JP4579947B2 - Wireless LAN power saving control method, wireless base station device, and wireless terminal device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To improve power saving in a radio terminal device under power saving control. <P>SOLUTION: When the radio terminal device STA under power saving control (PS mode) is being connected to a radio base station device AP, the AP sets a period of a multiple of the transmission period of a special beacon signal as a period for broadcast transmission and includes the period included in the special beacon signal (DTIM beacon) as information, and notifies it to the STA that is operating in the PS mode but not multicast data communication. The STA operating in the PS mode but not performing multicast data communication acquires the period in the included in the special beacon signal, transits from a sleep state to an awake one according to the period included in the DTIM beacon, and performs transmission/reception operation cyclically at that period. <P>COPYRIGHT: (C)2009,JPO&amp;INPIT

Description

  The present invention relates to a wireless LAN power saving control method, a wireless base station device, and a wireless terminal device, and more particularly, to receive multicast data in a wireless LAN system including a wireless base station device and a wireless terminal device that operates with power saving control. The present invention relates to a technique for improving a power saving effect for a wireless terminal device that does not.

In general, a wireless packet communication system is applied in a form using a wireless system as a part of a wired network (hereinafter referred to as NW) when configuring an overall communication network. That is, a wireless packet communication system is wired to the NW interface at one end of the wired NW, and communication between the wireless terminal device and the wired terminal or the wireless terminal device is performed by wireless connection.
FIG. 1 shows a configuration example of a general wireless LAN network (NW) in a wireless LAN communication system compliant with the conventional IEEE802.11 standard (see Non-Patent Document 1 below).
In the wireless LAN network (NW) shown in FIG. 1, a wireless base station apparatus (hereinafter referred to as AP) [10-5] includes a wireless terminal apparatus group [10] including at least one wireless terminal apparatus (hereinafter referred to as STA). −10] (for example, configured with STAs such as [10-1], [10-2], [10-3], and [10-4]).
The AP [10-5] transmits / receives unicast data to / from each destination / source of the wireless terminal device group [10-10] and broadcasts [10−] to all STAs of the wireless terminal device group [10-10]. 6] broadcast distribution and multicast [10-7] broadcast distribution to the STA receiving the multicast service.
For example, the STAs [10-1] and [10-2] in the wireless terminal device group [10-10] use a terminal such as a notebook PC in addition to unicast data transmission / reception in addition to a multicast service ( [10-8] receiving the video stream service), and the STAs of [10-3] and [10-4] do not receive the multicast service using a terminal such as a handset (cell phone type). Is a group [10-9] performing voice communication.
Here, when the wireless terminal device group [10-10] includes an STA operating in power saving control (hereinafter referred to as PS mode), the AP [10-5] is the wired NW side [10-11]. The data addressed to the STA operating in the PS mode arrived at from is temporarily accumulated.
[10-3] and [10-4] STAs such as STAs generally operate in the PS mode when waiting before starting a voice call.

The AP [10-5] notifies the STA under the AP of the wireless NW information (supported transmission rate, service set type (SSID), etc.) using a beacon signal transmitted at a constant period. In addition, as main information notified by the beacon signal, information on a beacon transmission cycle (Beacon Interval), and a TIM information element (Traffic Indication Map element format) [beacon frame [2-11] illustrated in FIG. 2-12].
The TIM information element [2-12] includes intermittent period information (number of intermittent beacons) of a beacon signal (DTIM beacon) with a delivery traffic indication map (DTIM) transmitted intermittently during beacon transmission. 2-1], a counter value until the next DTIM beacon is transmitted (the counter value is reduced every time a beacon is transmitted, and the beacon when it becomes 0 becomes a DTIM beacon) [2-2], It includes information obtained by bit-mapping [2-3] the buffered data addressed to the STA operating in the PS mode for each destination. Also, when either multicast or broadcast data is accumulated, [2-13] notifies that it is buffered.

Here, the STA operating in the PS mode recognizes the timing (period) at which the STA can receive the beacon signal based on the information of the Beacon Interval of the beacon period included in the received beacon.
Furthermore, when the STA operating in the PS mode first connects to the AP [10-5], the STA transitions from the sleep state to the awake state at an integral multiple of the requested beacon signal transmission period (or every beacon period), Buffering information (information obtained by bit-mapping [2-3] for each destination) is acquired from the received beacon.
The AP [10-5] performs buffering of data addressed to the STA operating in the target PS mode in a beacon signal that is an integral multiple of the beacon signal transmission cycle applied at the time of connection by the STA operating in the PS mode (or every beacon cycle). Information is included in [2-3] and notified. That is, the STA operating in the PS mode generally transitions from a sleep state in which transmission / reception is not performed to an awake state in which transmission / reception is performed at a fixed period in which a beacon signal can be received, and at that time, AP [10-5] The data addressed to the local station STA is received.
Here, the sleep state is a standby state in which the transmission / reception function is stopped and power consumption is suppressed, and the awake state is a state in which the transmission / reception function operates. The data transmission / reception procedure in the PS mode is performed according to the procedure defined in the IEEE802.11 standard.

In contrast to the notification procedure of unicast data having a destination, the broadcast / multicast data reception method in the PS mode follows the example of the procedure shown in FIG.
In the wireless NW configuration of FIG. 3, STA1 [1-5] and STA2 [1-6] operating in the PS mode, and STA3 [1-10] operating in the active mode [1-13] (always awake state). (STA not operating in PS mode) is connected under the control of AP [1-7]. Further, STA1 [1-5] is a terminal that does not participate in the multicast service assuming the terminals of the handsets shown in [10-3] and [10-4] in FIG. It is assumed that STA1 [1-5] receives a multicast deleter but is not used in an application or the like.
When broadcast / multicast data is stored, AP [1-7] has a cycle that is an integral multiple of the transmission cycle [1-3] (in the example in the figure, it is twice [1-3]). DTIM beacons ([1-2-1], [1-2-2], [1-2-3], [1-2-4], [1-2-5] transmitted in [1-4] (Where [1-3-1], [1-3-2], [1-3-3], [1-3-4], [1-3-5], [1-3] −6] is a normal beacon that is not a DTIM beacon, and immediately after the transmission of the multicast data ([1-1-1], [1-1-2], [1-1-3], [1-1 -4], [1-1-5]) and broadcast data ([1-1-11], [1-1-12], [1-1-13]).
In general, an STA operating in the PS mode transitions from a sleep state to an awake state ([1-11], [1-12]) at a timing when a DTIM beacon is transmitted, and receives broadcast / multicast data. (However, this operation is performed when the STA applies when connecting to the AP [1-7] and is not an essential operation).

That is, as described above, the STA operating in the PS mode performs the operation of transition from the sleep state to the away state, so that the DTIM beacon of the TIM information element [2-12] included in the beacon illustrated in FIG. Based on information on the transmission period [2-1] and the counter value [2-2] until the next DTIM beacon is transmitted, the state transits to the awake state at a timing at which the DTIM beacon can be received ([1-11 ], [1-12]).
Also, multicast data ([1-1-1], [1-1-2], [1-1-3], [1-1-4], [1-1-5]) is not required ( Also in STA1 [1-5] which does not receive a multicast service, in the cycle of the DTIM beacon so that broadcast can be received, the state transits from the sleep state to the awake state. For example, in the period [1-121] or [l-122], the broadcast is not transmitted because it is not buffered in the AP [1-7], but transits to awake.
Then, STA1 [1-5] must maintain the awake state until it receives multicast [1-1-1]. This is because AP [1-7] does not distinguish between broadcast and multicast buffering information, and when either is buffered, it is notified to the STA by a beacon signal. STA1 [1-5] must maintain an awake state until multicast data is received. That is, the STA cannot determine broadcast / multicast until reception is completed.
In the STA3 [1-10] not operating in the PS mode, the STAs connected in the PS mode (eg, STA1 [1-5], STA2 [ 1-6]), broadcast / multicast data is received in the period of the DTIM beacon.

FIG. 4 is a flowchart for explaining an example of a beacon / DTIM beacon transmission procedure at the time of STA connection operating in the PS mode in the conventional AP.
The AP starts [4-1] this flowchart when the connected STA starts the operation in the PS mode.
Next, the AP resets the counter value of [2-2] included in the beacon information element [2-12] shown in FIG. 2 (initial value: set to the same value as [2-1]), and has a fixed period. When the beacon transmission cycle [4-2] is transmitted (Yes [4-10]), the counter value [2-2] included in the beacon information element in FIG. 2 is decreased by 1 [4-3]. .
Note that [2-1] and [2-2] indicate “DTIM Period” and “DTIM count” in FIG. 2, respectively, and “DTIM Period” indicates that a normal beacon is transmitted before the DTIM beacon is transmitted. Represents an intermittent number. For example, when “DTIM Period” is 2, every two DTIM beacons are transmitted as in the following equation (1). At this time, “DTIM count” changes as shown in (n) below. Here, in “(2) *”, “DTIM count” which has become 0 is reset to 2 which is the value of “DTIM Period”.
[Equation 1]
DTIM Beacon (0) → Normal Beacon (2) ^* → Normal Beacon (1) → DTIM Beacon (0) → Normal Beacon (2) ^* → Normal Beacon (1) → ...
・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ (1)
Next, it is determined [4-4] whether the counter value of [2-2] is “0”. If it is not “0” (No [4-13]), a beacon is transmitted. And wait until the next beacon transmission timing [4-2].

In step [4-3], if the counter value in [2-2] is “0” (Yes [4-12]), whether broadcast or multicast to be transmitted is buffered. Judgment is made [4-5].
In Step [4-5], if Yes [4-14], it is described in [2-13] included in the beacon information element [2-12] in FIG. 4-6] and transmits a DTIM beacon [4-17].
After completing the transmission of the DTIM beacon, broadcast / multicast is transmitted [4-8], and the counter value of [2-2] is reset [4-16].
In Step [4-5], if No [4-15], a DTIM beacon is transmitted, and the counter value of [2-2] is reset [4-16].
However, when all the STAs connected to the AP have ended the operation in the PS mode after the start [4-1] in FIG. 4, this flowchart is immediately ended.

FIG. 5 is a flowchart for explaining an example of the sleep / awake state transition procedure in the STA operating in the conventional PS mode.
After starting the operation in the PS mode [5-1], the STA determines [5-2] whether it is the awake timing. Here, it is assumed that the awake timing is a DTIM beacon reception cycle.
If it is the DTIM beacon reception timing in step [5-2] (Yes [5-8]), the awake state [5-3] is entered, the DTIM beacon is received, and the beacon information element [2- 12] is acquired [5-4]. If the beacon intermittent number (DTIM beacon period) is changed based on the DTIM Period [2-1] in the acquired beacon information element [2-12], the awake timing is updated. Thereafter, it is determined whether or not the unicast data addressed to the local station STA is described in [2-3] of the beacon information element [2-12] in FIG. 2 and the multicast / broadcast bit is described in [2-13]. Perform [5-5].
If it is described in step [5-5] (Yes [5-10]), the waiter state is continued [5-6] until the described unicast data or multicast / broadcast is received. Then, transition to the sleep state [5-7].
In Step [5-5], in the case of No [5-11], the state immediately transitions to the sleep state.
However, when the operation in the PS mode is to be ended after the start [5-1] in FIG. 5, this flowchart is immediately ended and the operation is active.

FIG. 6 shows a block diagram of a PS mode beacon transmission control unit at the time of STA connection operating in the PS mode in a conventional AP.
The PS mode beacon transmission control unit [6-0] is implemented when one or more STAs connected to the AP operate in the PS mode. That is, the AP manages a list of STAs operating in the PS mode.
When data is input (received) [6-1] from the upper network, the AP uses the data memory management unit [6-2] when the data destination is an STA operating in the PS mode, or multicast. If it is / broadcast, buffer the data.
When the data destination is not an STA operating in the PS mode (operating in the active mode), the received data is transferred [6-4] to the transmission control unit [6-3] and the transmission control unit [6-3]. ], The frame is transmitted according to the CSMA / CA procedure of the IEEE 802.11 standard.
The beacon transmission cycle management unit [6-5] manages a beacon transmission cycle timer, and sends a beacon information element management unit [6-8] a transmission instruction [6-6] for each beacon transmission cycle. Do.

In response to the instruction [6-6], the beacon information element management unit [6-8] buffers the data memory management unit [6-2] in order to create the beacon information element [2-12] in FIG. [6-7]. The data memory management unit [6-2] notifies the beacon information element management unit [6-8] of the data destination and broadcast / multicast buffering information [6-7]. When the data destination information is notified [6-7], a bit (flag) corresponding to the data destination is set in [2-3] in the beacon information element [2-12] in FIG.
Further, in the beacon information element management [6-8], when the counter value of [2-2] in the beacon information element [2-12] in FIG. When the counter value decremented by 1 becomes “0” and the broadcast / multicast buffered information is notified [6-7], the beacon information element [2 in FIG. [2-13] in [-12] to set a bit (flag) indicating that broadcast / multicast is buffered.

The beacon information element [2-12] of FIG. 2 created by the above setting is notified [6-10] to the beacon transmission control unit [6-9]. The beacon transmission control unit [6-9] adds the notified format [6-10] to the beacon frame, and forwards the beacon frame to the transmission control unit [6-3] [6-13]. The transmission control unit [6-3] transmits a beacon frame according to the CSMA / CA procedure of the IEEE802.11 standard.
Further, the beacon transmission control unit [6-9] performs buffering after beacon transmission when the counter value of [2-2] in the beacon information element [2-12] in FIG. 2 is “0”. Instruct [6-11] the data memory management unit [6-2] to transmit the broadcast / multicast being performed.
When there is a transmission request from the STA operating in the PS mode after transmitting the beacon, the data memory management unit [6-2] transfers the buffered data addressed to the request STA to the transmission control unit [6-3]. [6-4] If the data memory management unit [6-2] is instructed [6-11], the buffered broadcast / multicast is sent to the transmission control unit [6-3]. Transfer [6-4].
The transmission control unit [6-3] transmits the transferred data [6-4] and multicast / broadcast to the wireless medium according to the CSMA / CA procedure of the IEEE802.11 standard.

FIG. 7 shows a block diagram of a sleep / awake state control unit in a STA operating in the conventional PS mode. The PS mode reception control unit [7-0] performs sleep / awake state and reception control.
When the STA operates in the PS mode, the PS mode management unit [7-1] notifies [7-6] the sleep / awake state control unit [7-2].
The sleep / awake state control unit [7-2] transitions from the sleep state to the awake state at a period in which the DTIM beacon can be received, and transitions from the awake state to the sleep state when reception of data or the like is completed. Manage. In the example of FIG. 7, it is assumed that the STA operating in the PS mode transits from the sleep state to the awake state only at the timing when the AP transmits the DTIM beacon.
In the DTIM beacon reception cycle, the sleep / awake state control unit [7-2] instructs the reception control unit [7-5] to start reception [7-14], and the reception control unit [7-5] Start for receiving.
The activated reception control unit [7-5] receives the frame from the wireless medium. The received frame is transferred [7-12] to the reception determination unit [7-4].

In the reception determination unit [7-4], when the transferred [7-12] frame is a DTIM beacon, the reception determination unit [7-4] transfers [7-10] to the information element inspection unit [7-3]. In the case of data or multicast / broadcast addressed to the local station STA, it is forwarded [7-11] to the upper layer [7-13]. At the same time, the data / multicast / broadcast reception information is notified [7-9] to the sleep / awake state control unit.
In the information element inspection unit [7-3], the counter value [2-2] in the beacon information element [2-12] of FIG. 2 included in the DTIM beacon and the beacon intermittent period information of [2-1]. [2-3] and the presence / absence of data addressed to the local station STA and the information indicating the presence / absence of broadcast / multicast in [2-13] are checked, and the information is sent to the sleep / awake state control unit [7-2]. Notification [7-7].
The sleep / awake state control unit [7-2] updates the cycle of state transition from sleep to awake based on the notified information [7-7], and transmits data or broadcast to the local station STA. / If it is indicated that multicast is present, the awake state is maintained until information indicating that these have been received from the reception determination unit [7-4] is notified [7-9].
That is, when all the scheduled reception notifications [7-9] have been received, the state transits from awake to the sleep state, and the reception control unit [7-5] is instructed to stop the reception operation [7-14]. .

However, in the conventional wireless LAN system, when a STA operating in the PS mode is connected, the AP increases the cycle (period) of transmitting a beacon signal and the intermittent number of beacon signals until a DTIM beacon is transmitted. By doing so, the effect of power saving can be expected. However, when the beacon period is set to be long, a large delay time occurs in receiving unicast data.
As a method for solving this problem, Wi-Fi WMM-APSD (, WMM Power Save (see Non-Patent Document 2 below)) and IEEE 802.11e standard (IEEE Std 802.11e-2005 (see Non-Patent Document 3 below)) The U-APSD (Unscheduled Automatic Power-Save Delivery) method in) uses a method that does not depend on the beacon period, considering the priority control for each application and the range of delay and fluctuation to maintain the communication quality of the application. A power saving control method for unicast data is defined.
In this method, the STA changes the state from the sleep mode to the active mode in a unique transmission / reception cycle in order to maintain the communication quality for each application, and requests the AP to transmit unicast data addressed to itself.

As prior art documents related to the invention of the present application, there are the following.
IEEE Std 802.11, 1999 edition, MEDIUM ACCESS CONTROL (MAC) AND PHYSICAL (PHY) SPECIFICATIONS, (7.3.2.6 TIM, 11.2 Power management) WMM Power Save for Mobile and Portable Wi-Fi CERTIFIED Devices, Wi-Fi Alliance December 2005, (P7-P12) IEEE Std 802.11e-2005, (11.2 Power management)

In the conventional wireless LAN system, the AP can expect a power saving effect by setting a large beacon transmission period and the number of intermittent beacons of DTIM beacons. However, since multicast data is transmitted only after transmission of a DTIM beacon, there is a problem that large delay and delay fluctuation occur.
For example, when an application that requires high communication quality such as video (moving image) stream distribution uses a multicast service, an STA that receives multicast data hinders playback of the application due to delay and delay fluctuation ( There is a possibility that a situation in which smooth reproduction is difficult due to the fact that it takes a long time to display an image due to the time required for buffering).
Therefore, in order to solve the delay / fluctuation problem caused by setting the beacon intermittent number of DTIM beacons to a large value, when the AP sets a short DTIM beacon period (less beacon intermittent number) in advance, For STAs operating in the PS mode that has not participated, there has been a problem that the effect of the power saving control is reduced because the mode is frequently switched to the active mode.

In addition, in the standard related to IEEE802.11, the problem of delay and fluctuation can be solved only by such a method. Furthermore, since broadcast / multicast buffering information by beacon signals is distinguished and not notified, awake state must be maintained in order to receive unnecessary multicast data, and high communication quality is required. Since the multicast application to be performed has a large amount of traffic, the time for maintaining the awakening becomes long, resulting in the problem of excessive power consumption.
Further, even when the U-APSD method is used, since broadcast / multicast data is specified to be transmitted after transmission of a DTIM beacon, such a problem has not been solved.
The present invention has been made to solve the above-described problems of the prior art, and an object of the present invention is to provide a wireless LAN power saving control method, a radio base station apparatus, and a wireless terminal that improve the effect of power saving control. To provide an apparatus.
The above and other objects and novel features of the present invention will become apparent from the description of this specification and the accompanying drawings.

Of the inventions disclosed in this application, the outline of typical ones will be briefly described as follows.
The present invention relates to a radio base station apparatus, at least one radio operating in power-saving control for transitioning to one of a sleep state in which a data transmission / reception function is stopped and an awake state in which the data transmission / reception function is activated. The wireless base station device is configured by a terminal device, and transmits a beacon signal at a constant cycle, transmits a special beacon signal at an integral multiple of the fixed cycle, and transmits the special beacon signal. The wireless terminal transmits a broadcast, and the wireless terminal changes the state from the sleep state to the awake state at a certain period that satisfies the condition for receiving the special beacon signal, and after completing the transmission / reception operation of desired data, A wireless LAN power saving control method in a wireless LAN system transitioning from a state to the sleep state Then, the radio base station apparatus sets a period that is an integral multiple of the transmission period of the special beacon signal as a period for which the broadcast transmission is scheduled, and includes the period of the integral multiple as information in the special beacon signal. When there is the broadcast to be transmitted at the timing of the integral multiple cycle included in the special beacon signal, the broadcast is transmitted, and the wireless terminal device is included in the special beacon signal The state transits from the sleep state to the awake state according to the integer multiple cycle, and the transmission / reception operation is performed at every integer multiple cycle.
In the prior art, when a STA operating in the PS mode is connected to an AP, broadcast and multicast data are transmitted immediately after all special beacon signals (DTIM beacons). An STA that includes DTIM beacon intermittent period information scheduled for broadcast transmission in the transmitted DTIM beacon, transmits a broadcast only after transmitting a DTIM beacon scheduled for broadcast transmission, operates in PS mode, and does not perform multicast data communication. The DTIM beacon intermittent period information included in the DTIM beacon is acquired, and reception control related to broadcast data is performed according to the DTIM beacon intermittent period information, which is different from the prior art.

Also, the present invention is characterized in that the radio base station apparatus does not transmit the multicast at the timing of the integer multiple period included in the special beacon signal.
In the prior art, when a STA operating in the PS mode is connected to an AP, broadcast and multicast data are transmitted immediately after all DTIM beacons, whereas in the present invention, the DTIM transmitted by the AP is transmitted. The beacon includes DTIM beacon intermittent period information scheduled for broadcast transmission, transmits a broadcast only after transmission of a DTIM beacon scheduled for broadcast transmission, does not perform multicast transmission, operates in PS mode, and multicast data communication The STA that has not performed the acquisition of the DTIM beacon intermittent period information included in the DTIM beacon differs from the prior art in that reception control related to broadcast data is performed according to the DTIM beacon intermittent period information.

In addition, the present invention is a wireless base station apparatus, at least one operating in power saving control for transitioning to any one of a sleep state in which a data transmission / reception function is stopped and an awake state in which the data transmission / reception function is activated. The wireless base station device transmits a beacon signal at a constant cycle, transmits a special beacon signal at an integral multiple of the fixed cycle, and transmits the special beacon signal. Sending multicast and broadcast, the wireless terminal device transitions from the sleep state to the awake state at a certain period that satisfies the condition that can receive the special beacon signal, after completing the transmission and reception operation of the desired data, Wireless LAN power saving control method in wireless LAN system transitioning from awake state to sleep state The radio base station apparatus arbitrarily determines an integer multiple of a transmission cycle of the special beacon signal, transmits the special beacon signal including the integer multiple cycle as information, and transmits the radio The terminal device transitions from the sleep state to the awake state according to the integer multiple cycle included in the special beacon signal, and performs the transmission / reception operation at every integer multiple cycle.
In the prior art, when the STA operating in the PS mode is connected to the AP, broadcast and multicast data is transmitted immediately after all the DTIM beacons, whereas in the present invention, the DTIM beacon transmitted by the AP is transmitted. A STA that transmits a DTIM beacon including arbitrarily determined DTIM beacon periodic information, operates in PS mode, and does not perform multicast data communication, acquires the DTIM beacon intermittent period information included in the DTIM beacon. In addition, it differs from the prior art in that reception control is performed according to the DTIM beacon intermittent period information.

The effects obtained by the representative ones of the inventions disclosed in the present application will be briefly described as follows.
According to the present invention, it is possible to improve the power saving of the wireless terminal device STA operating in the PS mode.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
In all the drawings for explaining the embodiments, parts having the same functions are given the same reference numerals, and repeated explanation thereof is omitted.
FIG. 8 is a diagram for explaining the wireless LAN power saving control method according to the embodiment of the present invention.
This embodiment is an embodiment in which the awake state maintenance time for receiving data is reduced in a STA operating in the PS mode that does not participate in the multicast service.
In the wireless NW configuration shown in FIG. 8, STA1 [1-5] and STA2 [1-6] operating in the PS mode and STA3 [1-10] operating in the active mode [1-13] (in the PS mode). A non-operating STA) is connected to the AP [1-7]. STA1 [1-5] is a terminal that does not participate in the multicast service.
AP [1-7] is a period [1-44] that is an integer multiple (n times) of the DTIM beacon transmission period [1-4] (in the example of FIG. 8, twice the DTIM beacon transmission period (n = 2)). ), 4 times the beacon transmission cycle), and broadcast data is accumulated, broadcast data [1-1-12], [1-1-13], and [1-1-14] are transmitted as DTIM beacons. Send later.
For integer multiples of the DTIM beacon transmission period, STA1 [1-5] maintains the sleep state. The DTIM beacon transmission cycle shown here is twice an example and may be different from the optimum value.

In addition, the period information twice that of the DTIM beacon is notified to the STA by an information element newly added in the DTIM beacon.
When multicast data is stored according to the procedure of the prior art, multicast data [1-1-1], [1-1-2], [1-1-3] is transmitted after all DTIM beacons are transmitted. ], [1-1-4], [1-1-5] are transmitted.
Here, the DTIM beacon transmission cycle or beacon cycle is set to a shorter period than a generally used period in consideration of a reduction in multicast data delay and fluctuation.
The STA1 [1-5] operating in the PS mode not receiving the multicast service receives the period information of the timing at which the broadcast included in the beacon signal is transmitted (in the example in the figure, [1-44 before transmitting the broadcast data). ] Is transmitted from the sleep state to the awake state based on the beacon cycle information (in this embodiment, twice the DTIM beacon cycle (n = 2)) and the transmission timing in this embodiment, and broadcast data is reliably received. To do. In addition, the STA2 [1-6] operating in the PS mode receiving a multicast service follows the period [1-9] so as to satisfy the condition that all DTIM beacons can be received according to the power saving control procedure according to the prior art. / [1-4] makes a transition from the sleep state to the awake state.

Moreover, in the modification of a present Example, AP is a period [1-44] of integral multiple (n times) of DTIM beacon transmission period [1-4] (in the example of FIG. 8, 2 times of DTIM beacon transmission periods). When broadcast data is accumulated at a multiple (n = 2) and four times the beacon transmission period), broadcast is transmitted, but multicast data is not transmitted.
Another modification of the present embodiment is characterized in that an integer multiple of the transmission period of the DTIM beacon is arbitrarily determined regardless of the broadcast transmission scheduled period.
In another modification of the present embodiment, since the AP does not require complicated operations and does not consider broadcast transmission, the AP can set the integral multiple period longer than the above case. 1-5] maintains the sleep state for a long time, and further achieves a power saving effect. However, since the timing after transmission of the DTIM beacon with the integer multiple cycle is not the timing for transmitting the broadcast, there is a possibility that the STA cannot receive the service using the broadcast.

An example of the additional information element of the beacon transmitted by the AP of this embodiment is shown in FIG.
The information element [9-1] includes an information element ID [9-5] indicating that it is broadcast transmission scheduled period information, and a counter value [9-3] of the number of DTIM beacon transmissions until the next broadcast transmission. ] And the number of intermittent DTIM beacons [9-4].
Each time a DTIM beacon is transmitted, the counter value is decreased, and the DTIM beacon when the DTIM beacon becomes “0” becomes the broadcast transmission scheduled timing. For example, if the number of intermittent DTIM beacons [9-4] is “10”, the counter value [9-3] starts from 10. Each time a DTIM beacon is transmitted, the counter value is decreased by one. When there is a broadcast after transmitting a DTIM beacon that becomes “0”, the broadcast is transmitted, and in the next DTIM beacon, the counter value [9-3] is reset to “10”.
The STA operating in the PS mode that does not receive the multicast service manages the sleep / awake state based on this information.

In this embodiment, the AP performs the above-described operation according to the flowchart shown in FIG. The part enclosed by [10-0] in the figure is a part added to the flowchart of the conventional AP of FIG. 4, and the part enclosed by [10-20] is a conventional example. 4 is a modified part of the flowchart of FIG. That is, in the flowchart of FIG. 10, the processing of step [4-5], step [4-6], and step [4-17] in FIG. 4 is not executed.
In step [4-4] of FIG. 10, when the counter value of [2-2] is determined to be “0” (Yes [4-12]), the counter value of the information element shown in FIG. It is determined [10-1] whether [9-3] is “0”.
In step [10-1], if it is “0” (Yes [10-3]), the counter value [9-3] of the information element shown in FIG. 9 is reset [10-4], and FIG. 1 is subtracted from the counter value [9-3] of the indicated information element [10-5]. In step [10-1], when it is not “0” (No [10-2]), 1 is subtracted from the counter value [9-3] of the information element shown in FIG. 9 [10-5].
Next, it is determined whether or not the broadcast / multicast to be transmitted is buffered in the AP [10-6], and if there is a broadcast / multicast to be transmitted in step [10-6] (Yes [10-8] ]) Describes the presence of broadcast / multicast in the information element [2-13] in FIG. 2, and performs DTIM beacon transmission [10-10].
In step [10-6], when there is no broadcast / multicast to be transmitted (No [10-7]), the process returns to DTIM beacon transmission [4-18] in FIG.
Next, it is determined again [10-11] whether or not the counter value [9-3] of the information element is “0”. In step [10-11], if “0” (Yes [10-12]), broadcast / multicast transmission [4-8] scheduled to be transmitted is performed after DTIM beacon transmission.
In step [10-11], if it is not “0” (No [10-13]), if there is a multicast buffered after DTIM beacon transmission, it is transmitted [10-15]. However, even if there is a buffered broadcast, the broadcast is not transmitted.

In a modification of the present embodiment, the AP performs the above-described operation according to the flowchart shown in FIG. The portion surrounded by [10-1-0] in the figure is a portion added to the flowchart of the conventional AP of FIG. 4, and the portion surrounded by [10-1-20] is the conventional implementation. It is the part which changed the flowchart of FIG. 4 which is an example. That is, in the flowchart of FIG. 11, the processing of step [4-5], step [4-6], step [4-17], and step [4-8] of FIG. 4 is not executed.
As a difference from the flowchart of FIG. 10, instead of performing broadcast / multicast transmission [4-8] scheduled to be transmitted after DTIM beacon transmission, in FIG. 11, broadcast transmission is performed, but multicast transmission is not performed [10]. -1-8].
In another modification of this embodiment, the AP performs the above-described operation according to the flowchart shown in FIG. The part enclosed by [10-2-0] in the figure is a part added to the flowchart of the conventional AP of FIG. 4, and the part enclosed by [10-1-20] is the conventional implementation. It is the part which changed the flowchart of FIG. 4 which is an example.
In the flowchart of FIG. 12, when the counter value of [2-2] is determined to be “0” (Yes [4-12]) in step [4-4], the information element shown in FIG. It is determined [10-1] whether or not the counter value [9-3] is “0”.
In step [10-1], if it is “0” (Yes [10-3]), the counter value [9-3] of the information element shown in FIG. 9 is reset [10-4], and FIG. The counter value [9-3] 1 of the indicated information element is decremented [10-5]. In step [10-1], when it is not “0” (No [10-2]), 1 is subtracted from the counter value [9-3] of the information element shown in FIG. 9 [10-5]. Next, it returns to step [4-5] of FIG.

The STA operating in the PS mode executes the above-described embodiment using the flowchart shown in FIG.
The portion surrounded by [11-0] in the figure is a portion added to the flowchart of the conventional STA shown in FIG. 5, and the portion surrounded by [11-20] is a flowchart of the conventional STA. is there.
After starting the operation in the PS mode [5-1], the STA determines [11-1] whether or not the multicast service is received. In step [11-1], when the multicast service is received (Yes [11-12]), it is determined [5-2] whether it is the awake timing of FIG. 5, and the conventional flowchart is executed. To do.
In step [11-1], if the multicast service is not received (No [11-13]), it is determined [11-2] whether it is the awake timing. Here, the awake timing is assumed to be the DTIM beacon reception period in the conventional STA, but in this embodiment, the Period [9-4] in the added information element [9-1] shown in FIG. According to (DTIM beacon intermittent), the cycle is an integral multiple of the DTIM beacon.
In step [11-2], when it is the awake timing (Yes [11-8]), the state is changed to the awake state [11-3], the DTIM beacon is received, and the beacon information element [2- 12] and the added beacon information element [9-1] in FIG. 9 is acquired [11-4].

Based on Period [9-4] in the acquired beacon information element [9-1], when the DTIM intermittent number (an integer multiple of the DTIM beacon period) is changed, the awake timing is updated.
Thereafter, whether or not the unicast data addressed to the local station STA is described in [2-3] of the beacon information element in FIG. 2 and whether the multicast / broadcast bit is described in [2-13] [11-5] ]I do.
If it is described in step [11-5] (Yes [11-10]), the awake state is continued [11-6] until the described unicast data or multicast / broadcast is received. Then, transition to the sleep state [11-7].
In step [11-5], if not described (No [11-11]), the state transits to the sleep state [11-7].
However, when the operation in the PS mode is to be ended after the start [5-1] in FIG. 5, this flowchart is immediately ended and the operation is active.

FIG. 14 shows a block diagram of a PS mode beacon transmission control unit at the time of STA connection operating in the PS mode in the AP of this embodiment.
The PS mode beacon transmission control unit [12-0] is implemented when at least one of the STAs connected to the AP operates in the PS mode.
That is, the AP manages a list of STAs operating in the PS mode. When data is input (received) [6-1] from the higher-level network, the AP uses the data memory management unit [12-2] when the data destination is an STA operating in the PS mode, or multicast broadcast. If so, buffer the data.
When the data destination is not the PS mode STA (operates in the active mode), the received data is transferred [6-4] to the transmission control unit [6-3], and the transmission control unit [6-3] Send frames according to the CSMA / CA procedure of the .11 standard.
The beacon transmission cycle management unit [6-5] manages a beacon transmission cycle timer, and transmits a beacon information element and additional information element management unit [12-8] to a transmission instruction [6- 6] is performed.
In response to the instruction [6-6], the beacon information element and the additional information element manager [12-8] generate the beacon information element [2-12] in FIG. ] Is inquired about the buffering status [6-7]. The data memory management unit [12-2] notifies the beacon information element and the additional information element management unit [12-8] of the data destination and broadcast / multicast buffering information [6-7].

In the beacon information element and additional information element management unit [12-8], when the data destination information is notified [6-7], [2-3] in the beacon information element [2-12] in FIG. ], A bit (flag) corresponding to the destination of the previous period data is set. Further, in the beacon information element and additional information element management unit [12-8], when the counter value of [2-2] in the beacon information element [2-12] in FIG. 2 is larger than “0”, Decrease the counter value by 1.
When the counter value decremented by 1 becomes “0” and the broadcast / multicast buffered information is notified [6-7], the beacon information element [ 2-12], a bit (flag) indicating that broadcast / multicast is buffered is set in [2-13].
When the counter value [2-2] in the beacon information element [2-12] is “0”, the counter value [9-3] of the information element shown in FIG. 9 is “0”. Judge whether or not.
If it is not “0”, 1 is decremented from the counter value [9-3] of the information element shown in FIG. If it is “0”, the counter value is reset, and then 1 is decremented from the counter value [9-3] of the information element shown in FIG.
The beacon information element [2-12] format of FIG. 2 and the beacon additional information required [9-1] format of FIG. 9 created by the above settings are notified to the beacon transmission control unit [12-9] [6-10] To do.

The beacon transmission control unit [12-9] adds the notified format [6-10] to the beacon frame, and forwards the beacon frame to the transmission control unit [6-3] [6-13]. The transmission control unit [6-3] transmits a beacon frame according to the CSMA / CA procedure of the IEEE802.11 standard.
Further, the beacon transmission control unit [12-9] has the counter value [2-2] in the beacon information element [2-12] in FIG. 2 being “0”, and the beacon information element [9 in FIG. [9-3] in [-1] is not “0”, the data memory management unit [12-2] is instructed to transmit the buffered multicast after the beacon transmission [6] -11].
Further, the counter value of [2-2] in the beacon information element [2-12] in FIG. 2 is “0”, and [9-3 in the beacon information element [9-1] in FIG. ] Is “0”, the data memory management unit [12-2] is instructed [6-11] to transmit the buffered broadcast and multicast after the beacon transmission.
The data memory management unit [12-2] transfers [6-4] the buffered broadcast / multicast to the transmission control unit [6-3] according to the content of the instruction [6-11].
The transmission control unit [6-3] transmits the transferred data [6-4] and multicast / broadcast to the wireless medium according to the CSMA / CA procedure of the IEEE802.11 standard.

In a modification of the present embodiment, the beacon transmission control unit [12-9] has the counter value [2-2] in the beacon information element [2-12] in FIG. When the counter value of [9-3] in the 9 beacon information elements [9-1] is “0”, the data memory management unit [12-2] transmits a buffered broadcast. [6-11], but multicast is not instructed.
In another modification of the present embodiment, the beacon information element and additional information element management unit [12-8] indicates that the counter value of [2-2] in the beacon information element [2-12] in FIG. If it is “0”, it is determined whether or not the counter value [9-3] of the information element shown in FIG. 9 is “0”.
If the counter value [9-3] of the information element shown in FIG. 9 is not “0”, the counter value [9-3] of the information element shown in FIG. If the counter value [9-3] of the information element shown in FIG. 9 is “0”, the counter value is reset, and then 1 is decremented from the counter value [9-3] of the information element shown in FIG. .
The beacon information element [9-1] format of FIG. 2 and the beacon additional information element [9-1] format of FIG. 9 created by the above settings are notified to the beacon transmission control unit [12-9] [6- 10], and performs the same operation as the conventional AP except for the above operation.

FIG. 15 is a block diagram showing a schematic configuration of the PS mode reception control unit of the STA operating in the PS mode according to the embodiment of the present invention.
The PS mode reception control unit [13-0] performs sleep / awake state and reception control when the STA operating in the PS mode does not receive the multicast service.
First, when the STA operates in the PS mode, the PS mode management unit [13-1] notifies the sleep / awake state control unit [13-2] [13-6].
The sleep / awake state control unit [13-2] transitions from the sleep state to the awake state at a cycle that is an integral multiple of the DTIM beacon cycle, and transitions from the awake state to the sleep state when reception of data or the like is completed. Manage. The period that is an integral multiple of the DTIM beacon period shown here follows the newly added information element [9-1] in FIG. 9 that is notified by the DTIM beacon.
The sleep / awake state control unit [13-2] instructs the reception control unit [13-5] to start reception [13-14] when awakening is performed.
The reception control unit [13-5] is activated for reception. The activated reception control unit [13-5] receives a frame from the wireless medium. The received frame is transferred [13-12] to the reception determination unit [13-4].

When the frame transmitted [13-12] is a DTIM beacon, the reception determination unit [13-4] transfers [13-3] to the information element and additional information element inspection unit [13-3]. In the case of data or multicast / broadcast addressed to the local station STA, it is forwarded [13-11] to the upper layer [13-13].
At the same time, the data / multicast / broadcast reception information is notified [13-9] to the sleep / awake state control unit [13-2].
In the information element and additional information element inspection unit [13-3], the counter value [2-2] in the beacon information element [2-12] in FIG. 2 included in the DTIM beacon and the beacon [2-1]. Intermittent cycle information, [2-3] presence / absence of data addressed to the local station STA, [2-13] information indicating presence / absence of broadcast / multicast, and counter value [9-3] of the information element shown in FIG. ] And Period [9-4] information, and notifies [13-7] the information to the sleep / awake state control unit [13-2].
The sleep / awake state control unit [13-2] updates the period of state transition from sleep to awake based on the notified information [13-7], and also transmits data or broadcast / address to the local station STA. When it is indicated that multicast is present, the awake state is maintained until information indicating that these have been received is notified [13-9] from the reception determination unit [13-4]. That is, when all the scheduled reception notifications [13-9] are received, the state shifts from awake to the sleep state, and instructs the reception control unit [13-5] to stop the reception operation [13-14].

As described above in detail, in this embodiment, the DTIM beacon transmitted by the AP includes the DTIM beacon intermittent period information scheduled for broadcast transmission, and transmits the broadcast only after transmitting the DTIM beacon scheduled for broadcast transmission. An STA that operates in the PS mode and is not performing multicast communication acquires the DTIM beacon intermittent period information included in the DTIM beacon and performs reception control related to broadcast data according to the DTIM beacon intermittent period information.
As a result, the AP and STA share timing information of the DTIM beacon period that can be received without being influenced by the transmission / reception timing of the STA operating in the PS mode and performing the multicast communication, and the STA can save power. It becomes possible to improve.
In the modification of the present embodiment, the DTIM beacon transmitted by the AP includes the DTIM beacon intermittent period information scheduled for broadcast transmission, transmits a broadcast only after transmitting the DTIM beacon scheduled for broadcast transmission, and performs multicast transmission. In addition, an STA that operates in the PS mode and does not perform multicast data communication acquires the DTIM beacon intermittent period information included in the DTIM beacon and is involved in broadcast data according to the DTIM beacon intermittent period information. Perform reception control.
As a result, the AP and the STA share the timing information of the DTIM beacon period at which the broadcast can be received without being influenced by the transmission / reception timing of the STA operating in the PS mode and performing the multicast data communication, and the multicast is performed. Since the STA does not receive, the power saving of the STA can be improved.

In another modification of the present invention, the AP includes DTIM beacon intermittent period information arbitrarily determined in the transmitted DTIM beacon, transmits the DTIM beacon, operates in the PS mode, and performs multicast communication. STAs that have not acquired the DTIM beacon intermittent period information included in the DTIM beacon and perform reception control according to the DTIM beacon intermittent period information.
Thereby, it is possible to improve the power saving of the STA without being influenced by the transmission / reception timing of the STA that operates in the PS mode and performs the multicast communication.
As mentioned above, the invention made by the present inventor has been specifically described based on the above embodiments. However, the present invention is not limited to the above embodiments, and various modifications can be made without departing from the scope of the invention. Of course.

It is a block diagram which shows the structural example of the general wireless LAN network in the communication system of the wireless LAN based on the conventional IEEE802.11 standard. It is a figure for demonstrating the TIM information element of the conventional beacon frame. It is a figure explaining the broadcast / multicast data transmission procedure in PS mode in the conventional wireless LAN system. It is a flowchart which shows an example of the beacon / DTIM beacon transmission procedure in the conventional AP. It is a flowchart which shows an example of the sleep / awake state transition procedure in STA which operate | moves by the conventional PS mode. It is a block diagram which shows schematic structure of the beacon transmission control part for PS modes of the conventional AP. It is a block diagram which shows schematic structure of the PS mode reception control part of STA which operate | moves by the conventional PS mode. It is a figure explaining the broadcast / multicast data transmission procedure in PS mode of the Example of this invention. It is a figure for demonstrating the broadcast transmission schedule information element in the beacon frame of the Example of this invention. It is a flowchart which shows an example of the beacon / DTIM beacon transmission procedure in AP of the Example of this invention. It is a flowchart which shows an example of the beacon / DTIM beacon transmission procedure in the modification of AP of the Example of this invention. It is a flowchart which shows an example of the beacon / DTIM beacon transmission procedure in the other modification of AP of the Example of this invention. It is a flowchart which shows an example of the sleep / awake state transition procedure in STA which operate | moves in PS mode of the Example of this invention. It is a block diagram which shows schematic structure of the beacon transmission control part for PS modes of AP of the Example of this invention. It is a block diagram which shows schematic structure of the PS mode reception control part in STA which operate | moves in PS mode of the Example of this invention.

Explanation of symbols

[6-0], [12-0] PS mode beacon transmission control unit [6-1] Data input from higher layer / wired network [6-2], [12-2] Data memory management unit [6-3 ] Transmission control unit [6-5] Beacon transmission cycle management unit [6-8] Beacon information element management unit [6-9], [12-9] Beacon transmission control unit [7-0], [13-0] PS mode reception control unit [7-1], [13-1] PS mode management unit [7-2], [13-2] Sleep / awake state control unit [7-3] Information element inspection unit [7-4 ], [13-4] Reception determination unit [7-5], [13-5] Reception control unit [7-13], [13-13] Data output to higher layer [10-1], [10-2 ], [10-3], [10-4] Wireless terminal equipment (STA)
[10-5] Radio base station apparatus (AP)
[10-6] Broadcast [10-7] Multicast [10-8] Wireless terminal device receiving multicast service [10-9] Wireless terminal device performing voice communication without receiving multicast service [10-10] Wireless terminal device group [10-11] Wired network [12-8] Beacon information element and additional information element management unit [13-3] Information element and additional information element inspection unit

Claims (7)

A radio base station device;
A sleep state in which the data transmission / reception function is stopped, and at least one wireless terminal device that operates in power saving control to transition to any one of the awake state in which the data transmission / reception function is activated;
The radio base station device transmits a beacon signal at a constant cycle, and transmits a special beacon signal at an integer multiple of the fixed cycle,
After sending the special beacon signal, send multicast and broadcast,
The wireless terminal device transitions the state from the sleep state to the awake state at a fixed period that satisfies the condition for receiving the special beacon signal, and completes the transmission / reception operation of desired data, and then from the awake state to the sleep state. A wireless LAN power saving control method in a wireless LAN system transitioning to
The radio base station apparatus transmits a period that is an integral multiple of the transmission period of the special beacon signal as a period for which the broadcast transmission is scheduled, and includes the period of the integral multiple as information in the special beacon signal. ,
When there is the broadcast to be transmitted at the timing of the integer multiple period included in the special beacon signal, the broadcast is transmitted,
The wireless terminal device transitions from the sleep state to the awake state according to the integer multiple cycle included in the special beacon signal, and performs the transmission / reception operation at every integer multiple cycle. LAN power saving control method.   2. The wireless LAN power saving control method according to claim 1, wherein the wireless base station apparatus does not transmit the multicast at the timing of the integer multiple cycle included in the special beacon signal. A radio base station device;
A sleep state in which the data transmission / reception function is stopped, and at least one wireless terminal device that operates in power saving control to transition to any one of the awake state in which the data transmission / reception function is activated;
The radio base station device transmits a beacon signal at a constant cycle, and transmits a special beacon signal at an integer multiple of the fixed cycle,
After sending the special beacon signal, send multicast and broadcast,
The wireless terminal device transitions the state from the sleep state to the awake state at a fixed period that satisfies the condition for receiving the special beacon signal, and completes the transmission / reception operation of desired data, and then from the awake state to the sleep state. A wireless LAN power saving control method in a wireless LAN system transitioning to
The radio base station apparatus arbitrarily determines an integer multiple of the transmission period of the special beacon signal, and transmits the special beacon signal including the integer multiple period as information,
The wireless terminal device transitions from the sleep state to the awake state according to the integer multiple cycle included in the special beacon signal, and performs the transmission / reception operation at every integer multiple cycle. LAN power saving control method. A radio base station device;
A sleep state in which the data transmission / reception function is stopped, and at least one wireless terminal device that operates in power saving control to transition to any one of the awake state in which the data transmission / reception function is activated;
The radio base station apparatus transmits a beacon signal at a constant cycle and transmits a special beacon signal at an integral multiple of the fixed cycle;
Means for transmitting multicast and broadcast after transmitting the special beacon signal;
The wireless terminal device transitions the state from the sleep state to the awake state at a fixed period that satisfies the condition for receiving the special beacon signal, and completes the transmission / reception operation of desired data, and then from the awake state to the sleep state. A wireless base station device in a wireless LAN system having means for transitioning to
The means 1 transmits a period that is an integral multiple of the transmission period of the special beacon signal as a period for which the broadcast transmission is scheduled, and includes the period of the integral multiple as information in the special beacon signal,
The said means 2 transmits the said broadcast when there exists the said broadcast to transmit in the timing of the said integral multiple period contained in the said special beacon signal, The radio base station apparatus characterized by the above-mentioned.   5. The radio base station apparatus according to claim 4, wherein the means 2 does not transmit the multicast at the timing of the integer multiple period included in the special beacon signal. 6. The radio base station apparatus transmits a beacon signal at a constant cycle and transmits a special beacon signal at an integral multiple of the fixed cycle;
Means for transmitting multicast and broadcast after transmitting the special beacon signal;
The wireless terminal device transitions the state from the sleep state to the awake state at a fixed period that satisfies the condition for receiving the special beacon signal, and completes the transmission / reception operation of desired data, and then from the awake state to the sleep state. A wireless base station device in a wireless LAN system having means for transitioning to
The means 1 arbitrarily determines an integral multiple of a transmission period of the special beacon signal, and transmits the special beacon signal including the integral multiple period as information. . A radio base station device;
A sleep state in which the data transmission / reception function is stopped, and at least one wireless terminal device that operates in power saving control to transition to any one of the awake state in which the data transmission / reception function is activated;
The radio base station device transmits a beacon signal at a constant cycle, and transmits a special beacon signal at an integer multiple of the fixed cycle,
After sending the special beacon signal, send multicast and broadcast,
The wireless terminal device transitions the state from the sleep state to the awake state at a fixed period that satisfies the condition for receiving the special beacon signal, and completes the transmission / reception operation of desired data, and then from the awake state to the sleep state. A wireless terminal device in a wireless LAN system having means 1 for transitioning to
The means 1 transitions from the sleep state to the awake state according to a cycle that is an integral multiple of the transmission cycle of the special beacon signal included in the special beacon signal, and performs the transmission / reception operation every cycle of the integral multiple. A wireless terminal device that is implemented.

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