JP3378429B2 - Broadcast communication control device - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a communication control device for performing broadcast communication between communication devices connected to a network.

[0002]

2. Description of the Related Art Data, unlike voice and image information, requires error-free communication. Therefore, in the one-to-one data communication, in order to guarantee reliability, communication is performed by the following means.

If the receiving side receives the data correctly,
Response information indicating correct reception is returned, and the transmitting side transmits data according to the response from the receiving side. If the response information does not arrive after a certain period of time, the transmitting side retransmits the data. If the receiving side detects an error or loss of data, the receiving side sends response information for a resend request to the sending side, and if the sending side receives the resend request response information, resends the resend requested data. .

The conventional data broadcasting communication basically employs the same method. That is, the sender sends the data,
If it is correctly received at the receiving side, each of the plurality of receiving sides sends response information (acknowledgement number) indicating that it has been correctly received to the transmitting side. If the receiving side does not receive correctly, the receiving side sends response information requesting retransmission to the transmitting side, and if the transmitting side receives the response information for the retransmission request, the transmitting side retransmits the same data. To do.

This means a one-to-n one-way connection in which one device transmits data and the other devices receive it. If each communication device wants to perform bidirectional communication with each other, it is necessary to create this connection for each device.

[0006]

However, in this method, since the response information is generated for each transmission device and the confirmation response packet is transmitted to the transmission device, the response information stored in the confirmation response packet. Inevitably there will be only one. Therefore, there is a problem that the number of acknowledgment packets flowing through the network increases as the number of communication devices increases, which may increase the load on the network.

On the other hand, some devices receive data correctly,
If another device fails to receive the same data correctly,
The transmitting side sends the data again, but in the conventional method, it is necessary to send back the response information for the retransmitted data without distinguishing between the device that correctly received it and the device that did not receive it. That is, the transmitting side receives the acknowledgment packet for the same data twice from the device that correctly received the first data and the retransmitted data. Therefore, unnecessary confirmation response packets are sent to the network, which also causes the congestion of the network, which is a problem.

[0008]

Therefore, in one confirmation response packet transmitted by a certain device, response information for all the devices other than the own device is stored and transmitted in a broadcast manner. As shown in FIG. 5, in the confirmation response packet, the latest sequence number among the sequence numbers of the data packets continuously received from each device is stored for each device. The acknowledgment packet is not generated immediately each time a data packet is received, but is generated after a fixed time or random time has elapsed.

Since one generated confirmation response packet is transmitted in a broadcast manner, each of the plurality of devices that have received the confirmation response packet can confirm how much the data transmitted by itself has been received. Yes, you can retransmit data that you have sent but have not yet received.

Further, the transmitting device adds information indicating whether or not the acknowledgment packet from each device for the data packet is received to the data packet and transmits it. The device receiving the data packet determines from the information whether or not it is necessary to send an acknowledgment packet for the data, and if necessary, sends an acknowledgment packet.

The device that received the data packet examines which packet it came from, the sequence number, compares it with the sequence number it has received consecutively from that device and compares it with a new and continuous sequence number. If so, it is determined that the data is correctly received, and the latest sequence number is updated.

If a time period in which the acknowledgment packet is not transmitted after the data packet is received, the acknowledgment packet is transmitted. Alternatively, if the acknowledgment packet is not transmitted for a while, the acknowledgment packet is transmitted.

When transmitting the acknowledgment packet, as shown in FIG. 5, the latest sequence number of the data packets continuously received from each device is stored in the acknowledgment packet together with the identifier of the device. The acknowledgment packet is transmitted in a broadcast manner.

When data packets are received from a plurality of devices at the same time, reception confirmation for those data packets can be realized by a single acknowledgment packet, so that traffic can be reduced.

The device that has received the acknowledgment packet knows to what extent each device correctly received the data packet transmitted by itself, from the contents of the acknowledgment packet. According to the above method, one acknowledgment packet has a plurality of acknowledgment information, and it is not necessary to transmit the acknowledgment packet for all data packets. Therefore, the amount of acknowledgment packets is reduced and the utilization efficiency of the network is improved. . In particular, in a situation in which each communication device transmits data evenly, the confirmation response to each communication device can be completed with one confirmation response packet, which works effectively.

Furthermore, if the acknowledgment packet is not generated each time a data packet is received, but is generated and transmitted after a random time has elapsed, it is difficult to synchronize the transmission timing of the acknowledgment packet transmitted from each device. Therefore, packet transmission requests are randomly generated. Therefore,
It is also effective when the communication devices share a transmission medium adopting a media access control method such as Ethernet. Further, since the confirmation response packet is not transmitted for the retransmission packet in which the reception of the data is confirmed, the load on the network can be reduced.

[0017]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a diagram showing a configuration example of a broadcast communication control device in a first embodiment according to the present invention. Second
As shown in the figure, the broadcast communication control device of the present invention is connected to a broadcast communication path capable of broadcast communication.

As shown in FIG. 3, the header portion of the packet includes the destination group identifier, the transmitter identifier, the sequence number, the packet type, and the packet length. Here, the packet type is an area in which the transmitting side stores a value so that the receiving side can identify whether the data packet or the acknowledgment packet is another packet. The sequence number field of the acknowledgment packet contains 0 and has no meaning.

As shown in FIG. 4, each of the communication devices is
The identifier of the group that is broadcasting, the identifier of the device that is a member of the group, the maximum sequence number of the data packets that are continuously received from each device, and the sequence number that has returned the acknowledgment packet are stored in the receiving group table. Hold. FIG. 4 shows an example of the reception group table of the device A.

As shown in FIG. 5, in the acknowledgment packet, in addition to the header part, the group identifier, the number of devices other than the own device of the group, the identifier of each device, and the data packets continuously received from the device. It has an area to store the maximum sequence number of each pair. In FIG. 5, the confirmation response packet transmitted from the device A to the other devices in the group 2 is taken as an example.

As shown in FIG. 6, each of the communication devices is
The transmission group table holds the identifier of the group performing the broadcast communication, the maximum sequence number transmitted by each device to each group, the identifier of the device that is a member of the group, and the maximum confirmation response number received. In FIG. 6, device A
3 shows an example of a transmission group table owned by.

<Transmission of Data Packet> When a data transmission request is received from the upper layer, the data packet generation means packetizes the data, stores it in a buffer, and assigns a sequence number. Here, the sequence number is the sequence number of the first data packet to be transmitted to the group, which is 1
As a result, each time one data packet is transmitted, the number increased by 1 is added. A retransmission timer is set for each data packet, and the broadcast communication unit broadcasts the data packet.

<Reception of data packet> When a packet arrives, the broadcast communication means receives the packet, and if it is a data packet, it is stored in the reception sequence number storage means for each sender.
If the packet is a confirmation response packet, the packet is sent to the confirmation response number storage means for each recipient. Reception of the confirmation response packet will be described later.

The receiving sequence number storage means for each sender is
The destination group identifier, the identifier of the transmitted communication device, and the sequence number are extracted, and the sequence number is compared with the maximum sequence number of the data packet received from that device, which is stored in the receiving group table. If the sequence number extracted from the packet is large and consecutive with the maximum sequence number in the reception group table, the maximum sequence number in the reception group table is updated to that sequence number. Further, the data part of the packet is sent to the buffer management means, and if the acknowledgment packet transmission timer is not set, it is set. The value set in the confirmation response packet transmission timer may be always constant, or may be a random number having a certain probability distribution. By using a random number, the number of acknowledgment packets sent to the broadcast transmission path at the same time is reduced,
Congestion can be avoided. As the probability distribution, a uniform distribution from the minimum value t1 to the maximum value t2, a uniform distribution in which the minimum value and the maximum value change in proportion to the number of members of the group,
Alternatively, use one of the exponential distributions in which the average value changes in proportion to the number of members of the group.

Further, the timing for setting the value in the acknowledgment packet transmission timer is set again when a data packet is received as described above and when it times out regardless of whether a data packet is received. There are two ways to do it again. In both cases,
If the timer has already been set, it will not be set again. When the acknowledgment packet transmission timer times out, the acknowledgment packet generation means is notified. When a certain number or more of data packets arrive at the group, the sender-specific reception sequence number storage means notifies the confirmation response packet generation means.

<Sending Confirmation Response Packet> When a notification is sent from the receiving sequence number storing means for each sender, or when a notification is sent from the sending timer for the confirmation response packet, the checking packet generating means stores the receiving sequence number for each sender. The means is requested to send the identifier of each device belonging to the group and the maximum sequence number (acknowledgement number) received continuously from each device. Further, the acknowledgment packet transmission timer is reset.

The receiving sequence number storage means for each sender is
The information of the group corresponding to the element is sent to the acknowledgment packet generating means. The confirmation response packet generation means,
An acknowledgment packet as shown in FIG. 5 is generated on the basis of the information received from the sender-specific reception sequence number storage means, and is broadcast to the group through the broadcast communication means.

<Reception of Acknowledgment Packet> When a packet arrives, the broadcast communication means receives the packet, and if it is a data packet, it is sent to the receiving sequence number storage means by sender, and if it is an acknowledgment packet, an acknowledgment response by recipient is sent. Send the packet to the number storage means.

The receiver-specific acknowledgment number storage means extracts the maximum sequence number (acknowledgement number) received continuously from the destination group identifier, the identifier of the communication device that transmitted the data packet, and the data packet transmitted by the device itself. The confirmation response number is stored in the transmission group table. The data packet generation means is notified to delete the data packet which is no longer required to be retransmitted.

<Retransmission of Data Packet> When a notification of data packet retransmission is received from the retransmission timer, the data packet reproducing means sends the sequence number and destination group of the data packet to the receiver-specific acknowledgment number storing means, and the data is retransmitted. Requests information about whether or not the packet has been acknowledged.

The acknowledgment number storage means for each receiver compares the sequence number of the data packet with the acknowledgment number obtained from the member of the group, and if even one acknowledgment number is smaller, the reception confirmation is confirmed. Send what has not been done to the data packet generation means.

When the reception confirmation is not made, the data packet generating means sends the corresponding data packet to the broadcast communication means, and the broadcast communication means broadcasts it.
FIG. 7 shows an example of the configuration of the broadcast communication control device in the second embodiment in which the confirmation response packet reception confirmation information adding means recited in claim 3 is added to the first embodiment.

What is different from the first embodiment is the format of the data packet, the processing when the data packet is received, and the processing when the data packet is transmitted. The data format is shown in FIG. A flag indicating whether or not each device needs to send an acknowledgment packet is stored in the header part. In the example of FIG. 8, the packet with the sequence number 700 transmitted by the device A indicates that the confirmation response packet has not been received from the device F yet.

<Transmission of Data Packet> When a data transmission request is received from the upper layer, the data packet generation means packetizes the data, stores it in the buffer, and assigns a sequence number. The sequence number is assigned in the same way as in the first embodiment. From the confirmation response packet reception confirmation information adding means, the identifier of the device which has not received the confirmation response packet for the data packet is received, and the flag of the device is set to "necessary". A retransmission timer is set for each data packet, and the broadcast communication unit broadcasts the data packet.

<Reception of Data Packet> When a packet arrives, the broadcast communication means receives the packet, and if it is a data packet, it is stored in the reception sequence number storage means for each sender.
If the packet is a confirmation response packet, the packet is sent to the confirmation response number storage means for each recipient. Reception of the confirmation response packet will be described later.

The reception sequence number storage means for each sender is
The destination group identifier, the identifier of the transmitted communication device, the sequence number, and the flag indicating the necessity / unnecessity of the confirmation response packet from the self device are extracted and stored in the sequence number and the reception group table. Compare with the maximum sequence number of the data packet received from the device.
If the sequence number extracted from the packet is large and consecutive with the maximum sequence number in the reception group table, the maximum sequence number in the reception group table is updated to that sequence number. Further, the data part of the packet is sent to the buffer management means, and if the flag extracted from the packet is "necessary" and the acknowledgment packet transmission timer is not set, the timer is set. When the timer times out, the acknowledgment packet generation means is notified.

[0037]

EFFECTS OF THE INVENTION It is not necessary to transmit an acknowledgment packet for all data packets, the amount of acknowledgment packets is reduced, and network utilization efficiency is improved. In addition, the concentration of the confirmation response packets can be avoided in the communication device that has transmitted the data packet, so the load on the transmission device can be reduced. This is especially effective when the respective communication devices transmit data evenly.

[Brief description of drawings]

FIG. 1 is a diagram showing a configuration example of a broadcast communication control device according to a first embodiment.

FIG. 2 is a diagram showing a state in which a broadcast communication control device is connected to a broadcast communication path.

FIG. 3 is a format common to a data packet and an acknowledgment packet in the first embodiment. As an example, a data packet that device A sends to members of group 2 is shown.

FIG. 4 is a reception group table that stores the maximum sequence numbers of data packets that are continuously received from each device. As an example, a table of the device A is shown.

FIG. 5 is a format of an acknowledgment packet. As an example, a packet that device A sends to members of group 2 is shown.

FIG. 6 is a transmission group table that stores the maximum acknowledgment number received from each device. As an example, a table of the device A is shown.

FIG. 7 is a diagram showing a configuration example of a broadcast communication control device according to a second embodiment.

FIG. 8 is a data packet format according to the second embodiment. As an example, a data packet that device A sends to members of group 2 is shown.

[Explanation of symbols]

7 ... Data packet generating means 10 ... Receiving sequence number storage means for each sender 8 ... Acknowledgment packet generating means

─────────────────────────────────────────────────── ─── Continuation of the front page (56) References JP-A-6-224919 (JP, A) JP-A-7-111503 (JP, A) JP-A-63-33941 (JP, A) JP-A-1- 225255 (JP, A) JP 60-246143 (JP, A) JP 63-197259 (JP, A) JP 5-91159 (JP, A) 1996 IEICE, B-823 (58) ) Fields surveyed (Int.Cl. ⁷ , DB name) H04L 12/40 H04L 1/00

Claims (3)

(57) [Claims] 1. A broadcast communication control device comprising a broadcast communication means for forming a group with a plurality of other broadcast communication control devices and transmitting and receiving packets to and from each other in the group, Data packet generation means for packetizing data to be transmitted, assigning sequence numbers to the packets in ascending order, and further storing header information including the sequence numbers in the packets, and a broadcast communication control device serving as a sender For each sender, the receiving sequence number storage means for storing the maximum sequence number of the data packets received from the other broadcast communication control devices in the group for each storing the maximum sequence number of all broadcast control apparatus as a sender of said group stored in the received sequence number storage means, Senders in the group
And a confirmation response packet generating means for generating a confirmation response packet to be broadcast to all the broadcast communication control apparatuses. 2. The confirmation response packet generation means according to claim 1, wherein the confirmation response packet is generated at regular time intervals or after a predetermined number of data packets arrive after the first data packet arrives. The broadcast communication control device according to claim 1. 3. A broadcast communication control device comprising a broadcast communication means for forming a group with a plurality of other broadcast communication control devices and transmitting and receiving packets to and from each other in the group, Data to be transmitted to the packet is packetized, a sequence number is given to the packet in ascending order, and further, information of a header including the sequence number is stored in the packet, and data packet generating means for storing the data packet as a receiver. Acknowledgment packet reception confirmation information giving means for giving information indicating whether or not an acknowledgment response packet has been received from the information communication control device, and a data packet provided with information indicating that no acknowledgment response packet has been received only when it is,該Gu
Broadcast to all broadcast controllers that are senders in the loop.
A broadcast response control device comprising: a response packet generation means for generating the response packet to be broadcast.