC address is set. The state of the setting confirmation register is cleared when power is supplied to the LAN card. The control unit 11 determines whether or not the LAN card has already been assigned a MAC address based on the state of the setting confirmation register. In addition, when the MAC address is assigned to the LAN card, the control unit 11 sets the setting confirmation register of the LAN card to a set state. Instead of the control unit 11, the control card interface in the LAN card may set the state of the setting confirmation register. In this case, when the control card interface receives the MAC address from the control card, the control card interface sets the setting confirmation register to the already set state.

  The number of MAC addresses stored in the MAC address storage unit 30 can be arbitrarily set according to the design, but basically the number of MAC addresses corresponding to the number of slots into which the LAN card 20 is inserted. Is stored in the MAC address storage unit 30. The MAC address is stored in the MAC address storage unit 30 when the multi-channel Ethernet device is manufactured.

  Next, the operation of the multi-channel Ethernet device of this embodiment will be described.

  FIG. 5 shows a procedure of MAC assignment processing by the control unit 11 of the control card 10. First, the control unit 11 determines whether or not the multi-channel Ethernet device has been activated (step 400). In this determination, the control unit 11 monitors the on / off state of a power supply (not shown) of the multi-channel Ethernet device, and determines that it is activated when the power is turned on. The determination of the on / off state of the power supply is performed, for example, by detecting the voltage level in the power supply line and determining whether or not the predetermined voltage level has been reached.

  When the multi-channel Ethernet device is activated, the control unit 11 then assigns a MAC address to the LAN card 20 inserted in the slot (step 401). In this MAC address assignment, the control unit 11 refers to the MAC address stored in the MAC address storage unit 30. Of the MAC addresses stored in the MAC address storage unit 30, the MAC address assigned to the LAN card is flagged to that effect (see FIG. 4). Further, the control unit 11 sets the setting confirmation register of the LAN card to which the MAC address is assigned to a set state (step 402).

  After assigning the MAC address and setting the setting confirmation register, the control unit 11 starts operation of the LAN card 20 (step 403). After starting the operation of the LAN card 20, the control unit 11 performs polling at regular intervals to check the contents of the setting confirmation registers of all the LAN cards currently inserted in the slots (step 404), and in the unset state. It is determined whether there is a LAN card (step 405). If there is an unconfigured LAN card, the control unit 11 determines that a new unconfigured LAN card has been inserted into the slot, and refers to the information stored in the MAC address storage unit 30 to determine the unconfigured LAN card. A MAC address is assigned to the LAN card (step 406). After assigning the MAC address to the LAN card, the control unit 11 stores “present” flag information in the slot column in which the LAN card is inserted in the MAC address storage unit 30.

  Subsequently, the control unit 11 sets the setting confirmation register of the LAN card to which the MAC address is assigned to a set state (step 407). Then, the control unit 11 operates the LAN card to which the MAC address is assigned in Step 407 (Step 408).

  In the polling process of step 404, when the control unit 11 detects that the LAN card has been removed from the slot, the MAC address storage unit 30 sets a flag “none” in the corresponding slot column. Store information.

  According to the multi-channel Ethernet device of this embodiment, at the time of activation, the control card 10 refers to the MAC address stored in the MAC address storage unit 30 and assigns the MAC address to the LAN card 20 inserted in the slot. Therefore, it is not necessary to register a MAC address in each LAN card at the time of card manufacture.

  The registration of the MAC address is performed for the multi-channel Ethernet device. The MAC address is registered in the multi-channel Ethernet device using an external address registration device as shown in FIG. 10, but the number of multi-channel Ethernet devices is smaller than the number of LAN cards. Address registration is greatly reduced.

  When the LAN card is replaced, the control card 10 refers to the MAC address stored in the MAC address storage unit 30 and assigns the MAC address to the replaced LAN card. In this case, the MAC address can be inherited within the range of the MAC address stored in the MAC address storage unit 30. For example, when a LAN card is started with all slots inserted and then the LAN card is replaced with another LAN card in any slot, the MAC assigned to the LAN card before replacement An address will be assigned to another exchanged LAN card. In this case, one MAC address is inherited between the LAN card before exchange and the other LAN card exchanged. Since MAC address inheritance is possible in this way, waste of MAC address resources can be suppressed.

  Further, since the control card 10 and the MAC address storage unit 30 are provided independently, it is not necessary to replace the MAC address storage unit 30 when the control card 10 breaks down and is replaced with another control card. As described above, since the MAC address can be inherited even when the control card is exchanged, waste of the MAC address resource can be suppressed.

  In the MAC address storage unit 30, the MAC address is stored for each slot ID. Therefore, when one slot among a plurality of slots is used as the active system and the other slots are used as the standby system, if the same MAC address is stored in the column corresponding to the ID of these slots, the active system and the standby system are used. The same MAC address is assigned to each.

(Second Embodiment)
In the multi-channel Ethernet device of the first embodiment, when a LAN card is inserted with no control card installed, MAC address assignment to the LAN card is not performed until the control card is installed. If a LAN card is inserted when the control card is busy, the MAC address is not immediately assigned to the LAN card. Thus, even when a LAN card is inserted into the slot, there is a case where the MAC address is not immediately assigned to the LAN card. In such a case, if communication is started in an unconfigured LAN card to which no MAC address is assigned, a packet with an incorrect MAC address may be transmitted. For example, when a LAN card having a MAC address already stored in the MAC address storage unit 25 is inserted into the slot, communication is started without immediately assigning a MAC address to the LAN card. The packet to which the MAC address (this is an incorrect MAC address) stored in the MAC address storage unit 25 is sent is transmitted. In order to prevent this problem, it is necessary to provide a function for stopping packet transmission to an unconfigured LAN card to which no MAC address is assigned.

  As a method for stopping the transmission of the packet, there is a method for stopping the transmission LINK pulse. However, this method makes it difficult to check the connectivity of the LAN as well as the stop control of the packet communication.

  Since the LINK pulse (data) from the WAN side does not need to be added with a MAC address in the LAN card, there is no problem even if such a LINK pulse is transmitted in an unconfigured LAN card. On the other hand, packets sent by the LAN card itself, for example, packet requests by a pause (PAUSE) frame sent by the LAN card 20 when traffic from the LAN 103 to the LAN card 20 is concentrated, are added with the above incorrect MAC address. Then, it becomes impossible to specify the LAN card where the traffic is concentrated. In this embodiment, a multi-channel Ethernet device that can suppress the transmission of a packet with such an incorrect MAC address will be described.

  FIG. 6 is a block diagram showing a schematic configuration of a multi-channel Ethernet device according to the second embodiment of the present invention.

  The multi-channel Ethernet device of the present embodiment has a function of stopping transmission of a packet (specifically, a pause frame) that requires addition of a MAC address until a MAC address is assigned (pause frame transmission stop function). Is the same as that of the multi-channel Ethernet device of the first embodiment except that is added to the LAN card.

  The LAN card 20 is obtained by adding a comparison unit 26 and a packet control unit 27 to the configuration of the LAN card shown in FIG. 2. The comparison unit 26 and the packet control unit 27 provide a pause frame transmission stop function.

  The LAN interface 23 has a function of transmitting a request packet (pause frame) for suppressing packet transmission on the LAN 103 when a large number of packets are received from the local LAN 103. The MAC address stored in the MAC address storage unit 25 is added to this packet.

  The comparison unit 26 is supplied with the ID of the slot into which the LAN card 20 is inserted from the control card 10 through the control card interface 24. Based on the slot ID received from the control card 10, the comparison unit 26 acquires the MAC address related to the slot in which the LAN card 20 is inserted from the MAC address storage unit 30, and the acquired MAC address and the MAC address storage unit The MAC address stored in 25 is compared, and the comparison result is supplied to the packet control unit 27. In addition, since the comparison unit 26 cannot perform the MAC address comparison after the LAN card is inserted into the slot until the slot ID is received from the control card 10, the comparison unit 26 replaces the MAC address comparison result. Then, a signal indicating that the slot ID has not been received is supplied to the packet control unit 27. The comparison unit 26 monitors the voltage of a power supply line (not shown) of the LAN card 20, for example, and the LAN card is inserted into the slot depending on whether the voltage of the power supply line has reached a predetermined voltage. Judge whether or not.

  The packet control unit 27 controls the transmission of the pause frame in the LAN interface 23, and allows the transmission of the pause frame only when the comparison result indicating that the MAC addresses match is received from the comparison unit 26. When a control signal is supplied to the LAN interface 23, and otherwise (when a signal indicating that the slot ID has not been received or a comparison result indicating that the MAC addresses do not match is received from the comparison unit 26), the pause is performed. A control signal for disabling frame transmission is supplied to the LAN interface 23. Pause frame transmission by the LAN interface 23 is performed based on a control signal from the packet control unit 27.

  Next, the operation of pause frame transmission control by the LAN card 20 performed in the multi-channel Ethernet device of this embodiment will be described. FIG. 7 shows a procedure of the pause frame transmission control.

  Referring to FIG. 7, first, the comparison unit 26 determines whether or not the LAN card 20 is inserted into the slot (step 700). If it is determined that the LAN card 20 has been inserted into the slot, the comparison unit 26 subsequently determines whether or not a slot ID has been received from the control card 10 (step 701). If the slot ID has not been received from the control card 10, the comparison unit 26 notifies the packet control unit 27 to that effect, and the packet control unit 27 sends a control signal indicating that the pause frame cannot be transmitted in response to the notification. The data is supplied to the interface 23 (step 702).

  When the slot ID is received from the control card 10, the comparison unit 26 acquires the MAC address related to the slot into which the LAN card 20 is inserted from the MAC address storage unit 30 based on the received slot ID, and acquires the MAC address. The MAC address thus compared is compared with the MAC address stored in the MAC address storage unit 25 (step 703). If the comparison result in step 703 does not match, the packet control unit 27 supplies a control signal indicating that the pause frame cannot be transmitted to the LAN interface 23 (step 704). If the comparison result in step 703 matches, the packet control unit 27 supplies the LAN interface 23 with a control signal indicating that the pause frame can be transmitted (step 705).

  According to the above-described pause frame transmission control, in an unconfigured LAN card in which no MAC address has been assigned yet, packet transmission by the pause frame is stopped, so a pause frame to which an incorrect MAC address is added. Will never be sent. Further, since the packet for which transmission is to be stopped is only a pause frame, a LINK pulse can be transmitted in an unconfigured LAN card.

  When the packet control unit 27 supplies the LAN interface 23 with a control signal indicating that the pause frame cannot be transmitted in step 704, the packet control unit 27 acquires the slot ID received in step 701 from the comparison unit 26, and together with the acquired slot ID, the MAC The control unit 11 of the control card 10 is notified that the addresses do not match via the control card interface 24, and the control unit 11 responds to the notification to the MAC address to the LAN card 20 inserted in the corresponding slot. The assignment may be performed again. By doing so, the MAC address is written to the LAN card 20 more accurately.

(Third embodiment)
In the multi-channel Ethernet device according to the first and second embodiments, a LAN card is configured that has a redundant structure in which one of at least two slots is an active system and the other is a standby system, and is inserted into the active and standby slots. It is also possible to assign the same MAC address to each other. Here, a multi-channel Ethernet device capable of assigning MAC addresses in such a redundant structure will be described.

  FIG. 8 is a block diagram showing a schematic configuration of a multi-channel Ethernet device according to the third embodiment of the present invention. Referring to FIG. 8, the apparatus main body 1 includes a slot into which the active LAN card 20a is inserted, a slot into which the standby LAN card 20b is inserted, and the LAN cards 20a and 20b inserted into these slots. Are connected to the line selection circuit 50. Multiple channels CH1 to CH18 are combined as a pair of two channels, such as “CH1” and “CH2”, “CH3” and “CH4”, and LAN cards 20a and 20b and line selection are selected for each combination. A circuit 50 is provided.

  Each of the LAN cards 20a and 20b has the same configuration as that shown in FIG. Specifically, the LAN card 20a can communicate between the optical interface connected to the WAN (private line network) 102a, the data conversion unit, the LAN interface connected to the LAN 103, and the control card 10. A control card interface; and a MAC address storage unit that stores a MAC address assigned by the control card. The LAN card 20b includes an optical interface connected to the WAN (private line network) 102b, a data conversion unit, a LAN interface connected to the LAN 103, a control card interface capable of communicating with the control card 10, A MAC address storage unit in which a MAC address assigned by the control card is stored.

  The line selection circuit 50 has one line connected to the LAN interface of the LAN card 20a and the other line connected to the LAN interface of the LAN card 20b, and selects one of these lines to connect to the LAN 103. It is.

  The control card 10 assigns the same MAC address to the LAN cards 20a and 20b. The MAC address storage unit 30 stores MAC addresses for each slot ID in advance. Here, the same MAC address is stored in the ID column of the slot into which the LAN cards 20a and 20b are inserted. The control card 10 refers to the MAC address stored in the MAC address storage unit 30, and assigns MAC addresses to the LAN cards 20a and 20b.

  A router 104 is installed on the local LAN 103. The router 104 includes a routing table 104a in which a MAC address and its destination port are stored as packet destination mapping data, and is stored in the destination MAC address and routing table 104a stored in the received packet. The port to be transmitted is determined based on the MAC address. For example, when the LAN card 20a is connected to the port A of the router 104, when the packet transmitted from the LAN card 20a passes through the router 104, the router 104 uses the relationship between the port A and the MAC address of the LAN card 20a. Is stored in the routing table 104a. When transmitting a packet to the LAN card 20a, the router 104 transmits a packet whose destination is the MAC address of the LAN card 20a stored in the routing table 104a. When a LAN card whose MAC address is not registered in the routing table 104 is used, it is necessary to update the routing table 104 for the MAC address.

  In the multi-channel Ethernet device of this embodiment, when the communication link is disconnected in the active LAN card 20a, the control card 10 uses the line selection circuit 50 to switch from the LAN card 20a to the standby LAN card. Switch to 20b.

  FIG. 9 schematically shows an operation at the time of switching between the active system and the standby system in the multi-channel Ethernet device shown in FIG. In the example shown in FIG. 9, the communication link on the WAN 102a side is disconnected in the operational LAN card 20a corresponding to the channel CH1. In the line selection circuit 50, the control unit 11 performs switching control from the line of the LAN card 20a to the line of the standby LAN card 20a corresponding to the channel CH2. In the present embodiment, since the same MAC address is assigned to each of the LAN cards 20a and 20b, it is not necessary to update the routing table 104a. Therefore, when switching from the LAN card 20a to the LAN card 20b, the network can be switched with a minimum communication interruption time without waiting for learning of the routing table 104a.

  Note that if the MAC addresses assigned to the LAN cards 20a and 20b are different, since the MAC address of the LAN card 20b is not registered in the routing table 104a when switching from the LAN card 20a to the LAN card 20b, the router 104 cannot perform packet transmission to the LAN card 20b. For this reason, communication is interrupted until the routing table 104a is updated for the MAC address of the LAN card 20b.

  The present invention can be applied to a media converter for connecting a local LAN used by each carrier manufacturer or the like to a wide area LAN network in addition to a multi-channel Ethernet device that can accommodate a plurality of LAN cards.

1 is a block diagram illustrating a schematic configuration of a multi-channel Ethernet device according to a first embodiment of the present invention. It is a block diagram which shows the structure of the LAN card mounted in the multi-channel Ethernet apparatus shown in FIG. It is a block diagram which shows schematic structure of the LAN interface which comprises the LAN card shown in FIG. It is a figure which shows an example of the information stored in the MAC address memory | storage part provided in the multi-channel Ethernet apparatus shown in FIG. It is a flowchart figure which shows one procedure of the MAC allocation process performed in the multi-channel Ethernet apparatus shown in FIG. It is a block diagram which shows schematic structure of the multi-channel Ethernet apparatus which is the 2nd Embodiment of this invention. FIG. 7 is a flowchart showing a procedure of pause frame transmission control performed in the multi-channel Ethernet device shown in FIG. 6. It is a block diagram which shows schematic structure of the multi-channel Ethernet apparatus which is the 3rd Embodiment of this invention. It is a schematic diagram which shows the operation | movement at the time of switching of the active system and a standby system in the multichannel Ethernet apparatus shown in FIG. It is a block diagram which shows the structure of the conventional multi-channel Ethernet apparatus.

Explanation of symbols

1 Device Main Body 10 Control Card 11 Control Unit 20 LAN Card 30 MAC Address Storage Unit 40 Bus

Claims (5)

A plurality of LAN cards for connecting to a network;
An apparatus main body having a plurality of slots into which the plurality of LAN cards are respectively inserted;
A removable control card mounted on the apparatus body,
The apparatus main body includes a MAC address storage unit in which MAC addresses used as unique addresses of the plurality of LAN cards on the network are stored in advance for each slot ID that can identify the plurality of slots,
The control card, for each of said plurality of LAN card, the LAN card based on the slot ID of the inserted slot obtains the MAC address from the MAC address storage unit, the LAN MAC addresses that the acquired This is assigned to the card,
Each of the plurality of LAN cards is
Another MAC address storage unit for storing the MAC address;
A multi-channel network device having a control card interface connected to the control card and storing the MAC address supplied from the control card in the another MAC address storage unit;
The control card supplies a slot ID of a slot in which the LAN card is inserted to each of the plurality of LAN cards,
Each of the plurality of LAN cards is
An interface for sending a packet to which the MAC address stored in the another MAC address storage unit is added to the network;
The MAC address is acquired from the MAC address storage unit based on the slot ID supplied from the control card, and whether or not the acquired MAC address matches the MAC address stored in the another MAC address storage unit A comparison unit for determining whether or not
A multi-channel network device comprising: a packet control unit that permits transmission of a packet by the interface only when the comparison unit determines that the MAC addresses match . When the comparison unit determines that the MAC address does not match, the packet control unit sends a mismatch signal indicating the fact together with the slot ID supplied from the control card through the control card interface. Supply to the card,
When the mismatch signal and the slot ID are supplied from the packet control unit, the control card acquires a corresponding MAC address from the MAC address storage unit based on the slot ID, and uses the acquired MAC address as the mismatch signal. reassign to the output the LAN card, multi-channel network apparatus according to claim 1. One of at least two of the plurality of LAN cards is an active system, and the other is a standby system.
3. The multi-channel network device according to claim 1, wherein the MAC address storage unit stores the same MAC address in association with a slot ID of a slot into which the active and standby LAN cards are respectively inserted. In a network device having a plurality of LAN cards for connecting to a network, a device main body having a plurality of slots into which the LAN cards are respectively inserted, and a removable control card mounted on the device main body. A MAC address assignment method,
As a step performed by the control card,
A MAC address used as a unique address of the plurality of LAN cards on the network refers to a MAC address storage unit stored in advance for each slot ID capable of identifying the plurality of slots;
For each of the plurality of LAN cards, acquiring a MAC address from the MAC address storage unit based on a slot ID of a slot in which the LAN card is inserted, and assigning the acquired MAC address to the LAN card ; ,
Supplying a slot ID of a slot in which the LAN card is inserted to each of the plurality of LAN cards,
As the steps performed by each of the plurality of LAN cards,
Storing the MAC address assigned by the control card in another MAC address storage unit provided in the local LAN card;
Sending a packet to which the MAC address stored in the another MAC address storage unit is added to the network;
Acquiring a MAC address from the MAC address storage unit based on the slot ID supplied from the control card, and comparing the acquired MAC address with a MAC address stored in the another MAC address storage unit; ,
And a step of permitting transmission of the packet only when the MAC addresses match in the comparison . As the steps performed by each of the plurality of LAN cards,
When the MAC address does not match in the comparison, the method further includes a step of supplying a mismatch signal indicating that to the control card together with the slot ID supplied from the control card,
As a step performed by the control card,
When the mismatch signal and the slot ID are supplied, a step of acquiring a MAC address from the MAC address storage unit based on the slot ID and reassigning the acquired MAC address to the LAN card that has output the mismatch signal The MAC address allocation method according to claim 4 , further comprising:

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