JP2015171088A - network relay device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a network relay device which can reflect the change of the network setting on a slave side as well when network setting is changed in a host side.SOLUTION: In a wireless LAN converter 10, the host side is connected to a wireless LAN router 1 and the slave side is connected to a PC 3A and PC 3B. The wireless LAN router 1 has a function of a DHCP server. The wireless LAN converter 10, when connected to the wireless LAN router 1 again after connection to the wireless LAN router 1 is interrupted, cancels wired connection once which is in the slave side, and connection is made once again.

Description

  The present invention relates to a network relay device including a plurality of network communication units.

  Generally, a router has a DHCP server function (see, for example, Patent Document 1). A client device (for example, a wireless LAN converter) connected to the router can perform network communication by being assigned an IP address from a DHCP server.

  When the router changes the IP address on the LAN side, the IP address of the client device is changed. For example, a router having a wireless LAN access point function (hereinafter referred to as a wireless LAN router) has an IP address on the LAN side of 192.168.0.1, and a wireless LAN converter connected to the wireless LAN router Consider a state where an IP address of 192.168.0.2 is assigned.

  Here, the wireless LAN router changes the IP address on the LAN side to 192.168.1.1. Then, the wireless LAN router resets the connection of the LAN port (here, the wireless LAN). Since the wireless LAN converter is reconnected after disconnection from the wireless LAN router, it requests the wireless LAN router for an IP address again. Thereafter, the wireless LAN converter is assigned an IP address of 192.168.1.2, for example, and network communication becomes possible again.

JP 2003-152731 A

  However, when another client device (for example, a PC) is connected to the lower side of the wireless LAN converter, the PC cannot know that the network setting has been changed on the upper side of the wireless LAN converter.

  For example, even if the connection between the wireless LAN converter and the wireless LAN router is interrupted as described above and the IP address is reassigned to the wireless LAN converter, the wired LAN connection is maintained between the PC and the wireless LAN converter. Therefore, the connection between the PC and the wireless LAN converter is not interrupted. Therefore, the PC continues to operate with the IP address as it is, and the network communication cannot be performed.

  That is, when the network setting is changed on the upper side, the lower-level apparatus cannot know that the network setting has been changed, and continues to operate without change.

  Accordingly, an object of the present invention is to provide a network relay device capable of reflecting a change in the network setting on the lower side when the network setting is changed on the upper side.

  The network relay device of the present invention includes a first network communication unit, a second network communication unit, and a control unit that controls the first network communication unit and the second network communication unit.

  Examples of the network relay device include a wireless LAN converter, a router, a wireless LAN access point, a wireless repeater, and a hub.

  The first network communication unit is a higher-level interface (for example, a WAN port), and the second network communication unit is a lower-level interface (for example, a LAN port).

  When the control unit detects that the first network communication unit has been disconnected and then shifts to the connected state, the control unit causes the second network communication unit to disconnect and then shifts to the connected state.

  That is, the control unit releases and reconnects the lower link when the upper link is released and then reconnected. As a result, the lower-level client device is disconnected from the higher-level client device, and re-acquires the IP address. Therefore, when the IP address is changed on the upper side, the change of the IP address can be reflected on the lower side.

  When the control unit shifts to the connected state after disconnecting the second network communication unit, the control unit may transmit a notification signal indicating that fact via the second network communication unit. In this case, it is possible to prompt the lower side to reconnect by a notification signal.

  Note that the network relay device of the present invention detects when the first network communication unit is disconnected and then shifts to the connected state, when the address in the second network communication unit is changed, or when the second network communication unit is disconnected. A mode in which a notification signal indicating that each state has occurred is transmitted via the second network communication unit when at least one of the states occurs when the transmission speed of the network communication unit is changed It is also possible to do.

  For example, a case where the network relay device is a router will be described. When the IP address on the LAN side is changed from 192.168.0.1 to 192.168.1.1, the router transmits a notification signal indicating that the IP address has been changed to the lower side. The client device connected to the lower side can know that the upper side IP address has been changed by receiving the notification signal. Therefore, the lower-level client device can make a request for an IP address.

  Further, when the lower transmission rate is changed, the router transmits a notification signal indicating that the transmission rate has been changed. For example, when the transmission rate of the wired LAN is changed from 100BASE to 10BASE, or when the wireless LAN is changed from IEEE802.11n to IEEE802.11g, 3 streams (3 transmission channels × 3 reception channels) to 2 streams (transmission 2) (Channel × reception 2 channels), etc.

  For example, consider a case where the transmission speed between a router and a wireless LAN access point connected to the router by wire is switched to a low speed 10BASE for power saving. In this case, if the transmission speed between the wireless LAN converter wirelessly connected to the wireless LAN access point and the PC connected by wire to the wireless LAN converter remains 100BASE, the upper side transmits 10BASE. In contrast to the speed, since the transmission speed of 100BASE remains at the lower side, useless power may be consumed. However, according to the present invention, the client device (for example, the wireless LAN converter) that has received the notification signal can know that the transmission rate on the upper side has been changed, and the transmission rate on the lower side of the wireless LAN converter itself can be determined. Can be changed.

  In addition, it is preferable that a control part is transmitted including the information regarding a transmission rate as a notification signal. In this case, when the control unit receives a notification signal including information on the transmission rate from another network relay device, the control unit determines the transmission rate in the second network communication unit based on the information on the transmission rate. Correspond to the transmission speed of other network relay devices. Thus, for example, when the information is changed from 100BASE to 10BASE, the transmission speed in the LAN can be unified to 10BASE by transmitting information including the information changed to 10BASE.

  Note that the notification signal is preferably transmitted by broadcast. By transmitting by broadcast, a notification signal can be transmitted to all devices in the network.

  According to the present invention, when the network setting is changed on the upper side, the change of the network setting can be reflected on the lower side.

It is a block diagram which shows the structure of a network system. It is a block diagram which shows the structure of a wireless LAN router. It is a block diagram which shows the structure of a wireless LAN converter. FIG. 4A is a flowchart showing the operation of the wireless LAN converter, and FIG. 4B is a flowchart showing the operation of the PC 3A. 5A is a flowchart showing the operation of the wireless LAN converter according to the modification, FIG. 5B is a flowchart showing the operation of the PC according to the modification, and FIG. 5 is a flowchart showing the operation of the wireless LAN converter when a notification signal is received. It is a block diagram of the network system which concerns on 2nd Embodiment. It is a block diagram which shows the structure of a wireless repeater. It is a block diagram which shows the structure of a hub. It is a figure which shows a structure in case the hub is connected to the low-order side of the wireless LAN converter. It is a block diagram of the network system which concerns on 3rd Embodiment. It is a block diagram which shows the structure of a router. It is a block diagram which shows the structure of a wireless LAN access point. It is a flowchart which shows operation | movement of the router (wireless LAN router 1 and router 1A) which concerns on an application example. It is a flowchart which shows operation | movement of the network relay apparatus which concerns on another application example.

(First embodiment)
FIG. 1 is a block diagram of a network system according to the first embodiment. The network system in FIG. 1 includes a wireless LAN router 1 connected to the Internet 200, a wireless LAN converter 10 connected wirelessly to the wireless LAN router 1, PC3A and PC3B connected to the wireless LAN converter 10 by wire, It has.

  The wireless LAN router 1 is a network relay device having a wireless LAN access point function and a router function. The wireless LAN router 1 also has a DHCP server function. FIG. 2 is a block diagram showing a configuration of the wireless LAN router 1.

  The wireless LAN router 1 includes a CPU 11, a RAM 12, a flash ROM 13, a wired communication unit (WAN port) 14, a wireless communication unit 15, a display unit 16, and a wired communication unit (LAN port) 17.

  The CPU 11 corresponds to a control unit, expands firmware (program) stored in the flash ROM 13 to the RAM 12 as work memory, and comprehensively controls the operation of the wireless LAN router 1. The CPU 11 realizes the function of the DHCP server by the firmware, and assigns an IP address in response to an IP address request from each terminal.

  The wired communication unit 14 is an interface on the WAN side, and is connected to the Internet 200 via, for example, an ADSL modem, an FTTH line termination device, or the like. In the wireless LAN router 1, the wired communication unit 14 is a higher-order port (in this case, a WAN port).

  The wired communication unit 17 is a lower port (LAN port), and performs data transmission / reception with other devices having a wired communication function in accordance with the standard of the wired LAN. Standards used by the wired communication unit 17 are mainly IEEE802.3i (10BASE-T), IEEE802.3u (100BASE-TX), IEEE802.3ab (1000BASE-T), and the like. Hereinafter, these standard names are simply referred to as 10BASE, 100BASE, 1000BASE, and the like.

  The wireless communication unit 15 includes an antenna and a wireless controller, and performs data transmission and reception with other devices having a wireless communication function in accordance with the wireless LAN standard. In the example of FIG. 1, the wireless communication unit 15 performs data transmission / reception with the wireless LAN converter 10 via a wireless communication function. The wireless communication unit 15 also corresponds to a lower side port (LAN port).

  The standards used by the wireless communication unit 15 are mainly IEEE802.11a, IEEE802.11b, IEEE802.11g, IEEE802.11n, IEEE802.11ac, and the like. Hereinafter, these standard names are simply referred to as 11a, 11b, 11g, 11n, and 11ac.

  Further, the frequencies used by the wireless communication unit 15 mainly include a 5 GHz band (used in 11a, 11n, and 11ac) and a 2.4 GHz band (used in 11b, 11g, and 11n). Also, the wireless communication unit 15 has one stream (one transmission channel × one reception channel) that uses one antenna simultaneously, and two streams (two transmission channels × two reception channels) that use two antennas simultaneously. ), Or parallel processing such as 3 streams (3 transmission channels × 3 reception channels) with three antennas simultaneously used. However, the standard, frequency, and number of channels are examples, and for example, further multi-channel processing is possible.

  The display unit 16 has a display function such as an LED or an LCD. The display unit 16 indicates the current operation state of the wireless LAN router 1. For example, the power on / off state is indicated, the current transmission speed of the wired LAN (1000 BASE, 100 BASE, or 10 BASE) is indicated, or the current use frequency band of the wireless LAN is indicated. To do.

  Next, FIG. 3 is a block diagram showing a configuration of the wireless LAN converter 10. The wireless LAN converter 10 is a network relay device that enables data transmission / reception between a wireless LAN and a wired LAN. As shown in FIG. 3, the wireless LAN converter 10 includes a CPU 21, a RAM 22, a flash ROM 23, a wireless communication unit 24, a wired communication unit 25, and a display unit 26.

  The CPU 21 corresponds to a control unit, expands firmware (program) stored in the flash ROM 23 to the RAM 22 that is a work memory, and comprehensively controls the operation of the wireless LAN converter 10.

  The CPU 21 requests an IP address after a link is established to the wireless LAN router 1 via the wireless communication unit 24. The wireless LAN router 1 assigns an IP address to the wireless LAN converter 10 by the function of the DHCP server. When the IP address is assigned, network communication with the wireless LAN router 1 becomes possible.

  The wireless communication unit 24 includes an antenna and a wireless controller, and performs data transmission / reception with devices having other wireless communication functions in accordance with the wireless LAN standard. The standard used by the wireless communication unit 24 is the same as that of the wireless communication unit 15 in the wireless LAN router 1 described above. In the wireless LAN converter 10, the wireless communication unit 24 is a higher-order port (LAN port).

  The wired communication unit 25 performs data transmission / reception with other devices having a wired communication function according to the standard of the wired LAN. The standard used by the wired communication unit 25 is 10BASE, 100BASE, or 1000BASE. In the wireless LAN converter 10, the wired communication unit 25 is a lower port (LAN port). PC 3A and PC 3B are connected to the wired communication unit 25.

  The PC 3A and the PC 3B are general personal computers, respectively, and detailed illustration of the configuration and description of the operation are omitted. The PC 3A and PC 3B are assigned an IP address by making a request for an IP address to the wireless LAN router 1 via the wireless LAN converter 10. As a result, the PC 3A and the PC 3B can perform network communication.

  In this example, the wireless LAN converter 10 corresponds to the network relay device of the present invention, the wireless communication unit 24 corresponds to the first network communication unit in the present invention, and the wired communication unit 25 corresponds to the second network communication device in the present invention. Corresponds to the network communication unit.

  The wireless LAN converter 10 is reconnected after releasing the connection of the wired communication unit 25 that is a lower-order port when the connection of the wireless communication unit 24 that is a higher-order port is disconnected and then shifts to a connected state. To do. As a result, when the connection between the wireless LAN router 1 and the wireless LAN converter 10 is canceled because the IP address on the LAN side of the wireless LAN router 1 is changed, the IP address is reacquired to the PC 3A and PC 3B. Can be made.

  FIG. 4A is a flowchart showing the operation of the wireless LAN converter 10 (CPU 21). FIG. 4B is a flowchart showing the operation of PC3A and PC3B.

  As shown in FIG. 4A, the wireless LAN converter 10 (CPU 21) determines whether there is a wireless LAN link which is a higher-order port (s11). This determination is repeated until the wireless LAN link is disconnected. When it is determined that the wireless LAN link has been released and the connection with the wireless LAN router 1 has been disconnected, it waits until the next wireless LAN is reconnected (s12).

  Then, when the wireless LAN is reconnected, the CPU 21 releases the link of the wired LAN, which is the lower port, and reconnects (s13). When the wireless LAN is reconnected, the CPU 21 requests the wireless LAN router 1 for an IP address and reacquires the IP address.

  On the other hand, as shown in FIG. 4B, the PC 3A and the PC 3B determine whether or not the wired LAN is connected (s21). This determination is repeated until the wired LAN is disconnected. If it is determined that the wired LAN has been disconnected, it waits until the next wired LAN is reconnected (s22). Then, when the wired LAN is reconnected, the PC 3A and the PC 3B request an IP address and reacquire the IP address (s23). Such an operation in the wired LAN with the PC 3A and the PC 3B and the PC 3B is realized by a function installed in a general OS.

  As a result, when the wireless LAN router 1 and the wireless LAN converter 10 are reconnected after the connection between the wireless LAN router 1 and the wireless LAN converter 10 is reconnected, the PC 3A and the PC 3B reacquire the IP address, and the upper IP address is changed. In this case, the IP address can be changed on the lower side. For example, when the IP address on the LAN side of the wireless LAN router 1 is changed from 192.168.0.1 to 192.168.1.1, the wireless LAN converter 10 temporarily disconnects from the wireless LAN router 1. Therefore, the IP address is reacquired and, for example, an IP address of 192.168.1.2 is assigned. At this time, since the lower-level PC 3A and PC 3B are also temporarily disconnected from the wireless LAN converter 10, they acquire IP addresses again, for example, 192.168.1.3 and 192.168.8.1. 4 IP addresses are assigned. Thereby, network communication is also possible in the PC 3A and the PC 3B.

  If the wireless LAN router 1 described above is a mobile router (the WAN side is wireless: mobile communication), IP address contention may occur. For example, when the PC 3B is a mobile PC and the IP address of 192.168.0.2 is assigned to the PC 3A and the IP address of 192.168.0.3 is assigned to the PC 3B at home, When reconnected to the router, an IP address of 192.168.0.2 may be assigned to PC3B, which is a mobile PC. At home, since the connection with the wireless LAN converter 10 is maintained, the IP address of 192.168.0.2 is maintained in the PC 3A. Therefore, the IP address of PC3A and the IP address of PC3B overlap with each other. Also in this case, with the wireless LAN converter 10 of the present embodiment, when the mobile router is brought home, the connection between the PC 3A and the wireless LAN converter 10 is released and then reconnected. IP address conflict does not occur.

  Next, FIG. 5A is a flowchart showing the operation of the wireless LAN converter 10 (CPU 21) according to the modification. The same operations as those in FIG. 4A are denoted by the same reference numerals, and description thereof is omitted. FIG. 5B is a flowchart showing operations of the PC 3A and PC 3B according to the modification.

  As shown in FIG. 5A, when the wireless LAN is reconnected, the wireless LAN converter 10 (CPU 21) transmits a notification signal via the wired communication unit 25, which is a lower port (s33). . In this example, the notification signal includes information indicating that the connection has been reconnected after the upper link is released. The notification signal is preferably transmitted by broadcast to the entire network.

  As shown in FIG. 5B, when receiving a notification signal from another network relay device (wireless LAN converter 10) (s41), the PC 3A and the PC 3B request an IP address and reacquire the IP address. (S42). Such an operation can be realized by an operation of an application program, a driver or the like installed in the PC 3A and the PC 3B.

  Even in the above manner, when the IP address on the upper side is changed, the IP address can be changed also on the lower side. Note that, when the wireless LAN is reconnected, the wireless LAN converter 10 may release the link of the wired LAN, which is the lower port, and transmit a notification signal while reconnecting.

  In the above-described example, the wireless LAN converter 10 corresponds to the network relay device of the present invention. However, the wireless LAN router 1 can perform an operation corresponding to the network relay device of the present invention.

  For example, when the wireless LAN router 1 is reconnected after the connection of the upper wired communication unit 14 is released, the wireless LAN router 1 releases the connection of the lower wireless communication unit 15 and then reconnects the Side network can be reset. Also, when the wireless LAN router 1 is reconnected after the connection of the higher-level wired communication unit 14 is released, the wireless LAN router 1 passes through the lower-level wireless communication unit 15 as shown in FIG. The network on the LAN side can also be reset by sending a notification signal. In this case, as shown in FIG. 5B, the wireless LAN converter 10 connected to the lower side makes a request for an IP address and reacquires the IP address. Further, as shown in FIG. 5C, when the wireless LAN converter 10 receives the notification signal (s51), the wireless LAN converter 10 releases the link of the wired LAN, which is the lower port, and reconnects (s52). May be performed. As a result, the lower-level PC 3A and PC 3B make a request for an IP address and reacquire the IP address.

(Second Embodiment)
Next, FIG. 6 is a block diagram of a network system according to the second embodiment. The same components as those in FIG. 1 are denoted by the same reference numerals, and detailed description thereof is omitted. The network system in FIG. 6 further includes a wireless repeater 100 that is wirelessly connected to the wireless LAN router 1 and a hub 250 that is connected to the wireless LAN router 1 by wire.

  FIG. 7 is a block diagram showing a configuration of the wireless repeater 100. The wireless repeater 100 includes a CPU 31, a RAM 32, a flash ROM 33, a wireless communication unit 34, and a display unit 36.

  The CPU 31 corresponds to a control unit, and develops firmware (program) stored in the flash ROM 33 in the RAM 32 that is a work memory, and comprehensively controls the operation of the wireless repeater 100.

  The CPU 31 is connected to the wireless LAN router 1 through the wireless communication unit 34 and is also connected to the PC 3C through the wireless communication unit 34. The wireless repeater 100 is a wireless relay device that simultaneously performs a function as a master unit and a slave unit of a wireless LAN. Thus, the wireless repeater 100 relays wireless communication between the wireless LAN router 1 and the PC 3C via the wireless communication unit 34. Note that the wireless LAN router 1 and the wireless LAN converter 10 can also realize the same function as the wireless repeater 100 by software operation.

  Note that the CPU 31 in the wireless repeater 100 according to the present embodiment has a DHCP client function for making an IP address request to the wireless LAN router 1 and acquiring an IP address when an upper port is connected.

  Also with such a wireless repeater 100, the operation of the network relay device of the present invention can be realized. That is, when the wireless repeater 100 is reconnected after the connection with the wireless LAN router 1 that is the upper port is released, the wireless repeater 100 releases the connection with the PC 3C that is the lower port and reconnects. As a result, when the wireless LAN router 1 and the wireless repeater 100 are reconnected after the connection between the wireless LAN router 1 and the wireless repeater 100 is reconnected, the PC 3C performs reacquisition of the IP address. The IP address can also be changed on the lower side.

  FIG. 8 is a block diagram showing the configuration of the hub 250. The hub 250 includes a CPU 41, a RAM 42, a flash ROM 43, a wired communication unit (LAN port) 44, a display unit 46, and a wired communication unit (LAN port) 47.

  The CPU 41 corresponds to a control unit, expands firmware (program) stored in the flash ROM 43 to the RAM 42 as work memory, and comprehensively controls the operation of the hub 250.

  The CPU 41 is connected to the wired communication unit (LAN port) 17 of the wireless LAN router 1 through the wired communication unit 44 and is also connected to the PC 3D and PC 3E through the wired communication unit 47. The hub 250 is a wired LAN relay machine, and has a switching function in this example.

  Note that the CPU 41 in the hub 250 of the present embodiment has a DHCP client function for making an IP address request to the wireless LAN router 1 and acquiring an IP address when an upper port is connected.

  The operation of the network relay device of the present invention can also be realized with such a hub 250. That is, when the hub 250 is reconnected after being disconnected from the wireless LAN router 1 by the wired communication unit 44 that is the upper port, the PC 3D and PC3E by the wired communication unit 47 that is the lower port. Disconnect from and reconnect. Thus, when the PC 3D and PC 3E are reconnected after the connection between the wireless LAN router 1 and the hub 250 is released, the IP address is reacquired, and the upper IP address is changed. In addition, the IP address can be changed on the lower side.

  For example, the detection of the disconnection of the upper port in the hub 250 may be performed as follows. When the hub 250 detects disconnection of any of the ports, the hub 250 transmits a confirmation signal such as Ping toward the default gateway address (LAN side IP address of the router device) to all the connected ports. When there is a response to the confirmation signal, the hub 250 determines that the connection of the upper port is maintained, and when there is no response, the hub 250 determines that the connection of the upper port is released.

  Also, even when the hub 250 detects the connection of any of the ports, the hub 250 transmits a confirmation signal such as Ping to the default gateway address (LAN side IP address of the router device) to all the ports in the connected state. When there is a response to the confirmation signal, it may be determined that the upper port is connected, and when there is no response, the upper port is not connected. The hub 250 may be configured to store identification information (for example, a port number) of a port that has responded in a storage unit such as the RAM 42 or the flash ROM 43. In this case, after determining the higher port, it is not necessary to perform the above determination every time a port other than the higher port is disconnected and connected. Of course, the same operation may be performed not only in the hub 250 but also in other network relay apparatuses.

  Note that the wireless repeater 100 and the hub 250 may also transmit a notification signal as shown in FIG. Further, when the wireless repeater 100 and the hub 250 receive a notification signal from another network relay device, the wireless repeater 100 and the hub 250 perform the operation of releasing the link of the lower side port and reconnecting as shown in FIG. You may go. Accordingly, for example, as shown in FIG. 9, even when the hub 250 is connected to the lower side of the wireless LAN converter 10, the notification signal transmitted from the wireless LAN converter 10 causes the hub 250 to be connected to the lower level wired LAN. Therefore, the PC 3D and the PC 3E connected to the hub 250 request an IP address and reacquire the IP address.

(Third embodiment)
Next, FIG. 10 is a block diagram of a network system according to the third embodiment. The components common to those in FIG. 6 are denoted by the same reference numerals, and detailed description thereof is omitted. The network system in FIG. 10 further includes a router 1A connected to the Internet 200, and a wireless LAN access point 50 connected to the router 1A by wire instead of the wireless LAN router 1. Wireless LAN converter 10 and wireless repeater 100 are wirelessly connected to wireless LAN access point 50. The hub 250 is connected to the router 1A by wire.

  FIG. 11 is a block diagram showing a configuration of the router 1A. The router 1A is obtained by omitting the configuration and function of the wireless communication unit 15 from the wireless LAN router 1 shown in FIG. Therefore, the operation of the network relay device of the present invention can be realized also in the router 1A.

  FIG. 12 is a block diagram showing the configuration of the wireless LAN access point 50. The wireless LAN access point 50 includes a CPU 51, a RAM 52, a flash ROM 53, a wireless communication unit 54, a wired communication unit 55, and a display unit 56.

  The CPU 51 corresponds to a control unit, expands firmware (program) stored in the flash ROM 53 to the RAM 52 as work memory, and comprehensively controls the operation of the wireless LAN access point.

  The CPU 51 is connected to the wired communication unit (LAN port) 17 of the router 1 </ b> A via the wired communication unit 55 and is also connected to the wireless LAN converter 10 and the wireless repeater 100 via the wireless communication unit 54.

  Note that the CPU 51 in the wireless LAN access point 50 according to the present embodiment has a DHCP client function for making an IP address request to the wireless LAN router 1 and acquiring an IP address when an upper port is connected.

  Also for the wireless LAN access point 50, the operation of the network relay device of the present invention can be realized. That is, when the wireless LAN access point 50 is reconnected after the connection with the router 1A by the wired communication unit 55 that is a higher-order port is released, Disconnect the device (wireless LAN converter 10 and wireless repeater 100) and reconnect. In order to cancel the connection with another device, the wireless connection itself with each device may be temporarily canceled or may be restarted after the operation of the wireless communication unit 54 is stopped. Since the wireless LAN converter 10 and the wireless repeater 100 are reconnected after the connection with the higher-order side is released, they are reconnected after the connection with the lower-order PC is released. As a result, when the upper IP address is changed, the lower PC can also change the IP address.

  The wireless LAN access point 50 may also transmit a notification signal as shown in FIG. When the wireless LAN access point 50 receives a notification signal from another network relay device, the wireless LAN access point 50 performs an operation of releasing the link of the lower port and reconnecting it, as shown in FIG. 5C. May be.

  Next, FIG. 13 is a flowchart showing the operation of routers (wireless LAN router 1 and router 1A) according to the application example. Generally, routers (wireless LAN router 1 and router 1A) can change the IP address on the LAN side. Here, the operation when the IP address on the LAN side of the router 1A is changed will be described with reference to the router 1A of FIG.

  As shown in FIG. 13A, when the IP address on the LAN side of the router 1A is changed (s61), the router 1A notifies the port on the lower side that the IP address of the router 1A has been changed. A signal is transmitted (s62). This notification signal is also preferably transmitted by broadcast. Generally, when the IP address on the LAN side is changed, the router releases the link on the lower side and reconnects. In this example, the router transmits a notification signal indicating that the IP address has been changed. As shown in FIG. 9, the notification signal is first transmitted to the hub 250 and the wireless LAN access point 50.

  When each lower-level device receives a notification signal indicating that the IP address has been changed from the router 1A, it requests the IP address and reacquires the IP address, as shown in FIG. 5B. Further, as shown in FIG. 5C, when each lower-level device receives a notification signal indicating that the IP address has been changed, the lower-level port link of the own device is released and reconnected. Perform the action. As a result, for example, the PC 3D and PC 3E connected to the hub 250 make a request for an IP address and reacquire the IP address. In addition, the wireless LAN converter 10 and the wireless repeater 100 connected to the wireless LAN access point 50 also request an IP address, reacquire the IP address, and cancel the link of the lower port, In order to reconnect, the PC 3A, PC 3B, and PC 3C also request an IP address and reacquire the IP address.

  Next, FIG. 14A is a flowchart showing the operation of the network relay device according to another application example. The operation of the network relay device in this example is performed by any one of the above-described wireless LAN router 1, router 1A, wireless LAN converter 10, wireless repeater 100, hub 250, or wireless LAN access point 50. Here, as a representative, the wireless LAN router 1 in FIG. 6 will be described.

  As shown in FIG. 14A, when the transmission speed of the lower port is changed (s81), the wireless LAN router 1 transmits a notification signal indicating that the transmission speed has been changed (s82). This notification signal is also preferably transmitted by broadcast.

  The case where the transmission speed is changed includes, for example, a case where the wired LAN is changed from 100BASE to 10BASE, a case where the wireless LAN is changed from 11n to 11g, a case where the stream is changed from 3 streams to 2 streams, and the like. Or, conversely, when the wired LAN is changed from 10BASE to 100BASE, when the wireless LAN is changed from 11g to 11n, when the stream is changed from 2 streams to 3 streams, and so on. The notification signal preferably includes information indicating the state after the change (100BASE, 11g, 2 streams, etc.) as information on the transmission rate.

  Taking the configuration of FIG. 6 as an example, the wireless LAN router 1 is connected to the wireless LAN converter 10 and the wireless repeater 100 when the transmission speed with the hub 250 is switched to low speed 10BASE for power saving. , A notification signal indicating that the wired LAN has been changed to 10BASE is transmitted.

  As shown in FIG. 14B, when each lower-level device receives a notification signal indicating that the transmission rate has been changed from the wireless LAN router 1 (s91), it responds to the change in the higher-level transmission rate. Then, the transmission speed of the own device is changed (s92). For example, in the example of FIG. 6, when the wireless LAN router 1 changes the wired LAN from 100BASE to 10BASE, the wireless LAN converter 10 changes the connection of the wired LAN with the PC 3A and PC 3B to 10BASE. As a result, the transmission speed in the LAN can be unified to 10BASE, and wasteful power consumption is prevented.

  Further, the wireless LAN router 1 may switch the transmission speed with the hub 250 to 100BASE or 1000BASE when transmitting / receiving a large amount of data. Also in this case, a notification signal indicating that the wired LAN has been changed to 100BASE or 1000BASE is transmitted to the wireless LAN converter 10 and the wireless repeater 100. Therefore, the transmission speed in the LAN can be returned to 100BASE or 1000BASE, and the bottleneck of data transfer can be eliminated.

1 ... Wireless LAN router 1A ... Routers 3A, 3B, 3C, 3D, 3E ... PC
DESCRIPTION OF SYMBOLS 10 ... Wireless LAN converter 50 ... Wireless LAN access point 100 ... Wireless repeater 200 ... Internet 250 ... Hub

Claims (8)

A first network communication unit;
A second network communication unit;
A control unit for controlling the first network communication unit and the second network communication unit;
A network relay device comprising:
When the control unit detects that the first network communication unit is disconnected after being disconnected,
A network relay device that shifts to a connected state after disconnecting the second network communication unit.   The said control part transmits the notification signal which shows having changed into the connection state after disconnecting the said 2nd network communication part via the said 2nd network communication part. Network relay device. A first network communication unit;
A second network communication unit;
A control unit for controlling the first network communication unit and the second network communication unit;
A network relay device comprising:
When the control unit detects that the first network communication unit is disconnected and then shifts to a connected state, when the address in the second network communication unit is changed, or in the second network communication unit When at least one of the following conditions occurs when the transmission speed is changed:
A network relay device, wherein a notification signal indicating that each state has occurred is transmitted via the second network communication unit.   4. The network relay device according to claim 3, wherein, when the transmission rate in the second network communication unit is changed, the control unit transmits information about the transmission rate as the notification signal. 5.   When the control unit receives the notification signal from another network relay device, the control unit shifts to a connected state after disconnecting the second network communication unit based on the notification signal, or the second network The network relay device according to claim 3 or 4, wherein a transmission rate in the communication unit is changed.   6. The network relay device according to claim 2, wherein the notification signal is transmitted by broadcast.   The network relay device according to claim 1, comprising a DHCP server function.   8. The network relay device according to claim 1, wherein both or either one of the first network communication unit and the second network communication unit is a wireless communication unit. 9.

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