JP5598652B2 - Wireless communication base station - Google Patents

Description

  The present invention relates to control of an access point of a wireless communication base station that performs data communication or the like, particularly in a wireless LAN (Local Area Network) system.

  Conventionally, as media access control of a wireless LAN system, access control defined by IEEE (The Institute of Electrical and Electronics Engineers) 802.11 system is widely known. For details of the IEEE802.11 system, see International Standard ISO / IEC (International Organization for Standardization / International Electrotechnical Commission) 8802-11: 1999 (E) ANSI / IEEE Std 802.11, 1999 Edition, Part11: Wireless LAN Medium Access Control (MAC ) and Physical Layer (PHY) Specifications.

  The network configuration in the IEEE 802.11 system includes an infrastructure mode in which a master control station such as an access point (AP) exists and an ad hoc mode configured only by a plurality of mobile stations (Station: STA). In the infrastructure mode, a network including one AP and a plurality of STAs existing in the area is called a basic service set (BSS). The STA establishes a logical association with a specific AP through a network management function. In the infrastructure mode, the AP periodically transmits management information called a beacon signal. The beacon signal frame notifies the existence of the network controlled by the AP and transmits parameters necessary for joining (belonging to) the network. Even after the STA belongs, it is used for the time synchronization function for synchronizing the transmission timing between the AP and the STA in the BSS. Since the beacon signal frame plays an important role in maintaining the network, it basically needs to be transmitted constantly.

  The function of the STA to search (discover) the network is called scanning, and two types of scanning, passive scan and active scan, are defined.

  Passive scan is a method in which a STA searches for a network by receiving and monitoring a beacon signal. When a STA receives a beacon signal, the presence of the AP that the STA is searching for based on the information contained therein, and its Parameters necessary for connection are acquired, and it is determined whether the STA is an available network. As a result, when it is determined that the STA is an available network, an authentication request signal is transmitted to the AP, and the AP that has received the authentication request signal starts belonging operation (attachment preparation state). Thereafter, through a predetermined process, the STA officially belongs to the AP (affiliation state).

On the other hand, active scan is a method for searching a network by exchanging probe request / response frames. The STA that intends to perform this active scan transmits a frame called a probe request, which is a network search signal, at a place where an AP is supposed to exist. The ID (SSID) of the network being searched is set in the probe request. The AP that has successfully received the probe request checks the SSID set therein, checks whether it matches the SSID of the AP itself, and as a result, if the STA is searching for an AP, the probe request is sent as a response to the AP request. A probe response frame is transmitted to the transmission source. The STA analyzes the contents of the probe response frame and acquires the presence of the AP searched by the STA and the parameters necessary for the connection. Based on this information, the process of determining whether or not the STA is an available network and the belonging process are started in the same manner as in the passive scan.

  FIG. 8 shows the configuration of the AP of the related wireless LAN system. 801 is an antenna, 802 is a radio transmission / reception unit that controls modulation / demodulation of a radio signal transmitted / received from the antenna, 803 is a beacon signal transmission unit that controls generation of a beacon signal, and 804 is an attribution control unit that controls the belonging state of the STA in the AP. . The beacon signal generated by the beacon signal transmission unit 803 is converted into a radio signal by the radio transmission / reception unit 802 and transmitted from the antenna 801. On the other hand, the AP manages how many STAs are currently attributed (attribution preparation). However, a beacon signal is generated and transmitted by the beacon signal transmission unit 803 regardless of the presence or absence of the belonging STA.

  FIG. 9 is a timing diagram showing an example in which the STA tries to belong to the AP in the passive scan mode in the related wireless LAN system shown for reference. (A) shows AP belonging (attachment preparation) state, (b) shows AP transmission, and (c) shows STA transmission.

  Regardless of whether or not there is an STA belonging (including the belonging preparation state) (the period of “no attribution” and the period of “affiliation” in (a)), the beacon signal is constantly transmitted in a predetermined cycle (T9001). ~ T9010). The STA receives a beacon signal at timing T9006, and transmits an authentication request signal to the AP at timing T9101, in order to perform attribution with the AP based on information obtained by the beacon signal. The AP that has received the authentication request signal enters the affiliation preparation state in order to perform affiliation with the STA (in (a), the non-affiliation state changes to the attribution state).

  FIG. 10 is a timing diagram showing an example in the case where the STA tries to belong to the AP in the active scan mode in the related wireless LAN system shown for reference. (A) shows AP belonging (attachment preparation) state, (b) shows AP transmission, and (c) shows STA transmission.

  Regardless of whether or not there is an STA belonging (including the belonging preparation state) (the period of “no attribution” and the period of “affiliation” in (a)), the beacon signal is constantly transmitted in a predetermined cycle (T10001). ~ T10010). The STA transmits a probe request signal at timing T10101. The AP that has received the probe request enters the belonging preparation state in order to associate with the STA (the unaffiliated state changes to the belonging state in (a)), and sends a probe response signal to the STA that has transmitted the probe request. Transmit (timing T10201). The STA that has received the probe response signal transmits an authentication request signal to the AP at timing T10102 in order to associate with the AP based on the information obtained by the STA.

  FIG. 11 shows a case where the STA belonging to only one STA belongs to the AP and the STA belonging to the last STA is removed from the AP, and the STA having no belonging state (or belonging preparation state) disappears from the AP. FIG. (A) shows the AP belonging (beginning of attribution) state, (b) shows AP transmission, and (c) shows STA transmission.

In a state where only one STA belongs to the AP (period of “belongs to” in (a)), the STA transmits an association release signal to the AP (timing T11101). The AP that has received the association cancellation signal cancels the affiliated state with the STA and shifts to the non-affiliated state (the period of “no attribution” in (a)). As in the case of FIG. 9 and FIG. 10, the beacon signal is predetermined regardless of whether or not there is an STA belonging (including the belonging preparation state) (the period of “no attribution” and the period of “affiliation” in (a)). (T11001 to T11010).

Usually, the STA scan mode is a mixture of a passive mode and an active mode. Therefore, the AP needs to continuously transmit the beacon signal frame so that it can cope with any STA. However, depending on the network traffic situation, for example, when no STA belongs to midnight and there is no STA to which it belongs, it will continue to consume wasted power for the transmission process of the beacon signal. There was a problem of becoming.

  Patent Document 1 describes an example of a technique for saving power consumption by stopping transmission of a beacon signal for a certain period of time. In this technology, for a beacon signal that needs to be transmitted constantly and periodically, a beacon signal during a period in which the beacon is notified is notified in advance to the STA in the BSS in advance of a period during which the beacon signal transmission is stopped. Is temporarily stopped. By this process, each STA can predict that a beacon signal will not be received during the period in which the advance notice is given, and thus a technique is disclosed that can also prevent malfunction due to this.

  Patent Document 2 discloses a technique for deleting useless transmission of multicast information transmitted from a master station device of a wireless LAN system. In other words, in the master station device of the wireless LAN system that transmits multicast information, the affiliation status of the master station device to the group is managed, and only when the slave station device that belongs to the group corresponding to the multicast information exists in the communicable area The multicast information is wirelessly transmitted.

  Patent Document 3 discloses a technique for reducing the power consumption of the access point of the wireless LAN system by stopping the power supply to other than the reception level detection comparison block of the access point when a certain condition is satisfied. Yes. That is, if the access point does not communicate with the terminal for a predetermined time, power is supplied only to the reception level detection comparison block, and power is supplied to the transmission block only when reception power exceeding a predetermined level is detected. The entire access point is configured to operate.

  Patent Document 4 relates to a load control method for a radio base station in a mobile communication system, and adjusts the load among a plurality of radio base stations in response to load fluctuations depending on the area of the radio base station, and reduces processing resources. A technique that can be used effectively is disclosed. In this method, the processing capability of a radio base station is predicted, and the number of radio units that perform processing by the radio control device of the radio base station is increased or decreased.

JP 2005-45616 A JP 2000-324120 A Japanese Patent Laid-Open No. 2001-156788 JP 2007-228213 JP

  The technique of Patent Document 1 described above is capable of temporarily stopping the transmission of a beacon signal without any trouble in a situation where one or more STAs belonging to the AP exist. However, there is no means for notifying the stop period of the beacon signal to STAs that have not yet belonged in this technology. Therefore, when a new STA arrives in a state where transmission of a beacon signal is stopped by this technique, there is a problem that the attribution process is hindered.

  Further, the technique disclosed in Patent Document 2 described above is such that a packet sent as a multicast from an upper host is not transmitted from the master station device when the corresponding slave station device does not belong to the group. However, the target of deletion by this technology is multicast packets, and other control signals including the local station identification signal (beacon signal) are maintained and managed even when the slave station device corresponding to the multicast does not belong to the group. There is a problem that it cannot be stopped because it is necessary.

  Further, in the technique of Patent Document 3 described above, the access point enters a state (sleep state) in which power supply to other than the reception level detection comparison block of the access point is stopped when there is no communication with the terminal for a predetermined time. Therefore, in this state, there is a problem that even though the belonging terminal still exists at the access point, transmission of the local station identification signal (beacon signal) is stopped.

In the technique of Patent Document 4 described above, the control criterion is the load status at each radio base station, and the control target also allocates resources such as antennas and sectors according to the load status of each radio base station. That's it. However, the local station identification signal that is the object of the control of the present invention basically needs to be transmitted constantly regardless of the load. If transmission of the local station identification signal is stopped by this technique even though there is an affiliated terminal, there is a problem that the inherent attribution control of the terminal is hindered.

The present invention avoids the above-mentioned problems and reduces the power consumption by continuously transmitting beacon signals in a situation where there is no terminal belonging to the wireless communication base station (or belonging preparation state). An object of the present invention is to provide a radio communication base station, a radio communication system, and a radio communication method that can avoid waste.

  The radio communication base station of the present invention is a radio communication base station that periodically transmits its own station identification information, and stops periodic transmission of its own station identification information when it is determined that there is no belonging terminal. .

  The radio communication system of the present invention is a radio communication system that periodically transmits its own station identification information from a radio communication base station. When it is determined that there is no belonging terminal, the station identification information is periodically transmitted. Stop sending.

  Further, the wireless communication method of the present invention is a wireless communication method in which the local station identification information is periodically transmitted from the wireless communication base station. Stop sending.

  As described above, in the wireless communication base station, the wireless communication system, and the wireless communication method of the present invention, when the presence / absence of a terminal belonging to the wireless communication base station is determined and it is determined that there is no terminal belonging to the wireless communication base station Can stop the local station identification information, that is, the beacon signal. As a result, it is possible to avoid waste of power consumption due to a beacon signal being transmitted unnecessarily in a situation where there is no belonging terminal.

It is a structural example of the system by the radio | wireless communication base station by this Embodiment. It is a block diagram which shows the structure of the radio | wireless communication base station of one embodiment of this invention. FIG. 6 is a timing diagram for explaining the operation of an embodiment of the present invention. It is a block diagram which shows the structure of the wireless LAN base station (AP) of other embodiment of this invention. It is a timing diagram which shows an example in case the STA of other embodiment of this invention tries to belong to AP at the time of a passive scan mode. It is a timing diagram which shows the example in case the STA of other embodiment of this invention tries to belong to AP at the time of an active scan mode. It is a timing diagram for explanation at the time of de-authentication in other embodiments of the present invention. It is a configuration of an AP of a related wireless LAN system. FIG. 10 is a timing diagram for explaining an operation when an STA tries to belong in a passive scan mode in a related wireless LAN system. FIG. 10 is a timing diagram for explaining an operation when an STA tries to belong in an active scan mode in a related wireless LAN system. FIG. 10 is a timing diagram for explaining the cancellation of authentication in a related wireless LAN system.

  Embodiments of the present invention will be described with reference to the drawings.

FIG. 1 shows a configuration example in a communication area by a radio communication base station according to the present embodiment.
101 is a wireless communication base station, 102 is a terminal 1, and 103 is a terminal 2. In this example, one wireless communication base station is installed in the communication area, and is composed of a terminal 1 existing in the same communication area and a terminal 2 existing outside the communication area.

  In this embodiment, in the wireless communication base station 101, the presence / absence of a terminal belonging to the wireless communication base station 101 is determined. When it is determined that there is no belonging terminal, the local station identification information can be stopped. As a result, it is possible to avoid waste of power consumption due to unnecessary transmission of the local station identification information in a situation where there is no belonging terminal.

  FIG. 2 is a block diagram showing the configuration of the radio communication base station according to the embodiment of the present invention.

  201 is an antenna, 202 is a wireless transmission / reception unit that controls modulation / demodulation of a radio signal transmitted / received from the antenna, 203 is a beacon signal transmission unit that controls generation of a beacon signal that is identification information of its own station, and 204 is a terminal in a wireless communication base station An attribution control unit for controlling the attribution state of

  The beacon signal generated by the beacon signal transmission unit 203 is converted into a radio signal by the radio transmission / reception unit 202 and transmitted from the antenna 201. The wireless communication base station manages the number of terminals to which the wireless communication base station currently belongs (or preparing for belonging) by the belonging control unit 204. When there is one or more belonging (including preparing for belonging) terminals managed by the belonging control unit 204, the belonging control unit 204 instructs the beacon signal transmitting unit 203 to transmit a beacon signal and transmits the beacon signal. Unit 203 generates and transmits a beacon signal. On the other hand, if there is no belonging (including preparing for belonging) terminal managed by the belonging control unit 204, the belonging control unit 204 instructs the beacon signal transmitting unit 203 to stop beacon signal transmission. Then, the generation of the beacon signal in the beacon signal transmission unit 203 is stopped. As a result, no beacon signal is transmitted from the antenna 201.

  FIG. 3 is a timing diagram for explaining the operation of the embodiment of the present invention. (A) shows the terminal (attribution start) state of the terminal in the radio communication base station, and (b) shows transmission from the radio communication base station (transmission of a beacon signal).

  In a state in which the terminal belongs to the wireless communication base station at the beginning (including the belonging preparation state) (a period of “belonging to belonging” in (a)), the beacon signal is transmitted in a predetermined cycle (T3001 to T3004). When the state changes from that state to a state where there is no terminal (including the belonging preparation state) at all (the period of “no attribution” in (a)), the transmission of the beacon signal is stopped (the period between T3004 and T3005). ). When the time further elapses and the wireless communication base station enters the belonging preparation state again (in (a), the non-affiliation state changes to the belonging state), the beacon signal starts to be transmitted in a predetermined cycle thereafter. (T3005-T3008).

  As described above, in one embodiment of the present invention, while one or more terminals belong to (or prepare to belong to) a radio communication base station, a beacon signal is transmitted as usual, but the radio communication base station When there is no more terminal belonging (or preparing for belonging), the transmission of the beacon signal can be stopped.

  Therefore, the power consumption due to the wireless communication base station continuously transmitting beacon signals unnecessarily, for example, at night, when no terminal belongs and the terminal to which a new terminal belongs does not arrive for a certain period of time. This has the effect of reducing waste.

  Next, another embodiment of the present invention will be described with reference to the drawings.

  FIG. 4 is a block diagram showing a configuration of a wireless LAN base station (AP) according to another embodiment of the present invention.

  401 is an antenna, 402 is a wireless transmission / reception unit that controls modulation / demodulation of a radio signal transmitted / received from the antenna, 403 is a beacon signal transmission unit that controls generation of a beacon signal, and 404 is an attribution control unit that controls the belonging state of the STA in the AP. 405 is a belonging STA presence / absence determination unit.

  The beacon signal generated by the beacon signal transmission unit 403 is converted into a radio signal by the radio transmission / reception unit 402 and transmitted from the antenna 401. The AP manages the number of STAs to which the AP currently belongs (or is in preparation for belonging) by the attribution control unit 404. Attribution STA presence / absence determination unit 405 determines the presence / absence of attribution STA. As a result, when there are one or more belonging (including preparing for belonging) STAs, the belonging STA presence / absence determining unit 405 instructs the beacon signal transmitting unit 403 to transmit a beacon signal, and the beacon signal transmitting unit 403 Generate and transmit a beacon signal. On the other hand, as a result of determining the presence / absence of the belonging STA by the belonging STA presence / absence determining unit 405, if there is no belonging (including preparation for belonging) STA, the belonging STA presence / absence determining unit 405 On the other hand, stop of the beacon signal transmission is instructed, and the beacon signal transmission unit 403 stops the generation of the beacon signal. As a result, no beacon signal is transmitted from the antenna 401.

  FIG. 5 is a timing diagram showing an example in which a STA according to another embodiment of the present invention attempts to belong to an AP in the passive scan mode. (A) shows the AP belonging (beginning of attribution) state, (b) shows AP transmission, and (c) shows STA transmission.

  In a state where there is no belonging STA (including the belonging preparation state), the beacon signal is not transmitted (in the period of “no attribution” in (a)). Even if the beacon signal is not transmitted, if the STA tries to re-assign to the same AP, such as when the STA stays in the vicinity of the AP to which the STA previously belonged, The acquired information may be retained. In this case, the STA transmits an authentication request signal to the AP at timing T5101 in order to perform attribution with the AP based on the held information. The AP that has received the authentication request signal enters the affiliation preparation state in order to perform affiliation with the STA (in (a), the non-affiliation state changes to the attribution state). Thereafter, transmission of the beacon signal at a predetermined cycle is started (T5001 to T5004).

  FIG. 6 is a timing diagram showing an example in which the STA according to another embodiment of the present invention attempts to belong to the AP in the active scan mode. (A) shows the AP belonging (beginning of attribution) state, (b) shows AP transmission, and (c) shows STA transmission. A beacon signal is not transmitted in a state where there is no STA (including the belonging preparation state) to which it belongs (the period of “no attribution” in (a)).

  The STA transmits a probe request signal at timing T6101. The AP that has received the probe request enters the belonging preparation state in order to associate with the STA (the unaffiliated state changes to the belonging state in (a)), and sends a probe response signal to the STA that has transmitted the probe request. Transmit (timing T6201). The STA that has received the probe response signal transmits an authentication request signal to the AP at timing T6102 in order to associate with the AP based on the information obtained by the STA. Thereafter, the AP changes from the “no attribution” state to the “belongs to attribution” state (period “no attribution” to “with attribution” in (a)), and starts transmitting a beacon signal at a predetermined cycle (T6001 to T6006). ).

  FIG. 7 shows a state where only one STA belongs to an AP in the other embodiment of the present invention, and the last STA belongs to the AP, and one AP belongs to the AP (or preparation for belonging). It is a timing chart showing an example in the case of shifting to a state where the STA of (state) disappears. (A) shows the AP belonging (beginning of attribution) state, (b) shows AP transmission, and (c) shows STA transmission.

  In a state where only one STA initially belongs to the AP (including the belonging preparation state) (belonging to “with belonging” in (a)), the beacon signal is transmitted in a predetermined cycle (T7001 to T7006). . In this state, when an association cancellation signal is transmitted from the STA to the AP (timing T7101), the AP that has received the signal cancels the belonging state with the STA and shifts to the non-affiliating state ("a" in (a)). No attribution "period). Thereafter, the AP changes from the “belonging to belonging” state to the “not belonging” state (the period “from belonging” to “not belonging” in (a)), and thereafter, beacon signal transmission is stopped (after T7006).

  As described above, in another embodiment of the present invention, when there is no STA belonging to (or preparing for) the AP in the BSS, the transmission of the beacon signal can be stopped. . In addition, when the STA arrives with the beacon signal stopped, the probe request or authentication request is transmitted to the AP, and when the AP receives the signal, the periodic transmission of the stopped beacon signal is resumed. . Therefore, the normal control can be performed thereafter. Therefore, waste of power consumption due to the AP continuously transmitting beacon signals unnecessarily, such as at night, when no STA belongs and the STA to be newly assigned does not arrive for a certain period of time. Can be reduced. If the STA arrives and transmits a predetermined signal, the beacon signal is immediately resumed, so that the subsequent communication operation is not hindered.

  Note that the beacon signal described in each of the above-described embodiments is an example, and the process described in each of the embodiments is used for the transmission suspension processing of control information that is periodically transmitted other than other beacon signals. It is also possible to apply.

  Further, as a condition for stopping the beacon signal, for example, a timer or the like may be provided so as to add only a time zone in which traffic such as nighttime is assumed to be small. As a result, the present invention can be implemented more effectively by performing this operation only in a time zone in which it is assumed that the number of incoming STAs is very small and the condition for stopping the beacon signal is often satisfied. Moreover, after satisfy | filling the conditions for stopping a beacon signal, it is good also as what stops an beacon signal, after providing observation time and confirming having satisfied a fixed time condition. As a result, for example, when a situation occurs where a single STA under the AP repeats attribution and attribution cancellation in a short cycle, frequent stop and restart of beacon signals can be suppressed, and system stability can be improved. I can do it.

  Further, in each of the embodiments described so far, the wireless communication network that is mainly applicable to the wireless LAN is assumed. However, if the network performs similar wireless communication at a relatively short distance, it is for other systems. It can be applied to various wireless networks.

  In each of the embodiments described so far, the wireless communication terminal that performs wireless communication in the wireless network is assumed to be a dedicated communication device, but may be as follows. That is, for example, a personal computer device that performs various data processing is mounted with a board, a card, or the like that performs communication processing corresponding to the wireless communication unit in this example, and the communication control processing is executed on the computer device side. In this manner, the software for executing the communication control process may be installed in the personal computer device to execute the temporary suspension process for transmission of a beacon signal or the like.

The program installed in the data processing device such as the personal computer device may be distributed via various recording (storage) media such as an optical disk and a memory card, or distributed via communication means such as the Internet. Also good.

(Appendix 1)
A radio communication base station that periodically transmits its own station identification information, and stops periodic transmission of its own station identification information when it is determined that there is no belonging terminal. .
(Appendix 2)
The wireless communication base station according to attachment 1, further comprising means for resuming periodic transmission of the local station identification information that has been stopped when a specific signal is received from a terminal. Communication base station.
(Appendix 3)
The wireless communication base station according to Supplementary Note 2, wherein the wireless communication base station is a wireless LAN defined by the IEEE802.11 standard.
(Appendix 4)
The wireless communication base station according to supplementary note 3, wherein the local station identification information is a beacon signal.
(Appendix 5)
The wireless communication base station according to appendix 4, wherein the specific signal is an authentication request signal or a probe request signal.
(Appendix 6)
A wireless communication system that periodically transmits its own station identification information from a wireless communication base station, characterized in that when it is determined that there is no belonging terminal, periodic transmission of said own station identification information is stopped. Wireless communication system.
(Appendix 7)
The wireless communication system according to attachment 6, further comprising means for resuming periodic transmission of the local station identification information that has been stopped when a specific signal is received from a terminal. .
(Appendix 8)
The wireless communication system according to appendix 7, wherein the wireless communication system is a wireless LAN defined by the IEEE802.11 standard.
(Appendix 9)
The wireless communication system according to appendix 8, wherein the local station identification information is a beacon signal.
(Appendix 10)
The wireless communication system according to appendix 9, wherein the specific signal is an authentication request signal or a probe request signal.
(Appendix 11)
A wireless communication method that periodically transmits its own station identification information from a wireless communication base station, characterized in that when it is determined that there is no belonging terminal, periodic transmission of its own station identification information is stopped. Wireless communication method.
(Appendix 12)
The wireless communication method according to attachment 11, further comprising a step of resuming periodic transmission of the local station identification information that has been stopped when a specific signal is received from a terminal. .
(Appendix 13)
The wireless communication method according to appendix 12, wherein the wireless communication method is a wireless LAN defined by the IEEE802.11 standard.
(Appendix 14)
The wireless communication method according to supplementary note 13, wherein the local station identification information is a beacon signal.
(Appendix 15)
15. The wireless communication method according to appendix 14, wherein the specific signal is an authentication request signal or a probe request signal.

101 wireless communication base station 102 terminal 1
103 Terminal 2
201 antenna 202 wireless transmission / reception unit 203 beacon signal transmission unit 204 attribution control unit

Claims (5)

A wireless communication base station that periodically transmits its own station identification information,
When it is determined that there is no terminal to which it belongs , means for stopping the periodic transmission of the local station identification information ,
Resuming periodic transmission of the local station identification information that was stopped when receiving a specific signal from the terminal,
The wireless communication base station is a wireless LAN defined by the IEEE 802.11 standard,
The radio communication base station, wherein the specific signal is an authentication request signal . The own station identification information radio communication base station according to claim 1, wherein the beacon signal. A wireless communication system that periodically transmits its own station identification information from a wireless communication base station,
Means for stopping periodic transmission of the local station identification information when it is determined that there is no terminal to which the terminal belongs ,
Resuming periodic transmission of the local station identification information that was stopped when receiving a specific signal from the terminal,
The wireless communication system is a wireless LAN defined by the IEEE 802.11 standard,
The wireless communication system, wherein the specific signal is an authentication request signal . The wireless communication system according to claim 3 , wherein the local station identification information is a beacon signal. A wireless communication method in which the local station identification information is periodically transmitted from a wireless communication base station,
When it is determined that there is no terminal to which it belongs , it stops periodic transmission of its own station identification information ,
When a specific signal is received from the terminal, the periodic transmission of the local station identification information that has been stopped is resumed,
The wireless communication method is a wireless LAN defined by the IEEE 802.11 standard,
The wireless communication method, wherein the specific signal is an authentication request signal .

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