JP2011135607A - Wireless lan device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To automate the setting of an operation mode in a wireless LAN device available as a wireless slave unit as well as a wireless master unit by switching the setting of the operation mode. <P>SOLUTION: The wireless LAN device 10 includes a packet transmission control unit 102 including a function of transmitting a DHCPDISCOVER packet to a wired device from a LAN switch 130 at the time of startup and a function of allowing an RF device 140 to transmit a probe request packet to other wireless LAN devices via an antenna 150, a first startup control unit 104 for setting the operation mode of the wireless LAN device 10 so that the wireless LAN device 10 operates as an access point at reception of a DHCPOFFER packet, and a second startup control unit 106 for setting the operation mode of the wireless LAN device 10 so that the wireless LAN device 10 operates as a client at reception of a probe response packet. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a wireless LAN device.

  With the spread of the Internet, various network devices that can be connected to a network such as a LAN (Local Area Network) have become popular. Such network devices include a wired network device wired to the network and a wireless network device wirelessly connected to the network.

  In recent years, wireless LAN devices that relay communication between wired network devices and wireless network devices have become widespread. This wireless LAN device includes a wired communication device for communicating with a wired network device and a wireless communication device for communicating with the wireless network device. As such a wireless LAN device, for example, in a wireless LAN, an access point (bridge) that functions as a so-called wireless master device or a wireless LAN converter that functions as a so-called wireless slave device (client) (for example, an Ethernet converter ( “Ethernet” is a registered trademark)). Furthermore, wireless LAN devices that can be used as both wireless master devices and wireless slave devices by switching operation mode settings have become widespread (for example, see Non-Patent Document 1 below).

BUFFALO Product Information> Network> Wireless LAN> Wireless LAN cordless handset, Internet <URL: http: //buffalo.jp/products/catalog/network/wli-uc-g/>

  By the way, in the wireless LAN apparatus that can be used as both the wireless master device and the wireless slave device described above, the user needs to switch the setting of the operation mode. For this reason, for a user who is unfamiliar with the wireless LAN device, the setting including the operation mode switching is complicated or difficult for the above-described wireless LAN device. Further, even a user who is familiar with the wireless LAN device may make a mistake in the contents of the above settings. Therefore, it has been required to automate the setting of the wireless LAN device described above.

  The present invention has been made to solve the above-described problems. By switching the operation mode setting, the operation mode setting of a wireless LAN device that can be used as both a wireless master device and a wireless slave device is automated. The purpose is to do.

  SUMMARY An advantage of some aspects of the invention is to solve at least a part of the problems described above, and the invention can be implemented as the following forms or application examples.

  Application Example 1 A wireless LAN device that is wired to a first network device and wirelessly connected to a second network device and relays communication between the first network device and the second network device. A wired communication device for communicating with the first network device; a wireless communication device for communicating with the second network device; and the wireless LAN device as a wireless LAN access point or client. A control unit that controls the operation of the wireless LAN device so as to operate, and the control unit transmits a DHCPDISCOVER packet from the wired communication device to the first network device at a predetermined timing. And transmitting a probe request packet from the wireless communication device to the second network device. When the packet transmission control unit having a function and the wired communication device receive a DHCPOFFER packet from the first network device as a response to the DHCPDISCOVER packet, the wireless LAN device operates as the access point. In addition, the first operation control unit capable of controlling the operation of the wireless LAN device and the wireless communication device receive a probe response packet from the second network device as a response to the probe request packet. A wireless LAN device comprising: a second operation control unit capable of controlling an operation of the wireless LAN device so that the wireless LAN device operates as the client.

  When the first network device is a network device having a function of a dynamic host configuration protocol (DHCP) server, the first network device receives a DHCPDISCOVER packet as a response thereto. The DHCPOFFER packet is returned to the wireless LAN device that is the transmission source of the DHCPDISCOVER packet. On the other hand, when the first network device is a network device that does not have a DHCP server function, even if the first network device receives the DHCPDISCOVER packet, the wireless LAN that is the transmission source of the DHCPDISCOVER packet A DHCPOFFER packet cannot be returned to the device. Further, when the second network device is an access point (wireless master), when the second network device receives the probe request packet, the wireless LAN that is the source of the probe request packet is returned as a response. A probe response packet is returned to the apparatus. On the other hand, when the second network device is not an access point (wireless master), the second network device probes the wireless LAN device that is the source of the probe request packet even if it receives the probe request packet. Response packet cannot be returned.

  In the wireless LAN device of Application Example 1, when a DHCPOFFER packet is received from the first network device as a response to the DHCPDISCOVER packet, a network device having a DHCP server function is connected to the wireless LAN device. Will be. In this case, in the wireless LAN device of Application Example 1, the first operation control unit is configured in the access point mode (wireless master mode) so that the wireless LAN device operates as an access point (wireless master device). The operation of the wireless LAN device can be controlled. Further, in the wireless LAN device of Application Example 1, when a probe response packet is received from the second network device as a response to the probe request packet, an access point (wireless master) already exists in the wireless LAN. Will be. In this case, in the wireless LAN device according to Application Example 1, the second operation control unit performs wireless LAN in client mode (wireless slave mode) so that the wireless LAN device operates as a client (wireless slave). The operation of the device can be controlled. Therefore, in the wireless LAN device of the application example 1, it is not necessary for the user to set an operation mode for operating the wireless LAN device as a wireless master device or a wireless slave device. That is, with the wireless LAN device of this application example, the operation mode setting of the wireless LAN device that can be used as both a wireless master device and a wireless slave device can be automated by switching the operation mode setting. Note that, as described above, the wireless LAN device of this application example automates the setting of the operation mode and avoids an artificial setting of the operation mode, so in particular, one wireless master device (access point) ) And a plurality of wireless slave devices (clients), it is effective when constructing a star type wireless LAN.

  Application Example 2 The wireless LAN device according to Application Example 1, wherein the predetermined timing is when the wireless LAN device is activated.

  In the wireless LAN device according to the application example 2, when the wireless LAN device is activated, the operation mode of the wireless LAN device can be automatically set regardless of the user's setting work.

  Application Example 3 The wireless LAN device according to Application Example 1 or 2, wherein the wired communication device receives the DHCPOFFER packet as a response to the DHCPDISCOVER packet, and the wireless communication device receives the probe request. When the probe response packet is received as a packet response, the second operation control unit does not control the operation of the wireless LAN device so that the wireless LAN device operates as the client. A wireless LAN device, wherein the operation control unit 1 controls the operation of the wireless LAN device so that the wireless LAN device operates as the access point.

  The wireless LAN device receives the DHCPOFFER packet when the first network device wired to the wireless LAN device is the first network device having a DHCP server function. When the user of the wireless LAN device connects the first network device to the wireless LAN device, the user can renew the wireless LAN device even if an access point already exists in the wireless LAN. It is thought that it has the intention to use it as a secure access point (wireless master unit). In the wireless LAN device according to the application example 3, the above-described user intention can be reflected.

  Application Example 4 In the wireless LAN device according to any one of Application Examples 1 to 3, the packet transmission control unit performs transmission of the DHCPDISCOVER packet and transmission of the probe request packet in parallel. Wireless LAN device.

  In the wireless LAN device according to the application example 4, the time required for setting the operation mode of the wireless LAN device can be shortened as compared with the case where the transmission of the DHCPDISCOVER packet and the transmission of the probe request packet are performed in series.

  Application Example 5 In the wireless LAN device according to any one of Application Examples 1 to 3, the packet transmission control unit performs transmission of the DHCPDISCOVER packet and transmission of the probe request packet in one packet. A wireless LAN device that performs transmission of the other packet after transmission.

  In the wireless LAN device according to the application example 5, the load per unit time of the control unit can be reduced as compared with the case where the transmission of the DHCPDISCOVER packet and the transmission of the probe request packet are performed in parallel.

  Application Example 6 The wireless LAN device according to Application Example 5, wherein the packet transmission control unit transmits the probe request packet after transmitting the DHCPDISCOVER packet.

  In the wireless LAN device of Application Example 6, when a DHCPOFFER packet is received as a response to the transmission of the DHCPDISCOVER packet, the process of transmitting the probe request packet is omitted, and the wireless LAN device is activated as an access point. Can do. Therefore, the time required for setting the operation mode of the wireless LAN device can be shortened.

  [Application Example 7] The wireless LAN device according to Application Example 6, wherein the control unit further includes another packet that exists in the wireless LAN before the packet transmission control unit transmits the probe request packet. A beacon detection unit that detects a beacon packet transmitted from a wireless LAN device by passive scan, and the second operation control unit has the same SSID (Service Set ID) as the own device by the beacon detection unit. When a beacon packet is detected, it recognizes that there is another base unit, and without transmitting the probe request packet by the packet transmission control unit and receiving the probe response packet by the wireless communication device, A wireless LAN device that controls the operation of the wireless LAN device so that the LAN device operates as the client. .

  Generally, in a wireless LAN device, radio waves in various frequency bands can be used for wireless communication. However, in order to prevent radio wave interference, frequency bands (for example, W53 and W56) that are preferentially used by various radars such as marine radars for ships, aircrafts, and military use, and fixed radars for weather are used in the wireless LAN. When used for wireless communication, there may be certain restrictions. Under such an environment, the wireless LAN device needs to avoid transmitting the probe request packet by using the above-described radio waves in an unusable frequency band. Further, there may be a case where the wireless LAN device cannot transmit the probe request packet to another wireless LAN device due to other reasons.

  In the wireless LAN device according to the application example 7, prior to the transmission of the probe request packet, the wireless LAN device has already detected the beacon packet having the same SSID as that transmitted from another wireless LAN device existing in the wireless LAN. It can be recognized that there is a wireless master for the own device in the LAN. Then, when detecting the beacon packet, the wireless LAN device of this application example operates as a client (wireless slave) without transmitting a probe request packet and receiving a probe response packet. That is, the wireless LAN device of this application example does not transmit a probe request packet. Therefore, it is possible to avoid transmitting the probe request packet using the above-described radio waves in an unusable frequency band. In addition, the wireless LAN device according to this application example can operate as a wireless slave device by detecting a beacon packet even when a probe request packet cannot be transmitted to another wireless LAN device.

  [Application Example 8] The wireless LAN device according to Application Example 6, wherein the control unit further includes another packet that exists in the wireless LAN before the packet transmission control unit transmits the probe request packet. A beacon detection unit that detects a beacon packet transmitted from a wireless LAN device by a passive scan, and the packet transmission control unit transmits the probe request packet after the beacon packet is detected by the beacon detection unit. And the second operation control unit, when receiving the probe response packet, controls the operation of the wireless LAN device so that the wireless LAN device operates as the client.

  As in Application Example 7, when various radars use frequency bands such as W53 and W56, the wireless LAN device cannot transmit radio waves in the corresponding frequency band. It is necessary to perform detection. However, for example, when there are a plurality of wireless master units in the wireless LAN, the beacon detection unit detects a plurality of beacon packets in order to detect a beacon packet having the same SSID as the own device. In this case, in the procedure of CSMA / CA (Carrier Sense Multiple Access / Collision Avoidance) for preventing collision (signal collision), the beacon detection unit transmits a wireless master device having the same SSID as the wireless LAN device. It takes time to detect the beacon packet. Furthermore, it takes time to identify the SSID included in each beacon packet detected by the beacon detector. In addition, even if the beacon detection unit detects a beacon packet, if the wireless master device that has transmitted the beacon packet is a wireless master device configured to reject an Any connection, the beacon packet includes an SSID. Is not included, it is impossible to identify whether the wireless master device has the same SSID as the wireless LAN device.

  In the wireless LAN device according to the application example 8, when at least one beacon packet is detected, it is determined that there is a possibility that the parent device that is the transmission source of the beacon packet is a wireless parent device for the own device. The probe request packet is transmitted and the probe response packet is received without analyzing the packet, and when the probe response packet is received, it operates as a client (wireless slave). Therefore, the above-described waiting time and the time required for identifying the SSID included in the beacon packet can be shortened. Even if the wireless master device is set to reject the Any connection, it can be connected.

  The present invention can also be configured as a wireless LAN device control method invention in addition to the above-described configuration as a wireless LAN device. Further, the present invention can be realized in various modes such as a computer program that realizes these, a recording medium that records the program, and a data signal that includes the program and is embodied in a carrier wave. In addition, in each aspect, it is possible to apply the various additional elements shown above.

  When the present invention is configured as a computer program or a recording medium on which the program is recorded, the entire program for controlling the operation of the wireless LAN device may be configured, or only the part that performs the functions of the present invention is configured. It is good also as what to do. Recording media include flexible disks, CD-ROMs, DVD-ROMs, magneto-optical disks, IC cards, ROM cartridges, printed matter printed with codes such as barcodes, computer internal storage devices (such as RAM and ROM). A variety of computer-readable media such as a memory) and an external storage device can be used.

It is explanatory drawing which shows schematic structure of the network system 1000 to which the wireless LAN apparatus as one Example of this invention is applied. 2 is an explanatory diagram showing a schematic configuration of a wireless LAN device 10. FIG. It is a flowchart which shows the flow of a starting control process of the wireless LAN apparatus 10 of 1st Example. It is a flowchart which shows the flow of a starting control process of the wireless LAN apparatus 10 of 2nd Example. It is explanatory drawing which shows schematic structure of the wireless LAN apparatus 10B of 3rd Example. It is a flowchart which shows the starting control processing flow of wireless LAN apparatus 10B in 3rd Example. It is a flowchart which shows the flow of a starting control process of the wireless LAN apparatus 10B in 4th Example.

Hereinafter, embodiments of the present invention will be described based on examples.
A. First embodiment:
A1. Network system configuration:
FIG. 1 is an explanatory diagram showing a schematic configuration of a network system 1000 to which a wireless LAN device as an embodiment of the present invention is applied. As shown in the figure, in the network system 1000 of this embodiment, the Internet INT and the wireless LAN are connected via a router 20RT. The router 20RT returns a DHCPOFFER packet including an IP address to the source of the DHCPDISCOVER packet as a response to the function of a DHCP (Dynamic Host Configuration Protocol) server, that is, for example, when receiving a DHCPDISCOVER packet. And has a function of assigning an IP address.

  In network system 1000, the wireless LAN includes an access point 10AP connected to the router 20RT via a LAN cable CAB, and Ethernet converters 10ECa, 10ECb, and 10ECc. The Ethernet converters 10ECa, 10ECb, and 10ECc are connected to a television receiver 20a, a personal computer (PC) 20b, and a printer 20c via a LAN cable CAB, respectively. Each of the television receiver 20a, personal computer (PC) 20b, and printer 20c is a device that includes a wired communication device including a LAN port and can be connected to a network. Further, the access point 10AP and the Ethernet converters 10ECa, 10ECb, 10ECc are wirelessly connected. The number of these various devices can be arbitrarily set.

  The Ethernet converters 10ECa, 10ECb, and 10ECc convert the wired packets received from the television receiver 20a, the personal computer 20b, and the printer 20c into wireless packets, and transmit the wireless packets to the access point 10AP. In addition, the Ethernet converters 10ECa, 10ECb, and 10ECc convert wireless packets received from the access point 10AP into wired packets and transmit them to the television receiver 20a, the personal computer 20b, and the printer 20c, respectively.

  In the present embodiment, as will be described later, the access point 10AP and the Ethernet converters 10ECa, 10ECb, 10ECc have the same configuration. These are wireless LAN devices that can be used as both a wireless master device (access point) and a wireless slave device (client) by switching operation mode settings. These correspond to the wireless LAN device in [Means for Solving the Problems]. Hereinafter, the access point 10AP and the Ethernet converters 10ECa, 10ECb, and 10ECc are collectively referred to as a wireless LAN device 10. Hereinafter, the router 20RT, the television receiver 20a, the personal computer 20b, and the printer 20c are collectively referred to as a wired device 20 as well.

  When the access point 10AP is recognized as a wireless LAN device in [Means for Solving the Problems], the router 20RT corresponds to the first network device in [Means for Solving the Problems], and the Ethernet converters 10ECa and 10ECb. , 10ECc corresponds to the second network device. Further, when the Ethernet converters 10ECa, 10ECb, and 10ECc are grasped as wireless LAN devices in [Means for Solving the Problems], the television receiver 20a, the personal computer 20b, and the printer 20c are respectively [for solving the problems]. Means] corresponds to the first network device, and the access point 10AP corresponds to the second network device.

A2. Configuration of wireless LAN device:
FIG. 2 is an explanatory diagram showing a schematic configuration of the wireless LAN device 10. As illustrated, the wireless LAN device 10 includes a CPU 100, a ROM 110, a RAM 120, a LAN switch 130, an RF device 140, and an antenna 150. Although not shown, the wireless LAN device 10 also has a function of dynamic frequency selection (DFS).

  The LAN switch 130 includes a plurality of LAN ports 132, to which a LAN cable CAB is connected. The LAN switch 130 communicates with the connected wired device 20 via the LAN cable CAB. The LAN switch 130 corresponds to a wired communication device in [Means for Solving the Problems]. The wireless LAN device 10 of the present embodiment includes the LAN switch 130 including a plurality of LAN ports 132, but instead of this, a single wired LAN port may be used.

  The RF device 140 and the antenna 150 perform wireless communication with other wireless LAN devices. The RF device 140 is a device that transmits and receives radio signals via the antenna 150. The RF device 140 and the antenna 150 correspond to the wireless communication apparatus in [Means for Solving the Problems].

  The CPU 100 performs overall control of the wireless LAN device 10. Further, the CPU 100 functions as a control unit including the packet transmission control unit 102, the first activation control unit 104, and the second activation control unit 106 by reading and executing the computer program stored in the ROM 110. Then, a startup control process described later is executed.

  The packet transmission control unit 102 searches for a wireless LAN access point capable of wireless communication and a function of transmitting a DHCPDISCOVER packet for searching for a DHCP server from the LAN switch 130 to the wired device 20 when the wireless LAN device 10 is activated. The RF device 140 has a function of transmitting a probe request packet to the other wireless LAN device via the antenna 150.

  When the wireless LAN device 10 is activated, the first activation control unit 104 receives the DHCPOFFER packet from the wired device 20 as a response to the DHCPDISCOVER packet, in the access point mode (wireless master mode). The wireless LAN device 10 has a function of starting up. The LAN switch 130 receives the DHCPOFFER packet when the wired device 20 is a network device (for example, the router 20RT) having a DHCP server function. The access point mode (wireless master mode) is an operation mode in which the wireless LAN device 10 operates as a wireless LAN access point (wireless master). The first activation control unit 104 corresponds to the first operation control unit in [Means for Solving the Problems].

  When the wireless LAN device 10 is activated, the second activation control unit 106 receives the probe response packet from the access point 10AP as a response to the probe request packet via the antenna 150. (Wireless slave mode) has a function of starting the wireless LAN device. The client mode (wireless slave mode) is an operation mode in which the wireless LAN device 10 operates as a wireless LAN client (wireless slave). The second activation control unit 106 corresponds to the second operation control unit in [Means for Solving the Problems].

A3. Startup control processing:
FIG. 3 is a flowchart showing the flow of activation control processing of the wireless LAN device 10 of the first embodiment. This process is a process executed by the CPU 100 (the packet transmission control unit 102, the first activation control unit 104, and the second activation control unit 106) included in the wireless LAN device 10 when the wireless LAN device 10 is activated.

  First, when the wireless LAN device 10 is powered on, the packet transmission control unit 102 transmits a DHCPDISCOVER packet to the wired device 20 connected from the LAN switch 130. In addition, the packet transmission control unit 102 transmits the probe request packet to the other wireless LAN apparatus via the antenna 150 in parallel with the DHCPDISCOVER packet (step S100).

  Then, the CPU 100 determines whether or not at least one of the DHCPOFFER packet and the probe response packet has been received (step S110). When the wired device 20 that is the transmission destination of the DHCPDISCOVER packet is a network device having a DHCP server function, the wireless LAN device 10 receives the DHCPOFFER packet as a response to the DHCPDISCOVER packet. On the other hand, when the wired device 20 is a network device that does not have a DHCP server function, the wireless LAN device 10 cannot receive a DHCPOFFER packet. When the other wireless LAN device to which the probe request packet is transmitted is an access point, the wireless LAN device 10 receives the probe response packet as a response to the probe request packet. On the other hand, when the other wireless LAN device is not an access point, the wireless LAN device 10 cannot receive the probe response packet.

  In step S110, when only the DHCPOFFER packet is received, the first activation control unit 104 acquires the IP address included in the DHCPOFFER packet and activates the wireless LAN device 10 as an access point (wireless master) (step S110). S120). Then, the CPU 100 ends the activation control process. In addition, even when both the DHCPPOEER and the probe response packet are received, the first activation control unit 104 acquires the IP address included in the DHCPOFFER packet and activates the wireless LAN device 10 as an access point (wireless master device). (Step S120). Then, the CPU 100 ends the activation control process. Thereafter, the wireless LAN device 10 transmits a beacon packet including an SSID (Service Set ID) as an access point.

  The wireless LAN device 10 receives the DHCPOFFER packet when the wired device 20 wired to the wireless LAN device 10 is a wired device 20 having a DHCP server function (for example, the router 20RT). When the user of the wireless LAN device 10 connects the wired device 20 (for example, the router 20RT) having the DHCP server function to the wireless LAN device 10, the user already has an access point in the wireless LAN. Even in this case, it is considered that the wireless LAN device 10 is intended to be used as a new access point (wireless master device). By executing steps 110 and 120 in the activation control process, the above-described user intention can be reflected.

  If only the probe response packet is received in step S110, the second activation control unit 106 activates the wireless LAN device 10 as an Ethernet converter (wireless slave) (step S130), and ends the activation control process. . Thereafter, the wireless LAN device 10 performs connection processing for establishing a wireless communication connection with the access point as an Ethernet converter. For example, AOSS (registered trademark) can be applied to this connection process. In step S110, when neither a DHCPOFFER packet nor a probe response packet is received (step S110: NO), the CPU 100 returns to step S100.

  In the wireless LAN device 10 of the first embodiment described above, it is not necessary for the user to set an operation mode for operating the wireless LAN device 10 as a wireless master device or a wireless slave device. That is, according to the wireless LAN device 10 of the first embodiment, the operation mode setting of the wireless LAN device that can be used as both the wireless master device and the wireless slave device can be automated by switching the operation mode setting. . Note that, as described above, the wireless LAN device 10 according to the first embodiment automates the setting of the operation mode and avoids an erroneous setting of the artificial operation mode. This is effective when a star-type wireless LAN including an access point) and a plurality of wireless slave devices (clients) is constructed.

  In the wireless LAN device 10 of the first embodiment, in the activation control process shown in FIG. 3, the transmission of the DHCPDISCOVER packet and the reception of the DHCPOFFER packet, the transmission of the probe request packet and the reception of the probe response packet are performed in parallel. Is going. Therefore, the time required for setting the operation mode of the wireless LAN device can be shortened as compared with the case where transmission of the DHCPDISCOVER packet and reception of the DHCPOFFER packet and transmission of the probe request packet and reception of the probe response packet are performed in series. Can do.

B. Second embodiment:
The configuration of the network system 1000 of the second embodiment and the configuration of the wireless LAN device 10 are the same as those of the first embodiment. In the second embodiment, the activation control process of the wireless LAN device 10 is different from the first embodiment. Hereinafter, the activation control process of the wireless LAN device 10 of the second embodiment will be described.

  FIG. 4 is a flowchart showing the flow of activation control processing of the wireless LAN device 10 of the second embodiment. This process is a process executed by the CPU 100 (the packet transmission control unit 102, the first activation control unit 104, and the second activation control unit 106) included in the wireless LAN device 10 when the wireless LAN device 10 is activated.

  First, when the wireless LAN device 10 is powered on, the packet transmission control unit 102 transmits a DHCPDISCOVER packet from the LAN switch 130 to the wired device 20 (step S200). Then, CPU 100 determines whether or not a DHCPOFFER packet has been received (step S210). When the wired device 20 that is the transmission destination of the DHCPDISCOVER packet is a network device having a DHCP server function, the wireless LAN device 10 receives the DHCPOFFER packet as a response to the DHCPDISCOVER packet.

  In step S210, when a DHCPOFFER packet is received (step S210: YES), the first activation control unit 104 acquires an IP address included in the DHCPOFFER packet, and sets the wireless LAN device 10 as an access point (wireless master). (Step S220), and the start control process ends. Thereafter, the wireless LAN device 10 transmits a beacon packet including the SSID as an access point.

  On the other hand, when the DHCPOFFER packet is not received in step S210 (step S210: NO), the packet transmission control unit 102 sends the probe request packet to the other wireless LAN device via the RF device 140 via the antenna 150. (Step S230). Then, the CPU 100 determines whether or not a probe response packet has been received (step S240). When another wireless LAN device to which the probe request packet is transmitted is an access point, the wireless LAN device 10 receives the probe response packet as a response to the probe request packet.

  In step S240, when the probe response packet is received (step S240: YES), the second activation control unit 106 activates the wireless LAN device 10 as an Ethernet converter (wireless slave) (step S250) and activates it. The control process ends. Thereafter, the wireless LAN device 10 performs connection processing for establishing a wireless communication connection with the access point as an Ethernet converter. For example, AOSS (registered trademark) can be applied to this connection process. In step S240, when the probe response packet is not received (step S240: NO), the CPU 100 returns to step S200.

  Similarly to the wireless LAN device 10 of the first embodiment, the wireless LAN device 10 of the second embodiment described above can also be used as a wireless master device or a wireless slave device by switching the operation mode setting. The setting of the operation mode of the LAN device can be automated.

  In the wireless LAN device 10 of the second embodiment, in the activation control process shown in FIG. 4, DHCPDISCOVER packet transmission and DHCPOFFER packet reception, probe request packet transmission, and probe response packet reception are serially performed. Is going to. Therefore, the load per unit time of the CPU 100 can be reduced as compared with the case where the transmission of the DHCPDISCOVER packet and the reception of the DHCPOFFER packet and the transmission of the probe request packet and the reception of the probe response packet are performed in parallel. In the wireless LAN device 10 of the second embodiment, when a DHCPOFFER packet is received as a response to the transmission of the DHCPDISCOVER packet in the activation control process, the process of transmitting the probe request packet is omitted, and the wireless LAN apparatus 10 The LAN device 10 can be activated as an access point.

C. Third embodiment:
The configuration of the network system 1000 of the third embodiment is the same as that of the first embodiment. In the third embodiment, the configuration of the wireless LAN device 10B and the activation control process are different from the configuration of the wireless LAN device 10 in the first embodiment and the activation control process. Hereinafter, the configuration of the wireless LAN device 10B of the third embodiment and the activation control process will be described.

  FIG. 5 is an explanatory diagram showing a schematic configuration of a wireless LAN device 10B in the third embodiment. As can be seen from a comparison between FIG. 5 and FIG. 2, the hardware configuration of the wireless LAN device 10B is the same as the hardware configuration of the wireless LAN device 10 in the first embodiment. However, in the wireless LAN device 10B according to the third embodiment, the CPU 100 uses the second activation as a functional block for performing activation control processing instead of the second activation control unit 106 in the wireless LAN device 10 according to the first embodiment. A control unit 106B is provided. In addition, the CPU 100 includes a beacon detection unit 108. The beacon detection unit 108 receives and detects a beacon packet transmitted from another wireless LAN device (wireless master) via the antenna 150 by the RF device 140. In addition, the beacon detection unit 108 can also analyze the contents of the beacon packet (for example, identification of SSID).

  FIG. 6 is a flowchart showing the flow of activation control processing of the wireless LAN device 10B of the third embodiment. This process is a process executed by the CPU 100 (packet transmission control unit 102, first activation control unit 104, second activation control unit 106B, and beacon detection unit 108) included in the wireless LAN device 10B when the wireless LAN device 10B is activated. is there.

  First, when the wireless LAN device 10B is powered on, the packet transmission control unit 102 transmits a DHCPDISCOVER packet from the LAN switch 130 to the wired device 20 (step S300). Then, the CPU 100 determines whether or not a DHCPOFFER packet has been received (step S310). When the DHCPOFFER packet is received (step S310: YES), the first activation control unit 104 acquires the IP address included in the DHCPOFFER packet and activates the wireless LAN device 10B as an access point (wireless master). (Step S320), the start control process is terminated.

  On the other hand, when the DHCPOFFER packet is not received in step S310 (step S310: NO), the beacon detection unit 108 detects a beacon packet transmitted from another wireless LAN device (step S330), and the beacon packet Is detected (step S340). When the beacon packet is not detected (step S340: NO), the CPU 100 returns to step S300. On the other hand, when a beacon packet is detected (step S340: YES), the second activation control unit 106B analyzes whether the detected beacon packet has the same SSID as that of the own device (step S350).

  In step S350, when the beacon packet has the same SSID as that of the own device (step S350: YES), the second activation control unit 106B activates the wireless LAN device 10B as an Ethernet converter (wireless slave device). (Step S360), the activation control process is terminated. In step S350, when the beacon packet does not have the same SSID as the own device (step S350: NO), the CPU 100 returns to step S330.

  Similarly to the wireless LAN device 10 of the first and second embodiments, the wireless LAN device 10B of the third embodiment described above can be used as a wireless master device or a wireless slave device by switching the operation mode setting. It is possible to automate the setting of the operation mode of a wireless LAN device.

  In general, wireless LAN devices can use radio waves in various frequency bands for wireless communication. However, in order to prevent radio wave interference, frequency bands (for example, W53 and W56) that are preferentially used by various radars such as marine radars for ships, aircrafts, and military use, and fixed radars for weather are used in the wireless LAN. When used for wireless communication, there may be certain restrictions. Under such an environment, the wireless LAN device needs to avoid transmitting the probe request packet by using the above-described radio waves in an unusable frequency band. Further, there may be a case where the wireless LAN device cannot transmit the probe request packet to another wireless LAN device due to other reasons.

  In the wireless LAN device 10B of the third embodiment, in the activation control process shown in FIG. 6, prior to transmission of the probe request packet, it is transmitted from another wireless LAN device (wireless master) existing in the wireless LAN. By detecting a beacon packet having the same SSID as its own device, it can be recognized that a wireless master device for the own device already exists in the wireless LAN. When the wireless LAN device 10B according to the present embodiment detects the beacon packet, the wireless LAN device 10B operates as a client (wireless slave) without transmitting a probe request packet and receiving a probe response packet. That is, the wireless LAN device 10B according to the present embodiment does not transmit a probe request packet. Therefore, it is possible to avoid transmitting the probe request packet using radio waves in a frequency band that cannot be used in the wireless LAN described above. Further, the wireless LAN device 10B according to the present embodiment can operate as a wireless slave device by detecting a beacon packet even when a probe request packet cannot be transmitted to another wireless LAN device.

D. Fourth embodiment:
The configuration of the network system 1000 of the fourth embodiment and the configuration of the wireless LAN device 10B are the same as those of the third embodiment. In the fourth embodiment, the activation control process of the wireless LAN device 10B is different from the third embodiment. The activation control process for the wireless LAN device 10B according to the fourth embodiment will be described below.

  FIG. 7 is a flowchart showing the flow of activation control processing of the wireless LAN device 10B in the fourth embodiment. This process is a process executed by the CPU 100 (packet transmission control unit 102, first activation control unit 104, second activation control unit 106B, and beacon detection unit 108) included in the wireless LAN device 10B when the wireless LAN device 10B is activated. is there.

  First, when power is supplied to the wireless LAN device 10B, the packet transmission control unit 102 transmits a DHCPDISCOVER packet from the LAN switch 130 to the wired device 20 (step S400). Then, the CPU 100 determines whether or not a DHCPOFFER packet has been received (step S410). When the DHCPOFFER packet is received (step S410: YES), the first activation control unit 104 acquires the IP address included in the DHCPOFFER packet and activates the wireless LAN device 10B as an access point (wireless master). (Step S420), the start control process is terminated.

  On the other hand, when the DHCPOFFER packet is not received in step S410 (step S410: NO), the beacon detection unit 108 detects a beacon packet transmitted from another wireless LAN device (step S430), and the beacon packet Is detected (step S440). When the beacon packet is not detected (step S440: NO), the CPU 100 returns to step S400.

  If at least one beacon packet is detected in step S440 (step S440: YES), the packet transmission control unit 102 may indicate that the parent device that transmitted the beacon packet is a wireless master device for the own device. The RF device 140 transmits the probe request packet to another wireless LAN device via the antenna 150 without analyzing the contents of each detected beacon packet (step S450). Then, CPU 100 determines whether a probe response packet has been received (step S460).

  If the probe response packet is received in step S460 (step S460: YES), the second activation control unit 106B activates the wireless LAN device 10B as an Ethernet converter (wireless slave) (step S470) and activates it. The control process ends. If the probe response packet is not received in step S460 (step S460: NO), the CPU 100 returns to step S400.

  As with the wireless LAN devices 10 and 10B of the first to third embodiments, the wireless LAN device 10 of the fourth embodiment described above can be used as a wireless master device or a wireless slave device by switching the operation mode setting. Also, the setting of the operation mode of the available wireless LAN device can be automated.

  For example, when there are a plurality of wireless master devices in the wireless LAN, the beacon detection unit 108 provided in the wireless LAN device 10B detects a plurality of beacon packets. In this case, due to the CSMA / CA procedure for preventing collision (signal collision), the beacon detection unit 108 waits until it detects a beacon packet transmitted by a wireless master device having the same SSID as the wireless LAN device 10B. take time. Furthermore, it takes time to identify the SSID included in each beacon packet detected by the beacon detection unit 108. In addition, even if the beacon detection unit 108 detects a beacon packet, if the wireless master device that has transmitted the beacon packet is a wireless master device configured to reject the Any connection, the beacon packet includes an SSID. Is not included, a wireless master device having the same SSID as that of the wireless LAN device 10B cannot be identified.

  In the wireless LAN device 10B of the fourth embodiment, when at least one of the beacon packets is detected in the activation control process shown in FIG. 7, the parent device that is the transmission source of the beacon packet is the wireless master device for the own device. It judges that there is a possibility, sends the probe request packet and receives the probe response packet without analyzing the beacon packet, and operates as a client (wireless slave unit) when the probe response packet is received To do. Therefore, the above-described waiting time and the time required for identifying the SSID included in the beacon packet can be shortened. In addition, even a wireless master device in which an Any connection rejection in which an SSID is not included in a beacon packet to be transmitted can be connected.

E. Variations:
As mentioned above, although several embodiment of this invention was described, this invention is not limited to such embodiment at all, and implementation in a various aspect is possible within the range which does not deviate from the summary. It is. For example, the following modifications are possible.

E1. Modification 1:
In the above embodiment, the example in which the wireless LAN device of the present invention is applied to the access point 10AP and the Ethernet converters 10ECa, 10ECb, and 10ECc has been shown, but the present invention is not limited to this. The present invention is generally a wireless LAN device that relays communication between a wired network device and a wireless network device, and can be used as a wireless master device or a wireless slave device by switching operation modes. Applicable. For example, a USB port, a USB cable, or the like may be used instead of the LAN port 132 or the LAN cable CAB for connection between the wired network device (wired device 20) and the wireless LAN device 10.

E2. Modification 2:
In the above embodiment, the activation control processing of the wireless LAN devices 10 and 10B is executed every time the wireless LAN devices 10 and 10B are activated. However, the present invention is not limited to this. For example, when the wireless LAN devices 10 and 10B are installed, the result (operation mode) of the activation control process executed for the first time is stored, and when the wireless LAN devices 10 and 10B are activated next time, the stored operation mode is used. You may make it start. Further, when the wireless LAN devices 10 and 10B are activated, it is detected whether or not the wired device 20 connected to the LAN switch 130 has been changed, and the wired device 20 connected to the LAN switch 130 has been changed. In this case, a new start control process may be executed. Whether or not the wired device 20 connected to the LAN switch 130 has been changed can be detected based on identification information unique to the wired device 20.

E3. Modification 3:
In the above embodiment, the setting of the operation mode of the wireless LAN devices 10 and 10B is performed when the wireless LAN devices 10 and 10B are activated (when the power is turned on) as the activation control process. Not limited. For example, the wireless LAN devices 10 and 10B may be provided with a reset button, and the operation mode of the wireless LAN devices 10 and 10B may be set when the reset button is pressed. Further, the operation mode of the wireless LAN device 10 may be set when a new wired device 20 is connected to the LAN switch 130.

E4. Modification 4:
In the above embodiment, a part of the configuration realized by hardware may be replaced with software, and conversely, a part of the configuration realized by software may be replaced by hardware.

DESCRIPTION OF SYMBOLS 1000 ... Network system 10, 10B ... Wireless LAN apparatus 10AP ... Access point 10ECa, 10ECb, 10ECc ... Ethernet converter 20 ... Wired device 20RT ... Router 20a ... Television receiver 20b ... Personal computer 20c ... Printer 100 ... CPU
DESCRIPTION OF SYMBOLS 102 ... Packet transmission control part 104 ... 1st starting control part 106,106B ... 2nd starting control part 108 ... Packet detection part 110 ... ROM
120 ... RAM
130 ... LAN switch 132 ... LAN port 140 ... RF device 150 ... Antenna CAB ... LAN cable INT ... Internet

Claims (8)

A wireless LAN device that is wired to the first network device and wirelessly connected to the second network device and relays communication between the first network device and the second network device,
A wired communication device for communicating with the first network device;
A wireless communication device for communicating with the second network device;
A control unit that controls the operation of the wireless LAN device so that the wireless LAN device operates as a wireless LAN access point or client.
The controller is
A packet having a function of transmitting a DHCPDISCOVER packet from the wired communication device to the first network device at a predetermined timing and a function of transmitting a probe request packet from the wireless communication device to the second network device. A transmission control unit;
When the wired communication device receives a DHCPOFFER packet from the first network device as a response to the DHCPDISCOVER packet, it controls the operation of the wireless LAN device so that the wireless LAN device operates as the access point. A first motion control unit capable of
When the wireless communication device receives a probe response packet from the second network device as a response to the probe request packet, the wireless LAN device operates so that the wireless LAN device operates as the client. A second operation control unit capable of controlling;
A wireless LAN device comprising: The wireless LAN device according to claim 1,
The predetermined timing is when the wireless LAN device is activated.
Wireless LAN device. The wireless LAN device according to claim 1 or 2,
When the wired communication device receives the DHCPOFFER packet as a response to the DHCPDISCOVER packet, and the wireless communication device receives the probe response packet as a response to the probe request packet, the second communication device The operation control unit does not control the operation of the wireless LAN device so that the wireless LAN device operates as the client, and the first operation control unit allows the wireless LAN device to operate as the access point. To control the operation of the wireless LAN device,
Wireless LAN device. A wireless LAN device according to any one of claims 1 to 3,
The packet transmission control unit performs transmission of the DHCPDISCOVER packet and transmission of the probe request packet in parallel.
Wireless LAN device. A wireless LAN device according to any one of claims 1 to 3,
The packet transmission control unit performs transmission of the DHCPDISCOVER packet and transmission of the probe request packet, transmission of one packet, and transmission of the other packet.
Wireless LAN device. The wireless LAN device according to claim 5,
The packet transmission control unit transmits the probe request packet after transmitting the DHCPDISCOVER packet;
Wireless LAN device. The wireless LAN device according to claim 6,
The control unit further detects a beacon packet transmitted from another wireless LAN device existing in the wireless LAN by passive scanning before the packet transmission control unit transmits the probe request packet. With a detector
The second operation control unit transmits the probe request packet by the packet transmission control unit when the beacon packet having the same SSID (Service Set ID) as that of the own device is detected by the beacon detection unit, And controlling the operation of the wireless LAN device so that the wireless LAN device operates as the client without receiving the probe response packet by the wireless communication device.
Wireless LAN device. The wireless LAN device according to claim 6,
The control unit further detects a beacon packet transmitted from another wireless LAN device existing in the wireless LAN by passive scanning before the packet transmission control unit transmits the probe request packet. With a detector
The packet transmission control unit transmits the probe request packet after the beacon packet is detected by the beacon detection unit,
The second operation control unit, when receiving the probe response packet, controls the operation of the wireless LAN device so that the wireless LAN device operates as the client.
Wireless LAN device.

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