JP2007221628A - Radio lan system and terminal - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a radio LAN system 10 in which a more convenient power saving operation can be achieved and the power save operation can be surely performed. <P>SOLUTION: Radio LAN terminals 20 possessed by a radio LAN system 10 includes: a radio LAN terminal 202 storing wake-up intervals during power saving operation based on radio LAN standards in association with the period of time to apply the relevant wake-up intervals; a radio LAN terminal 204 extracting and outputting wake-up intervals corresponding to the present date/time from the radio LAN terminal 202; a radio LAN terminal 207 determining whether or not the power saving operation can be performed; and a radio LAN terminal 205 causing the radio LAN terminal 204 to output the wake-up intervals corresponding to the present date/time when the power saving operation can be performed, and performing the power saving operation at the output wake-up intervals. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a wireless LAN terminal that performs wireless communication based on a wireless LAN standard and a wireless LAN system including the wireless LAN terminal.

  Non-Patent Document 1 discloses a power saving function in a wireless LAN system. According to Non-Patent Document 1, the wireless LAN terminal transmits a message indicating that the access point shifts to the power saving mode, and starts a doze mode operation that operates with a minimum necessary function except for receiving a beacon. To do. When the access point that has received the message receives communication data addressed to the wireless LAN terminal that has transmitted the message, the access point temporarily holds the communication data therein. Then, the access point stores in the beacon the fact that there is communication data held and the identification information of the destination wireless LAN terminal of the communication data and transmits it.

  The wireless LAN terminal receives the beacon by shifting to the active mode in accordance with the beacon cycle, and determines whether communication data addressed to itself is held in the access point. If it is determined that there is no communication data addressed to itself, the wireless LAN terminal performs a doze mode operation until the next beacon transmission timing. On the other hand, when it is determined that there is communication data addressed to itself, the wireless LAN terminal receives the communication data addressed to the own wireless LAN terminal held by the access point by transmitting a polling request to the access point.

ANS / IEEE Std 802.11, 1999 Edition “Part 11: Wireless LAN Medium Access Control (MAC) and Physical Layer (PHY) Specifications”, p. 128-136

  By the way, when the above power saving function is realized, the wireless LAN terminal needs to be instructed by the user to execute the power saving operation. Therefore, the wireless LAN terminal can execute the power saving operation when the user forgets to instruct the wireless LAN terminal to execute the power saving operation even though the wireless LAN terminal has a function for realizing the power saving operation. In some cases, the battery life of the wireless LAN terminal cannot be extended.

  The power saving function described above can make the battery life of the wireless LAN terminal longer by making the doze mode period longer than the period of the beacon transmitted from the access point on the wireless LAN terminal side. . However, since explicit input by the user is necessary, it is difficult to perform fine control of the doze mode period according to midnight, lunch time, during a meeting, during a visitor, or the like.

  The present invention has been made in view of the above circumstances, and an object of the present invention is to realize a more convenient power saving operation and to surely execute the power saving operation. .

  In order to solve the above problems, the present invention automatically changes the wake-up interval of the wireless LAN terminal according to a preset schedule.

  For example, a first aspect of the present invention is a wireless LAN system including a wireless LAN terminal and an access point that relays communication data transmitted and received by the wireless LAN terminal. Wakeup interval storage means for storing an up interval schedule, wakeup interval extraction means for extracting and outputting the wakeup interval corresponding to the current date and time from the wakeup interval storage means, and whether or not the power save operation can be executed When it is determined by the power save determination means and the power save determination means that the power save operation can be executed, the wakeup interval extraction means outputs a wakeup interval corresponding to the current date and time, Power to execute power save operation at the output wakeup interval To provide a wireless LAN system, characterized in that it comprises a chromatography blanking control unit.

  According to a second aspect of the present invention, there is provided a wireless LAN terminal that performs communication via an access point, wherein the wakeup interval during the power saving operation is associated with a period during which the wakeup interval is applied. A wakeup interval storage means for storing an interval schedule, a wakeup interval extraction means for extracting and outputting a wakeup interval corresponding to the current date and time from the wakeup interval storage means, and whether or not a power save operation can be executed. When it is determined by the power save determination means and the power save determination means that the power save operation can be executed, the wakeup interval extraction means outputs the wakeup interval corresponding to the current date and time. Power save control means for executing a power save operation at a wake-up interval Providing a wireless LAN terminal, characterized in that it comprises.

  A third aspect of the present invention includes a wireless LAN terminal, an access point that relays communication data transmitted and received by the wireless LAN terminal, and a beacon transmission interval control unit that controls a beacon transmission interval by the access point. In the wireless LAN system, the beacon transmission interval control means refers to the transmission interval schedule storage means for storing the beacon transmission interval schedule and the transmission interval schedule storage means based on the current date and time, and periodically or irregularly. A transmission interval transmission unit that transmits a beacon transmission interval to an access point, and the access point receives a beacon transmission interval from a transmission interval storage unit that stores a beacon transmission interval and a beacon transmission interval control unit Stored in the transmission interval storage means at the transmission interval of the received beacon A transmission interval receiving means for updating the transmission interval of the received beacon, and a beacon control means for transmitting a beacon including information indicating the transmission interval stored in the transmission interval schedule storage means with reference to the transmission interval schedule storage means A wireless LAN system is provided.

  According to the wireless LAN system or the wireless LAN terminal of the present invention, a more convenient power saving operation can be realized and the power saving operation can be surely executed.

  Hereinafter, a first embodiment of the present invention will be described.

  FIG. 1 shows an example of a system configuration of a wireless LAN system 10 according to the first embodiment of the present invention. The wireless LAN system 10 includes a schedule management device 12, a wireless LAN terminal 20, and an access point 30.

  The access point 30 is connected to the wired network 11, and communicates with the schedule management device 12, the communication device 13, and the like connected to the wired network 11 via the wired network 11, for example, Ethernet (registered trademark) or the like. Wired communication based on The access point 30 performs wireless communication with the wireless LAN terminal 20 based on a wireless LAN standard such as IEEE802.11a or IEEE802.11b, and transmits a signal called a beacon at predetermined intervals according to the wireless LAN standard. Wireless transmission.

  For example, the wireless LAN terminal 20 belongs to the access point 30 having the best received signal quality, and performs wireless communication based on the wireless LAN with the access point 30, thereby belonging to the access point 30 via the access point 30. It communicates with other wireless LAN terminals 20 that are connected, wireless LAN terminals 20 that belong to other access points 30, the schedule management device 12 that is connected to the wired network 11, the communication device 13, and the like. The wireless LAN terminal 20 may communicate with other communication devices via an external network such as the Internet connected to the wired network 11.

  The wireless LAN terminal 20 has a function of performing a so-called power saving operation that performs intermittent reception according to the wireless LAN standard, and activates the reception function in synchronization with the transmission timing of the beacon transmitted from the access point 30. To stop or stop.

  The schedule management device 12 stores a wake-up interval schedule for each wireless LAN terminal 20 for each wireless LAN terminal 20, and a corresponding wake-up interval in response to a request from each wireless LAN terminal 20. The schedule is transmitted to the wireless LAN terminal 20 via the access point 30. For example, as shown in FIG. 2, the wake-up interval schedule stores the wake-up interval for each time zone 41a for each day of the week 42a.

  Here, the wake-up interval is a time interval from the start of the previous active mode to the next start of the active mode. One wake-up interval includes one active mode period and one doze mode. Period. The active mode is a mode in which reception processing is executed during the power save operation as defined in the wireless LAN standard. The doze mode is a mode in which the reception processing is stopped during the power save operation. This mode operates in the power state.

  In the example shown in FIG. 2, the wake-up interval schedule 40a stores a multiple value of the transmission interval based on the transmission interval of beacons transmitted from the access point 30 (100 ms in this example). For example, in the case shown in FIG. 2, the wake-up interval of the wireless LAN terminal 20 is set to twice the beacon transmission interval (200 ms in this example) in the time zone from 8:00 to 12:00 on Monday. In the time zone from 13:00 to 17:00 on Saturday, the wakeup interval of the wireless LAN terminal 20 is set to 10 times the beacon transmission interval (1 second in this example).

  Each wireless LAN terminal 20 acquires the wake-up interval schedule 40 for its own wireless LAN terminal 20 from the schedule management device 12 via the access point 30, and corrects the acquired wake-up interval schedule 40 if necessary. And store. Each wireless LAN terminal 20 executes a power saving operation according to the wakeup interval based on the stored wakeup interval schedule 40.

  In the present embodiment, the schedule management device 12 stores the wake-up interval for each time zone as a schedule for each day of the week, but the present invention is not limited to this, and the schedule management device 12 For each calendar day, the wake-up interval for each time zone may be stored as a schedule. In the present embodiment, the schedule management device 12 may store a schedule for each access point 30, or may store the same schedule for all access points 30.

  FIG. 3 is a block diagram illustrating an example of a detailed functional configuration of the wireless LAN terminal 20 in the first embodiment. The wireless LAN terminal 20 includes an input unit 21, a wakeup interval storage unit 22, a wakeup interval acquisition unit 23, a wakeup interval extraction unit 24, a power save control unit 25, a wireless communication unit 26, a power save determination unit 27, and data A communication unit 28 is provided.

  The wireless communication unit 26 performs wireless communication based on the wireless LAN with the access point 30, and is based on the wireless LAN such as a process of belonging to the nearest access point 30 or a handover process for changing the access point 30 to which the access point 30 belongs. Perform processing required for wireless communication.

  The wireless communication unit 26 has a function of receiving a beacon, extracting information included in the beacon, and supplying the information to a block that requires the information. For example, when the beacon 50 having the frame format illustrated in FIG. 4 is received, the wireless communication unit 26 detects the transmission interval of the beacon transmitted by the access point 30 from the Beacon Interval 511 included in the beacon data main body 506, and detects it. The beacon transmission interval is sent to the power save control unit 25.

  In addition, the wireless communication unit 26 receives a beacon during the active mode period during intermittent reception, and sends information in the Partial Virtual Bitmap 525 included in the received beacon to the data communication unit 28.

  The data communication unit 28 transmits voice data, communication data, and the like input from the user to the access point 30 via the wireless communication unit 26, and voice data transmitted from the access point 30 via the wireless communication unit 26. Receive and output communication data.

  In addition, when the information in the Partial Virtual Bitmap 525 is received from the wireless communication unit 26, the data communication unit 28 determines whether the communication data addressed to the own wireless LAN terminal 20 is held in the access point 30 based on the received information. Determine whether or not. When communication data addressed to the own wireless LAN terminal 20 is held in the access point 30, the data communication unit 28 transmits a polling request to the access point 30 via the wireless communication unit 26. The communication data addressed to the own wireless LAN terminal 20 held in the network 30 is received.

  The wakeup interval storage unit 22 stores a wakeup interval schedule. The wake-up interval schedule is data in which a wake-up interval during a power saving operation based on the wireless LAN standard is associated with a period in which the wake-up interval is applied.

  The wakeup interval acquisition unit 23 acquires a wakeup interval schedule from the schedule management device 12 via the wireless communication unit 26 in response to an instruction from the user via the input unit 21. Then, the wakeup interval acquisition unit 23 updates the wakeup interval schedule in the wakeup interval storage unit 22 with the wakeup interval schedule acquired from the schedule management device 12.

  The wake-up interval storage unit 22 stores the wake-up interval schedule acquired by the wake-up interval acquisition unit 23. The wake-up interval schedule in the wake-up interval storage unit 22 is a wireless LAN if necessary. It is corrected via the input unit 21 by the user of the terminal 20.

  In the present embodiment, for example, after the wakeup interval acquisition unit 23 acquires the wakeup interval schedule 40a shown in FIG. 2 and stores it in the wakeup interval storage unit 22, the wakeup interval schedule 40a is stored in the wireless LAN terminal. The wakeup interval storage unit 22 stores a wakeup interval schedule 40b as shown in FIG. 5 and the wireless LAN terminal 20 stores the wakeup interval stored in the wakeup interval storage unit 22. The power saving operation is executed according to the interval schedule 40b.

  When instructed by the power save control unit 25, the wake up interval extraction unit 24 extracts the wake up interval corresponding to the current date and time from the wake up interval storage unit 22 and outputs the wake up interval to the power save control unit 25.

  The power save determination unit 27 determines whether or not the wireless LAN terminal 20 satisfies a condition for executing the power save operation. The condition for executing the power save operation is, for example, that communication is not being performed and that the user has not been set in advance to prohibit the power save operation. In addition to the above conditions, the condition for executing the power saving operation may be that the wireless LAN terminal 20 is not being charged or a predetermined time has elapsed after the end of communication.

  The power save control unit 25 causes the wake up interval extraction unit 24 to extract the wake up interval when the power save determination unit 27 determines that the condition for executing the power save operation is satisfied. Then, the power save control unit 25 transmits a power save notification including information indicating the wake up interval extracted by the wake up interval extracting unit 24 to the belonging access point 30 via the wireless communication unit 26.

  The power save control unit 25 then transmits a beacon transmitted from the access point 30 based on the wakeup interval extracted by the wakeup interval extraction unit 24 and the beacon transmission interval received from the wireless communication unit 26. The wireless LAN terminal 20 is shifted to the doze mode until the next beacon transmission timing. When the beacon transmission timing comes, the power save control unit 25 shifts the wireless LAN terminal 20 to the active mode and causes the wireless communication unit 26 to receive the beacon.

  When the power save determination unit 27 determines that the condition for executing the power save operation is not satisfied during the power save operation, the power save control unit 25 cancels the power save operation and A save cancellation notification is transmitted to the access point 30 belonging thereto via the wireless communication unit 26.

  The power save control unit 25 holds the wakeup interval applied last time, and when a wakeup interval different from the wakeup interval applied last time is extracted by the wakeup interval extraction unit 24, a new wakeup interval is set. Is transmitted to the access point 30 belonging thereto via the wireless communication unit 26. As described above, the power save control unit 25 transmits the power save notification when the power save operation is started and when the wake-up interval is changed.

  FIG. 6 is a block diagram illustrating an example of a detailed functional configuration of the access point 30 in the first embodiment. The access point 30 includes a wired communication unit 31, a power save terminal information storage unit 32, a power save notification reception unit 33, a wireless communication unit 34, a beacon transmission unit 35, a data storage unit 36, and a data transmission unit 37.

  The wireless communication unit 34 performs wireless communication with the wireless LAN terminal 20 based on a wireless LAN standard such as IEEE802.11a or IEEE802.11b, and performs wireless communication based on the wireless LAN such as attribution processing with the wireless LAN terminal 20. Perform processing required for communication. The wired communication unit 31, the power save notification reception unit 33, the beacon transmission unit 35, and the data transmission unit 37 communicate with the wireless LAN terminal 20 via the wireless communication unit 34.

  The power save notification receiving unit 33 receives the power save notification from the wireless LAN terminal 20 via the wireless communication unit 34, and stores the identification information of the wireless LAN terminal 20 that has transmitted the power save notification in the power save terminal information storage unit 32. And determining the data holding capacity for the wireless LAN terminal 20 that has transmitted the power save notification based on the information indicating the wake-up interval included in the power save notification, and the determined capacity is stored in the data storage unit. Secure in 36.

  When a power save cancellation notification is received from the wireless LAN terminal 20 via the wireless communication unit 34, the power save notification receiving unit 33 displays the identification information of the wireless LAN terminal 20 that has transmitted the power save cancellation notification as a power save. Delete from the terminal information storage unit 32.

  The wired communication unit 31 performs wired communication with the schedule management device 12, the communication device 13, another access point 30, and the like via the wired network 11 based on a communication standard such as Ethernet (registered trademark).

  When communication data addressed to the wireless LAN terminal 20 belonging to the access point 30 is received via the wired network 11, the wired communication unit 31 has the identification information of the destination wireless LAN terminal 20 of the received communication data. If stored in the power save terminal information storage unit 32, the received communication data is stored in the data storage unit 36 in association with the identification information of the destination wireless LAN terminal 20.

  On the other hand, when the identification information of the destination wireless LAN terminal 20 of the received communication data is not stored in the power save terminal information storage unit 32, the wired communication unit 31 transmits the received communication data via the wireless communication unit 34. Transmit to the destination wireless LAN terminal 20.

  The beacon transmission unit 35 wirelessly transmits a beacon via the wireless communication unit 34 at a predetermined timing (100 ms interval in this example). At this time, when communication data is stored in the data storage unit 36, the beacon transmission unit 35 stores each of the belonging wireless LAN terminals 20 stored in the Partial Virtual Bitmap 525 shown in FIG. 4. Among the bits assigned to, the bit corresponding to the destination wireless LAN terminal 20 is set to indicate that communication data is stored, and the beacon with the setting is transmitted.

  When the data transmission unit 37 receives a polling request from the wireless LAN terminal 20 via the wireless communication unit 34, the data transmission unit 37 stores the communication associated with the identification information of the wireless LAN terminal 20 that has transmitted the polling request. Data is extracted from the data storage unit 36, and the extracted communication data is transmitted to the wireless LAN terminal 20 that has transmitted the polling request. Note that, when the communication data is transmitted to the wireless LAN terminal 20, the data transmission unit 37 deletes the transmitted communication data from the data storage unit 36.

  FIG. 7 is a flowchart showing an example of the operation of the wireless LAN terminal 20 in the first embodiment. When the power save determination unit 27 determines that the condition for executing the power save operation is satisfied, the wireless LAN terminal 20 starts the operation shown in this flowchart.

  First, the power save control unit 25 causes the wakeup interval extraction unit 24 to extract the wakeup interval corresponding to the current date and time from the wakeup interval storage unit 22 (S100). Then, the power save control unit 25 transmits a power save notification including information indicating the wake up interval extracted by the wake up interval extracting unit 24 to the belonging access point 30 via the wireless communication unit 26 (S101). ).

  Next, based on the wakeup interval extracted by the wakeup interval extraction unit 24 and the beacon transmission interval received from the wireless communication unit 26, the power save control unit 25 determines the beacon transmitted from the access point 30. Receive timing is calculated. Then, the wireless LAN terminal 20 sets the calculated time until the reception timing in the built-in timer, and shifts the wireless LAN terminal 20 to the doze mode until the next beacon reception timing (S102).

  Next, the power save control unit 25 determines whether the counting by the built-in timer has ended (S103). When the counting by the built-in timer has not ended (S103: No), the power save control unit 25 continues the doze mode until the counting by the built-in timer ends.

  When the counting by the built-in timer ends (S103: Yes), the power save control unit 25 causes the wireless communication unit 26 to receive a beacon (S104). The wireless communication unit 26 receives the beacon, and transmits the information in the Beacon Interval 511 (see FIG. 4) included in the beacon to the power save control unit 25, and the information in the Partial Virtual Bitmap 525 (see FIG. 4) as the data communication unit 28. To each.

  Then, based on the information received from the wireless communication unit 26, the data communication unit 28 determines whether communication data addressed to the own wireless LAN terminal 20 is stored in the access point 30 (S105). When the communication data addressed to the own wireless LAN terminal 20 is not stored in the access point 30 (S105: No), the power save control unit 25 executes the process shown in step 108.

  When communication data addressed to the own wireless LAN terminal 20 is stored in the access point 30 (S105: Yes), the data communication unit 28 transmits a polling request to the access point 30 via the wireless communication unit 26 ( (S106), communication data is received from the access point 30 (S107).

  Next, the power save control unit 25 refers to the determination result of the power save determination unit 27 and determines whether or not the conditions for starting the power save operation are still satisfied (S108). When the conditions for starting the power saving operation are no longer satisfied (S108: No), the power saving control unit 25 transmits a power saving cancellation notification to the access point 30 via the wireless communication unit 26 (S111). Then, the power saving operation is canceled (S112), and the wireless LAN terminal 20 ends the operation shown in this flowchart.

  When the conditions for starting the power saving operation are still satisfied (S108: Yes), the power saving control unit 25 acquires the wakeup interval by causing the wakeup interval extracting unit 24 to extract the wakeup interval. (S109). Then, the power save control unit 25 determines whether the acquired wakeup interval is different from the previously acquired wakeup interval (S110).

  When the acquired wakeup interval is different from the previously acquired wakeup interval (S110: Yes), the power save control unit 25 executes the process shown in step 101 to indicate information indicating the changed wakeup interval. Is transmitted to the access point 30 belonging thereto via the wireless communication unit 26. On the other hand, when the acquired wake-up interval is the same as the previously acquired wake-up interval (S110: No), the power save control unit 25 executes the processing shown in step 102.

  FIG. 8 is a flowchart showing an example of the operation of the access point 30 in the first embodiment. For example, the access point 30 starts the operation shown in this flowchart at a predetermined timing such as when the power is turned on.

  First, the power save notification receiving unit 33 determines whether a power save notification is received from the wireless LAN terminal 20 via the wireless communication unit 34 (S200). When the power save notification is received (S200: Yes), the power save notification receiving unit 33 stores the identification information of the wireless LAN terminal 20 that has transmitted the power save notification in the power save terminal information storage unit 32 (S201).

  Then, the power save notification receiving unit 33 determines and determines the data holding capacity for the wireless LAN terminal 20 that has transmitted the power save notification based on the information indicating the wake-up interval included in the power save notification. The capacity is secured in the data storage unit 36 (S202), and the power save notification receiving unit 33 executes the process shown in step 200 again.

  When the power save notification is not received (S200: No), the wired communication unit 31 determines whether or not communication data addressed to the wireless LAN terminal 20 to which it belongs is received (S203). When the communication data addressed to the wireless LAN terminal 20 to which it belongs is received (S203: Yes), the power save notification receiving unit 33 has the identification information of the destination wireless LAN terminal 20 of the communication data received by the wired communication unit 31 as the power. It is determined whether or not it is stored in the save terminal information storage unit 32 (S204).

  When the identification information of the destination wireless LAN terminal 20 of the received communication data is stored in the power save terminal information storage unit 32 (S204: Yes), the wired communication unit 31 converts the received communication data into the destination wireless LAN. The information is stored in the data storage unit 36 in association with the identification information of the terminal 20 (S205), and the power save notification receiving unit 33 executes the process shown in step 200 again.

  On the other hand, when the identification information of the destination wireless LAN terminal 20 of the received communication data is not stored in the power save terminal information storage unit 32 (S204: No), the wired communication unit 31 transmits the received communication data to the wireless communication The data is transferred to the destination wireless LAN terminal 20 via the unit 34 (S206), and the power save notification receiving unit 33 executes the process shown in step 200 again.

  In step 203, when the communication data addressed to the wireless LAN terminal 20 to which it belongs is not received (S203: No), the beacon transmission unit 35 determines whether it is the transmission timing of the beacon (S207). When it is a beacon transmission timing (S207: Yes), the beacon transmission unit 35 determines whether communication data is stored in the data storage unit 36 (S208).

  When communication data is stored in the data storage unit 36 (S208: Yes), the beacon transmission unit 35 includes information indicating that the communication data is stored and the wireless LAN terminal 20 that is the destination of the communication data. The beacon is transmitted (S209), and the power save notification receiving unit 33 executes the process shown in step 200 again.

  On the other hand, when communication data is not stored in the data storage unit 36 (S208: No), the beacon transmission unit 35 transmits a beacon indicating that communication data is not stored (S210), and receives a power save notification. The unit 33 executes the process shown in Step 200 again.

  If it is not the beacon transmission timing in step 207 (S207: No), the data transmission unit 37 determines whether a polling request has been received from the wireless LAN terminal 20 (S211). When the polling request is not received (S211: No), the power save notification receiving unit 33 executes the process shown in Step 200 again.

  On the other hand, when the polling request is received (S211: Yes), the communication data stored in association with the identification information of the wireless LAN terminal 20 that has transmitted the polling request is extracted from the data storage unit 36, and the extracted communication is performed. The data is transmitted to the wireless LAN terminal 20 that has transmitted the polling request (S212), and the power save notification receiving unit 33 executes the process shown in step 200 again.

  FIG. 9 is a sequence diagram illustrating an example of the operation of the wireless LAN system 10 according to the first embodiment. In the wireless LAN terminal 20, when the conditions for executing the power saving operation are satisfied, the wireless LAN system 10 starts the operation shown in this flowchart.

  First, the wireless LAN terminal 20 acquires the current wakeup interval according to internal scheduling, and transmits a power save notification including the acquired wakeup interval (200 ms in this example) to the access point 30 (S300). . The access point 30 internally secures a storage capacity corresponding to the wake-up interval included in the received power save notification (S301).

  Next, the access point 30 starts a doze mode operation at the acquired wakeup interval (S302). Then, the wireless LAN terminal 20 shifts to the active mode at the next wakeup timing and receives a beacon (S303), and communication data addressed to the wireless LAN terminal 20 is held in the access point 30 in the received beacon. It is checked whether or not it is included (S304).

  Since the beacon transmitted from the access point 30 in step 303 does not include that the communication data addressed to the wireless LAN terminal 20 is held in the access point 30, the wireless LAN terminal 20 again wakes up the 200 ms wake. The doze mode operation and beacon reception at the up interval are repeated (S305, S306).

  When the communication data addressed to the wireless LAN terminal 20 is received via the wired network 11 (S307), the access point 30 holds the received communication data (S308), indicating that the communication data is held. The beacon including the indicated information is transmitted at the next and subsequent beacon transmission timings (S309).

  The wireless LAN terminal 20 shifts to the active mode at the wake-up timing, receives a beacon, and the received beacon includes that the communication data addressed to the wireless LAN terminal 20 is held in the access point 30 Is detected (S310), and a polling request is transmitted to the access point 30 (S311). In response to the polling request, the access point 30 transmits the held communication data to the wireless LAN terminal 20 that has transmitted the polling request (S312).

  Next, the access point 30 receives a beacon (S313), detects that communication data addressed to the wireless LAN terminal 20 is not held in the access point 30 in the received beacon (S314), The doze mode operation and the reception of the beacon are repeated again at the wake-up interval of 200 ms (S315, S316).

  If the access point 30 detects that the wakeup interval acquired according to the internal scheduling is different from the previously acquired wakeup interval (S317), the access point 30 sets the changed wakeup interval (400 ms in this example). A power save notification including this is transmitted to the access point 30 (S318). Then, the access point 30 secures a storage capacity in the data storage unit 36 according to the wake-up interval included in the received power save notification (S319). Then, the wireless LAN terminal 20 repeats the doze mode operation and the reception of the beacon at a wakeup interval of 400 ms (S320, S321).

  The first embodiment of the present invention has been described above.

  As is clear from the above description, according to the wireless LAN system 10 of the present embodiment, a more convenient power saving operation can be realized and the power saving operation can be surely executed.

  Next, a second embodiment of the present invention will be described.

  FIG. 10 is a system configuration diagram showing an example of a system configuration of the wireless LAN system 10 according to the second embodiment of the present invention. The wireless LAN system 10 includes a wireless LAN terminal 20, an access point 30, and a beacon transmission interval control device 60. Except for the points described below, in FIG. 10, the components denoted by the same reference numerals as those in FIG. 1 have the same or similar functions as those in FIG.

  The beacon transmission interval control device 60 is connected to the wired network 11 and manages the transmission interval of beacons transmitted by the access point 30 according to a schedule registered therein. The beacon transmission interval control device 60 transmits the changed beacon transmission interval to the access point 30 via the wired network 11 when the beacon transmission interval is changed according to the schedule registered therein. .

  The access point 30 transmits a beacon according to the transmission interval received from the beacon transmission interval control device 60. The wireless LAN terminal 20 executes a power saving operation in synchronization with the beacon transmitted from the access point 30. In the present embodiment, the wireless LAN terminal 20 performs an active mode operation in synchronization with the timing at which a beacon is transmitted from the access point 30. That is, when the transmission interval of the beacon transmitted from the access point 30 is 100 ms, the wireless LAN terminal 20 performs the power saving operation at a wakeup interval of 100 ms.

  FIG. 11 is a block diagram illustrating an example of a detailed functional configuration of the wireless LAN terminal 20 in the second embodiment. The wireless LAN terminal 20 includes a power save control unit 25, a wireless communication unit 26, a power save determination unit 27, and a data communication unit 28. Except for the points described below, in FIG. 11, the components denoted by the same reference numerals as those in FIG. 3 have the same or similar functions as those in FIG.

  The power save control unit 25 notifies the power save notification via the wireless communication unit 26 when the power save determination unit 27 determines that the condition for executing the power save operation is satisfied. Send to point 30. In the present embodiment, the power save control unit 25 may not include information indicating the transmission interval of beacons extracted from beacons in the power save notification.

  FIG. 12 is a block diagram illustrating an example of a detailed functional configuration of the access point 30 in the second embodiment. The access point 30 includes a wired communication unit 31, a power save terminal information storage unit 32, a power save notification reception unit 33, a wireless communication unit 34, a beacon transmission unit 35, a data storage unit 36, a data transmission unit 37, and a transmission interval storage unit. 38. Except for the points described below, in FIG. 12, the components denoted by the same reference numerals as those in FIG. 6 have the same or similar functions as those in FIG.

  When the power save notification receiving unit 33 receives a power save notification from the wireless LAN terminal 20 via the wireless communication unit 34, the power save notification receiving unit 33 stores the identification information of the wireless LAN terminal 20 that has transmitted the power save notification. Stored in the unit 32. The transmission interval storage unit 38 stores beacon transmission intervals. The beacon transmission unit 35 transmits a beacon according to the transmission interval stored in the transmission interval storage unit 38. When the access point 30 is activated, a default value (for example, a value indicating a transmission interval of 100 ms) is stored in the transmission interval storage unit 38.

  When the wired communication unit 31 receives a beacon transmission interval from the beacon transmission interval control device 60 via the wired network 11, the transmission interval stored in the transmission interval storage unit 38 at the received transmission interval. Update. In addition, when the wired communication unit 31 receives a beacon transmission interval from the beacon transmission interval control device 60 via the wired network 11, the wired communication unit 31 belongs to the own access point 30 based on the received transmission interval. While each of the wireless LAN terminals 20 is in the doze mode, the storage capacity for holding the communication data addressed to the wireless LAN terminal 20 is determined, and the determined storage capacity is secured in the data storage unit 36.

  FIG. 13 is a block diagram illustrating an example of a detailed functional configuration of the beacon transmission interval control device 60. The beacon transmission interval control device 60 includes a transmission interval schedule storage unit 61, a transmission interval registration reception unit 62, a wired communication unit 63, and a transmission interval notification unit 64.

  The transmission interval schedule storage unit 61 stores the beacon transmission interval in a format as shown in FIG. 2, for example, in association with the time zone to which the transmission interval is applied. The wired communication unit 63 performs wired communication with the access point 30 and the communication device 13 via the wired network 11 based on a communication standard such as Ethernet (registered trademark). When receiving a beacon transmission interval schedule from another device via the wired communication unit 63, the transmission interval registration receiving unit 62 registers the received schedule in the transmission interval schedule storage unit 61.

  The transmission interval notification unit 64 refers to the transmission interval schedule storage unit 61 based on the current date and time, and when the application period of the transmission interval of the current beacon has elapsed, the transmission interval of the beacon to be applied to the next period, The data is transmitted to the access point 30 via the wired communication unit 63. The transmission interval notification unit 64 stores, for example, the transmission interval of the beacon transmitted to the access point 30 last time, and the transmission interval corresponding to the current date and time in the transmission interval schedule storage unit 61 is stored. If it is different from, it is determined that the application period of the current beacon transmission interval has elapsed.

  Note that the beacon transmission interval schedule in the transmission interval schedule storage unit 61 may be changed directly via the console of the beacon transmission interval control device 60 in addition to being changed via the transmission interval registration receiving unit 62. Good. The transmission interval schedule storage unit 61 may store a beacon transmission interval schedule that is different for each access point 30.

  FIG. 14 is a flowchart illustrating an example of the operation of the beacon transmission interval control device 60. For example, at a predetermined timing such as when the power is turned on, the beacon transmission interval control device 60 starts the operation shown in this flowchart.

  First, the transmission interval registration receiving unit 62 determines whether or not a beacon transmission interval schedule has been received via the wired communication unit 63 (S400). When the beacon transmission interval schedule is received (S400: Yes), the received schedule is registered in the transmission interval schedule storage unit 61 (S401), and the transmission interval registration reception unit 62 executes the process shown in step 400 again. To do.

  When the beacon transmission interval schedule has not been received (S400: No), the transmission interval notification unit 64 determines whether or not the current date and time is the date and time when the currently applied beacon transmission interval should be changed. Determine (S402). When the current date / time is not the date / time when the transmission interval of the currently applied beacon is to be changed (S402: No), the transmission interval registration receiving unit 62 executes the process shown in step 400 again.

  When the current date and time is the date and time when the beacon transmission interval currently applied is to be changed (S402: Yes), the transmission interval notification unit 64 sets the changed beacon transmission interval to the wired communication unit 63. (S403), the transmission interval registration acceptance unit 62 executes the process shown in step 400 again.

  FIG. 15 is a flowchart illustrating an example of the operation of the access point 30 in the second embodiment. For example, the access point 30 starts the operation shown in this flowchart at a predetermined timing such as when the power is turned on.

  First, the beacon transmission unit 35 starts beacon transmission at a transmission interval corresponding to the default value (in this example, a value indicating 100 ms) stored in the transmission interval storage unit 38 (S500). Then, the wired communication unit 31 determines whether or not the beacon transmission interval is received from the beacon transmission interval control device 60 via the wired network 11 (S501). When the beacon transmission interval is received (S501: Yes), the wired communication unit 31 updates the transmission interval in the transmission interval storage unit 38 with the received beacon transmission interval (S502).

  Next, the wired communication unit 31 holds communication data addressed to the wireless LAN terminal 20 while each of the wireless LAN terminals 20 belonging to the own access point 30 is in the doze mode based on the received transmission interval. The storage capacity is determined, the determined storage capacity is secured in the data storage unit 36 (S503), and the wired communication unit 31 executes the process shown in step 501 again.

  When the beacon transmission interval is not received (S501: No), the power save notification receiving unit 33 determines whether or not a power save notification is received from the wireless LAN terminal 20 via the wireless communication unit 34 ( S504). When the power save notification is received (S504: Yes), the power save notification receiving unit 33 stores the identification information of the wireless LAN terminal 20 that has transmitted the power save notification in the power save terminal information storage unit 32 (S505), The wired communication unit 31 executes the process shown in step 501 again.

  When the power save notification has not been received (S504: No), the wired communication unit 31 determines whether communication data addressed to the wireless LAN terminal 20 to which it belongs has been received (S506). When the communication data addressed to the wireless LAN terminal 20 to which it belongs is received (S506: Yes), the power save notification receiving unit 33 has the identification information of the wireless LAN terminal 20 that is the destination of the received communication data. It is determined whether it is stored in the power save terminal information storage unit 32 (S507).

  When the identification information of the destination wireless LAN terminal 20 of the received communication data is stored in the power save terminal information storage unit 32 (S507: Yes), the wired communication unit 31 converts the received communication data into the destination wireless LAN. The data is stored in the data storage unit 36 in association with the identification information of the terminal 20 (S508), and the wired communication unit 31 executes the process shown in step 501 again.

  On the other hand, when the identification information of the destination wireless LAN terminal 20 of the received communication data is not stored in the power save terminal information storage unit 32 (S507: No), the wired communication unit 31 transmits the received communication data to the wireless communication The data is transmitted to the destination wireless LAN terminal 20 via the unit 34 (S509), and the wired communication unit 31 executes the process shown in step 501 again.

  In step 506, when the communication data addressed to the wireless LAN terminal 20 to which it belongs is not received (S506: No), the beacon transmission unit 35 determines whether or not it is the beacon transmission timing (S510). If it is the beacon transmission timing (S510: Yes), the beacon transmission unit 35 sets the transmission interval in the transmission interval storage unit 38 to the built-in timer, and starts counting the next beacon transmission timing (S511). .

  Next, the beacon transmission unit 35 determines whether communication data is stored in the data storage unit 36 (S512). When communication data is stored in the data storage unit 36 (S512: Yes), the beacon transmission unit 35 indicates that the communication data is stored, information indicating the wireless LAN terminal 20 that is the destination of the communication data, and A beacon including a beacon interval is transmitted (S513), and the wired communication unit 31 executes the process shown in step 501 again.

  On the other hand, when communication data is not stored in the data storage unit 36 (S512: No), the beacon transmission unit 35 transmits a beacon indicating that the communication data is not stored and a beacon interval (S514), and wired. The communication unit 31 executes the process shown in step 501 again.

  In step 510, when it is not the beacon transmission timing (S510: No), the data transmission unit 37 determines whether a polling request is received from the wireless LAN terminal 20 (S515). When the polling request has not been received (S515: No), the wired communication unit 31 executes the process shown in Step 501 again.

  On the other hand, when the polling request is received (S515: Yes), the communication data stored in association with the identification information of the wireless LAN terminal 20 that has transmitted the polling request is extracted from the data storage unit 36, and the extracted communication is performed. The data is transmitted to the wireless LAN terminal 20 that has transmitted the polling request (S516), and the wired communication unit 31 executes the process shown in step 501 again.

  FIG. 16 is a flowchart showing an example of the operation of the wireless LAN terminal 20 in the second embodiment. When the power save determination unit 27 determines that the condition for executing the power save operation is satisfied, the wireless LAN terminal 20 starts the operation shown in this flowchart.

  First, the wireless communication unit 26 receives a beacon, extracts information indicating the beacon transmission interval included in the beacon, and sends the information to the power save control unit 25 (S600). Then, the power save control unit 25 sets a built-in timer based on the information indicating the beacon transmission interval received from the wireless communication unit 26, and starts counting the next beacon reception timing (S601).

  Next, the power save control unit 25 transmits a power save notification to the belonging access point 30 via the wireless communication unit 26 (S602), and sets the wireless LAN terminal 20 to the doze mode until the next beacon transmission timing. Transition is performed (S603).

  Then, the power save control unit 25 determines whether the counting by the built-in timer has ended (S604). When the counting by the built-in timer has not ended (S604: No), the power save control unit 25 continues the doze mode until the counting by the built-in timer ends.

  When the counting by the built-in timer ends (S604: Yes), the power save control unit 25 causes the wireless communication unit 26 to receive a beacon (S605). The wireless communication unit 26 transmits information in the Beacon Interval 511 (see FIG. 4) included in the beacon to the power save control unit 25 and information in the Partial Virtual Bitmap 525 (see FIG. 4) to the data communication unit 28, respectively.

  Then, based on the information received from the wireless communication unit 26, the data communication unit 28 determines whether communication data addressed to the own wireless LAN terminal 20 is stored in the access point 30 (S606). When the communication data addressed to the own wireless LAN terminal 20 is not stored in the access point 30 (S606: No), the power save control unit 25 executes the process shown in step 609.

  When communication data addressed to the own wireless LAN terminal 20 is stored in the access point 30 (S606: Yes), the data communication unit 28 transmits a polling request to the access point 30 via the wireless communication unit 26. (S607), communication data is received from the access point 30 (S608).

  Next, the power save control unit 25 refers to the determination result of the power save determination unit 27 to determine whether or not the conditions for starting the power save operation are still satisfied (S609). When the condition for starting the power saving operation is not satisfied (S609: No), the power saving control unit 25 transmits a power saving cancellation notification to the access point 30 via the wireless communication unit 26 (S610). Then, the power saving operation is canceled (S612), and the wireless LAN terminal 20 ends the operation shown in this flowchart.

  If the condition for starting the power saving operation is still satisfied (S609: Yes), the power saving control unit 25 determines the time until the next beacon transmission timing based on the transmission interval included in the received beacon. Is set in the built-in timer (S611), and the processing shown in step 603 is executed.

  The second embodiment of the present invention has been described above.

  Also in the present embodiment, the wireless LAN system 10 can realize a more convenient power save operation and can reliably execute the power save operation.

  As mentioned above, although this invention was demonstrated using embodiment, the technical scope of this invention is not limited to the range as described in embodiment mentioned above. It will be apparent to those skilled in the art that various modifications or improvements can be made to the above-described embodiment. Furthermore, it is apparent from the scope of the claims that the embodiments added with such changes or improvements can be included in the technical scope of the present invention.

1 is a system configuration diagram illustrating an example of a system configuration of a wireless LAN system 10 according to a first embodiment of the present invention. It is explanatory drawing which shows an example of the wake-up space | interval schedule 40 delivered from the schedule management apparatus 12. FIG. It is a block diagram which shows an example of a detailed functional structure of the wireless LAN terminal 20 in 1st Embodiment. It is explanatory drawing which shows an example of the frame structure of the beacon 50. FIG. 6 is an explanatory diagram showing an example of a wake-up interval schedule 40 modified by a user of the wireless LAN terminal 20. FIG. It is a block diagram which shows an example of a detailed functional structure of the access point 30 in 1st Embodiment. 4 is a flowchart illustrating an example of an operation of the wireless LAN terminal 20 in the first embodiment. It is a flowchart which shows an example of operation | movement of the access point 30 in 1st Embodiment. It is a sequence diagram which shows an example of operation | movement of the wireless LAN system 10 in 1st Embodiment. It is a system configuration figure showing an example of a system configuration of wireless LAN system 10 concerning a 2nd embodiment of the present invention. It is a block diagram which shows an example of a detailed functional structure of the wireless LAN terminal 20 in 2nd Embodiment. It is a block diagram which shows an example of a detailed functional structure of the access point 30 in 2nd Embodiment. 3 is a block diagram illustrating an example of a detailed functional configuration of a beacon transmission interval control device 60. FIG. 4 is a flowchart showing an example of operation of a beacon transmission interval control device 60. It is a flowchart which shows an example of operation | movement of the access point 30 in 2nd Embodiment. 7 is a flowchart illustrating an example of an operation of a wireless LAN terminal 20 in the second embodiment.

Explanation of symbols

10 --- Wireless LAN system, 11 --- Wired network, 12 --- Schedule management device, 13 --- Communication equipment, 20 --- Wireless LAN terminal, 21 --- Input unit, 22 --- Wake Up interval storage unit, 23 --- Wake-up interval acquisition unit, 24 --- Wake-up interval extraction unit, 25 --- Power save control unit, 26, 34 --- Wireless communication unit, 27 --- Power save Determination unit, 28 --- data communication unit, 30 --- access point, 31, 63--wired communication unit, 32 --- power save terminal information storage unit, 33 --- power save notification reception unit, 35 --- Beacon transmission unit, 36 --- Data storage unit, 37 --- Data transmission unit, 38 --- Transmission interval storage unit, 40 --- Wake-up interval schedule, 41 --- Time zone, 42-- --Day of week, 50 --- beacon, 60 --- beacon transmission interval control device, 61 --- transmission interval schedule storage, 6 --- transmission interval registration accepting unit, 64 --- transmission interval notifying unit

Claims (4)

A wireless LAN system comprising a wireless LAN terminal and an access point that relays communication data transmitted and received by the wireless LAN terminal,
The wireless LAN terminal is
A wake-up interval storage means for storing a wake-up interval schedule during the power saving operation;
A wakeup interval extracting means for extracting and outputting a wakeup interval corresponding to the current date and time from the wakeup interval storage means;
Power save determination means for determining whether or not the power save operation can be executed;
When the power save determination unit determines that the power save operation can be performed, the wakeup interval extraction unit outputs the wakeup interval corresponding to the current date and time, and outputs the wakeup interval. And a power saving control means for executing the power saving operation. The wireless LAN system according to claim 1,
Wake-up interval management means for storing the wake-up interval schedule in association with each of the plurality of wireless LAN terminals and returning a corresponding wake-up interval schedule in response to a request from the wireless LAN terminal. ,
The wireless LAN terminal is
A wireless LAN system, further comprising: a wakeup interval obtaining unit that obtains a wakeup interval schedule of the own wireless LAN terminal from the schedule management unit and stores the wakeup interval schedule in the wakeup interval storage unit. A wireless LAN terminal that communicates via an access point,
A wakeup interval storage means for storing a wakeup interval schedule in which a wakeup interval during the power saving operation is associated with a period in which the wakeup interval is applied;
A wakeup interval extracting means for extracting and outputting a wakeup interval corresponding to the current date and time from the wakeup interval storage means;
Power save determination means for determining whether or not the power save operation can be executed;
When the power save determination unit determines that the power save operation can be performed, the wakeup interval extraction unit outputs the wakeup interval corresponding to the current date and time, and outputs the wakeup interval. And a power saving control means for executing the power saving operation. A wireless LAN terminal;
An access point that relays communication data transmitted and received by the wireless LAN terminal;
A wireless LAN system comprising a beacon transmission interval control means for controlling a beacon transmission interval by the access point,
The beacon transmission interval control means includes
A transmission interval schedule storage means for storing a transmission interval schedule of a beacon;
A transmission interval transmission means for referring to the transmission interval schedule storage means based on the current date and time, and transmitting a beacon transmission interval to the access point periodically or irregularly;
The access point is
Transmission interval storage means for storing the transmission interval of the beacon;
When receiving the beacon transmission interval from the beacon transmission interval control means, the transmission interval receiving means for updating the beacon transmission interval stored in the transmission interval storage means with the received beacon transmission interval;
A wireless LAN system comprising: a beacon control unit configured to transmit a beacon including information indicating a transmission interval stored in the transmission interval schedule storage unit with reference to the transmission interval schedule storage unit.

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