JP2007288728A - Power saved wireless lan multicast communication quality control method and radio base station device therefor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide power saved wireless LAN multicast communication quality control techniques with which communication quality of a multicast application can be maintained. <P>SOLUTION: An AP [3-5] transmits beacon signals in a fixed cycle and transmits DTIM beacon signals in a cycle where the beacon signals are intermittent. In a case [3-1] where an STA which operates under power saved control exists and an STA which receives a packet of multicast data exists, the AP [3-5] updates [3-6] information into the number of intermissions less than the number of intermissions in a timing to transmit a DTIM beacon signal [3-8]. In a case [3-2] where the STA that operates under power saved control does not exist or the STA which receives a packet of multicast data does not exist, the AP [3-5] updates [3-7] information on the number of intermissions into the number of intermission before a change into the number of intermission less than the number of intermissions in a timing to transmit a DTIM beacon signal [3-33]. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a power-saving wireless LAN multicast communication quality control method having a procedure for maintaining multicast communication quality in a wireless packet communication system in which a wireless base station and a wireless terminal operating with at least one power-saving control exist, and the method thereof The present invention relates to a radio base station apparatus.

In general, a wireless packet communication system is applied in a form using a wireless system as a transmission medium as a part of a wired network when configuring an entire communication network. That is, a wireless packet communication system is connected to a network interface at one end of a wired network, and communication between the wireless terminal and the wired terminal or the wireless terminal is performed by wireless connection.
In a wireless LAN communication system compliant with the conventional IEEE 802.11 standard (Non-Patent Document 1), a wireless terminal (STAtion (STA) operating in power saving mode (Power Save mode (PS mode)) is connected to a wireless base station ( When connected under the access point (AP)), the AP temporarily accumulates data packets addressed to the PS mode STA arrived from the wired network (NW) side. The wireless NW information (supported transmission rate, service set type (SSID), etc.) is notified to the STA under the AP using the beacon signal to be transmitted.Other main information notified by the beacon signal is the beacon transmission cycle. (Beacon Interval) information and the TIM (Traffic Indication Map) information element in the beacon frame shown in Fig. 1. The TIM information element includes Intermittent period information (number of intermittent beacons) [2-1] of a beacon signal (DTIM beacon) with a delivery traffic indication map (DTIM: Delivery Traffic Indication Map) transmitted intermittently of beacon transmission or the next DTIM beacon Counter value until the beacon is transmitted (the counter value is reduced each time a beacon is transmitted, and the beacon when it becomes 0 becomes a DTIM beacon) [2-2], and buffered packets addressed to the PS mode STA [2-3] etc., which are converted into a bitmap for each destination, etc. Here, the PS mode STA is a beacon by the STA based on the information of the Beacon Interval included in the beacon received before the PS mode is activated. Set the timing to receive the signal, and three times the set beacon signal transmission cycle (or every beacon cycle) The state transitions from active to active, and buffering information (information obtained by bit-mapping [2-3] for each destination) is acquired from the received beacon.Bitmap information for each destination in the TIM information element of the received beacon [ 2-3] Each PS mode STA notified that the packet is buffered starts a packet transmission / reception procedure in the PS mode defined in the IEEE 802.11 standard after receiving the beacon.

  A normal unicast packet communicates between the PS mode STA and the AP according to such a procedure, whereas reception of broadcast / multicast data packets in the PS mode follows the example of the procedure shown in FIG. FIG. 2 shows STA1 [1-5] and STA2 [1-6] operating in the PS mode, and STA3 [1-10] always operating in the active [1-13] (STA not operating in the PS mode). Is connected to AP [1-7]. AP [1-7] transmits DTIM beacons [1-2-1] to [1-2-3] transmitted at a cycle [1-4] that is an integral multiple of the beacon transmission cycle [1-3]. Immediately after that, when packets [1-1-1] to [1-1-3] of broadcast / multicast data are accumulated, the packets are distributed to each STA. As a delivery method, a broadcast / multicast data packet is transmitted after the CSMA / CA (Carrier Sense Multiple Access with Collision Avoidance) protocol having a procedure for avoiding a collision at the time of packet transmission defined in the IEEE 802.11 standard. To do. The PS mode STA changes the state from sleep to active at the timing of receiving the DTIM beacon, and receives a broadcast / multicast data packet. In other words, as described above, the PS mode STA sets the period [1-8] and [1-9] for receiving the beacon signal by itself, and transitions the state from sleep to active at the set timing [1-12]. In addition, the information on the transmission period [2-1] of the DTIM beacon of the TIM information element included in the beacon shown in FIG. 1 and the counter value [2-2] until the next DTIM beacon is transmitted. It must be set to actively transition the state [1-11] at the timing at which the DTIM beacon can always be received. Also, in STA3 [1-10] not operating in PS mode, when STA [1-5 or 1-6] connected in PS mode exists under the connected AP, STA3 [1-10] receives a broadcast / multicast data packet in the period of the DTIM beacon.

  However, in the conventional wireless packet communication system, information in which the AP transmits a beacon period and an intermittent period in which a DTIM beacon is intermittently transmitted is notified to the wireless terminal, and the wireless terminal side depends on the notification information. The control operation was expected to save power in the wireless terminal. However, when the beacon reception cycle is set to be long for the PS mode STA, a large delay time occurs in transmission / reception of the unicast packet. As a method for solving this problem, Patent Document 1 already requires real-time performance such as voice communication by setting an optimal beacon reception cycle according to the communication quality characteristics of the application used by the PS mode STA. A wireless LAN communication system that improves the communication quality of applications is disclosed.

IEEE Std 802.11, 1999 edition, MEDIUM ACCESS CONTROL (MAC) AND PHYSICAL (PHY) SPECIFICATIONS, (7.3.2.6 TIM, 11.2 Power management) Japanese Patent Laying-Open No. 2004-128949 (Patent No. 3654284) “Radio terminal apparatus and radio communication system using the same”

  In the conventional wireless packet communication system, the AP can expect a power saving effect by setting the beacon transmission cycle and the DTIM beacon intermittent cycle longer. However, since the multicast data packet is transmitted only after the transmission of the DTIM beacon, a large delay and delay fluctuation occur. For example, when an application that requires high communication quality such as video (moving image) stream distribution uses multicast, an STA that receives a packet of multicast data may interfere with reproduction of the application due to delay and delay fluctuation. Was assumed. In order to solve this problem, there is a method of setting the DTIM beacon period and the beacon period short in advance in the AP. However, if there is no STA that uses the multicast service, the AP can be saved in the PS mode. There was a problem that the effect of electric power generation was reduced. Further, the method for improving the communication quality of the application or reducing the packet delay according to the invention of Patent Document 1 maintains the communication quality when the PS mode STA transmits and receives unicast data. Can not be maintained. In addition, there is a problem that communication quality for downlink multicast from the AP to the wireless terminal cannot be improved.

  An object of the present invention is to provide a power-saving wireless LAN multicast communication quality control method and its base station capable of maintaining communication quality of a multicast application by a dynamic change method and priority control of beacon and DTIM beacon transmission periods in an AP. An apparatus is provided.

  Of the inventions disclosed in this specification, the outline of typical ones will be briefly described as follows.

  1st invention is comprised from the some radio | wireless terminal apparatus which transmits / receives data by radio | wireless packet communication with a radio base station apparatus, 1 or the said some radio | wireless terminal apparatus operate | moves by power-saving control, The said radio base station Transmits a beacon signal at a constant period and transmits a beacon signal with a delivery traffic display map at an intermittent period of the beacon signal that is an integral multiple of the constant period, and transmits the beacon signal and the beacon with the delivery traffic display map. The signal includes information on the number of intermittents corresponding to the fixed period and the intermittent period, respectively, and the wireless base station transmits broadcast and multicast data packets after transmitting the beacon signal with the distribution traffic indication map. Power-saving wireless LAN multicast communication product in wireless packet communication system In the control method, when there is one or a plurality of the wireless terminal devices operating in the power saving control and there are one or a plurality of the wireless terminal devices receiving the multicast data packet, The radio base station apparatus updates the information to an intermittent number less than the intermittent number at the timing of transmitting the beacon signal with the delivery traffic display map, and there is no wireless terminal apparatus that operates in power saving control, or When there is no wireless terminal device that receives a packet of multicast data, the wireless base station device transmits a beacon signal with a delivery traffic display map before changing to an intermittent number less than the intermittent number. The information on the intermittent number is updated to the intermittent number of times, and the radio base station apparatus is updated after each updated timing. , And transmits the delivery traffic display map with the beacon signal at a period corresponding to each of the information of said intermittent number.

  In the prior art, a beacon signal with a delivery traffic display map is transmitted at a constant intermittent period in which no change is made, whereas the method of the first invention is based on the presence or absence of a wireless terminal device operating in power saving control and multicasting. It differs from the prior art in that the intermittent transmission cycle of the beacon signal with a delivery traffic display map is dynamically changed at the corresponding timing depending on the combination of the presence or absence of a communication terminal.

  According to a second aspect of the present invention, a wireless base station apparatus includes a plurality of wireless terminal apparatuses that transmit and receive data by wireless packet communication, and one or a plurality of the wireless terminal apparatuses operate with power saving control, and the wireless base station Transmits a beacon signal at a constant period and transmits a beacon signal with a delivery traffic display map at an intermittent period of the beacon signal that is an integral multiple of the constant period, and transmits the beacon signal and the beacon with the delivery traffic display map. The signal includes information on the number of intermittents corresponding to the fixed period and the intermittent period, respectively, and the wireless base station transmits broadcast and multicast data packets after transmitting the beacon signal with the distribution traffic indication map. Power-saving wireless LAN multicast communication product in wireless packet communication system In the control method, when there is one or a plurality of the wireless terminal devices operating in the power saving control and there are one or a plurality of the wireless terminal devices receiving the multicast data packet, The radio base station apparatus updates information in a fixed cycle shorter than the fixed cycle at a timing of transmitting the beacon signal with the delivery traffic display map, and the radio base station device operates with power saving control. Is not present, or when the wireless terminal device that receives the multicast data packet does not exist, the constant before updating to the short constant period at the timing of transmission of the beacon signal with the delivery traffic indication map The information is updated periodically, and the wireless terminal device performs the update from the updated timing. And transmitting said beacon signal at a fixed period corresponding to each information having a predetermined period which is.

  In the prior art, the beacon signal is transmitted at a constant cycle without changing, whereas the method of the second invention is based on the combination of the presence / absence of a wireless terminal device operating with power saving control and the presence / absence of a multicast communication terminal. The point that the beacon signal transmission cycle is dynamically changed at the corresponding timing is different from the prior art.

  The present invention dynamically changes the intermittent transmission cycle of a beacon signal with a delivery traffic display map at a corresponding timing according to the combination of presence / absence of a wireless terminal device operating in power saving control and presence / absence of a multicast communication wireless terminal. However, unlike the prior art, this has the effect of improving the power saving effect and suppressing the delay and fluctuation of multicast.

  Further, the present invention is different from the prior art in that the transmission period of the beacon signal is dynamically changed at a corresponding timing depending on the presence / absence of a wireless terminal device operating in power saving control and the presence / absence of a multicast communication terminal. This has the effect of improving the power saving effect and suppressing the delay and fluctuation of multicast.

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

  FIG. 3 is a diagram showing a DTIM Period update opportunity according to the first embodiment of the present invention. AP [3-5] receives a multicast service under its control (within BSS) when one or more STAs operating in PS mode are communicating, and whether or not it operates in PS mode. When one or more STAs exist, the DTIM Period [2-1] described in the TIM information element (see FIG. 1) included in the beacon frame is updated to an appropriate value. Here, DTIM Period indicates the number of continuous beacons until the DTIM beacon is transmitted (the number of intermittent beacons). When DTIM Period = 2, a normal non-DTIM beacon is transmitted once between DTIM beacons. Is done. Further, DTIM Count [2-2] indicates a counter value until the next DTIM beacon is transmitted, and the count is decreased by 1 with beacon transmission. When DTIM Count = 0, this indicates that this beacon is a DTIM beacon. The AP transmits a DTIM beacon at a period according to the value of DTIM Period.

  FIG. 3 shows an example of an opportunity to update the information element (DTIM Period) and an update value selection method. First, there is no STA participating in the multicast service, AP [3-5] detects that STA [3-4] participates in the multicast service [3-1], and STA [ 3-4] is in the PS mode, or when another connected STA is in the PS mode, the AP [3-5] is the value of the DTIM period of the DTIM beacon [3-8] to be transmitted next Update [3-6]. The value to be updated here needs to consider an allowable delay time in order to maintain the quality of the application provided by the multicast service, and it is desirable to update the DTIM Period to a small value. However, when updating to a value that is too short, there is a possibility that the effect of the power saving control may be greatly reduced for PS mode STAs not participating in the multicast service. Therefore, the AP has the characteristics of the multicast application that provides the service. The optimum value according to the above is selected as the DTIM Period and must be updated.

  In the example of FIG. 3, DTIM Period = 5 before detection of participation in the multicast service, whereas in the updated DTIM beacon, DTIM Period = 2. Next, the AP [3-5] detects the withdrawal of the multicast service [3-2], and if no other STA connected to the AP participates in the multicast service, the DTIM beacon to be transmitted next is transmitted. The value of DTIM Period in [3-33] is updated [3-7]. The value updated here is preferably updated to a large value in order to increase the effect of power saving control for the PS mode STA. In the example of FIG. 3, the DTIM Period = 5, which is set initially, is returned to and the updated value is notified by the DTIM beacon. After that, when the AP [3-5] detects that the STA participates [3-3] in the multicast service, the value of the DTIM Period [3-22] of the DTIM beacon [3-21] to be transmitted next The procedure for updating is performed in the same manner.

  As is apparent from FIG. 3, AP [3-5] transmits a DTIM beacon in a short period (2) after joining the multicast service [3-1], and transmits multicast data transmitted after transmission of the DTIM beacon signal. Packets are also transmitted at short intervals. After leaving the multicast service [3-2], a DTIM beacon is transmitted in a long cycle (5). After joining the multicast service [3-3] again, the DTIM beacon is transmitted in a short cycle (2), and the multicast data packet transmitted after the transmission of the DTIM beacon signal is also transmitted in a short cycle. This has the effect of improving the power saving effect and suppressing the delay and fluctuation of multicast.

  As an example of the multicast service join / leave detection method, the STA performs the join / leave sequence with the multicast server using IGMP (Internet Group Management Protocol), etc., and the AP snoops this sequence. There is a method for detecting participation / withdrawal. In another method, the AP can use a multicast service joining / leaving detection method that joins when a multicast frame is received from a higher-level wired network and leaves when no multicast frame is received for a certain period of time.

  FIG. 4 is a flowchart of the DTIM Period update method in the AP according to this embodiment, and shows a control method in which the AP updates the DTIM Period. First, after starting AP activation [3-1-1], DTIM Period is set to an initial value (initial value is set to DTIM Period = 5 according to the example of FIG. 3) [3-1-21]. Next, it is determined whether a PS mode STA exists under the AP [3-1-2]. If the PS mode STA exists (Yes [3-1-3]), it is determined [3-1-4] whether there is an STA participating in the multicast service under the AP. When there is an STA participating in the multicast service (Yes [3-1-6]), it is determined [3-1-7] whether it is the current DTIM beacon transmission timing. If it is the DTIM beacon transmission timing (Yes [3-1-9]), the DTIM period is changed (DTIM Period = 2 according to the example of FIG. 3) and the DTIM beacon is transmitted [3-1-10]. In the control after the transmission is completed, it is determined [3-1-11] whether the PS mode STA exists under the AP. When the PS mode STA does not exist (No [3-1-12]), the DTIM Period is set to an initial value (DTIM Period = 5) [3-1-21]. If the PS mode STA exists (Yes [3-1-13]), it is determined [3-1-14] whether there is an STA participating in the multicast service under the AP. When there is no STA participating in the multicast service (No [3-1-15]), it is determined [3-1-17] whether it is the current DTIM beacon transmission timing. If it is the DTIM beacon transmission timing (Yes [3-1-19]), the DTIM beacon is transmitted after changing the DTIM Period (changed to the initial value of 5 according to the example of FIG. 3). After the transmission is completed, the control for updating the DTIM Period is repeatedly performed. When there is an STA participating in the multicast service (Yes [3-1-16]), a DTIM beacon is transmitted using a setting value of DTIM Period = 2.

  FIG. 5 is a functional block diagram of a device having a beacon information change processing function according to this embodiment, and shows a beacon information change control unit for changing beacon information. In FIG. 5, the multicast participation / withdrawal determination unit [5-1-10] determines the presence / absence of a STA receiving a multicast service, and the PS mode STA detection unit [5-1-12] The presence / absence of the STA is detected, and the multicast participation / withdrawal determination unit [5-1-10] and the PS mode STA detection unit [5-1-12] are detected by the beacon information change determination unit [5-1-11]. Notify If there is an STA participating in the multicast in the beacon information change determination unit [5-1-11] and the PS mode STA is connected, the information element change processing unit [5-1-1] in the beacon is connected. The beacon information element change processing unit [5-1-13] performs the beacon information element change process to the optimum value. Also, in the beacon information change determination unit [5-1-11], when there is no STA participating in the multicast or there is no PS mode STA, the beacon information element change processing unit [5-1-13]. Similarly, the beacon information element change processing unit [5-1-13] performs the beacon information element change process to the optimum value.

FIG. 6 is a diagram illustrating a change in beacon frame transmission cycle and a change opportunity according to the second embodiment of the present invention. The first embodiment changes the number of continuous beacons until the DTIM beacon is transmitted (the number of intermittent beacons), whereas the second embodiment changes the beacon transmission cycle. is there. AP [3-5] transmits a beacon in the BSS when one or more STAs operating in the PS mode are communicating and when there are one or more STAs receiving a multicast service. Change the cycle. In the example of FIG. 6, DTIM Period = 2, and when the AP detects [4-1] participation in the multicast service, the value of the Beacon Interval described in the beacon frame is set as an initial value. change to a shorter period than the _BT L [4-5] have _{BT S [4-6] (BT S} <BT L), then the DTIM beacon [4-7] for transmitting information of a beacon interval under AP Notify the connected STA. The transmission of the beacon transmitted after the DTIM beacon transmission is repeated at the changed value beacon period [4-6]. Next, when AP [3-5] detects that the multicast service is withdrawn [4-2], the value of Beacon Interval described in the beacon frame is changed to the initial value BT _L [4-5]. In the DTIM beacon [4-8] to be transmitted next, the Beacon Interval information is notified to the STA under the AP. Transmission of the beacon after the DTIM beacon transmission is repeated at the changed value of the beacon period BT _L [4-5]. Thereafter, similarly, when joining / withdrawing of the multicast service is detected, the beacon period is changed using the method described above.

As is clear from FIG. 6, since the DTIM Period remains 2, AP [3-5] has a short beacon period (BT _S ) after joining the multicast service [4-1], so the DTIM beacon is also a short period. Multicast data packets transmitted after (BT _S × 2) and transmitted after transmission of the DTIM beacon signal are also transmitted in a short cycle. Since the beacon period (BT _L ) is long after leaving the multicast service [4-2], the DTIM beacon is also transmitted with a long period (BT _L × 2). Since the beacon period (BT _S ) is short after joining the multicast service again [4-3], the DTIM beacon is also transmitted with a short period (BT _S × 2), and the multicast data packet transmitted after the transmission of the DTIM beacon signal is also short. Send at periodic intervals. This has the effect of improving the power saving effect and suppressing the delay and fluctuation of multicast.

FIG. 7 is a flowchart of a method of changing the Beacon Interval in the AP according to this embodiment, and shows a control method in which the AP updates the Beacon Interval. After AP activation start [4-1-1] First, the initial value Beacon Interval (initial value according to the example of FIG. 6 is a BT _L) set [4-1-21] to. Next, it is determined whether the PS mode STA exists under the AP [4-1-2]. When the PS mode STA exists (Yes [4-1-3]), it is determined [4-1-4] whether there is an STA participating in the multicast service under the AP. If there is an STA participating in the multicast service (Yes [4-1-6]), a determination [4-1-7] is made as to whether it is currently DTIM beacon transmission timing. If it is the DTIM beacon transmission timing (Yes [4-1-9]), the Beacon Interval is changed (BT _S (BT _S <BT _L ) according to the example of FIG. 6) and the DTIM beacon is transmitted [4-1]. −10]. After changing, it transmits a beacon according to the periodicity of BT _S. It is determined whether a PS mode STA exists under the AP [4-1-11]. When the PS mode STA does not exist (No [4-1-12]), the Beacon Interval is set to the initial value (BT _L ) [4-1-21]. If the PS mode STA exists (Yes [4-1-13]), it is determined whether there is an STA participating in the multicast service under the AP [4-1-14]. When there is no STA participating in the multicast service (No [4-1-15]), it is determined [4-1-17] whether or not it is the current DTIM beacon transmission timing. DTIM if a beacon transmission timing (Yes [4-1-19]), changing the Beacon Interval (modified BT _L of initial values according to the example of FIG. 6) to send the DTIM beacon. After the change, repeat the control to update the Beacon Interval. In the case where STA participating in the multicast service exists (Yes [4-1-16]), Beacon Interval transmits a beacon with BT _S.

  FIG. 8 is a functional block diagram of an apparatus having a beacon interval change processing function according to the present embodiment, and shows a beacon interval change control unit for changing the Beacon Interval. In FIG. 8, the multicast participation / withdrawal determination unit [7-1-10] determines the presence / absence of a STA receiving the multicast service, and the PS mode STA detection unit [7-1-12] is in the PS mode under the AP. The presence / absence of the STA is detected, and the multicast participation / withdrawal determination unit [7-1-10] and the PS mode STA detection unit [7-1-12] are respectively detected by the Beacon Interval change determination unit [7-1-11]. Notify The Beacon Interval change determination unit [7-1-11] notifies the Beacon Interval update processing unit [7-1-13] when there are STAs participating in the multicast and the PS mode STA is connected. The Beacon Interval update processing unit [7-1-13] changes the value of the Beacon Interval to the optimum value, and transmits a beacon according to the changed Beacon Interval. Also, the Beacon Interval change determination unit [7-1-11] notifies the Beacon Interval update processing unit [7-1-13] when there is no STA participating in the multicast or there is no PS mode STA. Similarly, a beacon is transmitted according to the changed Beacon Interval.

  As mentioned above, the invention made by the present inventor has been specifically described based on the embodiment. However, the invention is not limited to the embodiment, and various modifications can be made without departing from the scope of the invention. Of course.

It is a figure which shows the TIM information element of a beacon frame. It is a figure which shows the example of the broadcast / multicast sequence in PS mode in the conventional wireless packet communication system. It is a figure which shows the update opportunity of DTIM Period by Example 1 of this invention. It is a flowchart of the DTIM Period update method in AP by Example 1 of this invention. It is a block diagram of the apparatus which has a beacon information change control function by Example 1 of this invention. It is a figure which shows the change of the transmission period of the beacon frame by the Example 2 of this invention, and a change opportunity. It is a flowchart of the Beacon Interval change method in AP by Example 2 of this invention. It is a block diagram of the apparatus which has a beacon interval change control function by Example 2 of this invention.

Explanation of symbols

1-5, 1-6 ... STA (operating in PS mode), 1-10 ... STA (always active), 1-7 ... AP, 1-21-1-1-3 ... DTIM beacon , 1-3-1 to 1-3-8 ... beacon, 1-1-1 to 1-1-3 ... broadcast / multicast data, 3-8, 3-33, 3-21 ... DTIM beacon, 3-4 ... STA, 3-5 ... AP, 4-7, 4-8 ... DTIM beacon, 5-1-10 ... multicast participation / withdrawal determination unit, 5-1-11 ... beacon information change determination unit, 5-1-12 ... PS mode STA detection unit, 5-1-13 ... Information element update processing unit in beacon, 7-1-10 ... Multicast participation / withdrawal determination unit, 7-1-11 ... Beacon Interval change determination unit, 7-1- 12 ... PS mode STA detector, 7-1-13 ... Beacon Interv al Change processor

Claims (4)

The wireless base station apparatus includes a plurality of wireless terminal apparatuses that transmit and receive data by wireless packet communication, and one or a plurality of the wireless terminal apparatuses operate with power saving control. A beacon signal with a distribution traffic display map is transmitted at an intermittent period of the beacon signal that is an integral multiple of the constant period, and the beacon signal and the beacon signal with a distribution traffic display map are A wireless packet communication system that transmits broadcast and multicast data packets after the transmission of the beacon signal with the distribution traffic display map. Power wireless LAN multicast communication quality control method Te,
When there are one or more wireless terminal devices operating in the power saving control and there are one or more wireless terminal devices receiving the multicast data packet, the wireless base station device is: When the beacon signal with the delivery traffic display map is transmitted, the information is updated to the intermittent number less than the intermittent number, and the wireless terminal device operating with power saving control does not exist or the multicast data packet is received. When there is no wireless terminal device to perform, the wireless base station device transmits the beacon signal with the delivery traffic display map to the intermittent number before changing to the intermittent number less than the intermittent number at the timing of transmitting the beacon signal with the distribution traffic display map. Update the number information,
The wireless base station apparatus transmits the beacon signal with a delivery traffic display map at a period corresponding to each piece of information of the intermittent number from the updated timing and thereafter. Quality control method. The wireless base station apparatus includes a plurality of wireless terminal apparatuses that transmit and receive data by wireless packet communication, and one or a plurality of the wireless terminal apparatuses operate with power saving control. A beacon signal with a distribution traffic display map is transmitted at an intermittent period of the beacon signal that is an integral multiple of the constant period, and the beacon signal and the beacon signal with a distribution traffic display map are A wireless packet communication system that transmits broadcast and multicast data packets after the transmission of the beacon signal with the distribution traffic display map. Power wireless LAN multicast communication quality control method Te,
When there are one or more wireless terminal devices operating in the power saving control and there are one or more wireless terminal devices receiving the multicast data packet, the wireless base station device is: When the beacon signal with the delivery traffic display map is transmitted, the information is updated at a certain period shorter than the certain period, and the radio base station apparatus has no radio terminal apparatus that operates in power saving control, or When the wireless terminal device that receives the multicast data packet does not exist, the information is updated in the fixed period before the update in the short fixed period at the transmission timing of the beacon signal with the delivery traffic display map. ,
The wireless terminal device transmits the beacon signal at a fixed period corresponding to each information of the updated fixed period after the updated timings. Method. The wireless base station apparatus includes a plurality of wireless terminal apparatuses that transmit and receive data by wireless packet communication, and one or a plurality of the wireless terminal apparatuses operate with power saving control. A beacon signal with a distribution traffic display map is transmitted at an intermittent period of the beacon signal that is an integral multiple of the constant period, and the beacon signal and the beacon signal with a distribution traffic display map are Including a period and information on the number of intermittents corresponding to the intermittent period, and the wireless base station saves in a wireless packet communication system that transmits broadcast and multicast data packets after transmission of the beacon signal with the delivery traffic indication map. No power wireless LAN multicast communication quality control A base station apparatus,
A beacon with a delivery traffic display map when there is one or more of the wireless terminal devices operating in the power saving control and one or more of the wireless terminal devices receiving the multicast data packet; Information is updated to an intermittent number less than the intermittent number at the timing of signal transmission, and there is no wireless terminal device that operates with power saving control, or there is the wireless terminal device that receives the multicast data packet If not, at the timing to transmit the beacon signal with the delivery traffic display map, update the intermittent number information to the intermittent number before changing to the intermittent number less than the intermittent number,
A power-saving wireless LAN multicast communication quality control radio base station apparatus that transmits the beacon signal with a delivery traffic display map at a period corresponding to each piece of information of the intermittent number from the updated timing. The wireless base station apparatus includes a plurality of wireless terminal apparatuses that transmit and receive data by wireless packet communication, and one or a plurality of the wireless terminal apparatuses operate with power saving control. A beacon signal with a distribution traffic display map is transmitted at an intermittent period of the beacon signal that is an integral multiple of the constant period, and the beacon signal and the beacon signal with a distribution traffic display map are Including a period and information on the number of intermittents corresponding to the intermittent period, and the wireless base station saves in a wireless packet communication system that transmits broadcast and multicast data packets after transmission of the beacon signal with the delivery traffic indication map. No power wireless LAN multicast communication quality control A base station apparatus,
A beacon with a delivery traffic display map when there is one or more of the wireless terminal devices operating in the power saving control and one or more of the wireless terminal devices receiving the multicast data packet; Information is updated at a certain period shorter than the certain period at a signal transmission timing, and there is no wireless terminal apparatus that operates in power saving control, or there is the wireless terminal apparatus that receives the multicast data packet If not, at the timing of transmission of the beacon signal with the delivery traffic display map, update the information to the fixed period before updating to the short fixed period,
A power-saving wireless LAN multicast communication quality control radio base station apparatus that transmits the beacon signal at a fixed period corresponding to each information of the updated fixed period from each updated timing.

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