JP4818950B2 - Wireless LAN data packet collision avoidance control method and apparatus - Google Patents

Description

  The present invention relates to a wireless LAN data packet collision avoidance control method and apparatus, and more particularly, to a wireless LAN data packet collision avoidance control method and apparatus for avoiding data packet collision.

As a conventional technique, in the IEEE802.11 wireless LAN standard, one or a plurality of wireless terminal devices (stations; hereinafter referred to as STAs) belonging to a wireless base station device (access point; hereinafter referred to as AP). There is a method of performing data packet communication between each other (or between a plurality of STAs). In this standard, the wireless LAN specifies transmission / reception of data packets using a CSMA / CA (Carrier Sense Multiple Access with Collision Avoidance) method (DCN: Distributed Coordination Function) called autonomous distributed control (see Non-Patent Document 1 below). Has been.
In addition, the AP uses the CSMA / CA method at a fixed transmission cycle (beacon interval) (see Non-Patent Document 2 below) with respect to the STA belonging to the AP (or the STA attempting to belong). Send a beacon signal. This beacon signal has a role of notifying the STA of various information necessary for communication.
Based on the IEEE802.11 standard, IEEE802.11a which is a wireless LAN standard of 5 GHz band, and IEEE802.11b and IEEE802.11g which are wireless LAN standards of 2.4 GHz band are defined. Here, IEEE802.11b is a standard that allows data packets to be transmitted at a maximum wireless transmission rate of 54 Mbps, which is equivalent to the IEEE802.11a standard, while IEEE802.11g is a maximum transmission rate of 11 Mbps.
However, since IEEE802.11g must share a channel with IEEE802.11b, means are provided for avoiding packet collisions caused by differences in modulation schemes. In IEEE802.11g, as one means of avoiding this collision, a control frame called a CTS-to-Self frame is transmitted to itself to suppress transmission of IEEE802.11b STA and IEEE802.11g STA. (NAV: Network Allocation Vector) is defined) (see Non-Patent Document 3 below).

Further, based on the IEEE 802.11 standard (including the IEEE 802.11a, b, and g standards), the wireless LAN standard IEEE 802.11e having a QoS support function is standardized.
As one of the systems standardized by IEEE802.11e, an EDCA system (see Non-Patent Document 4 below) for performing priority control by extending DCF is adopted.
The EDCA (Enhanced Distributed Channel Access) system performs data packet transmission with priority for services with high communication quality requirements such as voice and moving images. The EDCA method is classified into access categories having four priorities (AC: AC_VO, AC_VI, AC_BE, AC_BK), and realizes priority control using different access parameters (CWmin / max, AIFS, TXOP) for each AC. .
A wireless LAN that implements the EDCA method gives priorities by setting the CWmin / max and AIFS period values according to the priorities prior to packet transmission, and sets TXOPlimit as the period during which data bucket transmission is available When the right to perform transmission is obtained, data packets are continuously transmitted over a TXOP limit period at SIFS intervals (a short period in which carrier sense is not performed). By setting TXOPlimit, the radio band can be occupied for a certain period for data packet transmission.

An example of the prior art is shown in FIG. As shown in the data packet transmission procedure of FIG. 1, CWmin / max [1-3] and AIFS [1-2] are set and given priority.
AIFS [1-2] performs carrier sense for a fixed period, then acquires a random number from the range of CWmin / max [1-3], and performs carrier sense for a random period called back-off based on this random number. carry out. If the channel is idle (not used) in AIFS and back-off carrier sense, the right to transmit a data packet is acquired. If the channel is busy (used), the channel waits for transmission and becomes idle until it becomes idle. Resume backoff processing.
When the transmission right is acquired, data packets [1-4] and [1-7] are continuously transmitted at intervals of SIFS [1-6] (short packet interval without carrier sense) during the period of TXOPlimit [1-9]. I can do it.
In this access method based on CSMA / CA, ACK (reception response) frames [1-5] and [1-8] for notifying successful reception are received from the destination of the data packet (unicast data packet). Thus, the success or failure of the data packet transmission is determined, and if the ACK frames [1-5] and [1-8] are not received after the data packet transmission, it is determined that the data packet transmission has failed, and the channel As soon as it changes from busy [1-1] to idle, it performs back-off control (carrier sense) by acquiring a random number from the range expanded by CWmin / max [1-3] after carrying out carrier sense of AIFS [1-2] To retransmit the data packet.
In addition, as shown in FIG. 2, for example, a multicast data packet without retransmission control does not receive an ACK frame (the multicast data packet receiving station does not transmit an ACK frame), and in the period of TXOPlimit [2-9]. , Multicast data packets [2-4], [2-6], and [2-8] are transmitted at intervals of SIFS [2-5] and [2-7].

FIG. 1-1 shows a block diagram of the MAC transmission control unit.
Unicast data packets / multicast data packets are input from the upper layer [1-1-1] to the reception queue [1-1-2] of the MAC transmission control unit [1-1-0] [1-1-10]. Is done. When there is data to be transmitted, the reception cute [1-1-2] notifies the TXOP management unit [1-1-4] of the existence of data to be transmitted [1-1-15]. When the TXOP management unit [1-1-4] does not acquire the TXOP, the AIFS / backoff carrier sense unit [1-1-5] is notified of the AIFS and the backoff start notification [1-1-16]. To notify.
The AIFS / backoff carrier sense unit [1-1-5] performs carrier sense triggered by the notification [1-1-16]. If the channel is idle, the AIFS / backoff carrier sense unit [1-1-5] issues a transmission instruction [1-1-17] to the transmission queue [1-1-3].
The transmission queue [1-1-3] requests [1-1-24] data to be transmitted to the reception queue [1-1-2]. The reception queue [1-1-2] receiving the request [1-1-24] transfers data to the transmission queue [1-1-3], and the transmission queue [1-1-3] is the physical layer [1]. [1-8] Pass data to [1-1-11].

At this time, if the transferred data is unicast data, the transmission queue [1-1-3] copies the data to be transferred to the physical layer [1-1-8] and transmits the transmission queue [1-1-3]. ]. The physical layer [1-1-8] transmits [1-1-12] the received data to the wireless section as a data packet.
After the transmission is completed, the physical layer [1-1-8] notifies the TXOP management unit [1-1-4] of the transmission completion [1-1-19], and the TXOP management unit [1-1-4] Start the TXOP timer. If the transmission queue [1-1-3] holds the copied data, the transmission queue [1-1-3] notifies the ACK reception unit determination unit [1-1-7] that the data has been transmitted [1-1-18].
The ACK receiving unit determination unit [1-1-7] waits until a time when an ACK is expected to be received. When the ACK receiving unit determining unit [1-1-7] receives an ACK from the wireless section [1-1-13] via the physical layer [1-1-8] [1-1-14], The reception of ACK is notified [1-1-20] and [1-1-18] to the TXOP management unit [1-1-4] and the transmission queue [1-1-3]. In the transmission queue [1-1-3], the copied data is discarded.
During the period until the TXOP timer expires, the TXOP management unit [1-1-4] receives a notification [1-1-15] that there is data to be transmitted from the reception queue [1-1-2], and Every time the ACK reception notification [1-1-20] is received, the notification [1-1-22] is sent to the SIFS control unit [1-1-6].

The SIFS control unit [1-1-6] notifies the transmission instruction [1-1-23] to the transmission queue [1-1-3] after the SIFS period. The transmission queue [1-1-3] requests [1-1-24] data to be transmitted to the reception queue [1-1-2].
Further, in the case where the ACK reception unit determination unit [1-1-7] does not receive the ACK by the time when the ACK reception is expected to be received, the TXOP management indicates that the ACK has not been received. [1-1-20] and [1-1-18] are notified to the section [1-1-4] and the transmission queue [1-1-3].
The TXOP management unit [1-1-4] stops the TXOP timer, and again sends the AIFS and backoff start notification [1-1-16] to the AIFS / backoff carrier sense unit [1-1-5]. Retransmission control is performed by notifying.
In this retransmission control, since the copied data is accumulated in the transmission queue [1-1-3], the data request [1-1-24] is not made to the reception queue [1-1-2], and the AIFS is performed. In the backoff carrier sense unit [1-1-5], if the channel becomes idle, the transmission queue [1-1-3] passes the accumulated data to the physical layer [1-1-8]. [1-1-11].

On the other hand, when sending multicast data, the transmission queue [1-1-3] does not copy the data after [1-1-11] passing the data to the physical layer [1-1-8]. The ACK receiving unit determining unit [1-1-7] is notified [1-1-18] that the multicast data has been transmitted.
Having received this notification [1-1-18], the ACK receiving unit determining unit [1-1-7] immediately transmits multicast data to the TXOP managing unit [1-1-4] without waiting for ACK reception. [1-1-20].
After completion of data packet transmission, the physical layer [1-1-8] notifies the TXOP management unit [1-1-4] of transmission completion [1-1-19], and the TXOP management unit [1-1-4]. Then, if the TXOP timer is not activated, the timer is activated.
After the TXOP timer is started, notification [1-1-15] and notification [1-1-7] from the ACK reception unit determination unit [1-1-7] that the TXOP timer expires and that there is data to be transmitted exist. −20] is notified to the SIFS control unit [1-1-6] [1-1-22], and the MAC transmission control unit performs the above series of data transmission processing in the same manner as the unicast data.

FIG. 1-2 shows a flowchart of transmission control.
The start time of the AP or STA is set as [1-2-1]. If there is data to be transmitted [1-2-2] (Yes), carrier sense is performed for AIFS period [1-2-3], and if the channel is idle (Yes), backoff is performed [ 1-2-4], and if it is further idle (Yes), transmit data [1-2-5].
Thereafter, the determination [1-2-6] of whether or not the TXOP timer is activated is performed. If not activated (No), the TXOP timer is activated [1-2-7] when the data transmission is completed.
Thereafter, a determination [1-2-8] is performed as to whether the transmitted data is multicast data or unicast data. If it is multicast data (Yes), it is determined whether the TXOP timer has expired. [1-2-11] is performed. If the TXOP timer expires, the flow returns to the flow after start [1-2-2].
If the transmitted data is not multicast data (unicast data) (No), a determination [1-2-9] of whether or not an ACK is received is performed. If no ACK is received (No), the TXOP timer is set. End [1-2-10] and return to the flow after start [1-2-2].
If the ACK is received in the determination [1-2-9] (Yes), the determination [1-2-11] is performed to determine whether the TXOP timer has expired, and the TXOP has not expired (No ), Confirm [1-2-12] whether there is data to be transmitted. When there is data to be transmitted (Yes), the data transmission [1-2-5] is performed after [1-2-13] between SIFSs.

As prior art documents related to the invention of the present application, there are the following.
IEEE Std 802.11, 1999 edition MEDIUM ACCESS CONTROL (MAC) AND PHYSICAL (PHY) SPECIFICATIONS, (9.1 MAC architecture) IEEE Std 802.11, 1999 edition, MEDIUM ACCESS CONTROL (MAC) AND PHYSICAL (PHY) SPECIFICATlONS, (7.2.3.1 Beacon frame body) IEEE Std 802.11g, MEDIUM ACCESS CONTROL (MAC) and PHYSICAL (PHY) SPECIFICAT1ONS, (9.2.11 NAV distribution) IEEE802.11e-2005, MEDIUM ACCESS CONTROL (MAC) and PHYSICAL (PHY) SPECIFICATIONS, (9.1.3.1 HCF contention-based channel access (EDCA))

In the conventional technologies IEEE802.11 and IEEE802.11e, retransmission control is not performed for multicast data transmission, as shown in FIGS.
FIG. 3 shows an example of a transmission / reception procedure of a unicast data packet and a multicast data packet when the IEEE802.11e standard is used.
First, in the transmission procedure of the unicast data packet, the transmitting station [3-1] performs the AIFS [3-30] period and the backoff period carrier sense [3-31]. Data packet (1) [3-4] is transmitted to receiving station 1 [3-2]. Receiving station 1 [3-2] returns ACK frame [3-11] when it successfully receives [3-13] unicast data packet [3-4].
The transmitting station [3-1] receives the ACK frame [3-27] and confirms that the transmission of the unicast data packet (1) [3-4] is successful. In addition, the transmitting station [3-1] transmits the data packet continuously for the TXOP period [3-24] after the transmission of the unicast data packet (1) [3-4] is completed.
Next, the transmitting station [3-1] transmits a unicast data packet (2) [3-5] addressed to the receiving station 2 [3-3]. Here, when the unicast data packet (2) [3-5] is not normally received by the receiving station 2 [3-3] due to a collision with a data packet transmitted from another station or a propagation error, Since the transmitting station [3-1] does not receive the ACK frame, the transmitting station [3-1] shifts to retransmission [3-29] control.
In retransmission control, after carrier sense of AIFS [3-31], backoff with a wide CW range is performed to reduce packet collision again, and if the channel is idle, a unicast data packet (2) Resend [3-6].
Thus, the unicast data packet can maintain a high transmission / reception success rate of the data packet by performing retransmission control.

On the other hand, in the transmission of the multicast data packet, when transmitting the multicast data packet (3) [3-7], the transmitting station [3-1] transmits the carrier sense and backoff period [AIFS [3-35] period [ 3-34] Perform carrier sense, and if the channel is idle, send multicast data packet (3) [3-7].
The transmitting station [3-1] transmits data packets continuously for TXOP period [3-26] after the completion of transmission of the multicast data packet (3) [3-7].
Here, the multicast data packet (3) [3-7] reaches the receiving station 1 [3-2] and the receiving station 2 [3-3] due to a collision with a data packet transmitted from another station or a propagation error. Even if not, since multicast does not perform retransmission control, multicast data packets (4) [3-8] to multicast data packets (6) [3-10] are transmitted continuously for the TXOP period [3-26]. .
For example, as shown in FIG. 4, it is assumed that AP (wireless base station apparatus) [4-2] transmits a multicast data packet, and STA (wireless terminal) [4-1] transmits a unicast data packet.
When AP [4-2] and STA [4-1] perform AIFS and backoff [4-3] and acquire the transmission right at the same time, unicast data packet [4-4] and multicast data packet [4] −6] causes a collision between packets.
The unicast data packet [4-4] is retransmitted at [4-16] after performing AIFS + backoff [4-17], whereas the multicast data packet [4-6] has a packet loss.

Further, as shown in FIG. 5, when the unicast data packet [5-4] has a data length [5-5] longer than the multicast data packet, the multicast data packet is transmitted continuously in the TXOP period [5-10]. Therefore, packet collisions [5-11], [5-12], and [5-13] occur continuously up to the multicast data packets [5-6], [5-7], and [5-8].
In other words, since multicast data packets are not subjected to retransmission control, there is a problem that when a collision occurs, packet loss occurs at the receiving station and packet loss occurs continuously.
The present invention has been made to solve the problems of the prior art, and an object of the present invention is to prevent data packet transmission without retransmission control in a wireless LAN data packet collision avoidance control method and apparatus thereof. Thus, it is an object of the present invention to provide a technique capable of reducing data packet collision avoidance.
The above and other objects and novel features of the present invention will become apparent from the description of this specification and the accompanying drawings.

Of the inventions disclosed in this application, the outline of typical ones will be briefly described as follows.
(1) A wireless base station device (hereinafter referred to as an access point) and a plurality of wireless terminal devices (hereinafter referred to as stations) that transmit and receive data packets by wireless packet communication with the access point, and according to the CSMA / CA protocol in the wireless LAN communication system for transmitting data packets, the access point or the station, said when transmitting data packets, one regular and between conduct random period carrier sense, the certain period and a random period carrier sense after the transmission right At the time of acquisition, a packet (or pseudo packet) without data is first transmitted, and after completion of packet transmission without data, a short interval during which carrier sense is not performed over a period in which an arbitrarily determined transmission right can be maintained Continuously in the data packet To send the door.
In the prior art, when an access point or a station transmits a data packet, the data packet is transmitted from the first transmission according to the CSMA / CA protocol. In the invention described in (1), the first transmission is a data packet. The present invention is different from the prior art in that it transmits a packet having no data and then transmits a data packet. As a result, it is possible to avoid collision of data packets transmitted for the first time, and to reduce packet loss.

(2) In the wireless LAN system according to (1), carrier sense is performed after completion of packet transmission without the data, and the channel is idle as a result of carrier sense after completion of packet transmission without the data. In the case, the data packet is continuously transmitted at a short interval without performing carrier sense over a period in which the arbitrarily determined transmission right can be maintained, and the result of carrier sense after completion of packet transmission without the data If the channel is busy, the transmission of the data packet is stopped and the data packet is transmitted again according to the CSMA / CA protocol.
In the prior art, when an access point or a station transmits a data packet according to the CSMA / CA protocol, the data packet is transmitted from the initial transmission, and once the transmission is started, the TXOP period is continuously set in the carrier. In contrast to transmitting data packets at short intervals without sensing, in the invention described in (2), the first transmission transmits a packet having no data, and then transmits the data packet and has the data. The invention described in (2) is different from the prior art in that carrier sense is performed after transmission of no packet, and if the channel is idle, data packets are transmitted at short intervals during which the carrier sense is not continuously performed during the TXOP period. ing. As a result, it is possible to avoid collision of data packets transmitted for the first time, and it is possible to avoid continuous collision even when a packet to be collided is long, and packet loss can be reduced.

(3) In the wireless LAN system according to (1), when the data packet is transmitted continuously over a period in which the arbitrarily determined transmission right can be maintained after the packet transmission without the data is completed, Carrier sense is performed before transmission of each data packet, and if the channel is idle as a result of carrier sense before transmission of each data packet, the data packet is transmitted and before transmission of each data packet. If the channel is busy as a result of the carrier sense, the transmission of the data packet is stopped and the data packet is transmitted again according to the CSMA / CA protocol.
In the prior art, when an access point or station transmits a data packet, it transmits the data packet from the first transmission according to the CSMA / CA protocol, and once the transmission is started, the TXOP period is continuously carrier sensed. In the invention described in (3), in the invention described in (3), the first transmission transmits a packet having no data, and then transmits the data packet and no data is transmitted. The invention described in (3) is different from the prior art in that all data packets transmitted continuously in the TXOP period after packet transmission are subjected to carrier sense before transmission. As a result, it is possible to avoid collision of data packets transmitted for the first time, and it is possible to avoid collision by detecting interference with data packets to be transmitted thereafter, thereby reducing packet loss. It becomes.

(4) In a wireless LAN communication system that includes an access point and a plurality of stations that transmit and receive data packets by wireless packet communication with the access point, and that transmits the data packet according to the CSMA / CA protocol, the access point or station is , when transmitting the data packet, one regular and between conduct random period carrier sense, the at constant period and a random period after carrier sense transmission rights acquisition, suppress other access points or other station transmits A CTS-to-Self frame describing a period is transmitted at an arbitrarily determined transmission rate, and after the CTS-to-Self frame transmission is completed, the data is continuously transmitted over a period in which an arbitrarily determined transmission right can be maintained. packet When transmitting, perform carrier sense before transmission of each data packet, and as a result of carrier sense before transmission of each data packet, if the channel is idle, transmit the data packet, If the channel is busy as a result of carrier sense before data packet transmission, the data packet transmission is stopped and the data packet is transmitted again according to the CSMA / CA protocol.
In the prior art, when an access point or station transmits a data packet, it transmits the data packet from the first transmission according to the CSMA / CA protocol, and once the transmission is started, the TXOP period is continuously carrier sensed. In the invention described in (4), the first transmission transmits a CTS-to-Self frame, and then transmits the data packet, and the CTS-to -Describe the period during which other radio stations suppress transmission in the Self frame, arbitrarily set the transmission rate of the CTS-to-Self frame, and the TXOP period after CTS-to-Self frame transmission. All data packets transmitted continuously are subject to (4) in that carrier sense is performed before transmission. Placing the invention differs from the prior art. As a result, it is possible to avoid the collision of the data packet of the first transmission, and to detect the interference to the data packet to be transmitted thereafter, to avoid the collision, and to set the Duration field to an arbitrary length. it is possible to perform the transmission suppression of other stations due to, it is possible to reduce the packet loss.

(5) Consists of an access point and a plurality of stations that transmit and receive data packets by wireless packet communication with the access point. The access point transmits a beacon signal at a constant period and transmits the data packet according to the CSMA / CA protocol. in the wireless LAN communication system, access point, the when transmitting data packets, and implement one regular and between random period carrier sense, when the predetermined period and a random period after carrier sense transmission rights acquisition, the beacon signal When transmitting the data packet continuously over a period in which the arbitrarily determined transmission right can be maintained after completion of the beacon signal transmission, carrier sense is performed before the transmission of each data packet, Before the transmission of each data packet If the channel is idle as a result of the carrier sense, the data packet is transmitted. If the channel is busy as a result of the carrier sense before transmission of each data packet, the transmission of the data packet is stopped. The data packet is transmitted as soon as the channel becomes idle.
In the prior art, when transmitting all data packets, the access point transmits data packets from the first transmission according to the CSMA / CA protocol, and once transmission is started, the carrier sense is continuously performed for the TXOP period. In contrast to transmitting data packets at short intervals that are not performed, in the invention described in (5), it is possible to arbitrarily set carrier sense (AIFS and back-off period) before transmitting a beacon signal, and after completing the beacon signal transmission. The invention described in (5) is different from the prior art in that all data packets transmitted continuously during the TXOP period are subjected to carrier sense before transmission. As a result, the priority of the data packet can be freely set, the collision of the data packet transmitted for the first time can be avoided, and the collision to the data packet to be transmitted thereafter can be detected to avoid the collision. Therefore, packet loss can be reduced.

The effects obtained by the representative ones of the inventions disclosed in the present application will be briefly described as follows.
According to the wireless LAN data packet collision avoidance control method and apparatus of the present invention, it is possible to reduce data packet collision avoidance for data packet transmission without retransmission control.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
In all the drawings for explaining the embodiments, parts having the same functions are given the same reference numerals, and repeated explanation thereof is omitted.
[Example 1]
FIG. 6 is a diagram for explaining a multicast collision avoidance procedure according to the first embodiment of this invention.
In the present embodiment, the AP (wireless base station apparatus) [6-2] transmits a multicast data packet, and the STA (wireless terminal apparatus) [6-1] transmits a unicast data packet. In this embodiment or an embodiment described later, STA [6-1] may transmit a multicast data packet, and AP [6-2] may transmit a unicast data packet.
AP [6-2] and STA [6-1] perform carrier sense of the AIFS and the backoff period [6-3] in order to check the channel usage status. Here, since the back-off period is a random period, it is usually a period with a different length. However, when the number of STAs to be communicated increases, the probability of selecting a random time with the same length increases.
When the AIFS and the back-off period [6-3] are the same, the STA [6-1] and the AP [6-2] transmit a packet at the same time. Here, the STA [6-1] transmits a unicast data packet [6-4], and the AP [6-2] transmits a packet (Null packet) [6-6] having no data.
Unicast data packet [6-4] and Null packet [6-6] collide with each other [6-11], and STA [6-1] performs retransmission control (AIFS + backoff [6-17]). After the collision of the Null packet [6-6], the AP [6-2] continuously transmits the multicast data packets [6-7], [6-8] at the SIFS interval [6-9] for the TXOP period [6-10]. ] Is sent.

AP [6-2] in FIG. 6 transmits a multicast data packet according to the flowchart in FIG.
AP [6-2] starts [6-1-1] at the time of activation, and determines [6-1-2] whether or not it has a multicast data packet to be transmitted.
If there is a multicast data packet, “Yes” is set, and then it is checked whether the channel is idle only during the AIFS period [6-1-3] and the backoff period [6-1-4].
If the channel is idle in the AIFS period [6-1-3] and the back-off period [6-1-4], “Yes” is set, and a Null packet is transmitted [6-1-5]. After the transmission of the Null packet is completed, it waits for SIFS period [6-1-9] and determines whether the TXOP timer is activated [6-1-6].
If the TXOP timer is not activated, the TXOP timer is started [6-1-7] at the start of data transmission. AP [6-2] transmits a multicast data packet [6-1-8] simultaneously with the start of the TXOP timer.
After the transmission of the multicast data packet [6-1-8] is completed, it is determined [6-1-11] whether the TXOP timer has expired. If it has expired, it becomes “Yes”, and the flow returns to the flow after start [6-1-1]. If it has not expired, “No” is determined, and it is determined [6-1-12] whether or not there is a multicast data packet to be transmitted.
If there is no multicast data packet to be transmitted, the result is “No”, the TXOP timer is ended [6-1-10], and the flow returns to the flow after the start [6-1-1]. If there is a multicast data packet to be transmitted, the answer is “Yes”, and the multicast data packet is transmitted [6-1-8] after waiting for SIFS period [6-1-13].

FIG. 6-2 is a block diagram illustrating a schematic configuration of a MAC transmission control unit that implements the multicast collision avoidance method according to the first embodiment of the present invention.
A multicast data packet is input [1-1-10] from the upper layer [1-1-1] to the reception queue [1-1-2] of the MAC transmission control unit [1-1-0]. When there is data to be transmitted, the reception queue [1-1-2] notifies the TXOP management unit [1-1-4] of the existence of data to be transmitted [1-1-15].
If the TXOP management unit [1-1-4] has not acquired the TXOP (the TXOP timer is not activated), the AIFS / backoff start notification [1-1-16] is sent to the AIFS / backoff. Notify the carrier sense unit [1-1-5].
The AIFS / backoff carrier sense unit [1-1-5] performs carrier sense triggered by the notification [1-1-16]. If the channel is idle, the AIFS / backoff carrier sense unit [1-1-5] issues a transmission instruction [6-2-17] to the pseudo packet transmission control unit [6-2-3].
The pseudo packet transmission control unit [6-2-3] generates a Null packet having no data and passes the Null packet to the physical layer [1-1-8] [6-2-11]. The physical layer [1-1-8] transmits [1-1-12] to the passed Null packet radio section.
After the transmission is completed, the physical layer [1-1-8] notifies the TXOP management unit [1-1-4] of the completion of Null packet transmission [1-1-19]. When receiving the Null packet transmission completion notification [1-1-19], the TXOP management unit [1-1-4] notifies the SIFS control unit [1-1-6] [1-1-22]. I do.
The SIFS control unit [1-1-6] notifies the transmission queue [1-1-3] of the transmission instruction [1-1-23] after the SIFS period. The transmission queue [1-1-3] requests [1-1-24] multicast data to be transmitted to the reception queue [1-1-2].

The reception queue [1-1-2] receiving the request [1-1-24] transfers multicast data to the transmission queue [1-1-3], and the transmission queue [1-1-3] is the physical layer. [1-1-8] The multicast data is transferred [1-1-11].
The physical layer [1-1-8] transmits [1-1-12] the received multicast data to the wireless section as a multicast data packet. The physical layer [1-1-8] notifies the TXOP management unit [1-1-4] that the multicast data packet has started to be transmitted [1-1-1], and the TXOP management unit [1-1-1-]. 4] starts the TXOP timer.
When receiving the notification [1-1-15] that the multicast data to be transmitted exists from the reception queue [1-1-2], the TXOP management unit [1-1-4] receives the notification [1-1-15]. [1-6] is notified [1-1-22]. The SIFS control unit [1-1-6] notifies the transmission queue [1-1-3] of the transmission instruction [1-1-23] after the SIFS period.
In this operation, during the period until the TXOP timer expires, the notification [1-1-15] that there is multicast data that the TXOP management unit [1-1-4] transmits from the reception queue [1-1-2] exists. Repeated as long as you receive.
After the physical layer [1-1-8] is notified [1-1-19] that the multicast data packet has started to be transmitted from the physical layer [1-1-8] to the TXOP management unit [1-1-4], the TXOP management unit [1- 1-4] receives the notification [1-1-15] that there is multicast data to be transmitted from the reception queue [1-1-2], the TXOP management unit [1-1-4] The timer of TXOP is stopped, and it waits until it receives notification [1-1-15] that there is multicast data to be transmitted from the reception queue [1-1-2].

[Example 2]
FIG. 7 is a diagram for explaining a multicast collision avoidance procedure according to the second embodiment of this invention.
According to the present embodiment, AP (radio base station apparatus) [7-2] transmits a multicast data packet, and STA (radio terminal apparatus) [7-1] transmits unicast.
AP [7-2] and STA [7-1] perform carrier sense of the AIFS and the backoff period [7-3] in order to check the channel usage status. Here, since the back-off period is a random period, it is usually a period with a different length. However, when the number of STAs to be communicated increases, the probability of selecting a random time with the same length increases.
When the AIFS and the back-off period [7-3] are the same, the STA [7-1] and the AP [7-2] transmit packets simultaneously. The STA [7-1] transmits a unicast data packet [7-4], and the AP [7-2] transmits a null packet [7-6] having no data. At this time, the unicast data packet [7-4] and the null packet [7-6] collide with each other [7-11].
AP [7-2] performs carrier sense [7-18] in the PIFS period after the completion of Null packet [7-6] transmission. When the data length [7-5] of the unicast data packet [7-4] is longer than the data length [7-17] of the Null packet [7-6], the channel is busy [7-13]. As a result, the AP [7-2] stops transmitting the multicast data packet [7-7].
AP [7-2] performs carrier sense for the AIFS and backoff period [7-14] after the channel is idle. If the channel is idle for the period [7-14], the Null packet [7-15] is transmitted again. If the PIFS period [7-19] channel is idle after completion of the transmission of the Null packet [7-15], after the period [7-20], the multicast data packet [7-7] whose transmission was previously stopped is transmitted. To do.
Thereafter, multicast data packets [7-8] and [7-11] are continuously transmitted at SIFS intervals [7-9] for the TXOP period [7-10]. However, if the channel is determined to be busy in the PIFS period [7-19], the procedure for transmitting the Null packet is performed again.

AP [7-2] in FIG. 7 transmits a multicast data packet according to the flowchart in FIG.
AP [7-2] starts [7-1-1] at the time of activation, and determines [7-1-2] whether or not it has a multicast data packet to be transmitted. If there is a multicast data packet, the answer is “Yes”, and then the AIFS period [7-1-3] and the backoff period [7-1-4] check whether the channel is idle. If the channel is idle in the AIFS period [7-1-3] and the backoff period [7-1-4], “Yes” is set, and a Null packet is transmitted [7-1-5].
After the transmission is completed, the PIFS period carrier sense [7-1-9] is performed. If it is not idle, "No" is set, and the flow returns to the flow after the start [7-1-1]. If the channel is idle, it becomes “Yes”, and it is determined [7-1-6] whether the TXOP timer is activated.
If the TXOP timer is not activated, the TXOP timer is started [7-1-7] at the start of data transmission. The AP [7-2] transmits [7-1-8] a multicast data packet simultaneously with the start of the TXOP timer.
After the transmission of the multicast data packet is completed, it is determined [7-11] whether the TXOP timer has expired. If it has expired, it becomes “Yes”, and the flow returns to the flow after the start [7-1-1]. If it has not expired, “No” is determined, and it is determined [7-1-12] whether or not there is a multicast data packet to be transmitted.
If there is no multicast data packet to be transmitted, the answer is “No”, the TXOP timer is ended [7-1-10], and the flow returns to the flow after the start [7-1-1]. If there is a multicast data packet to be transmitted, the answer is “Yes”, and only the SIFS period is waited [7-1-13], and the multicast data packet is transmitted [7-1-8].

FIG. 7-2 is a block diagram illustrating a schematic configuration of a MAC transmission control unit that implements the multicast collision avoidance method according to the second embodiment of the present invention.
A multicast data packet is input [1-1-10] from the upper layer [1-1-1] to the reception queue [1-1-2] of the MAC transmission control unit [1-1-0]. If there is data to be transmitted, the reception queue [1-1-2] notifies the presence of data to be transmitted to the TXOP management unit [1-1-4] [1-1-15].
If the TXOP management unit [1-1-4] has not acquired the TXOP (the TXOP timer is not activated), the AIFS / backoff start notification [1-1-16] is sent to the AIFS / backoff. Notify the carrier sense unit [1-1-5].
The AIFS / backoff carrier sense unit [1-1-5] performs carrier sense triggered by the notification [1-1-16]. If the channel is idle, the AIFS / backoff carrier sense unit [1-1-5] issues a transmission instruction [6-2-17] to the pseudo packet transmission control unit [6-2-3].
The pseudo packet transmission control unit [6-2-3] generates a Null packet having no data and passes the Null packet to the physical layer [1-1-8] [6-2-11]. The physical layer [1-1-8] transmits [1-1-12] to the passed Null packet radio section.

After the transmission is completed, the physical layer [1-1-8] notifies the TXOP management unit [1-1-4] of the completion of Null packet transmission [1-1-19]. When the TXOP management unit [1-1-4] receives the Null packet transmission completion notification [1-1-19], the TXOP management unit [1-1-4] notifies the SIFS / PIFS control unit [7-2-6] [1-1-22]. ]I do.
If the SIFS / PIFS control unit [7-2-6] has not acquired the TXOP (the TXOP timer is not activated), the SIFS / PIFS control unit [7-2-6] performs carrier sense during the PIFS period, and if the channel is busy, The transmission processing stop instruction [7-2-24] is notified to the TXOP management unit [1-1-4].
The TXOP management unit [1-1-4] again notifies the AIFS / backoff carrier sense unit [1-1-5] of the AIFS / backoff start notification [1-1-16].
In the SIFS / PIFS control unit [7-2-6], if the channel is idle, the transmission queue [1-1-3] is notified of the transmission instruction [1-1-23]. The transmission queue [1-1-3] requests [1-1-24] multicast data to be transmitted to the reception queue [1-1-2].
The reception queue [1-1-2] that has received the request [1-1-24] transfers multicast data to the transmission queue [1-1-3], and the transmission queue [1-1-3] Multicast data is passed to the layer [1-1-8] [1-1-11].

The physical layer [1-1-8] transmits [1-1-12] the received multicast data to the radio section as a multicast data packet.
The physical layer [1-1-8] notifies the TXOP management unit [1-1-4] that the multicast data packet has started transmission [1-1-19], and the TXOP management unit [1-1-1-]. 4], the TXOP timer is started.
When receiving the notification [1-1-15] that there is multicast data to be transmitted from the reception queue [1-1-2], the TXOP management unit [1-1-4] receives the SIFS / PIFS control unit [7]. -2-6] is notified [1-1-22].
The SIFS / PIFS control unit [7-2-6] notifies the transmission instruction [1-1-23] to the transmission queue [1-1-3] after the SIFS period when the TXOP timer is activated.
This operation receives notification [1-1-15] that there is multicast data transmitted from the reception queue [1-1-2] by the TXOP management unit [1-1-4] until the TXOP timer expires. Repeated as long as possible.
After the physical layer [1-1-8] is notified [1-1-19] that the multicast data packet has started to be transmitted from the physical layer [1-1-8] to the TXOP management unit [1-1-4], the TXOP management unit [1- 1-4] receives the notification [1-1-15] that there is multicast data to be transmitted from the reception queue [1-1-2], the TXOP management unit [1-1-4] The timer of TXOP is stopped, and it waits until it receives notification [1-1-15] that multicast data to be transmitted exists from the reception queue [1-1-2].

[Example 3]
FIG. 8 is a diagram for explaining a multicast collision avoidance procedure according to the third embodiment of the present invention.
In the present embodiment, the AP (radio base station apparatus) [8-2] transmits a multicast data packet.
AP [8-2] performs carrier sense for the AIFS and the backoff period [8-3] in order to check the channel usage status. After carrying out carrier sense, AP [8-2] transmits a Null packet [8-6] having no data.
AP [8-2] performs carrier sense in the PIFS period [8-13] after completion of transmission of the Null packet [8-6]. If the PIFS period [8-13] channel is idle, a multicast data packet [8-7] is transmitted and TXOP [8-10] is started.
Thereafter, carrier sensing is performed for the PIFS intervals [8-15] and [8-16] only during the TXOP period [8-10], and multicast data packets [8-8] and [8-9] are continuously transmitted.
Here, when the channel is busy [8-17] in the PIFS period [8-20] to be executed before the transmission of the subsequent multicast data packet [8-11], the AP [8-2] The transmission of the multicast data packet [8-11] is stopped.
AP [8-2] performs carrier sense in the AIFS and backoff period [8-18] after the channel becomes idle. If the channel is idle for the period [8-18], the Null packet [8-12] is transmitted again.
After the Null packet [8-12] transmission is completed, if the PIFS period [8-13] channel is idle, the multicast data packet [8-11] whose transmission has been stopped first is transmitted after the period [8-19]. TXOP [8-10] is started when multicast data packet [8-11] is transmitted.
When busy is detected in the period [8-20], there is a possibility that the multicast data packet [8-9] may be lost, but whether the multicast data packet [8-9] is lost or not is determined. Since this cannot be detected, in this embodiment, transmission is started from the packet of the multicast data packet [8-11] that could not be transmitted during the previous TXOP period when transmission was resumed.

The AP [8-2] in FIG. 8 transmits a multicast data packet according to the flowchart in FIG. 8-1.
The AP [8-2] starts [8-1-1] when starting up, and determines [8-1-2] whether or not it has a multicast data packet to be transmitted. If there is a multicast data packet, “Yes” is set, and then the AIFS period [8-1-3] and the backoff period [8-1-4] check whether the channel is idle.
If the channel is idle in the AIFS period [8-1-3] and the backoff period [8-1-4], “Yes” is set, and a Null packet is transmitted [8-1-5]. After Null packet transmission is completed, PIFS period carrier sense [8-1-9] is performed. If it is not idle, "No" is set, and the flow returns to the flow after start [8-1-1].
If the channel is idle, “Yes” is determined, and it is determined [8-1-6] whether the TXOP timer is activated. If the TXOP timer is not activated, the TXOP timer is started [8-1-7] at the start of data transmission. AP [8-2] transmits a multicast data packet [8-1-8] simultaneously with the start of the TXOP timer.
After the transmission of the multicast data packet is completed, it is determined [8-11] whether or not the TXOP timer has expired. If it has expired, it becomes “Yes”, and the flow returns to the flow after start [8-1-1]. If it has not expired, “No” is determined, and it is determined [8-1-12] whether or not there is a multicast data packet to be transmitted.
If there is no multicast data packet to be transmitted, the answer is “No”, the TXOP timer is ended [8-1-10], and the flow returns to the flow after the start [8-1-1]. If there is a multicast data packet to be transmitted, “Yes” is set, and PIFS period carrier sense [8-1-13] is performed. If it is not idle, it becomes “No”, the TXOP timer is ended [8-1-14], and the flow returns to the flow after the start [8-1-1].
If it is idle in the PIFS period carrier sense [8-1-13], “Yes” is set, and a multicast data packet is transmitted [8-1-8].
As described above, until the TXOP expires or as long as there is a multicast data packet to be transmitted, the multicast data packet is transmitted at the carrier sense interval of the PIFS period.

FIG. 8-2 is a block diagram illustrating a schematic configuration of the MAC transmission control unit that implements the multicast collision avoidance method according to the third embodiment of this invention.
A multicast data packet is input [1-1-10] from the upper layer [1-1-1] to the reception queue [1-1-2] of the MAC transmission control unit [1-1-0].
If there is data to be transmitted, the reception queue [1-1-2] notifies the presence of data to be transmitted to the TXOP management unit [1-1-4] [1-1-15]. If the TXOP management unit [l-1-4] has not acquired the TXOP (the TXOP timer is not activated), the AIFS / backoff start notification [1-1-16] is sent to the AIFS / backoff. Notify the carrier sense unit [1-1-5].
The AIFS / backoff carrier sense unit [1-1-5] performs carrier sense triggered by the notification [1-1-16]. If the channel is idle, the AIFS / backoff carrier sense unit [1-1-5] issues a transmission instruction [6-2-17] to the pseudo packet transmission control unit [6-2-3].
The pseudo packet transmission control unit [6-2-3] generates a Null packet having no data and passes the Null packet to the physical layer [1-1-8] [6-2-11]. The physical layer [1-1-8] transmits [1-1-12] the passed Null packet to the radio section.

After the transmission is completed, the physical layer [1-1-8] notifies the TXOP management unit [1-1-4] of the completion of Null packet transmission [1-1-19]. When the TXOP management unit [1-1-4] receives the Null packet transmission completion notification [1-1-19], the TXOP management unit [1-1-4] notifies the PIFS control unit [8-2-6] [1-1-22]. ]I do.
The PIFS control unit [8-2-6] performs carrier sense during the PIFS period, and if the channel is busy, instructs the TXOP management unit [1-1-4] to stop the transmission process [7-2-24]. ] Is notified. The TXOP management unit [1-1-4] again notifies the AIFS / backoff carrier sense unit [1-1-5] of the AIFS / backoff start notification [1-1-16].
The PIFS control unit [8-2-6] notifies the transmission instruction [1-1-23] to the transmission queue [1-1-3] if the channel is idle. The transmission queue [1-1-3] requests [1-1-24] multicast data to be transmitted to the reception queue [1-1-2].
The reception queue [1-1-2] receiving the request [1-1-24] transfers multicast data to the transmission queue [1-1-3], and the transmission queue [1-1-3] is the physical layer. [1-1-8] The multicast data is transferred [1-1-11].
The physical layer [1-1-8] transmits [1-1-12] the received multicast data to the radio section as a multicast data packet. The physical layer [1-1-8] notifies the TXOP management unit [1-1-4] that the multicast data packet has started transmission [1-1-19], and the TXOP management unit [1-1-1-]. 4] starts the TXOP timer.

When receiving the notification [1-1-15] that there is multicast data to be transmitted from the reception queue [1-1-2], the TXOP management unit [1-1-4] receives the PIFS control unit [8-2]. -6] is notified [1-1-22]. If the channel is idle, the PIFS control unit [8-2-6] notifies the transmission queue [1-1-3] of the transmission instruction [1-1-23].
If the channel is busy, the transmission processing stop instruction [7-2-24] is notified to the TXOP management unit [1-1-4]. In this operation, when the PIFS control unit [8-2-6] determines that the channel is idle, the TXOP management unit [1-1-4] receives the reception queue until the TXOP timer expires. As long as it receives notification [1-1-15] that there is multicast data to be transmitted from [1-1-2], it is repeated.
After the physical layer [1-1-8] is notified [1-1-19] that the multicast data packet has started to be transmitted from the physical layer [1-1-8] to the TXOP management unit [1-1-4], the TXOP management unit [1- 1-4] does not receive notification [1-1-15] that there is multicast data to be transmitted from the reception queue [1-1-2], or is busy in the PIFS control unit [8-2-6]. If it is determined, the TXOP management unit [1-1-4] stops the TXOP timer and notifies that there is multicast data to be transmitted from the reception queue [1-1-2] [1-1-15. ] Or wait until the channel becomes idle.

[Example 4]
FIG. 9 is a diagram for explaining a multicast collision avoidance procedure according to the fourth embodiment of the present invention.
In this embodiment, the AP (radio base station apparatus) [9-2] transmits a multicast data packet. AP [9-2] performs AIFS and carrier sense in the back-off period [9-3] in order to check the channel usage status.
After performing carrier sense, AP [9-2] transmits a CTS-to-Self frame [9-6]. The CTS-to-Self frame [9-6] is a frame defined in IEEE802.11g / WiFi-802.11g, and the Duration field of the CTS-to-Self frame [9-6] has a value longer than the TXOP period. Shall be included.
In addition, the STA that has received the CTS-to-Self frame [9-6] is set with a NAV that is prohibited from being transmitted except during the TXOP period. Also, the transmission transmission rate of the CTS-to-Self frame [9-6] is set to the same transmission rate as the multicast transmission rate or an arbitrarily determined transmission rate, and is transmitted at the set transmission rate.
AP [9-2] performs carrier sense in the PIFS period [9-13] after completing the transmission of the CTS-to-Self frame [9-6]. If the PIFS period [9-13] channel is idle, a multicast data packet [9-7] is transmitted and TXOP [9-10] is started.
After that, the carrier sense of PIFS intervals [9-15] and [9-16] is performed only during the TXOP period [9-10], and multicast data packets [9-8] and [9-9] are continuously transmitted.
Here, when the carrier sense of PIFS is busy, the transmission of the multicast data packet is stopped and the carrier sense is performed during the AIFS and the back-off period after the channel becomes idle as in the third embodiment. Then, the CTS-to-Self frame is transmitted again.

AP [9-2] in FIG. 9 transmits a multicast data packet according to the flowchart in FIG.
AP [9-2] starts [9-1-1] at the time of activation, and determines [9-1-2] whether or not it has a multicast data packet to be transmitted.
If there is a multicast data packet, “Yes” is set, and then the AIFS period [9-1-3] and the backoff period [9-1-4] check whether the channel is idle. If the channel is idle in the AIFS period [9-1-3] and the backoff period [9-1-4], the channel becomes “Yes” and the CTS-to-Self frame is transmitted [9-1-5]. . The transmission [9-1-5] of the CTS-to-Self frame is performed at the same transmission rate as the multicast data packet or an arbitrarily determined transmission rate.
After transmission of the CTS-to-Self frame is completed, PIFS period carrier sense [9-1-9] is performed. If it is not idle, "No" is set, and the flow returns to the flow after start [9-1-1]. If the channel is idle, “Yes” is determined and it is determined [9-1-6] whether the TXOP timer is activated. If the TXOP timer is not activated, the TXOP timer is started [9-1-7] at the start of data transmission.

AP [9-2] transmits [9-1-8] a multicast data packet simultaneously with the start of the TXOP timer. After the transmission of the multicast data packet is completed, it is determined [9-1-11] whether the TXOP timer has expired. If it has expired, it becomes “Yes”, and the flow returns to the flow after start [9-1-1]. If it has not expired, “No” is determined, and it is determined [9-1-12] whether or not there is a multicast data packet to be transmitted.
If there is no multicast data packet to be transmitted, the result is “No”, the TXOP timer is ended [9-1-10], and the flow returns to the flow after the start [9-1-1]. If there is a multicast data packet to be transmitted, “Yes” is set, and PIFS period carrier sense [9-1-13] is performed.
If it is not idle, it becomes “No”, the TXOP timer is ended [9-1-14], and the flow returns to the flow after the start [9-1-1]. If it is idle in the PIFS period carrier sense [9-1-13], “Yes” is set, and a multicast data packet is transmitted [9-1-8]. As described above, until the TXOP expires or as long as there is a multicast data packet to be transmitted, the multicast data packet is transmitted at the carrier sense interval of the PIFS period.

FIG. 9-2 is a block diagram illustrating a schematic configuration of a MAC transmission control unit that implements the multicast collision avoidance method according to the fourth embodiment of the present invention.
A multicast data packet is input [1-1-10] from the upper layer [1-1-1] to the reception queue [1-1-2] of the MAC transmission control unit [1-1-0]. If there is data to be transmitted, the reception queue [1-1-2] notifies the presence of data to be transmitted to the TXOP management unit [1-1-4] [1-1-15].
If the TXOP management unit [1-1-4] has not acquired the TXOP (the TXOP timer is not activated), the AIFS / backoff start notification [1-1-16] is sent to the AIFS / backoff. Notify the carrier sense unit [1-1-5].
The AIFS / backoff carrier sense unit [1-1-5] performs carrier sense triggered by the notification [1-1-16]. If the channel is idle, the AIFS / backoff carrier sense unit [1-1-5] issues a transmission instruction [6-2-17] to the CTS-to-Self transmission control unit [9-2-3]. .
The CTS-to-Self transmission control unit [9-2-3] generates a CTS-to-Self frame and passes it to the physical layer [1-1-8] [9-2-11]. When passing the CTS-to-Self frame to the physical layer [1-1-8], the same transmission rate as the multicast data packet or an arbitrarily determined transmission rate is also notified [9-2-4]. To do.

The physical layer [1-1-8] transmits [1-1-12] the transferred CTS-to-Self frame at the transmission rate notified [9-2-4] to the wireless section. After the transmission is completed, the physical layer [1-1-8] notifies the TXOP management unit [1-1-4] of the completion of CTS-to-Self frame transmission [1-1-19].
When the TXOP management unit [1-1-4] receives the CTS-to-Self frame transmission completion notification [1-1-19], the TXOP management unit [1-1-4] notifies the PIFS control unit [8-2-6] [1-1]. -1-22].
The PIFS control unit [8-2-6] performs carrier sense during the PIFS period, and if the channel is busy, instructs the TXOP management unit [1-1-4] to stop the transmission process [7-2-24]. ] Is notified. The TXOP management unit [1-1-4] again notifies the AIFS / backoff carrier sense unit [1-1-5] of the AIFS / backoff start notification [1-1-16].
If the channel is idle in the PIFS control unit [7-2-6], the transmission instruction [1-1-23] is notified to the transmission queue [1-1-3]. The transmission queue [1-1-3] requests [1-1-24] multicast data to be transmitted to the reception queue [1-1-2]. The reception queue [1-1-2] receiving the request [1-1-24] transfers multicast data to the transmission queue [1-1-3], and the transmission queue [1-1-3] is the physical layer. [1-1-8] The multicast data is transferred [1-1-11].
The physical layer [1-1-8] transmits [1-1-12] the received multicast data to the wireless section as a multicast data packet. The physical layer [1-1-8] notifies the TXOP management unit [1-1-4] that transmission of a multicast data packet has started [1-1-19].

Upon receiving the notification, the TXOP management unit [1-1-4] starts a TXOP timer. When receiving the notification [1-1-15] that there is multicast data to be transmitted from the reception queue [1-1-2], the TXOP management unit [1-1-4] receives the PIFS control unit [7-2]. -6] is notified [1-1-22].
If the channel is idle, the PIFS control unit [8-2-6] notifies the transmission queue [1-1-3] of the transmission instruction [1-1-23]. If the channel is busy, the transmission processing stop instruction [7-2-24] is notified to the TXOP management unit [1-1-4].
In this operation, if the PIFS control unit [7-2-6] determines that the channel is idle, the TXOP management unit [1-1-4] receives the reception queue until the TXOP timer expires. As long as it receives notification [1-1-15] that there is multicast data to be transmitted from [1-1-2], it is repeated.
After the physical layer [1-1-8] notifies the TXOP management unit [1-1-4] that transmission of a multicast data packet is started [1-1-19], the TXOP management unit [1- 1-4] does not receive notification [1-1-15] that there is multicast data to be transmitted from the reception queue [1-1-2], or is busy in the PIFS control unit [8-2-6]. If it is determined, the TXOP management unit [1-1-4] stops the TXOP timer and notifies that there is multicast data to be transmitted from the reception queue [1-1-2] [1-1-15. ] Or wait until the channel becomes idle.

[Example 5]
FIG. 10 is a diagram for explaining a multicast collision avoidance procedure according to the fifth embodiment of the present invention.
In this embodiment, the AP (radio base station apparatus) [10-2] transmits a multicast data packet. The AP [10-2] transmits the beacon signal [10-6] at a fixed period (Beacon Interval) [10-22]. Here, the beacon signal [10-6] is transmitted after an arbitrarily determined AIFS period and backoff period [10-3].
The multicast data packet [10-7] is transmitted after the beacon signal [10-6] is transmitted. That is, after transmitting the beacon signal [10-6], carrier sensing is performed in the PIFS period [10-13] and if it is idle, the multicast data packet [10-7] is transmitted, and TXOP [10-10] is transmitted. Start.
After that, during the TXOP period [10-10], carrier sense of PIFS intervals [10-15], [10-16] is performed and multicast data packets [10-8], [10-9] are continuously transmitted. . Here, when the PIFS carrier sense is busy, the transmission of the multicast data packet is stopped. After the channel becomes idle, the PIFS period carrier sense is performed again. Send.
However, at this time, it is assumed that the transmission time of the multicast data packet does not exceed the TXOP period [10-10]. In addition, the TXOP period [10-10] setting period in the AP [10-2] is set to a value that does not exceed a certain period (Beacon Interval).

The AP [10-2] in FIG. 10 transmits a multicast data packet according to the flowchart in FIG. 10-1.
AP [10-2] starts [10-1-1] at the time of activation, and first determines [10-1-0] whether or not it is the transmission cycle of the beacon signal. If the transmission period of the beacon signal is “Yes”, then it is checked whether the AIFS period [10-1-3] and the backoff period [10-1-4] channel are idle.
The ranges of the AIFS period [10-1-3] and the back-off period [10-1-4] are arbitrarily set. In the AIFS period [10-1-3] and the back-off period [10-1-4], if the channel is idle, “Yes” is determined and it is determined whether or not there is a multicast data packet to be transmitted [10-1 -2].
If there is a multicast data packet, “Yes” is set, and a beacon is transmitted [10-1-5]. After the transmission is completed, the PIFS period carrier sense [10-1-9] is performed, and if it is not idle, “No” is determined and it is determined whether it is the next beacon period [10-1-20]. If it is the next beacon period, “Yes” is set, and the flow returns to the flow after start [10-1-1].

If the channel is idle, “Yes” is determined and it is determined [10-1-6] whether the TXOP timer is activated. If the TXOP timer is not activated, the TXOP timer is started [10-1-7] at the start of data transmission.
The AP [10-2] transmits [10-1-8] a multicast data packet simultaneously with the start of the TXOP timer. After the transmission of the multicast data packet is completed, it is determined [10-1-11] whether the TXOP timer has expired. If it has expired, it becomes “Yes”, and the flow returns to the flow after start [10-1-1].
If it has not expired, “No” is determined, and it is determined [10-1-12] whether it is “not the next beacon period” or “no multicast data packet to be transmitted”. When it corresponds to either “No next beacon period” or “No multicast data packet to be transmitted”, it is “No”, the TXOP timer is ended [10-1-10], and the start [ 10-1-1] Return to the subsequent flow.
If it does not correspond to either “not the next beacon period” or “does not have a multicast data packet to transmit”, “Yes” is set, and PIFS period carrier sense [10-1-13] is performed. If it is not idle, it becomes "No" and returns to the determination of [10-1-12].
In the PIFS period carrier sense [10-1-13], if it is idle, “Yes” is set, and a multicast data packet is transmitted [10-1-8]. As described above, until the TXOP expires or as long as there is a multicast data packet to be transmitted, the multicast data packet is transmitted at the carrier sense interval of the PIFS period.

FIG. 10-2 is a block diagram illustrating a schematic configuration of a MAC transmission control unit that implements the multicast collision avoidance method according to the fifth embodiment of the present invention.
A multicast data packet is input [1-1-10] from the upper layer [1-1-1] to the reception queue [1-1-2] of the MAC transmission control unit [1-1-0]. If there is data to be transmitted, the reception queue [1-1-2] notifies the presence of data to be transmitted to the TXOP management unit [1-1-4] [1-1-15].
The beacon period management unit [10-2-4] manages the beacon transmission period and notifies the TXOP management unit [1-1-4] of the beacon transmission opportunity [10-2-22].
When receiving the notification [10-2-22], if the TXOP management unit [1-1-4] has not acquired the TXOP (the TXOP timer is not activated), the AIFS and the backoff are performed. The start notification [1-1-16] is notified to the AIFS / backoff carrier sense unit [1-1-5].
The AIFS / backoff carrier sense unit [1-1-5] performs carrier sense triggered by the notification [1-1-16]. If the channel is idle, the AIFS / backoff carrier sense unit [1-1-5] issues a transmission instruction [6-2-17] to the beacon transmission control unit [10-2-3].

The beacon transmission control unit [10-2-3] generates a beacon and passes the beacon to the physical layer [1-1-8] [10-2-11]. The physical layer [1-1-8] transmits [1-1-12] the passed beacon to the radio section.
After the transmission is completed, the physical layer [1-1-8] notifies the TXOP management unit [1-1-4] of the completion of beacon transmission [1-1-19]. When receiving the beacon transmission completion notification [1-1-19], the TXOP management unit [1-1-4] sends a notification [1-1-22] to the PIFS control unit [10-2-6]. Do.
The PIFS control unit [10-2-6] performs carrier sense during the PIFS period. If the channel is busy, the PIFS control unit [10-2-6] inquires of the TXOP management unit [1-1-4] whether the next beacon period has been reached. [10-2-24].
When the next beacon period has been reached, the TXOP management unit [1-1-4] sends an AIFS and backoff start notification [1-1-16] to the AIFS / backoff carrier sense unit [1-1. To -5]. If the next beacon period has not been reached, the TXOP management unit [1-1-4] instructs the PIFS control unit [10-2-6] again to perform carrier sense during the PIFS period.
In the PIFS control unit [10-2-6], if the channel is idle, the transmission queue [1-1-3] is notified of the transmission instruction [1-1-23]. The transmission queue [1-1-3] requests [1-1-24] multicast data to be transmitted to the reception queue [1-1-2].

The reception queue [1-1-2] receiving the request [1-1-24] transfers multicast data to the transmission queue [1-1-3], and the transmission queue [1-1-3] is the physical layer. [1-1-8] The multicast data is transferred [1-1-11].
The physical layer [1-1-8] transmits [1-1-12] the received multicast data to the wireless section as a multicast data packet.
The physical layer [1-1-8] notifies the TXOP management unit [1-1-4] that the multicast data packet has started transmission [1-1-19], and the TXOP management unit [1-1]. -4] starts the TXOP timer. When receiving the notification [1-1-15] that there is multicast data to be transmitted from the reception queue [1-1-2], the TXOP management unit [1-1-4] receives the PIFS control unit [10-2-2]. 6] is notified [1-1-22].
If the channel is idle, the PIFS control unit [10-2-6] notifies the transmission queue [1-1-3] of the transmission instruction [1-1-23]. If the channel is busy, the TXOP management unit [1-1-4] is inquired whether the next beacon period has been reached [10-2-24].
When the next beacon period has been reached, the TXOP management unit [1-1-4] sends the AIFS and backoff start notification [1-1-16] to the AIFS / backoff carrier sense unit [1-1]. To -5]. If the next beacon period has not been reached, the TXOP management unit [1-1-4] instructs the PIFS control unit [10-2-6] again to perform carrier sense during the PIFS period.

In this operation, if the PIFS control unit [10-2-6] determines that the channel is idle, the TXOP management unit [1-1-4] receives the data until the TXOP timer expires. This is repeated as long as notification [1-1-15] that there is multicast data to be transmitted is received from the queue [1-1-2].
After the physical layer [1-1-8] is notified [1-1-19] that the multicast data packet has started to be transmitted from the physical layer [1-1-8] to the TXOP management unit [1-1-4], the TXOP management unit [1- 1-4] receives the notification [1-1-15] that there is multicast data to be transmitted from the reception queue [1-1-2], the TXOP management unit [1-1-4] It waits until it receives notification [1-1-15] that multicast data to be transmitted exists from the reception queue [1-1-2].
As mentioned above, the invention made by the present inventor has been specifically described based on the above embodiments. However, the present invention is not limited to the above embodiments, and various modifications can be made without departing from the scope of the invention. Of course.

It is a figure for demonstrating the conventional unicast data packet transmission procedure. It is a block diagram which shows schematic structure of the conventional MAC transmission control part. It is a flowchart which shows the conventional unicast data packet transmission procedure. It is a figure for demonstrating the conventional multicast data packet transmission procedure. It is a figure for demonstrating the transmission / reception procedure of the conventional unicast data packet and a multicast data packet. It is a figure for demonstrating the example at the time of the conventional multicast data packet collision occurrence. It is a figure for demonstrating the example at the time of the conventional multicast data packet continuous collision occurrence. It is a figure for demonstrating the collision avoidance procedure of the multicast data packet of Example 1 of this invention. It is a flowchart which shows the transmission procedure of the multicast data packet of Example 1 of this invention. It is a block diagram which shows schematic structure of the MAC transmission control part which implements the multicast data packet collision avoidance method of Example 1 of this invention. It is a figure for demonstrating the collision avoidance procedure of the multicast data packet of Example 2 of this invention. It is a flowchart which shows the transmission procedure of the multicast data packet of Example 2 of this invention. It is a block diagram which shows schematic structure of the MAC transmission control part which implements the multicast data packet collision avoidance method of Example 2 of this invention. It is a figure for demonstrating the collision avoidance procedure of the multicast data packet of Example 3 of this invention. It is a flowchart which shows the transmission procedure of the multicast data packet of Example 3 of this invention. It is a block diagram which shows schematic structure of the MAC transmission control part which implements the multicast data packet collision avoidance method of Example 3 of this invention. It is a figure for demonstrating the collision avoidance procedure of the multicast data packet of Example 4 of this invention. It is a flowchart which shows the multicast data packet transmission procedure of Example 4 of this invention. It is a block diagram which shows schematic structure of the MAC transmission control part which implements the multicast data packet collision avoidance method of Example 4 of this invention. It is a figure for demonstrating the collision avoidance procedure of the multicast data packet of Example 5 of this invention. It is a flowchart which shows the multicast data packet transmission procedure of Example 5 of this invention. It is a block diagram which shows schematic structure of the MAC transmission control part which implements the multicast data packet collision avoidance method of Example 5 of this invention.

Explanation of symbols

3-1 Transmitting station 3-2, 3-3 Receiving station 4-1, 5-1, 6-1 Wireless terminal device (STA)
4-2,5-2,6-2,8-2,9-2,10-2 Radio base station apparatus (AP)
1-1-0 MAC Transmission Control Unit 1-1-1 Upper Layer 1-1-2 Reception Queue 1-1-3 Transmission Queue 1-1-4 TXOP Management Unit 1-1-5 AIFS / Backoff Carrier Sense Unit 1-1-6 SIFS Control Unit 1-1-7 ACK Reception Determination Unit 1-1-8 Physical Layer 6-2-3 Pseudo Packet Transmission Control Unit 7-2-6 SIFS / PIFS Control Unit 8-2-6 10-2-6 PIFS control unit 9-2-3 CTS-to-Self transmission control unit 10-2-3 beacon transmission control unit 10-2-4 beacon period management unit

Claims (10)

A wireless LAN in a wireless LAN communication system that includes a wireless base station device and a plurality of wireless terminal devices that transmit and receive data packets by wireless packet communication with the wireless base station device, and transmits the data packets according to the CSMA / CA protocol A data packet collision avoidance control method,
The radio base station apparatus or the radio terminal apparatus, when transmitting the data packet, to implement one regular and between random period carrier sensing,
When acquiring the transmission right after the carrier sense for the predetermined period and the random period, a packet without data is transmitted first,
A wireless LAN data packet collision characterized by transmitting the data packet continuously at a short interval without performing carrier sense over a period in which an arbitrarily determined transmission right can be maintained after completion of packet transmission without the data Avoidance control method. After completion of packet transmission without the data, carrier sense is performed,
As a result of carrier sense after completion of packet transmission without data, when the channel is idle, the carrier sense is continuously performed at a short interval without performing carrier sense over a period in which the arbitrarily determined transmission right can be maintained. If the channel is busy as a result of carrier sense after transmitting the data packet and completing the packet transmission without the data, the transmission of the data packet is stopped, and the data packet is again transmitted according to the CSMA / CA protocol. The wireless LAN data packet collision avoidance control method according to claim 1, wherein transmission is performed. When transmitting the data packet continuously over a period in which the arbitrarily determined transmission right can be maintained after the packet transmission without the data is performed, carrier sense is performed before the transmission of each data packet,
When the channel is idle as a result of carrier sense before transmission of each data packet, the data packet is transmitted. When the channel is busy as a result of carrier sense before transmission of each data packet. The wireless LAN data packet collision avoidance control method according to claim 1, wherein the transmission of the data packet is stopped and the data packet is transmitted again according to the CSMA / CA protocol. A wireless LAN in a wireless LAN communication system that includes a wireless base station device and a plurality of wireless terminal devices that transmit and receive data packets by wireless packet communication with the wireless base station device, and transmits the data packets according to the CSMA / CA protocol A data packet collision avoidance control method,
The radio base station apparatus or the radio terminal apparatus, when transmitting the data packet, to implement one regular and between random period carrier sensing,
The CTS-to-Self frame that describes a period during which other radio base station apparatuses or other radio terminal apparatuses suppress transmission when acquiring the transmission right after the carrier sense for the predetermined period and the random period at a transmission rate arbitrarily determined Send
After transmitting the CTS-to-Self frame, when transmitting the data packet continuously over a period in which an arbitrarily determined transmission right can be maintained, carrier sense is performed before transmitting each data packet; When the channel is idle as a result of carrier sense before transmission of each data packet, the data packet is transmitted. When the channel is busy as a result of carrier sense before transmission of each data packet. Stops transmitting the data packet, and transmits the data packet again according to the CSMA / CA protocol. A radio base station apparatus and a plurality of radio terminal apparatuses that transmit and receive data packets by radio packet communication with the radio base station apparatus, the radio base station apparatus transmits a beacon signal at a constant period, and CSMA / CA A wireless LAN data packet collision avoidance control method in a wireless LAN communication system for transmitting the data packet according to a protocol,
The radio base station apparatus, when transmitting the data packet, to implement one regular and between random period carrier sensing,
Transmitting the beacon signal at the time of transmission right acquisition after the fixed period and random period carrier sense,
After transmitting the beacon signal, when transmitting the data packet continuously over a period in which an arbitrarily determined transmission right can be maintained, carrier sense is performed before transmitting each data packet, and each data packet is transmitted. If the channel is idle as a result of carrier sense before transmission, the data packet is transmitted. If the channel is busy as a result of carrier sense before transmission of each data packet, the data is transmitted. A wireless LAN data packet collision avoidance control method, comprising: stopping packet transmission and transmitting the data packet as soon as the channel becomes idle. A radio base station apparatus, wherein is composed of a plurality of wireless terminal devices for transmitting and receiving data packets by the wireless base station apparatus and the wireless packet communication, said in the wireless LAN communication system that transmits the data packets according to CSMA / CA protocol wireless A wireless LAN data packet collision avoidance control device provided in a base station device or the wireless terminal device ,
When transmitting the data packet, and AIFS / backoff carrier sense unit implementing one regular and between random period carrier sensing,
A pseudo packet transmission control unit for transmitting a packet having no data at the beginning when acquiring the transmission right after the fixed period and the random period carrier sense;
A SIFS control unit for instructing transmission of the data packet continuously at a short interval without performing carrier sense over a period in which the arbitrarily determined transmission right can be maintained after transmission of the packet without the data is completed. A feature of the wireless LAN data packet collision avoidance control device. A radio base station apparatus, wherein is composed of a plurality of wireless terminal devices for transmitting and receiving data packets by the wireless base station apparatus and the wireless packet communication, said in the wireless LAN communication system that transmits the data packets according to CSMA / CA protocol wireless A wireless LAN data packet collision avoidance control device provided in a base station device or the wireless terminal device ,
When transmitting the data packet, and AIFS / backoff carrier sense unit implementing one regular and between random period carrier sensing,
A pseudo packet transmission control unit for transmitting a packet having no data at the beginning when acquiring the transmission right after the fixed period and the random period carrier sense;
A period in which carrier sense is performed after completion of packet transmission without the data, and when the channel is idle as a result of carrier sense after completion of packet transmission without the data, an arbitrarily determined transmission right can be maintained. If the channel is busy as a result of carrier sense after completion of packet transmission without instructing transmission of the data packet continuously at short intervals without performing carrier sense, the data A wireless LAN data packet collision avoidance control apparatus, comprising: a SIFS / PIFS control unit that stops packet transmission. A radio base station apparatus, wherein is composed of a plurality of wireless terminal devices for transmitting and receiving data packets by the wireless base station apparatus and the wireless packet communication, said in the wireless LAN communication system that transmits the data packets according to CSMA / CA protocol wireless A wireless LAN data packet collision avoidance control device provided in a base station device or the wireless terminal device ,
When transmitting the data packet, and AIFS / backoff carrier sense unit implementing one regular and between random period carrier sensing,
A pseudo packet transmission control unit for transmitting a packet having no data at the beginning when acquiring the transmission right after the fixed period and the random period carrier sense;
When transmitting the data packet continuously over a period in which the arbitrarily determined transmission right can be maintained after the packet transmission without the data is performed, carrier sense is performed before the transmission of each data packet, When the channel is idle as a result of carrier sense before transmission of each data packet, the transmission of the data packet is instructed, and when the channel is busy as a result of carrier sense before transmission of each data packet The wireless LAN data packet collision avoidance control apparatus includes a PIFS control unit that stops transmission of the data packet. A radio base station apparatus, wherein is composed of a plurality of wireless terminal devices for transmitting and receiving data packets by the wireless base station apparatus and the wireless packet communication, said in the wireless LAN communication system that transmits the data packets according to CSMA / CA protocol wireless A wireless LAN data packet collision avoidance control device provided in a base station device or the wireless terminal device ,
When transmitting the data packet, and AIFS / backoff carrier sense unit implementing one regular and between random period carrier sensing,
The CTS-to-Self frame that describes a period during which other radio base station apparatuses or other radio terminal apparatuses suppress transmission when acquiring the transmission right after the carrier sense for the predetermined period and the random period at a transmission rate arbitrarily determined A CTS-to-Self transmission control unit for transmission;
After transmitting the CTS-to-Self frame, when transmitting the data packet continuously over a period in which an arbitrarily determined transmission right can be maintained, carrier sense is performed before transmitting each data packet; When the channel is idle as a result of carrier sense before transmission of each data packet, the transmission of the data packet is instructed, and as a result of carrier sense before transmission of each data packet, the channel is busy In this case, the wireless LAN data packet collision avoidance control device includes a PIFS control unit that stops transmission of the data packet. A radio base station apparatus and a plurality of radio terminal apparatuses that transmit and receive data packets by radio packet communication with the radio base station apparatus, the radio base station apparatus transmits a beacon signal at a constant period, and CSMA / CA A wireless LAN data packet collision avoidance control device provided in the wireless base station device in a wireless LAN communication system that transmits the data packet according to a protocol ,
When transmitting the data packet, and AIFS / backoff carrier sense unit implementing one regular and between random period carrier sensing,
A beacon transmission control unit for transmitting the beacon signal at the time of transmission right acquisition after the fixed period and the random period carrier sense;
After transmitting the beacon signal, when transmitting the data packet continuously over a period in which an arbitrarily determined transmission right can be maintained, carrier sense is performed before transmitting each data packet, and each data packet is transmitted. If the channel is idle as a result of carrier sense before transmission, the data packet is instructed to be transmitted. If the channel is busy as a result of carrier sense before transmission of each data packet, A wireless LAN data packet collision avoidance control apparatus comprising: a PIFS control unit that stops transmission of a data packet and instructs the transmission of the data packet as soon as the channel becomes idle.

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