JP7667697B2 - Electronic device, tethering terminal, communication system, and communication method - Google Patents

Description

The present disclosure relates to an electronic device, a tethering terminal, a communication system, and a communication method for connecting to a wireless communication network.

There is known a technology that automatically switches between a communication path that connects to a wireless communication network via a tethering terminal and a communication path that connects to a wireless communication network without going through a tethering terminal. For example, Patent Document 1 discloses that a mobile terminal device compares the communication method of a wireless communication network that can be connected to the mobile terminal with the communication method of a wireless communication network that can be connected to via a tethering terminal device, and controls the mobile terminal device to connect to the wireless communication network with the communication method having the higher priority.

JP 2014-183481 A

In Patent Document 1, the above-mentioned priority is determined based on parameters including the communication speed of each communication method. For example, a communication method whose communication speed meets a condition is identified as having a high priority and is connected to the wireless communication network of that communication method. Therefore, there is a risk that the mobile terminal device will automatically be connected to a wireless communication network that the user does not intend (for example, a network with weak security).

One aspect of the present disclosure aims to provide an electronic device, a tethering terminal, a communication system, and a communication method that can selectively connect to wireless communication networks of multiple different communication methods while preventing the device from connecting to a wireless communication network that is not intended by the user.

An electronic device according to one aspect of the present disclosure includes a first communication unit for wirelessly connecting to a network, a second communication unit for wirelessly connecting to a tethering terminal, and a communication control unit that, when connected to a first access point of the network via the tethering terminal by the second communication unit, and when connection destination information including a second access point different from the first access point is received from the tethering terminal by the second communication unit, connects to the second access point by the first communication unit and disconnects the second communication unit.

A tethering terminal according to one embodiment of the present disclosure includes a network communication unit for wirelessly connecting to a network, a device communication unit for wirelessly connecting to an electronic device, a tethering control unit that executes tethering to connect the electronic device connected by the device communication unit to the network connected by the network communication unit, and an information transmission unit that is capable of transmitting destination information including a second access point different from the first access point to the electronic device connected by the device communication unit when the electronic device is connected to a first access point of the network by the tethering.

A communication system according to one aspect of the present disclosure includes an electronic device and a tethering terminal, the electronic device being capable of wirelessly connecting to a network and the tethering terminal, the tethering terminal being capable of wirelessly connecting to the network and the electronic device, and including an information transmitting unit that transmits destination information including a second access point different from the first access point from the tethering terminal to the electronic device when the electronic device is connected to a first access point of the network via the tethering terminal, and a communication control unit that connects the electronic device to the second access point and disconnects the electronic device from the tethering terminal when the destination information is received by the electronic device from the tethering terminal.

A communication method according to one aspect of the present disclosure is a communication method executed in a communication system including an electronic device and a tethering terminal, the electronic device being capable of wirelessly connecting to a network and the tethering terminal, the tethering terminal being capable of wirelessly connecting to the network and the electronic device, the method including: transmitting, when the electronic device is connected to a first access point of the network via the tethering terminal, destination information including a second access point different from the first access point, from the tethering terminal to the electronic device; and, when the destination information is received by the electronic device from the tethering terminal, connecting the electronic device to the second access point and disconnecting the electronic device from the tethering terminal.

FIG. 1 illustrates an example of an overall configuration of a communication system. FIG. 2 is a block diagram showing an electrical configuration of the electronic device. FIG. 2 is a block diagram showing the electrical configuration of the tethering terminal. FIG. 4 is a data configuration diagram of a connection destination table in the first embodiment. 4 is a flowchart of wireless connection control executed in the communication system of the first embodiment. 11 is a specific example of a connection destination setting screen in the first embodiment. FIG. 4 is a data configuration diagram of a connection destination table in the first embodiment. FIG. 4 is a data configuration diagram of a connection destination table in the first embodiment. FIG. 1 illustrates an example of an overall configuration of a communication system. FIG. 1 illustrates an example of an overall configuration of a communication system. 10 is a flowchart of wireless connection control executed in a communication system according to a second embodiment. FIG. 11 is a data configuration diagram of a connection destination table in the second embodiment. 13 is a specific example of a connection destination setting screen in the second embodiment. FIG. 11 is a diagram for explaining transition of connection destination information in the second embodiment. 13 is a specific example of a connection destination setting screen in the second embodiment. FIG. 11 is a diagram for explaining transition of connection destination information in the second embodiment. 13 is a specific example of a connection permission instruction screen. FIG. 13 is a data configuration diagram of a connection destination table in the modified example. FIG. 13 is a data configuration diagram of a connection destination table in the modified example. FIG. 13 is a data configuration diagram of a connection destination table in the modified example.

Embodiments of the present disclosure will be described below with reference to the drawings. Note that in the drawings, identical or equivalent elements are given the same reference numerals, and duplicate descriptions will be omitted.

[First embodiment]
The configuration of a communication system 100 according to the first embodiment will be described. Fig. 1 is a diagram showing an example of the overall configuration of the communication system 100. Fig. 2 is a block diagram showing the electrical configuration of an electronic device 110. Fig. 3 is a block diagram showing the electrical configuration of a tethering terminal 120. Fig. 4 is a data configuration diagram of connection destination tables 210, 310 in the first embodiment.

As shown in FIG. 1, the communication system 100 includes an electronic device 110 and a tethering terminal 120. The electronic device 110 is a communication device capable of performing wireless LAN communication 161 and device-to-device communication 162. The electronic device 110 can connect to a network 130 by wireless LAN communication 161 using a router 140 as an access point. The electronic device 110 can also connect to the tethering terminal 120 by device-to-device communication 162. The device-to-device communication 162 includes short-range wireless communication 162A that can connect the electronic devices to each other, and wireless LAN communication 162B that has a longer communication distance than the short-range wireless communication 162A.

The tethering terminal 120 is a communication terminal capable of performing device-to-device communication 162 and mobile communication 163, and also equipped with a tethering function. The tethering terminal 120 can access the mobile communication network 150 by mobile communication 163 and connect to the network 130. The tethering terminal 120 can connect to the electronic device 110 by short-range wireless communication 162A, and can remotely change settings of the electronic device 110. The electronic device 110 can also connect to the tethering terminal 120 by wireless LAN communication 162B, and can connect to the network 130 using the tethering terminal 120 performing mobile communication 163 as an access point.

In this embodiment, the network 130 is, for example, the Internet or a WAN. The wireless LAN communications 161, 162B are Wi-fi (registered trademark), but may conform to other wireless LAN standards. The short-range wireless communication 162A is Bluetooth (registered trademark), but may also be other short-range wireless communication (for example, NFC) capable of connecting electronic devices to each other. The mobile communication 163 is, for example, 3G, LTE, WiMAX, 4G, 5G, etc.

As shown in Figs. 1 and 2, the electronic device 110 of this embodiment is a wearable sound input/output device that is worn around the user's neck. The electronic device 110 may be any communication device that the user can carry, such as a smartphone, a headset, or a smartwatch. The electronic device 110 includes a speaker 111, a microphone 112, a first communication unit 211, a second communication unit 212, a control unit 200, etc.

The first communication unit 211 is a communication interface for wirelessly connecting to the network 130. For example, the first communication unit 211 is a board unit on which an integrated circuit that controls the wireless LAN communication 161 is mounted.

The second communication unit 212 is a communication interface for wirelessly connecting to the tethering terminal 120. For example, the second communication unit 212 is a board unit on which an integrated circuit that controls the device-to-device communication 162 (near-field wireless communication 162A and wireless LAN communication 162B) is mounted.

The electronic device 110 of this embodiment includes one Wi-fi board unit and one Bluetooth board unit. The one Wi-fi board unit functions as a first communication unit 211 when wireless LAN communication 161 is performed, and functions as a second communication unit 212 when wireless LAN communication 162B is performed. The one Bluetooth board unit functions as a second communication unit 212 when short-range wireless communication 162A is performed.

The control unit 200 includes a CPU, memory, etc., and controls the electronic device 110. For example, the control unit 200 is configured with a SoC (System on Chip). The CPU of the control unit 200 executes a program stored in the memory to realize each of the functional blocks illustrated in FIG. 2. These functional blocks include a communication control unit 201 and a registration unit 202. A connection destination table 210 is also stored in the memory of the control unit 200.

As shown in FIG. 4, the connection destination table 210 of this embodiment registers one access point to which the user has permitted connection using the tethering terminal 120, along with its address and type. For example, the type of access point is one of "private", "public", and "tethering". "Private" indicates that it is an access point for a private network (e.g., home or office Wi-Fi). "Public" indicates that it is an access point for a public network (e.g., free Wi-Fi). Generally, private networks have a higher security level than public networks. "Tethering" indicates that the tethering terminal 120 functions as an access point.

In the example of FIG. 4, the access point "MY HOME" registered in the connection destination table 210 is a router 140 installed in the user's home, and is therefore an access point of a private network. Therefore, the type of this access point is set to "private." Although not shown, the address of the access point "MY HOME" is also registered in the connection destination table 210.

When the communication control unit 201 is connected to a first access point of the network 130 via the tethering terminal 120 by the second communication unit 212, and connection destination information including a second access point different from the first access point is received from the tethering terminal 120, the communication control unit 201 can connect to the second access point by the first communication unit 211 and disconnect the second communication unit 212 (more specifically, wireless LAN communication 162B). For example, the first access point is the mobile communication network 150 to which the tethering terminal 120 is connected. The second access point is the router 140 connected to the network 130.

The registration unit 202 registers the access points of the network 130 in the connection destination table 210. In detail, the registration unit 202 registers the second access point included in the connection destination information in the connection destination table 210. The communication control unit 201 connects to the second access point registered in the connection destination table 210. Specific aspects of these functional blocks will be described later.

As shown in FIG. 1 and FIG. 3, the tethering terminal 120 in this embodiment is a smartphone. The tethering terminal 120 may be any communication terminal equipped with a user interface function for inputting and outputting information and the above-mentioned tethering function, and may be, for example, a notebook PC, a tablet terminal, a mobile router, etc.

The tethering terminal 120 includes a speaker 121, a microphone 122, a touch panel display 123, a network communication unit 311, a device communication unit 312, a control unit 300, etc. The touch panel display 123 is a user interface capable of displaying information and inputting operations. Instead of the touch panel display 123, the tethering terminal 120 may include a display unit such as a display and an operation unit such as buttons and keys.

The network communication unit 311 is a communication interface for wirelessly connecting to the network 130 via the mobile communication network 150. For example, the network communication unit 311 is a board unit on which an integrated circuit that controls the mobile communication 163 is mounted. In this embodiment, the network communication unit 311 is an LTE communication module. Furthermore, the network communication unit 311 is also mounted with an integrated circuit that controls wireless LAN communication (e.g., Wi-fi), thereby enabling it to execute both mobile communication 163 and wireless LAN communication.

The device communication unit 312 is a communication interface for wirelessly connecting to the electronic device 110. For example, the device communication unit 312 is a board unit on which an integrated circuit for controlling the device-to-device communication 162 (near-field wireless communication 162A and wireless LAN communication 162B) is mounted. The device communication unit 312 in this embodiment is a Wi-Fi/Bluetooth communication module.

The control unit 300 includes a CPU, ROM, RAM, etc., and controls the tethering terminal 120. The CPU of the control unit 300 executes a program stored in the memory to realize each of the functional blocks illustrated in FIG. 3. These functional blocks include a tethering control unit 301, an information transmission unit 302, a search unit 303, and a judgment unit 304. A connection destination table 310 is also stored in the memory of the control unit 300. As shown in FIG. 4, the connection destination table 310 of this embodiment is synchronized with the connection destination table 210 as described below, and the same access points as those in the connection destination table 210 are registered.

The tethering control unit 301 executes tethering to connect the electronic device 110 connected by the device communication unit 312 to the network 130 connected by the network communication unit 311. When the electronic device 110 is connected to a first access point of the network 130 by tethering, the information transmission unit 302 can transmit connection destination information including a second access point different from the first access point to the electronic device 110 connected by the device communication unit 312.

The search unit 303 searches for a second access point. After searching for the second access point, the determination unit 304 determines whether or not to transmit destination information including the second access point to the electronic device 110. The information transmission unit 302 transmits the destination information to the electronic device 110 when it is determined that the destination information should be transmitted to the electronic device 110. Specific aspects of these functional blocks will be described later.

Among the various processes executed by the communication system 100 of the first embodiment, the process related to wireless connection control to the network 130 will be described. FIG. 5 is a flowchart of the wireless connection control executed by the communication system 100 of the first embodiment. FIG. 6 is a specific example of a connection destination setting screen 600 in the first embodiment.

In the following explanation, it is assumed that the electronic device 110 and the tethering terminal 120 have been paired via short-range wireless communication 162A (see FIG. 1) as a result of initial settings previously performed by the user. It is assumed that an application program that enables the user to remotely operate the network connection of the electronic device 110 has been pre-installed and activated in the tethering terminal 120. It is also assumed that the tethering function of the tethering terminal 120 has been pre-set to on.

When the electronic device 110 is powered on, the control unit 200 of the electronic device 110 starts the process shown in FIG. 5. In S501, the communication control unit 201 identifies an access point registered in the connection destination table 210 as a target point. The target point is an access point that is the target of wireless communication in order for the electronic device 110 to connect to the network 130.

In S503, the communication control unit 201 determines whether the type of the target point is "tethering". If the type of the target point is not "tethering", in S505, the communication control unit 201 executes a first connection. In the first connection, the first communication unit 211 executes wireless LAN communication 161 with the target point (in the example of FIG. 1, the router 140 of the access point "MY HOME"), thereby connecting the electronic device 110 to the network 130.

If the type of the target point is "tethering", the communication control unit 201 executes a second connection in S507. In the second connection, the second communication unit 212 executes wireless LAN communication 162B with the target point (i.e., the tethering terminal 120), and the tethering control unit 301 of the tethering terminal 120 executes the above-mentioned tethering. As a result, the electronic device 110 is connected to the network 130 via the tethering terminal 120 performing mobile communication 163.

Note that in S505 and S507, for example, if the electronic device 110 cannot detect the target point or if an authentication error or network error occurs, the first connection or the second connection cannot be established, and the electronic device 110 cannot connect to the network 130. In this case, the communication control unit 201 returns the process to S501 and waits until the first connection or the second connection can be established. At this time, at least one of the electronic device 110 and the tethering terminal 120 may notify the error by outputting a predetermined sound, turning on a lamp, displaying an image, etc.

The control unit 300 of the tethering terminal 120 starts the process shown in FIG. 5 when the tethering terminal 120 is powered on. In S521, the search unit 303 searches for access points that are candidates for connection destinations of the electronic device 110. Specifically, the search unit 303 uses the network communication unit 311 to search for all access points to which the tethering terminal 120 can connect via wireless LAN communication as candidate access points for connection destinations. Furthermore, when the tethering function of the tethering terminal 120 is on, the search unit 303 includes the tethering terminal 120 itself in the candidate access points for connection destinations.

In S523, the determination unit 304 determines whether to send the connection destination information to the electronic device 110. In this example, when the user inputs a specific instruction to the above-mentioned application program, the connection destination setting screen 600 (see FIG. 6) is displayed on the touch panel display 123, and the determination of S523 is made. In S523, if the determination unit 304 determines, based on the user's operation on the connection destination setting screen 600, that connection permission has been granted to any of the access points searched for in S521, it determines to send the connection destination information to the electronic device 110.

The connection destination setting screen 600 of the first embodiment illustrated in FIG. 6 includes a pairing device display area 601, a current setting display area 602, an access point designation area 603, a decision button 604, and a cancel button 605. The pairing device display area 601 is an area that shows the identification information of the pairing device (in this example, the electronic device 110).

The current setting display area 602 is an area that displays the information currently set in the destination table 310 of the tethering terminal 120. In this example, since the destination table 310 is substantially synchronized with the destination table 210 of the electronic device 110, the information displayed in the current setting display area 602 is the same as the information currently set in the destination table 210.

The access point designation area 603 is an area for designating an access point to which the paired device is to connect. For example, the access point designation area 603 displays a list of the access points searched for in S521 (i.e., access points to which the tethering terminal 120 can connect) along with the type and radio wave strength of each access point. The user can operate the touch panel display 123 or the like to arbitrarily select one access point from the list displayed in the access point designation area 603, thereby allowing the paired device to wirelessly connect to that access point.

In the access point designation area 603 in FIG. 6, the button corresponding to the selected access point is displayed to be distinguished from the buttons corresponding to non-selected access points. When an access point is selected in this manner and the user presses the decision button 604, the determination unit 304 determines in S523 that the connection destination information is to be sent to the electronic device 110. In this case, in S525, the determination unit 304 registers the selected access point in the connection destination table 310 of the tethering terminal 120. In detail, the information registered in the connection destination table 310 is updated to the selected access point and its type.

In S527, the information transmission unit 302 transmits the connection destination information including the selected access point and its type to the electronic device 110, which is the pairing device. In other words, the connection destination information includes the second access point detected by the tethering terminal 120 to which the tethering terminal 120 can currently connect wirelessly. Thereafter, the connection destination setting screen 600 is closed, and the process returns to S521. Note that if the user presses the cancel button 605, the determination unit 304 does not determine in S523 that the connection destination information should be transmitted to the electronic device 110. Therefore, the connection destination information is not transmitted, the connection destination setting screen 600 is closed, and the process returns to S521.

In the electronic device 110, in S509, the registration unit 202 determines whether or not connection destination information has been received from the tethering terminal 120. If it is determined in S509 that the connection destination information has been received, in S511, the registration unit 202 registers an access point in the connection destination table 210 of the electronic device 110 based on the received connection destination information. In detail, the information registered in the connection destination table 210 is updated to the access point and its type included in the connection destination information. The connection destination table 210 of the electronic device 110 becomes synchronized with the connection destination table 310 of the tethering terminal 120.

After S511 is executed, or if it is not determined in S509 that the connection destination information has been received, the process returns to S501. If the connection destination table 210 is updated in S511, the newly registered access point is treated as the target point, and the processes of S501 to S507 are executed as described above, thereby switching the access point to which the electronic device 110 is connected.

The following describes a specific example based on the process shown in FIG. 5. FIGS. 7A and 7B are data configuration diagrams of connection destination tables 210 and 310 in the first embodiment. FIGS. 8A and 8B are diagrams showing an example of the overall configuration of communication system 100.

As described above, in the example shown in FIG. 1, the user wearing electronic device 110 is at home, and so electronic device 110 is within the communication range of access point "MY HOME." In electronic device 110, access point "MY HOME" is identified as the target point based on connection destination table 210 shown in FIG. 4 (S501). In electronic device 110, a first connection with access point "MY HOME" is executed (S505). As a result, electronic device 110 performs wireless LAN communication 161 with router 140 of access point "MY HOME" and connects to network 130.

Suppose that a user wearing electronic device 110 leaves home carrying tethering terminal 120 that has been paired with electronic device 110 in advance. In the example shown in Fig. 8A and Fig. 8B, electronic device 110 of the user who has left home is outside the communication range of access point "MY HOME" and within the communication range of access point "FREE SPOT A". In this case, electronic device 110 cannot perform wireless LAN communication 161 with access point "MY HOME" and therefore cannot connect to network 130.

The user then uses the tethering terminal 120 to connect the electronic device 110 to another access point. Specifically, the user uses the above-mentioned application program to cause the tethering terminal 120 to display the connection destination setting screen 600. In this case, as illustrated in FIG. 6, "Wearable Device 1", which is the user's electronic device 110, is displayed in the pairing device display area 601. The access point "MY HOME" set in the connection destination tables 210 and 310 is displayed in the current setting display area 602, and its connection status is displayed as "not connected".

In the access point designation area 603, a list of access points that are candidates for connection destinations searched for in S521 is displayed. In this list, in addition to displaying the tethering terminal 120 with the tethering function set to on as access points, access points to which the tethering terminal 120 can connect via wireless LAN communication 161 are displayed. In the example of FIG. 6, multiple access points including the user's tethering terminal 120 "MY MOBILE" and the aforementioned "FREE SPOT A" are displayed in the access point designation area 603 as selectable access points.

In this manner, in this embodiment, the access points detected by the tethering terminal 120 are regarded as access points to which the electronic device 110 in the vicinity of the tethering terminal 120 can connect, and are displayed in the access point designation area 603. This allows the tethering terminal 120 to display access points to which the electronic device 110 can connect in the access point designation area 603 without inquiring of the electronic device 110.

For example, if a user desires a highly secure communication method, the user selects the access point "MY MOBILE" in the access point designation area 603 and presses the decision button 604. In this case, connection destination information including the access point "MY MOBILE" is sent from the tethering terminal 120 to the electronic device 110 (S523: YES, S527). As shown in FIG. 7A, the access point "MY MOBILE" is registered in both the connection destination tables 210, 310 (S525, S509: YES, S511).

Therefore, in the electronic device 110, based on the connection destination table 210 shown in FIG. 7A, the access point "MY MOBILE" that performs high-security tethering is identified as the target point (S501). In the electronic device 110, a second connection with the access point "MY MOBILE" is executed (S507). As a result, as shown in FIG. 8A, the electronic device 110 performs wireless LAN communication 162B with the tethering terminal 120 of the access point "MY MOBILE" and connects to the network 130 via the mobile communication network 150.

On the other hand, if the user desires an economically superior communication method, the user selects the access point "FREE SPOT A" in the access point designation area 603 and presses the decision button 604. In this case, connection destination information including the access point "FREE SPOT A" is transmitted from the tethering terminal 120 to the electronic device 110 (S523: YES, S527). As shown in FIG. 7B, the access point "FREE SPOT A" is registered in both the connection destination tables 210, 310 (S525, S509: YES, S511).

Therefore, in the electronic device 110, based on the connection destination table 210 shown in FIG. 7B, the public access point "FREE SPOT A" that can be used free of charge is identified as the target point (S501). In the electronic device 110, a first connection to the access point "FREE SPOT A" is executed (S505). As a result, as shown in FIG. 8B, the electronic device 110 performs wireless LAN communication 161 with the router 140 of the access point "FREE SPOT A" and connects to the network 130.

Here, when switching to a new access point based on the connection destination information and establishing a wireless connection, the communication control unit 201 of the electronic device 110 interrupts the first or second connection based on the access point before switching and executes the first or second connection based on the access point after switching. For example, when the electronic device 110 storing the connection destination table 210 shown in FIG. 7A is connected to the network 130 by tethering the access point "MY MOBILE", it is assumed that the electronic device 110 receives connection destination information including the access point "FREE SPOT A" from the tethering terminal 120. In this case, the connection destination table 210 in the electronic device 110 is updated as shown in FIG. 7B. The above tethering is interrupted (i.e., the second communication unit 212 is disconnected), and the first communication unit 211 performs wireless communication with the access point "FREE SPOT A" to connect to the network 130.

In this way, even when the communication control unit 201 is connected to a first access point of the network 130 via the tethering terminal 120, if connection destination information including a second access point is received from the tethering terminal 120, the communication control unit 201 can connect to the second access point via the first communication unit 211 and disconnect the second communication unit 212 (specifically, wireless LAN communication 162B).

In addition, when the electronic device 110 is in a tethering connection, the electronic device 110 will not connect to a new access point (e.g., a wireless LAN access point) unless permission is given by the tethering terminal 120. For example, when the electronic device 110 receives connection destination information, it assumes that permission has been given by the tethering terminal 120, and becomes able to connect to a new access point. In this case, the access point to which the electronic device 110 connects is set primarily by the tethering terminal 120.

On the other hand, when the electronic device 110 is not in a tethering connection (i.e., connected to a wireless LAN), the electronic device 110 can proactively connect to a new access point (e.g., a wireless LAN access point) based on the connection destination table 210. Therefore, the entity that sets the access point is appropriately switched depending on whether the electronic device 110 is in a tethering connection, thereby preventing the electronic device 110 from connecting to an unintended access point.

As described above, according to the first embodiment of the present disclosure, connection destination information including an access point specified by the user on the tethering terminal 120 is received by the electronic device 110 from the tethering terminal 120. The electronic device 110 connects to the access point indicated by the connection destination information via wireless communication. This allows the electronic device 110 to selectively connect to wireless communication networks of multiple different communication methods while preventing the electronic device 110 from connecting to a wireless communication network unintended by the user.

In addition, among the access points detected by the tethering terminal 120, connection destination information including the access point specified by the user is transmitted to the electronic device 110. In other words, the access points included in the connection destination information are access points permitted as connection destinations for the electronic device 110. Therefore, the electronic device 110 can connect to the access points permitted to be connected to by the tethering terminal 120 through user operation among the access points detected by the tethering terminal 120.

[Second embodiment]
A second embodiment of the present disclosure will be described below. In the following, configurations and processes having substantially the same functions as those of the first embodiment will be referred to by the same reference numerals, and descriptions thereof will be omitted, and only points different from the first embodiment will be described.

The communication system 100 of the second embodiment has the same configuration as the first embodiment (see Figures 1 to 3), but the data configuration and details of processing are different. Figure 9 is a flowchart of wireless connection control executed by the communication system 100 of the second embodiment. Figure 10 is a data configuration diagram of the connection destination tables 210, 310 in the second embodiment. Figure 11 is a specific example of the connection destination setting screen 600 in the second embodiment.

As shown in FIG. 10, the connection destination table 210 of this embodiment can register multiple access points to which the user has permitted connection using the tethering terminal 120, and registers the priority, connection settings, address, type, etc. of each access point. The priority indicates the level of priority with which each access point is identified as a target point. The connection settings indicate whether or not the electronic device 110 is to be automatically connected to an access point identified as a target point. In addition, a "connected" flag is set for a target point to which the electronic device 110 is currently connected.

In the example of FIG. 10, one access point "MY HOME" is registered in the connection destination table 210. The highest priority "1" is set for this access point "MY HOME", the connection setting is set to "automatic", and the corresponding address and type are set, as in the first embodiment. As in the first embodiment, the connection destination table 310 is synchronized with the connection destination table 210.

In this embodiment, the priority of the access points registered in the connection destination tables 210 and 310 is automatically set according to the type of the access point. For example, the highest priority is set for an access point whose type is "private." A lower priority is set for an access point whose type is "public." A lower priority is set for an access point whose type is "tethering." A lower priority is set for an access point whose type is "public."

In other words, in the connection destination tables 210 and 310 of this embodiment, the access points of the wireless LAN communication 161 that are permitted to be connected by the tethering terminal 120 are set to a higher priority than the access points of tethering. Note that, when there are multiple access points of the same type, the priority of each access point may be set according to a predetermined rule (for example, first order of registration, most number of accesses, longest connection time, etc.).

Of the various processes executed by the communication system 100 of the second embodiment, the process relating to wireless connection control to the network 130 will be described. The control unit 200 of the electronic device 110 starts the process shown in FIG. 9 when the electronic device 110 is powered on. In S901, the communication control unit 201 refers to the connection destination table 210 and identifies a target point based on priority. In detail, the communication control unit 201 identifies an effective point that can be wirelessly connected to the electronic device 110 from among the access points registered in the connection destination table 210. Furthermore, the communication control unit 201 identifies the effective point with the highest priority among the identified effective points as the target point.

In S903, the communication control unit 201 refers to the connection destination table 210 and determines whether the type of the target point identified in S901 is "automatic." In this example, if the type of the target point is "manual," the communication control unit 201 transmits a connection permission request to the tethering terminal 120 in S905. The connection permission request is a command that inquires of the tethering terminal 120 as to whether to connect the electronic device 110 to the target point.

Then, the communication control unit 201 waits for a response command to the connection permission request for a predetermined waiting time. If a response command for connection permission is received within the waiting time in S907, the communication control unit 201 transitions the process to S503. If the communication control unit 201 determines in S903 that the type of the target point is "automatic," it also transitions the process to S503. The subsequent steps S503 to S511 are the same as in the first embodiment.

In S907, if the waiting time has elapsed without receiving a response command, or if a response command refusing connection has been received, the communication control unit 201 returns the process to S901. In S901, the communication control unit 201 identifies the valid point with the next highest priority as the target point, and executes the same processes as described above (S903 to S907).

If there are no valid points in the connection destination table 210, or if connection permission has not been received for all valid points in the connection destination table 210, the communication control unit 201 cannot connect to any access point. In this case, the communication control unit 201 may retry the process from S901 after a predetermined time has elapsed, or may notify an error in at least one of the electronic device 110 and the tethering terminal 120.

The control unit 300 of the tethering terminal 120 starts the process shown in FIG. 9 when the tethering terminal 120 is powered on. In S921, the control unit 300 determines whether a connection permission request has been received from the electronic device 110. If a connection permission request has been received in S921, the control unit 300 performs a response process in response to a user instruction in the tethering terminal 120 in S923. For example, if the user instructs the tethering terminal 120 to permit connection, the control unit 300 transmits a response command for permitting connection to the electronic device 110.

After S923 is executed, or if a connection permission request has not been received in S921, the control unit 300 transitions the process to S521. The subsequent steps S521 to S527 are the same as in the first embodiment, but the connection destination setting screen 600 displayed in S523 differs from the first embodiment (see FIG. 6).

In the connection destination setting screen 600 of the second embodiment illustrated in FIG. 11, a list of the access points searched for in S521 is displayed in an access point designation area 603 along with the connection permission, connection settings, type, and signal strength of each access point. The user can operate the touch panel display 123 or the like to set the connection permission for an access point to "O" or "X." The connection permission "O" indicates an access point to which the user has permission to connect. The connection permission "X" indicates an access point to which the user has denied connection.

Furthermore, the user can set the connection setting to "automatic" or "manual" in association with an access point with connection permission "o". The connection setting "automatic" indicates that the electronic device 110 is automatically connected to an access point with connection permission "o". The connection setting "manual" indicates that the electronic device 110 is not automatically connected to an access point with connection permission "o". When the decision button 604 is pressed, connection destination information including the access point etc. set in the access point designation area 603 is sent to the electronic device 110 in S527, and registered in each connection destination table 210, 310 in S511, S525.

Specific aspects based on the process shown in FIG. 9 are described below. FIG. 12 is a diagram for explaining the transition of connection destination information in the second embodiment. FIG. 13 is a specific example of a connection destination setting screen 600 in the second embodiment. FIG. 14 is a diagram for explaining the transition of connection destination information in the second embodiment. FIG. 15 is a specific example of a connection availability instruction screen 1500.

As described above, in the example shown in FIG. 1, the user wearing electronic device 110 is at home, and therefore electronic device 110 is within the communication range of access point "MY HOME." In electronic device 110, access point "MY HOME" is identified as the target point based on connection destination table 210 shown in FIG. 10 (S501). Because the connection setting for access point "MY HOME" is "automatic," a first connection to access point "MY HOME" is executed without a connection permission request being sent from electronic device 110 (S505). As a result, electronic device 110 connects to network 130 via home router 140, as shown in FIG. 1.

In this state, when the user causes the tethering terminal 120 to display the connection destination setting screen 600, the connection destination setting screen 600 is displayed in the format shown in FIG. 11. Specifically, "Wearable Device 1", which is the user's electronic device 110, is displayed in the pairing device display area 601. The access point "MY HOME" set in the connection destination tables 210, 310 is displayed in the current setting display area 602, and "Connected" is displayed as its connection status.

Because the tethering terminal 120 is at the user's home, the access point "MY HOME" searched for in S521 and the access point "MY MOBILE" of the tethering terminal 120 itself are displayed in the access point designation area 603. As set in the connection destination tables 210 and 310, the access point "MY HOME" is displayed in association with a connection permission of "◯" and a connection setting of "Automatic." Because the user has not yet granted permission to connect to the tethering terminal 120, the access point "MY MOBILE" is displayed in association with a connection permission of "X."

For example, suppose that the user changes the connection permission for the access point "MY MOBILE" in the access point designation area 603 shown in FIG. 11 to "○", sets the connection setting to "Automatic", and presses the decision button 604 as shown in FIG. 12. In this case, it is determined in S523 that the connection destination information should be sent to the electronic device 110, and the connection destination information including the contents set in the access point designation area 603 is sent from the tethering terminal 120 to the electronic device 110 (S527). As shown in FIG. 12, the new access point "MY MOBILE" is registered in the connection destination table 210, 310 (S511, S525).

Then, suppose that the user wearing the electronic device 110 leaves the house carrying the tethering terminal 120. In the example shown in Figs. 8A and 8B, the electronic device 110 of the user who has left the house is outside the communication range of the access point "MY HOME" and within the communication range of the access point "FREE SPOT A." The electronic device 110 is disconnected from the access point "MY HOME" and therefore cannot connect to the network 130.

In this case, the electronic device 110 refers to the connection destination table 210 (see FIG. 12) and identifies the access point "MY MOBILE", which has the second highest priority after the access point "MY HOME", as the target point (S901). Because the connection setting for the access point "MY MOBILE" is "automatic", the electronic device 110 executes a second connection to the access point "MY MOBILE" without sending a connection permission request (S507). As a result, as shown in FIG. 8A, the electronic device 110 connects to the network 130 via the mobile communication network 150, using the tethering terminal 120 as an access point.

In this state, when the user causes the tethering terminal 120 to display the connection destination setting screen 600, the connection destination setting screen 600 is displayed in the format shown in FIG. 13. Specifically, the access points "MY HOME" and "MY MOBILE" set in the connection destination tables 210, 310 (see FIG. 12) are displayed in the current setting display area 602, and the connection status of the access point "MY MOBILE" is displayed as "connected."

For example, the tethering terminal 120 is within the communication range of the access points "FREE SPOT A" and "XYZ COMPANY". These access points "FREE SPOT A" and "XYZ COMPANY" searched for in S521, and the tethering terminal 120's own access point "MY MOBILE" are displayed in the access point designation area 603. The access point "MY MOBILE" is displayed in association with a connection permission of "◯" and a connection setting of "Automatic" as set in the connection destination tables 210, 310. The access points "FREE SPOT A" and "XYZ COMPANY" are displayed in association with a connection permission of "X" because the user has not yet granted permission to connect.

For example, suppose that the user changes the connection permission for the access point "FREE SPOT A" to "○" in the access point designation area 603 shown in FIG. 13, sets the connection setting to "Manual" and presses the decision button 604 as shown in FIG. 14. In this case, it is determined in S523 that the connection destination information should be sent to the electronic device 110, and the connection destination information including the contents set in the access point designation area 603 is sent from the tethering terminal 120 to the electronic device 110 (S527). As shown in FIG. 14, the new access point "FREE SPOT A" is registered in the connection destination table 210, 310 (S511, S525).

In this example, the priority of the type "public" of the access point "FREE SPOT A" is lower than the type "private" and higher than the type "tethering." Therefore, in the connection destination tables 210 and 310 shown in FIG. 14, the priority of each access point is automatically set in descending order of the access points "MY HOME," "FREE SPOT A," and "MY MOBILE."

In the connection destination table 210 illustrated in FIG. 14, the priority level "2" of the newly registered access point "FREE SPOT A" is higher than the priority level "3" of the currently connected access point "MY MOBILE". In this case, the electronic device 110 identifies the access point "FREE SPOT A" as the new target point to replace the access point "MY MOBILE" (S901). Since the connection setting of the access point "FREE SPOT A" is "manual", a connection permission request is sent from the electronic device 110 to the tethering terminal 120 (S905).

When the tethering terminal 120 receives a connection permission request (S921: YES), for example, a connection permission instruction screen 1500 is displayed on the touch panel display 123. In the connection permission instruction screen 1500 illustrated in FIG. 15, the access point "FREE SPOT A" that is the target of the connection permission request is displayed together with its type and radio wave strength.

When the user presses the "Allow" button on the connection permission instruction screen 1500, a response command for connection permission is sent from the tethering terminal 120 to the electronic device 110 (S923). This allows the user to permit the electronic device 110 to connect to the access point "FREE SPOT A". Note that when the user presses the "Do not allow" button on the connection permission instruction screen 1500, a response command for connection refusal is sent from the tethering terminal 120 to the electronic device 110 (S923). This allows the user to refuse the electronic device 110 from connecting to the access point "FREE SPOT A".

When the electronic device 110 receives the connection permission (S907: YES), a wireless connection to the permitted access point is established. In this example, the second connection of the tethering terminal 120 with the access point "MY MOBILE" is disconnected and switched to the first connection with the access point "FREE SPOT A" (S505). As a result, as shown in FIG. 8B, the electronic device 110 connects to the network 130 via the router 140 of the access point "FREE SPOT A".

In this way, as in the first embodiment, even when the communication control unit 201 is connected to a first access point of the network 130 via the tethering terminal 120, if connection destination information including a second access point is received from the tethering terminal 120, the communication control unit 201 can connect to the second access point via the first communication unit 211 and disconnect the second communication unit 212 (specifically, wireless LAN communication 162B).

When the electronic device 110 is in a tethering connection, the electronic device 110 will not connect to a new access point unless permission is given from the tethering terminal 120. For example, when the electronic device 110 receives connection destination information or when there is an access point of type "automatic" in the connection destination table 210, the electronic device 110 assumes that permission has been given from the tethering terminal 120 and becomes able to connect to a new access point. On the other hand, when the electronic device 110 is not in a tethering connection (i.e., when connected to a wireless LAN), the electronic device 110 can proactively connect to a new access point (e.g., a wireless LAN access point) based on the connection destination table 210.

In the example shown in FIG. 14, the case where the connection setting of the access point "FREE SPOT A" is set to "manual" is illustrated. Instead, if the connection setting of the access point "FREE SPOT A" is set to "automatic", the electronic device 110 executes a first connection with the access point "FREE SPOT A" without sending a connection permission request (S505). As a result, the access point to which the electronic device 110 is connected is automatically switched from the tethering terminal 120 to the access point "FREE SPOT A".

As described above, according to the second embodiment of the present disclosure, connection destination information including an access point specified by the user on the tethering terminal 120 is received by the electronic device 110 from the tethering terminal 120. The electronic device 110 connects to the access point indicated by the connection destination information via wireless communication. This allows the electronic device 110 to selectively connect to wireless communication networks of multiple different communication methods while preventing the electronic device 110 from connecting to a wireless communication network unintended by the user.

In addition, connection destination information including access points permitted by the user among the access points detected by the tethering terminal 120 is transmitted to the electronic device 110. Therefore, the electronic device 110 can connect to access points permitted to be connected by the tethering terminal 120 by user operation among the access points detected by the tethering terminal 120. Furthermore, the electronic device 110 can automatically connect to access points of type "automatic" that were previously connected based on the connection destination table 210.

In addition, when multiple access points are registered in the connection destination table 210, the one with the highest priority among the valid points that can currently be wirelessly connected to the electronic device 110 is identified as the target point (S901), and connection to that target point is possible (S505, S507). In other words, when multiple second access points with priority settings are registered in the connection destination table 210, the communication control unit 201 can identify and connect to the target point with the highest priority among the second access points that can currently be wirelessly connected to the electronic device 110.

In addition, if the connection setting of the target point identified in S901 is "manual", a connection permission request is sent to the tethering terminal 120 (S905), and when a response command of connection permission is received from the tethering terminal 120, the target point is connected to (S505, S507). In other words, if automatic connection prohibition is set for the identified target point, the communication control unit 201 inquires of the tethering terminal 120 connected by the second communication unit 212 about connection permission to the target point, and when connection permission is received from the tethering terminal 120, the communication control unit 201 can connect to the target point.

In the above embodiment, the connection setting does not have to be associated with the access point included in the connection destination information (in other words, the access point registered in the connection destination tables 210, 310). In this case, if the communication control unit 201 determines in S903 that the target point is an access point of a predetermined type (e.g., public), it may send a connection permission request in S905. In other words, if the identified target point is an access point of a predetermined type, the communication control unit 201 may inquire of the tethering terminal 120 connected by the second communication unit 212 about permission to connect to the target point, and may connect to the target point if permission to connect is received from the tethering terminal 120.

In addition, the user may specify in the tethering terminal 120 an access point that is prohibited from connection among the access points searched in S521. For example, in S527, connection prohibition information including the access points for which connection prohibition has been specified is transmitted to the electronic device 110. In the electronic device 110, the access points indicated in the received connection prohibition information are registered in a prohibition table stored in the control unit 200. If the target point identified in S901 is registered in the prohibition table, a connection to the target point is not performed. In other words, if a connection prohibition is set for the identified target point, the communication control unit 201 does not need to connect to the target point.

Furthermore, in the above embodiment, for example, by omitting the processing of S903, a connection permission request may be sent to the tethering terminal 120 in S905 regardless of whether the connection setting of the target point identified in S901 is "automatic" or "manual." In this case, in the tethering terminal 120, the judgment unit 304 may refer to the connection destination table 310, judge whether the connection setting of the target point is "manual" or "automatic," and execute processing according to the judgment result.

For example, if the connection setting of the target point is "automatic", the determination unit 304 automatically transmits a response command for connection permission to the electronic device 110. This response command for connection permission may be connection destination information for connecting the electronic device 110 to the target point (i.e., connection destination information including the target point). In this way, the determination unit 304 may refer to the connection destination table 310 of the tethering terminal 120 to determine whether the access point has previously been set to the connection setting "automatic", and transmit connection destination information to the electronic device 110 according to the determination result. Note that if the connection setting of the target point is "manual", the determination unit 304 may display the connection permission instruction screen 1500 and respond according to the user operation, as in the above embodiment.

[remarks]
The present disclosure is not limited to the above-described embodiment, and various modifications are possible. For example, the priority and connection settings of the access points registered in the connection destination tables 210 and 310 may be automatically changed based on various conditions. Figures 16A to 16C are data configuration diagrams of the connection destination tables 210 and 310 in the modified example. As shown in Figures 16A to 16C, the connection destination tables 210 and 310 in the modified example register the last access date and time, which is the date and time when the electronic device 110 last connected to the access point, in association with the access point.

In this modified example, when it is determined that a specified condition is met for an access point of type "public" with a relatively low security level based on the last access date and time, the priority and connection settings are updated as follows. Below, a case will be described in which it is determined that a specified condition is met when the current date has changed from the date indicated by the last access date and time. Alternatively, it may be determined that a specified condition is met when a specified time (e.g., 12 hours) has passed since the last access date and time.

In the connection destination table 210 shown in FIG. 16A, the date indicated by the last access date and time of the access point "FREE SPOT A" of the type "public" is "2021/3/9". When the current date changes, the electronic device 110 updates the connection setting of the access point "FREE SPOT A" from "automatic" to "manual" as shown in FIG. 16B. The tethering terminal 120 can also update the connection destination table 310 in the same manner as above. This makes it possible to prevent the electronic device 110 from automatically connecting to an access point of the type "public" to which the electronic device 110 has not connected for a certain period of time.

As another aspect, when the current date changes, the electronic device 110 lowers the priority of the access point "FREE SPOT A" as shown in FIG. 16C. Specifically, the priority of the access point "FREE SPOT A" is set lower than the priority of the access point "MY HOME" of the type "tethering". The tethering terminal 120 can also update the connection destination table 310 in the same manner as above. This allows the electronic device 110 to be connected preferentially to the tethering terminal 120 over an access point of the type "public" that has not been connected for a certain period of time.

As a method other than the above, the priority of the access points registered in the connection destination tables 210 and 310 may be set according to a predetermined rule (for example, earliest registration, most frequent access, longest connection time, etc.) regardless of the type of access point. Among "public" access points, the priority of those that have never experienced a network connection using another communication method (tethering, etc.) while connected to the access point may be increased. In addition, the priority of the access points registered in the connection destination tables 210 and 310 may be manually set or changed by the user at will using the tethering terminal 120.

The functional blocks of the electronic device 110 and the tethering terminal 120 may be realized by logic circuits (hardware) formed in integrated circuits (IC chips) such as ASICs (Application Specific Integrated Circuits) and FPGAs (Field Programmable Gate Arrays), or may be realized by software using a CPU (Central Processing Unit) and GPU (Graphics Processing Unit).

This disclosure is not limited to the above-described embodiments, and various modifications are possible within the scope of the claims. The technical scope of the present invention also includes embodiments obtained by appropriately combining the technical means disclosed in different embodiments. Furthermore, new technical features can be formed by combining the technical means disclosed in each embodiment.

100 Communication system, 110 Electronic device, 120 Tethering terminal, 201 Communication control unit, 202 Registration unit, 211 First communication unit, 212 Second communication unit, 301 Tethering control unit, 302 Information transmission unit, 303 Search unit, 304 Determination unit, 311 Network communication unit, 312 Device communication unit

Claims (10)

a first communication unit for wirelessly connecting to a network;
A second communication unit for wirelessly connecting to the tethering terminal;
a registration unit that registers an access point of the network in a connection destination table;
a communication control unit that controls a wireless connection with the access point registered in the connection destination table,
The communication control unit
When a first access point of the network is registered in the connection destination table, the second communication unit connects to the first access point via the tethering terminal;
When a second access point different from the first access point is registered in the connection destination table, the first communication unit connects to the second access point,
when connection destination information including the second access point is received from the tethering terminal while connected to the first access point by the second communication unit via the tethering terminal, the registration unit registers the second access point included in the connection destination information in the connection destination table, and the communication control unit connects to the second access point by the first communication unit and disconnects the second communication unit;
The connection destination information includes the second access point to which a user of the tethering terminal has given permission to connect, among the connectable second access points searched for by the tethering terminal.
Electronic devices. when the second communication unit is connected to the first access point via the tethering terminal and the connection destination information is not received from the tethering terminal, the communication control unit continues the connection to the first access point via the tethering terminal;
2. The electronic device according to claim 1. when a plurality of the second access points, each having a priority set, are registered in the connection destination table, the communication control unit identifies and connects to a target point having the highest priority among the second access points that can currently be wirelessly connected to the electronic device;
2. The electronic device according to claim 1 . A first communication unit for wirelessly connecting to a network;
A second communication unit for wirelessly connecting to the tethering terminal;
a communication control unit that is capable of connecting to the second access point via the first communication unit and disconnecting the second communication unit when connection destination information including a second access point different from the first access point is received from the tethering terminal while connected to a first access point of the network via the second communication unit via the tethering terminal;
a registration unit that registers an access point of the network in a connection destination table;
An electronic device comprising:
The registration unit registers the second access point included in the connection destination information in the connection destination table,
The communication control unit connects to the second access point registered in the connection destination table,
when a plurality of the second access points, each having a priority set, are registered in the connection destination table, the communication control unit identifies and connects to a target point having the highest priority among the second access points that can currently be wirelessly connected to the electronic device;
When automatic connection prohibition is set for the identified target point, the communication control unit inquires of the tethering terminal connected by the second communication unit about permission to connect to the target point, and when the permission to connect is received from the tethering terminal, connects to the target point.
Electronic devices. A first communication unit for wirelessly connecting to a network;
A second communication unit for wirelessly connecting to the tethering terminal;
a communication control unit that is capable of connecting to the second access point via the first communication unit and disconnecting the second communication unit when connection destination information including a second access point different from the first access point is received from the tethering terminal while connected to a first access point of the network via the second communication unit via the tethering terminal;
a registration unit that registers an access point of the network in a connection destination table;
An electronic device comprising:
The registration unit registers the second access point included in the connection destination information in the connection destination table,
The communication control unit connects to the second access point registered in the connection destination table,
the communication control unit, when a plurality of the second access points to which priority has been set are registered in the connection destination table, identifies and connects to a target point having the highest priority among the second access points that can currently be wirelessly connected to the electronic device;
When the identified target point is a predetermined type of access point, the communication control unit inquires of the tethering terminal connected by the second communication unit about permission to connect to the target point, and when the permission to connect is received from the tethering terminal, connects to the target point.
Electronic devices. the communication control unit does not connect to the target point when a connection prohibition is set for the identified target point;
6. The electronic device according to claim 3. the connection destination information includes the second access point detected by the tethering terminal and to which the tethering terminal can currently connect wirelessly;
7. The electronic device according to claim 1. A tethering terminal,
a network communication unit for wirelessly connecting to a network;
a device communication unit for wirelessly connecting to an electronic device;
a tethering control unit that executes tethering to connect the electronic device connected by the device communication unit to a first access point of the network connected by the network communication unit;
a search unit that searches for a second access point to which the tethering terminal can be connected and which is different from the first access point;
a determination unit that determines whether or not to transmit connection destination information including the second access point to the electronic device when the electronic device is connected to the first access point by the tethering;
an information transmitting unit capable of transmitting the connection destination information to the electronic device connected by the device communication unit when the determining unit determines that the connection destination information should be transmitted to the electronic device;
Equipped with
the determination unit determines that the connection destination information is to be transmitted to the electronic device when a user has given permission to connect to any of the second access points searched for by the search unit in the tethering terminal;
the connection destination information includes the second access point to which the user has given permission to connect;
Tethering device. A communication system including an electronic device and a tethering terminal,
the electronic device is capable of wirelessly connecting to a network and the tethering terminal, includes a connection destination table in which access points of the network are registered, and is capable of wirelessly connecting to the access points registered in the connection destination table;
the tethering terminal is capable of wirelessly connecting to the network and the electronic device, and is capable of executing tethering to connect the electronic device connected to the tethering terminal to a first access point of the network;
The electronic device includes:
If the first access point is registered in the connection destination table, a connection is made to the first access point via the tethering terminal;
If a second access point different from the first access point is registered in the connection destination table, a connection is made to the second access point;
When the electronic device is connected to the first access point by the tethering,
when a user gives permission to connect to any of the second access points searched for by the tethering terminal, the tethering terminal transmits, to the electronic device, connection destination information including the second access point given permission by the user;
When the electronic device receives the connection destination information from the tethering terminal, the electronic device registers the second access point included in the connection destination information in the connection destination table, connects to the second access point, and disconnects from the tethering terminal.
Communication systems. A communication method executed in a communication system including an electronic device and a tethering terminal,
the electronic device is capable of wirelessly connecting to a network and the tethering terminal, includes a connection destination table in which access points of the network are registered, and is capable of wirelessly connecting to the access points registered in the connection destination table;
the tethering terminal is capable of wirelessly connecting to the network and the electronic device, and is capable of executing tethering to connect the electronic device connected to the tethering terminal to a first access point of the network;
When the first access point is registered in the connection destination table, the electronic device connects to the first access point via the tethering terminal; and
When a second access point different from the first access point is registered in the connection destination table, the electronic device connects to the second access point; and
When the electronic device is connected to the first access point by the tethering,
When a user gives permission to connect to any of the second access points searched for by the tethering terminal, the tethering terminal transmits, to the electronic device, connection destination information including the second access point to which the user gives permission to connect;
When the electronic device receives the connection destination information from the tethering terminal, the electronic device registers the second access point included in the connection destination information in the connection destination table, connects to the second access point, and disconnects from the tethering terminal;
A communication method comprising:

Images