JP5749310B2 - Method of connecting wireless link when it is determined as non-moving state using movement detection sensor, portable terminal, and program - Google Patents

Description

  The present invention relates to a technology for automatically starting a wireless LAN (Local Area Network) interface in a mobile terminal.

  In recent years, with the spread of smartphones, a large amount of data communication has occurred, the traffic on the mobile phone network has increased rapidly, and there has been a problem of increased congestion and decreased communication quality. As a technique for solving this, there is data offload. Data offload is a technique for diverting data traffic to be transferred to one communication network to the other communication network.

  Conventionally, when a mobile terminal detects that it is approaching a wireless LAN area, the wireless LAN interface is activated to monitor the communication quality, and when the communication quality is good, the connection destination is changed from the mobile phone network to the wireless LAN. There is a technique for switching (see, for example, Patent Document 1). According to this technology, the mobile terminal holds wireless LAN area information in advance, and determines the activation timing of the wireless LAN interface by comparing it with the current position. The portable terminal previously downloads the wireless LAN area information from the server via the network.

  As another technique, there is a technique for automatically starting a wireless LAN interface when an acceleration sensor is constantly activated and a stopped state continues for a predetermined time, which is an application tool for a smartphone (for example, non-patented). Reference 1).

  As another technique using an acceleration sensor, there is a technique for estimating a user's movement state (walking, running, stopping, bicycle, automobile, bus, train) (see, for example, Non-Patent Document 2). According to this technology, it is possible to estimate a moving state from acceleration data and automatically generate and store a life log by simply holding the portable terminal in a bag. However, it is difficult to estimate the movement state accurately because a movement different from the movement such as a user operation on the portable terminal becomes noise.

JP 2012-5036 A

"Kyocera Intelligent Wi-Fi", [online], [Search August 24, 2013], Internet <URL: http://www.kyocera.co.jp/prdct/telecom/consumer/202k/function3/index .html> A. Kobayashi, Kengo Iwamoto, Satoshi Nishiyama, “User Mobile State Estimation Method Using Mobile Phones”, IPSJ Journal, Vol.50, No.1, pp.193-208, 2009, [online], [ Search on August 24, 2013], Internet <URL: http://ci.nii.ac.jp/naid/10021819284>

  When automatically connecting to a wireless LAN, the mobile terminal needs to constantly search for an access point even while the mobile phone network is connected. Even when there is no access point around the current position of the mobile terminal, it is necessary to activate the wireless LAN interface, and wasteful power consumption for the battery is required.

  On the other hand, according to the technique described in Patent Document 1, it is not necessary to constantly search for a wireless LAN area because the mobile terminal stores wireless LAN area information in advance. However, the wireless LAN area information must be constantly updated according to the actual situation. In addition, the mobile terminal must always start the positioning unit and constantly compare the current position with the wireless LAN area information, and wasteful power consumption for the battery is required.

  Further, according to the technique described in Non-Patent Document 1, it is not necessary to always activate the wireless LAN interface, but it is necessary to always activate the acceleration sensor in order to determine the movement state. From the viewpoint of power consumption for the battery, the power consumption of the acceleration sensor itself is less than that of the wireless LAN interface. However, the power consumption increases due to the processing load of the CPU for the arithmetic processing for estimating the movement state from the acceleration data obtained from the acceleration sensor.

  Accordingly, an object of the present invention is to provide a method, a portable terminal, and a program capable of detecting a wireless network as a data offload destination and connecting a wireless link while suppressing power consumption as much as possible.

According to the present invention, in a wireless link connection method of a mobile terminal including a wireless communication unit that communicates with an access point, a movement detection sensor, and a display that is visually recognized by a user ,
A first step of activating both the wireless communication unit and the movement detection sensor when the display backlight is turned on after returning from the sleep state by a user operation ;
A second step of detecting an access point of a desired connection destination by a peripheral scan of the wireless communication unit and determining whether or not a non-moving state by data from a movement detection sensor;
When the second step is determined to be true, the access point of the desired connection destination previously detected by the scan of the wireless communication unit is detected again after the predetermined standby time has elapsed, and the non-existence is determined by the data from the movement detection sensor. A third step of determining whether or not the vehicle is in a moving state;
When it is determined that the third step is true, the wireless communication unit includes a fourth step of connecting the wireless link to the desired connection destination access point.

According to another embodiment of the wireless link connection method of the present invention,
The portable terminal stores an access point identifier of a desired connection destination in advance,
The second step and the third step are:
Determining whether the access point detected by the wireless communication unit matches a pre-stored access point identifier;
It is also preferable to determine whether or not the vehicle is in a non-moving state based on data collected from the movement detection sensor during a predetermined detection time.

According to another embodiment of the wireless link connection method of the present invention,
The movement detection sensor is an acceleration sensor,
The mobile terminal stores in advance model data in which a movement probability p _i is associated with a model feature vector of a predetermined dimension calculated by FFT (Fast Fourier Transform) from acceleration data,
Regarding the determination of the non-moving state in the second step and the third step,
A current vector of a predetermined dimension is calculated by executing FFT on the acceleration data output from the acceleration sensor for each unit time with a predetermined time window width,
Search for the model feature vector that is closest to the current vector,
Obtain the movement probability p _i associated with the model feature vector,
A movement probability value P (t) = Πp (t) obtained by acquiring a movement probability p (t) per unit time for a predetermined time and multiplying a plurality of movement probabilities p (t),
It is also preferable to determine that the movement determination value P (t) is not moving when the movement determination value P (t) is equal to or less than a predetermined threshold.

According to another embodiment of the wireless link connection method of the present invention,
The predetermined detection time of the third step is shorter than the predetermined detection time of the second step and is repeated a plurality of times.
The determination of the non-moving state in the third step is performed every time the predetermined detection time elapses.
A movement judgment value P (t) = Πp (t) obtained by multiplying a plurality of past movement probabilities p (t) is calculated,
It is also preferable that when the movement determination value P (t) is equal to or less than a predetermined threshold value, it is determined that the movement is not performed, and the repetition process is stopped.

According to another embodiment of the wireless link connection method of the present invention,
Model data is
From the acceleration data measured in advance in a number of different movement states, calculate a model vector of a predetermined dimension by performing FFT every unit time with a predetermined time window width,
Classifying multiple model vectors into a predetermined number of clusters by clustering,
For each cluster, calculate a representative model feature vector,
It is also preferable that the model feature vector is created by associating the movement probability p _i corresponding to the movement state of the cluster.

According to the present invention, in a mobile terminal including a wireless communication unit that communicates with an access point, a movement detection sensor, and a display that is visually recognized by a user ,
An activation start control means for activating both the wireless communication unit and the movement detection sensor when the display backlight is turned on by returning from the sleep state by a user operation ;
A first determination unit that detects an access point of a desired connection destination by a peripheral scan of a wireless communication unit and determines whether or not a non-moving state is detected by data from a movement detection sensor;
When the first determination means is determined to be true, the access point of the desired connection destination previously detected by the scan of the wireless communication unit is detected again after the elapse of the predetermined standby time, and the data from the movement detection sensor is used. Second determination means for determining whether or not the vehicle is in a non-moving state;
When it is determined that the second determination unit is true, the wireless communication unit includes a wireless link connection unit that connects a wireless link to an access point of a desired connection destination using a wireless communication unit.

According to another embodiment of the mobile terminal of the present invention,
The access point identifier of the desired connection destination is stored in advance,
The first determination means and the second determination means are:
Determining whether the access point detected by the wireless communication unit matches a pre-stored access point identifier;
It is also preferable to determine whether or not the vehicle is in a non-moving state based on data collected from the movement detection sensor during a predetermined detection time.

According to another embodiment of the mobile terminal of the present invention,
The movement detection sensor is an acceleration sensor,
Model data storage means for storing in advance model data in which a movement probability p _i is associated with a model feature vector of a predetermined dimension calculated by FFT from acceleration data;
Regarding the determination of the non-moving state in the first determination means and the second determination means,
A current vector of a predetermined dimension is calculated by executing FFT on the acceleration data output from the acceleration sensor for each unit time with a predetermined time window width,
Search for the model feature vector that is closest to the current vector,
Calculating the movement probability p _i associated with the model feature vector;
A movement probability value P (t) = Πp (t) obtained by acquiring a movement probability p (t) per unit time for a predetermined time and multiplying a plurality of movement probabilities p (t),
It is also preferable to determine that the movement determination value P (t) is not moving when the movement determination value P (t) is equal to or less than a predetermined threshold.

According to another embodiment of the mobile terminal of the present invention,
The predetermined detection time of the second determination means is shorter than the predetermined detection time of the first determination means and is repeated a plurality of times.
The determination of the non-moving state of the second determination means is performed every time the predetermined detection time elapses.
A movement judgment value P (t) = Πp (t) obtained by multiplying a plurality of past movement probabilities p (t) is calculated,
It is also preferable that when the movement determination value P (t) is equal to or less than a predetermined threshold value, it is determined that the movement is not performed, and the repetition process is stopped.

According to another embodiment of the mobile terminal of the present invention,
Model data is
From the acceleration data measured in advance in a number of different movement states, calculate a model vector of a predetermined dimension by performing FFT every unit time with a predetermined time window width,
Classifying a given number of clusters by clustering multiple model vectors,
For each cluster, calculate a representative model feature vector,
It is also preferable that the model feature vector is created by associating the movement probability p _i corresponding to the movement state of the cluster.

According to the present invention, in a program for causing a computer mounted on a portable terminal having a wireless communication unit that communicates with an access point, a movement detection sensor, and a display visually recognized by a user to function,
An activation start control means for activating both the wireless communication unit and the movement detection sensor when the display backlight is turned on by returning from the sleep state by a user operation ;
A first determination unit that detects an access point of a desired connection destination by a peripheral scan of a wireless communication unit and determines whether or not a non-moving state is detected by data from a movement detection sensor;
When the first determination means is determined to be true, the access point of the desired connection destination previously detected by the scan of the wireless communication unit is detected again after the elapse of the predetermined standby time, and the data from the movement detection sensor is used. Second determination means for determining whether or not the vehicle is in a non-moving state;
When the second determination means is determined to be true, the wireless communication unit is used to cause the computer to function as a wireless link connection means for connecting a wireless link to a desired connection destination access point.

  According to the wireless link connection method, portable terminal, and program of the present invention, it is possible to connect a wireless link by detecting a wireless network that is a data offload destination while suppressing power consumption as much as possible.

It is explanatory drawing showing the connection control of the wireless network according to the movement of the portable terminal in this invention. It is a functional block diagram of the portable terminal in this invention. It is a flowchart showing the process of the portable terminal in this invention. It is explanatory drawing showing the process of the portable terminal according to the movement in this invention. It is explanatory drawing showing determination of the non-moving state based on the acceleration data in this invention. It is explanatory drawing showing the production | generation of the model data in this invention.

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

  FIG. 1 is an explanatory diagram showing connection control of a wireless network according to movement of a mobile terminal in the present invention.

According to the system of FIG. 1, two wireless networks are arranged.
(1) First wireless network: Wireless WAN (Wide Area Network) (for example, a cellular phone network or a WiMAX (Worldwide Interoperability for Microwave Access) network)
(2) Second wireless network: Wireless LAN (Local Area Network)
In the following description, it is assumed that the wireless WAN is a mobile phone network.

The mobile terminal 1 includes at least the following four functional units as hardware.
(1) First wireless communication unit connected to the wireless WAN (2) Second wireless communication unit connected to the wireless LAN (3) User interface such as a display (4) Movement detection sensor such as an acceleration sensor The possessed portable terminal 1 moves with the user. In addition, the mobile terminal 1 is always connected to the wireless WAN regardless of where the mobile terminal 1 moves.

According to FIG. 1, the mobile terminal of the present invention controls the connection of the wireless network in the following steps.
(S11) It is assumed that the mobile terminal 1 enters the wireless LAN area of the desired connection destination access point as the user moves. Then, assume that the user depresses the switch of the mobile terminal 1 to return from the sleep state, and the backlight of the display is turned on. At this time, the mobile terminal 1 activates the power of the movement detection sensor and the second wireless communication unit.
Next, when the user stops, the “non-moving state” is detected by data from the movement detection sensor of the mobile terminal 1.
In addition, the second wireless communication unit of the mobile terminal 1 searches for a wireless LAN access point. According to FIG. 1, it is assumed that an access point of a desired connection destination is found. Then, the portable terminal 1 switches from the first wireless communication unit connected to the mobile phone network to the second wireless communication unit connected to the wireless LAN in order to perform data offload for subsequent data communication. As long as the mobile terminal 1 is in the wireless LAN area, the data offload is continued.

(S12) Thereafter, it is assumed that the user moves again and the mobile terminal 1 enters the wireless LAN area of the access point of the undesired connection destination. Then, it is assumed that the user depresses the switch of the mobile terminal 1 to return from the sleep state. At this time, the mobile terminal 1 activates the power of the movement detection sensor and the second wireless communication unit.
Next, when the user stops, the “non-moving state” is detected by data from the movement detection sensor of the mobile terminal 1.
In addition, it is assumed that the second wireless communication unit of the mobile terminal 1 searches for a wireless LAN access point, but the desired connection destination access point is not found. Then, the mobile terminal 1 continues data communication with the mobile phone network without executing data offload.

  In addition, according to the present invention, it is assumed that the mobile terminal uses the start timing of the connection sequence to the fixed access point as a use application, and until the connection to the mobile access point such as a mobile router, Not assumed.

FIG. 2 is a functional configuration diagram of the mobile terminal according to the present invention.
FIG. 3 is a flowchart showing processing of the mobile terminal in the present invention.
FIG. 4 is an explanatory diagram showing processing of the mobile terminal according to movement in the present invention.

  The mobile terminal 1 includes, as hardware, a first wireless communication unit 101 connected to a mobile phone network, a second wireless communication unit 102 connected to a wireless LAN, a user interface 103 such as a display, and movement detection. An acceleration sensor 104. The acceleration sensor 104 may be, for example, a capacitance type or piezoresistive type triaxial acceleration measuring instrument formed by, for example, MEMS (Micro Electro Mechanical Systems) technology.

  In addition, the mobile terminal 1 includes a communication switching unit 110, an activation start control unit 111, a first determination unit 112, a second determination unit 113, a wireless link connection unit 114, and a model data storage unit 115. Have. These functional components are realized by executing a program that causes a computer mounted on the mobile terminal 1 to function. Further, this program may be a “WiFi connection tool” application that can be installed on a smartphone.

  First, it is assumed that the user interface 103 is activated by a user operation. This is the time when the mobile terminal returns from the sleep state by a user operation. At this time, the backlight of the display is turned on. In the data offload according to the present invention, the data offload determination process is started when the user interface 103 is activated.

[Start-up control unit 111]
(S311) When the user interface 103 is activated, the activation start control unit 111 activates the second wireless communication unit 102 of the wireless LAN interface.
(S321) The activation start control unit 111 also activates the acceleration sensor 104 at the same time.

[First determination unit 112]
(S312) The first determination unit 112 detects the access point of the desired connection destination by the peripheral scan of the second wireless communication unit 102. The identifiers of the desired connection destination access points are stored in advance in the portable terminal 1 as a list. The identifier of the access point is specifically an SSID (Service Set IDentifier), and of course may be a BSSID (Basic SSID). For example, it is also preferable that a telecommunications carrier of a mobile phone network sets an SSID including the same character string in all access points installed by itself. In this case, data communication in the company's mobile phone network can be offloaded to the company's wireless LAN.

  It is also preferable that an access point whose reception sensitivity of RSSI (Received Signal Strength Indication, Received Signal Strength Indicator) is not more than a predetermined threshold is not detected.

(S313) The first determination unit 112 determines whether or not the access point identifier detected by the second wireless communication unit 102 matches the access point identifier stored in advance. If the access point identifier does not match the desired connection destination, the process ends. According to S313 in FIG. 4, it generally takes about 3 to 5 seconds to detect an access point.

(S322) The first determination unit 112 collects data from the acceleration sensor 104 for a predetermined detection time.

(S323) The first determination unit 112 uses the model data storage unit 115 to determine whether or not the acceleration data collected from the acceleration sensor 104 is “non-moving state”. According to S323 in FIG. 4, the predetermined detection time requires about 5 seconds.

The model data storage unit 115 stores in advance model data in which a movement probability is associated with a model feature vector of a predetermined dimension (for example, 16 dimensions) calculated by FFT (Fast Fourier Transform) from acceleration data.
Model feature vector x <-> Movement probability p
x ₁ <-> p ₁
x ₂ <-> p ₂
・ ・ ・ <-> ・ ・ ・
x ₁₆ <-> p ₁₆

  FIG. 5 is an explanatory diagram showing determination of a non-moving state based on acceleration data in the present invention.

The first determination unit 112 determines whether or not it is in the “non-moving state” in the following steps.
(Step 1) A current vector of a predetermined dimension is calculated by performing FFT on the acceleration data output from the acceleration sensor for each unit time with a predetermined time window width. For example, it can be realized by the following numerical example.
Sampling rate of acceleration data output from the acceleration sensor: 16Hz
FFT predetermined time window width: 2 seconds FFT execution time interval: 1 second Thus, a 16-dimensional current vector is calculated.

(Step 2) A model feature vector having the closest distance to the current vector is searched.
The current vector and the plurality of model feature vectors are also 16-dimensional vectors, and the distance between both vectors can be calculated. For each FFT execution time (every second), the model feature vector closest to the current vector is searched (pattern matching).

(Step 3) The movement probability p (t) associated with the model feature vector at time t is calculated. The movement probability p (t) is derived every time FFT is executed.

(Step 4) A movement probability p (t) is acquired for a predetermined time (the latest Tact seconds), and a movement determination value P (t) = Πp (t) obtained by multiplying a plurality of movement probabilities p (t) is calculated. For example, assuming that Tact = 5 seconds, the movement determination value is integrated as follows.
P (t) = p (t-4) * p (t-3) * p (t-2) * p (t-1) * p (t)
t: Current time In the above example, it is necessary to calculate an integrated value for 5 seconds. However, for example, when p (t−2) = 0, the integration process can be terminated at that time. In this case, the process can be completed in only 3 seconds.

(Step 5) When the movement determination value P (t) is equal to or less than the predetermined threshold value Thact, it is determined that the movement is “non-moving”. For example, when the movement determination value P (t) measured for 5 seconds is 0.15 and the predetermined threshold Thact is 0.25, it is determined that the movement is not performed.

[Second determination unit 113]
(S33) When the second determination unit 113 determines that the first determination unit 112 is true, the second determination unit 113 waits for a predetermined time. According to S33 of FIG. 4, the process waits for about 5 seconds.

(S341) The second determination unit 113 detects the access point of the desired connection destination again by the peripheral scan of the second wireless communication unit 102.
(S342) The second determination unit 113 determines whether or not the access point identifier detected by the second wireless communication unit 102 matches the same access point identifier as the desired connection destination detected in the previous S313. To do. If the access point identifier of the desired connection destination detected earlier does not match, the process ends.

(S <b> 352) The second determination unit 113 determines again whether or not it is in the “non-moving state” based on the data from the acceleration sensor 104. Here, the predetermined detection time of the second determination unit 113 is the same as the Tact seconds of the first determination unit 112. Compared to the first determination unit 112, the second determination unit 113 can detect the moving state early because the movement state determination continues to operate for 5 seconds in S33 of FIG. The latest movement state determination result at the timing when the wireless LAN scan is completed is used as the result of S352.

The determination of the non-moving state of the second determination unit 113 repeats the following steps every time a predetermined detection time (for example, 1 second) elapses.
(Step 1) The second determination unit 113 calculates a movement determination value P (t) = Πp (t) obtained by multiplying a plurality of past movement probabilities p (t).

(Step 2) When the movement determination value P (t) is equal to or smaller than the predetermined threshold value, the second determination unit 113 determines that the movement determination value P (t) is “non-moving state” and stops the repetition process.

[Wireless link connection unit 114]
(S36) When the wireless link connection unit 114 determines that the second determination unit 113 is true, the wireless link connection unit 114 uses the second wireless communication unit 102 of the wireless LAN to establish a wireless link for the desired connection destination access point. Start the connection sequence. According to S36 of FIG. 4, it takes about 10 seconds to execute the wireless LAN connection sequence.

  According to FIG. 4, the non-moving state is determined in about 15 seconds in total of the first determination time (5 seconds) + standby time (5 seconds) + second determination time (5 seconds), and the wireless LAN Start the connection sequence. In addition, since the non-moving state is determined every second for the second determination time, the “non-moving state” may be determined in the first one second. Then, according to the present invention, the non-moving state can be determined and the wireless LAN connection sequence can be started in about 11 seconds (5 seconds + 5 seconds + 1 second) at the shortest.

[Model data storage unit 115]
The model data storage unit 115 stores in advance model data in which a movement determination value is associated with a model feature vector of a predetermined dimension calculated by FFT from acceleration data.

  FIG. 6 is an explanatory diagram showing generation of model data in the present invention.

According to FIG. 6, model data is created in the following steps.
(S61) Input acceleration data measured in a number of different movement states (for example, seven movement states of walking, running, bicycle, stop, car, bus, train). At this time, it is also preferable that a label indicating the moving state is given for each acceleration data. A model vector of a predetermined dimension (for example, 16 dimensions) is calculated from the acceleration data by performing FFT every unit time (for example, 1 second) with a predetermined time window width (for example, 2 seconds). By setting the predetermined time window width to 2 seconds, one 16-dimensional model vector is derived.

(S62) A predetermined number of clusters are classified by clustering a plurality of model vectors. The clustering method may be a k-means method of non-hierarchical clustering that classifies into k clusters. By clustering, a large number of model vectors are roughly classified into seven movement states such as walking, running, bicycle, stop, automobile, bus, and train.

(S63) A representative model feature vector is calculated for each cluster. As a representative model feature vector, a vector serving as the center of gravity of a plurality of model vectors in one cluster is calculated.

(S64) The model feature vector is associated with the movement probability p _i corresponding to the movement state of the cluster. A plurality of model vectors included in each cluster have individually corresponding movement states. The movement probability p _i is calculated from the breakdown of the movement state.
For example, when the cluster 1 includes vectors of 100 walks, 150 runs, 10 bicycles, 0 stops, 1 car, 2 buses and 3 trains, the movement probability p _i is calculated as follows. .
p ₁ = (100 + 150 + 10) / (100 + 150 + 10 + 0 + 1 + 2 + 3)
The numerator is always the sum of walking, running and cycling.

  As described above in detail, according to the wireless link connection method, the portable terminal, and the program of the present invention, the wireless network that detects the data offload destination is detected and the wireless link is connected while suppressing the power consumption as much as possible. can do.

  According to the present invention, the process of detecting the access point and determining the non-moving state is repeated a plurality of times in order to avoid connecting to a fixedly installed access point while the mobile terminal is moving. . In addition, according to the present invention, the wireless LAN wireless communication unit and the movement detection sensor are not activated until the user interface is activated by a user operation, which is effective from the viewpoint of power consumption.

  Various changes, modifications, and omissions of the above-described various embodiments of the present invention can be easily made by those skilled in the art. The above description is merely an example, and is not intended to be restrictive. The invention is limited only as defined in the following claims and the equivalents thereto.

DESCRIPTION OF SYMBOLS 1 Portable terminal 101 1st radio | wireless communication part 102 2nd radio | wireless communication part 103 User interface 104 Acceleration sensor 110 Communication switching part 111 Startup start control part 112 1st determination part 113 2nd determination part 114 Wireless link connection part 115 Model data storage unit 2 Wireless LAN access point 3 Wireless WAN base station

Claims (11)

In a wireless link connection method of a mobile terminal including a wireless communication unit that communicates with an access point, a movement detection sensor, and a display that is visually recognized by a user ,
A first step of activating both the wireless communication unit and the movement detection sensor when returning from a sleep state by a user operation and the backlight of the display is turned on ;
A second step of detecting an access point of a desired connection destination by a peripheral scan of the wireless communication unit and determining whether or not the mobile point is in a non-moving state based on data from the movement detection sensor;
When the second step is determined to be true, after the elapse of a predetermined waiting time, the access point of the desired connection destination detected first by the scan of the wireless communication unit is detected again, and the movement detection sensor A third step for determining whether or not the data is in a non-moving state;
A wireless link connection method comprising: a fourth step of connecting the wireless link to a desired connection destination access point when the wireless communication unit determines that the third step is true. The portable terminal stores an access point identifier of a desired connection destination in advance,
The second step and the third step are:
Determining whether the access point detected by the wireless communication unit matches the access point identifier stored in advance,
The radio link connection method according to claim 1 , wherein it is determined whether or not the mobile terminal is in a non-moving state based on data collected from the movement detection sensor during a predetermined detection time. The movement detection sensor is an acceleration sensor,
The mobile terminal stores in advance model data in which a movement probability p _i is associated with a model feature vector of a predetermined dimension calculated by FFT (Fast Fourier Transform) from acceleration data,
Regarding the determination of the non-moving state in the second step and the third step,
A current vector of a predetermined dimension is calculated by executing FFT on the acceleration data output from the acceleration sensor for each unit time with a predetermined time window width,
Search for a model feature vector that is closest to the current vector,
Obtaining a movement probability p _i associated with the model feature vector;
A movement probability value P (t) = Πp (t) obtained by acquiring a movement probability p (t) per unit time for a predetermined time and multiplying a plurality of movement probabilities p (t),
The radio link connection method according to claim 2 , wherein when the movement determination value P (t) is equal to or less than a predetermined threshold value, the movement determination value P (t) is determined to be in a non-moving state. The predetermined detection time of the third step is shorter than the predetermined detection time of the second step and is repeated a plurality of times.
The determination of the non-moving state in the third step is performed every time the predetermined detection time elapses.
A movement judgment value P (t) = Πp (t) obtained by multiplying a plurality of past movement probabilities p (t) is calculated,
4. The radio link connection method according to claim 3 , wherein when the movement determination value P (t) is equal to or less than a predetermined threshold value, it is determined that the movement is not performed and the repetition process is stopped. The model data is
From the acceleration data measured in advance in a number of different movement states, calculate a model vector of a predetermined dimension by performing FFT every unit time with a predetermined time window width,
Classifying multiple model vectors into a predetermined number of clusters by clustering,
For each cluster, calculate a representative model feature vector,
The radio link connection method according to claim 3 or 4 , wherein the model feature vector is created by associating a movement probability p _i corresponding to a movement state of the cluster with the model feature vector. In a mobile terminal including a wireless communication unit that communicates with an access point, a movement detection sensor, and a display that is visually recognized by a user ,
An activation start control means for activating both the wireless communication unit and the movement detection sensor when the backlight of the display is turned on by returning from a sleep state by a user operation ;
A first determination unit that detects an access point of a desired connection destination by a peripheral scan of the wireless communication unit, and determines whether or not the wireless communication unit is in a non-moving state based on data from the movement detection sensor;
When the first determination means is determined to be true, after the elapse of a predetermined waiting time, the access point of the desired connection destination previously detected by the scan of the wireless communication unit is detected again, and the movement detection sensor Second determination means for determining whether or not the vehicle is in a non-moving state based on the data of
A portable terminal comprising: a wireless link connection unit configured to connect a wireless link to an access point of a desired connection destination using the wireless communication unit when the second determination unit is determined to be true. The access point identifier of the desired connection destination is stored in advance,
The first determination means and the second determination means are:
Determining whether the access point detected by the wireless communication unit matches the access point identifier stored in advance,
The mobile terminal according to claim 6 , wherein it is determined whether or not the mobile terminal is in a non-moving state based on data collected from the movement detection sensor during a predetermined detection time. The movement detection sensor is an acceleration sensor,
Model data storage means for storing in advance model data in which a movement probability p _i is associated with a model feature vector of a predetermined dimension calculated by FFT from acceleration data;
Regarding the determination of the non-moving state in the first determination means and the second determination means,
A current vector of a predetermined dimension is calculated by executing FFT on the acceleration data output from the acceleration sensor for each unit time with a predetermined time window width,
Search for a model feature vector that is closest to the current vector,
Calculating a movement probability p _i associated with the model feature vector;
A movement probability value P (t) = Πp (t) obtained by acquiring a movement probability p (t) per unit time for a predetermined time and multiplying a plurality of movement probabilities p (t),
The mobile terminal according to claim 7 , wherein the mobile terminal is determined to be in a non-moving state when the movement determination value P (t) is equal to or less than a predetermined threshold value. The predetermined detection time of the second determination means is shorter than the predetermined detection time of the first determination means and is repeated a plurality of times.
The determination of the non-moving state of the second determination means is performed every time the predetermined detection time elapses.
A movement judgment value P (t) = Πp (t) obtained by multiplying a plurality of past movement probabilities p (t) is calculated,
The mobile terminal according to claim 8 , wherein when the movement determination value P (t) is equal to or less than a predetermined threshold value, it is determined that the movement is not performed and the repetition process is stopped. The model data is
From the acceleration data measured in advance in a number of different movement states, calculate a model vector of a predetermined dimension by performing FFT every unit time with a predetermined time window width,
Classifying a given number of clusters by clustering multiple model vectors,
For each cluster, calculate a representative model feature vector,
The mobile terminal according to claim 8 or 9 , wherein the mobile terminal is created by associating the model feature vector with a movement probability p _i corresponding to a movement state of the cluster. In a program for causing a computer mounted on a portable terminal having a wireless communication unit that communicates with an access point, a movement detection sensor, and a display visually recognized by a user to function,
An activation start control means for activating both the wireless communication unit and the movement detection sensor when the backlight of the display is turned on by returning from a sleep state by a user operation ;
A first determination unit that detects an access point of a desired connection destination by a peripheral scan of the wireless communication unit, and determines whether or not the wireless communication unit is in a non-moving state based on data from the movement detection sensor;
When the first determination means is determined to be true, after the elapse of a predetermined waiting time, the access point of the desired connection destination previously detected by the scan of the wireless communication unit is detected again, and the movement detection sensor Second determination means for determining whether or not the vehicle is in a non-moving state based on the data of
When the second determination means is determined to be true, the wireless communication unit is used to cause the computer to function as a wireless link connection means for connecting a wireless link to a desired connection destination access point. A program for terminals.

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