JP3938752B2 - Packet communication method and system - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a wireless LAN, and relates to a wireless packet communication technique showing a procedure of retransmission control when a packet collision or a propagation error occurs when a wireless base station performs wireless communication by centralized management.
[0002]
[Prior art]
As a conventional technique, there is an IEEE802.11a standard standardized by IEEE802.11 which is standardizing a wireless LAN, and this wireless transmission speed realizes a maximum of 54 Mbps. Along with such high-speed wireless LAN, stream-type services such as voice and video equivalent to those of wired systems are required. Therefore, in IEEE 802.11, standardization for extending the MAC layer and performing QoS support is currently underway as IEEE 802.11 TGe. Thus, as an access control method, an EDCF (Enhanced Distributed Coordination Function) based on autonomous distributed control and an HCF (Hybrid Coordination Function) having a centralized control function are provided.
[0003]
When the IEEE 802.11 TGe standard is adapted to VoIP used in voice traffic, VoIP requires bandwidth guarantee, low delay time, and low packet discard rate. In addition, as a feature of VoIP, the transmission cycle of VoIP packets is a constant interval by CODEC (COmpressor / DECompressor) which is a voice data compression technique.
[0004]
In order to satisfy the above conditions, an HCF having a centralized control function by a radio base station that can easily realize bandwidth guarantee and transmission period scheduling is one solution.
[0005]
The procedure of the packet communication method in the HCF will be described with reference to FIGS. FIG. 15 is a diagram illustrating a packet communication method in the upstream direction from the wireless terminal (STA) to the wireless base station (AP), and FIG. 16 is a packet in the downstream direction from the wireless base station (AP) to the wireless terminal (STA). It is a figure which shows the communication method. In the following description, the direction from the radio terminal (STA) to the radio base station (AP) is the uplink direction, and the direction from the radio base station (AP) to the radio terminal (STA) is the downlink direction.
[0006]
As shown in FIG. 15, the radio base station (AP) [111] has a PIFS (Polling InterFrame) time shorter than a DIFS (DCF InterFrame Space) time used before data frame transmission in autonomous distributed control (DCF). Space) [113] If it is idle, the poll frame [114] is transmitted to the wireless terminal (STA) [112]. As a result, the poll frame is transmitted with priority over frames by other autonomous distributed control.
[0007]
The poll frame [114] includes the channel usage period (TXOP: Transmission Opportunity) [119] information of the polled wireless terminal (STA) [112], and guarantees communication between TXOP [119]. Poll frame [114] The wireless terminal (STA) [120] other than the destination is set to transmission standby (NAV) [121] during the TXOP period.
[0008]
The wireless terminal (STA) [112] that has normally received the Poll frame [114] transmits a data frame [116] to the wireless base station (AP) [111] with a space between SIFS (Station InterFrame Space) [115]. The wireless base station (AP) [111] vacates SIFS [117] and completes the communication by returning an acknowledgment packet (ACK frame) [118] to the wireless terminal (STA) [112].
[0009]
Also, as shown in FIG. 16, if the radio base station (AP) [111] is idle for a time PIFS [113] shorter than the DIFS time used before data frame transmission in autonomous distributed control (DCF), the poll frame [114] is transmitted to the wireless terminal (STA) [112]. As a result, the poll frame is transmitted with priority over frames by other autonomous distributed control.
[0010]
The poll frame [114] includes the channel usage period (TXOP: Transmission Opportunity) [119] information of the polled wireless terminal (STA) [112], and guarantees communication between TXOP [119]. Poll frame [114] The wireless terminal (STA) [120] other than the destination is set to transmission standby (NAV) [121] during the TXOP period.
[0011]
The radio base station (AP) [111] that has transmitted the poll frame [114] transmits the data frame [116] to the radio terminal (STA) [112] with a gap between SIFS [115]. The wireless terminal (STA) [112] that has normally received the data frame [116] returns an acknowledgment packet (ACK frame) [118] to the wireless base station (AP) [111] with a gap between SIFS [117]. To complete the communication. By using such an HCF procedure, scheduling and bandwidth guarantee by centralized management of the radio base station AP can be performed.
[0012]
However, in the IEEE802.11 standard, four frequency channels are allocated, and when the number of wireless LAN communication areas increases, communication overlaps in adjacent areas and shares the same frequency. FIG. 17 is a diagram illustrating an example of communication in the same frequency adjacent area. As shown in FIG. 17, the radio base station (AP1) [211] and the radio terminal (STA1) [213] communicate in the area A [215], and the radio base station (AP2) [212] and the radio terminal ( STA2) [214] is communicating in area B [216].
[0013]
Since area A [215] and area B [216] overlap and have the same frequency, all the radio stations share the same frequency and perform communication. In such an environment, when communication is performed using the HCF in the areas A [215] and B [216], a frame collision always occurs when a poll frame is transmitted simultaneously. Alternatively, in the case of communication by traffic having periodicity in transmission intervals such as VoIP, collisions occur continuously when the transmission cycle is synchronized.
[0014]
FIG. 18 is a diagram illustrating an example of a Poll frame collision by the HCF procedure in the same frequency adjacent area. As shown in FIG. 18, when the Poll frames [319] and [320] are transmitted from the radio base stations (AP1) [311] and (AP2) [312] at the same time after PIFS [315] and [316], they are received. In the wireless terminal (STA1) [313] and (STA2) [314] on the side, a poll frame reception error [323] due to collision occurs. In the case of VoIP, since the transmission interval is periodic, when the transmission period is synchronized, the next period transmission poll frames [321] and [322] continuously collide. This increases the delay of the VoIP packet and the packet discard rate.
[0015]
As another conventional retransmission method using HCF, for example, there is a method disclosed in Patent Document 1. FIG. 19 is a diagram illustrating a poll retransmission method when there is no data frame reception expected after transmission of a poll frame. As shown in FIG. 19, the radio base station (AP) completes transmission of the Poll frame [3114], and after receiving SIFS [3414] and receiving no data frame [3413], after performing carrier sense between PIFS [3415], If the line is not used, the radio base station (AP) retransmits the poll frame [3412] when no carrier is detected during Backoff [3417] in which random time carrier sense, which is a collision avoidance period, is performed. The poll frame retransmission method of Patent Document 1 is a method using DCF.
[0016]
[Patent Document 1]
JP 2002-319895 A
[0017]
[Problems to be solved by the invention]
The problem to be solved by the present invention is that, in the prior art, when VoIP communication is performed using HCF in the same frequency adjacent area, a poll frame is transmitted immediately after the PIFS time. Collisions occur due to simultaneous frame transmission. In addition, the poll frame retransmission method using only DCF at the time of retransmission according to Patent Document 1 is autonomously distributed, and therefore increases the delay time due to the transmission standby period as compared with the HCF that transmits preferentially. Further, since traffic such as VoIP has a periodicity in transmission intervals and there is a possibility of continuous collisions, there is a problem that the delay time of the data packet and the packet discard rate are increased.
[0018]
The present invention has been carried out against this background, and is based on the base station centralized control using HCF, and the retransmission procedure when a poll frame collides in a wireless network having overlapping areas of the same frequency adjacent area. It is an object of the present invention to provide a packet communication method and system capable of providing a collision avoidance method and suppressing a data packet delay time and a packet discard rate.
[0019]
[Means for Solving the Problems]
A first aspect of the present invention is a packet communication method, and for data transfer in the uplink direction, a data packet to be transmitted to a second radio station periodically arrives at the first radio station, If the second wireless station does not detect a carrier by performing carrier sense for a first fixed period every time the data packet arrives, the second wireless station acquires a communication right from the second wireless station to the first wireless station. The first wireless station transmits the data packet to the second wireless station after a second fixed period shorter than the first fixed period after receiving the communication right acquisition frame. This is a packet communication method for transmitting a loaded data frame.
[0020]
Here, a feature of the present invention is that the second wireless station receives the communication right acquisition frame addressed to the first wireless station from the first wireless station after the second predetermined period of time after completion of transmission. If the data frame is not normally received, a random number N is generated, and the communication right acquisition frame is repeatedly retransmitted N times until the data frame is received from the first wireless station. After retransmitting the communication right acquisition frame addressed to the first wireless station, stop retransmission of the communication right acquisition frame if the data frame from the first wireless station is not received after the second predetermined period. When the first wireless station generates the data packet and the communication right acquisition frame is not normally received, the first wireless station performs carrier sense for a third fixed period longer than the first fixed period, and When not detecting the carrier is in place to further conduct random time carrier sense, and transmits the second of said data frame addressed to the wireless station at the time of not detecting the result carrier.
[0021]
For data transfer in the downlink direction, according to the packet communication method of the present invention, a data packet to be transmitted to the first radio station periodically arrives at the second radio station, and the second radio station If no carrier is detected by performing carrier sense for a first fixed period for each period in which the data packet is generated, a communication right acquisition frame is transmitted from the second wireless station to the first wireless station, Further, after the second wireless station completes transmission of the communication right acquisition frame, data in which the data packet is put on the first wireless station with a second fixed period shorter than the first fixed period. A packet communication method for transmitting a frame.
[0022]
Here, a feature of the present invention is that the second radio station receives the data from the first radio station after the second predetermined period after the data frame transmission addressed to the first radio station is completed. When an ACK frame indicating that the data frame has been normally received is not received, a random number N is generated, and the communication right acquisition frame and the data frame are received N times until an ACK frame is received from the first wireless station. Repeatedly retransmits the ACK frame from the first radio station after the second predetermined period after retransmitting the communication right acquisition frame and the data frame addressed to the first radio station N times. If not received, retransmission of the communication right acquisition frame and the data frame is stopped, and carrier sense is performed for a third fixed period longer than the first fixed period. When the result does not detect the carrier may further implement random time carrier sense, there is to transmitting said data frame of the first to the radio station at the time did not detect the results carriers.
[0023]
That is, the conventional HCF is a centralized control by a base station, and in a wireless communication environment where two or more areas overlap in the same frequency adjacent area, when a plurality of packets are generated simultaneously, a poll frame is transmitted immediately after PIFS. A collision between poll frames occurs. Further, in the method according to Patent Document 1, DCF is used for retransmission of a poll frame after a collision occurs, and there is a possibility that a delay time due to a transmission standby period is extended.
[0024]
On the other hand, in the packet communication method of the present invention, when the Poll frame collides, the Poll frame is retransmitted until N (random number) continuous communication is successful, and when the Nth communication is not successful, the autonomous distributed control is performed. (DCF) Retransmission is performed by random access, and continuous retransmission by HCF is preferentially transmitted to DCF. Therefore, there is no influence of delay time due to transmission waiting time such as random Backoff, and random number N is the same system. Is applied to a plurality of areas, a radio station with a small N value first stops retransmission by the HCF with respect to a radio station with a large N value, and a radio station with a large N value can retransmit a poll frame by the HCF.
[0025]
Therefore, compared with the prior art, it is different from the conventional one in that it prevents a continuous collision and any one of the radio stations provides a retransmission procedure that allows retransmission by the HCF. Thereby, there is an effect of suppressing the delay time and the discard rate in continuous retransmission of HCF.
[0026]
For uplink data transfer, the second radio station generates a random number M in advance, performs the communication right acquisition frame re-transmission continuously M times in a cycle in which the data packet arrives, and When retransmitting the communication right acquisition frame, it is preferable to move the transmission start time of the communication right acquisition frame at random.
[0027]
For downlink data transfer, the second wireless station generates a random number M in advance, and retransmits the communication right acquisition frame and the data frame continuously M times in the cycle in which the data packet arrives. When the communication right acquisition frame and the data frame are retransmitted, it is desirable to move the transmission start time of the communication right acquisition frame and the subsequent data frame at random times.
[0028]
That is, in the prior art, traffic having a periodic transmission interval continues to collide every cycle, whereas the packet communication method of the present invention has a continuous collision over M (random number) cycles. By shifting the transmission start time of a poll frame with periodicity at random time, the transmission start time is prevented from synchronizing with a poll frame in another area, and the random number M is applied to a plurality of areas in the same system. However, a radio station with a small M value first moves the start time of the poll frame with respect to a radio station with a large M value, and a radio station with a large M value avoids collision in the next cycle without changing the start time of the poll frame. To do this, move the poll frame at random time and set the poll frame start time to the same random time. It is possible to lower the probability of more re-collision. As a result, there is an effect of preventing the collision in a continuous cycle.
[0029]
A second aspect of the present invention includes a first radio station and a second radio station, and for uplink data transfer, the first radio station transmits to the second radio station. When the second wireless station does not detect a carrier as a result of the carrier sense, and means for carrying out carrier sense for the first fixed period for each cycle in which the data packet arrives Means for transmitting a communication right acquisition frame addressed to the first wireless station, and the first wireless station has a second shorter than the first predetermined period after completing the reception of the communication right acquisition frame. And a means for transmitting a data frame carrying the data packet addressed to the second radio station after a certain period of time.
[0030]
Here, a feature of the present invention is that the second wireless station is connected to the first wireless station from the first wireless station after the second fixed period after the transmission of the communication right acquisition frame addressed to the first wireless station. Means for generating a random number N if the data frame is not normally received, means for repeatedly retransmitting the communication right acquisition frame N times until a data frame is received from the first wireless station, If the data frame from the first radio station is not received after the second predetermined period after retransmitting the communication right acquisition frame addressed to the first wireless station N times, the communication right acquisition frame Means for stopping retransmission, and the first wireless station is longer than the first predetermined period when the generating means generates the data packet and the communication right acquisition frame is not normally received. When the carrier sense is performed for a certain period of time and the carrier is not detected as a result, a means for performing further random time carrier sense and the second radio station addressed when the carrier is not detected as a result of the carrier sense. And means for transmitting the data frame.
[0031]
In addition, the second radio station performs a retransmission of the communication right acquisition frame continuously for the M times in a cycle in which the data packet arrives, and a means for generating a random number M, and further acquires the communication right. When performing frame retransmission, it is preferable to include means for moving a transmission start time of the communication right acquisition frame at random.
[0032]
For downlink data transfer, the packet communication system of the present invention includes a first radio station and a second radio station, and the second radio station is addressed to the first radio station. Means for performing carrier sense for a first fixed period for each period when the data packet to be transmitted periodically arrives and the data packet is generated, and if no carrier is detected as a result of this carrier sense, the second Means for transmitting a communication right acquisition frame from the wireless station to the first wireless station; and after the transmission of the communication right acquisition frame is completed, the first predetermined period is shorter than the first predetermined period, and the first And a means for transmitting a data frame carrying the data packet addressed to a radio station.
[0033]
Here, a feature of the present invention is that the second radio station receives the data from the first radio station after the second predetermined period after the data frame transmission addressed to the first radio station is completed. Means for generating a random number N when not receiving an ACK frame indicating that the data frame has been normally received, and the communication right acquisition frame and the N times until the ACK frame is received from the first wireless station Means for repeatedly retransmitting a data frame; from the first radio station after the second predetermined period after retransmitting the communication right acquisition frame and the data frame addressed to the first radio station N times; Means for stopping retransmission of the communication right acquisition frame and the data frame when not receiving the ACK frame, and a third fixed period longer than the first fixed period. If the carrier is not detected as a result, the means for performing carrier sensing at random time and the data frame addressed to the first radio station at the time when the carrier is not detected as a result of the carrier sense And means for transmitting.
[0034]
The second radio station performs re-transmission of the communication right acquisition frame and the data frame continuously with the means for generating a random number M, and with the period at which the data packet arrives for the M times. When retransmitting the right acquisition frame and the data frame, it is preferable to include means for moving the transmission start time of the communication right acquisition frame at random times.
[0035]
A third aspect of the present invention is a radio station, which includes a first radio station and a second radio station, and for data transfer in the uplink direction, the first radio station includes the second radio station. The data packet to be transmitted to the radio station periodically arrives, and the second radio station performs means for performing carrier sense for a first fixed period for each period in which the data packet is generated, and this carrier sense. If a carrier is not detected as a result of the above, a means for transmitting a communication right acquisition frame addressed to the first wireless station is provided, and the first wireless station, after receiving the communication right acquisition frame, Corresponding to the first radio station applied to a packet communication system comprising means for transmitting a data frame carrying the data packet addressed to the second radio station with a second fixed period shorter than the fixed period It is a radio station.
[0036]
Here, the feature of the present invention is that means for performing carrier sense for a third fixed period longer than the first fixed period and, as a result, performing carrier sense at random time when no carrier is detected. And means for transmitting the data frame addressed to the second radio station when no carrier is detected as a result of the carrier sense.
[0037]
Alternatively, a third aspect of the present invention is a radio station, comprising a first radio station and a second radio station, and for data transfer in the uplink direction, the first radio station includes A data packet to be transmitted to the second radio station periodically arrives, and the second radio station performs means for performing carrier sense for a first fixed period for each period in which the data packet arrives, and the carrier Means for transmitting a communication right acquisition frame from the second wireless station to the first wireless station when a carrier is not detected as a result of the sense, wherein the first wireless station transmits the communication right acquisition frame to the first wireless station. After completion of reception, applied to a packet communication system comprising means for transmitting a data frame carrying the data packet addressed to the second wireless station with a second fixed period shorter than the first fixed period The second It is a radio station corresponding to the station.
[0038]
Here, a feature of the present invention is that the data frame from the first radio station is normally received after the second fixed period after the transmission of the communication right acquisition frame addressed to the first radio station is completed. If not, means for generating a random number N, means for repeatedly retransmitting the communication right acquisition frame N times until receiving a data frame from the first radio station, and N times the first radio Means for stopping retransmission of the communication right acquisition frame when the data frame from the first wireless station is not received after the second predetermined period after retransmitting the communication right acquisition frame addressed to the station. There is.
[0039]
Further, means for generating a random number M, and performing the communication right acquisition frame re-transmission continuously in the M times in the period in which the data packet arrives, and further when performing the communication right acquisition frame retransmission, It is desirable to provide means for moving the transmission start time of the communication right acquisition frame at random times.
[0040]
For downlink data transfer, the radio station of the present invention includes a first radio station and a second radio station, and the second radio station is addressed to the first radio station. Means for performing carrier sense for a first fixed period every period when a data packet to be transmitted arrives periodically and the data packet is generated, and the first radio if no carrier is detected as a result of this carrier sense Means for transmitting a communication right acquisition frame to the station; and after the transmission of the communication right acquisition frame, the data packet addressed to the first wireless station with a second fixed period shorter than the first fixed period. A wireless station corresponding to the second wireless station applied to a packet communication system including a means for transmitting a data frame carrying the.
[0041]
Here, a feature of the present invention is that the data frame from the first radio station is normally received after the second fixed period after the transmission of the data frame addressed to the first radio station is completed. Means for generating a random number N, and retransmits the communication right acquisition frame and the data frame N times until the ACK frame is received from the first wireless station. And when the ACK frame from the first wireless station is not received after the second predetermined period after retransmitting the communication right acquisition frame and the data frame addressed to the first wireless station N times. Implements means for stopping retransmission of the communication right acquisition frame and the data frame, and carrier sense for a third fixed period longer than the first fixed period, When the carrier is not detected as a result of this, means for carrying out random time carrier sensing, and means for transmitting the data frame addressed to the first radio station when no carrier is detected as a result of this carrier sensing. It is in place.
[0042]
Means for generating a random number M; and retransmitting the communication right acquisition frame and the data frame continuously in the M times in the period in which the data packet arrives; and further, the communication right acquisition frame and the data frame When retransmitting is performed, it is preferable to include means for moving the transmission start time of the communication right acquisition frame at random times.
[0043]
DETAILED DESCRIPTION OF THE INVENTION
A packet communication system according to an embodiment of the present invention will be described with reference to FIGS. FIG. 1 is a block diagram of a radio base station according to this embodiment. FIG. 2 is a block diagram of the wireless terminal of this embodiment. FIG. 3 is a diagram illustrating a communication procedure for uplink data transfer in which a poll using the HCF of this embodiment is retransmitted N times. FIG. 4 is a diagram illustrating a communication procedure for uplink data transfer in which a poll using the HCF of this embodiment is retransmitted N times and then retransmitted by the DCF. FIG. 5 is a flowchart showing a control procedure for uplink data transfer on the radio base station side using the HCF and DCF of this embodiment. FIG. 6 is a flowchart showing a control procedure for uplink data transfer on the wireless terminal side using the HCF and DCF of this embodiment. FIG. 7 is a diagram showing a procedure for uplink data transfer in the Poll frame transmission time shift when M period collisions occur continuously in the present embodiment. FIG. 8 is a flowchart showing a procedure for uplink data transfer of poll frame transmission time movement when M period collisions occur continuously in the present embodiment.
[0044]
FIG. 9 is a diagram illustrating a communication procedure for data transfer in the downlink direction in which the poll using the HCF of this embodiment is retransmitted N times. FIG. 10 is a diagram illustrating a communication procedure for downlink data transfer in which a poll using the HCF of this embodiment is retransmitted N times and then retransmitted by the DCF. FIG. 11 is a flowchart illustrating a control procedure for downlink data transfer on the radio base station side using the HCF and DCF of the present embodiment. FIG. 12 is a flowchart illustrating a control procedure for downlink data transfer on the wireless terminal side using the HCF and DCF of this embodiment. FIG. 13 is a diagram showing a procedure for data transfer in the downlink direction of Poll frame transmission time movement when M period collisions occur continuously in the present embodiment. FIG. 14 is a flowchart showing a procedure for data transfer in the downlink direction of Poll frame transmission time movement when M period collisions occur continuously in the present embodiment. The overall configuration of the packet communication system will be described with reference to FIG. 17, focusing on the wireless terminal (STA) [213] and the wireless base station (AP1) [211].
[0045]
As shown in FIG. 17, the present embodiment includes a wireless terminal (STA1) [213] and a wireless base station (AP1) [211]. For uplink data transfer, the wireless terminal 213 is configured as shown in FIG. As shown in FIG. 1, a data packet storage unit 6 is provided in which data packets transmitted to the radio base station [211] periodically arrive. The radio base station [211] receives the data packet as shown in FIG. A carrier sense execution unit 1 that performs carrier sense between PIFSs, which is a first fixed period for each arrival period, and a poll as a communication right acquisition frame addressed to the wireless terminal [213] when no carrier is detected by this carrier sense And the polling transmission unit 2 for transmitting the frame, and the wireless terminal [213] receives the poll frame by the polling reception unit 7 after completing the PIFS. Remote is a short second a certain period SIFS between spaced by a packet communication system including a data packet transmission and reception unit 8 for transmitting data frames carrying the data packets to the radio base station [211] addressed.
[0046]
Here, a feature of the present embodiment is that the radio base station [211] transmits the data frame from the radio terminal [213] to the data packet after SIFS after completion of the transmission of the poll frame addressed to the radio terminal [213]. The random number N generation unit 4 that generates a random number N when the transmission / reception unit 3 does not normally receive the polling transmission unit 2 repeats the poll frame N times until a data frame is received from the wireless terminal [213]. If retransmission is performed and the data frame from the wireless terminal [213] is not received after SIFS after retransmitting the Poll frame addressed to the N times wireless terminal [213], the retransmission of the Poll frame is stopped, The wireless terminal [213] performs carrier sensing between DIFSs, which is a third fixed period longer than PIFS, and as a result, performs the carrier sensing. If no carrier is detected, a carrier sense execution unit 9 for carrying out random time carrier sense is further provided, and the data packet transmission / reception unit 8 is addressed to the radio base station [211] when no carrier is detected as a result of the carrier sense. The data frame is transmitted.
[0047]
Further, the radio base station [211] includes a random number M generation unit 5 that generates a random number M, and the polling transmission unit 2 retransmits the Poll frame continuously for the M times in the cycle in which the data packet arrives. In addition, when the Poll frame retransmission is performed, the transmission start time of the Poll frame is shifted by a random time.
[0048]
As shown in FIG. 17, the present embodiment includes a wireless terminal (STA1) [213] and a wireless base station (AP1) [211]. For data transfer in the downlink direction, as shown in FIG. The radio base station [211] includes a data packet storage unit 10 in which data packets to be transmitted to the radio terminal [213] periodically arrive, and carrier sense for performing inter-PIFS carrier sense for each period in which the data packet arrives The implementation unit 1, the polling transmission unit 2 that transmits a poll frame to the wireless terminal [213] from the wireless base station [211] when the carrier sense is not detected as a result of the carrier sense, and the SIFS after the transmission of the poll frame is completed A data packet transmission / reception unit 3 for transmitting a data frame carrying the data packet addressed to the wireless terminal [213] at an interval; A packet communication system.
[0049]
Here, the feature of the present embodiment is that the radio base station [211] normally transmits the data frame from the radio terminal [213] after SIFS is completed after transmission of the data frame addressed to the radio terminal [213]. When not receiving an ACK frame indicating that it has been received, the random number N generating unit 4 that generates a random number N is provided, and the polling transmission unit 2 and the data packet transmission / reception unit 3 receive the ACK frame from the wireless terminal [213]. The Poll frame and the data frame are repeatedly retransmitted N times until the P terminal and the data frame addressed to the N times wireless terminal [213] are transmitted from the wireless terminal [213] after the retransmission and after SIFS. If the ACK frame is not received, the retransmission of the Poll frame and the data frame is stopped, The carrier sense implementation unit 1 performs inter-DIFS carrier sense and, as a result, does not detect a carrier, further performs a random time carrier sense. The polling transmission unit 2 and the data packet transmission / reception unit 3 perform carrier detection as a result of this carrier sense. When the data frame is not detected, the data frame addressed to the wireless terminal [213] station is transmitted.
[0050]
Further, as shown in FIG. 1, the radio base station [211] includes a random number M generation unit 5 that generates a random number M. The polling transmission unit 2 and the data packet transmission / reception unit 3 have a period at which the data packet arrives. When the Poll frame and the data frame are retransmitted continuously for the M times, and when the Poll frame and the data frame are retransmitted, the transmission start time of the Poll frame is shifted by a random time.
[0051]
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
[0052]
(First Example)
The packet communication system of the first embodiment will be described with reference to FIGS. As shown in FIG. 3, first, when traffic such as VoIP with periodic transmission intervals starts communication, the transmission interval between the wireless terminal (STA) [412] and the wireless base station (AP) [411]. The information such as the channel use period (TXOP) of the wireless terminal [412] is negotiated by exchanging management frames. Based on these pieces of information, the packet generation period is used as a trigger for polling.
[0053]
In FIG. 3, before the transmission of the poll frame, the radio base station [411] performs carrier sense between PIFSs [418]. When the carrier sense recognizes that the line is not being used, a poll frame is transmitted. In the wireless terminal [412], for example, in the case of a Poll frame reception error [417] due to a collision with a Poll frame in the same frequency adjacent area, the wireless terminal [412] does not transmit a data frame, and the wireless base station [411] Continuously, the Poll frame is retransmitted after inter-PIFS carrier sense. When the Poll frame [414] is normally received before N (random number) retransmissions, the wireless terminal [412] transmits the data frame [415] after SIFS, and the wireless base station 411 that has received the data frame. Transmits an ACK frame [416] to the wireless terminal [412] after the SIFS and completes the communication.
[0054]
In FIG. 4, when the Poll frame [513] collides as in FIG. 3 and collision occurs continuously up to N (random number) times, the wireless terminal [512] performs autonomous distributed control (DCF [522]). I do. After performing carrier sensing between DIFS [517] (SIFS <PIFS <DIFS), the wireless terminal [512] performs Backoff [518] processing for performing carrier sensing at random time which is a collision avoidance period. When no carrier is detected during Backoff [518], the wireless terminal [512] transmits a data packet [519] to the wireless base station [511]. As described above, a retransmission method when using the HCF is provided.
[0055]
The flowchart in FIG. 5 is control on the radio base station side, and after a Poll frame is generated, a random number is generated and a counter N value is set. The timer is started, and if the PIFS time is Idle, a Poll frame is transmitted. If no data frame is received after the SIFS, the counter N value is decreased by one. When N = 0, this flowchart is terminated.
[0056]
The flowchart in FIG. 6 is control on the wireless terminal side. First, if the timer is started and the Idle between DIFSs is set, a random Backoff time is set and the Backoff timer is started. If the random Backoff time is Idle, data is transmitted after SIFS. If it is not between DIFS or the random Backoff time Idle, each timer is reset, and it is determined whether or not a Poll frame has been received. When a Poll frame is received, a data frame is transmitted after SIFS. If no poll frame is received, the process returns to the start.
[0057]
(Second embodiment)
The packet communication system of the second embodiment will be described with reference to FIGS. As shown in FIG. 7, first, similarly to the first embodiment, when traffic such as VoIP with periodic transmission intervals starts communication, the transmission interval between the wireless terminal (STA) and the wireless base station (AP), Information such as the usage period (TXOP) of the wireless terminal (STA) is negotiated by exchanging management frames. Based on these pieces of information, the packet generation period is used as a trigger for polling.
[0058]
In FIG. 7, before transmitting the Poll frame, the radio base station (AP) performs inter-PIFS carrier sense. When the carrier sense recognizes that the line is not being used, a poll frame is transmitted. In the wireless terminal (STA), a Poll frame reception error occurs due to a collision of the Poll frame. The wireless terminal (STA) does not transmit a data frame, and the wireless base station (AP) continuously retransmits the Poll frame up to N (random number) after carrier sensing between PIFSs, and after N times autonomous distributed control (DCF) is performed.
[0059]
Here, traffic having periodicity in packet transmission, such as VoIP, may collide with other VoIP traffic communicating in other adjacent areas of the same frequency continuously between each other. When a Poll frame is retransmitted over a continuous M (random number) cycle, the Poll frame transmission start time for each cycle is set to move at a random time for transmission. Thereafter, the radio base station (AP) transmits a poll frame from the time moved. As described above, collisions caused by synchronization of traffic having periodicity in the transmission interval are avoided.
[0060]
In the flowchart of FIG. 8, first, a random value is generated and a counter M value is set. After the occurrence of the poll frame, a random number is generated and the counter N value is set in the same manner as in FIG. 5 of the first embodiment. The retransmission flag is set to OFF. The retransmission flag is used to determine whether or not the Poll frame has been retransmitted continuously. If the timer is started and if the inter-PIFS Idle is not received after the SIFS for transmitting the Poll frame, the retransmission flag is turned ON and the N counter is decremented.
[0061]
Thereafter, the above operation is performed again to retransmit the poll frame. If the data frame after SIFS is received and the retransmission flag is ON, the counter value of M is decreased. When the counter value of M becomes 0, the start time of the next transmission poll frame is set to random time movement. If the retransmission flag is OFF, it is determined that the poll frame has not been retransmitted, and the counter M value is cleared.
[0062]
As described above, the first and second embodiments are embodiments regarding data transfer in the upstream direction. In the following embodiment, downlink data transfer will be described.
[0063]
(Third embodiment)
A packet communication system according to the third embodiment will be described with reference to FIGS. As shown in FIG. 9, first, traffic such as VoIP with periodic transmission intervals starts transmission intervals between the wireless terminal (STA) [412] and the wireless base station (AP) [411] when communication starts. The information such as the channel use period (TXOP) of the wireless terminal [412] is negotiated by exchanging management frames. Based on these pieces of information, the packet generation period is used as a trigger for polling.
[0064]
In FIG. 9, before transmitting the poll frame, the radio base station [411] performs carrier sense between PIFSs [418]. When recognizing that the line is not used by carrier sense, a poll frame is transmitted. When data to be transmitted to the wireless terminal [412] has arrived, the data frame [ 416]. For example, in the case of a Poll frame reception error [417] due to a collision with a Poll frame in the same frequency adjacent area, the radio terminal [412] cannot receive a data frame from the radio base station [411]. Since the ACK frame is not transmitted, the radio base station [411] continuously retransmits the poll frame and the data frame after inter-PIFS carrier sense. If the Poll frame [414] and the data frame [416] are normally received by the wireless terminal [412] before N (random number) retransmissions, the wireless terminal [412] transmits the ACK frame [415] after the SIFS. The wireless base station [411] that completes reception of the ACK frame completes communication after SIFS.
[0065]
In FIG. 10, when the Poll frame [513] collides as in FIG. 9, and the collision occurs continuously up to N (random number) times, the radio base station [511] performs autonomous distributed control (DCF [522] )I do. After performing carrier sense between DIFS [517] (SIFS <PIFS <DIFS), the radio base station [511] performs Backoff [518] processing for performing carrier detection at random time, which is a collision avoidance period, if the line is not used. . When no carrier is detected during Backoff [518], the radio base station [511] transmits a data frame [519] to the radio terminal [512]. As described above, a retransmission method when using the HCF is provided.
[0066]
The flowchart of FIG. 11 is control on the radio base station side, and after the occurrence of a poll frame, a random number is generated and a counter N value is set. The timer is started, and if the PIFS time is Idle, a Poll frame is transmitted. If no ACK frame is received after the SIFS, the counter N value is decreased by one. When N = 0, this flowchart is terminated.
[0067]
The flowchart of FIG. 12 is control on the radio base station side performed following the procedure of the flowchart of FIG. 11. First, if the timer is started and Idle between DIFSs, a random Backoff time is set, and the Backoff timer is set. Start. If the random Backoff time is Idle, a data frame is transmitted after SIFS. If it is not between the DIFS or the random Backoff time Idle, each timer is reset to determine whether or not an ACK frame has been received. If an ACK frame is received, communication is terminated. If no ACK frame is received, return to start.
[0068]
(Fourth embodiment)
A packet communication system according to the fourth embodiment will be described with reference to FIGS. First, similarly to the third embodiment, when traffic such as VoIP with periodic transmission intervals starts communication, the transmission interval between the wireless terminal (STA) and the wireless base station (AP), the STA usage period (TXOP) Such information is negotiated by exchanging management frames. Based on these pieces of information, the packet generation period is used as a trigger for polling.
[0069]
In FIG. 13, before transmitting the Poll frame, the radio base station (AP) performs PIFS time carrier sense. If it is recognized by carrier sense that the line is not used, a poll frame and a data frame following the poll frame are transmitted. In the wireless terminal (STA), a Poll frame and data frame reception error occurs due to a collision between the Poll frame and the data frame. Accordingly, the wireless terminal (STA) does not transmit the ACK frame, but the wireless base station (AP) continuously retransmits the Poll frame and the data frame up to N (random number) after the inter-PIFS carrier sense, and N times Later, autonomous distributed control (DCF) is performed.
[0070]
Here, traffic having periodicity in packet transmission, such as VoIP, may collide with the VoIP traffic communicating in other adjacent areas of the same frequency with each other in continuous poll frames and data frames. There is. When a Poll frame and a data frame are retransmitted over a continuous M (random number) cycle, the Poll frame transmission start time for each cycle is set to move at a random time for transmission. Thereafter, the radio base station (AP) transmits a poll frame and a subsequent data frame from the time shifted. As described above, collisions caused by synchronization of traffic having periodicity in the transmission interval are avoided.
[0071]
In the flowchart of FIG. 14, first, a random number value is generated and a counter M value is set. After the occurrence of the poll frame, a random number is generated and the counter N value is set in the same manner as in FIG. 11 of the third embodiment. The retransmission flag is set to OFF. The retransmission flag is used to determine whether or not the Poll frame has been retransmitted continuously. A timer is started, and if it is Idle between PIFSs, a poll frame and a data frame are transmitted. When an ACK frame is not received after SIFS, the retransmission flag is turned ON and the N counter is decreased.
[0072]
Thereafter, the above operation is performed again to retransmit the poll frame and data frame. If the ACK frame after SIFS is received and the retransmission flag is ON, the counter value of M is decreased. When the counter value of M becomes 0, the start time of the next transmission poll frame and the subsequent data frame is set to random time movement. If the retransmission flag is OFF, it is determined that the poll frame and data frame have not been retransmitted, and the counter M value is cleared.
[0073]
(Example summary)
In the present embodiment, in order to make the explanation easy to understand, the embodiments have been described separately, but actually, the first or second embodiment and the third or fourth embodiment are used in combination. For example, if the procedure described in the first or third embodiment is executed and communication is still not successful, the procedure described in the second or fourth embodiment may be executed. A means is provided for summing up the respective communication success rates when the procedure described in the first or third embodiment is executed and when the procedure described in the second or fourth embodiment is executed. The procedure with the higher communication success rate may be selected according to the above.
[0074]
【The invention's effect】
As described above, according to the present invention, a retransmission procedure and a collision avoidance method when a Poll frame collides in a wireless network having overlapping areas of the same frequency adjacent area based on base station centralized control using HCF are provided. In addition, the delay time of the data packet and the packet discard rate can be suppressed.
[Brief description of the drawings]
FIG. 1 is a block diagram of a radio base station according to the present embodiment.
FIG. 2 is a block configuration diagram of a wireless terminal according to the present embodiment.
FIG. 3 is a diagram showing a communication procedure for uplink data transfer in which a Poll using the HCF of this embodiment is retransmitted N times.
FIG. 4 is a diagram showing a communication procedure for uplink data transfer in which a poll using the HCF of this embodiment is retransmitted N times after being retransmitted by DCF.
FIG. 5 is a flowchart showing a control procedure for uplink data transfer on the radio base station side using HCF and DCF according to the embodiment;
FIG. 6 is a flowchart showing a control procedure for uplink data transfer on the wireless terminal side using the HCF and DCF of this embodiment.
FIG. 7 is a diagram illustrating a procedure for uplink data transfer in a Poll frame transmission time shift when M period collisions occur continuously in the embodiment;
FIG. 8 is a flowchart showing a procedure for uplink data transfer in a Poll frame transmission time shift when M period collisions occur continuously in the embodiment;
FIG. 9 is a diagram showing a communication procedure for downlink data transfer in which a poll using the HCF of this embodiment is retransmitted N times.
FIG. 10 is a diagram showing a communication procedure for downlink data transfer in which a poll using HCF of this embodiment is retransmitted N times after being retransmitted by DCF.
FIG. 11 is a flowchart showing a control procedure for downlink data transfer on the radio base station side using the HCF and DCF of the embodiment;
FIG. 12 is a flowchart showing a control procedure for downlink data transfer on the wireless terminal side using the HCF and DCF of the embodiment;
FIG. 13 is a diagram showing a procedure for data transfer in the downlink direction of poll frame transmission time movement when M period collisions occur continuously in the embodiment;
FIG. 14 is a flowchart showing a procedure for data transfer in the downlink direction of Poll frame transmission time movement when M period collisions occur continuously in the embodiment;
FIG. 15 is a diagram showing a procedure for uplink data transfer in the packet communication method in the HCF.
FIG. 16 is a diagram showing a procedure for downlink data transfer in the packet communication method in the HCF.
FIG. 17 is a diagram for explaining the same frequency adjacent area.
FIG. 18 is a diagram showing an example of a Poll frame collision by the HCF procedure in the same frequency adjacent area.
FIG. 19 is a diagram illustrating a poll retransmission method when there is no data frame reception expected after transmission of a poll frame.
[Explanation of symbols]
1, 9 Career Sense Implementation Department
2 Polling transmission part
3 Data packet transceiver
4 random number N generator
5 Random number M generator
6, 10 Data packet storage unit
7 Polling receiver
8 Data packet transceiver
211, 212, 411, 511 Wireless base station (AP)
213, 214, 412, 512 Wireless terminals (SAT1, STA2, STA)
215 Area A
216 Area B
319, 320, 413, 414, 513, 514, 3411, 3412 Poll frame
321 and 322 Next period transmission poll frame
323, 324 Poll frame reception error due to collision
3413 No data frame
3414 SIFS
3416 TXOP
415, 516 ACK frame
416, 519 data frame
417 Poll frame reception error
315-318, 418, 520, 3415 PIFS
517 DIFS
518, 3417 Random Backoff
521 Poll frame reception error
522 DCF

Claims (12)

A data packet to be transmitted to the second wireless station periodically arrives at the first wireless station, and the second wireless station performs carrier sense for a first fixed period for each period at which the data packet arrives. If the carrier is not detected, the second wireless station transmits a communication right acquisition frame to the first wireless station, and the first wireless station completes reception of the communication right acquisition frame, and then In a packet communication method for transmitting a data frame carrying the data packet addressed to the second wireless station with a second fixed period shorter than one fixed period,
When the second radio station does not normally receive the data frame from the first radio station after the second predetermined period after the transmission of the communication right acquisition frame addressed to the first radio station is completed. Generate a random number N and repeat the communication right acquisition frame N times until receiving the data frame from the first wireless station,
After retransmitting the communication right acquisition frame addressed to the first wireless station N times, if the data frame from the first wireless station is not received after the second predetermined period, the communication right acquisition frame Stop resending
When the first radio station performs carrier sense for a third fixed period longer than the first fixed period, and as a result, does not detect the carrier, it further performs random time carrier sense, The packet communication method, wherein the data frame addressed to the second radio station is transmitted when not detected. The second wireless station generates a random number M in advance, performs retransmission of the communication right acquisition frame continuously M times in a period in which the data packet arrives, and further performs retransmission of the communication right acquisition frame The packet communication method according to claim 1, wherein when the communication right acquisition frame is transmitted, the transmission start time of the communication right acquisition frame is moved at random time. A data packet to be transmitted to the first wireless station periodically arrives at the second wireless station, and the second wireless station performs carrier sense for a first fixed period for each period at which the data packet arrives. If the carrier is not detected, the second wireless station transmits a communication right acquisition frame to the first wireless station, and after the second wireless station completes transmission of the communication right acquisition frame, In a packet communication method for transmitting a data frame carrying the data packet addressed to the first wireless station with a second fixed period shorter than the first fixed period,
The ACK frame indicating that the second radio station has normally received the data frame from the first radio station after the second predetermined period after the transmission of the data frame addressed to the first radio station is completed. Is generated, a random number N is generated, and the communication right acquisition frame and the data frame are repeatedly retransmitted N times until an ACK frame is received from the first wireless station,
After retransmitting the communication right acquisition frame and the data frame addressed to the first wireless station N times, if the ACK frame from the first wireless station is not received after the second predetermined period, Stop retransmitting the communication right acquisition frame and the data frame;
When the carrier sense is performed for a third fixed period longer than the first fixed period and, as a result, no carrier is detected, the carrier sense is further performed for a random time, and the carrier is not detected as a result. A packet communication method characterized by transmitting the data frame addressed to one radio station. The second wireless station generates a random number M in advance, performs retransmission of the communication right acquisition frame and the data frame continuously M times in a period in which the data packet arrives, and further acquires the communication right acquisition The packet communication method according to claim 3, wherein when the frame and the data frame are retransmitted, the transmission start time of the communication right acquisition frame and the subsequent data frame is moved at random time. A first wireless station and a second wireless station, wherein data packets to be transmitted to the second wireless station periodically arrive at the first wireless station, and the second wireless station Means for performing carrier sense for a first fixed period for each period when the data packet arrives, and means for transmitting a communication right acquisition frame to the first radio station when no carrier is detected as a result of the carrier sense. The first wireless station, after completing the reception of the communication right acquisition frame, sends the data packet to the second wireless station with a second fixed period shorter than the first fixed period. In a packet communication system comprising means for transmitting a loaded data frame,
The second radio station is
Means for generating a random number N if the data frame from the first wireless station is not normally received after the second predetermined period after the completion of transmission of the communication right acquisition frame addressed to the first wireless station;
Means for repeatedly retransmitting the communication right acquisition frame N times until receiving the data frame from the first wireless station;
If the data frame from the first radio station is not received after the second predetermined period after retransmitting the communication right acquisition frame addressed to the first wireless station N times, the communication right acquisition frame Means for stopping retransmission, and
The first radio station is
Means for performing carrier sense for a third period of time longer than the first period of time, and as a result, when no carrier is detected, means for performing further random time carrier sense;
And a means for transmitting the data frame addressed to the second radio station when no carrier is detected as a result of the carrier sense. The second radio station is
Means for generating a random number M;
When the communication right acquisition frame is retransmitted continuously for the M times in the period when the data packet arrives, and when the communication right acquisition frame is retransmitted, the transmission start time of the communication right acquisition frame is set. The packet communication system according to claim 5, further comprising means for moving at random times. A first wireless station and a second wireless station are provided, and data packets transmitted to the first wireless station periodically arrive at the second wireless station, and the data packets arrive. Means for performing carrier sense for a first fixed period for each period, means for transmitting a communication right acquisition frame to the first radio station if no carrier is detected as a result of the carrier sense, and the communication right acquisition frame A packet communication system comprising: means for transmitting a data frame carrying the data packet addressed to the first wireless station at a second fixed period shorter than the first fixed period after transmission is completed.
The second radio station is
If an ACK frame indicating that the data frame from the first radio station has been normally received is not received after the second predetermined period after the transmission of the data frame addressed to the first radio station, a random number N Means for generating
Means for repeatedly retransmitting the communication right acquisition frame and the data frame N times until receiving the ACK frame from the first wireless station;
If the communication right acquisition frame and the data frame addressed to the first radio station are retransmitted N times and the ACK frame from the first radio station is not received after the second predetermined period, the communication is performed. Means for stopping retransmission of the right acquisition frame and the data frame;
Means for performing carrier sense for a third period of time longer than the first period of time, and as a result, when no carrier is detected, means for performing further random time carrier sense;
And a means for transmitting the data frame addressed to the first radio station when no carrier is detected as a result of the carrier sense. The second radio station is
Means for generating a random number M;
When the communication right acquisition frame and the data frame are retransmitted continuously for the M times in the period when the data packet arrives, and when the communication right acquisition frame and the data frame are retransmitted, The packet communication system according to claim 7, further comprising: a communication right acquisition frame and means for moving a transmission start time of the data frame following the communication right at random. A first wireless station and a second wireless station, wherein data packets to be transmitted to the second wireless station periodically arrive at the first wireless station, and the second wireless station Means for carrying out carrier sense for a first fixed period every period when the data packet arrives, and if no carrier is detected as a result of this carrier sense, transmits a communication right acquisition frame to the first radio station And the first wireless station receives the communication right acquisition frame and completes reception of the data packet addressed to the second wireless station with a second fixed period shorter than the first fixed period. In a radio station corresponding to the second radio station applied to a packet communication system provided with means for transmitting a data frame carrying
Means for generating a random number N if the data frame from the first wireless station is not normally received after the second predetermined period after the completion of transmission of the communication right acquisition frame addressed to the first wireless station;
Means for repeatedly retransmitting the communication right acquisition frame N times until receiving the data frame from the first wireless station;
If the data frame from the first radio station is not received after the second predetermined period after retransmitting the communication right acquisition frame addressed to the first wireless station N times, the communication right acquisition frame A radio station comprising means for stopping retransmission . Means for generating a random number M;
When the communication right acquisition frame is retransmitted continuously for the M times in the period when the data packet arrives, and when the communication right acquisition frame is retransmitted, the transmission start time of the communication right acquisition frame is Means for moving at random time and
The radio station according to claim 9, further comprising: A first wireless station and a second wireless station, wherein data packets to be transmitted to the first wireless station periodically arrive at the second wireless station, and the second wireless station Means for carrying out carrier sense for a first fixed period every period when the data packet arrives, and if no carrier is detected as a result of this carrier sense, transmits a communication right acquisition frame to the first radio station Means for transmitting a data frame carrying the data packet addressed to the first radio station after a second fixed period shorter than the first fixed period after transmission of the communication right acquisition frame is completed; In a radio station corresponding to the second radio station applied to a packet communication system comprising:
If an ACK frame indicating that the data frame from the first radio station has been normally received is not received after the second predetermined period after the transmission of the data frame addressed to the first radio station, a random number N Means for generating
Means for repeatedly retransmitting the communication right acquisition frame and the data frame N times until receiving the ACK frame from the first wireless station;
If the communication right acquisition frame and the data frame addressed to the first radio station are retransmitted N times and the ACK frame from the first radio station is not received after the second predetermined period, the communication is performed. Means for stopping retransmission of the right acquisition frame and the data frame;
Means for performing carrier sense for a third period of time longer than the first period of time, and as a result, when no carrier is detected, means for performing further random time carrier sense;
Radio station, characterized in that a means for transmitting the data frame of the first to the radio station at the time when the result detected no carrier of the carrier sense. Means for generating a random number M;
When the communication right acquisition frame and the data frame are retransmitted continuously for the M times in the period when the data packet arrives, and when the communication right acquisition frame and the data frame are retransmitted, Means for moving the transmission start time of the communication right acquisition frame and the subsequent data frame at random times;
The wireless station according to claim 11, comprising:

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