JPH11196041A - Radio multicast transfer method and radio communication system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a radio multicast data transfer method capable of improving its reliability, even against a channel of poor quality and also keeping its high data transfer efficiency, even when the number of receiving stations increases. SOLUTION: Receiving stations 201 to 205 are divided into groups 211 to 213 which can be mutually transmitted and received. A transmitting station 101 selects a key station of each group to send a multicast data frame 301 to the key station and performs polling 341 to the group 211. The station 201 serving as a key station receives a frame and returns an ACK311. A station 202 which is not serving as a key station monitors the response of a key station and returns a NAK321, only when a retransmission request is needed. Thus, the station 101 interrupts its polling, immediately sends a retransmission frame 331 and performs polling 342 again to the station 202 to acquire an ACK312. if no NAK is confirmed in a fixed time T1, the station 101 applies polling to another group and ends the transfer of data, when an ACK314 is received from the key station 205 of the final group 213.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for selectively transmitting broadcast data by wireless multicast communication, in which a receiving station returns a response frame to a transmitting station for broadcast data sent from a transmitting station. The present invention relates to a wireless multicast data transfer method and a wireless communication system in which a transmitting station retransmits a frame as needed.

[0002]

2. Description of the Related Art Conventionally, as a means for collectively transferring the same data to a plurality of specific receiving stations, multicast communication has been carried out using IETF (Internet Engineering Task F).
orce). In IP multicast using an Internet protocol (hereinafter referred to as “IP”), a best-effort service is assumed, and retransmission of an erroneous packet during data transfer is not considered (“Host Extensions for IP Multicas”).
t ”, IETF RFC 1112, 1989).

Generally, in a multicast communication system in which retransmission of erroneous data is considered, when a receiving station detects an error in a received packet or data frame, a negative acknowledgment (#) indicating an erroneous frame number as a response is received. Negati
ve Acknowledgement: hereinafter, referred to as “NAK”) is sent back to the transmitting station to make a retransmission request. The transmitting station performs retransmission only when retransmission is requested by NAK.

[First Conventional Example] FIG. 1 is a diagram showing a first example of multicast data transfer according to a conventional technique. In this figure, the transmitting station 101 sends the receiving stations 201 to 20 to each other.
5 shows how the data transfer to multicast 5 is performed with time. In the figure, a white rectangle indicates a data frame, a black rectangle indicates a NAK frame, a downward arrow extending in a vertical direction indicates a lapse of time, and an oblique arrow extending in a substantially horizontal direction indicates a state in which a frame is transmitted. . Note that these notations are the same in each of the following drawings.

In FIG. 1, the transmitting station 101 waits for a response from the receiving station after transmitting the multicast data frame 301. Here, the multicast data frame is created by giving the address of the destination receiving station group or the like to the broadcast data, and data transmission is performed to a plurality of receiving stations by one frame transmission. When each receiving station detects an error in the received multicast data frame 301, it returns a NAK frame to the transmitting station 101 and requests retransmission. FIG. 3 shows an example in which the receiving station 201 and the receiving station 205 detect an error in a frame. That is, after receiving the multicast data frame 301, the receiving station 201 transmits the NAK 321 to the transmitting station 1
01 and the receiving station 205 is NAK322
To the transmitting station 101.

In transmitting station 101, NAK 321 and NA
K322 is received, and the frames requested by these NAKs are retransmitted as retransmission frames 331. Then, after the retransmission is completed, the transmitting station 101 regards that the data transfer has succeeded if no further retransmission of the frame is requested.

On the other hand, if there is subsequent multicast data at this time, the transmitting station 101 can transfer the next multicast data. In this case, the transmitting station 10
1 transmits a multicast data frame 302, and thereafter, retransmits as necessary according to the same procedure as described above. FIG. 3 shows an example in which a frame is incorrect in the receiving station 203 when the transmitting station 101 transmits the multicast data frame 302. Therefore, the receiving station 203
Transmits NAK 323 requesting retransmission of a frame to transmitting station 10.
In this case, it is assumed that the NAK 323 is incorrect on the transmission path. Therefore, the NAK 323 does not reach the transmitting station 101, and the transmitting station 101 cannot recognize the necessity of retransmission, and regards the transfer of the multicast data frame 302 as successful. Moreover, the transmitting station 101
Since the transmission ends when there is no subsequent data, the multicast data transfer to the receiving station 203 ends in failure.

[Second Conventional Example] Next, FIG. 2 is a diagram showing a second example of the conventional multicast data transfer.
The same components as those in FIG. 1 are denoted by the same reference numerals. FIG. 2 also shows a state in which data transmission is performed by multicast from the transmitting station 101 to the receiving stations 201 to 205 as time elapses, similarly to FIG. The figure shows an example in which the multicast data is divided into four frames and sent to the receiving station. A white rectangle representing the data frame is divided into four sections, and a number shown inside each section is assigned to the frame. Means the assigned sequence number. In the figure, a hatched rectangle indicates an acknowledgment (Acknowledgement:
Hereinafter, this will be referred to as “ACK”).

In FIG. 2, the transmitting station 101 waits for a response from the receiving station after transmitting the multicast data frame 301 composed of a series of frames from the first to the fourth. Each receiving station returns an ACK to the transmitting station 101 when all of the transmitted multicast data frames 301 are received without error, while an error is detected when an error is detected in the received multicast data frame 301. Retransmission is requested by returning the frame number to the transmitting station 101 as a NAK frame.

In FIG. 2, receiving station 202 and receiving station 203
Receives a series of frames without error and returns ACK3
11 and ACK 312 are returned to the transmitting station 101. Also, in FIG.
An example is shown in which the third frame is incorrect and the third frame is incorrect in the receiving station 205. At this time,
The receiving station 201 returns NAK321 to the transmitting station 101, and the receiving station 205 returns NAK322 to the transmitting station 101, thereby requesting retransmission of the second and third frames, respectively.

[0011] When the transmitting station 101 receives the NAK,
The frame of the number requested by the received NAK is retransmitted. In the case of FIG. 2, the transmitting station 101 has NAK321 and NA
The second and third frames requested by K322 are retransmitted as retransmission frame 331 and retransmission frame 332, respectively. In response, the receiving station that has requested retransmission returns an ACK to transmitting station 101 if the frame requested by itself has been correctly received. That is, the receiving station 201 and the receiving station 205 return ACKs 313 and ACK 314 to the transmitting station 101, respectively, to notify the transmitting station 101 of the successful reception. The transmitting station 101 determines that transmission has been completed when ACKs have been returned from all the receiving stations, and determines that transmission of the multicast data frame 301 has been completed when the ACK 314 has been received from the receiving station 205.

[0012] When the transmitting station 101 completes the transmission of the multicast data, the subsequent multicast data can be transferred. In the figure, it is assumed that the transfer of the multicast data frame 302 is performed after the transfer of the multicast data frame 301 is completed.
It is transmitted in the number frame. In this case, the receiving station 201 and the receiving station 202 perform reception without error and return ACK 315 and ACK 316 to the transmitting station 101, respectively.
Also, FIG. 2 shows a case where the seventh frame is incorrect in receiving station 203, and retransmission is performed in the same procedure as described above. That is, the receiving station 203 transmits
NAK323 is returned to 01 to request retransmission of the seventh frame. Then, the transmitting station 101 retransmits the requested seventh frame as a retransmission frame 333, and if the frame requested by the receiving station 203 is correctly received, the ACK 31
8 is returned to the transmitting station 101 to notify the reception success.

In addition, FIG. 2 also shows a case where the ACK 317 from the receiving station 205 is incorrect. In this case, the transmitting station 101 cannot recognize the receiving situation of the receiving station 205. Therefore, the transmitting station 101 starts a timer at the end of transmission of the multicast data frame 302, and
The timeout of this timer triggers the receiving station 205
The polling of the receiving station 205 (polling 341 in the figure) is performed in order to know the receiving status of the receiving station 205. Receiving station 205
Is an ACK to the polling signal from the transmitting station 101.
319, the state of the own station is transmitted to the transmitting station 10.
Notify 1. It is assumed that the transmitting station 101 has completed the retransmission of the multicast data frame 302 after receiving the ACK 319.

[0014]

As described above, in the multicast data transfer method shown in the first conventional example, the transmitting station 101 performs retransmission upon the NAK from the receiving station. Therefore, when the NAK does not reach the transmitting station 101 correctly due to a transmission error, or when NAKs transmitted from a plurality of receiving stations collide on the transmission path, the transmitting station 101 can recognize the necessity of retransmission. The required retransmission was not performed. Therefore, there is a problem that the reliability of the multicast data transfer is reduced.

For this reason, when the receiving station returns a NAK, a back-off algorithm is used to reduce the probability of a NAK frame collision, or an individual connection is established to return a response. However, in such a case, there is a problem that when the number of receiving stations increases, the time for delivery confirmation becomes enormous, and the transfer efficiency of multicast data decreases.

In the multicast data transfer method shown in the second conventional example, ACK and NA are used to confirm delivery.
Although reliability is ensured by using K together, there is a problem that the transmitting station 101 needs to receive responses from all receiving stations. Therefore, when the receiving station returns a response such as ACK or NAK, a back-off algorithm is used to reduce the collision probability of the response frame, or
Individual connections were made to return responses. However, also in this case, there is a problem that as the number of receiving stations increases, the time required for confirming delivery increases.

Further, in the second conventional example, if a response such as ACK or NAK returned by the receiving station is incorrect on the transmission line, the transmitting station 1
In the case of No. 01, it is necessary to confirm by polling or the like the receiving station that has failed to receive a response after waiting for a timeout, so that there is also a problem that an increase in transmission time causes deterioration of transmission efficiency. The present invention has been made in view of the above points, and has as its object to reduce the reliability of a communication path of poor quality and to increase the time required for a response when the number of receiving stations increases, thereby increasing the data rate. It is an object of the present invention to provide a wireless multicast data transfer method and a wireless communication system that can solve the problems of conventional multicast data transfer such as a decrease in transfer efficiency.

[0018]

In order to solve the above-mentioned problems, according to the first aspect of the present invention, a transmitting station creates a frame in which broadcast data is provided with an address of a destination receiving station group and the like,
Perform data transfer to the receiving station in one frame transmission,
The receiving station returns an acknowledgment if the broadcast data is correctly received, and returns a negative acknowledgment if the frame has an error.When the transmitting station receives the negative acknowledgment, In the wireless multicast communication for retransmitting the requested frame, (1) the receiving stations that can directly transmit and receive each other are grouped in advance, and (2) the transmitting station is an arbitrary receiving station from among the groups. (3) after the transmitting station multicasts the frame to the receiving station, (4) the transmitting station polls one of the groups and requests a response, 5) The polled representative station of the group returns an acknowledgment or a negative acknowledgment depending on whether the broadcast data has been correctly received, and (6) the polled group. The receiving station other than the representative station monitors the response returned by the representative station.If the response is an acknowledgment or the response cannot be monitored and the broadcast data cannot be received correctly, the receiving station performs random access. (7) the transmitting station suspends polling when the negative response is returned, immediately retransmits the frame requested by the negative response by multicast,
A polling is performed again to the receiving station which returned the negative response from the group in which the polling was interrupted. (8) When a negative response is returned again from the receiving station, the procedure (7) is repeated each time. On the other hand, if an acknowledgment is returned from the receiving station and no negative acknowledgment is returned from another receiving station within a predetermined time, polling is performed for the next group. The procedure (4) to (8) is repeated, and the transfer of the frame is completed when an acknowledgment is received from the representative station of the last group.

According to a second aspect of the present invention, in the first aspect of the present invention, when the transmitting station immediately retransmits the requested frame by multicast in the step (7), the transmitting station: If consecutive negative acknowledgments are received from the same receiving station, the receiving station returning the negative acknowledgment is newly selected as a representative station of the group to which the receiving station belongs.

According to a third aspect of the present invention, there is provided a transmitting station and a receiving station group for performing broadcast data transfer by wireless multicast communication, and the transmitting station assigns an address of a destination receiving station group or the like to the broadcast data. A data frame is transmitted to the receiving station in a single frame transmission, and the receiving station returns an acknowledgment if the broadcast data is correctly received, and a negative acknowledgment if the frame has an error. And return
When the transmitting station receives a negative acknowledgment, in a wireless communication system that retransmits a frame requested by the negative acknowledgment, those that can directly transmit and receive each other are grouped in advance, A station for selecting an arbitrary receiving station from the groups as a representative station in advance, and requesting a response by polling one of the groups after transmitting the frame to the receiving station by multicast. Means for interrupting polling each time a negative acknowledgment from the receiving station is detected, immediately retransmitting the frame requested by the negative acknowledgment by multicast, and returning a negative acknowledgment among the groups for which polling was interrupted. Retransmission control means for performing polling again to the receiving station, and an acknowledgment is returned from the receiving station, and within a predetermined time after the acknowledgment is returned. Detects that no negative response is returned from another receiving station, changes the polling target to the next group, and completes the transfer of the frame when an acknowledgment is received from the representative station of the last group. Means, the receiving station determines at the time of polling whether or not the own station is a representative station, when the determination means is determined to be a representative station, the broadcast data, Means for returning an acknowledgment or a negative response to the transmitting station according to whether or not the signal has been correctly received; and when the determining means determines that the received signal is other than the representative station, the response returned by the representative station is monitored. Means for acquiring a transmission right by random access and returning a negative response to the transmitting station when the transmission data cannot be correctly received or the response cannot be monitored and the broadcast data cannot be received correctly. It is a symptom.

According to a fourth aspect of the present invention, in the third aspect of the invention, when the retransmission control means immediately retransmits the requested frame by multicast, the same receiving station continuously denies the request. It is characterized by detecting that a response has been received, and causing the selecting means to newly select the receiving station which has returned the negative response as a representative station of a group to which the receiving station belongs.

[0022]

Embodiments of the present invention will be described below with reference to the drawings. [First Embodiment] FIG. 3 is a diagram showing a procedure of a wireless multicast data transfer method according to the present embodiment. As in the conventional example, data is transmitted from the transmitting station 101 to the receiving stations 201 to 205 by multicast. The state is shown over time. Note that in FIG. 3, the same components as those in FIGS. 1 and 2 are denoted by the same reference numerals. FIG. 4 is a flowchart showing the operation of the transmitting station 101, and FIG.
Is a flowchart showing the operation of each receiving station.

In the present embodiment, as shown in FIG. 3 or FIG. 6, receiving stations that can directly transmit and receive each other are grouped. That is, the receiving station 201 and the receiving station 20
2 belongs to the group 211, and the receiving station 203 and the receiving station 20
4 belong to the group 212. Further, it is assumed that the receiving station 205 exists alone, and the receiving station 205 forms one group 213 by one station.

Here, the transmitting station 101 randomly selects a representative station from each group prior to multicast data transmission. In the present embodiment, as shown in FIG. 6, the receiving station 201 is the representative station in the group 211, and the group 21
In 2, it is assumed that the receiving station 203 is a representative station. Also,
Since the group 213 includes only one station, the receiving station 2
05 is the representative station. Incidentally, reference numeral 22 shown in FIG.
Reference numerals 1 and 222 denote multicast non-receiving terminals existing in the area 111 covered by the transmitting station.

Referring to FIG. 3, the transmitting station 101 transmits the multicast data frame 301 (step Sa1 in FIG. 4), and the receiving station receives the multicast data frame 301 (step S1 in FIG. 5).
b1). After finishing transmitting the multicast data frame 301, the transmitting station 101 polls the representative station of each group (step Sa2). That is, the transmitting station 101 first receives the receiving station 2 which is the representative station of the group 211.
01 is polled (see polling 341 in FIG. 3). Since the receiving station 201 is the representative station (the determination result in step Sb2 is “yes”), the polled receiving station 201 (step Sb3) responds to the fact that the multicast data frame 301 has been received without error.
ACK 311 is returned to transmitting station 101 (step Sb4,
The determination result of step Sb5 is “ACK”). As a result, the transmitting station 101 receives the ACK 311 (the determination result in step Sa3 is “ACK”).

On the other hand, the receiving stations other than the representative station in the polled group can monitor the result returned by the representative station so that the response returned by the representative station is ACK or the response of the representative station can be monitored. If not, and the multicast data frame 301 cannot be correctly received, a transmission right is acquired by random access, and a NAK is returned to the transmitting station within a predetermined time T1.

Therefore, the receiving station 202 which is a member of the group 211 (the determination result in step Sb2 is "no")
Monitors a polling signal and a response to the error (step Sb7) upon detecting an error in the received (step Sb1) multicast data frame 301 (determination result of step Sb6 is "yes"). If the response returned by the receiving station 201 does not notify the transmitting station 101 of the situation of the receiving station 201, that is, an error of the multicast data frame 301 (step S
The determination result of b8 is “no”, and NAK321 is returned following ACK311 (step Sb9).

When transmitting station 101 receives NAK 321 (determination result of step Sa4 is "yes"), it interrupts polling and immediately retransmits the requested frame in retransmitted frame 331 (step Sa5). Since this retransmission is performed by multicast, all the receiving stations within the area 111 (see FIG. 6) covered by the transmitting station 101 can receive the retransmission frame 331, but the first transmission frame (that is, the multicast data frame 301)
Receiving stations 201.203 to 20 that have already correctly received
5 discards the retransmission frame 331.

After terminating the transmission of the retransmission frame 331, the transmitting station 101 again polls the receiving station 202 of the group 211 that has returned the NAK (see polling 342 in FIG. 3, step Sa2). Receiving station 202
Is A when the retransmission frame 331 is correctly received.
CK is returned, and if reception fails, NA
Returns K. In this case, the receiving station 202 sets the retransmission frame 3
The receiving station 202 returns an ACK 312 to the transmitting station 101 because it is assumed that the receiving station 31 has been successfully received.

Here, the transmitting station 101 receives the ACK from the group 211 (if the determination result in step Sa3 is “AC
If the NAK is not received within a predetermined time T1 after the “K”) (the determination result in step Sa4 is “no”), polling is performed on the representative station of the next group (step S4).
The determination result of a6 is “no”). Therefore, the transmitting station 101 polls the receiving station 203, which is a representative station of the group 212 (see polling 343 in FIG. 3), and an ACK 313 corresponding thereto is returned from the receiving station 203 to the transmitting station 101.

According to the above procedure, the transmitting station 101 polls the last group, ie, the group 213 (polling 344 in FIG. 3, step Sa2), and receives the ACK 314 from the last group (the decision result in step Sa3 is "ACK"). ", And the determination result of step Sa4 is" n
o "), the multicast data frame 30
It is considered that transmission of No. 1 has been completed (the determination result of step Sa6 is “yes”).

At this point, if there is subsequent multicast data, transmitting station 101 can transmit the next multicast data frame 302. Therefore, after transmitting the multicast data frame 302 (step Sa1), the transmitting station 101 performs retransmission as necessary according to the same procedure as described above. In this case, it is assumed that an error has occurred between the receiving station 203 and the receiving station 205.

The transmitting station 101 polls the receiving station 201 (step Sa2), receives an ACK 315 for the polling (step Sa3), and transmits a polling 346 to the receiving station 203 (step Sa2).
2). Then, transmitting station 101 receives N
AK322 (Steps Sb2 to Sb4, Step Sb5
Is determined to be "NAK", and retransmission is requested (determination result of step Sa3 is "NAK"), so the retransmission frame 332 is transmitted by multicast (step Sa).
5). Since this retransmission frame 332 can be received by all the receiving stations in the area 111, in addition to the receiving station 203 that has requested retransmission, the receiving station 20 that has failed to correctly receive the multicast data frame 302 in the previous transmission
5 receives the retransmission frame 332. In addition, the other receiving stations 201 and 202 and the receiving station 204 that have correctly received the multicast data frame 302 (step Sb1).
ＳSb2, the determination result of step Sb6 is “no”)
After receiving the retransmission frame 332, it is discarded.

Next, the transmitting station 101 transmits a polling 347 to the receiving station 203 which has returned the NAK among the groups 212 in which the polling was interrupted (step Sa).
2) and receive a response to this (step Sa)
3). In this case, the receiving station 203 returns ACK 316 to the transmitting station 101 because the receiving station 203 has correctly received the retransmission frame 332. If NAK does not arrive within a predetermined time T1 after receiving ACK 316 (step Sa4, step Sa6), transmitting station 101 performs polling 348 on receiving station 205, which is the representative station of the next group 213 (step Sa2). ). As described above, the receiving station 205 has failed to receive the multicast data frame 302 transmitted for the first time, but has successfully received the subsequent retransmission frame 332, and thus transmits the ACK 317 to the transmitting station 101 here. return. Thus, when transmitting station 101 receives ACK from the last group and does not receive NAK within a fixed time T1, it considers that transmission of multicast data frame 302 has ended. If there is no subsequent data, the transmission is completed.

[Second Embodiment] FIG. 7 is a diagram showing a procedure of a wireless multicast data transfer method according to the present embodiment. Similar to the first embodiment, the transmitting station 101 multicasts data to the receiving stations 201 to 205. Shows how data transfer is performed with time. In FIG. 7, FIG.
3 are denoted by the same reference numerals. Also, in the present embodiment, the receiving stations are grouped as shown in FIG. 6 as in the first embodiment. The same applies to the case where the transmitting station 101 selects representative stations one by one prior to multicast data transmission, and the representative stations in each group are the same as in the first embodiment.

Referring to FIG. 7, the transmitting station 101 transmits a multicast data frame 301, and polls the representative station of each group when the transmission of the frame is completed. That is, the transmitting station 101 first polls the receiving station 201, which is the representative station of the group 211, for polling 3.
Perform 41. The polled receiving station 201 returns an ACK 311 to the transmitting station 101 because the multicast data frame 301 has been correctly received. On the other hand, the receiving station 202 in the group 211 monitors the response of the receiving station 201, which is a representative station of the same group, and detects an error when receiving the multicast data frame 301. After that, NAK 321 is returned to transmitting station 101 to request retransmission.

After receiving the NAK 321, the transmitting station 101 immediately retransmits the requested data by multicast (see retransmission frame 331). This retransmission frame 331 can be received by all the multicast receiving stations existing in the area 111 of FIG. However, the receiving stations 201, 204, and 205 that have successfully received the previous multicast data frame 301 discard the retransmission frame 331 when they are received.

Next, the transmitting station 101 sends the retransmission frame 331
, The polling 342 is performed on the receiving station 202 that has returned the NAK among the groups 211 whose polling has been interrupted earlier. Here, it is assumed that the receiving station 202 has also detected an error when receiving the retransmission frame 331. Therefore, polled receiving station 2
02 returns NAK 322 to the transmitting station 101 again. Thus, when transmitting station 101 continuously receives NAKs from the same station, it changes the receiving station that returned the NAK to a new representative station of that group (that is, receiving station group 211). The state of the receiving station group in the area 111 at this time is shown in FIG. 8, and is the same as FIG. 6 except that the representative station has been changed in the group 211. And the transmitting station 10
1 transmits a frame requested to be retransmitted by NAK as a retransmission frame 332,
The polling 343 is performed for the receiving station 202 which is one new representative station. On the other hand, the receiving station 202 returns its own reception result as a response.
2 has been successfully received, and ACK 312 is returned to the transmitting station 101.

Thereafter, the transmitting station 101 polls all the remaining groups. That is, the transmitting station 101
Performs polling 344 to the receiving station 203 and
After receiving CK313, polling 345 is performed by receiving station 2
If the process is performed at 05, the ACK 314 is returned from the receiving station 205 of the group 213 which is the final group. Then, if NAK is not returned within a predetermined time T1, the transmitting station 101 determines that transmission of the multicast data frame 301 has been completed.

If there is more data at this point,
Since the transmitting station 101 can transmit subsequent data, the transmitting station 101
2 transmission is started. Therefore, after transmitting the multicast data frame 302, the transmitting station 101 starts polling in the same manner as in the case of the multicast data frame 301. In this case, since the representative station has been changed in the group 211 at the time of the previous data transmission, polling 346 is performed on the receiving station 202 which is a new representative station. Here, since receiving station 202 has detected an error when receiving multicast data frame 302, receiving station 202 returns NAK 323 to transmitting station 101 as a response.

As a result, the transmitting station 101 transmits the NAK323
The retransmission frame 333 is transmitted immediately after receiving the retransmission frame. At this time, the representative station of the group 211 is changed at the time of transmitting the multicast data frame 301, and the receiving station in which a transmission error is likely to occur is selected as the representative station, so that the time from polling to the start of retransmission is reduced. . Next, the transmitting station 101 performs polling 347 again with respect to the receiving station 202 which is the representative station of the group 211, and sends ACK 315 as a response to
I get from two. Since the transmitting station 101 does not receive the NAK within a predetermined time T1 after receiving the ACK 315, the transmitting station 101 performs polling 348 to the receiving station 203, which is the representative station of the next group 212, and returns AC
Receive K316.

As described above, the transmitting station 101 performs polling for all the groups, and after receiving the ACK from the group 213 which is the last receiving station group, if the NAK is not returned within the predetermined time T1, It is assumed that the transmission of the multicast data frame 302 has been completed. When there is no subsequent data, the transmission of the multicast data is completed.

[0043]

As described above, according to the present invention,
When the transmitting station performs the multicast data transfer, the receiving stations that can transmit and receive each other are grouped into receiving station groups. Then, after the transmitting station selects a representative station from each group one by one and transmits a series of frames by multicast, it polls each group. At this time, the acknowledgment is returned only by the representative station, and the other receiving stations in the group monitor the response returned by the representative station and determine that it is necessary to request retransmission from the reception result of the own station. Returns a negative response only to When a negative response is returned, the transmitting station restarts polling after retransmitting only the requested frame by multicasting, and when only an acknowledgment is returned, polls the next group, and returns from the last group. When the acknowledgment is returned, the multicast data transfer is completed.

As a result, while providing high reliability, it is possible to reduce the time required for confirming the delivery and to achieve efficient multicast data transfer. Also, if a frame requested to be retransmitted by a certain receiving station is a frame that another receiving station was also requesting for retransmission, all frames that attempted to request retransmission of the frame at the first Since the receiving station can receive this, efficient retransmission can be performed.

According to the second or fourth aspect of the present invention, when a transmitting station performs multicast data transfer, a receiving station that is likely to cause a transmission error is selected as a representative station from each group. Thereby, in addition to the effects described above, it is possible to poll the station where transmission errors are most likely to occur as a representative station at the time of delivery confirmation, and the time from when an error is detected to when retransmission is started is reduced. effective. At this time, the number of frames returned as a response can be reduced by dynamically changing the representative station according to the situation while following the temporal variation of the received signal level due to fading for each receiving station. In addition, there is an effect that the time required for retransmission can be shortened and highly efficient multicast data transfer can be realized.

[Brief description of the drawings]

FIG. 1 is an explanatory diagram showing a procedure of a wireless multicast data transfer method according to a first conventional example.

FIG. 2 is an explanatory diagram showing a procedure of a wireless multicast data transfer method according to a second conventional example.

FIG. 3 is an explanatory diagram showing a procedure of a multicast data transfer method according to the first embodiment of the present invention.

FIG. 4 is a flowchart showing an operation of the multicast data transmitting station in the embodiment.

FIG. 5 is a flowchart showing an operation of the multicast data receiving station in the embodiment.

FIG. 6 is an explanatory diagram showing an example of grouping of receiving stations in the embodiment.

FIG. 7 is an explanatory diagram showing a procedure of a multicast data transfer method according to a second embodiment of the present invention.

FIG. 8 is an explanatory diagram showing an example of grouping of receiving stations after the representative station of the group 211 is changed from the state shown in FIG. 6 in the embodiment.

[Explanation of symbols]

 101 transmitting station 111 area covered by transmitting station 201-205 receiving station 211-213 group 221,222 multicast non-receiving terminal 301,302 multicast data frame 311-319 ACK 321-323 NAK 331-333 retransmission frame 341-348 polling T1 Fixed time (when waiting for NAK response)

 ──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Masahiro Morikura Nippon Telegraph and Telephone Corporation, 3-9-1-2 Nishishinjuku, Shinjuku-ku, Tokyo

Claims (4)

[Claims] 1. A transmitting station creates a frame in which the address of a group of destination receiving stations and the like are added to broadcast data, and performs data transfer to the receiving station in one frame transmission.
If the broadcast data is correctly received, an acknowledgment is returned.If the frame has an error, a negative acknowledgment is returned.When the transmitting station receives the negative acknowledgment, the frame requested by the negative acknowledgment is returned. In the wireless multicast communication for retransmission, (1) the receiving stations capable of directly transmitting and receiving each other are grouped in advance, and (2) the transmitting station selects an arbitrary receiving station from each group as a representative station. ,
(3) after the transmitting station multicasts the frame to the receiving station, (4) the transmitting station polls one of the groups and requests a response, (5)
The polled representative station of the group returns an acknowledgment or a negative response depending on whether or not the broadcast data has been correctly received. (6) The receiving stations other than the polled representative station of the group include: The response returned by the representative station is monitored, and when the response is an acknowledgment or the response cannot be monitored, and the broadcast data cannot be received correctly, a transmission right is acquired by random access and a negative response is returned. (7) the transmitting station suspends polling when a negative response is returned, immediately retransmits the frame requested by the negative response by multicast, and then transmits a negative response among the groups whose polling was suspended. The polling is again performed to the returning receiving station. (8) When a negative response is returned again from the receiving station, the procedure (7) is repeated each time while the negative response is returned. If an acknowledgment is returned from the station and no negative acknowledgment is returned from another receiving station within a certain time, poll the next group, and (9) the procedure (4) until the transmitting station polls all groups. (8) A wireless multicast data transfer method, wherein the transfer of the frame is completed when an acknowledgment is received from the representative station of the last group. 2. When the transmitting station immediately retransmits the requested frame by multicast in the step (7), if the transmitting station continuously receives a negative response from the same receiving station, 2. The wireless multicast data transfer method according to claim 1, wherein the receiving station returning the negative response is newly selected as a representative station of a group to which the receiving station belongs. 3. A transmitting station and a receiving station group for performing broadcast data transfer by wireless multicast communication, wherein the transmitting station creates a frame in which broadcast data is given an address of a destination receiving station group and the like, and Data transmission is performed to the receiving station by frame transmission, and the receiving station returns an acknowledgment if the broadcast data is correctly received, and returns a negative acknowledgment if the frame has an error. In a wireless communication system that retransmits a frame requested in the negative response when receiving a negative response, the receiving stations are grouped in advance so that they can directly transmit and receive each other, and the transmitting station includes: Selecting means for selecting an arbitrary receiving station as a representative station from each group in advance; and, after transmitting the frame to the receiving station by multicast, polling one of the groups. Means for requesting a response, and each time a negative response from the receiving station is detected, suspending polling, immediately retransmitting the frame requested by the negative response by multicast, and then suspending the polling. Retransmission control means for re-polling the receiving station that has returned the negative response, an acknowledgment is returned from the receiving station, and a negative response is returned from another receiving station within a predetermined time after the acknowledgment is returned. Means for detecting that there is no frame, changing the polling target to the next group, and completing the transfer of the frame when receiving an acknowledgment from the representative station of the last group. A determination means for determining whether or not the own station is a representative station at the time of polling, and when the determination means determines that the broadcast station is a representative station, the broadcast data correctly Means for returning an acknowledgment or a negative response to the transmitting station according to whether or not reception is possible; and when the determining means determines that the received signal is other than the representative station, the response returned by the representative station is monitored. Means for acquiring a transmission right by random access and returning a negative response to the transmitting station when an acknowledgment or the response cannot be monitored and the broadcast data cannot be received correctly. Wireless communication system. 4. The retransmission control means, when immediately retransmitting the requested frame by multicast, detects that consecutive negative acknowledgments have been received from the same receiving station,
4. The wireless communication system according to claim 3, wherein the selecting unit newly selects the receiving station that has returned the negative response as a representative station of a group to which the receiving station belongs.