JP2015186110A - System and method for radio wave information collection, and measurement control method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To accurately grasp the state of radio field intensity at another access point, while suppressing an increase of power consumption at a terminal.SOLUTION: Based on radio field intensity information, an access point 2 generates instruction information which instructs the measurement of radio field intensity, according to the detection of an influence change upon access point 2 by another access point 5, to transmit the generated instruction information to a terminal 1. The terminal 1, on receiving the instruction information from the access point 2, measures radio field intensity on basis of the instruction information.

Description

  The present invention relates to a radio wave information collection system, a radio wave information collection device, and a measurement control method.

  With the widespread use of wireless LANs, the number of homes with a wireless LAN environment is increasing. The wireless LAN environment is maintained by installing one or a plurality of access points in the home, and enables access to the Internet or the like at any location in the home by performing wireless communication with the access points.

  By the way, when a wireless LAN environment is established in a neighboring house, radio waves transmitted from an access point installed in the user's home interfere with radio waves transmitted from other access points installed in the neighboring house. There are things to do.

  On the other hand, a technique for making interference with other access points less likely to occur in wireless communication channel setting has been proposed. For example, in Patent Document 1, information indicating an interference state is stored based on a result of performing a channel scan (measurement of radio wave intensity) for each channel, and the information indicating the interference state indicating that the interference is minimum is used. An access point has been proposed in which an associated channel is set as a channel used for wireless communication.

JP 2013-201629 A

  By the way, the interference situation with other access points can change as time passes. For example, the location and channel of an access point installed in a neighboring house may change due to a change in the layout of the house in the neighboring house or a change of residents due to moving or the like.

  In this regard, the access point described in Patent Document 1 merely selects a channel on which interference is unlikely to occur based on information indicating interference information stored when radio field intensity is measured for each channel. For this reason, there is a problem in that sufficient communication quality cannot be obtained due to interference with radio waves emitted from other access points in accordance with changes in the installation position and channel of other access points. For such a problem, for example, it is conceivable to increase the frequency of measuring the radio field intensity at the terminal. However, simply increasing the measurement frequency at the terminal causes a problem that the power consumption at the terminal increases.

  Accordingly, the present invention has been made to solve these problems, and radio wave information that can accurately grasp the radio wave intensity status of other access points while suppressing an increase in power consumption in the terminal. It is an object to provide a collection system, a radio wave information collection device, and a measurement control method.

  A radio wave information collection system according to a first aspect of the present invention is a radio wave information collection system including a radio wave information collection device and a mobile terminal, wherein the mobile terminal is configured to transmit the mobile terminal in a communicable area of a predetermined access point. A measurement unit that measures the radio field strength of another access point different from the predetermined access point and the channel used by the other access point, the radio field strength of the other access point, and the other access point used A terminal transmission unit that transmits radio wave intensity information including a channel to the radio wave information collection device, the radio wave information collection device receiving a radio wave intensity information from the portable terminal, and the device reception A device storage unit that stores the radio field intensity information received by the unit, and the other access point is based on the radio field intensity information. A change detection unit for detecting a change in influence on a predetermined access point, an instruction information generation unit for generating instruction information for instructing measurement of radio wave intensity in response to detection of the change by the change detection unit, and generation A device transmission unit that transmits the instruction information to the portable terminal, and the measurement unit, when receiving the instruction information from the radio wave information collection device, measures a radio wave intensity based on the instruction information.

In addition, there are a plurality of the mobile terminals, and when the change detection unit detects the change, the instruction information generation unit further generates the instruction information for another mobile terminal different from the mobile terminal that transmitted the radio wave intensity. Then, the device transmission unit may transmit the instruction information to the other portable terminal.
In addition, the instruction information generation unit may generate the instruction information including regulation information that defines a measurement frequency of radio wave intensity in the portable terminal. The change detection unit may detect the change based on a change in the channel of the other access point included in the radio wave intensity information.

  Further, the measurement unit acquires identification information of the other access point, and the terminal transmission unit transmits the radio wave intensity information further including the identification information of the other access point to the radio wave information collection device, The change detection unit may detect the change based on a channel change of another access point corresponding to the identification information included in the radio wave intensity information.

  Further, the measurement unit acquires identification information of the other access point, and the terminal transmission unit transmits the radio wave intensity information further including the identification information of the other access point to the radio wave information collection device, The change detection unit may detect the change based on a change in the identification information included in the radio wave intensity information.

  Further, the measurement unit acquires identification information of the other access point, and the terminal transmission unit transmits the radio wave intensity information further including the identification information of the other access point to the radio wave information collection device, The change detection unit may detect the change when the identification information included in the radio wave intensity information is different from the already acquired identification information.

  The portable terminal further includes a position information acquisition unit that acquires position information indicating a position of the portable terminal when the radio field intensity is measured, and the terminal transmission unit further includes the position information of the portable terminal. Including the radio wave intensity information including the radio wave information collecting device, and the change detecting unit receives the radio wave intensity information at the position indicated by the position information included in the radio wave intensity information. The change may be detected based on a change amount between the radio field intensity of the other access point included in the radio field intensity information and the radio field intensity of the other access point included in the device storage unit.

  When the radio wave intensity is measured within a predetermined time at the position indicated by the position information acquired by the position information acquisition unit, the measurement unit may not newly measure the radio wave intensity at the position. The terminal transmission unit includes identification information for identifying the mobile terminal in the radio wave intensity information, and transmits the radio wave information collection device, and the device transmission unit is a mobile terminal that has transmitted the radio wave intensity information. The radio field intensity information is transmitted to another different mobile terminal, and the measurement unit measures the radio field intensity within a predetermined time by another mobile terminal at the position indicated by the position information acquired by the position information acquisition unit. If it is, the radio wave intensity need not be newly measured at the position.

  The radio wave information collection device according to the second aspect of the present invention includes a radio wave intensity of another access point that is different from the predetermined access point, measured by a mobile terminal in a communicable area of the predetermined access point, and the other A receiving unit that receives from the mobile terminal radio field intensity information including a channel used by the access point and the location information of the mobile terminal, and a device storage unit that stores the radio field intensity information received by the receiving unit; Based on the radio wave intensity information, a change detection unit that detects a change in influence of the other access point on the predetermined access point, and a measurement of the radio wave intensity in response to the change detection unit detecting the change An instruction information generation unit that generates instruction information for instructing the device, and a device transmission unit that transmits the generated instruction information to the portable terminal.

  In the measurement control method according to the third aspect of the present invention, in a communicable area of a predetermined access point, the radio wave intensity of another access point different from the predetermined access point measured by the mobile terminal, Receiving the radio wave intensity information including the channel used by the access point and the location information of the mobile terminal from the mobile terminal, storing the received radio wave intensity information in a storage unit; and A step of detecting a change in the influence of the other access point on the predetermined access point, and a step of generating instruction information instructing measurement of radio wave intensity in response to detecting the change; Transmitting the generated instruction information to the portable terminal.

  According to the present invention, it is possible to accurately grasp the state of the radio field intensity of other access points while suppressing an increase in power consumption in the terminal.

It is a figure which shows the external environment of the electromagnetic wave information collection system which concerns on 1st Embodiment, and the said electromagnetic wave information collection system. It is a figure which shows the example of a relationship between the communicable area of the access point which concerns on 1st Embodiment, and the communicable area of several other access points. It is a function block diagram of the terminal which concerns on 1st Embodiment. It is a function block diagram of the access point which concerns on 1st Embodiment. It is a figure which shows an example of the electromagnetic wave intensity information memorize | stored in an apparatus memory | storage part. It is a figure which shows the influence degree of the radio wave interference by the frequency interval of a channel. It is a figure which shows an example of the field intensity of each other access point of a some channel, and an interference degree. It is a sequence diagram which concerns on the process which measures electromagnetic wave intensity in the terminal which concerns on 1st Embodiment. It is a function block diagram of the terminal which concerns on 2nd Embodiment. It is a sequence diagram which concerns on the process which measures electromagnetic wave intensity in the terminal which concerns on 2nd Embodiment. It is a sequence diagram which concerns on the process which measures electromagnetic wave intensity in the some terminal which concerns on 3rd Embodiment.

Hereinafter, embodiments of the present invention will be described.
<First Embodiment>
[Configuration of radio wave information collection system S]
FIG. 1 is a diagram illustrating a radio wave information collection system S and an external environment of the radio wave information collection system S according to the first embodiment. The radio wave information collecting system S is connected to a plurality of external servers 3 via a network N such as the Internet. The radio wave information collection system S includes a terminal 1 and a predetermined access point 2 that functions as a radio wave information collection device.

  The terminal 1 is a mobile terminal such as a mobile phone such as a smartphone, a tablet, and a game machine used by a resident of a predetermined house. The terminal 1 may be a fixed terminal such as a desktop personal computer.

  The predetermined access point 2 is installed in a predetermined house and communicates with the terminal 1 by radio. The predetermined access point 2 receives, for example, a broadcast signal such as cable television broadcast, converts it into a signal such as video and audio, and outputs it, or acquires content provided by the external server 3 on the Internet to obtain the terminal 1 It is a set-top box that can be transmitted wirelessly. The predetermined access point 2 may be a wireless LAN access point that does not have the above-described function. Hereinafter, the predetermined access point 2 is simply referred to as the access point 2.

  The plurality of other access points 5 are installed in a neighborhood of the predetermined residence where the access point 2 is installed, and communicate wirelessly with a user terminal (not shown) of the neighborhood home. . Hereinafter, the access point is also expressed as AP in the figure.

  FIG. 2 is a diagram illustrating a relationship example between a communicable area indicating an area where the access point 2 according to the first embodiment can communicate wirelessly and a communicable area of a plurality of other access points 5.

  As shown in FIG. 2, in the user home 100, the access point 2 is installed in the living room, and the wireless LAN environment is maintained. On the other hand, other access points 5-1, 5-2, and 5-3 are installed in neighboring homes 101-1, 101-2, and 101-3 near the user home 100.

  A plurality of ellipses indicated by broken lines in FIG. 2 indicate points where the radio wave intensity of each of the access points is equal, and the area inside the ellipse is an area that can be communicated via the access point. It is shown that. Here, the radio wave intensity refers to a received signal intensity (RSSI) of a radio wave transmitted from each access point.

  For example, in FIG. 2, three ellipses centered on the access point 2 are displayed. Of these three ellipses, the innermost ellipse indicates the point of the first radio wave intensity, and the inner ellipse indicates the second radio wave intensity point that is weaker than the first radio wave intensity. The outermost ellipse indicates a point of the third radio wave intensity that is weaker than the second radio wave intensity. Here, it is assumed that the terminal 1 can wirelessly communicate with the access point 2 in an area inside the outermost ellipse.

  In addition, radio waves transmitted from other access points 5-1, 5-2 and 5-3 reach the user home 100 and interfere with the wireless LAN environment of the user home 100. At this time, the degree of interference differs between the living room, the bedroom, and the child room of the user home 100. That is, in the living room, the other access point 5-1 of the neighboring house 101-1 interferes strongly, in the bedroom, the other access point 5-2 of the neighboring house 101-2 strongly interferes, and in the child room, the neighboring house 101-3. The other access point 5-3 interferes strongly.

  In this regard, in the radio wave information collecting system S, the channel of the access point 2 is set to a channel that can stably use the wireless LAN environment wherever the user home 100 is based on the radio wave intensity of the other access point 5. . However, the state of interference with other access points 5 can change over time. For example, the layout of the home in a nearby house is changed, or the resident is replaced due to moving, etc., so that the installation position of other access points 5 installed in the nearby house changes, or the channel changes. Or

  On the other hand, in the radio wave information collecting system S, the frequency of measurement of the radio wave intensity at the terminal 1 is increased in response to detecting the change in the radio wave intensity at the other access point 5, thereby reducing the power consumption at the terminal 1. While suppressing the increase, the state of the radio field intensity of the other access point 5 is accurately grasped. Hereinafter, functional configurations of the terminal 1 and the access point 2 constituting the radio wave information collection system S will be described.

[Configuration example of terminal 1]
FIG. 3 is a functional configuration diagram of the terminal 1 according to the first embodiment.
The terminal 1 includes an input unit 11, a display unit 12, a wireless unit 13, a storage unit 14, and a control unit 15.

  The input unit 11 includes, for example, a button, a contact sensor arranged so as to overlap the display unit 12, and receives an operation input from the user of the terminal 1. When the terminal 1 is a desktop or notebook personal computer or the like, the input unit 11 may be configured with a mouse or a keyboard.

  The display unit 12 includes, for example, a liquid crystal display or an organic EL (Electro-Luminescence) display. The display unit 12 displays characters, graphics, and the like under the control of the control unit 15.

  The wireless unit 13 modulates the signal output from the control unit 15 to generate an RF (Radio Frequency) signal, and wirelessly transmits the RF signal to the access point 2 via an antenna (not shown). The radio unit 13 demodulates the RF signal received from the access point 2 via the antenna, and outputs a signal obtained by the demodulation to the control unit 15. Here, the wireless unit 13 is connected to the access point 2 by any one of the 13 channels defined in the 2.4 GHz band used in IEEE 802.11b, IEEE 802.11g, and IEEE 802.11n, for example. Communicate. Note that the wireless unit 13 may perform communication at a frequency of 5 GHz band used in IEEE 802.11a and IEEE 802.11n.

  The storage unit 14 is configured by, for example, a ROM and a RAM. The storage unit 14 stores various programs for causing the terminal 1 to function. For example, the storage unit 14 stores a content acquisition program for causing the control unit 15 of the terminal 1 to function as a measurement unit 151, a terminal transmission unit 152, and a content acquisition unit 153 described later. The storage unit 14 may read and store a program stored in a storage medium such as an external memory, or may store a program downloaded from an external device via the network N.

  The control part 15 is comprised by CPU, for example. The control unit 15 comprehensively controls functions related to the terminal 1 by executing various programs stored in the storage unit 14. The control unit 15 includes a measurement unit 151, a terminal transmission unit 152, and a content acquisition unit 153.

  The measuring unit 151 measures the radio field intensity of the access point 2, the radio field intensity of another access point 5 different from the access point 2, and the channel used by the other access point 5 in the communicable area of the access point 2. To do. The measurement unit 151 acquires the MAC address and ESSID that are identification information of the other access points 5 at the time of measurement.

  For example, the measurement unit 151 starts measuring the radio field intensity in response to the execution of the content acquisition program. Further, when receiving the instruction information for instructing the measurement of the radio wave intensity from the access point 2, the measurement unit 151 measures the radio wave intensity based on the instruction information. Here, the instruction information includes regulation information that defines the measurement frequency of the radio wave intensity at the terminal 1, and the measurement unit 151 measures the radio wave intensity at the measurement frequency that is defined in the regulation information.

  Here, it is assumed that the measurement unit 151 performs measurement periodically (for example, once a week) when the content acquisition program is executed. The measurement unit 151 may perform measurement in the background when the content acquisition unit 153 acquires content from the external server 3, that is, when the user of the terminal 1 is browsing the content. Good.

  The terminal transmission unit 152 includes information indicating the radio field intensity of the access point 2, information indicating the radio field intensity of the other access point 5, information indicating the channel used by the other access point 5, the MAC address of the other access point 5, Radio wave intensity information including the ESSID and the measured date and time is transmitted to the access point 2.

  The content acquisition unit 153 acquires content from the external server 3 via the access point 2 in response to the content acquisition operation performed by the input unit 11. When the acquired content is text information, image information, or video information, the content acquisition unit 153 displays the content on the display unit 12. When the acquired content includes audio information, the content acquisition unit 153 may output audio based on the audio information from a speaker (not shown) included in the terminal 1.

[Configuration example of access point 2]
Next, the functional configuration of the access point 2 will be described. FIG. 4 is a functional configuration diagram of the access point 2 according to the first embodiment. The access point 2 includes a wireless unit 21, a communication unit 22, a device storage unit 23, and a control unit 24.

The radio unit 21 modulates the signal output from the control unit 24 to generate an RF signal, and wirelessly transmits the RF signal to the terminal 1 via an antenna (not shown). The radio unit 21 demodulates the RF signal received from the terminal 1 via the antenna and outputs a signal obtained by the demodulation to the control unit 24. Here, it is assumed that the wireless unit 21 performs wireless communication with the terminal 1 through any one of 13 channels defined in the 2.4 GHz band. The wireless unit 21 may perform wireless communication at a frequency of 5 GHz band.
The communication unit 22 communicates with an external device by wire. Specifically, the communication unit 22 communicates with the external server 3 via the network N.

  The device storage unit 23 includes, for example, a ROM and a RAM. The device storage unit 23 stores various programs for causing the access point 2 to function. The device storage unit 23 may store a program downloaded from an external device via the network N.

  The control unit 24 is configured by a CPU, for example. The control unit 24 comprehensively controls functions related to the access point 2 by executing various programs stored in the device storage unit 23. The control unit 24 includes a device reception unit 241, a storage control unit 242, a change detection unit 243, an instruction information generation unit 244, a device transmission unit 245, a channel selection unit 246, a channel setting unit 247, and a content transmission. Part 248.

  The device receiving unit 241 includes the radio wave intensity of the access point 2, the radio wave intensity of the other access point 5, the channel used by the other access point 5, and the like measured by the terminal 1 in the communicable area of the access point 2. Radio wave intensity information including the MAC address and ESSID of the access point 5 and the measured date and time are received from the terminal 1.

  When the device receiving unit 241 receives the radio wave intensity information from the terminal 1, the storage control unit 242 receives the radio field intensity information from the No that identifies the acquired date and location and the radio wave intensity of the access point 2, and A value when the radio field intensity is subtracted is added and stored in the device storage unit 23. FIG. 5 is a diagram illustrating an example of the radio wave intensity information stored in the device storage unit 23. As shown in FIG. 5, the radio field intensity information includes No, date, time, radio field intensity (RSSI_0) of the access point 2, the MAC address of the other access point 5, the ESSID of the other access point 5, and the other access point. 5, the channel strength of other access point 5 (RSSI of other AP), the value obtained by subtracting the radio field strength of other access point 5 from the radio field strength of access point 2 (RSSI_0−other AP RSSI). Thereby, the device storage unit 23 stores the radio wave intensity information received by the device reception unit 241.

  When the radio field intensity information is newly stored in the device storage unit 23, the change detection unit 243 detects a change in the influence of the other access point 5 on the access point 2 based on the radio field intensity information. Note that the change detection unit 243 may periodically detect the change in the effect by referring to the radio wave intensity information stored in the device storage unit 23.

  Specifically, the change detection unit 243 changes the influence based on the change of the channel of the other access point 5 corresponding to the ESSID or the MAC address that is the identification information of the other access point 5 included in the radio wave intensity information. Detect that

  For example, the change detection unit 243 extracts channels of other access points 5 within a predetermined period for each identical ESSID from the radio wave intensity information stored in the device storage unit 23. Then, when a plurality of channels associated with the same ESSID do not match, the change detection unit 243 changes the channel of the other access point 5 of the ESSID, and the other access point 5 changes to the access point 2. It is determined that the effect on the change has occurred.

  If the channel of another access point 5 changes, there is a possibility that the access point 2 interferes with the channel currently used. The access point 2 can detect the change in the influence of the other access point 5 on the access point 2 with high accuracy by detecting the channel change of the other access point 5.

  Further, the change detection unit 243 extracts ESSIDs of other access points 5 within a predetermined period for each identical MAC address from the radio wave intensity information stored in the device storage unit 23. Then, the change detection unit 243 determines that the influence of the other access point 5 on the access point 2 has changed when the ESSID associated with the same MAC address changes. For example, when the ESSID of another access point 5 changes, it is highly likely that the influence on the access point 2 will change because the user of the other access point 5 changes the setting of the access point. It is done. Therefore, the access point 2 can accurately detect the change in the influence of the other access point 5 on the access point 2 by detecting the change in the ESSID of the other access point 5. Note that the change detection unit 243 may further determine whether the channel or radio wave intensity of the other access point 5 has changed in response to detecting a change in the ESSID of the other access point 5. . Then, the change detection unit 243 may change the influence of the other access point 5 on the access point 2 in response to determining that the channel or the radio wave intensity has changed.

  The change detection unit 243 detects a change in influence based on the change in ESSID included in the radio wave intensity information. Specifically, the change detection unit 243 detects that the influence has changed when the ESSID included in the radio wave intensity information newly stored in the device storage unit 23 is different from the already acquired ESSID.

  For example, the change detection unit 243 refers to the radio wave intensity information measured within a predetermined period, stored in the device storage unit 23, identifies the ESSID of the other access point 5 detected within the predetermined period, Pre-stored in the device storage unit 23. The change detection unit 243 includes a new ESSID that does not match the previously identified ESSID among the ESSIDs of other access points 5 included in the radio wave intensity information newly stored in the device storage unit 23. It is determined whether or not. If the change detection unit 243 determines that a new ESSID exists, the change detection unit 243 determines that another access point 5 is newly installed and the influence on the access point 2 has changed.

  Changing the ESSID or detecting a new ESSID means that another access point 5 has been changed or newly installed. When the installation status of other access points 5 changes in this way, there is a risk that the access point 2 interferes with the channel currently used. Therefore, the access point 2 can accurately detect the change in the influence of the other access points 5 on the access point 2 by detecting the change in the ESSID.

The instruction information generation unit 244 generates instruction information for instructing the measurement of the radio wave intensity in response to the change detection unit 243 detecting the change. Specifically, the instruction information generation unit 244 generates instruction information including regulation information that defines the measurement frequency of the radio wave intensity at the terminal 1. Here, the measurement frequency of the radio field intensity defined by the regulation information is larger than the frequency (for example, once a week) when the measurement unit 151 performs measurement when the content acquisition program is executed (for example, Once every 6 hours).
The device transmission unit 245 transmits the generated instruction information to the terminal 1.

  In this way, in the terminal 1, when the change detection unit 243 detects a change in influence, the radio wave intensity is measured more frequently than in the case where the change detection unit 243 does not detect a change in influence. It is possible to accurately grasp the situation of the radio field intensity of the access point 5.

  The channel selection unit 246 calculates, for each of the plurality of channels, the degree of interference with the radio wave emitted by the access point 2 based on the radio field intensity of the other access point 5, and based on the interference level of each of the plurality of channels Select the channel used by Point 2.

  Specifically, the channel selection unit 246 refers to the radio wave intensity information measured after the change detection unit 243 detects the change in influence, and the access point out of the radio wave intensity of each of the plurality of other access points 5. 2. Select a radio wave intensity that has a relatively strong influence on 2. Here, for each of the other access points 5, the channel selection unit 246 selects the highest radio field strength among the radio field strengths of the other access points 5 acquired by the device reception unit 241. Note that the channel selection unit 246 may select, for each of the other access points 5, the radio field intensity that minimizes the value obtained by subtracting the radio field intensity of the other access point 5 from the radio field intensity of the access point 2.

  Subsequently, the channel selection unit 246 stores a plurality of information on the basis of the influence level of the radio wave interference caused by the frequency interval of the channel and the radio wave intensity selected for each of the other access points 5 stored in advance in the device storage unit 23. The radio field intensity of each of the other access points 5 corresponding to each channel is estimated. FIG. 6 is a diagram showing the influence ω (Δchi) of radio wave interference due to the frequency interval (Δchi) of the channel. Here, “i” of Δchi is a value indicating an interval apart.

  FIG. 6 shows the influence of radio wave interference due to the channel frequency interval in the 2.4 GHz band and the influence degree of radio wave interference due to the channel frequency interval in the 5 GHz band. As shown in FIG. 6, the influence degree of radio wave interference varies depending on the frequency band of wireless communication. For example, in the 2.4 GHz band, when the channel is separated by 1, the influence ω (Δch1) of radio wave interference becomes −2 dBm, and when the channel is separated by 2, the influence ω (Δch2) of radio wave interference becomes −5 dBm. . In the 5 GHz band, when the channel is separated by 1, the influence ω (Δch1) of radio wave interference becomes −100 dBm.

  For example, among the radio wave intensities of the other access points 5 shown in FIG. 5, for “OtherAP1”, the highest radio wave intensity is “−40”, and the channel corresponding to “OtherAP1” is “6”. The channel selection unit 246 sets the radio wave intensity corresponding to the channel “6” to “−40”.

  Subsequently, the channel selection unit 246 affects the radio wave intensity of the channels “5” and “7” whose frequency interval is one distance from the channel “6” to the radio wave intensity “−40” corresponding to the channel “6”. It is estimated as “−42” obtained by adding “−2”. Similarly, the channel selection unit 246 adds “−45” to the radio wave intensity corresponding to the channels “4” and “8”, and the radio wave intensity “−40” corresponding to the channel “6”. ”, The radio field intensity corresponding to the channels“ 3 ”and“ 9 ”is estimated as“ −50 ”, the radio field intensity corresponding to the channels“ 2 ”and“ 10 ”is estimated as“ −68 ”, and the channel The radio field intensity corresponding to “1”, “11”, “12”, and “13” is estimated as “−140”.

Subsequently, the channel selection unit 246 calculates the degree of interference with the radio wave emitted by the access point 2 based on the estimated radio wave intensity of each of the other access points 5 for each of the plurality of channels. Specifically, the channel selection unit 246 calculates a value (CIR-RSSI_0) obtained by subtracting the radio wave intensity (RSSI_0) of the access point 2 from the power ratio (CIR) of the carrier-to-interference wave as the interference degree. This degree of interference is obtained by the following equation. Here, N is the number of other access points 5.

  Here, when the value (CIR-RSSI_0) calculated by the equation (1) is large, the degree of interference of the other access point 5 with respect to the access point 2 is small, and when the value calculated by the equation (1) is small, the access is performed. The degree of interference of the other access point 5 with respect to the point 2 is large.

  The channel selection unit 246 selects the channel of the access point 2 based on the calculated interference levels of the plurality of channels. Specifically, the channel selection unit 246 selects the channel with the smallest interference degree of the other access point 5 with respect to the access point 2, that is, the channel with the highest value (CIR-RSSI_0) indicating the interference degree among a plurality of channels. select.

  FIG. 7 is a diagram illustrating an example of the radio wave intensity and the degree of interference of each other access point of a plurality of channels. In the example shown in FIG. 7, since the value indicating the degree of interference corresponding to channel 1 is the largest, the channel selection unit 246 selects channel 1 as the channel with the smallest degree of interference of the other access point 5 with respect to the access point 2. To do.

  In response to channel selection unit 246 selecting a channel, channel setting unit 247 sets the channel used by radio unit 21 to the channel selected by channel selection unit 246. The channel setting unit 247 may set a channel when the content transmission unit 248 is not transmitting content.

  The content transmission unit 248 acquires content from the external server 3 via the communication unit 22 in response to content acquisition operation performed by the input unit 11 of the terminal 1. The content transmission unit 248 transmits the content acquired from the external server 3 to the terminal 1 via the wireless unit 21.

[Sequence for measuring radio field intensity]
Next, a sequence related to processing for measuring radio wave intensity in the terminal 1 will be described. FIG. 8 is a sequence diagram relating to processing for measuring radio wave intensity in the terminal 1 according to the first embodiment. Here, it is assumed that the device storage unit 23 stores radio wave intensity information.

  First, the measurement unit 151 of the terminal 1 measures the radio field intensity, for example, in response to the execution of the content acquisition program (S10). Subsequently, the terminal transmitter 152 transmits information indicating the radio field intensity of the access point 2, information indicating the radio field intensity of the other access point 5, information indicating the channel used by the other access point 5, Radio wave intensity information including the MAC address and ESSID and the measured date and time is transmitted to the access point 2.

  Subsequently, when the device receiving unit 241 receives the radio field strength information, the storage control unit 242 determines that the other radio wave intensity information includes the No that identifies the acquired date and location and the radio field strength of the access point 2 and the other access points 5. A value obtained by subtracting the radio wave intensity is added and stored in the device storage unit 23 (S20).

Subsequently, when the radio wave intensity information is newly stored in the device storage unit 23, the change detection unit 243 determines whether or not the influence of other access points 5 on the access point 2 has changed based on the radio wave intensity information. Is determined (S30).
When the change detection unit 243 determines that the influence has changed, the instruction information generation unit 244 generates instruction information for instructing measurement of the radio wave intensity (S40). Thereafter, the device transmission unit 245 transmits the generated instruction information to the terminal 1.

  Subsequently, when receiving the instruction information for instructing the measurement of the radio field intensity from the access point 2, the measurement unit 151 measures the radio field intensity based on the instruction information (S50). Subsequently, the terminal transmission unit 152 transmits radio wave intensity information including information indicating the measured radio wave intensity to the access point 2.

[Effect in the first embodiment]
As described above, the access point 2 of the radio wave information collection system S according to the first embodiment responds to the detection of the change in the influence of the other access point 5 on the access point 2 based on the radio wave intensity information. Then, the instruction information for instructing the measurement of the radio wave intensity is generated, and the generated instruction information is transmitted to the terminal 1. When the terminal 1 receives the instruction information from the access point 2, the terminal 1 measures the radio wave intensity based on the instruction information.

  In this way, in the terminal 1, when the access point 2 detects the change in influence, the radio wave intensity is measured more frequently than in the case where the change in influence is not detected. It is possible to accurately grasp the strength situation. In addition, since the terminal 1 measures the radio wave intensity at a high frequency only when the access point 2 detects a change in influence, the latest radio wave intensity situation is suppressed while suppressing an increase in power consumption in the terminal 1. Can be grasped.

  In addition, since the access point 2 generates instruction information including regulation information that defines the measurement frequency of the radio wave intensity at the terminal 1, the frequency measured after detecting the change in the influence of the other access points 5 on the access point 2 Can be freely defined.

<Second Embodiment>
[Detect change in influence based on location information of terminal 1]
Next, the second embodiment will be described. In the first embodiment, a change in influence of another access point 5 on the access point 2 is detected based on a change in channel and a change in ESSID. On the other hand, in the second embodiment, the terminal 1 notifies the access point 2 of its own location information, and the access point 2 changes the radio field intensity of other access points 5 at the same location based on the location information. Is different from the first embodiment in that the change in the influence of the other access point 5 on the access point 2 is detected. Further, the second embodiment differs from the first embodiment in that when the terminal 1 measures the radio wave intensity within a predetermined time at a predetermined position, the radio wave intensity is not newly measured at the position.

FIG. 9 is a functional configuration diagram of the terminal 1 according to the second embodiment.
The control unit 15 of the terminal 1 further includes a position information acquisition unit 154. The position information acquisition unit 154 acquires position information indicating the position of the terminal 1 in response to the measurement unit 151 measuring the radio wave intensity. Thereby, the position information acquisition unit 154 acquires position information indicating the position of the terminal 1 when the measurement unit 151 measures the radio wave intensity.
When the position information acquisition unit 154 acquires the position information of the terminal 1 when the radio field intensity is measured, the terminal transmission unit 152 transmits the radio field intensity information further including the position information to the access point 2.

  When the device reception unit 241 receives the radio wave intensity information, the change detection unit 243 specifies the radio wave intensity of the other access point 5 included in the radio wave intensity information at the position indicated by the position information included in the radio wave intensity information. . Subsequently, the change detection unit 243 refers to the radio wave intensity information stored in the device storage unit 23 and identifies the radio wave intensity of the other access point 5 corresponding to the position. Subsequently, the change detection unit 243 detects a change in influence based on the amount of change between the radio wave intensity specified from the received radio wave intensity information and the radio wave intensity specified from the radio wave intensity information stored in the device storage unit 23. To do.

  Here, when the radio field intensity of a plurality of other access points 5 is measured, the change detection unit 243 detects the amount of change in each radio field intensity. Then, the change detection unit 243 detects that the influence of the other access point 5 on the access point 2 has changed when at least one of the plurality of change amounts exceeds the predetermined amount.

  After that, the instruction information generation unit 244 generates instruction information for instructing the measurement of the radio wave intensity in response to the change detection unit 243 detecting the change, and the device transmission unit 245 transmits the generated instruction information to the terminal 1. Send to.

  When receiving the instruction information for instructing the measurement of the radio field intensity from the access point 2, the measurement unit 151 measures the radio field intensity based on the instruction information. Here, the measurement unit 151 associates the measured time with the measured position information and stores it in the storage unit 14 as measurement history information, and whether to newly measure the radio field intensity based on the measurement history information. Control whether or not. Specifically, the measurement unit 151 stops the measurement when the radio wave intensity is measured within a predetermined time at the position indicated by the position information acquired by the position information acquisition unit 154 when starting the measurement. Thereby, the measurement part 151 can suppress the increase in power consumption, without newly measuring radio wave intensity in the said position.

[Sequence for measuring radio field intensity]
Next, a sequence related to processing for measuring radio wave intensity in the terminal 1 will be described. FIG. 10 is a sequence diagram relating to processing for measuring radio wave intensity in the terminal 1 according to the second embodiment. Here, it is assumed that the device storage unit 23 stores radio wave intensity information.

  First, the measurement unit 151 of the terminal 1 measures the radio field intensity, for example, in response to the execution of the content acquisition program (S10). Subsequently, the position information acquisition unit 154 acquires position information indicating the position of the terminal 1 when the measurement unit 151 measures the radio wave intensity (S11).

  Subsequently, the terminal transmitter 152 transmits information indicating the radio field intensity of the access point 2, information indicating the radio field intensity of the other access point 5, information indicating the channel used by the other access point 5, Radio wave intensity information including the MAC address and ESSID, the measured date and time, and the location information of the terminal 1 is transmitted to the access point 2.

  Subsequently, when the device receiving unit 241 receives the radio wave intensity information, when the radio wave intensity information is subtracted from the radio wave intensity of another access point 5 from the No. for identifying the acquired date and location and the radio wave intensity of the access point 2. Is added and stored in the device storage unit 23 (S20).

  Subsequently, the change detection unit 243 refers to the received radio wave intensity information and the radio wave intensity information stored in advance in the device storage unit 23, detects the change amount of the radio wave intensity of the other access point 5 at the same position, Based on the change amount, it is determined whether or not the influence of the other access point 5 on the access point 2 has changed (S30). When the change detection unit 243 determines that the influence has changed, the instruction information generation unit 244 generates instruction information for instructing measurement of the radio wave intensity (S40), and the device transmission unit 245 displays the generated instruction information. Transmit to terminal 1.

  Subsequently, the measurement unit 151 receives the instruction information for instructing the measurement of the radio field intensity from the access point 2 and then measures the radio field intensity based on the instruction information. Here, based on the position indicated by the position information acquired by the position information acquisition unit 154, the measurement unit 151 determines whether or not the radio field intensity has been measured within a predetermined time at the measurement position (S51).

  When the measurement unit 151 determines that the radio field intensity is measured within a predetermined time at the measurement position (when the determination is Yes), the measurement unit 151 does not measure the radio field intensity based on the instruction information. Further, when it is determined that the radio field intensity is not measured within a predetermined time at the measurement position (when the determination is No), the measurement unit 151 measures the radio field intensity based on the instruction information (S50). Subsequently, the terminal transmission unit 152 transmits radio wave intensity information including information indicating the measured radio wave intensity, position information, and the like to the access point 2.

[Effects of Second Embodiment]
As described above, the access point 2 of the radio wave information collecting system S according to the second embodiment is affected by the other access point 5 on the access point 2 based on the change amount of the radio wave intensity measured at the same position. Detect changes. By doing in this way, the access point 2 does not change the channel and ESSID of the other access point 5, and even when the radio field intensity changes due to the movement of the installation position of the other access point 5, etc. It can be detected that the influence of the other access point 5 on the access point 2 has changed.

  In addition, when the measurement unit 151 measures the radio wave intensity within a predetermined time at the position indicated by the position information acquired by the position information acquisition unit 154, the measurement unit 151 does not newly measure the radio wave intensity at the position. Can be further suppressed.

<Third Embodiment>
[Allow other terminals 1 to measure radio wave information]
Subsequently, a third embodiment will be described. In the first embodiment, when a change in the influence of another access point 5 on the access point 2 is detected, instruction information is transmitted to one terminal 1. In contrast, in the third embodiment, when the access point 2 detects a change in influence, the instruction information generation unit 244 further generates instruction information for another terminal 1 different from the terminal 1 that transmitted the radio wave intensity, The second embodiment is the same as the first embodiment in that the frequency of measurement is increased by transmitting instruction information to a plurality of terminals 1 and causing the plurality of terminals 1 to measure the radio wave intensity, and the other points are the same.

  Hereinafter, the radio wave information collection system S according to the third embodiment will be described while describing a sequence related to the process of measuring the radio wave intensity in the terminal 1. FIG. 11 is a sequence diagram relating to a process of measuring radio wave intensity in a plurality of terminals 1 (terminal 1A and terminal 1B) according to the third embodiment. Here, it is assumed that the device storage unit 23 stores radio wave intensity information. Note that description of processing similar to the sequence shown in FIG. 8 is omitted.

  The device transmission unit 245 transmits the instruction information generated in S40 to the terminal 1A that has transmitted the radio wave intensity information, and transmits the instruction information to the terminal 1B that has not transmitted the radio wave intensity information.

  Subsequently, when the measurement unit 151 of the terminal 1A and the terminal 1B receives the instruction information for instructing the measurement of the radio field intensity from the access point 2, the measurement unit 151 measures the radio field intensity based on the instruction information (S50, S60). Subsequently, the terminal transmission unit 152 of the terminal 1A and the terminal 1B transmits radio wave intensity information including information indicating the measured radio wave intensity to the access point 2.

  Here, the terminal 1B may not newly measure the radio wave intensity at a position where the terminal 1A measures the radio wave intensity within a predetermined time. Specifically, the terminal transmission unit 152 of the terminal 1A measures the radio field intensity in S10, and then transmits the radio field intensity information including the identification information for identifying the terminal 1A to the access point 2. As shown in FIG. 11, when the device receiving unit 241 receives the radio wave intensity information, the device transmitter 245 transmits the radio wave intensity information to another terminal 1B different from the terminal 1A that has transmitted the radio wave intensity information.

  The device transmission unit 245 transmits the radio wave intensity information to the other terminal 1B at the timing when the device reception unit 241 receives the radio wave intensity information, but is not limited thereto. For example, the device transmission unit 245 may transmit the radio wave intensity information of the terminal 1A and the instruction information when the change is detected in response to detecting the change in the terminal 1A. Further, the terminal 1B transmits an acquisition request for the radio wave intensity information to the access point 2 in response to receiving the instruction information, and the device transmission unit 245 transmits the radio wave intensity information of the terminal 1A to the terminal in response to the acquisition request. You may transmit to 1B.

  The terminal 1B stores the received radio wave intensity information in the storage unit 14. When measuring the radio field intensity, the measurement unit 151 of the terminal 1B refers to the radio field intensity information stored in the storage unit 14, and at the position indicated by the position information acquired by the position information acquisition unit 154, other terminals (terminals) 1A) determines whether or not the radio field intensity is measured within a predetermined time. When the measurement unit 151 of the terminal 1B determines that the radio field intensity is measured within a predetermined time, the measurement unit 151 does not newly measure the radio field intensity at the position. By doing in this way, since the terminal 1B does not newly perform measurement at a position where the other terminal has measured the radio wave intensity within a predetermined time, it is possible to suppress an increase in power consumption.

[Effect in the third embodiment]
As described above, when the access point 2 of the radio wave information collection system S according to the third embodiment detects a change in influence, the access point 2 transmits instruction information to the plurality of terminals 1 to increase the radio wave intensity to the plurality of terminals 1. Let me measure. By doing in this way, when there is a change in influence, the radio field intensity is measured at the plurality of terminals 1, so that the measurement frequency can be further increased and the radio field intensity at a plurality of positions can be grasped in a short time.

  As mentioned above, although this invention was demonstrated using embodiment, the technical scope of this invention is not limited to the range as described in the said embodiment. It will be apparent to those skilled in the art that various modifications or improvements can be added to the above embodiment. In particular, the specific embodiments of the distribution / integration of the devices are not limited to those illustrated above, and all or a part thereof may be added in arbitrary units according to various additions or according to functional loads. It can be configured functionally or physically distributed and integrated. For example, the function of the control unit 24 of the access point 2 described in the present embodiment may be implemented in another device different from the access point of the wireless LAN. Here, the other device may be, for example, a mobile terminal such as a smartphone or a tablet having a tethering function that allows itself to function as an access point.

DESCRIPTION OF SYMBOLS 1 ... Terminal, 11 ... Input part, 12 ... Display part, 13 ... Radio | wireless part, 14 ... Memory | storage part, 15 ... Control part, 151 ... Measuring part, 152. .. Terminal transmission unit, 153... Content acquisition unit, 2... Access point, 21... Radio unit, 22 .. communication unit, 23... Storage unit, 24. ... device receiver, 242 ... storage controller, 243 ... change detector, 244 ... instruction information generator, 245 ... device transmitter, 246 ... channel selector, 247 ..Channel setting unit, 248 ... content transmission unit, 3 ... external server, N ... network, S ... channel selection system

Claims (12)

A radio wave information collection system comprising a radio wave information collection device and a mobile terminal,
The portable terminal is
In a communicable area of the predetermined access point, a measurement unit that measures the radio field intensity of another access point different from the predetermined access point and the channel used by the other access point;
A radio wave intensity of the other access point, and a terminal transmitter that transmits radio wave intensity information including a channel used by the other access point to the radio wave information collection device,
The radio wave information collecting device includes:
A device receiver for receiving the radio field intensity information from the mobile terminal;
A device storage unit for storing the radio field intensity information received by the device reception unit;
A change detection unit that detects a change in the influence of the other access point on the predetermined access point based on the radio wave intensity information;
An instruction information generating unit for generating instruction information for instructing measurement of radio wave intensity in response to the change detecting unit detecting a change;
A device transmitter that transmits the generated instruction information to the mobile terminal;
When the measurement unit receives the instruction information from the radio wave information collection device, the measurement unit measures a radio wave intensity based on the instruction information.
Radio wave information collection system. There are a plurality of the mobile terminals,
When the change detection unit detects the change, the instruction information generation unit further generates the instruction information for another mobile terminal different from the mobile terminal that transmitted the radio wave intensity,
The device transmission unit transmits the instruction information to the other portable terminal;
The radio wave information collection system according to claim 1. The instruction information generation unit generates the instruction information including definition information that defines a measurement frequency of radio wave intensity in the portable terminal.
The radio wave information collection system according to claim 1 or 2. The change detection unit detects the change based on a change in the channel of the other access point included in the radio wave intensity information.
The radio wave information collection system according to any one of claims 1 to 3. The measurement unit acquires identification information of the other access point,
The terminal transmission unit transmits the radio wave intensity information further including identification information of the other access point to the radio wave information collection device,
The change detection unit detects the change based on a change in a channel of another access point corresponding to the identification information included in the radio wave intensity information;
The radio wave information collection system according to claim 4. The measurement unit acquires identification information of the other access point,
The terminal transmission unit transmits the radio wave intensity information further including identification information of the other access point to the radio wave information collection device,
The change detection unit detects the change based on a change in the identification information included in the radio wave intensity information;
The radio wave information collection system according to any one of claims 1 to 5. The measurement unit acquires identification information of the other access point,
The terminal transmission unit transmits the radio wave intensity information further including identification information of the other access point to the radio wave information collection device,
The change detection unit detects the change when the identification information included in the radio wave intensity information is different from the already acquired identification information.
The radio wave information collection system according to any one of claims 1 to 6. The mobile terminal further includes a position information acquisition unit that acquires position information indicating a position of the mobile terminal when the radio field intensity is measured,
The terminal transmission unit transmits the radio wave intensity information further including position information of the mobile terminal to the radio wave information collection device,
When the device reception unit receives the radio field intensity information, the change detection unit is configured to detect the radio field intensity of the other access point included in the radio field intensity information at a position indicated by the position information included in the radio field intensity information. Detecting the change based on the amount of change with the radio wave intensity of the other access point included in the device storage unit,
The radio wave information collection system according to any one of claims 1 to 7. When the measurement unit measures the radio wave intensity within a predetermined time at the position indicated by the position information acquired by the position information acquisition unit, the measurement unit does not newly measure the radio wave intensity at the position.
The radio wave information collection system according to claim 8. The terminal transmission unit includes identification information for identifying the portable terminal in the radio wave intensity information and transmits the radio wave information to the radio wave information collection device,
The device transmission unit transmits the radio field intensity information to another mobile terminal different from the mobile terminal that transmitted the radio field intensity information,
The measurement unit does not newly measure the radio wave intensity at the position when another mobile terminal measures the radio wave intensity within a predetermined time at the position indicated by the position information acquired by the position information acquisition unit,
The radio wave information collection system according to claim 9. In the communicable area of the predetermined access point, the radio wave intensity of another access point different from the predetermined access point measured by the mobile terminal, the channel used by the other access point, and the location information of the mobile terminal A receiver that receives radio field intensity information including: from the mobile terminal;
A device storage unit for storing the radio wave intensity information received by the reception unit;
A change detection unit that detects a change in the influence of the other access point on the predetermined access point based on the radio wave intensity information;
An instruction information generating unit for generating instruction information for instructing measurement of radio wave intensity in response to the change detecting unit detecting a change;
A device transmission unit that transmits the generated instruction information to the mobile terminal;
A radio wave information collecting device. In the communicable area of the predetermined access point, the radio wave intensity of another access point different from the predetermined access point measured by the mobile terminal, the channel used by the other access point, and the location information of the mobile terminal Receiving from the mobile terminal radio field intensity information including:
Storing the received radio field intensity information in a storage unit;
Detecting a change in influence of the other access point on the predetermined access point based on the radio field intensity information;
Generating instruction information for instructing measurement of radio field intensity in response to detecting the change;
Transmitting the generated instruction information to the mobile terminal;
A measurement control method comprising:

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