JP2013141127A - Portable terminal, wireless lan connection system, and wireless lan connection method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a portable terminal which controls a wireless LAN function by turning it on or off as appropriate to save power consumption, and which can share WLAN connection setting information with other terminals.SOLUTION: The portable terminal comprises: a WLAN section which executes beacon signal reception/transmission, synchronization and connection negotiation; a parameter generation section which generates parameters indicating WLAN connection setting information and beacon signal transmission position information; a mail generation section which generates a mail to notify the parameters; a mail transmission section which transmits the mail to portable terminals belonging to a group; a mail receiving section which receives mails; a location information acquisition section which acquires the terminal's own location by receiving a mail; a determination section which outputs a WLAN setting signal when the distance between the beacon signal transmission position information notified by the received mail and the terminal's own location becomes equal to or less than a predetermined value; and a WLAN management section which, upon acquiring the WLAN setting signal, turns the function of the WLAN section on and alters WLAN connection settings on the basis of the acquired or generated WLAN connection setting information.

Description

  The present invention relates to a mobile terminal that constructs a mobile network, a wireless LAN connection system, and a wireless LAN connection method.

  In recent years, social network services such as Twitter (registered trademark), Facebook (registered trademark), Google+ (registered trademark), blogs, video posting sites such as YouTube (registered trademark) and Nico Nico Douga (registered trademark), Picasa (registered trademark) ), Various information sharing services such as photo sharing services such as myPicturetown (registered trademark) have been born. By applying these information sharing services and mobile network technology in combination, members gathered for a certain purpose in a certain place in a group such as a company, a circle, or member members. By simply building a local area network (LAN, mainly wireless LAN, and wireless LAN is also referred to as WLAN in this specification), you can freely share information that only attendees in the group need to share, such as conference materials and videos. It is considered that services that can communicate and share with each other will become popular.

  This shared service, for example, wants to provide information about classes to students (members) attending on that day among students (groups) of university classes. It can be used when you do not want to provide information or do not need to provide information to students who do not. The same applies to the case where it is desired to provide coupon information only to customers (members) who visit the store on the day of the event among customers (groups) who have registered as members of the store. Furthermore, the same applies to the case where it is desired to distribute electronic materials only to employees (groups) who belong to the same day among employees (groups) who belong to the same department at workplace meetings. Here, it is assumed that the aforementioned group (company, circle, member member, etc.) has means for broadcasting certain information to all members who belong to the group in advance. Examples of the means for broadcasting include a broadcast mail (mailing list), a broadcast SMS, and Twitter. Further, the above-mentioned group is not necessarily composed of only members belonging to a single community such as a company. Therefore, setting information for LAN construction may not be shared between members in the group.

  As an example of a conventional technique for performing communication between wireless communication devices in which a wireless LAN module is mounted, Patent Document 1 is available. The wireless communication device disclosed in Patent Document 1 aims to avoid the complexity of manually switching the wireless connection mode of the wireless communication device to either the ad hoc mode or the infrastructure mode. In Patent Document 1, one wireless communication device in a wireless communication system configured by a plurality of wireless communication devices has a plurality of wireless connection modes in a wireless LAN communication system, and another wireless communication device to be wirelessly connected is used. A wireless connection mode switching unit that switches a wireless connection mode of the wireless communication device according to a wireless connection mode to be used, and a wireless connection mode that is switched by the wireless connection mode switching unit, And a wireless LAN connection unit for connection.

  Hereinafter, a LAN construction procedure (conventional method) in the case of performing communication between portable terminals equipped with a wireless LAN module will be described in detail with reference to FIG. FIG. 1 is a diagram showing an outline of operations performed by a conventional portable terminal 900 that performs communication between terminals. FIG. 1A is a diagram illustrating an outline of operations performed by each mobile terminal 900 when communication is performed between two mobile terminals 900. FIG. 1B is a diagram illustrating an outline of operations performed by each mobile terminal when communication is performed between three or more mobile terminals 900. In order for the portable terminals 900 to perform local wireless communication, it is necessary to first synchronize with each other and then to negotiate for connection. As shown in FIG. 1A, when a terminal-to-terminal communication environment is constructed with two portable terminals using the portable terminal A 900a as a parent terminal and the portable terminal B 900b as a child terminal, the portable terminal A 900a is first required for synchronization. A beacon signal is transmitted (arrow with number 1 in the figure). The beacon signal also includes SSID (Service Set Identifier, service set identifier) information for the mobile terminal B 900b to identify the mobile terminal A 900a. The portable terminal B 900b searches for a wireless channel in order to receive a beacon signal. When the mobile terminal B 900b can receive the beacon signal transmitted by the mobile terminal A 900a, the mobile terminal B 900b uses the received beacon signal to synchronize with the mobile terminal A 900a (broken arrow with number 2 in the figure). When the synchronization is successful, the mobile terminal A 900a and the mobile terminal B 900b perform negotiation (security setting, IP address assignment) for connection (broken arrow with number 3 in the figure). The same applies when the number of connected mobile terminals increases as shown in FIG. First, the portable terminal A 900a transmits a beacon signal necessary for synchronization (an arrow with a number 1 in the figure). The mobile terminal B 900b, the mobile terminal C 900c, and the mobile terminal D 900d search for a wireless channel in order to receive a beacon signal. When the mobile terminal B 900b (mobile terminal C 900c, mobile terminal D 900d) can receive the beacon signal transmitted by the mobile terminal A 900a, the mobile terminal B 900b (mobile terminal C 900c, mobile terminal D 900d) uses the received beacon signal to carry it. Synchronize with the terminal A 900a (broken arrow with number 2 in the figure). When the synchronization is successful, the mobile terminal A 900a to the mobile terminal D 900d negotiate for connection (security setting, IP address assignment) (dashed arrow with number 3 in the figure).

  Hereinafter, with reference to FIG. 2 and FIG. 3, the connection operation when the conventional mobile terminal 900 performs inter-terminal communication as described above will be described in which the operation of each component is clarified. FIG. 2 is a block diagram showing a configuration of a conventional portable terminal 900 that performs communication between terminals. FIG. 3 is a flowchart showing the operation of a conventional portable terminal 900 that performs communication between terminals. In the description of FIG. 2 and FIG. 3, only the case where there are two mobile terminals 900 (mobile terminal A 900a and mobile terminal B 900b) will be described for convenience. However, as described above, even when there are three or more mobile terminals 900 Inter-terminal communication can be realized by the same component. The conventional portable terminal A 900a and portable terminal B 900b include a WLAN unit 910 that transmits and receives beacon signals and executes synchronization processing and connection negotiation processing according to preset WLAN connection settings, and a control unit 970. The portable terminal 900 performs each process based on control of the control part 970. FIG. The WLAN unit 910 includes a beacon generation unit 911, a WLAN transmission unit 912, a WLAN reception unit 913, a synchronization processing unit 914, and a negotiation unit 915. The beacon generating means 911 of the portable terminal A 900a generates a beacon signal necessary for synchronization. The WLAN transmission means 912 of the portable terminal A 900a transmits the generated beacon signal to the portable terminal B 900b (SS912). The portable terminal B 900b searches for a wireless channel in order to receive a beacon signal. The WLAN receiving unit 913 of the mobile terminal B 900b receives the beacon signal transmitted by the mobile terminal A 900a (SS913). The synchronization processing unit 914 of the portable terminal B 900b synchronizes with the portable terminal A 900a using the received beacon signal (SS914). When the synchronization is successful, the negotiation unit 915 of the portable terminal A 900a and the portable terminal B 900b negotiates for connection (SS915a, SS915b). At the time of connection negotiation, it is necessary to match the security settings between the mobile terminal A 900a and the mobile terminal B 900b. If these settings cannot be shared, connection between terminals is impossible.

JP 2010-093652 A

  Hereinafter, with reference to FIG. 4, the problem of the prior art which the present invention solves will be described. FIG. 4 is a diagram for explaining the problems of the prior art that the present invention solves. FIG. 4A illustrates power consumption, which is the first problem of the conventional technology. FIG. 4B illustrates the sharing of WLAN connection setting information, which is the second problem of the prior art.

<Power consumption>
In a conventional connection method for inter-terminal communication by a mobile terminal, a parent terminal (mobile terminal A 900a in the example of FIG. 1) needs to be triggered to transmit a beacon signal. In this case, the child terminals (terminals other than the parent terminal that intend to participate in the communication between the terminals, the portable terminal B 900b, the portable terminal C 900c, and the portable terminal D 900d in the example of FIG. 1) wirelessly match the beacon signal transmission timing of the parent terminal. A channel search needs to be performed. Therefore, when the wireless LAN function and the wireless LAN interface of the child terminal are OFF, the wireless channel cannot be searched, so the beacon signal cannot be received and the subsequent synchronization processing can be executed. As a result, communication between terminals cannot be established. If the wireless LAN function is always ON, continuous communication is possible, but this is a problem from the viewpoint of power saving. If the user of the child terminal is notified of the transmission of the beacon signal by any method, the wireless terminal function can be turned on / off by manual operation of the child terminal user, but this is problematic for the user. Ideally, the wireless LAN function is turned on at the same time when the parent terminal transmits a beacon signal or immediately before the child terminal does not go through user operation, and the wireless LAN is always turned off in other scenes. .

<Sharing of WLAN connection setting information>
In addition, even when the child terminal has succeeded in searching for a wireless channel, various setting information necessary for connection such as security settings in advance between the parent terminal and the child terminal (this is referred to as WLAN connection setting in this specification). If it is not shared, connection negotiation cannot be performed and communication between terminals cannot be established. As described above, in the service of building a WLAN by only attendees among members in a group and sharing information, the group is not necessarily composed only of members belonging to a single community such as a company, In some cases, WLAN connection setting information is not shared among members in the group. Such a problem related to sharing of WLAN connection setting information is a problem from the viewpoint of providing a stable service.

  Therefore, the present invention provides a portable terminal that can save power by performing ON / OFF control of the wireless LAN function in a timely manner and can share WLAN connection setting information between portable terminals participating in the communication between terminals. The purpose is to do.

  The portable terminal of the present invention includes a WLAN unit, a parameter generation unit, a mail generation unit, a mail transmission unit, a mail reception unit, a mail analysis unit, a position acquisition unit, a determination unit, and a WLAN management unit. Prepare.

  The WLAN unit transmits and receives beacon signals and executes synchronization processing and connection negotiation processing according to preset WLAN connection settings. The parameter generation unit generates parameters indicating WLAN connection setting information and beacon signal transmission position information and outputs a WLAN setting signal. The mail generation unit generates a mail notifying the generated parameters. The mail transmission unit transmits the generated mail to mobile terminals belonging to a predetermined group. The mail receiving unit receives the transmitted mail. The mail analysis unit analyzes the received mail and acquires parameters. The position acquisition unit acquires its own position when receiving a mail. The determination unit outputs a WLAN setting signal when the distance between the beacon signal transmission position information indicated by the parameter and the acquired own position is equal to or less than a predetermined value. When the WLAN management unit obtains the WLAN setting signal, the WLAN unit function is turned on, and the WLAN connection setting of the WLAN unit is changed based on the WLAN connection setting information indicated in the acquired or generated parameter. To do.

  According to the portable terminal of the present invention, power saving can be realized by performing ON / OFF control of the wireless LAN function in a timely manner, and the WLAN connection setting information can be shared between portable terminals participating in inter-terminal communication.

The figure which shows the outline of the operation | movement which the conventional portable terminal which communicates between terminals performs. The block diagram which shows the structure of the conventional portable terminal which communicates between terminals. The flowchart which shows operation | movement of the conventional portable terminal which communicates between terminals. The figure explaining the subject of the prior art which this invention solves. The figure which shows the outline of the operation | movement which the portable terminal (2 units | sets) of Example 1 performs. The figure which shows the outline of the operation | movement which the portable terminal (3 or more) of Example 1 performs. The figure which illustrates the parameter which the parameter generation part of the portable terminal of the present invention generates. 1 is a block diagram illustrating a configuration of a mobile terminal according to a first embodiment. 5 is a flowchart illustrating the operation of the mobile terminal according to the first embodiment. The figure which shows the outline of the operation | movement which the portable terminal (2 units | sets) of Example 2 performs. The figure which shows the outline of the operation | movement which the portable terminal (3 or more) of Example 2 performs. FIG. 4 is a block diagram illustrating a configuration of a mobile terminal according to a second embodiment. 9 is a flowchart illustrating the operation of the mobile terminal according to the second embodiment. FIG. 10 is a diagram illustrating an outline of operations performed by the wireless LAN connection system according to the third embodiment. FIG. 9 is a block diagram illustrating a configuration of a wireless LAN connection system according to a third embodiment. 10 is a flowchart illustrating the operation of the wireless LAN connection system according to the third embodiment. FIG. 10 is a diagram illustrating an outline of operations performed by the wireless LAN connection system according to the fourth embodiment. FIG. 9 is a block diagram illustrating a configuration of a wireless LAN connection system according to a fourth embodiment. 10 is a flowchart illustrating the operation of the wireless LAN connection system according to the fourth embodiment.

  Hereinafter, embodiments of the present invention will be described in detail. In addition, the same number is attached | subjected to the structure part which has the same function, and duplication description is abbreviate | omitted.

<Group>
In this specification, the term “group” means a set of portable terminals that are allowed to share information through inter-terminal communication. Group information can be managed on a mailing list or on a server.

<Parent terminal>
In this specification, the term “parent terminal” refers to a mobile terminal that transmits a beacon signal and triggers the start of communication between terminals among mobile terminals belonging to a group.

<Child terminal>
In this specification, the term “child terminal” refers to a mobile terminal other than a parent terminal among mobile terminals belonging to a group. The child terminal receives the beacon signal from the parent terminal and starts communication between terminals.

  The outline of the operation of the portable terminal of the first embodiment which is the most basic configuration example of the present invention will be described below with reference to FIGS. FIG. 5 is a diagram showing an outline of operations performed by the portable terminals 100 (two) of the present embodiment. FIG. 6 is a diagram illustrating an outline of operations performed by the mobile terminal 100 (three or more) according to the present embodiment. First, as shown in FIG. 5, a case where there are two mobile terminals 100 (mobile terminal A 100a and mobile terminal B 100b) in the present embodiment and the parent terminal is the mobile terminal A 100a will be described. In this case, the portable terminal A 100a instructs the WLAN connection setting information such as security and the beacon signal transmission position information to the portable terminal B 100b which is a child terminal using a broadcast mail (such as ML) (number 1 in the figure). Arrow with). The portable terminal A 100a transmits a beacon signal simultaneously with the mail transmission or after a predetermined time has elapsed since the mail transmission (an arrow with a number 2 in the figure). The mobile terminal B 100b acquires the current position of its own terminal using the reception of mail from the mobile terminal A 100a as a trigger, and the beacon of the mobile terminal A 100a indicated by the current position and the parameters described in the mail from the mobile terminal A 100a. It is determined whether or not the signal transmission position is close enough to allow wireless LAN connection. If the mobile terminal B 100b determines that the current position of the mobile terminal B and the beacon signal transmission position of the mobile terminal A 100a are close enough to enable wireless LAN connection, the mobile terminal B 100b turns on the wireless LAN function and sends a mail. The WLAN connection setting is changed according to the WLAN connection setting information indicated in the described parameter. Specifically, the mobile terminal B 100b synchronizes with the mobile terminal A 100a based on the WLAN connection setting information indicated in the parameters (broken arrow with number 3 in the figure). After the synchronization processing, the mobile terminal A 100a and the mobile terminal B 100b perform connection negotiation based on the WLAN connection setting information indicated by the parameters (dashed arrow with number 4 in the figure).

  As shown in FIG. 6, the same applies to the case where there are three or more mobile terminals 100 (mobile terminals A100a to G100g) and the parent terminal is the mobile terminal A100a. The mobile terminal A 100a instructs the WLAN connection setting information such as security and the beacon signal transmission position information to the mobile terminals B 100b to G 100g, which are the child terminals, using broadcast mail (such as ML) (number in the figure). Arrow with 1). The portable terminal A 100a transmits a beacon signal simultaneously with the mail transmission or after a predetermined time has elapsed since the mail transmission (an arrow with a number 2 in the figure). The mobile terminals B100b to G100g acquire the current position of the terminal by using the reception of mail from the mobile terminal A100a as a trigger, and the mobile position indicated in the parameters described in the current position and the mail from the mobile terminal A100a. It is determined whether or not the beacon signal transmission position of the terminal A 100a is close enough to the extent that wireless LAN connection is possible. In FIG. 6, the area where wireless LAN connection is possible is expressed as an area inside the circle. The mobile terminal B100b, the mobile terminal C100c, the mobile terminal D100d, and the mobile terminal E100e that exist in an area where wireless LAN connection is possible can establish a wireless LAN connection between the current position of the mobile terminal A100a and the beacon signal transmission position of the mobile terminal A100a. The wireless LAN function is turned on, and the WLAN connection setting is changed according to the WLAN connection setting information indicated in the parameter described in the mail. Specifically, the mobile terminal B 100b, the mobile terminal C 100c, the mobile terminal D 100d, and the mobile terminal E 100e synchronize with the mobile terminal A 100a based on the WLAN connection setting information indicated by the parameters (broken arrow with number 3 in the figure). ). After the synchronization processing, the mobile terminal A 100a to the mobile terminal E 100e perform connection negotiation based on the WLAN connection setting information indicated by the parameters (dashed arrow with number 4 in the figure).

  On the other hand, in the mobile terminal F100f and the mobile terminal G100g that exist outside the area where wireless LAN connection is possible, the current position of the mobile terminal and the beacon signal transmission position of the mobile terminal A100a are close enough that wireless LAN connection is possible. It is determined that the wireless LAN function is not turned on, and control, synchronization processing, and connection negotiation are not performed. Therefore, the wireless LAN functions of the portable terminal F100f and the portable terminal G100g that exist outside the area where wireless LAN connection is possible remain OFF.

  Hereinafter, the configuration and operation of the mobile terminal 100 according to the present embodiment will be described in detail with reference to FIGS. 8 and 9. FIG. 8 is a block diagram illustrating the configuration of the mobile terminal 100 according to the present embodiment. FIG. 9 is a flowchart showing the operation of the mobile terminal 100 of the present embodiment.

  As shown in FIG. 8, the mobile terminal 100 of the present embodiment includes a WLAN unit 910, a parameter generation unit 110, a mail generation unit 120, a mail transmission unit 130, a mail reception unit 140, a mail analysis unit 150, A location acquisition unit 160, a control unit 170, a determination unit 180, and a WLAN management unit 190 are provided. The WLAN unit 910 includes a beacon generation unit 911, a WLAN transmission unit 912, a WLAN reception unit 913, a synchronization processing unit 914, and a negotiation unit 915, like the conventional mobile terminal described with reference to FIG. Although FIG. 8 describes and describes only two portable terminals (portable terminal A 100a and portable terminal B 100b) for convenience, even when there are three or more portable terminals 100, the same effect can be obtained by the same components. Yes (see description of FIG. 6). Note that the mobile terminal 100 executes each process based on the control of the control unit 170.

  First, the parameter generation unit 110 of the mobile terminal A 100a generates a parameter indicating WLAN connection setting information and beacon signal transmission position information and outputs a WLAN setting signal (S110). The WLAN setting signal will be described later. Here, the parameters generated by the parameter generation unit 110 will be described with reference to FIG. FIG. 7 is a diagram illustrating a parameter 110-1 generated by the parameter generation unit 110 of the mobile terminal 100 according to the present embodiment. As the parameter 110-1, for example, as shown in FIG. 7, SSID (service set identifier), wireless channel, security method, security key, scheduled beacon signal transmission time, and beacon signal transmission position information can be specified. In the example of FIG. 7, SSID = musenlan-a, wireless channel = 802.11g, 6CH, security method = WEP, security key = 123456, scheduled beacon signal transmission time = 15: 00 on September 15, 2011, beacon signal Transmission position information (latitude, longitude) = (35.668954, 139.691318) is designated. In this embodiment, the scheduled beacon signal transmission time is not an essential parameter, but other parameters are essential. In the example of FIG. 7, the beacon signal transmission position information is specified by (latitude, longitude). However, the present invention is not limited to this, and a method of specifying the beacon signal transmission position information using the base station ID may be used. Some or all of the parameters generated by the parameter generation unit 110 may be manually determined by the user of the mobile terminal A 100a that is the parent terminal. When the user manually sets the beacon signal transmission position information, a database for converting address information into latitude and longitude information is stored in any storage area in the mobile terminal 100, and the address information specified by the user is stored. The information may be automatically converted into latitude and longitude information, and the parameter generation unit 110 may include the information as beacon signal transmission position information in the parameter. In the present embodiment, the above-described WLAN connection setting information specifically includes SSID, wireless channel, security method, and security key.

  Next, the mail generation unit 120 of the mobile terminal A 100a generates a mail notifying the generated parameters (S120). The mail transmitting unit 130 of the mobile terminal A 100a transmits the generated mail to the mobile terminals belonging to the predetermined group (the mobile terminal B 100b in the example of FIG. 8) (S130).

  The mail receiving unit 140 of the mobile terminal B 100b receives the mail transmitted from the mobile terminal A 100a (S140). The mail analysis unit 150 of the mobile terminal B 100b analyzes the received mail and acquires parameters (S150). The position acquisition unit 160 of the mobile terminal B 100b acquires its own position when receiving an email (S160). The determination unit 180 of the portable terminal B 100b outputs a WLAN setting signal when the distance between the beacon signal transmission position information indicated by the parameter and the acquired own position is equal to or less than a predetermined value (S180Y). Here, the “predetermined value” can be set, for example, on the order of several tens of meters. If the distance between the beacon signal transmission position information indicated in the parameter and the acquired own position is not less than or equal to a predetermined value (S180N), step S190 is not performed (END). When acquiring the WLAN setting signal from the determination unit 180, the WLAN management unit 190 of the portable terminal B 100b turns on the function of the WLAN unit 910 and sets the WLAN connection setting information (SSID, wireless) indicated in the acquired parameter. Based on the channel, security method, and security key, the WLAN connection setting of the WLAN unit 910 is changed (S190).

  On the other hand, when the WLAN management unit 190 of the mobile terminal A 100a that is the parent terminal acquires a WLAN setting signal from the parameter generation unit 110, the WLAN management unit 190 turns on the function of the WLAN unit 910 and sets the parameters generated by the parameter generation unit 110 to Based on the indicated WLAN connection setting information (SSID, wireless channel, security method, security key), the WLAN connection setting of the WLAN unit 910 is changed (S190).

  The WLAN units 910 of the mobile terminal A 100a and the mobile terminal B 100b transmit and receive beacon signals, and execute synchronization processing and connection negotiation processing according to the WLAN connection settings changed in step S190 (SS912, SS913, SS914, SS915).

  As described above, according to the mobile terminal 100 of the present embodiment, all the mobile phones belonging to the group predetermined by the mail transmitting unit 130 of the parent terminal are notified of the broadcast mail that notifies the parameter generated by the parameter generating unit 110 of the parent terminal. By distributing to the terminal (child terminal), the parent terminal's beacon signal transmission position and WLAN connection setting information can be shared between the parent terminal and the child terminal. Only the WLAN management unit 190 of the child terminal that is capable of LAN connection and is close enough to some extent turns on the wireless LAN function and changes the WLAN connection setting, thereby realizing power saving, and the parent terminal-child terminal WLAN connection setting information can be shared between them.

  Hereinafter, an outline of the operation of the mobile terminal of the second embodiment in which a function for broadcasting including the scheduled beacon signal transmission time is added to the mobile terminal of the first embodiment will be described with reference to FIGS. FIG. 10 is a diagram illustrating an outline of operations performed by the mobile terminals 200 (two) according to the present embodiment. FIG. 11 is a diagram illustrating an outline of operations performed by the mobile terminal 200 (three or more) according to the present embodiment. As shown in FIGS. 10 and 11, the difference between the mobile terminal 200 of the present embodiment and the mobile terminal 100 of the first embodiment is that a new beacon signal is transmitted in the parameter indicated in the broadcast mail indicated by the arrow number 1 in the figure. This is the point where the scheduled time is added. When the portable terminal B 200b receives a mail from the portable terminal A 200a, the position of the terminal itself is triggered by the arrival of the scheduled beacon signal transmission time (or a time before the scheduled beacon signal time) described in the mail. And determines whether or not the position and the beacon signal transmission position of the portable terminal A 200a indicated by the parameters are close enough to enable wireless LAN connection. When the mobile terminal B 200b determines that the position of the mobile terminal A and the beacon signal transmission position of the mobile terminal A 200a are close enough to allow wireless LAN connection, the mobile terminal B 200b turns on the wireless LAN function and writes it in the mail. The WLAN connection setting is changed in accordance with the WLAN connection setting information indicated in the designated parameter. Since the same applies to the case of FIG.

  Hereinafter, the configuration and operation of the mobile terminal 200 according to the present embodiment will be described in detail with reference to FIGS. 12 and 13. FIG. 12 is a block diagram showing the configuration of the mobile terminal 200 of this embodiment. FIG. 13 is a flowchart showing the operation of the mobile terminal 200 of this embodiment.

  As shown in FIG. 12, the mobile terminal 200 of this embodiment includes a WLAN unit 910, a parameter generation unit 210, a mail generation unit 120, a mail transmission unit 130, a mail reception unit 140, a mail analysis unit 150, A location acquisition unit 260, a control unit 170, a determination unit 180, and a WLAN management unit 190 are provided. Since each component other than the parameter generation unit 210 and the position acquisition unit 260 of the mobile terminal 200 of the present embodiment performs the same operation as each component assigned the same number in the mobile terminal 100 of the first embodiment, description thereof is omitted. . Although FIG. 12 describes and describes only two portable terminals (mobile terminal A 200a and portable terminal B 200b) for convenience, even when there are three or more portable terminals 200, the same effect can be obtained by the same components. Yes (see description of FIG. 11). Note that the portable terminal 200 executes each process based on the control of the control unit 170.

  Hereinafter, operations of the parameter generation unit 210 and the position acquisition unit 260 that are different from the first embodiment will be described. The parameter generation unit 210 of the mobile terminal A 200a, which is the parent terminal, generates a parameter indicating the scheduled beacon signal transmission time in addition to the aforementioned WLAN connection setting information and beacon signal transmission position information (S210). Therefore, the parameters generated here include all of the WLAN connection setting information, the beacon signal transmission position information, and the scheduled beacon signal transmission time, like the parameter 110-1 illustrated in FIG. Thereafter, steps S120, S130, S140, and S150 are executed in the same manner as in the first embodiment. Next, when the difference between the current time and the scheduled beacon signal transmission time indicated by the parameter is equal to or smaller than a predetermined value, the position acquisition unit 260 of the mobile terminal B 200b that is the child terminal acquires its own position (S260). Therefore, the position acquisition unit 260 of the mobile terminal 200 has a function of acquiring the current time from a time display built-in crystal resonator, a time server, or the like (not shown in FIG. 12). Thereafter, step S180 is executed in the same manner as in the first embodiment.

  In this embodiment, since the mobile terminal A 200a as the parent terminal determines the scheduled beacon signal transmission time, the change of the WLAN connection setting of the mobile terminal A 200a as the parent terminal (S190) and the beacon signal transmission (SS 912) are The beacon signal transmission scheduled time elapses or the time elapse of a predetermined time before the beacon signal transmission scheduled time (S170Y) is executed as a trigger. As in the first embodiment, when the WLAN management unit 190 acquires the WLAN setting signal from the determination unit 180, the function of the WLAN unit 910 is turned on and the acquired parameter is set to the acquired parameter for the mobile terminal B 200b that is the child terminal. Based on the indicated WLAN connection setting information, the WLAN connection setting of the WLAN unit 910 is changed (S190). Hereinafter, the WLAN unit 910 of the mobile terminal A 200a and the mobile terminal B 200b performs a synchronization process and a connection negotiation process according to the reception of the beacon signal and the WLAN connection setting changed in step S190 (SS913, SS914, SS915).

  As described above, according to the mobile terminal 200 of this embodiment, the parameter generation unit 210 of the parent terminal generates a parameter including the scheduled beacon signal transmission time notified by the user of the parent terminal, and sends a broadcast mail notifying the parameter. The parent terminal mail transmission unit 130 distributes to all portable terminals (child terminals) belonging to a predetermined group, so that the parent terminal beacon signal transmission scheduled time and the beacon signal transmission position between the parent terminal and the child terminal. WLAN connection setting information can be shared, and only the WLAN management unit 190 of the child terminals belonging to the group, which are close enough to the parent terminal so that wireless LAN connection is possible at the scheduled time, In order to change the WLAN connection setting by turning on the wireless LAN function, in addition to the effect of the first embodiment, it exists near the time desired by the user of the parent terminal It is possible to start communication between Turkey terminal and the terminal, it is possible to improve the convenience of the user.

  Hereinafter, an outline of the operation of the wireless LAN connection system according to the third embodiment in which a system equivalent to the portable terminal 100 according to the first embodiment is realized by a portable terminal and a server will be described with reference to FIG. FIG. 14 is a diagram showing an outline of operations performed by the wireless LAN connection system 1 of the present embodiment. In the present embodiment, the mobile terminal A 300a which is the parent terminal does not send a broadcast mail to all the child terminals using the mailing list, but sends a mail notifying parameters to the server 10 (number 1 in the figure). Arrow). It is assumed that the server 10 manages area information of all mobile terminals belonging to the group. The server 10 that has received the mail from the mobile terminal A300a that is the parent terminal determines the child terminals that exist around the mobile terminal A300a that is the parent terminal from the area information that it manages, for example, FIG. The above-mentioned mail is transmitted only to the mobile terminal B 300b and the mobile terminal H 300h that are in the same area as the mobile terminal A 300a that is the parent terminal (an arrow with a number 2 in the figure). Thereafter, as in the first and second embodiments, synchronization processing and connection negotiation processing are performed between the child terminal (mobile terminal B300b, mobile terminal H300h) that has received the mail and the parent terminal (mobile terminal A300a). Here, the area setting method illustrated in FIG. 14 and the determination method of whether or not the area to which the parent terminal and the child terminal belong are the same. For example, the child terminal belongs to the same base station periphery as the parent terminal. It can also be decided based on whether or not. Further, for example, determination may be made based on whether or not a child terminal belongs to an area where a parent terminal exists among areas divided into a mesh shape on the order of several tens of meters on the basis of latitude and longitude. In addition, for example, the mail transmitted from the parent terminal is analyzed, and it is determined whether or not the child terminal exists within a predetermined distance range from the point indicated by the beacon signal transmission position information described in the mail. May be.

  Hereinafter, the configuration and operation of the wireless LAN connection system according to the third embodiment will be described in detail with reference to FIGS. 15 and 16. FIG. 15 is a block diagram showing the configuration of the wireless LAN connection system 1 of this embodiment. FIG. 16 is a flowchart showing the operation of the wireless LAN connection system 1 of the present embodiment.

  As shown in FIG. 15, the wireless LAN connection system 1 of this embodiment includes a mobile terminal 300 and a server 10. The mobile terminal 300 includes a WLAN unit 910, a parameter generation unit 110, a mail generation unit 120, a mail transmission unit 130, a mail reception unit 140, a mail analysis unit 150, a control unit 170, a WLAN management unit 190, Is provided. The WLAN unit 910 includes a beacon generation unit 911, a WLAN transmission unit 912, a WLAN reception unit 913, a synchronization processing unit 914, and a negotiation unit 915 (not shown) in the same manner as the conventional portable terminal described in FIG. . The server 10 includes a mail transmission unit 13, a mail reception unit 14, a mail analysis unit 15, a terminal position acquisition unit 16, and a control unit 17. FIG. 15 illustrates only two mobile terminals (mobile terminal A 300a and mobile terminal B 300b) for convenience, but even when there are three or more mobile terminals 300, the same effect can be obtained by the same components. Yes (see description of FIG. 14). The portable terminal 300 executes each process based on the control of the control unit 170, and the server 10 executes each process based on the control of the control unit 17.

  First, the parameter generation unit 110 of the mobile terminal A 300a which is the parent terminal generates a parameter indicating WLAN connection setting information (S110). In this embodiment, the only information necessary as a parameter is the WLAN connection setting information. However, as described above, whether the child terminal exists within a predetermined distance from the point indicated by the beacon signal transmission position information for determining whether or not the area to which the parent terminal and the child terminal belong is the same as the server 10 In the case of a determination method based on “no”, it is necessary to add beacon signal transmission position information as a parameter. Next, the mail generation unit 120 of the mobile terminal A300a that is the parent terminal generates a mail notifying the generated parameters (S120). The mail transmission unit 130 of the mobile terminal A 300a that is the parent terminal transmits the generated mail to the server 10 (S130).

  Next, the mail receiver 14 of the server 10 receives the mail transmitted from the mobile terminal A 300a that is the parent terminal (S14). The mail analysis unit 15 of the server 10 analyzes the mail received from the mobile terminal A300a that is the parent terminal, and acquires parameters (S15). Here, as described above, when the server 10 determines whether or not the area to which the parent terminal and the child terminal belong is the same, whether or not the child terminal belongs to the periphery of the same base station as the parent terminal It is described in an email sent by the parent terminal, such as when determining whether a child terminal belongs to an area where the parent terminal exists among areas divided into meshes on the order of several tens of meters based on latitude and longitude. If the same area can be determined without depending on the beacon signal transmission position information, the mail analysis unit 15 and step S15 are unnecessary. In this case, the server 10 may transmit the mail received from the mobile terminal A 300a as the parent terminal to all the child terminals belonging to the same area without analyzing the mail. Next, the terminal position acquisition unit 16 of the server 10 acquires the positions of the mobile terminal A300a that is the parent terminal that transmitted the mail and all the child terminals that belong to the group to which the mobile terminal A300a that is the parent terminal belongs (S16). . Here, the terminal position acquisition unit 16 of the server 10 may acquire the position of the child terminal as the name of one of the areas defined above. The terminal position acquisition unit 16 of the server 10 can acquire the base station ID as the terminal position, for example, when the area is determined based on the base station. In addition, when an area divided into meshes of the order of several tens of meters based on latitude and longitude is defined as an area, the area number can be acquired as the terminal position. When defining the same area as a predetermined distance from the point indicated by the beacon signal transmission position information described in the mail transmitted from the parent terminal, first, the terminal position acquisition unit 16 of the server 10 All the positions of the child terminals belonging to the same group as the parent terminal are acquired, 1 indicates that the acquired position of the child terminal belongs to the same area as the parent terminal, and 0 indicates that the position of the acquired child terminal does not belong to the same area. 1-bit information may be acquired as the terminal position. Next, the mail transmission unit 13 of the server 10 is a child terminal belonging to the group to which the mobile terminal A300a that is the parent terminal that transmitted the mail belongs, and an area to which the mobile terminal A300a that is the parent terminal that transmitted the mail belongs. The received mail is transmitted to all the child terminals belonging to the same area (in the case of FIG. 15, only the portable terminal B 300b) (S13).

  Next, the mail receiving unit 140 of the mobile terminal B 300b that is the child terminal receives the mail transmitted from the server 10 (S140). The mail analysis unit 150 of the mobile terminal B 300b analyzes the received mail and acquires parameters (S150). When receiving a mail from the server 10, the WLAN management unit 190 of the mobile terminal B 300b turns on the function of the WLAN unit 910, and based on the WLAN connection setting information indicated in the acquired parameter, the WLAN unit 910 The WLAN connection setting is changed (S190).

  On the other hand, the WLAN management unit 190 of the mobile terminal A 300a which is the parent terminal turns on the function of the WLAN unit 910 and based on the WLAN connection setting information indicated by the parameter generated by the parameter generation unit 110, the WLAN unit 910 The WLAN connection setting is changed (S190).

  The WLAN unit 910 of the mobile terminal A 300a and the mobile terminal B 300b transmits and receives a beacon signal, and executes synchronization processing and connection negotiation processing according to the WLAN connection setting changed in step S190 (SS911, SS912, SS913, SS914, SS915).

  As described above, according to the wireless LAN connection system 1 of the present embodiment, since the terminal location acquisition unit 16 of the server 10 transmits mail only to the child terminals belonging to the same area as the parent terminal, in addition to the effects of the first embodiment. Since it is not necessary to include the determination unit 180 included in the mobile terminal 100 according to the first embodiment, it is easy to implement the function of the present invention in the mobile terminal, and hardware resources can be saved.

  Hereinafter, with reference to FIG. 17, an outline of the operation of the wireless LAN connection system 2 of the fourth embodiment in which the wireless LAN connection system 1 of the third embodiment is added with a function of transmitting mail from the server in accordance with the scheduled beacon signal transmission time. explain. FIG. 17 is a diagram showing an outline of operations performed by the wireless LAN connection system 2 of the present embodiment. As shown in FIG. 17, the difference between the wireless LAN connection system 2 of the present embodiment and the wireless LAN connection system 1 of the third embodiment is that the server 20 matches the mail indicated by the arrow 2 in the figure with the scheduled beacon signal transmission time. It is a point to transmit. When the server 20 receives a mail from the portable terminal A 400a (an arrow with a number 1 in the figure), the beacon signal transmission scheduled time described in the mail (or a time a predetermined time before the beacon signal scheduled time) As a trigger, it is determined whether or not the parent terminal and the child terminal belong to the same area, and mail is transmitted to all the child terminals belonging to the same area as the parent terminal (arrow number 2 in the figure).

  Hereinafter, the configuration and operation of the wireless LAN connection system 2 according to the fourth embodiment will be described in detail with reference to FIGS. 18 and 19. FIG. 18 is a block diagram showing the configuration of the wireless LAN connection system 2 of this embodiment. FIG. 19 is a flowchart showing the operation of the wireless LAN connection system 2 of the present embodiment.

  As shown in FIG. 18, the wireless LAN connection system 2 of this embodiment includes a mobile terminal 400 and a server 20. The portable terminal 400 includes a WLAN unit 910, a parameter generation unit 210, a mail generation unit 120, a mail transmission unit 130, a mail reception unit 140, a mail analysis unit 150, a control unit 170, a WLAN management unit 190, Is provided. The WLAN unit 910 includes a beacon generation unit 911, a WLAN transmission unit 912, a WLAN reception unit 913, a synchronization processing unit 914, and a negotiation unit 915 (not shown) in the same manner as the conventional portable terminal described in FIG. . The parameter generation unit 210 of the mobile terminal 400 according to the present embodiment performs the same operation as the parameter generation unit 210 included in the mobile terminal 200 according to the second embodiment. In addition, since each component other than the parameter generation unit 210 of the portable terminal 400 of this embodiment performs the same operation as each component having the same number in the portable terminal 300 of the third embodiment, description thereof is omitted. The server 20 includes a mail transmission unit 13, a mail reception unit 14, a mail analysis unit 15, a terminal position acquisition unit 26, a control unit 17, and a timer unit 29. Since each component other than the terminal position acquisition unit 26 and the timer unit 29 of the server 20 performs the same operation as each component having the same number in the server 10 of the third embodiment, the description thereof is omitted. Although FIG. 18 describes and describes only two portable terminals (mobile terminal A 400a and portable terminal B 400b) for convenience, even when there are three or more portable terminals 400, the same effect can be obtained by the same constituent unit. Yes (see description of FIG. 17).

  Hereinafter, operations of the parameter generation unit 210 of the mobile terminal 400, the terminal position acquisition unit 26 of the server 20, and the timer unit 29, which are different from the third embodiment, will be described.

  In addition to the WLAN connection setting information and the beacon signal transmission position information, the parameter generation unit 210 of the mobile terminal A 400a that is the parent terminal generates a parameter indicating the scheduled beacon signal transmission time (S210). The terminal location acquisition unit 26 of the server 20 is a parent terminal that has transmitted a mail when the difference between the current time indicated by the timer 29 and the scheduled beacon signal transmission time indicated by the parameter is less than or equal to a predetermined value (S29Y). The position of the mobile terminal A 400a and the positions of all the child terminals belonging to the group to which the mobile terminal A 400a belongs are acquired (S26). As in the third embodiment, the terminal position acquisition unit 26 of the server 20 may acquire the position of the child terminal as the name of any of the areas defined above. The terminal position acquisition unit 26 of the server 20 can acquire the base station ID as the terminal position, for example, when the area is determined based on the base station. In addition, when an area divided into meshes of the order of several tens of meters based on latitude and longitude is defined as an area, the area number can be acquired as the terminal position. When defining the same area as a predetermined distance from the point indicated by the beacon signal transmission position information described in the mail transmitted from the parent terminal, first, the terminal position acquisition unit 26 of the server 20 All the positions of the child terminals belonging to the same group as the parent terminal are acquired, 1 indicates that the acquired position of the child terminal belongs to the same area as the parent terminal, and 0 indicates that the position of the acquired child terminal does not belong to the same area. 1-bit information may be acquired as the terminal position. Hereinafter, steps S13, S140, and S150 are the same as those in the third embodiment.

  In this embodiment, since the mobile terminal A 400a as the parent terminal determines the scheduled beacon signal transmission time, the change of the WLAN connection setting of the mobile terminal A 400a as the parent terminal (S190) and the beacon signal transmission (SS912) are as follows. The beacon signal transmission scheduled time elapses or the time elapse of a predetermined time before the beacon signal transmission scheduled time (S170Y) is executed as a trigger. Similarly, for the mobile terminal B 400b that is a child terminal, when the WLAN management unit 190 receives a mail from the server 20, the WLAN connection setting information indicated by the acquired parameter is turned on by turning on the function of the WLAN unit 910. Based on the above, the WLAN connection setting of the WLAN unit 910 is changed (S190). Hereinafter, the WLAN unit 910 of the mobile terminal A 400a and the mobile terminal B 400b performs a synchronization process and a connection negotiation process according to the reception of the beacon signal and the WLAN connection setting changed in step S190 (SS913, SS914, SS915).

  As described above, according to the wireless LAN connection system 2 of the present embodiment, the parameter generation unit 210 of the parent terminal generates a parameter including the scheduled beacon signal transmission time notified by the user of the parent terminal, and sends a mail notifying the parameter. The mail transmission unit 130 of the parent terminal transmits to the server 20, and the terminal position acquisition unit 26 of the server 20 triggers the arrival of the scheduled beacon signal transmission time (or a time before the scheduled beacon signal time). In addition to the effects of the second embodiment, the portable terminal 200 of the second embodiment is provided to determine whether or not the child terminals belong to the same area and send mail only to the child terminals belonging to the same area as the parent terminal. Since it is not necessary to provide the determination unit 180, the function of the present invention can be easily implemented in the mobile terminal, and hardware resources can be saved.

Claims (5)

A WLAN unit that transmits and receives beacon signals and executes synchronization processing and connection negotiation processing in accordance with preset WLAN connection settings;
A parameter generator for generating a parameter indicating WLAN connection setting information and beacon signal transmission position information and outputting a WLAN setting signal;
A mail generation unit that generates a mail notifying the generated parameters;
A mail transmitting unit that transmits the generated mail to a mobile terminal belonging to a predetermined group;
A mail receiver for receiving the transmitted mail;
An email analysis unit that analyzes the received email and obtains the parameters;
A position acquisition unit that acquires its own position when the mail is received;
A determination unit that outputs a WLAN setting signal when a distance between the beacon signal transmission position information indicated by the parameter and the acquired own position is equal to or less than a predetermined value;
When the WLAN setting signal is acquired, the WLAN unit function is turned on, and the WLAN connection setting of the WLAN unit is changed based on the WLAN connection setting information indicated in the acquired or generated parameter. A WLAN management unit;
A mobile terminal comprising: The mobile terminal according to claim 1,
In addition to the WLAN connection setting information and the beacon signal transmission position information, the parameter generation unit generates a parameter indicating a scheduled beacon signal transmission time,
The mobile terminal is characterized in that the position acquisition unit acquires its own position when a difference between a current time and a scheduled beacon signal transmission time indicated by the parameter is equal to or less than a predetermined value. A wireless LAN connection system comprising a mobile terminal and a server,
The portable terminal is
A WLAN unit that transmits and receives beacon signals and executes synchronization processing and connection negotiation processing in accordance with preset WLAN connection settings;
A parameter generator for generating a parameter indicating WLAN connection setting information;
A mail generation unit that generates a mail notifying the generated parameters;
A mail sending unit for sending the generated mail to the server;
A mail receiving unit that receives mail transmitted from the server;
An email analysis unit that analyzes the received email and obtains the parameters;
When the mail is received or generated, the function of the WLAN unit is turned on, and the WLAN connection setting of the WLAN unit is changed based on the WLAN connection setting information indicated in the acquired or generated parameter A WLAN management unit;
With
The server
An email receiver that receives email sent from the mobile terminal;
An email analysis unit that analyzes the received email and obtains the parameters;
A mobile terminal that has transmitted the e-mail, and a terminal location acquisition unit that acquires the location of a mobile terminal that belongs to the group to which the mobile terminal belongs;
A mobile terminal that belongs to a group to which the mobile terminal that transmitted the mail belongs, and that transmits the received mail to all mobile terminals that belong to the same area as the distance from the mobile terminal that transmitted the mail; ,
A wireless LAN connection system comprising: The wireless LAN connection system according to claim 3,
In addition to the WLAN connection setting information, the parameter generation unit generates a parameter indicating a beacon signal transmission scheduled time,
The terminal location acquisition unit includes a mobile terminal that transmits the mail when a difference between a current time and a scheduled beacon signal transmission time indicated by the parameter is equal to or less than a predetermined value, and a mobile terminal that belongs to a group to which the mobile terminal belongs. A wireless LAN connection system for acquiring the position of a terminal. A WLAN step for transmitting and receiving a beacon signal and executing a synchronization process and a connection negotiation process in accordance with a preset WLAN connection setting;
A parameter generation step of generating a parameter indicating WLAN connection setting information and beacon signal transmission position information and outputting a WLAN setting signal;
A mail generation step of generating a mail notifying the generated parameters;
A mail transmission step of transmitting the generated mail to a mobile terminal belonging to a predetermined group;
An email receiving step of receiving the sent email;
An email analysis step of analyzing the received email to obtain the parameters;
A position acquisition step of acquiring its own position when receiving the mail;
A determination step of outputting a WLAN setting signal when a distance between the beacon signal transmission position information indicated by the parameter and the acquired own position is equal to or less than a predetermined value;
A WLAN management step of turning on the WLAN function when the WLAN setting signal is acquired, and changing the WLAN connection setting based on the WLAN connection setting information indicated in the acquired or generated parameter;
A wireless LAN connection method comprising:

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