JP2005080162A - Radio base station device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To suppress a delay time by avoiding polling collision under a wireless network having one or more communication areas wherein interference occurs in the same frequency. <P>SOLUTION: The radio base station device for exchanging data with a plurality of radio terminal devices is provided with: a means for transmitting a beacon in the period of TB; a means for transmitting data after access control according to a CSMA/CA protocol; a means for transmitting to a radio terminal device a polling signal giving an instruction of down data transmission and up data transmission; a means for transmitting a polling signal to be transmitted to the radio terminal device preferentially over a packet to be transmitted according to the CSMA/CA protocol; and a means for making, when data having a period of a time interval T1 are transmitted or received, the beacon transmission interval TB to be m times of T1 (m is a natural number) and virtually making the time interval T1 to be a slot with a fixed time interval T2 having a relationship of T1=n T2 (n is a natural number). <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a wireless LAN, and more particularly to a wireless base station apparatus (access point) that schedules transmission / reception of data with periodicity by centralized management in the wireless LAN.

  Wireless LAN standardization work is carried out in, for example, IEEE 802.11. In the IEEE 802.11a standard standardized in IEEE 802.11, a wireless transmission speed of 54 Mbps at the maximum is realized, and the wireless transmission speed can be increased. (See Non-Patent Document 1).

  Along with such an increase in the wireless transmission speed, a stream type service such as voice and moving image equivalent to a wired system has been demanded even in a wireless LAN.

  Therefore, in IEEE 802.11, standardization for extending the MAC layer and performing QoS support is currently being promoted in task group E (TGe). In this task group E (TGe), as an access control method, HCF (hybrid coordination function) based on autonomous distributed control and HCF controlled channel access of centralized control using polling are being studied. .

  FIG. 6 is a diagram showing a communication procedure using centralized control by polling as means for transmitting and receiving data having periodicity.

  In this communication procedure, as shown in FIG. 6A, first, when the radio base station (AP [611]) does not use the channel between PIFSs [613] (idle), it is addressed to the STA [612]. The poll data frame [614] is transmitted to the STA [612] with the data packet and the poll frame as one frame.

  Next, the STA [612] that has normally received the poll data frame [614] leaves the SIFS [615], and sets the data packet addressed to the AP [611] and the acknowledgment ACK frame as one frame and the data ACK frame [616]. ] Is transmitted to AP [611].

  Next, AP [611] clears SIFS [617], returns ACK frame [618] to STA [612], and completes communication.

  When the traffic has periodicity, as shown in FIG. 6B, polling is performed in accordance with the transmission / reception signal cycle [619] by centralized control.

Thus, centralized control by polling easily realizes bandwidth guarantee and scheduling. Therefore, if centralized control by polling is used, VoIP is used for voice traffic and has a certain packet transmission period by CODEC (Compressor / DECompressor) which is a voice data compression technique, and requires bandwidth guarantee, low delay time, etc. (Voice over IP) can be applied to a wireless LAN.
http: // www. iee802. org / 11

  However, in the IEEE 802.11 standard, four frequency channels are allocated, and when the number of wireless LAN communication areas is increased, communication is performed by sharing the same frequency in the adjacent area or the same area.

FIG. 7 is a diagram illustrating an example of communication in the same frequency adjacent area.
In FIG. 7, the wireless base station 1 (AP1 [711]) and the wireless terminal device 1 (STA1 [713]) in the communication area A [715] and the wireless base station 2 (AP2 [712] in the communication area B [716] ) And the wireless terminal device 2 (STA2 [714]), the interference area A [717] given by the AP1 [711] is wider than the communication area A [715]. Interference area B [718] given by AP2 [712] is also wider than the area of communication area B [716]. The interference area A [717] and the communication area B [716] partially overlap each other. Also, the interference area B [718] and the communication area A [716] partially overlap.

  Therefore, when AP1 [711] and AP2 [712] simultaneously transmit poll frames, a collision of poll frames always occurs. In the case of traffic having periodicity in transmission intervals such as VoIP, once a collision occurs, the collisions occur continuously.

FIG. 8 is a diagram illustrating an example of a pole frame collision that occurs in the communication environment of FIG.
As shown in FIG. 8, AP1 [811] and AP2 [812] transmit poll data frames [819] and [820] simultaneously after PIFS [815] and [816] in the communication environment of FIG. In this case, STA1 [813] and STA2 [814] on the receiving side generate a poll data frame reception error [823] due to collision.

  In the case of VoIP, since there is a transmission periodicity, next-period transmission poll data frames [821] and [822] collide continuously. This collision also causes a delay increase problem for VoIP traffic requiring a low delay delay time.

  As described above, in the above-described centralized control by polling, the wireless base station performs polling immediately after the PIFS time in a wireless network environment having one or more communication areas in which interference occurs at the same frequency. There was a problem that the nature was large. Further, the above-described centralized control by polling has a problem that in the case of traffic having a transmission periodicity such as VoIP, there is a high possibility of continuous collisions and the delay time increases. And the above-mentioned HCF controlled channel access does not solve these problems.

  Therefore, in view of such circumstances, the present invention uses polling between a wireless base station device (access point) and a wireless terminal device (station) in a wireless network environment having one or more communication areas in which interference occurs at the same frequency. To provide a radio base station apparatus that avoids polling collisions and suppresses delay time for traffic requiring low delay by performing radio communication scheduling when transmitting and receiving data having the same periodicity With the goal.

  According to the present invention, the above problem is solved by the following means.

  The first invention is a wireless base station device that transmits and receives data by wireless packet communication with a plurality of wireless terminal devices, a means for transmitting a beacon for notifying basic information of a wireless network at a period between TBs; Means for transmitting data after access control according to the CSMA / CA protocol, transmission of downlink (radio base station apparatus to radio terminal apparatus direction) data, and transmission of uplink (radio terminal apparatus to radio base station apparatus direction) data Means for transmitting a polling signal for instructing to the wireless terminal device, means for transmitting the polling signal to be transmitted to the wireless terminal device in preference to a packet transmitted according to the CSMA / CA protocol, and a period of the time interval T1 The beacon transmission interval TB is set to m times T1 (m is a natural number), and The (n is a natural number) the time interval T1 T1 = n · T2 is a radio base station apparatus comprising: means for virtually slotted, characterized in that it comprises at fixed time intervals T2 having relationships.

  According to a second aspect of the present invention, in the radio base station apparatus according to the first aspect of the present invention, the usage status of the slotted virtual slot of the time interval T2 is further set to (1) unused, (2) use by beacon or polling. (3) Storage means for classifying into use other than beacon or polling and storing it for each cycle (time interval T1), and starting transmission / reception processing of data having periodicity of the time interval T1 from the i-th cycle In this case, the polling signal is selected in synchronism with the head of the selected virtual slot by selecting the virtual slot stored in (1) unused and the storage means in all cycles before the i-1th cycle. And a means for starting the transmission process.

  According to a third aspect of the present invention, in the radio base station apparatus according to the first aspect of the present invention, the usage status of the slotted virtual slot of the time interval T2 is (1) unused, (2) used by beacon or polling. (3) Storage means for classifying into use other than beacon or polling and storing it for each cycle (time interval T1), and starting transmission / reception processing of data having periodicity of the time interval T1 from the i-th cycle In all cases before the (i-1) -th cycle, (1) virtual slots stored in the storage means and (3) uses other than beacon or polling and stored in the storage means And a means for selecting a virtual slot that is least frequently used and starting transmission processing of the polling signal in synchronization with the head of the selected virtual slot. Is a wireless base station apparatus according to claim.

  According to a fourth invention, in the radio base station apparatus according to any one of the first to third inventions, when transmitting the beacon, a beacon or a polling signal is transmitted from another radio base station. Investigation means for investigating whether or not it is performed at a time interval equal to or greater than TB; and means for transmitting a beacon when a beacon or a polling signal from the other radio base station is not found by the investigation in the investigation means, When a beacon or polling signal from the other radio base station is found by the investigation in the investigation means, the discovered beacon or polling signal is synchronized with the head of a virtual slot, and the other Investigate whether or not a beacon or polling signal is transmitted from the wireless base station, and store information of the investigation result -Conpolation signal status storage means, based on the information of the investigation result stored in the beacon polling signal status storage means, select a virtual slot in which the beacon or polling signal of the other radio base station is not transmitted, And a means for transmitting a beacon in synchronization with the head of the selected virtual slot.

  In the prior art, a scheduling method for a data transmission / reception procedure having periodicity is not defined in a wireless network environment having one or more communication areas at the same frequency, whereas in the first invention, periodicity is not provided. When transmitting / receiving data having the data, the data transmission / reception cycle is virtually slotted at regular time intervals, and the transmission / reception processing is started in synchronization with the head of the virtual slot. Therefore, according to the first aspect of the invention, radio packet scheduling can be performed. Therefore, according to the first aspect of the invention, it is possible to avoid polling collisions and suppress delay time.

  Also, in the conventional technology, when polling is used as a data transmission / reception procedure having periodicity in a wireless network environment having one or more communication areas in which interference occurs, there is a possibility that collision between polling may occur. In the second invention, when transmitting and receiving data having periodicity, the radio base station apparatus uses a radio channel that is not used for each virtual slot in the first invention, used by beacon or polling, other than beacon or polling. Investigate usage and remember the findings. The second aspect of the invention repeats this investigation a plurality of times as one period, selects a virtual slot that has not been used until the period immediately before performing the polling signal transmission process, and starts in synchronization with the head. Therefore, according to the second invention, it is possible to schedule radio packets, avoid collision of polling signals, and suppress delay time.

  Also, in the conventional technology, when polling is used as a data transmission / reception procedure having periodicity in a wireless network environment having one or more communication areas in which interference occurs, there is a possibility that collision between polling may occur. In the third invention, when transmitting and receiving data having periodicity, the radio base station apparatus stores the investigation result in the second invention, and repeats this for a plurality of times as one period, thereby transmitting the polling signal. A virtual slot that has not been used for beacon or polling up to the period immediately before performing and has the lowest channel use frequency is selected and started in synchronization with the head. Therefore, according to the third invention, it is possible to perform scheduling of radio packets, avoid collision of polling signals, and suppress delay time.

  In the fourth invention, unlike the prior art, the radio base station apparatus checks the transmission timing of a beacon or polling signal transmitted by another radio base station apparatus for a certain period, and transmits the beacon or polling transmitted from the other radio base station apparatus. If a signal is not found, a beacon is transmitted immediately. If a beacon or polling signal transmitted from another radio base station device is found, the head of the virtual slot is synchronized with the beacon, and another beacon or polling is performed for each virtual slot. The presence or absence of signal transmission is investigated, the investigation result is stored, and a beacon is transmitted in a virtual slot in which no other beacon or polling signal is transmitted. Therefore, according to the fourth invention, it is possible to perform scheduling of radio packets in cooperation with other radio base station apparatuses, avoid collision of polling signals, and suppress delay time.

  The best mode for carrying out the present invention will be described in detail with reference to the accompanying drawings.

  FIG. 1 is a diagram showing an embodiment of the first invention. In the embodiment of the first invention, scheduling is performed using slotting.

  Before transmitting / receiving VoIP data, the radio base station AP [101] sets the beacon transmission cycle TB [103] to m times the VoIP data transmission / reception interval T1 [102] as shown in FIG. X). A beacon means a control frame.

  Next, as shown in FIG. 1B, the radio base station AP [101] sets a time longer than the VoIP data transmission / reception procedure time TR [117] using polling to T2 [118] (T2> TR). Set to. However, the radio base station AP [101] sets T2 so that the relationship between T1 and T2 is T1 = n × T2 (n = 1, 2, 3,...).

  Next, as shown in FIG. 1C, the radio base station AP [111] virtually divides T1 into n virtual slots in units of time T2. As shown in FIG. 1C, slot numbers 1 to n [118] are attached to the n virtual slots.

  Next, the radio base station AP [111] starts transmitting a beacon.

  Next, when the wireless base station AP [111] transmits / receives VoIP data having a periodicity of T1 [102] (time: TR [117]), the timing synchronized with the head of the virtual slot whose time interval is T2 The transmission / reception procedure time TR [117] is started.

  As described above, according to the first embodiment of the present invention, when transmitting / receiving VoIP data having periodicity, the timing of unused or infrequently used is specified in all the periods before starting transmission / reception. Will be able to. Since the timing of unused or low usage frequency in all cycles before starting transmission / reception is likely to be unused or low usage frequency even after starting transmission / reception, according to the embodiment of the first invention, VoIP data can be transmitted and received at a timing that is not used or is not frequently used.

  As described above, according to the embodiment of the first invention, traffic can be scheduled by the radio base station AP, so that polling collisions can be reduced, and for traffic requiring low delay. The delay time can be reduced.

  FIG. 2 is a diagram showing an embodiment of the second invention. In the embodiment of the second invention, the channel usage status is investigated using virtual slots.

  As shown in FIG. 2 (a), the radio base station AP first sets the VoIP data transmission / reception cycle T1 [201] to the virtual slot by the method shown in the first embodiment before the transmission / reception of VoIP data. Slotting is performed every T2 [202].

  Next, the radio base station AP assigns a slot number to a plurality of virtual slots T2 [202] in the VoIP data transmission / reception cycle T1 [201] [203].

  Next, the radio base station AP investigates the usage status of each virtual slot. Here, the usage status of each virtual slot includes (1) Unused radio channel [204], (2) Beacon or polling use [205], (3) Beacon or polling use [206] 3 There are aspects.

The radio base station AP repeats this investigation a plurality of times (k times) for the virtual slots with slot numbers 1 to n in units of T1. Specifically, as illustrated in FIG. 2B, the radio base station AP performs the above investigation from the virtual slots of slot numbers 1 to n [213] in T1 ₁ [213], T1 _k [215]. To the virtual slots of slot numbers 1 to n [213] in FIG. Here, k is an arbitrary integer.

  The wireless base station AP investigates the investigation result of the usage status of the virtual slot (any one of the above (1), (2), and (3)) divided by the VoIP transmission period and the slot number. Store as a result map.

  FIG. 3A is a diagram illustrating an example of a survey result map stored in the storage unit.

  In the survey result map shown in FIG. 3A, for example, in the first cycle [213], the virtual slot with slot number 2 is unused (1) and the virtual slots with slot numbers 1 and 3 are beacons or polled. Is stored (2), and the investigation result is stored that the virtual slots of slot numbers 4 to n are used (3) by means other than beacon or polling.

When the timing at which the VoIP data transmission / reception starts is the i-th cycle T _i , the radio base station AP obtains the survey results from the cycle T ₁ where the survey is started to the i−1-th cycle T _i−1. Reading from the map, the slot number in which the investigation result of unused (1) is stored in all periods (period T ₁ to period T _i-1 ) is selected. The radio base station AP in the present embodiment reads the survey result map shown in FIG. 3A from the storage means and selects slot number 2.

  Then, as shown in FIG. 3B, the radio base station AP [311] has a period T1 [313] at a timing synchronized with the head of the virtual slot with the slot number 2 selected in the i-th [317] period. ] VoIP data transmission / reception procedure ([314], [315], [316]) is started.

As described above, according to the embodiment of the second invention, the VoIP data transmission / reception procedure ([314], [315], [316]) having the periodicity of T1 [313] starts transmission / reception. It is started at the timing synchronized with the head of the virtual slot of slot number 2 in which the investigation result of unused (1) is stored in all the previous cycles (cycle T ₁ to cycle T _i-1 ).

If it is unused (1) in all periods (period T ₁ to period T _i-1 ) before the start of transmission / reception, it is highly possible that the transmission / reception is not used after the start of transmission / reception. According to the example, polling collisions can be reduced, and the delay time can be reduced for traffic requiring low delay.

  Next, an embodiment of the third invention will be described.

The radio base station AP according to the third embodiment of the present invention, when the timing of starting VoIP data transmission / reception is the i-th cycle T _i , is the i−1th cycle T _i− from the cycle T ₁ in which the investigation is started. The survey result up to _{1 is} read from the survey result map, and the slot number in which the survey result of unused (1) is stored or the slot number in which the survey result of use other than beacon or polling (3) is stored The slot number with the lowest use frequency is selected. The radio base station AP in the present embodiment reads the survey result map shown in FIG. 3A from the storage means and selects slot number 2.

  Then, as shown in FIG. 3B, the radio base station AP [311] has a period T1 [313] at a timing synchronized with the head of the virtual slot with the slot number 2 selected in the i-th [317] period. ] VoIP data transmission / reception procedure ([314], [315], [316]) is started.

As described above, according to the embodiment of the third invention, the VoIP data transmission / reception procedure ([314], [315], [316]) having the periodicity of T1 [313] starts transmission / reception. Timing that is not used (1) or used by other than beacon or polling (3) in the previous cycle (cycle T ₁ to cycle T _i-1 ) and synchronized with the beginning of the virtual slot of slot number 2 with the lowest use frequency Start with.

When there is no unused (1) virtual slot in the period (period T ₁ to period T _i-1 ) before the start of transmission / reception, it is a usage (3) other than a beacon or polling and the usage frequency is minimum The slot becomes a virtual slot that is highly likely to be unused (1) or used by other than beacon or polling (3) even after the start of transmission / reception, and to be least frequently used. Therefore, according to the embodiment of the third invention, polling collision can be reduced, and the delay time can be suppressed for traffic requiring low delay.

  FIG. 4 is a diagram showing an embodiment of the fourth invention. In the embodiment of the fourth invention, the beacon transmission timing is determined.

  As in the case of the embodiment of the first invention, the radio base station AP first sets the beacon transmission period to a certain period TB = notifying the basic information of the radio network to all radio stations. Set to m × T1.

  Further, the radio base station AP sets a virtual slot and slots the VoIP data transmission / reception cycle T1. Again, the radio base station AP assigns slot numbers 1 to n to each slot.

  Next, as shown in FIG. 5, the radio base station [412] is used by a beacon transmitted by another radio base station AP [411] other than its own AP [412] in each virtual slot before beacon transmission. Is checked for the time of beacon period TB [513]. In the embodiment of the fourth invention, the investigation time is the beacon period TB, but the investigation time may be a time longer than the beacon period TB. The radio base station AP [412] conducts this investigation at intervals of T1 [512] in the same manner as in the second embodiment and the third embodiment. [516] times.

  The radio base station AP [412] transmits a beacon immediately if a beacon from another radio base station AP [411] is not found from the investigation result.

  On the other hand, when a beacon of another AP is found from the investigation result, the radio base station AP [412] continues to investigate the beacon for each virtual slot at a TB interval from the start of another beacon transmission.

  The radio base station AP [412] synchronizes the virtual slot of the own radio base station AP [412] with the virtual slot of the other radio base station AP [411] before transmitting the beacon.

  Then, the radio base station AP [412] transmits a beacon in synchronization with the head of the virtual slot to which the beacon of another radio base station AP [411] is not transmitted.

  As described above, according to the embodiment of the fourth invention, the beacon of the own radio base station AP can be transmitted at a timing when there is a high possibility that another radio base station AP is not transmitting the beacon. . Therefore, according to the embodiment of the fourth invention, the radio base station AP can perform scheduling of radio packets in cooperation with other radio base stations AP having the same system, thereby reducing polling collisions. In addition, the delay time can be suppressed for traffic requiring low delay.

  In the above-described fourth embodiment, beacons transmitted from other radio base stations AP are used when determining the beacon transmission timing. However, in the present invention, the beacon transmission timing is set to other values. It can also be determined using a polling signal transmitted from the radio base station AP.

  The embodiments described above are merely examples and do not limit the present invention. Various changes, modifications, and omissions within the scope of the technical idea and aspect of the present invention can be easily made by those skilled in the art. Accordingly, the invention is limited only as limited by the following claims and the equivalents thereto.

It is a figure which shows the Example of 1st invention which performs scheduling using slotting. It is a figure which shows the Example of 2nd invention which investigates the usage condition of a virtual slot. It is a figure which shows an example (a) of the investigation result map memorize | stored in the memory | storage means, and the transmission timing (b) of VoIP data. In the Example of 4th invention, it is a figure which shows a mode that the transmission timing of a beacon is determined. In the Example of 4th invention, it is a figure which shows a mode that the channel usage condition investigation using a beacon is performed. It is a figure which shows the communication procedure using the centralized control by polling as a transmission / reception means of the data which has periodicity. It is a figure which shows the example of communication of the same frequency adjacent area. It is a figure which shows the example of the pole frame collision which arises in the same frequency adjacent area.

Explanation of symbols

101 Wireless base station AP
102 VoIP data transmission / reception interval T1
103 Beacon transmission period TB
111 Radio base station AP
117 VoIP data transmission / reception procedure time TR
118 T2 (T2> TR)
120 Slot number 1 to n
201 VoIP data transmission / reception cycle T1
203 Slot number 204 Radio channel not used (1)
205 Use by beacon or polling (2)
206 (3) Use other than beacon or polling 212 T1
213 Slot number 1 to n
215 T1 _k
311 Wireless base station AP
313 period T1
314, 315, 316 VoIP data transmission / reception procedure 317 i-th 411 Other radio base station AP
412 Own radio base station AP
512 T1
513 Beacon period TB
514 1
516k
611 Wireless base station AP
612 STA
613 PIFS
614 Poll Data Frame 616 SIFS
617 SIFS
618 ACK frame 619 Transmission / reception transmission period 711 Wireless base station 1 (AP1)
712 Wireless base station 2 (AP2)
713 Wireless terminal device 1 (STA1)
714 Wireless terminal device 2 (STA2)
715 Communication area A
716 Communication area B
717 Interference area A
718 Interference area B
811 AP1
812 AP2
813 STA1
814 STA2
815, 816 PIFS
819, 820 Poll data frame 821, 822 Poll data frame 823 Poll data frame reception error due to collision

Claims (4)

In a wireless base station device that transmits and receives data by wireless packet communication with a plurality of wireless terminal devices,
Means for transmitting a beacon to broadcast basic information of a wireless network in a period between TBs;
Means for transmitting data after access control according to the CSMA / CA protocol;
Means for transmitting a polling signal instructing transmission of downlink (radio base station apparatus to radio terminal apparatus direction) data and transmission of uplink (radio terminal apparatus to radio base station apparatus) data to the radio terminal apparatus;
Means for preferentially transmitting a polling signal to be transmitted to the wireless terminal device over a packet transmitted in accordance with a CSMA / CA protocol;
When transmitting and receiving data having periodicity of time interval T1, the transmission interval TB of the beacon is set to m times T1 (m is a natural number), and the time interval T1 is T1 = n · T2 (n is a natural number) Means for virtually slotting at a constant time interval T2 having the relationship:
A radio base station apparatus comprising: The radio base station apparatus according to claim 1, further comprising:
The slotted time slot T2 virtual slot usage status is classified into (1) unused, (2) use by beacon or polling, and (3) use other than beacon or polling for one period (time interval T1). Storage means for storing each)
When transmission / reception processing of data having periodicity of the time interval T1 is started from the i-th cycle, (1) unused and stored in the storage means in all cycles before the i-1th cycle. Means for starting a polling signal transmission process in synchronization with the head of the selected virtual slot;
A radio base station apparatus comprising: The radio base station apparatus according to claim 1, further comprising:
The slotted time slot T2 virtual slot usage status is classified into (1) unused, (2) use by beacon or polling, and (3) use other than beacon or polling for one period (time interval T1). Storage means for storing each)
When transmission / reception processing of data having periodicity of the time interval T1 is started from the i-th cycle, (1) unused and stored in the storage means in all cycles before the i-1th cycle. Or (3) use other than beacon or polling and a virtual slot that is stored in the storage means and has the lowest use frequency, and synchronizes with the head of the selected virtual slot. Means for starting the transmission process;
A radio base station apparatus comprising: The radio base station apparatus according to any one of claims 1 to 3, further comprising:
Investigation means for investigating whether or not a beacon or a polling signal is transmitted from another radio base station at a time interval equal to or greater than TB when transmitting the beacon;
Means for transmitting a beacon when a beacon or polling signal from the other radio base station is not found by the investigation in the investigation means;
When a beacon or polling signal from the other radio base station is found by the investigation in the investigation means, the discovered beacon or polling signal is synchronized with the head of a virtual slot, and the other Beacon polling signal status storage means for investigating whether or not a beacon or polling signal is transmitted from the wireless base station, and storing information of the investigation result;
Based on the information of the investigation result stored in the beacon polling signal status storage means, a virtual slot in which a beacon or polling signal of the other radio base station is not transmitted is selected, and the head of the selected virtual slot is selected. Means for transmitting beacons synchronously;
A radio base station apparatus comprising: