JP5636517B2 - Portable terminal, program and method for controlling network connection according to acceleration information - Google Patents

Description

  The present invention relates to a technology for switching a wireless network connection for a portable terminal having a plurality of wireless interfaces.

  In recent years, with the spread of smartphones, a large amount of data communication has occurred, and the traffic of 3G (3rd Generation) mobile phone networks has increased rapidly. As a result, an increase in congestion and a decrease in communication quality in this cellular phone network are problems.

  Data offloading is a technique for solving this problem. Data offload is a technique for diverting data traffic to be transferred to one communication network to another communication network.

  As an example of this technology, Patent Document 1 discloses that communication quality is improved by activating an interface unit connected to the first communication network when it is detected that the area is approaching the first communication network (wireless LAN). A wireless terminal device that monitors and switches the connection destination from the second communication network (mobile phone network) to the first communication network when the communication quality of the first communication network is good is disclosed. This wireless terminal device makes the area information of the first communication network (wireless LAN) indispensable and stores the information itself or obtains it from a server.

JP 2012-5036 A

  Normally, in a wireless terminal device that can be connected to both a mobile phone network and a wireless LAN, it is necessary to always search the wireless LAN area in order to switch the communication network appropriately, for example, even when connected to the mobile phone network. is there. As a result, a great amount of power is consumed.

  On the other hand, in the technique of Patent Document 1, the wireless terminal device stores wireless LAN area information so that the wireless LAN area does not always have to be searched. However, the area information must correspond to the actual situation and must be constantly updated. This situation is the same even when the wireless LAN area information is acquired from the server. In this case, a system including a server and a wireless terminal that constantly updates the area information must be constructed.

  Therefore, an object of the present invention is to provide a portable terminal, a connection control program, and a method that can switch the connection with a communication network without using power network area information while suppressing power consumption.

According to the present invention, a first wireless interface connected to a first wireless network and a second wireless network connected to a second wireless network included in or adjacent to the area of the first wireless network. A portable terminal equipped with a wireless interface,
An acceleration sensor for detecting acceleration;
Non-movement determining means for determining whether the portable terminal is in a non-moving state continuously for a predetermined time using acceleration information output from the acceleration sensor;
While connected to the first wireless network, the second wireless interface is stopped, and when the non-moving determination means makes a true determination, the first wireless interface is activated with the first wireless interface activated. Interface control means for activating the second wireless interface while connected to
Within-range determination means for determining whether the portable terminal is in the area of the second wireless network using the activated second wireless interface;
A connection control means for starting connection with the second wireless network when the area determination means makes a true determination;
The area determination means measures the received signal strength of the second wireless network after the connection with the second wireless network is started, and determines whether the received signal strength is a predetermined threshold value or less,
The connection control means is provided with a mobile terminal characterized in that the connection with the second wireless network is terminated when it is determined that the received signal strength is equal to or less than a predetermined threshold.

  According to the portable terminal of the present invention, the non-moving determination means is such that when the periodic acceleration fluctuation corresponding to walking is not detected for a predetermined time from the acceleration information, the portable terminal is continuously in the non-moving state for the predetermined time. It is also preferable to perform the determination.

  Furthermore, as one embodiment of the portable terminal according to the present invention, it is preferable that the connection control means starts connection with the second wireless network at least when the backlight is lit.

In addition, according to the portable terminal of the present invention, the communication quality determining means for measuring the communication quality of the first wireless network and the communication quality of the second wireless network and determining which communication quality is higher is further provided. Has
The connection control means is connected to the second wireless network when the true determination is performed by the area determination means and the communication quality determination means determines that the communication quality of the second wireless network is higher. It is also preferable to start.

According to the present invention, the first wireless interface connected to the first wireless network and the second wireless network connected to the second wireless network having an area included in or adjacent to the area of the first wireless network. A network connection control program installed in a portable terminal having two wireless interfaces,
The mobile terminal includes an acceleration sensor that detects acceleration,
The network connection control program is
Non-movement determining means for determining whether the portable terminal is in a non-moving state continuously for a predetermined time using acceleration information output from the acceleration sensor;
While connected to the first wireless network, the second wireless interface is stopped, and when the non-moving determination means makes a true determination, the first wireless interface is activated with the first wireless interface activated. Interface control means for activating the second wireless interface while connected to
Within-range determination means for determining whether the portable terminal is in the area of the second wireless network using the activated second wireless interface;
When the area determination means makes a true determination, the computer functions as a connection control means for starting connection with the second wireless network,
The area determination means measures the received signal strength of the second wireless network after the connection with the second wireless network is started, and determines whether the received signal strength is a predetermined threshold value or less,
The connection control means is provided with a network connection control program characterized in that the connection with the second wireless network is terminated when it is determined that the received signal strength is not more than a predetermined threshold value.

According to the present invention, furthermore, a first wireless interface connected to the first wireless network and a second wireless network included in or adjacent to the area of the first wireless network are connected. A network connection control method in a mobile terminal provided with a second wireless interface,
The mobile terminal includes an acceleration sensor that detects acceleration,
The network connection control method is as follows:
A first step of determining whether the mobile terminal is in a non-moving state for a predetermined time using acceleration information output from the acceleration sensor;
While connected to the first wireless network, the second wireless interface is stopped, and when the true determination is made in the first step, the first wireless interface is activated with the first wireless interface activated. A second step of activating the second wireless interface while connected to the network;
A third step of determining whether the mobile terminal is within the area of the second wireless network using the activated second wireless interface;
A fourth step of starting a connection with the second wireless network when a true determination is made in the third step;
A fifth step of measuring the received signal strength of the second wireless network after the connection with the second wireless network is started and determining whether the received signal strength is a predetermined threshold value or less;
When a true determination is made in the fifth step, a network connection control method is provided that includes a sixth step of terminating the connection with the second wireless network.

  According to the portable terminal, the network connection control program, and the method of the present invention, the connection with the wireless network can be switched without using the area information of the wireless network while suppressing the power consumption.

It is explanatory drawing which shows roughly the network connection control in the portable terminal of this invention. It is a graph which shows the time change in each axial direction component of the acceleration output from an acceleration sensor when carrying a portable terminal and walking. It is a functional block diagram which shows one Embodiment of the portable terminal by this invention. It is a flowchart which shows one Embodiment of the network connection control method by this invention (the first half). It is a flowchart which shows one Embodiment of the network connection control method by this invention (latter half).

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

  FIG. 1 is an explanatory diagram schematically showing network connection control in the portable terminal of the present invention.

According to FIG.
a) 3G (3rd Generation) mobile phone network as a first wireless network;
b) A wireless LAN (Local Area Network) as a second wireless network having a communication area 3 included in the communication area 2 of the 3G mobile phone network is provided.

  The mobile terminal 1 includes a first wireless interface 100 connected to the 3G mobile phone network, a second wireless interface 101 connected to the wireless LAN, and an acceleration sensor 102 that detects the acceleration of the mobile terminal 1. Yes.

  The user initially possesses the mobile terminal 1, moves on foot within the communication area 2 of the 3G mobile phone network, and heads for the wireless LAN communication area 3 installed in a cafe, company building, home, or the like. Here, the mobile terminal 1 is connected to the 3G mobile phone network via the first wireless interface 100. During this time, the second wireless interface 101 that can be connected to the wireless LAN is stopped.

  In such a situation, the mobile terminal 1 uses the acceleration information output from the acceleration sensor 102 to determine that the user holding the mobile terminal 1 is in a walking (moving) state. Specifically, as will be described in detail later, periodic fluctuations corresponding to walking are detected from the acceleration information, and it is determined that the user is in a moving state.

  Next, the user enters the wireless LAN communication area 3 (cafe, company building, home, or the like where the wireless LAN is installed) and stops (for example, sits down for communication). Here, the mobile terminal 1 determines that the user has stopped walking (non-moving state) continuously for a predetermined time (for example, 60 seconds) using the acceleration information output from the acceleration sensor 102 as well. Specifically, as will be described in detail later, it is determined that the user is in a non-moving state continuously for a predetermined time, assuming that periodic fluctuations corresponding to walking are not detected for a predetermined time from the acceleration information.

  Based on this determination, the portable terminal 1 activates the second wireless interface 101 on the assumption that there is a possibility of entering the communication area 3 of the wireless LAN (second wireless network 101). Next, when the portable terminal 1 determines from the signal information acquired using the activated second wireless interface 101 that it is in the communication area 3 of the wireless LAN, the portable terminal 1 is connected to the wireless LAN. To start.

  Thereafter, the user starts to move again on foot and goes outside the communication area 3 of the wireless LAN. Here, the communication area 3 of the wireless LAN is, for example, in the range of several tens to several hundreds of meters from an access point installed indoors. Accordingly, the mobile terminal 1 determines from the acceleration information of the acceleration sensor 102 that, when the user is in a walking (moving) state and has moved a predetermined number of steps (for example, 240 steps), the user is in the communication area 3 of the wireless LAN. Judge that he went out.

  When the user is in a walking (moving) state for a predetermined time (for example, 120 seconds), it can be determined that the user has gone out of the wireless LAN communication area 3.

  Based on this determination, the mobile terminal 1 starts connection with the 3G mobile phone network again, while stopping the second wireless interface 101 and ends connection with the wireless LAN.

As described above, the mobile terminal 1 is
a) Using acceleration information output from the acceleration sensor 102, it is determined whether the mobile terminal 1 is in a moving state (walking state) or in a non-moving state (a state in which walking is stopped) for a predetermined time. To do.
b) Next, based on this determination, it is assumed that the mobile terminal 1 has entered or exited the communication area 3 of the second wireless network (wireless LAN) and the first wireless network (3G mobile phone network) The connection is switched between the two wireless networks.

  As described above, the mobile terminal 1 determines the connection with the wireless network using the acceleration information. Therefore, it is not necessary to hold and update the area information of the wireless network in advance and further. That is, it is possible to appropriately switch the connection with the wireless network without using any area information of the wireless network.

  In addition, the portable terminal 1 activates the second wireless interface 101 for the first time when it is determined that it is in a non-moving state for a predetermined time when it is determined to switch the connection with the wireless network. Therefore, it is not necessary to always activate the second wireless interface 101 for switching determination. As a result, power consumption can be suppressed.

  Furthermore, the portable terminal 1 determines the activation of the wireless interface 101 in a state in which walking is stopped for a predetermined time (non-moving state). Therefore, even if the user simply walks across the communication area 3 of the second wireless network (wireless LAN), or even temporarily stops during that time, the second wireless interface 101 is not activated. No connection to the second wireless network. As a result, unnecessary activation of the wireless interface and communication connection can be avoided.

  Here, as a modification, the communication quality (received signal strength, throughput, packet error rate, etc.) of both the first and second wireless networks is compared, and it is determined that the communication quality of the second wireless network is higher. At this time, it is also possible to start connection with the second wireless network.

  In FIG. 1, only one communication area 3 of the second wireless network (wireless LAN) is shown, but a plurality of wireless LAN communication areas 3 are connected to the first wireless network (3G mobile phone network). It may be installed in the communication area 2. The activated second wireless interface 101 may be connected to any of the plurality of wireless LANs.

  Further, the first and second wireless networks are not limited to the 3G mobile phone network and the wireless LAN, respectively. For example, it is also preferred that the first wireless network has a wider communication area while the second wireless network typically provides higher speed communications.

  Further, the second wireless network is adjacent to the first wireless network, and the mobile terminal 1 moves from the communication area 2 of the first wireless network to the communication area 3 of the second wireless network, and further to the communication area. The situation may be such that the vehicle can move so as to pass in reverse.

  FIG. 2 is a graph showing temporal changes in the axial components of the acceleration output from the acceleration sensor 102 when the mobile terminal 1 is held and moved on foot.

  FIG. 2A shows the x-axis, y-axis, and z-axis assigned to the mobile terminal 1. According to the figure, the x-axis is the direction in the screen of the display 10 of the mobile terminal 1 and the axis in the terminal longitudinal direction. The y axis is a direction in the screen of the display 10 and perpendicular to the terminal longitudinal direction. The z axis is an axis in a direction perpendicular to the screen of the display 10.

Next, FIG. 2B shows an actual measurement example of the output from the acceleration sensor 102 when the user moves the mobile terminal 1 in a pants pocket and moves on foot. FIG. 2C shows an actual measurement example of the output from the acceleration sensor 102 when the user moves on foot while holding the mobile terminal 1 in hand. Each of these figures
X-axis direction component of acceleration: ACC _x ,
Y-axis direction component of acceleration: ACC _y , and z-axis direction component of acceleration: ACC _z
Each time change of is represented as a graph. In addition, the vertical axis | shaft of a graph is an acceleration and a unit is [G] (1G = 9.8m / s < ² >).

According to FIG. 2 (B), ACC _x , ACC _y, and ACC _z all indicate values that vary periodically. This period (T = about 1.1 seconds) corresponds to a walking period, and these periodic fluctuations indicate that the user is moving on foot. The frequency of this fluctuation is about 0.91 Hz in any of ACC _x , ACC _y and ACC _z . The walking cycle is a time period corresponding to two steps from the contact of the heel to the contact of the heel of the same foot. Therefore, the frequency of fluctuation in FIG. 2B is a frequency of a cycle every two steps.

On the other hand, also in FIG. 2 (C), ACC _x , ACC _y, and ACC _z all indicate values that vary periodically. This period (T = about 0.54 seconds) corresponds to half of the walking period, and these periodic fluctuations also indicate that the user is moving on foot. The frequency of this fluctuation is about 1.83 Hz in any of ACC _x , ACC _y and ACC _z . This frequency corresponds to the frequency of the cycle for each step.

  Next, for example, by the following methods a1) to a3) or b1) to b3), each acceleration data shown in FIGS. 2B and 2C includes periodic fluctuations corresponding to walking motion. If the periodic acceleration fluctuation corresponding to walking is detected from the acceleration information, it is determined that the portable terminal 1 is in a moving (walking) state. On the other hand, when a periodic change in acceleration corresponding to walking is not detected for a predetermined time from the acceleration information, the mobile terminal 1 determines that it is in a non-moving state (a state in which walking is stopped) continuously for a predetermined time. Furthermore, when a periodic fluctuation corresponding to walking motion is detected, the number of steps is calculated by counting the number of fluctuations.

Here, one method for extracting periodic fluctuations corresponding to walking motion from the acceleration data will be described. This method uses the technique disclosed in Japanese Patent Application Laid-Open No. 2012-21870.
a1) First, vertical acceleration is calculated from acceleration data (ACC _x , ACC _y and ACC _z ).
a2) Next, the local maximum point (or local minimum point) of vertical acceleration is detected as the walking timing. Here, the maximum point (minimum point) corresponds to the time when the body is lowered and the foot is grounded (the foot is raised with the body), and every time the maximum point (minimum point) appears in the vertical acceleration graph. This means that walking has progressed by one step.

a3) Finally, when the walking timing is not detected within a predetermined time (for example, 60 seconds), it is determined that there is no periodic variation corresponding to the walking motion. On the other hand, when the walking timing is detected within a predetermined time, it is determined that there is a periodic variation corresponding to the walking motion, and the number of detected walking timings is determined as the number of steps within the predetermined time.

Furthermore, another method for extracting periodic fluctuations corresponding to walking motion from acceleration data will be described.
b1) First, when the mobile terminal 1 is housed in a pants pocket and moved on foot, or when the mobile terminal 1 is held on hand and moved on foot, the acceleration axial components are measured, and the measured values Investigate the Fourier transform (spectrum analysis) pattern. Thereby, the spectrum pattern used as the reference | standard of walk judgment is determined, and the same pattern is memorize | stored beforehand. Here, this spectrum pattern is a pattern having a specific amplitude (power) in a period corresponding to walking motion.

b2) Next, a Fourier transform process is performed on each of ACC _x , ACC _y, and ACC _z actually measured at the predetermined time T ₁ .
b3) Finally, when the Fourier transform spectra of ACC _x , ACC _y, and ACC _z subjected to the Fourier transform process are approximated within a predetermined range to a spectrum pattern stored in advance, the mobile terminal 1 is in a walking (moving) state. Judge that it was in. On the other hand, when the Fourier transform spectrum of ACC _x , ACC _y and ACC _z does not approximate the spectrum pattern stored in advance, the portable terminal 1 continuously stops walking for a predetermined time T ₁ (non-moving state). It is determined that

In addition to the above, it is also possible to apply the walking determination and step counting methods used in the conventional pedometer. As described above, the mobile terminal 1 uses the acceleration information output from the acceleration sensor 102 to determine whether or not the mobile terminal 1 is in a non-moving state for a predetermined time T ₁ or is in a moving state. It can be determined whether or not.

As a further modification, the standard deviation σ _{acc of} acceleration from the data of ACC _x , ACC _y and ACC _{z at} a predetermined time T ₁ , that is,
σ _acc = (Σ (| ACC | _i −av | ACC |) ² / n) ^0.5
This standard deviation σ _acc is determined by the following conditional expression σ _acc ≦ S with S as a predetermined threshold value
If satisfying, the time T _1, the mobile terminal 1 can be determined that there in a non-moving state. Here, | ACC | _i is the magnitude of acceleration calculated from the values of ACC _x , ACC _y and ACC _z obtained at each sampling time. Further, av | ACC | is an average value of | ACC | _i (i = 1, 2,..., N: n is the number of sampling times). Further, Σ is a summation about i.

  However, in general, when a user enters or leaves the wireless LAN communication area 3 set in a cafe, company building, home, or the like, the movement form may actually be walking. Is almost. Therefore, as described above, by determining the presence or absence of walking, it is possible to connect to the wireless LAN more reliably in a situation where the wireless LAN can be connected. Further, the second wireless interface can be more reliably kept stopped in a situation where it is not necessary or impossible to connect to the wireless LAN.

  FIG. 3 is a functional configuration diagram showing an embodiment of the mobile terminal 1 according to the present invention.

  As shown in FIG. 3, the mobile terminal 1 includes a first wireless interface 100, a second wireless interface 101, an acceleration sensor 102, and a processor memory. Here, the processor memory realizes its function by executing a program.

  In addition, the processor memory includes a communication unit 110, a non-movement determination unit 120, an interface control unit 121, a range determination unit 122, a communication quality determination unit 123, and a connection control unit 124 as functional components. .

  The first wireless interface 100 is connected to the first wireless network (3G mobile phone network) and mediates communication with the first wireless network. On the other hand, the second wireless interface 101 is connected to a second wireless network (wireless LAN) having a communication area 3 included in or adjacent to the communication area 2 of the first wireless network, Mediate communications.

  The acceleration sensor 102 can be a three-axis type acceleration measuring instrument formed by using a micro electro mechanical systems (MEMS) technique, for example, by a capacitance method or a piezoresistive method. As the acceleration sensor 102, an acceleration sensor that measures gravitational acceleration to determine the vertical posture of the mobile terminal 1 or counts the number of steps of the user who holds the mobile terminal 1 may be used.

  The non-moving determination unit 120 uses the acceleration information output from the acceleration sensor 102 to determine whether or not the mobile terminal 1 is in a non-moving state (a state in which walking is stopped) continuously for a predetermined time. It is determined whether or not is in a moving state.

  Specifically, the non-moving determination unit 120 determines that the mobile terminal 1 is in a non-moving state continuously for a predetermined time when a periodic acceleration fluctuation corresponding to walking is not detected from the acceleration information for a predetermined time. Do. Further, when a periodic change in acceleration corresponding to walking is detected within the predetermined time from the acceleration information, it is determined that the mobile terminal 1 is in a moving state. Further, these determination results are output to the interface control unit 121.

  The interface control unit 121 stops the second wireless interface 101 while connected to the first wireless network. Further, when the determination result that the non-moving state (the state in which walking is stopped) is obtained from the non-moving determining unit 120 for a predetermined time, the second wireless interface 101 is activated. Further, the interface control unit 121 outputs start / stop information of the first and second wireless interfaces 100 and 101 to the connection control unit 124.

  The area determination unit 122 determines whether the mobile terminal 1 is in the communication area 3 of the second wireless network from the presence or absence of the reception signal or the strength of the reception signal using the activated second wireless interface 101. To do. The determination result is output to the connection control unit 124. On the other hand, the communication quality determination unit 123 measures the communication quality of the first wireless network (received signal strength, throughput, packet error rate, etc.) and the communication quality of the second wireless network, Determine if it is high. The determination result is output to the connection control unit 124.

  The connection control unit 124 starts connection with the second wireless network when the area determination unit 122 determines that the mobile terminal 1 is in the communication area 3 of the second wireless network. As a change mode, the connection control unit 124 determines that the mobile terminal 1 is within the communication area 3 of the second wireless network by the area determination unit 122 and the second wireless communication by the communication quality determination unit 123. It is also preferable to start connection with the second wireless network when it is determined that the communication quality of the network is higher.

  The connection control unit 124 further detects the second wireless network when the non-movement determining unit 120 determines that the mobile terminal 1 is in the moving state after the connection to the second wireless network is started. Terminate the connection with. Further, as a change mode, the connection control unit 124 indicates that the mobile terminal 1 is not in the communication area 3 of the second wireless network by the area determination unit 122 after the connection with the second wireless network is started. It is also preferable to terminate the connection with the second wireless network when the determination is made.

Here, the area determination unit 122 measures (monitors) the received signal strength from the access point of the second wireless network, and when the received signal strength falls below a predetermined threshold value _h , the communication area of the second wireless network 3 can be determined not to be present.

  Further, the connection control unit 124 outputs connection / disconnection information of the first and second wireless interfaces 100 and 101 to the interface control unit 121.

  The communication unit 110 transmits / receives data, voice, and the like via the first and second wireless networks using the path controlled by the connection control unit 124.

  4 and 5 are flowcharts showing an embodiment of a network connection control method according to the present invention.

[Switching connection from first wireless network to second wireless network]
First, each step will be described with reference to FIG.
(S400) Initially, communication is established with the first wireless network (3G mobile phone network).
(S401) Initially, the second wireless interface 101 is stopped, and if not stopped at this step, the second wireless interface 101 is stopped.

(S402) A non-movement determination loop (steps S402 to S406) is started. Here, the start time t is zero, the sampling time interval of the acceleration measured as Delta] t, the non-movement determination time is T _1. In addition, the initial value of the parameter i for the number of times of sampling (elapsed time) is set to zero. Note that the non-movement determination time T ₁ is set to T ₁ = 60 (seconds), for example.

(S403) The parameter i is incremented by 1.
(S404) Wait until time t reaches t = Δt × i.
(S405) The accelerations ACC _xi , ACC _yi and ACC _zi are measured.

(S406) time t, when satisfying the condition of t ≧ _{T 1} (when time _{T 1} from the loop start has elapsed), and terminates the non-movement determination loop.
(S407) The vertical acceleration is calculated from the measured acceleration data (ACC _xi , ACC _yi and ACC _zi ), and the walking timing as the maximum point is detected.
(S408) the mobile terminal 1 determines whether a non-moving state continues for a time T ₁ (the state was stopped walking). In this case, it is also preferred to walk timing during the time T ₁ is is determined whether or not detected.

(S409) real determined in step S408, i.e., when the portable terminal 1 has been performed a determination to be in continuous to non-moving state during the time T _1, to activate the second radio interface 101.
On the other hand, when a false determination is made in step S408, the non-movement determination loop (steps S402 to S406) is performed again to monitor the acceleration.

(S410) It waits for a beacon signal transmitted from the access point of the second wireless network, and receives the beacon signal if it is transmitted.
(S411) When a beacon signal is received, the communication quality (reception signal strength, throughput, packet error rate, etc.) of the second wireless network is measured from this beacon signal or from the result of transmission / reception of a predetermined signal.
(S412) It is determined whether or not the mobile terminal 1 is in the communication area 3 of the second wireless network from the presence or absence of the beacon signal or the received signal strength.

(S413) A beacon signal transmitted from the base station of the first wireless network when a true determination is made in step S412, that is, when it is determined that the mobile terminal 1 is in the communication area 3 of the second wireless network. Receive.
On the other hand, when a false determination is made in step S412, the second wireless interface is stopped, and the mobile terminal 1 moves to a movement determination (steps S520 and S521 in FIG. 5).

(S414) The communication quality of the first wireless network is measured from the received beacon signal or from the result of sending and receiving the predetermined signal.
(S415) The communication qualities of the first and second wireless networks are compared to determine whether the communication quality of the second wireless network is higher.

(S416) When a true determination is made in step S415, that is, a determination that the communication quality of the second wireless network is higher, a LAN connection request is transmitted to the access point of the second network.
On the other hand, when a false determination is made in step S415, the second wireless interface is stopped and the mobile terminal 1 moves to a movement determination (steps S520 and S521 in FIG. 5).

  In addition, as a change mode, steps S411 and S414 (communication quality measurement) and step S415 (communication quality comparison determination) can be omitted. In other words, if a true determination is made in step S412 (communication area determination), an embodiment in which the process proceeds to step S416 (LAN connection request) is possible.

  Further, as a further change mode, whether or not the backlight of the display 10 of the mobile terminal 1 is turned on after the determination that the mobile terminal 1 is in the communication area 3 is made in step S412. It is also possible to determine.

  In this case, when it is determined that the backlight is turned on, the process proceeds to step S413 and subsequent steps (connection to the second wireless network). In fact, when the backlight is on, the user is likely to communicate on the spot. Therefore, by turning on the backlight as a condition for connection with the second wireless network, the connection can be switched more reliably in a situation where the user is actually communicating and switching of the communication connection is effective. it can.

(S417) A LAN connection response is received from the access point of the second wireless network.
(S418) Connect to the second wireless network and establish communication.
(S419) It is also preferable to stop the first wireless interface 100 after connection to the second wireless network. Thereby, the power consumption by the interface which is not connected is suppressed. This completes the connection switching from the first wireless network to the second wireless network.

  Here, when the first wireless network is a 3G telephone communication network and the second wireless network is a wireless LAN, it waits for an incoming voice communication even after connection to the second wireless network (S418). It is also preferable not to stop the first wireless interface 100. On the other hand, for example, when the first wireless network is WiMAX (Worldwide Interoperability for Microwave Access) and the second wireless network is a wireless LAN, both networks are used for data communication. 100 can be stopped.

[Switching connection from second wireless network to first wireless network]
Hereinafter, subsequent steps will be described with reference to FIG.

Initially, communication is established with the second wireless network (wireless LAN).
(S500) The movement determination loop (steps S500 to S504) is started. Here, the start time t is zero, the sampling time interval of the acceleration measured as Delta] t, the non-movement determination time and T _2. In addition, the initial value of the parameter j for the number of times of sampling (elapsed time) is set to zero. The movement determination time T ₂ is set to T ₂ = 120 (seconds), for example.

(S501) The parameter j is incremented by 1.
(S502) Wait until time t reaches t = Δt × j.
(S503) The accelerations ACC _xj , ACC _yj and ACC _zj are measured.

(S504) time t, when satisfying the condition of t ≧ _{T 2} (when time _{T 2} from the loop start has elapsed), and ends this moving determination loop.
(S505) calculates the number of steps during the immediately preceding moving determination loop (moving determination time T _2), accumulates the first movement determining loop after the start of the step number N _w.

(S506) the number of steps _{N w} is equal to or a predetermined threshold value _{N th} or more _{(N w} ≧ _{N th).} Here, the threshold value N _th is 240 (steps), for example.
(S507) When a true determination is made in step S506, that is, when it is determined that N _w ≧ N _th , the first wireless interface 101 is changed (if the first wireless interface 101 is stopped). Start.
On the other hand, when a false determination is made in step S506, the movement determination loop (steps S500 to S504) is performed again to monitor the acceleration.

(S508) A beacon signal transmitted from the base station of the first wireless network is received.
(S509) A 3G connection request is transmitted to the base station of the first wireless network.
(S510) A 3G connection response is received from the base station of the first wireless network.
(S511) Connect to the first network and establish communication.
(S512) The second wireless interface 101 is stopped. This completes the connection switching from the second wireless network to the first wireless network.

  Here, when a false determination is made in step S408 (determination of whether or not in a non-moving state) or S412 (determination of whether or not in communication range) in FIG. 4, that is, the second wireless interface 101 is activated. Will describe steps (S520 to S523) in the case where does not connect to the second wireless network.

(S520) The second wireless interface 101 is stopped.
(S521) The movement determination loop is started. This loop can be equivalent to the movement determination loop (steps S500 to S504) described above.
(S522) calculates the number of steps during the immediately preceding moving determination loop (moving determination time T _2), accumulates the first movement determining loop after the start of the step number N _w.

(S523) the number of steps _{N w} is equal to or a predetermined threshold value _{N th} or more _{(N w} ≧ _{N th).} Here, the threshold value N _th is 240 (steps), for example.
When a true determination is made in step S523, that is, a determination that N _w ≧ N _th is made, the start-up / stop circuit in the second wireless interface 101 is terminated. On the other hand, if a false determination is made in step S523, the process returns to step S521 to repeat the movement determination loop for calculating the number of steps.

  As a result, the stopped second wireless interface 101 is in a state where it can be activated again only after the mobile terminal 1 has moved a predetermined number of steps (predetermined distance). That is, when the mobile terminal 1 is not connected to the second wireless network, even if the mobile terminal 1 is in a non-moving state, the second wireless interface 101 is not activated again.

As a change mode, instead of the step count measurement / determination in steps S500 to S506,
(S501 ′) Measure (monitor) the received signal strength I _lan from the access point of the second wireless network,
(S502 ′) It is determined whether or not the received signal strength I _lan is equal to or less than a predetermined threshold I _th (I _lan ≦ I _th ). If I _lan ≦ I _th , the process _{proceeds to} step S507 (activation of the first wireless interface). Embodiments that use such steps are also possible.

  As described above in detail, according to the mobile terminal, network connection control program and method of the present invention, it is determined whether or not the mobile terminal 1 is in a non-moving state based on the acceleration information of the mobile terminal 1 and is necessary. The second wireless interface is activated according to the possibility of becoming. As a result, it is possible to switch the connection with the wireless network without using the area information of the wireless network while suppressing power consumption.

  Furthermore, data offload for diverting data traffic to be transferred to the mobile phone network to another wireless network can be appropriately performed. As a result, it is possible to contribute to suppression of increase in congestion and deterioration in communication quality in the mobile phone network.

  It should be noted that all of the embodiments described above are illustrative of the present invention and are not intended to be limiting, and the present invention can be implemented in other various modifications and changes. Therefore, the scope of the present invention is defined only by the claims and their equivalents.

DESCRIPTION OF SYMBOLS 1 Mobile terminal 10 Display 100 1st radio | wireless interface 101 2nd radio | wireless interface 102 Acceleration sensor 110 Communication part 120 Non-movement determination part 121 Interface control part 122 Area determination part 123 Communication quality determination part 124 Connection control part 2 3G mobile telephone network Communication area (communication area of the first wireless network)
3 Wireless LAN communication area (communication area of the second wireless network)

Claims (6)

A first wireless interface connected to the first wireless network, and a second wireless interface connected to a second wireless network included in or adjacent to the area of the first wireless network. A mobile device,
An acceleration sensor for detecting acceleration;
Non-movement determining means for determining whether or not the mobile terminal is in a non-moving state for a predetermined time using acceleration information output from the acceleration sensor;
While connected to the first wireless network, the second wireless interface is stopped, and when the non-movement determination means makes a true determination, the first wireless interface is activated Interface control means for activating the second wireless interface while connected to the first wireless network;
Within-range determination means for determining whether or not the mobile terminal is within the area of the second wireless network using the activated second wireless interface;
A connection control means for starting connection with the second wireless network when the area determination means makes a true determination;
The range determination means measures the received signal strength of the second wireless network after the connection with the second wireless network is started, and determines whether the received signal strength is equal to or less than a predetermined threshold. ,
The mobile terminal according to claim 1, wherein the connection control unit terminates the connection with the second wireless network when it is determined that the received signal strength is equal to or less than a predetermined threshold.   The non-moving determination means determines that the mobile terminal is in a non-moving state continuously for the predetermined time when a periodic acceleration fluctuation corresponding to walking is not detected from the acceleration information for the predetermined time. The mobile terminal according to claim 1.   The portable terminal according to claim 1 or 2, wherein the connection control means starts connection with the second wireless network at least when a backlight is lit. Further comprising communication quality determination means for measuring communication quality of the first wireless network and communication quality of the second wireless network and determining which communication quality is higher,
The connection control means, when the true determination is performed by the area determination means and when the communication quality determination means determines that the communication quality of the second wireless network is higher, The mobile terminal according to any one of claims 1 to 3, wherein connection with a wireless network is started. A first wireless interface connected to the first wireless network, and a second wireless interface connected to a second wireless network included in or adjacent to the area of the first wireless network. A network connection control program installed in a mobile terminal,
The portable terminal includes an acceleration sensor that detects acceleration,
The network connection control program is:
Non-movement determining means for determining whether or not the mobile terminal is in a non-moving state for a predetermined time using acceleration information output from the acceleration sensor;
While connected to the first wireless network, the second wireless interface is stopped, and when the non-movement determination means makes a true determination, the first wireless interface is activated Interface control means for activating the second wireless interface while connected to the first wireless network;
Within-range determination means for determining whether or not the mobile terminal is within the area of the second wireless network using the activated second wireless interface;
When the area determination means makes a true determination, the computer functions as a connection control means for starting connection with the second wireless network,
The range determination means measures the received signal strength of the second wireless network after the connection with the second wireless network is started, and determines whether the received signal strength is equal to or less than a predetermined threshold. ,
The connection control means terminates the connection with the second wireless network when it is determined that the received signal strength is equal to or less than a predetermined threshold. A first wireless interface connected to the first wireless network, and a second wireless interface connected to a second wireless network included in or adjacent to the area of the first wireless network. A network connection control method in a mobile terminal,
The portable terminal includes an acceleration sensor that detects acceleration,
The network connection control method includes:
A first step of determining whether or not the mobile terminal is in a non-moving state for a predetermined time using acceleration information output from the acceleration sensor;
While connected to the first wireless network, the second wireless interface is stopped, and when a true determination is made in the first step, the first wireless interface is activated. A second step of activating the second wireless interface while connected to the first wireless network;
Using the activated second wireless interface, a third step of determining whether the portable terminal is within the area of the second wireless network;
A fourth step of starting a connection with the second wireless network when a true determination is made in the third step;
A fifth step of measuring the received signal strength of the second wireless network after the connection with the second wireless network is started and determining whether the received signal strength is a predetermined threshold value or less;
A network connection control method, comprising: a sixth step of terminating connection with the second wireless network when a true determination is made in the fifth step.

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