JP2011029985A - Wireless communication apparatus, wireless communication system, communication control method and control program - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a wireless communication apparatus that provides superior services to a user, a wireless communication system, a communication control method and a control program. <P>SOLUTION: The wireless communication apparatus includes: a wireless communication means with a base station function capable of housing a mobile terminal as a slave unit; a detection means for detecting an external base station existing around the apparatus; and a control means for controlling the wireless communication means based on results of the detection means. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a wireless communication device, a wireless communication system, a communication control method, and a control program.

  Known client terminals such as portable game machines and portable music players that have a predetermined wireless communication function, for example, a wireless LAN (Local Area Network) communication function and can be connected to the Internet environment via an access point Yes. Since these client terminals usually do not have a wide-area communication function such as a mobile phone network, Internet services cannot be used in places where wireless LAN access points are not installed, for example, outdoors.

  Therefore, Patent Document 1 and Patent Document 2 operate a communication terminal having a wide-area communication function and a wireless LAN communication function as a mobile wireless LAN access point, and accommodate the client terminal as described above as a slave unit. Describe. In this case, the communication terminal can relay the wide area communication network and the wireless LAN. Therefore, even in a place where there is no access point, the client terminal can use the Internet service via the communication terminal.

JP 2003-284152 A JP 2003-283536 A

  In order to provide a high-quality communication service to the user, it is necessary to consider the presence of fixed wireless LAN access points in the vicinity of the communication terminal, regarding the control (for example, start or stop) of the access point function in the communication terminal preferable.

  For example, when the distance between the client terminal and the fixed wireless LAN access point is more than a certain distance, it is desirable to activate the mobile wireless LAN access point in order to continue providing the communication service to the user. On the other hand, it is generally said that a fixed wireless LAN access point is superior in terms of communication fee, bandwidth, response performance, etc., to a mobile wireless LAN access point such as the above communication terminal. Yes. Therefore, when the client terminal can be connected to both the fixed and mobile access points, it is preferable to connect to the fixed wireless LAN access point as much as possible.

  Patent Document 1 and Patent Document 2 describe that a communication terminal serves as a mobile wireless LAN access point to accommodate a client terminal and connect the client terminal to the Internet via a wide area communication network. However, Patent Document 1 and Patent Document 2 do not consider the presence of a fixed wireless LAN access point in the vicinity of a communication terminal, regarding the control of the access point function. Therefore, a high-quality communication service (for example, a seamless and low-cost communication service) cannot be provided to the user.

  The present invention has been made to solve the above-described problems, and provides a wireless communication device, a wireless communication system, a communication control method, and a control program capable of providing a high-quality communication service to a user. The purpose is to do.

  In order to solve the above-described problems, a wireless communication apparatus according to the present invention includes a wireless communication unit having a base station function capable of accommodating a mobile terminal as a slave unit, and a detection unit that detects an external base station existing in the vicinity. And control means for controlling the wireless communication means based on the detection result of the detection means.

  The wireless communication system of the present invention includes an external base station, a mobile terminal, and a wireless communication device, and the wireless communication device has a base station function capable of accommodating the mobile terminal as a slave unit. Wireless communication means provided, detection means for detecting an external base station existing in the vicinity, and control means for controlling the wireless communication means based on a detection result of the detection means.

  Further, the communication control method of the present invention is a communication control method in a wireless communication apparatus having a base station function capable of accommodating a mobile terminal as a slave unit, and detects an external base station existing in the vicinity, The wireless communication device is controlled based on the detection result.

  Further, the control program of the present invention is a control program for causing a computer of a wireless communication apparatus having a base station function capable of accommodating a mobile terminal as a slave unit to execute an external base station existing in the vicinity. Based on the detection result, the computer is caused to execute a process for detecting and a process for controlling the wireless communication apparatus.

  According to the present invention, it is possible to provide a high-quality communication service to a user.

It is a block diagram which shows the structural example of the mobile terminal of 1st Embodiment which concerns on this invention. It is a block diagram which shows the structural example of the radio | wireless communications system of 2nd Embodiment which concerns on this invention. 3 is a flowchart for explaining a first operation example of the mobile terminal shown in FIG. 2. 3 is a flowchart for explaining a second operation example of the mobile terminal shown in FIG. 2. It is a block diagram which shows the structural example of the mobile terminal of 3rd Embodiment which concerns on this invention. 6 is a flowchart for explaining an operation example of the mobile terminal shown in FIG. 5. 6 is a flowchart for explaining an operation example of the detection unit shown in FIGS. 2 and 5. It is a block diagram which shows the structural example of the radio | wireless communications system of 4th Embodiment which concerns on this invention. It is a specific example of wireless LAN client setting DB memorize | stored in the setting memory | storage part shown in FIG. FIG. 9 is a sequence chart for explaining an operation example of the wireless communication system shown in FIG. 8 (specifically, an operation example when a mobile terminal connects to a fixed wireless LAN access point as a client). FIG. 9 is a sequence chart for explaining an operation example of the wireless communication system shown in FIG. 8 (specifically, an operation example when a mobile terminal serves as an access point and accommodates a wireless LAN client terminal). It is a block diagram which shows the structural example of the mobile terminal of 5th Embodiment which concerns on this invention.

[First Embodiment]
FIG. 1 is a block diagram showing a configuration example of a mobile terminal 1 (wireless communication apparatus) according to the first embodiment of the present invention. The mobile terminal 1 includes a wireless communication unit 2 (wireless communication unit), a detection unit 3 (detection unit), and a control unit 4 (control unit). The wireless communication unit 2 has a base station function that can accommodate a mobile terminal (not shown) as a slave unit. The detection unit 3 detects external base stations (not shown) existing in the vicinity. The control unit 4 controls the wireless communication unit 2 based on the detection result of the detection unit 3.

  That is, the mobile terminal 1 according to the first embodiment considers the presence of external base stations in the vicinity with respect to control (for example, activation or deactivation) of the base station function in the local station. Therefore, for example, when the distance between the mobile terminal and the external base station is more than a certain distance due to the movement of the user, the base station function can be activated. By starting the base station function, the mobile terminal can be accommodated as a slave unit. Therefore, the user can use the service continuously regardless of movement. That is, it is possible to provide a seamless communication service to the user. On the other hand, when the mobile terminal can be connected to an external base station, the mobile terminal can be connected to an external base station that is superior in terms of communication charges and the like. That is, it is possible to provide a service at a low price to the user.

In summary, the mobile terminal 1 according to the first embodiment of the present invention can provide a high-quality communication service to the user.
[Second Embodiment]
FIG. 2 is a block diagram illustrating a configuration example of the wireless communication system 10 according to the second embodiment of the present invention.

  The wireless communication system 10 includes a mobile terminal 12 (wireless communication device), a fixed wireless LAN (Local Area Network) access point 14 (external base station), and a wireless LAN client terminal 16 (mobile terminal).

  The fixed wireless LAN access point 14 is a fixed wireless LAN access point installed outside the mobile terminal 12, and accommodates (connects to) the mobile terminal 12 and the wireless LAN client terminal 16 as slave units (also referred to as clients). ) Here, “accommodating (connecting) as a slave (client)” means, for example, that the wireless LAN client terminal 16 establishes a wireless LAN connection to the mobile terminal 12 in the infrastructure mode.

  The wireless LAN client terminal 16 is a portable terminal carried by a user (typically, for example, a portable game machine or a portable music player). The wireless LAN client terminal 16 is connected as a slave to the fixed wireless LAN access point 14 or the mobile terminal 12 operating as a mobile wireless LAN access point.

  The mobile terminal 12 is a mobile terminal carried by a user, and includes a wireless LAN interface unit 20 (wireless communication unit), a detection unit 22 (detection unit), and a control unit 24 (control unit). The wireless LAN interface unit 20 corresponds to a predetermined wireless communication standard (in this case, a wireless LAN) and has a base station function (also referred to as an access point function) that can accommodate the wireless LAN client terminal 16 as a client. . The detection unit 22 detects a fixed wireless LAN access point 14 existing in the vicinity. The control unit 24 controls the wireless LAN interface unit 20 based on the detection result of the detection unit 22 (detection result regarding whether or not the fixed wireless LAN access point 14 exists around the mobile terminal 12).

  FIG. 3 is a flowchart for explaining a first operation example of the mobile terminal 12 shown in FIG. The detection unit 22 detects whether or not the fixed wireless LAN access point 14 is present around the mobile terminal 12 (step S1). The detection unit 22 transmits the detection result to the control unit 24. The control unit 24 controls the wireless LAN interface unit 20 based on the detection result.

  Specifically, for example, when the mobile terminal 12 moves outdoors or the like and the fixed wireless LAN access point 14 does not exist around the mobile terminal 12 (No determination in step S2), the control unit 24 Instructs the wireless LAN interface unit 20 to activate the access point function (step S4). The wireless LAN interface unit 20 accommodates the wireless LAN client terminal 16 as a slave unit (step S5).

  On the other hand, for example, when the mobile terminal 12 is located indoors and the fixed wireless LAN access point 14 exists around the mobile terminal 12 (Yes in step S2), the control unit 24 The interface unit 20 is instructed to stop the access point function (step S3). The wireless LAN interface unit 20 cancels the attribution of the wireless LAN client terminal 16 (step S6).

  As described above, the mobile terminal 12 according to the present embodiment has the positional relationship between the fixed wireless LAN access point 14 and the mobile wireless LAN access point (the presence of the fixed wireless LAN access point 14 around the mobile terminal 12). ) Is considered for wireless communication control. Therefore, the mobile terminal 12 can provide a high-quality communication service to the user.

  Specifically, for example, when there is no fixed wireless LAN access point 14 around the mobile terminal 12, the control unit 24 instructs the wireless LAN interface unit 20 to activate the access point function. Here, the wireless LAN client terminal 16 is usually carried by the user together with the mobile terminal 12. Therefore, there is a high possibility that the wireless LAN client terminal 16 exists near the mobile terminal 12. That is, when the distance between the wireless LAN client terminal 16 and the fixed wireless LAN access point 14 is more than a certain distance, the mobile terminal 12 can accommodate the wireless LAN client terminal 16 if the access point function is activated. Accordingly, it is possible to continue providing communication services (for example, services on the Internet) to the wireless LAN client terminal 16. In addition, since the above process is automatically performed, the user does not need to be aware of the switching of the access point every time the user moves.

  On the other hand, when the fixed wireless LAN access point 14 is present around the mobile terminal 12, the control unit 24 instructs the wireless LAN interface unit 20 to stop the access point function. By the way, it is generally said that a fixed wireless LAN access point is superior to a mobile wireless LAN access point in terms of communication fee, bandwidth, response performance, and the like. That is, the mobile terminal 12 can automatically connect the wireless LAN client terminal 16 to the fixed wireless LAN access point 14 when the wireless LAN client terminal 16 can be connected to both the fixed and mobile access points. it can. Therefore, the user can enjoy a communication service under more favorable conditions (conditions superior in terms of communication fee, bandwidth, response performance, etc.).

  Here, the mobile terminal 12 is not necessarily involved in the connection between the wireless LAN client terminal 16 and the fixed wireless LAN access point 14. That is, when connection to both access points is possible, the fact that one access point (that is, the mobile access point) does not start itself results in the connection between the wireless LAN client terminal 16 and the fixed wireless LAN access point 14. It leads to making it connect.

  FIG. 4 is a flowchart for explaining a second operation example of the mobile terminal 12 shown in FIG. The wireless LAN interface unit 20 operates the access point function (step S10). That is, the mobile terminal 12 can accommodate the wireless LAN client terminal 16 as a client.

  The detection unit 22 detects whether or not the fixed wireless LAN access point 14 exists around the mobile terminal 12 (step S11). The detection unit 22 transmits the detection result to the control unit 24.

  When the fixed wireless LAN access point 14 exists in the vicinity of the mobile terminal 12 (in the case of Yes determination in step S12), the control unit 24 makes a new connection from the wireless LAN client terminal 16 to the wireless LAN interface unit 20. An instruction is given to reject the connection request (step S13).

  On the other hand, when the fixed wireless LAN access point 14 does not exist around the mobile terminal 12 (in the case of No determination in step S12), the control unit 24 sends the wireless LAN interface unit 20 from the wireless LAN client terminal 16 to the wireless LAN interface unit 20. An instruction is given to accept a new connection request (step S14).

As described above, in this operation example, a new connection request from the wireless LAN client terminal 16 to the mobile terminal 12 is rejected according to the presence state of the fixed wireless LAN access point 14 around the mobile terminal 12, Or the control which permits is performed. Therefore, existing communication (that is, communication already established between the mobile terminal 12 acting as a mobile wireless LAN access point and the wireless LAN client terminal 16) is not forcibly disconnected. Moreover, the new connection is performed under better conditions (because, for example, communication is performed with the fixed wireless LAN access point 14 which is excellent in communication charge, bandwidth, response performance, etc.). Of course, when there is no fixed wireless LAN access point 14 in the vicinity, a new connection request is accepted by the wireless LAN interface unit 20. Therefore, the communication service for the wireless LAN client terminal 16 that has made the connection request does not stagnate.
[Third Embodiment]
FIG. 5 is a block diagram illustrating a configuration example of the mobile terminal 100 according to the third embodiment of the present invention. The difference between the mobile terminal 100 and the mobile terminal 12 shown in FIG. 2 is that a session management unit 102 is further added. The session management unit 102 checks the communication state of a transport layer protocol (for example, TCP or UDP) by monitoring a NAT address conversion table, for example. Here, NAT is an abbreviation for Network Address Translation. TCP is an abbreviation for Transmission Control Protocol. UDP is an abbreviation for User Datagram Protocol. The session management unit 102 obtains information (session information) as to whether or not the wireless LAN client terminal 16 is communicating with the wide area communication network via the mobile terminal 100 based on the check result. In response to the request from the control unit 24, the session management unit 102 notifies the control unit 24 of the session information at that time. Based on the session information, the control unit 24 stops the access point function or prohibits a new connection from the wireless LAN client terminal 16.

  FIG. 6 is a flowchart for explaining an operation example of the mobile terminal 100 shown in FIG. The wireless LAN interface unit 20 operates the access point function (step S30). That is, the mobile terminal 100 can accommodate the wireless LAN client terminal 16 as a client. In this state, the detection unit 22 detects whether or not the fixed wireless LAN access point 14 exists around the mobile terminal 100 (step S31). The detection unit 22 transmits the detection result to the control unit 24. When the fixed wireless LAN access point 14 is present around the mobile terminal 100 (Yes in step S32), the control unit 24 acquires session information (step S33). Specifically, the control unit 24 requests the session management unit 102 for session information. The session management unit 102 detects session information by checking the communication state of TCP or UDP, and notifies the control unit 24 of the detected session information. The control unit 24 determines the presence / absence of a session based on the notified session information (step S34). When there is no session (in the case of No determination in step S34), the control unit 24 instructs the wireless LAN interface unit 20 to stop the access point function (step S35). The wireless LAN interface unit 20 releases the attribution of the wireless LAN client terminal 16 (step S36).

  On the other hand, when a session remains (in the case of Yes determination in step S34), the control unit 24 instructs the wireless LAN interface unit 20 to reject a new connection request from the wireless LAN client terminal 16 ( Step S37). And the process of step S33 and step S34 is repeated until there is no session.

  In the third embodiment described above, when there is a session, the mobile terminal 100 performs only a process for suppressing a new connection, and stops the access point function and the wireless LAN client terminal 16 only when there is no session. Release attribution of. Therefore, it is possible to avoid a situation where the session is forcibly disconnected, so that seamless access point switching processing is possible. Moreover, the new connection is performed under better conditions (because, for example, communication is performed with the fixed wireless LAN access point 14 which is excellent in communication charge, bandwidth, response performance, etc.).

  FIG. 7 is a flowchart for explaining an operation example of the detection unit 22 shown in FIGS. 2 and 5. First, the storage unit (not shown) of the mobile terminal 12 stores wireless LAN client settings (including setting of a fixed wireless LAN access point to which the mobile terminal can connect as a client). Examples of the setting of the fixed wireless LAN access point include an identifier (for example, an extended service set identifier (ESSID)) that identifies the fixed wireless LAN access point.

  The detection unit 22 acquires the ESSID from the beacon signal received by the wireless LAN interface unit 20. Then, the detection unit 22 compares the received ESSID with the ESSID preset in the storage unit (step S50). As a result of the comparison, when it is determined that the received ESSID is the same as the preset ESSID (Yes in step S51), the detection unit 22 determines the reception intensity of the beacon signal including the ESSID and a predetermined threshold value. Compare (step S52).

  As a result of the comparison, when it is determined that the reception intensity exceeds the threshold (in the case of Yes determination in step S53), the detection unit 22 has at least one fixed type around the mobile terminal 12 (or the mobile terminal 100). It is determined that the wireless LAN access point 14 exists (step S54). On the other hand, when the received ESSID is not the set ESSID (in the case of No determination in step S51), and when the received ESSID is the set ESSID but it is determined that the reception intensity is below the threshold (step S53). In the case of No determination in step S <b> 55), the detection unit 22 determines that there is no fixed wireless LAN access point 14 in the vicinity (step S <b> 55).

  Note that the operation example described above is merely an example, and is not limited to the above. For example, it is not always necessary to measure the reception strength. At the stage where the set ESSID is found, the detection unit 22 has at least one fixed wireless LAN access point around the mobile terminal 12 (or the mobile terminal 100). It can also be determined that 14 exists.

Here, a specific example of “rejection of a new connection request from the wireless LAN client terminal 16” in the second and third embodiments described above will be described. The wireless LAN interface unit 20 in which the access point function is operating shifts to a mode not found from the wireless LAN client terminal 16 (stealth mode). Here, the stealth mode refers to a mode in which a beacon signal transmitted to the surroundings is stopped. Since the wireless LAN client terminal 16 cannot detect the beacon signal, the wireless LAN client terminal 16 cannot make a connection request to the mobile terminal 12 (or the mobile terminal 100) in the stealth mode. As a result, a new connection request is rejected. In addition, the mobile terminal 12 (or the mobile terminal 100) refers to the source MAC address of the received packet, and when it is a packet from the wireless LAN client terminal 16, it does not respond to it. As a result, a new connection request can be rejected.
[Fourth Embodiment]
FIG. 8 is a block diagram illustrating a configuration example of a wireless communication system 200 according to the fourth embodiment of the present invention. The wireless communication system 200 includes a mobile terminal 300 (wireless communication apparatus), a fixed wireless LAN access point 350 (external base station), a wireless LAN client terminal 400 (portable terminal), and a mobile wireless base station 450. .

  The fixed wireless LAN access point 350 is a fixed access point installed outside the mobile terminal 300, and accommodates the mobile terminal 300 and the wireless LAN client terminal 400 as clients.

  The wireless LAN client terminal 400 is a portable terminal carried by a user, and connects as a client to the fixed wireless LAN access point 350 and the mobile terminal 300 operating as a mobile wireless LAN access point.

  The mobile radio base station 450 is a radio base station of a mobile wide area network such as a 3G network, an LTE network, a WiMax network, or a PHS network. Here, 3G is an abbreviation for 3rd Generation. LTE is an abbreviation for Long Term Evolution. WiMax is an abbreviation for Worldwide Interoperability for Microwave Access. PHS is an abbreviation for Personal Handyphone System.

  The mobile terminal 300 includes a wide area network communication function (1), a wireless LAN communication function (2), and a routing function (3). The wide area network communication function (1) is a function in which the mobile terminal 300 communicates with a predetermined mobile wide area network via the mobile radio base station 450. The wireless LAN communication function (2) is a function in which the mobile terminal 300 communicates with other wireless LAN devices (the fixed wireless LAN access point 350 and the wireless LAN client terminal 400) through the wireless LAN. The routing function (3) is a function in which the mobile terminal 300 relays the mobile wide area network and the wireless LAN.

  Regarding the wireless LAN communication function (2), the mobile terminal 300 includes a client (child device) function (2-1) and an access point (base station) function (2-2). The client function (2-1) is a function of connecting itself to the fixed wireless LAN access point 350 as a client. The access point function (2-2) is a function for accommodating the wireless LAN client terminal 400 as a client by itself as an access point.

  That is, the wireless LAN client terminal 400 can be connected to the mobile wide area network by the function (1), the function (2-2), and the function (3) of the mobile terminal 300. Therefore, for example, the wireless LAN client terminal 400 can use a communication service (service on the Internet or mobile wide area network) even outdoors without the fixed wireless LAN access point 350.

  Specifically, the mobile terminal 300 includes a mobile network interface unit 302, a wireless LAN interface unit 304 (wireless communication unit), a setting input unit 306, a setting storage unit 308, and a control unit 310 (control unit). Prepare. The mobile terminal 300 further includes a setting conversion unit 312 (setting conversion unit) and a detection unit 314 (detection unit).

  The mobile network interface unit 302 transmits / receives data to / from the mobile radio base station 450 via a radio propagation path.

  The wireless LAN interface unit 304 includes a “client function” and an “access point function”. The “client function” is a function for connecting to the fixed wireless LAN access point 350 as a client. The “access point function” is a function for accommodating the wireless LAN client terminal 400 as a client by itself as an access point. The wireless LAN interface unit 304 transmits and receives wireless LAN packets to and from the fixed wireless LAN access point 350 and the wireless LAN client terminal 400.

  The setting input unit 306 inputs “wireless LAN client settings” (settings required when the wireless LAN interface unit 304 connects as a wireless LAN client), and stores the input wireless LAN client settings in the setting storage unit 308.

  Here, “wireless LAN client setting” includes, for example, ESSID, connection channel, encryption type, encryption key, IP (Internet Protocol) address setting, and the like.

  As an input method of “wireless LAN client setting” in the setting input unit 306, a method of inputting using a wireless LAN automatic setting function can be cited. Specific examples of wireless LAN automatic setting include, for example, WPS (Wi-Fi Protected Setup), AOSS (Air Station One-Touch Secure System / registered trademark), and Easy Wireless Start (registered trademark). Other examples of the input method include a method of inputting from an external device such as a PC (Personal Computer) or a method of inputting via an NFC such as FeliCa (registered trademark). Here, NFC is an abbreviation for Near Field Communication.

  The setting storage unit 308 stores “wireless LAN client settings” input from the setting input unit 306 as a DB (database).

  FIG. 9 is a specific example of the “wireless LAN client setting DB” stored in the setting storage unit 308. The wireless LAN client setting DB is a collection of ESSID, connection channel, encryption type, encryption key, and IP (Internet Protocol) address setting for each fixed wireless LAN access point 350. FIG. 9 shows a case where, for example, five fixed wireless LAN access points 350 are set.

  Furthermore, the date and time of the last discovery, the AP (access point) possible flag, and the discovery frequency can be stored in the wireless LAN client setting DB. The date and time of the last discovery is information on the date and time when the mobile terminal 300 last discovered a fixed wireless LAN access point (or the date and time when the mobile terminal 300 was last connected as a “client”). The AP possible flag is a flag indicating whether or not each setting (for example, five settings) shown in FIG. 9 can be used as a setting when the wireless LAN interface unit 304 functions as an “access point”. For example, in the case of FIG. 9, a status of “possible” is given to those that can be used. The AP possible flag is set, for example, when setting is input. The discovery frequency is a frequency (the number of times of discovery per unit time) discovered during the access point scan by the mobile terminal 300. For example, in FIG. The fixed wireless LAN access point 350 of FIG. 1 has the AP-enabled flag turned on (possible), the date and time of the last discovery was 12:39 on April 12, 2009, and the discovery frequency (for example, 1 day Is found 10 times).

  Here, returning to the description of FIG. 8 again, the control unit 310 mainly controls the wireless LAN interface unit 304. Specifically, control unit 310 executes processing related to activation / deactivation of “client function” and “access point function” in wireless LAN interface unit 304.

  The setting conversion unit 312 converts “wireless LAN client setting” to “wireless LAN access point setting”. Here, the wireless LAN client setting is a setting when the wireless LAN interface unit 304 connects as a client. The wireless LAN access point setting is a setting when the wireless LAN interface unit 304 connects the wireless LAN client terminal 400 as a client, that is, when the wireless LAN interface unit 304 operates as an access point.

  Here, the conversion means that the setting method of the IP address assigned to the wireless LAN interface unit 304 is specifically converted. Therefore, in the present embodiment, settings other than the IP address (ESSID, connection channel, encryption type, encryption key) are used as they are as wireless LAN access point settings, without converting the values (hereinafter referred to as “wireless LAN access point settings”). , This is sometimes called diversion). Further, “date and time of last discovery”, “AP possible flag”, and “discovery frequency” are only referred to, and are not particularly converted.

  Here, the conversion of the IP address setting method will be described. For example, when the IP address setting of the wireless LAN interface unit 304 for client connection is dynamic IP address assignment by DHCP, the setting conversion unit 312 converts the setting to the DHCP server activation setting in the mobile terminal 300. To do. Here, DHCP is an abbreviation for Dynamic Host Configuration Protocol. When the IP address setting of the wireless LAN interface unit 304 is a fixed IP address, the setting conversion unit 312 converts the IP address assigned to the wireless LAN interface unit 304 using the default gateway value. In addition, when the fixed wireless LAN access point 350 is a DNS (Domain Name System) server, the setting conversion unit 312 converts the setting to a DNS server activation setting.

  The detecting unit 314 detects a fixed wireless LAN access point 350 existing in the vicinity.

  FIG. 10 is a sequence chart for explaining an operation example of the wireless communication system 200 shown in FIG. 8 (specifically, an operation example when the mobile terminal 300 is connected to the fixed wireless LAN access point 350 by a client).

  First, the setting input unit 306 inputs the above-described “wireless LAN client setting” by a predetermined input method (step S100). The setting input unit 306 instructs the setting storage unit 308 to store the input “wireless LAN client setting” (step S101). The setting storage unit 308 stores “wireless LAN client setting” (step S102).

  On the other hand, the wireless LAN interface unit 304 scans the fixed wireless LAN access point 350 (step S103). The wireless LAN interface unit 304 transmits an identifier (for example, ESSID) list of “fixed wireless LAN access points existing around the mobile terminal 300” discovered by scanning to the control unit 310 (step S104). Hereinafter, this list may be referred to as a “neighboring list”.

  Next, the control unit 310 sends the “identifier list in the connectable fixed wireless LAN access point setting list (ie,“ wireless LAN client setting DB ”stored in the setting storage unit 308)” to the setting storage unit 308. Is requested (step S105). Hereinafter, this list may be referred to as a “connectable list”. The setting storage unit 308 transmits a connectable list to the control unit 310 (step S106).

  The control unit 310 compares the identifier of the “peripheral list” with the identifier of the “connectable list”. The control unit 310 determines that the fixed wireless LAN access point having the identifiers present in both lists is a fixed wireless LAN access point that exists in the vicinity of the mobile terminal 300 and can be connected (step S107). The control unit 310 sets this time as “access point discovery date and time (or time is acceptable)” and acquires date and time information from a predetermined time measuring unit (not shown). The control unit 310 instructs the setting storage unit 308 to update the “last discovered date” and “discovery frequency” in the wireless LAN client setting DB of the discovered fixed wireless LAN access point 350 (step S108). ). Receiving the update instruction, the setting storage unit 308 rewrites the “last discovered date” value in the wireless LAN client setting DB with the date information and increments the “discovery frequency” value (step S109).

  The control unit 310 selects one from those determined as “a fixed wireless LAN access point that exists in the vicinity and can be connected” in step S107. The control unit 310 instructs the wireless LAN interface unit 304 to connect to the selected wireless LAN access point (step S110). Here, when there are a plurality of fixed wireless LAN access points that exist in the vicinity and can be connected, the control unit 310 can select, for example, a fixed wireless LAN access point having the highest reception strength of the beacon signal. Alternatively, the control unit 310 can select the fixed wireless LAN access point having the highest priority (for example, the lowest number in FIG. 9). The wireless LAN interface unit 304 connects to the access point as a client (S111). If there is only one fixed wireless LAN access point that exists in the vicinity of the mobile terminal 300 and can be connected in step S107, that one access point is automatically selected. Good.

  FIG. 11 is a sequence chart for explaining an operation example of the wireless communication system 200 shown in FIG. 8 (specifically, an operation example when the mobile terminal 300 serves as an access point and accommodates the wireless LAN client terminal 400). It is.

  For example, the control unit 310 receives an instruction to activate the access point function from an operation input unit (not shown) (step S200). The control unit 310 requests the setting storage unit 308 for setting information regarding the fixed wireless LAN access point 350 for which the AP enable flag is on (step S201). The setting storage unit 308 extracts setting information regarding the fixed wireless LAN access point 350 whose AP enable flag is on, and transmits the setting information to the control unit 310 (step S202). For example, in FIG. 1 and no. The fixed wireless LAN access point 350 of No. 4 can be used as a setting when the wireless LAN interface unit 304 functions as an access point.

  The control unit 310 determines settings when the wireless LAN interface unit 304 functions as an access point (step S203). For example, when the AP enabled flag is set to ON, the control unit 310 automatically selects the setting. Further, when there are a plurality of settings where the AP enable flag is on, the control unit 310 selects any one of the settings. For example, the control unit 310 can select a setting with the latest date (time) found last (that is, closest to the current date (time)). Or the control part 310 can also select the setting with the highest discovery frequency. The “discovery frequency” may be “connection frequency (frequency at which the wireless LAN interface unit 304 connects to the fixed wireless LAN access point 350 as a client)”.

  The control unit 310 issues a request for converting “wireless LAN client setting” to “wireless LAN access point setting” to the setting conversion unit 312 (step S204). The setting conversion unit 312 converts the method for setting the IP address assigned to the wireless LAN interface unit 304 by the method described above (step S205). The setting conversion unit 312 transmits the converted setting to the control unit 310 (step S206).

  The control unit 310 changes the terminal setting so as to provide the same service as the service provided by the fixed wireless LAN access point 350 by using a part or all of the converted settings (step S207). The control unit 310 transmits the changed terminal setting and the access point function activation instruction to the wireless LAN interface unit 304 (step S208). The wireless LAN interface unit 304 activates the access point function based on the converted terminal setting (step S209). Thereafter, the wireless LAN interface unit 304 that has received a connection request from the wireless LAN client terminal 400 connects to the wireless LAN client terminal 400 (S210).

  As described above, when the mobile terminal 300 according to the fourth embodiment operates as a mobile access point, a part of “wireless LAN client setting” is automatically converted for “wireless LAN access point setting”. And use other settings.

  Therefore, when connecting the wireless LAN client terminal 400 to the mobile terminal 300 that operates as a mobile wireless LAN access point, the user accesses the mobile terminal 300 and the wireless LAN client terminal 400 using mobile wireless LAN access. There is no need to set a new point. Therefore, it is possible to greatly save the user's trouble.

Furthermore, since the settings of the fixed wireless LAN access point and the mobile wireless LAN access point are the same, it is not necessary to increase the setting of the mobile wireless LAN access point in the wireless LAN client terminal 400 separately. In general, the wireless LAN client terminal 400 has a limited number of network settings due to restrictions such as cost. However, as described above, since setting of a mobile wireless LAN access point is not necessary, another wireless LAN communication device (for example, another fixed wireless LAN access point) can be set accordingly. Therefore, a limited number of network settings can be used effectively. Furthermore, since the setting time can be saved, the usability of the wireless LAN client terminal 400 can be improved.
[Fifth Embodiment]
FIG. 12 is a block diagram illustrating a configuration example of a mobile terminal 500 according to the fifth embodiment of the present invention. The difference between the mobile terminal 500 and the mobile terminal 300 shown in FIG. 8 is that the mobile terminal 500 further includes an information presentation unit 502 (information presentation means). Therefore, since the other components are the same as those of the mobile terminal 300 shown in FIG. 8, their descriptions are omitted. Strictly speaking, however, a function for controlling the information presentation unit 502 is added to the control unit 310 shown in FIG.

  The information presentation unit 502 has a function of presenting setting information that can be used as a wireless LAN access point setting to the user and selecting setting information that the user wants to use.

  The operation of such a mobile terminal 500 will be described. In step S203 of FIG. 11, when there are a plurality of settings where the AP possible flag is on, in FIG. 11, it has been described that one of a plurality of settings is automatically selected based on the discovery date and discovery frequency. This automatic selection can be a manual selection using the information presentation unit 502. Specifically, the information presentation unit 502 receives a setting list whose AP enable flag is on from the control unit 310 (or directly from the setting storage unit 308), displays it on a display means (not shown), and uses it for the user. Select the setting you want. One of the settings is selected by the user, and the information presenting unit 502 transmits the selected setting to the control unit 310. Thereafter, processing similar to that in step S204 in FIG. 11 is executed.

  As described above, according to the fifth embodiment, the setting information that can be used as the wireless LAN access point setting is presented to the user, and the setting information to be used is selected. Accordingly, the setting information desired to be used can be selected from a viewpoint different from the automatic selection, and control with more variations can be performed.

  The fourth and fifth embodiments described above can be combined with the first to third embodiments. Specifically, for example, the details of the process (activation of the access point function) in step S4 in FIG. 3 may be a series of processes shown in steps S200 to S209 in FIG. In this case, as described above, the processing shown in FIG. 10 (that is, processing when the mobile terminal connects to the fixed wireless LAN access point as a client) can be executed together. Thereby, in step S203 of FIG. 11, when there are a plurality of ON-enabled flags, one of the plurality of settings can be automatically selected according to the discovery date and the discovery frequency. Of course, the execution of the process shown in FIG. 10 is not essential, and one of a plurality of settings can be “manually selected” by adopting the configuration of the mobile terminal as shown in the fifth embodiment. Needless to say.

  In the first to fifth embodiments described above, the case where the standard of the wireless communication network in the mobile terminal (the wireless communication network that is not the wide-area wireless communication network) is a wireless LAN is taken as an example. For example, another wireless communication standard having a standard similar to that of the wireless LAN can be used.

  In the first to fifth embodiments described above, the mobile terminals (mobile terminals 1, 12, 100, 300, and 500) have been described as being controlled by dedicated hardware. However, these mobile terminals can be controlled and operated by a computer circuit (for example, a CPU (Central Processing Unit)) (not shown) based on a control program. In this case, these control programs are stored in a storage medium (for example, a ROM (Read Only Memory) or a hard disk) inside the mobile terminal, or an external storage medium (for example, a removable medium or a removable disk). It is read and executed by a computer circuit.

DESCRIPTION OF SYMBOLS 1 Mobile terminal 2 Wireless communication part 3 Detection part 4 Control part 10 Wireless communication system 12 Mobile terminal 14 Fixed wireless LAN access point 16 Wireless LAN client terminal 20 Wireless LAN interface part 22 Detection part 24 Control part 100 Mobile terminal 102 Session management part 200 wireless communication system 300 mobile terminal 302 mobile network interface unit 304 wireless LAN interface 350 fixed portion 306 sets the input unit 308 setting storage unit 310 control unit 312 setting conversion unit 314 detector wireless LAN access point 400 wireless LAN client terminal 450 the mobile radio Base station 500 Mobile terminal 502 Information presentation unit

Claims (26)

A wireless communication means having a base station function capable of accommodating a portable terminal as a slave unit;
Detection means for detecting external base stations existing in the vicinity;
Control means for controlling the wireless communication means based on the detection result of the detection means;
A wireless communication apparatus comprising:   2. The wireless communication apparatus according to claim 1, wherein when there is no external base station in the vicinity, the control means instructs the wireless communication means to start up the base station function.   3. The wireless communication apparatus according to claim 1, wherein when there is an external base station in the vicinity, the control unit instructs the wireless communication unit to stop the base station function. 4.   In a state where the base station function is activated in the wireless communication means, if there is an external base station in the vicinity, the control means does not accept a new connection request from a portable terminal to the wireless communication means The wireless communication device according to claim 1, wherein the wireless communication device is instructed to do so.   When the wireless communication means is in a state where it does not accept a new connection request, when there is no external base station in the vicinity, the control means sends a new connection request by a portable terminal to the wireless communication means. The wireless communication apparatus according to claim 4, wherein the wireless communication apparatus instructs to accept the data.   The wireless communication means that has received an instruction not to accept a new connection request from the mobile terminal from the control means stops the mobile terminal from discovering itself by stopping transmission of the beacon signal. The wireless communication apparatus according to claim 4 or 5.   When the network identifier received from the external base station is the same as the preset network identifier and the reception strength of the received network identifier signal exceeds a predetermined threshold, the detecting means The wireless communication apparatus according to claim 2, wherein the wireless communication apparatus determines that there exists.   When the network identifier received from the external base station is not the same as the preset network identifier, or the signal identifier is below the predetermined threshold, the detection means has an external base station in the vicinity. The wireless communication apparatus according to claim 2, wherein it is determined that the wireless communication apparatus does not.   The wireless communication apparatus according to any one of claims 1 to 8, wherein the wireless communication unit further includes a slave unit function capable of being connected to an external base station as a slave unit. .   10. The wireless communication apparatus according to claim 9, further comprising setting conversion means for converting a setting as a slave unit into a setting as a base station when the wireless communication means activates the base station function.   11. The wireless communication apparatus according to claim 10, wherein the setting conversion means converts a setting related to an IP (Internet Protocol) address.   When there are a plurality of settings as slave units that can be converted and used as the settings of the base station, the control means is configured by the mobile terminal in each external base station corresponding to the settings as each slave unit. 12. The wireless communication apparatus according to claim 10, wherein a setting of an external base station having the latest discovery time is selected.   When there are a plurality of settings as slave units that can be converted and used as the setting of the base station, the control means includes the mobile terminal in each external base station corresponding to the settings as each slave unit. 12. The wireless communication apparatus according to claim 10, wherein a setting of an external base station having the highest connection frequency is selected.   When there are a plurality of settings as slave units that can be converted and used as the setting of the base station, information presenting means for presenting the plurality of settings to the user and selecting any one of the settings is provided. The wireless communication apparatus according to claim 10, further comprising:   The wireless communication apparatus according to claim 1, wherein the wireless communication standard in the wireless communication unit is a wireless LAN standard. An external base station,
A mobile device,
A wireless communication device,
The wireless communication device comprises a wireless communication means having a base station function capable of accommodating the portable terminal as a slave unit;
Detection means for detecting external base stations existing in the vicinity;
Control means for controlling the wireless communication means based on the detection result of the detection means;
A wireless communication system comprising:   17. The wireless communication system according to claim 16, wherein when there is no external base station in the vicinity, the control unit instructs the wireless communication unit to start the base station function.   18. The radio communication system according to claim 16, wherein, when an external base station exists in the vicinity, the control unit instructs the radio communication unit to stop the base station function.   In a state where the base station function is activated in the wireless communication means, if there is an external base station in the vicinity, the control means does not accept a new connection request from a portable terminal to the wireless communication means The wireless communication system according to any one of claims 16 to 18, characterized by:   When the wireless communication means is in a state where it does not accept a new connection request, when there is no external base station in the vicinity, the control means sends a new connection request by a portable terminal to the wireless communication means. The wireless communication system according to claim 19, wherein the wireless communication system instructs to accept the request. A communication control method in a wireless communication device having a base station function capable of accommodating a mobile terminal as a slave unit,
Detect external base stations in the vicinity,
The communication control method, wherein the wireless communication device is controlled based on the detection result.   The communication control method according to claim 21, wherein when there is no external base station in the vicinity, the wireless communication device activates the base station function.   23. The communication control method according to claim 21, wherein the radio communication device stops the base station function when an external base station exists in the vicinity.   The wireless communication device does not accept a new connection request by a mobile terminal when an external base station exists in the vicinity in a state where the base station function is activated in the wireless communication device. The communication control method according to any one of 21 to 23.   When the wireless communication device is in a state where it does not accept a new connection request, when there is no external base station in the vicinity, the wireless communication device accepts a new connection request from a mobile terminal. The communication control method according to claim 24. A control program for causing a computer of a wireless communication apparatus having a base station function capable of accommodating a portable terminal as a slave unit,
A process for detecting external base stations in the vicinity;
A control program causing the computer to execute processing for controlling the wireless communication device based on the detection result.

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