JP2007104033A - Station for composing radio lan system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an STA using a Sleep mode efficiently for reducing power consumption even if a beacon signal period to be received differs from the value of a beacon interval contained in the frame of the beacon signal. <P>SOLUTION: There are provided: a radio section 4 for receiving the beacon signal of an access point AP; a control section 9 for controlling the entire station STA; a power supply section 10 for supplying power to the STA; an SW section 11 for supplying power from the power supply section to the radio section and for stopping the supply; a measurement section 7 for measuring the beacon signal period of AP received by the radio section; and a storage section 8 for storing the measured beacon signal period. The control section stores the measured result of the beacon signal period at AP by the measurement section into the storage section with the information of AP, and controls the supply and stop of the power supply to the radio section by the SW section based on the stored beacon signal period. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a STA used in a wireless LAN system including a plurality of access points (hereinafter abbreviated as “AP”) and stations connectable to the plurality of different APs (hereinafter abbreviated as “STA”). . In particular, the present invention relates to a STA that efficiently performs a sleep mode operation using a set value for each AP.

  A wireless LAN system (IEEE802.11 or the like) including a plurality of APs and STAs connectable to the plurality of different APs is known.

  In such a wireless LAN system, when a user moves while carrying a STA and connects to a different AP, the following control is performed. That is, in order to identify the connection destination AP, the STA stores the ESSID that is the ID of each connection destination AP and the WEP key that is the encryption key as profile information of the connection destination AP, and switches the ESSID and WEP key. To connect to a different AP.

  As an example of switching the connection destination AP using this method in the STA, there is a method described in Patent Document 1, for example.

That is, each of the plurality of APs sends out a beacon signal periodically notifying a beacon frame including network information related to its own AP into the service area, and performs data communication with STAs participating in its own network. Do. The STA performs carrier detection, receives a beacon signal, stores the first network information of the first AP based on the beacon signal, participates in the first network by the first AP,
When receiving a beacon signal from a second AP configuring another different second network, the second network information regarding the second AP is stored. When the connection destination is switched from the participating first network to the second AP of another different second network, the second network by the second AP is changed based on the stored second network information. Participate and continue data communication.
JP 2004-229225 A

  However, since the above conventional switching method stores and connects only identification information such as the ID and WEP of the AP, it cannot sufficiently deal with the problem of characteristics caused by the type and location of the connected AP. In the sleep mode operation (power supply stop), there is a problem that a sufficient power consumption reduction effect cannot be obtained and throughput is lowered.

  An operation example of a sleep mode that is generally used in a wireless LAN system compliant with IEEE 802.11 will be described. FIG. 14 shows the relationship between the power consumption of STA [1], which is one of the stations, and the sleep mode operation when the beacon signal transmitted by AP [1], which is one of a plurality of access points, is ideal. FIG. In STA [1], the power consumed varies depending on the power ON / OFF control. In this example, the power when the power is on is 100 mW, and the power when the power is off is 1 mW. In STA [1], data communication is possible when the power is on, but data communication is not possible when the power is off. In STA [1], the time from when the power is turned on (Wake ON) to when the power is turned on is X1, the time when the power is turned on is Δt, and the power is completely turned off after the power is turned off (Wake OFF). Let X2 be the time until it is turned off.

  In STA [1], when data communication with AP [1] is not being performed, the power consumption can be reduced by turning off the power supply as illustrated. In STA [1], when data is transmitted to AP [1], STA [1] wants to send data to AP [1] by turning on the power immediately before transmitting the data. Sometimes you can send data.

  On the other hand, since the wireless LAN system compliant with IEEE802.11 is a CSMA / CA system, it is difficult to predict the time when data comes from AP [1] in STA [1]. Therefore, in a wireless LAN system compliant with IEEE 802.11, AP [1] notifies the presence / absence of transmission data from AP [1] to STA [1] using a beacon signal. With this information, STA [1] can determine whether or not to operate the sleep mode after receiving the beacon signal and before the next beacon signal.

  As a result, in STA [1], the power is turned on immediately before the beacon signal of AP [1] reaches STA [1], and while the beacon signal is received, the power is continuously turned on. If no data is transmitted from AP [1] to STA [1] until the next beacon signal after the signal reception is completed, the power can be turned off. STA [1] can sleep when data communication is not performed by repeating the beacon signal reception and power ON / OFF operations of AP [1] in this way. Further, a beacon signal cycle that is an interval between a beacon signal and a beacon signal is included as a value of a beacon interval (BI) in a frame of a beacon signal transmitted by AP [1].

  However, there is a case where the BI value notified from AP [1] in STA [1] does not match the beacon signal period actually received by STA [1]. When STA [1] is connected to a plurality of APs, the period of the beacon signal received varies depending on the type of AP and the installation location.

  An example in which the BI value and the beacon signal period actually received by STA [1] do not match will be described with reference to FIG. FIG. 15 is a block diagram illustrating a concept of a communication system and a communication device. The communication system includes AP [1] and STA [1], and STA [2] and STA [3]. AP [1] is AP [1], which is the reach range of beacon signals transmitted by AP [1]. 1] Configure area 1. In the AP [1] area 1, the AP [1] and the STA [1] perform data communication, and also in the AP [1] area 1, the STA [2] and the STA [3] perform data communication.

  With reference to FIG. 16, the exchange of data communication in the AP [1] area 1 will be described. FIG. 16 is a diagram illustrating details of data communication performed in the AP [1] area 1. AP [1] tries to transmit a beacon signal every BI period. STA [2] and STA [3] perform data communication using the same radio channel as AP [1]. Since AP [1] transmits a beacon signal if the wireless channel being used is free, AP [1] transmits a beacon signal B1 and a beacon signal B2 every reference time. On the other hand, since STA [2] and STA [3] also perform data communication if the radio channel is free, the frames of DATA1 and ACK1, and DATA2 and ACK2 are exchanged. As shown in FIG. 16, when data communication is performed between STA [2] and STA [3] at the time when AP [1] transmits beacon signal B3, AP [1] schedules beacon signal B3. The beacon signal B3 is transmitted after the frame exchange between the STA [2] and the STA [3] is completed without being transmitted at the time. As a result, the time for transmitting the beacon signal B3 is delayed.

  As described above, the operation of the STA [1] in the sleep mode when the BI value notified from the AP [1] in the STA [1] and the beacon signal period actually received by the STA [1] do not match. This will be described with reference to FIG. FIG. 17 shows the power consumption and sleep mode of STA [1] when the BI value notified from AP [1] in STA [1] does not match the beacon signal period actually received by STA [1]. It is a figure which shows the relationship.

  The STA [1] is set to turn on at every BI reference time notified from the AP [1] and turn off when the beacon signal reception ends. Since the beacon signal B1 arrives at the STA [1] according to the reference time, the STA [1] is turned on at the time when the beacon signal B1 arrives, receives the beacon signal B1, and turns on after the reception of the beacon signal B1. Is turned off.

  However, since the beacon signal B2 arrives at the STA [1] with a delay from the reference time, the STA [1] turns on the power before the beacon signal B2 arrives and does not receive the beacon signal B2 much. Power is consumed. Also, since the beacon signal B3 reaches STA [1] earlier than the reference time, the STA [1] cannot turn on the power after the beacon signal B3 arrives and cannot receive the beacon signal B3. The power supply is kept on until the beacon signal B4 arrives. For this reason, the beacon signal B3 cannot be received and a large amount of power is consumed.

  In STA [1], even when it is determined that the beacon signal B3 cannot be received, the power can be turned off to forcibly use the sleep mode operation. However, since it cannot be determined whether there is transmission data from AP [1] to STA [1] between beacon signal B3 and beacon signal B4, AP [1] is between beacon signal B3 and beacon signal B4. ] To STA [1], data transmission from AP [1] to STA [1] cannot be performed and throughput is reduced.

  Further, another example will be described with reference to FIG. FIG. 18 shows the STA [1] when the beacon signal period of the AP [1] actually received increases monotonously with respect to the reference time by the BI notified from the AP [1]. The relationship between power consumption and Sleep mode is shown.

  As shown in FIG. 18 (a), STA [1] is set to turn on at every BI reference time notified from AP [1] and turn off when reception of the beacon signal ends. Yes. Since the beacon signal B1 arrives at the STA [1] according to the reference time, the STA [1] is turned on at the time when the beacon signal B1 arrives, receives the beacon signal B1, and turns on after the reception of the beacon signal B1. Is turned off.

  However, since the beacon signal B2 arrives at the STA [1] with a delay from the reference time, the STA [1] turns on the power before the beacon signal B2 arrives and does not receive the beacon signal B2 much. Power is consumed. Further, since the beacon signal B3 arrives at the STA [1] further later than the reference time, the STA [1] is turned on before the beacon signal B3 arrives, and further when the beacon signal B3 is not received. It consumes a lot of power.

  In FIG. 18B, the BI is 100 ms, the beacon signal length is 1 ms, the actual beacon signal arrival time from AP [1] to STA [1] is 0 ms, 110 ms, and 220 ms. The calculation result of the power consumption in STA [1] in the case of monotonously increasing is shown.

  Since the times of X1 and X2 are sufficiently small with respect to Δt, they are ignored, and the time of WakeON is every 100 ms, and WakeOFF increases with the increase in the arrival time of the beacon signal, so as shown in FIG. Δt also increases. Since the power consumption of STA [1] is proportional to the time Δt, the power consumption increases as Δt increases.

  The present invention is intended to solve such a problem of the prior art, and even if the beacon signal period to be received is different from the value of the beacon interval (BI) included in the frame of the beacon signal, the present invention is efficient. An object of the present invention is to provide a STA that uses the sleep mode and can reduce power consumption.

  The STA of the present invention includes a plurality of APs and a STA selectively connected to any of the plurality of APs, and the AP transmits a beacon signal including its own information in its own area. Used in LAN systems.

  In order to solve the above-described conventional problems, the STA of the present invention includes a radio unit that receives the beacon signal of the AP, a control unit that controls the entire STA, a power source unit that supplies power to the STA, and the radio SW unit for supplying and stopping power supply from the power supply unit to the unit, a measurement unit for measuring the AP beacon signal period received by the wireless unit, and a storage unit for storing the measured beacon signal period Prepare. The control unit stores a measurement result of the AP beacon signal cycle by the measurement unit together with the AP information in the storage unit, and based on the stored beacon signal cycle, the SW unit controls the radio unit. Control power supply and shutdown.

  According to the STA of the present invention, the beacon signal period of the received AP is measured and stored, and control is performed based on the stored beacon signal period. Even if the received beacon signal period is different from the BI value, Low power consumption can be realized.

  In the STA of the present invention, preferably, for each AP to be connected, a beacon signal period of the AP received by the wireless unit is measured by the measuring unit, and a measurement result for each AP together with information on the AP. The control unit stores the power in the storage unit, and controls the SW unit based on the beacon signal cycle stored for the connected AP to supply and stop power to the wireless unit. As a result, when reconnecting to the same AP, power is supplied to and stopped from the wireless unit without re-measurement, so that low power consumption can be realized even when STAs handoff between different APs.

  In the STA of the present invention, the beacon signal period of the AP received by the radio unit is measured a plurality of times by the measurement unit, the control unit determines a representative value from the plurality of measurement data, and the representative value is determined. The set value of the AP beacon signal cycle may be stored in the storage unit together with the AP information.

  In that case, the minimum value can be selected from the plurality of measurement data and determined as the representative value. As a result, even when the beacon signal cycle of the connected AP is not constant, the AP beacon signal can be reliably received, and as a result, low power consumption and prevention of a decrease in throughput can be realized.

  In addition, a mode value may be selected from the plurality of measurement data and determined as the representative value. As a result, even when the beacon signal cycle of the connected AP is not constant, if the AP beacon signal cycle is extremely biased, the time required to supply power to the radio unit is reduced, resulting in lower power consumption. Electricity can be realized.

  Further, in the STA of the present invention, a threshold value of a beacon signal reception failure probability is set in the storage unit, and the control unit controls the SW unit based on the set value of the beacon signal period to supply power to the radio unit If the reception failure probability exceeds the threshold value stored in the storage unit as a result of supplying and stopping, the power supply to the wireless unit is canceled, and the AP beacon received by the wireless unit The signal period may be measured again by the measurement unit, and the measurement result may be stored in the storage unit together with the AP information as a set value again. By setting the threshold value of the reception failure probability of the beacon signal, the reception failure probability can be made smaller than the threshold value, and low power consumption and prevention of a decrease in throughput can be realized.

  Further, a threshold value of a ratio of power supply time and stop time is set in the storage unit, and based on the set value of the beacon signal period, the control unit controls the SW unit to supply power to the radio unit. As a result of stopping, when the ratio of the power supply time and the stop time exceeds the threshold stored in the storage unit, the power supply to the wireless unit is canceled and received by the wireless unit The beacon signal period of the AP can be measured again by the measurement unit, and the measurement result can be stored in the storage unit together with the AP information as a set value again. By setting the threshold value of the ratio between the power supply time and the stop time, the time during which power is supplied to the wireless unit can be reduced, and as a result, low power consumption can be realized.

  In addition, a threshold value of a beacon signal reception failure probability is set in the storage unit, the AP beacon signal period received by the wireless unit is measured a plurality of times by the measurement unit, and the measurement result is stored together with the AP information. The setting candidate value of the beacon signal period and the reception failure probability for the setting candidate value are obtained from the result of measurement performed multiple times, and the obtained reception failure probability is obtained from the threshold value stored in the storage unit. The small setting candidate value can be determined as the representative value.

  In addition, a threshold value of a beacon signal reception failure probability is set in the storage unit, the AP beacon signal period received by the wireless unit is measured a plurality of times by the measurement unit, and the measurement result is stored together with the AP information. The beacon signal cycle setting candidate value, the reception failure probability for the setting candidate value, and the ratio of the power supply time and the stop time are calculated from the results of the plurality of measurements. The setting candidate value that is smaller than the threshold value stored in the storage unit and has the smallest power supply time may be determined as the representative value.

  According to the above configuration, by setting a threshold value for the reception failure probability, a setting value for the beacon signal period at which the beacon reception failure probability is equal to or less than the threshold value is set, resulting in low power consumption and prevention of a decrease in throughput. it can.

  In addition, a threshold value of a ratio between a power supply time and a stop time is set in the storage unit, the beacon signal period of the AP received by the wireless unit is measured a plurality of times by the measurement unit, and a measurement result is measured by the AP. The information is stored in the storage unit, and the setting value of the beacon signal period and the ratio of the power supply time and the stop time with respect to the setting candidate value are obtained from the results of the plurality of measurements, and the power supply time and the stop The setting candidate value having a time ratio smaller than the threshold value stored in the storage unit may be determined as the representative value.

  In addition, a threshold value of a ratio between a power supply time and a stop time is set in the storage unit, the beacon signal period of the AP received by the wireless unit is measured a plurality of times by the measurement unit, and a measurement result is measured by the AP. The information is stored in a storage unit, and the setting candidate value of the beacon signal period, the reception failure probability with respect to the setting candidate value, and the ratio of the supply time and the stop time of the power supply are obtained from the results of the plurality of measurements. The setting candidate value in which the ratio between the supply time and the stop time is smaller than the threshold stored in the storage unit and the reception failure probability is the smallest may be determined as the representative value.

  Further, when determining a representative value from the setting candidate values, if the ratio of the power supply time and the stop time is not less than or equal to a threshold for all the setting candidate values, the power supply time The setting candidate value that becomes the minimum may be determined as the representative value.

  According to these configurations, by setting a threshold value of the ratio between the power supply time and the stop time, the set value of the beacon signal cycle in which the ratio of the power supply time and the stop time is equal to or less than the threshold value is set. Low power consumption and low throughput can be prevented.

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

(Embodiment 1)
With reference to FIG. 1, the structure of the communication system and communication apparatus in Embodiment 1 of this invention is demonstrated. FIG. 1A is a block diagram showing a concept of a communication system in the present embodiment. This communication system includes access points AP [1], AP [2] and a station STA [1]. AP [1] constitutes AP [1] area 1 which is the reach range of the beacon signal transmitted by AP [1], and AP [2] is the reach range of the beacon signal transmitted by AP [2]. AP [2] area 2 is configured. In addition, information on AP [1] and AP [2] is stored in STA [1] as a profile as shown in FIG.

  FIG. 2 is a block diagram illustrating the concept of STA [1]. The STA [1] includes an antenna unit 3 that transmits and receives a radio signal, and a radio unit 4 that is supplied with a high-frequency signal input / output from the antenna unit 3. The radio unit 4 includes a high frequency unit 5 that converts a high frequency signal into a baseband signal, a signal processing unit 6 that modulates and demodulates the baseband signal, and a measurement unit 7 that measures the beacon signal period of the received AP beacon signal. The STA [1] further includes a storage unit 8 that stores values measured by the measurement unit 7, a power supply unit 10 that supplies power to the STA [1], a high-frequency unit 5, a signal processing unit 6, and a measurement unit 7. The wireless unit 4 includes an SW unit 11 that performs ON / OFF control of power supply, and a wireless unit 4, a storage unit 8, and a control unit 9 that controls the SW unit 11.

  When the STA [1] is movable and the STA [1] exists in the AP [1] area 1, the antenna unit 3, the high frequency unit 5, the signal processing unit 6, and the control unit 9 A beacon signal of AP [1] and a data signal to STA [1] transmitted from AP [1] are received. In addition, the STA [1] transmits a data signal to the AP [1] by the control unit 9, the signal processing unit 6, the high frequency unit 5, and the antenna unit 3. Thereby, STA [1] is connected to AP [1] and performs data communication. When STA [1] exists in AP [2] area 2, the AP [2] beacon signal is received and connected to AP [2] for data communication.

  When STA [1] is connected to AP [1], it receives the beacon signal of AP [1] using the antenna unit 3, the high frequency unit 5, and the signal processing unit 6, and instructs the control unit 9 to Thus, the beacon signal cycle received by the measurement unit 7 is measured, and stored in the storage unit 8 as a profile (see FIG. 1A) in association with the ESSID of AP [1]. Similarly, when STA [1] is connected to AP [2], it receives the beacon signal of AP [2], measures the received beacon signal period, and sets the ESSID of AP [2]. The information is stored in the storage unit 8 as a profile.

  Next, the operation of STA [1] will be described with reference to FIG. FIG. 3 is a flowchart showing an operation in STA [1] of the first embodiment.

  When the STA [1] moves into the AP [1] area 1, the STA [1] receives the beacon signal of the AP [1] and performs frame exchange for connection with the AP [1]. It is connected and data communication can be performed (step S1). Next, STA [1] uses the control unit 9 to check whether the beacon setting value of AP [1] is stored in the storage unit 8 (step S2).

  In STA [1], if the beacon setting value of AP [1] is stored in the storage unit 8, the control unit 9 uses the beacon setting value of AP [1] stored in the storage unit 8, The SW unit 11 is controlled to control power ON / OFF of the wireless unit 4. Thereby, STA [1] enters the Wake state when receiving the beacon signal of AP [1], and performs the sleep mode operation in which the STA [1] enters the Sleep state at other times (step S3).

  In STA [1], if the beacon set value of AP [1] is not stored in the storage unit 8, the beacon signal is received using the antenna unit 3, the high frequency unit 5, and the signal processing unit 6, and the control unit 9 The beacon signal period received by the measurement unit 7 is measured according to the instruction, and the beacon set value is stored as a profile (see FIG. 1A) in the storage unit 8 in association with the ESSID of AP [1] (step S4). .

  Further, when the STA [1] leaves the AP [1] area 1, the STA [1] ends the data communication with the AP [1]. However, the storage unit 8 of the STA [1] stores the beacon setting value of the AP [1]. Is stored as profile information. When the STA [1] moves again into the AP [1] area 1, the control unit 9 of the STA [1] uses the AP [1] beacon setting value stored in the storage unit 8 to switch the SW unit. 11 to turn on / off the power of the wireless unit 4. As a result, when receiving the beacon signal of AP [1], the Wake state is entered, and the operation of entering the Sleep state is repeated at other times. Therefore, once the beacon signal period of AP [1] is measured in STA [1] and the beacon signal period of AP [1] is stored as the beacon setting value, the sleep mode is not performed without re-measurement. Perform the operation.

  As a specific example, as shown in FIG. 4, the BI is 100 ms, the beacon signal length is 1 ms, and the actual beacon signal arrival time from AP [1] to STA [1] is 0 ms, The power consumption in STA [1] when monotonically increasing with respect to the reference time by BI, such as 110 ms and 220 ms, is calculated. The time for X1 and X2 is sufficiently small with respect to Δt, so it is ignored, the time for WakeON is every 110 ms, the time for Δt is 1 ms equal to the reception time of the beacon signal, the time for WakeOFF is added to the time for WakeON to add Δt The obtained values are 1 ms, 111 ms, and 221 ms.

In STA [1], assuming that the power consumption when the power is turned off is sufficiently small and negligible compared to the power consumption when the power is turned on, the power consumption of STA [1] becomes the value of ΣΔt, which is the total time of Wake time. Proportional. In the case of FIG. 4, beacon signal B in STA [1]
The total time for receiving from 1 to the beacon signal B11 is ΣΔt = 1 + 1.
It becomes. On the other hand, in the case shown in FIG. 18 which is a conventional example, the total time for receiving from beacon signal B1 to beacon signal B11 in STA [1] is ΣΔt = 1 + 1.
1 + 21 +... + 101 = 561. Therefore, if the method of Embodiment 1 is used, the power consumption at the time of standby in STA [1] can be reduced to about 1/50 of the conventional example.

  In the above example, the power consumption in STA [1] when the beacon signal arrival time from AP [1] to STA [1] monotonously increases with respect to the reference time by BI is shown. Even if the arrival time is other than that case, the effect of reducing the power consumption can be obtained in STA [1].

(Embodiment 2)
In the second embodiment, when the measured beacon signal cycle is not a constant value in STA [1], the minimum value is obtained as a representative value from the measured value and set to the beacon setting value.

  The concept of the communication system and the communication device in the present embodiment is the same as that in FIG. The block diagram showing the concept of STA [1] is the same as FIG. Therefore, reference is made to FIGS. 1 and 2 in the following description. An example of the profile of STA [1] in this embodiment is shown in FIG. In the profile of FIG. 5, the beacon signal measurement count is set to 100 and the measurement result representative value is set to the minimum value as the initial setting value.

  The operation of STA [1] in this embodiment will be described with reference to FIG. FIG. 6 is a flowchart showing the operation of STA [1] of the present embodiment.

  When STA [1] moves into AP [1] area 1, STA [1] receives the beacon signal of AP [1] and performs frame exchange for connection with AP [1]. It is connected to AP [1] and data communication can be performed (step S1). Next, STA [1] uses the control unit 9 to check whether the beacon setting value of AP [1] is stored in the storage unit 8 (step S2).

  In STA [1], if the storage unit 8 stores the beacon setting value of AP [1], the control unit 9 uses the AP [1] beacon setting value stored in the storage unit 8 to switch The unit 11 is controlled to control ON / OFF of the power of the wireless unit 4. Thereby, STA [1] enters the Wake state when receiving the beacon signal of AP [1], and performs the sleep mode operation in which the STA [1] enters the Sleep state at other times (step S3).

  In STA [1], if the beacon setting value of AP [1] is not stored in the storage unit 8, the control unit 9 measures the beacon signal set in the profile (FIG. 5) stored in the storage unit 8. The beacon signal period of AP [1] is measured by the number of times. The profile of STA [1] stores a value of 100 times as the number of times the beacon signal is measured. Therefore, the beacon signal is received 100 times using the antenna unit 3, the high frequency unit 5 and the signal processing unit 6, and the control unit 9, the measurement unit 7 measures the beacon signal period received 100 times, and associates it with the ESSID of AP [1] and stores it in the storage unit 8 as a profile (FIG. 5) (step S10).

  Next, since the representative value of the profile (FIG. 5) is set to the minimum value, the control unit 9 obtains the minimum value from the measurement result measured in step S10 and sets it as the beacon setting value (step S11). ).

  As a specific example, FIG. 7 shows a result of measuring the beacon signal period of AP [1] by STA [1] in step S10. From the measurement result of FIG. 7, the control unit 9 of the STA [1] stores the minimum value of 90 ms as the beacon setting value in the storage unit 8 (step S11). Next, since the value of 90 ms is stored as the beacon setting value of AP [1] in the storage unit 8, the control unit 9 uses the value of 90 ms to control the SW unit 11 to turn on the power of the wireless unit 4. / OFF control is performed. As a result, STA [1] enters the Wake state in order to receive the beacon signal of AP [1] every 90 ms of the beacon setting value, continues the Wake state until the time when the beacon signal reception ends, and after the reception of the beacon signal ends. The sleep mode operation for entering the sleep state is performed (step S3).

  When beacon signals are transmitted from AP [1] to STA [1] with the same distribution as in FIG. 7 for the next 100 times, the storage unit 8 stores 90 ms as the beacon setting value of AP [1]. Is set, and by using this value to perform the sleep mode operation, STA [1] changes from the sleep state to the wake state with a value of 90 ms. Thereby, a beacon signal can be received reliably and power consumption can be reduced most.

  On the other hand, when the STA [1] operates in the sleep mode using the BI value of 100 ms as in the conventional example, the STA [1] receives four beacon signals that arrive at a time interval of 90 ms. become unable. In addition, since the arrival time of the beacon signal cannot be predicted, when the beacon signal is surely received, the operation in the sleep mode cannot be performed.

  As a result, the relationship between the beacon signal transmitted by AP [1], the power consumption in STA [1], and the sleep mode, as shown in FIG. 17 in the conventional example, is as shown in FIG. In the second embodiment, it can be seen that the reception probability of a beacon signal in STA [1] is higher than in the conventional example, and the power consumption can be further reduced.

  Further, when STA [1] leaves the AP [1] area 1, the data communication with the AP [1] is terminated, but the storage unit 8 of the STA [1] stores the beacon setting value of the AP [1]. Stored as profile information. When STA [1] moves into AP [2] area 2, after receiving the beacon signal of AP [2] according to the flow of FIG. 6 and performing frame exchange for connection with AP [2], It is connected to AP [2] and data communication can be performed (step S1). Next, STA [1] uses the control unit 9 to check whether the beacon setting value of AP [2] is stored in the storage unit 8 (step S2).

  In STA [1], if the storage unit 8 stores the beacon setting value of AP [2], the control unit 9 uses the AP [2] beacon setting value stored in the storage unit 8 to switch The unit 11 is controlled to control ON / OFF of the power of the wireless unit 4. As a result, the STA [1] enters the Wake state when receiving the beacon signal of the AP [2], and performs the sleep mode operation in which the STA [1] enters the Sleep state at other times (step S3).

  In STA [1], if the beacon setting value of AP [2] is not stored in the storage unit 8, the control unit 9 sets the AP [2] by the value of the beacon signal measurement count stored in the storage unit 8. Measure the beacon signal period. The profile of STA [1] (FIG. 5) stores a value of 100 times as the number of times the beacon signal is measured. Therefore, the beacon signal is received 100 times using the antenna unit 3, the high frequency unit 5 and the signal processing unit 6. Then, the beacon signal cycle received by the measurement unit 7 is measured 100 times according to the instruction from the control unit 9, and is stored as a profile (FIG. 5) in the storage unit 8 in association with the ESSID of AP [2] (step S10).

  Next, since the representative value of the profile (FIG. 5) in the storage unit 8 is set to the minimum value, the control unit 9 obtains the minimum value from the measurement result measured in step S10 and sets it as the set value ( Step S11).

  As a result, the beacon setting values of AP [1] and AP [2] are stored in the storage unit 8 as profiles (FIG. 5) in STA [1]. Therefore, in a state where STA [1] moves between AP [1] area 1 and AP [2] area 2 and repeats connection and disconnection with respect to AP [1] and connection and disconnection with respect to AP [2]. However, STA [1] can operate in the sleep mode without re-measuring the beacon signal period of AP [1] and AP [2]. Thereby, the time for measuring the beacon signal period can be reduced, and the power consumption can be reduced.

  As a specific example, in STA [1], the time taken to measure one beacon signal period is about 100 ms. When 100 measurements are performed, the beacon signal period of AP [1] is measured. The total time taken for is 10 s. Similarly, the time taken for STA [1] to measure the AP [2] beacon signal period is 10 s. Assuming that STA [1] is connected to AP [1], AP [1] is disconnected and connected to AP [2], and STA [1] is connected to AP [2] after 100 s. It is assumed that the operation of disconnecting from AP [2] and connecting to AP [1] is repeated from the state of being connected. In this case, STA [1] repeats the connection between AP [1] and AP [2] every 100 s, but only needs to measure the beacon signal period of AP [1] and AP [2] only once. Therefore, the measurement time other than the first connection is 0 s.

  On the other hand, in STA [1], when the measured beacon signal period of each AP is not stored as a profile (FIG. 5), STA [1] uses the time of 10s every 100s, and AP [1] or AP The beacon signal cycle of [2] is measured. Therefore, in STA [1], the wake time for consuming 100 mW in 100 s is about 10 s, and the time for consuming 1 mW in power and sleeping is 90 s, so the total power consumption of 100 s Becomes (1000 + 90) = 1090 mWs.

  In Embodiment 2, STA [1] consumes 1 mW of power and sleeps for 100 s, so the total power consumption is 100 mWs. As described above, in the second embodiment, the power consumption for measuring the beacon signal is 1/11 compared to the case where the measured beacon signal period of each AP is not stored in the profile (FIG. 5).

  In this embodiment, in STA [1], an example is a method of measuring the beacon signal period of AP [1] and setting the minimum value as the beacon setting value of AP [1] as a representative value of the beacon signal period. However, the same effect can be obtained even if a value other than the minimum value is used as the representative value.

(Embodiment 3)
In the third embodiment, in STA [1], when the measured beacon signal period is not a constant value, the mode value is obtained as a representative value from the measured value and set to the beacon setting value.

  The concept of the communication system and the communication device in the present embodiment is the same as that in FIG. The block diagram showing the concept of STA [1] is the same as FIG. Therefore, reference is made to FIGS. 1 and 2 in the following description. An example of the profile of STA [1] in the present embodiment is almost the same as that in FIG. However, in the profile of FIG. 5, the mode value is set as the representative value of the measurement result.

  The operation of STA [1] in the present embodiment is basically the same as the operation shown in the flowchart of FIG. That is, the same applies to steps S1, S2, S3, and S10, except that in step S11, the mode value is obtained from the measurement result measured in step S10 and set to the set value.

  As a specific example, FIG. 9 shows the result of STA [1] measuring the AP [1] beacon signal period in step S10. From the measurement result of FIG. 9, the control unit 9 of the STA [1] stores the mode value of 110 ms as the beacon setting value in the storage unit 8 (step S11). Next, the control unit 9 controls the SW unit 11 using the value of 110 ms stored as the beacon setting value of AP [1] in the storage unit 8 to control the power on / off of the wireless unit 4. I do. As a result, STA [1] enters the Wake state in order to receive the beacon signal of AP [1] every 110 ms of the beacon setting value, continues the Wake state until the beacon signal reception end time, and after receiving the beacon signal, Sleep The sleep mode operation to enter the state is performed (step S3).

  When a beacon signal is transmitted from AP [1] to STA [1] with the same distribution as in FIG. 9 for the next 100 times, the storage unit 8 stores 110 ms as the beacon setting value of AP [1]. Therefore, the sleep mode operation is performed using this value, and STA [1] changes from the sleep state to the wake state with a value of 110 ms. At this time, a beacon signal transmitted at an interval of 90 ms from AP [1] to STA [1] cannot be received by STA [1]. Therefore, the reception failure probability in STA [1] is 1%. In STA [1], the remaining 99% can receive a beacon signal, and ΣΔt, which is the total time when the power is turned on, is ΣΔt = 1 + 1 +... + 1 = 99 ms.

On the other hand, when the operation of the sleep mode is performed using the BI value of 100 ms as in the conventional example, STA [1] cannot receive one beacon signal that arrives in 90 ms. Therefore, even in the conventional example, the reception failure probability is 1%. However, in the conventional example, in STA [1], the power is turned on in the time of 100 ms of BI, so ΣΔt, which is the total time when the power is turned on, is ΣΔt = 11 + 11 +... + 11 = 1089 ms.

  As described above, by using the method of Embodiment 3, the power consumption during standby in STA [1] can be reduced to about 1/11 compared to the conventional example. Also in the present embodiment, when STA [1] repeatedly connects and disconnects with respect to AP [1] and AP [2] alternately as described above, as in the second embodiment, the conventional technique is used. Power consumption is reduced compared to the example.

(Embodiment 4)
In the fourth embodiment, in STA [1], when the reception failure probability becomes equal to or higher than the threshold value during the sleep mode operation, the sleep mode is canceled, the beacon signal period is measured again, and the beacon setting value is reset. .

  The concept of the communication system and the communication device in the present embodiment is the same as that in FIG. The block diagram showing the concept of STA [1] is the same as FIG. Therefore, reference is made to FIGS. 1 and 2 in the following description. An example of the profile of STA [1] in the present embodiment is substantially the same as that shown in FIG. However, in this embodiment, it is assumed that a value of 3 is set as the threshold value of the reception failure probability in the profile of FIG.

  Next, the operation of STA [1] will be described with reference to FIG. FIG. 10 is a flowchart showing the operation of STA [1] in the present embodiment. Steps S1, S2, S3, S10, and S11 are the same flow as the operation shown in FIG.

  In the present embodiment, after step S3, it is determined whether the reception failure probability is equal to or higher than a threshold (step S12). If the reception failure probability is equal to or higher than the threshold, STA [1] again measures the beacon signal period of AP [1] (step S10), obtains the minimum value as a representative value, and sets it to the set value (step S11). ). Step S13, which is performed when the reception failure probability is not equal to or higher than the threshold, shows the operation in the fifth embodiment described later in the same drawing for the sake of convenience. In the present embodiment, the process directly returns to step S1.

  As a specific example, FIG. 11 shows the result of STA [1] measuring the beacon signal period of AP [1] in step S10. From the measurement result of FIG. 11, the control unit 9 of the STA [1] stores the minimum value of 100 ms as the beacon setting value in the storage unit 8 (step S11).

  When a beacon signal is always transmitted from AP [1] to STA [1] with the same distribution as in FIG. 11, the storage unit 8 stores a value of 100 ms as the beacon setting value of AP [1]. Therefore, the control unit 9 controls the SW unit 11 using a value of 100 ms, and controls the power on / off of the wireless unit 4. Therefore, STA [1] enters the Wake state to receive the beacon signal of AP [1] every 100 ms of the beacon setting value, continues the Wake state until the time when the beacon signal reception ends, and after the beacon signal reception ends, The sleep mode operation to enter the state is performed (step S3).

  However, when the beacon signal cycle from AP [1] to STA [1] changes from the state shown in FIG. 11 to the state shown in FIG. 7, four times out of 100 from AP [1] in STA [1]. Since a beacon signal with a beacon signal period of 90 ms is transmitted, in STA [1], the beacon signal cannot be received four times out of 100 times. In STA [1], a value of 3 is set as the threshold value of the reception failure probability (step S12), so STA [1] again measures the beacon signal period of AP [1] (step S10). Then, the minimum value is obtained as the representative value and set to the set value (step S11).

  As a result, even if the distribution of the beacon signal period transmitted from AP [1] to STA [1] changes due to factors such as changes in the environment of AP [1] area 1, beacon signals in STA [1] Can be suppressed to a certain level or less, and STA [1] has the effect of reducing power consumption. In addition, if the threshold value of the beacon signal reception failure probability is set to 1 in STA [1], remeasurement and resetting are performed when the beacon signal of AP [1] cannot be received even once, so STA [1] It is possible to minimize the reception failure probability of the beacon signal of AP [1].

(Embodiment 5)
In the fifth embodiment, in STA [1], when ΣΔt that is the total time of the wake time becomes equal to or larger than the threshold value during the sleep mode operation, the beacon signal period is measured again and the beacon setting value is reset. The

The concept of the communication system and the communication device in the present embodiment is the same as that in FIG. The block diagram showing the concept of STA [1] is the same as FIG. Therefore, reference is made to FIGS. 1 and 2 in the following description. An example of the profile of STA [1] in the present embodiment is almost the same as that in FIG. However, in the present embodiment, it is assumed that a value of 1400 ms is set as the threshold of ΣΔt in the profile of FIG.

  The operation of STA [1] in the present embodiment is shown in the flowchart of FIG. Steps S1, S2, S3, S10, S11, and S12 are the same as the operations described in the fourth embodiment, and a description thereof is omitted.

In step S12, if the reception failure probability is not greater than or equal to the threshold, it is determined whether or not ΣΔt is greater than or equal to the threshold (step S13). If ΣΔt is not greater than or equal to the threshold value, the process returns to step S1 and the operation is repeated. If ΣΔt is greater than or equal to the threshold value, STA [1] again measures the beacon signal period of AP [1] (step S10), finds the minimum value as a representative value, and sets it as the set value (step S11). .

  As a specific example, it is assumed that the result of measuring the beacon signal period of AP [1] by STA [1] in step S10 is the same as that in FIG. From the measurement result of FIG. 7, the control unit 9 of the STA [1] stores the minimum value of 90 ms as the beacon setting value in the storage unit 8 (step S11).

  When a beacon signal is always transmitted from AP [1] to STA [1] with the same distribution as in FIG. 7, the beacon setting value of AP [1] is stored in storage unit 8 in STA [1]. Since the value of 90 ms is stored, the control unit 9 controls the SW unit 11 using the value of 90 ms to control ON / OFF of the power supply of the wireless unit 4. As a result, STA [1] enters the Wake state in order to receive the beacon signal of AP [1] every 90 ms of the installation value, continues the Wake state until the beacon signal reception end time, and after the beacon signal reception ends, Sleep The sleep mode operation to enter the state is performed (step S3).

However, when the beacon signal cycle from AP [1] to STA [1] changes from FIG. 7 to FIG. 11, in STA [1], the time during which the beacon signal is not received is long even in the Wake state. Therefore, the time of ΣΔt, which is the total time of the Wake state, also becomes longer. That is, since the beacon setting value is set to 90 ms in STA [1], the beacon signal cycle transmitted from AP [1] to STA [1] is 60 times for 100 ms, 30 times for 110 ms, and 10 for 120 ms. Σt = (100−90) × 60 + (1
10−90) × 30 + (120−90) × 10 = 1500 ms, which is larger than 1400 ms, which is the threshold of ΣΔt. Therefore, STA [1] again measures the beacon signal period of AP [1] (step S10), finds the minimum value as a representative value, and sets it to the set value (step S11).

  In this way, even if the distribution of the beacon signal period transmitted from AP [1] to STA [1] changes due to factors such as the environment of AP [1] area 1 changing, Wake in STA [1] The value of ΣΔt, which is the total time, can be suppressed to a certain level or less, and the effect of reducing power consumption can be obtained in STA [1].

(Embodiment 6)
In Embodiment 6, in STA [1], when the measured beacon signal cycle is not a constant value, the reception failure probability prediction value and the ΣΔt prediction value for each setting candidate value are obtained from the measurement value, and the reception failure probability A setting candidate value having a predicted value that is less than or equal to a threshold and has the smallest ΣΔt predicted value is configured to be set as a beacon set value.

  The concept of the communication system and the communication device in the present embodiment is the same as that in FIG. The block diagram showing the concept of STA [1] is the same as FIG. Therefore, reference is made to FIGS. 1 and 2 in the following description. An example of the profile of STA [1] in the present embodiment is almost the same as that in FIG. However, in the present embodiment, it is assumed that a value of 5 is set as the threshold of the reception failure probability and a beacon signal reception priority mode is set as the mode in the profile of FIG.

  The operation of STA [1] in the present embodiment is shown in the flowchart of FIG. Steps S1, S2, S3, S10, S12, and S13 are the same as the operations shown in FIG.

In step S10, STA [1] measures the beacon signal period of AP [1], and in step S20, the control unit 9 calculates the reception failure probability predicted value and ΣΔt predicted value for each setting candidate value from the measurement result. Calculate the relationship. Next, it is determined whether or not the beacon signal reception priority mode is set (step S21). Here, in the beacon signal reception priority mode, a setting candidate value is selected from the result of step S20 where the reception failure probability prediction value is smaller than the threshold value 5 which is the threshold value of the reception failure probability and the ΣΔt prediction value is the smallest. And set as a beacon set value (step S22). Steps S23 and S24 that proceed when the mode is not the beacon signal reception priority mode are shown in the same drawing for the sake of convenience in later-described Embodiment 7, and the process directly proceeds to Step S3 in the present embodiment.

  As a specific example, in step S10, STA [1] measures the beacon signal cycle of AP [1] 100 times, and in step S20, the control unit 9 determines the reception failure probability for each setting candidate value from the measurement result. The result of calculating the relationship between the predicted value and the ΣΔt predicted value is shown in FIG. Since the relationship between the reception failure probability prediction value and the ΣΔt prediction value for each setting candidate value can be obtained from the measurement result by the method shown in FIG. 18 or FIG. 4, description thereof is omitted here.

Next, in STA [1], it is determined whether or not the beacon signal reception priority mode is set (step S21). Here, in the beacon signal reception priority mode, the reception failure probability prediction value is smaller than the threshold value 5 which is the threshold value of the reception failure probability and the ΣΔt prediction value is the smallest in STA [1] based on the result of FIG. A setting candidate value is selected and set as a beacon setting value (step S22). In the example of FIG. 13, the setting candidate values whose predicted reception failure probability is smaller than the threshold value of 5 are 80 ms, 90 ms, and 100 ms. When the setting candidate value is 80 ms, the ΣΔt predicted value is 3000 ms, when the setting candidate value is 90 ms, the ΣΔt predicted value is 2000 ms, and when the setting candidate value is 100 ms, the ΣΔt predicted value is 1000 ms. . Accordingly, in this case, 100 ms is selected as the set value candidate value and set as the beacon set value (step S22).

  In STA [1], the threshold value of the reception failure probability can be changed. If 1 is set as the threshold value of the reception failure probability, the beacon setting value is selected so that the failure probability of receiving the beacon signal becomes zero. Regarding the data communication from AP [1] to STA [1], when moving images and audio data are communicated, a state in which the delay is minimized by setting a beacon setting value at which the threshold of the reception failure probability is 1 is set. realizable.

(Embodiment 7)
In Embodiment 7, in STA [1], when the measured beacon signal period is not a constant value, a reception failure probability prediction value and a ΣΔt prediction value for each setting candidate value are obtained from the measurement value, and ΣΔt is a threshold value. In the following, it is configured to set a setting value that minimizes the reception failure probability.

The concept of the communication system and the communication device in the present embodiment is the same as that in FIG. The block diagram showing the concept of STA [1] is the same as FIG. Therefore, reference is made to FIGS. 1 and 2 in the following description. An example of the profile of STA [1] in the present embodiment is almost the same as that in FIG. However, in the present embodiment, it is assumed that the value of 2500 is set as the threshold of ΣΔt and the power consumption priority mode is set as the mode in the profile of FIG.

  The operation of STA [1] in the present embodiment is shown in the flowchart of FIG. Steps S1, S2, S3, S10, S12, S13, and S20 are the same as the operations described in the sixth embodiment, and a description thereof is omitted.

In step S21, if it is not the beacon signal reception priority mode, it is the power consumption priority mode (step S23), so from the result of step S20, the ΣΔt predicted value is smaller than the threshold of ΣΔt and the reception failure probability predicted value is the smallest. A setting candidate value is selected and set as a beacon setting value (step S24).

  A specific example will be described using the example shown in FIG. That is, in step S10, STA [1] measures the beacon signal cycle of AP [1] 100 times, and the control unit 9 calculates the reception failure probability predicted value and the ΣΔt predicted value for each setting candidate value from the measurement result. This will be described using the result of calculating the relationship (step S20). Since the relationship between the reception failure probability prediction value and the ΣΔt prediction value for each setting candidate value can be obtained from the measurement result by the method shown in FIG. 18 or FIG. 4, description thereof is omitted here.

Next, in STA [1], it is determined whether it is the beacon signal reception priority mode or the low power consumption priority mode (step S21). Here, if it is not the beacon signal reception priority mode, it is the power consumption priority mode (step S23), so in STA [1] from the result of FIG. A setting candidate value with the smallest probability prediction value is selected and set as a beacon setting value (step S24). In the example of FIG. 13, the threshold prediction value of ΣΔt is 2500 m.
Setting candidate values smaller than s are 90 ms and 100 ms. When the setting candidate value is 90 ms, the reception failure probability prediction value is 1. When the setting candidate value is 100 ms, the reception failure probability prediction value is 4, and in this case, 90 ms is selected as the setting candidate value, and the beacon setting is It is set as a value (step S24).

In STA [1], the threshold of ΣΔt can be changed, and the threshold of ΣΔt is 1000.
If ms is set, the set value is selected so that the power consumption is minimized in the case of FIG. For data communication between AP [1] and STA [1], if STA [1] is a mobile terminal that operates on a battery and wants to reduce power consumption and increase standby time, Σ
By setting a small value as the threshold value of Δt, it is possible to realize a state where the power consumption is the smallest.

If 500 ms is set as the threshold of ΣΔt in STA [1], there is no setting candidate value in which the value of ΣΔt is smaller than 500 ms in the example of FIG. 13, and therefore ΣΔt is 1000 ms as the closest value. A setting candidate value is selected, and 100 ms is set as the beacon setting value.

  The STA of the present invention can sufficiently achieve the effect of reducing power consumption in accordance with the AP and characteristics of the connection destination and the surrounding environment, and is particularly useful for STAs used as mobile terminals.

(A) is a block diagram which shows the concept of the communication system in embodiment of this invention, (b) is a figure which shows the example of the profile which shows the information of AP memorize | stored in STA. The block diagram which shows the structure of STA [1] of the embodiment The flowchart which shows operation | movement of STA [1] in Embodiment 1 of this invention. The figure which shows the relationship between the power consumption of this STA [1], and Sleep mode The figure which shows the profile memorize | stored in STA [1] in Embodiment 2 of this invention Flow chart showing operation of STA [1] The figure showing the result of having measured the beacon signal period in the same STA [1] The figure which shows the relationship between the power consumption of this STA [1], and Sleep mode The figure showing the result of having measured the beacon signal period in STA [1] in Embodiment 3 of this invention. The flowchart which shows operation | movement of STA [1] in Embodiment 4 of this invention. The figure showing the result of having measured the beacon signal period in the same STA [1] The flowchart which shows operation | movement of STA [1] in Embodiment 6 of this invention. The figure showing the relationship between the setting candidate value, reception failure probability predicted value, and ΣΔt predicted value in Embodiment 6 The figure which shows the relationship between the power consumption of STA and sleep mode in an ideal case The block diagram which shows the concept of the communication system and communication apparatus in the area of AP [1] in a prior art example. The figure which shows the data communication in the area of the same AP [1] The figure which shows the relationship between the power consumption of STA of a prior art example, and Sleep mode The figure which shows the relationship between the power consumption of STA of another prior art example, and Sleep mode

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Area of AP [1] Area of AP [2] 3 Antenna part 4 Radio part 5 High frequency part 6 Signal processing part 7 Measurement part 8 Storage part 9 Control part 10 Power supply part 11 SW part AP [1], AP [2 ] Access point STA [1], STA [2], STA [3] Station

Claims (12)

A plurality of access points (hereinafter abbreviated as “AP”) and stations (hereinafter abbreviated as “STA”) selectively connected to any of the plurality of APs. In the STA used in a wireless LAN system that transmits a beacon signal including its own information in the STA,
A wireless unit that receives the beacon signal of the AP;
A control unit that controls the entire STA;
A power supply for supplying power to the STA;
A SW unit for supplying and stopping power from the power unit to the radio unit;
A measurement unit for measuring a beacon signal period of the AP received by the wireless unit;
A storage unit for storing the measured beacon signal period,
The control unit stores a measurement result of the AP beacon signal cycle by the measurement unit together with the AP information in the storage unit, and based on the stored beacon signal cycle, the SW unit controls the radio unit. STA characterized by controlling supply and stop of power supply. For each AP to be connected, measure the beacon signal period of the AP received by the wireless unit by the measurement unit, and store the measurement result in the storage unit together with the AP information for each AP,
2. The STA according to claim 1, wherein the control unit controls the SW unit based on the beacon signal cycle stored for the connected AP to supply and stop power to the radio unit. The beacon signal period of the AP received by the wireless unit is measured a plurality of times by the measuring unit,
3. The control unit according to claim 1, wherein the control unit determines a representative value from the plurality of measurement data, and stores the representative value in the storage unit as the AP beacon signal cycle setting value together with the AP information. STA.   The STA according to claim 3, wherein a minimum value is selected from the plurality of measurement data and determined as the representative value.   The STA according to claim 3, wherein a mode value is selected from the plurality of measurement data and determined as the representative value. A threshold value for the failure probability of receiving a beacon signal is set in the storage unit,
Based on the set value of the beacon signal cycle, the control unit controls the SW unit to supply and stop the power to the radio unit. As a result, the reception failure probability is stored in the storage unit. When the threshold value is exceeded, the power supply to the wireless unit is canceled, the AP beacon signal period received by the wireless unit is remeasured by the measuring unit, and the measurement result is set as a set value again along with the AP information. The STA according to claim 1, which is stored in the storage unit. A threshold value of a ratio of power supply time and stop time is set in the storage unit,
Based on the set value of the beacon signal cycle, the control unit controls the SW unit to supply and stop the power to the wireless unit. As a result, the ratio between the power supply time and the stop time is the storage unit. When the threshold value stored in the wireless unit is exceeded, the power supply to the wireless unit is canceled, the beacon signal period of the AP received by the wireless unit is measured again by the measuring unit, and the measurement result is set again to the set value. The STA according to claim 1, wherein the STA is stored together with the AP information in a storage unit. A threshold value for the failure probability of receiving a beacon signal is set in the storage unit,
The beacon signal cycle of the AP received by the wireless unit is measured a plurality of times by the measurement unit, the measurement result is stored in the storage unit together with the information of the AP, and the setting of the beacon signal cycle is determined from the measurement result obtained a plurality of times. 4. The candidate value and a reception failure probability for the setting candidate value are obtained, and the setting candidate value whose obtained reception failure probability is smaller than the threshold stored in the storage unit is determined as the representative value. STA. A threshold value for the failure probability of receiving a beacon signal is set in the storage unit,
The beacon signal period of the AP received by the wireless unit is measured a plurality of times by the measurement unit, and the measurement result is stored in the storage unit together with the AP information,
From the results of the multiple measurements, determine the beacon signal cycle setting candidate value, the reception failure probability for the setting candidate value, and the ratio of the power supply time and the stop time,
8. The STA according to claim 3, 6, or 7, wherein the setting candidate value is determined as the representative value, wherein the reception failure probability is smaller than the threshold value stored in the storage unit and the power supply time is minimized. . A threshold value of a ratio of power supply time and stop time is set in the storage unit,
The beacon signal period of the AP received by the wireless unit is measured a plurality of times by the measurement unit, and the measurement result is stored in the storage unit together with the AP information,
From the results of the plurality of measurements, determine the setting candidate value of the beacon signal period, and the ratio of the power supply time and the stop time for the setting candidate value,
The STA according to claim 3, wherein the setting candidate value that is smaller than the threshold value stored in the storage unit is determined as the representative value. A threshold value of a ratio of power supply time and stop time is set in the storage unit,
The beacon signal period of the AP received by the wireless unit is measured a plurality of times by the measurement unit, and the measurement result is stored in the storage unit together with the AP information,
From the results of the multiple measurements, determine the beacon signal cycle setting candidate value, the reception failure probability for the setting candidate value, and the ratio of the power supply time and the stop time,
8. The setting candidate value is determined as the representative value, wherein the ratio between the power supply time and the stop time is smaller than the threshold stored in the storage unit and the reception failure probability is the smallest. STA described. When determining a representative value from the setting candidate values, if the ratio of the power supply time and the stop time is not less than or equal to a threshold for all the setting candidate values, the power supply time is minimized. The STA according to claim 10 or 11, wherein the setting candidate value is determined as the representative value.

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