JPH02170645A - System and equipment for packet transmission - Google Patents

Abstract

PURPOSE:To improve a communication quality by setting a packet sending interval according to a data generating rate reported beforehand, temporarily accumulating the generated packet, and successively sending it to a transmission path according to the packet sending interval. CONSTITUTION:The packets generated in a packet generating source are once accumulated in a packet buffer before they are sent to a transmission path 102, and sent to the transmission path 102 according to the sending interval set beforehand. Consequently in a multiplexing device, a queue generated due to the simultaneous arrival of the packets at a certain time is reduced until the arrival of the next packets. Thus since the delay and rejection rate of the multiplexing device is reduced, the communication at high quality can be executed.

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to a packet transmission method in a packet switching network.

(Prior art) In packet switching, the terminal (here means the information source)
can send as many packets as you want into the network.

Now, if multiple packets are sent out continuously at the same speed as the transmission path speed, the packets will be input into the network in a continuous (continuous) form even on the transmission path.

At the entrance of the network, a plurality of transmission paths are multiplexed by a multiplexer. Since packet transmission from a terminal occurs asynchronously, packets from different transmission paths may arrive at the same time. If the input and output transmission path speeds of a multiplexing device are the same, simultaneous arrival of packets causes packet waiting in the device. It is desirable to minimize this waiting time as much as possible since it may deteriorate the communication quality as will be described later.

Here, this meeting will be explained. - As an example, the network is transmitted and exchanged using the ATM method described in the paper [Standardization trend of high-speed wideband 15DN centered on ATM] published by Kawarasaki and Kaida in the Institute of Electronics and Communication Engineers Technical Research Report Information Network 1NS7-110. shall be. A
TM is a method of transmitting and exchanging packets called cells, and is characterized in that short packets of fixed length are used, and that the network is divided into slots for each packet.

Therefore, since the minimum time between packet arrivals is one slot, the slot will be used as a unit of time below. It is assumed that in the multiplexing device, L input transmission lines are multiplexed into one output transmission line. At this time, waiting occurs, but if we consider the case where the waiting time for this is the maximum, as shown in Figure 2, it is the case where L packets arrive at one slot at the same time, and in this case, the length of the queue is The queue length increases by L-1 from the original queue length. Assuming that packets are input to the multiplexer in a continuous manner on each transmission path as described above, if two packets arrive simultaneously, the same thing will happen in the next slot, so
When consecutive packets form a queue one after another, and packets between T slots are consecutive, the queue increases by TX(L-1).

This increase in queue length has an adverse effect on communication quality in the following two ways.

(1) Increase in zero communication delay time.

(2) Increased packet discard rate.

Here, (1) is due to waiting time due to meeting,
(2) is caused by the fact that packets are discarded due to buffer overflow because the queuing buffer used for waiting is limited.

For example, transmission line L=32. When T=10, the maximum increase in communication delay time is as much as 310 slots, and communication quality deteriorates significantly.

(Problems to be Solved by the Invention) The purpose of the present invention is to solve the drawbacks of such conventional methods,
An object of the present invention is to provide a packet transmission control method and device for improving communication quality.

(Means for solving the problem) The present invention sets a packet sending interval according to a data generation rate declared in advance, temporarily stores the generated packets in a packet buffer, and sends the packets according to the packet sending interval. This is a packet transmission method characterized by sending packets sequentially from a packet buffer to a transmission path.

Further, the second invention includes a packet transmission interval setting circuit for setting a packet transmission interval, a packet buffer circuit for accumulating packets, a packet taken out from the packet buffer circuit, and a transmission path for the packet according to the transmission interval. This is a packet transmitting device characterized by comprising a packet transmitting control circuit that transmits packets.

Furthermore, a third invention provides a packet transmitting apparatus according to the second invention, which includes means for monitoring the number of packets accumulated in the packet buffer circuit in the apparatus, or means for obtaining information on the traffic state within the network from the network. and a circuit for generating a control signal for controlling the amount of packet generation to a packet generation source in the device according to the accumulated number or the intra-network traffic information.

Furthermore, a fourth aspect of the present invention is that the packet transmitting device according to the second aspect of the present invention includes means for monitoring the number of packets accumulated in the packet buffer circuit in the device, or means for obtaining information on the traffic state within the network from the network. and a circuit that generates a control signal requesting a transmission interval setting circuit in the device to reset the transmission interval according to the accumulated number or the intra-network traffic information. .

Furthermore, a fifth invention is a packet transmitting apparatus according to the second invention, which includes means for monitoring the number of packets accumulated in the packet buffer circuit in the apparatus, or means for obtaining information on the traffic state in the network from the network. and generates a control signal C1 for controlling the amount of packet generation to the packet generation source in the device according to the accumulated number or the intra-network traffic information, and causes the transmission interval setting circuit in the device to reset the transmission interval. This is a packet transmitting device characterized by having a circuit that generates a control signal C2 that requests setting.

(Operation) FIG. 1 shows the principle of the present invention. In the present invention, FIG.
As shown in a), the packets generated at the packet source are temporarily stored in the packet buffer before being sent out to the transmission path 102. Generally, as shown in FIG. 1(b), there may be a packet generation source that continuously generates a plurality of packets at the same speed as the transmission path speed, that is, without any intervals. In the present invention, even when packets are generated without any interval, they are stored in the packet buffer and then stored in the packet buffer shown in FIG.
), the data is transmitted to the transmission path 102 according to preset transmission intervals. Therefore, as shown in FIG. 3, in the multiplexing device, the queue in which packets simultaneously arrive at a certain time decreases until the next packet arrives.

In addition, in special situations such as when the traffic at the packet source temporarily increases, if packets are sent at intervals to the transmission path, the amount of packets accumulated in the packet buffer described above will gradually increase. There is a risk that the packet buffer will overflow.

At this time, by controlling the packet generation source to reduce the amount of packets generated, the input to the packet buffer is regulated, that is, the arrival of packets to the packet buffer is suppressed.

Alternatively, the speed at which packets are sent from the packet buffer is increased by resetting the packet sending interval to be shorter depending on the degree of packet accumulation in the packet buffer.

Alternatively, by restricting the input to the packet buffer described above for the terminal and setting the sending interval short, the arrival of packets to the packet buffer is suppressed and the speed at which packets are sent from the packet buffer is increased.

By these means, it is possible to prevent or reduce the occurrence of packet discards caused by overflow of the packet buffer.

In addition, information indicating the network traffic status obtained from the network,
For example, it is possible to change the transmission interval depending on the amount of traffic by considering the amount of packets stored in the exchange, or to reduce the probability of bucket puffer overflow.

(Example) Next, an example of the present invention will be described with reference to the drawings.

In the present invention, as shown in FIG.
The packets generated are stored in the packet buffer 404, which is a first-in-first-out (FIFO) buffer memory.

Furthermore, the packet generation source 401 sends the packet sending rate R to the packet sending interval setting circuit 402 in advance before sending out a series of packets. Here, R is expressed as a ratio to the physical speed of the transmission path, and takes a value between 1 and θ.

The packet transmission interval setting circuit 402 uses the reciprocal value (1/R) of the packet transmission rate R as the initial value setting value Tin1t of the packet transmission interval T. Further, the set value T is sent to the packet sending control circuit 403.

The packet sending control circuit 403 has a packet buffer 404
Send one packet to the transmission path 407, and then always (
T-1) Send the next packet after waiting a slot. For example, if R=1 then T=1 and packets are sent out at maximum rate, i.e. continuously, or if R=0.5 then t=2 and buckets are sent out at least every other slot. .

Although T=17R is shown here as an example of the calculation formula for setting the sending interval in the packet sending control circuit 403, T may be changed depending on the packet sending characteristics of the packet generation source.
, (17R)-1, or 0.7.times.(1/R). However, if T<1, T
=1.

FIG. 5 shows a second embodiment of the packet transmitting device according to the present invention. As shown in FIG. 5, the second embodiment has a configuration in which the following functions are added to the first embodiment.

The buffer control circuit 405 observes the packet buffer 404 and obtains the number B of accumulated packets in the packet buffer 404. The buffer control circuit 405 also controls the transmission line 407.
It is assumed that information indicating the network traffic status and the number of accumulated packets in the subscriber exchange can be obtained from the above information.

Generally, in a network, in order to perform congestion control, etc., each switching node requires a function to report information indicating the traffic status, such as the number of accumulated packets, to other nodes.

Here, it is assumed that such information or some intra-network traffic information that is aggregation of such information is sent from the network to the packet transmitting device using a signaling packet. This also includes transmission restriction signals from the network for flow control.

The buffer control circuit 405 sends a control signal 409 to the packet generation source 401 according to the number B of packets in the buffer and the intra-network traffic information. The control signal 4
09 is determined as shown in FIG. 8 using, for example, the maximum number of packets that can be stored in the packet buffer Bmax, the number of packets that can be stored in the subscriber exchange Q, and the maximum number of packets that can be stored in the subscriber exchange Qmax.

The packet generator 401 has a control signal 409 of 5TOP.
During a certain period, the amount of packets created is suppressed. for example,
During the period, the amount of packets created is limited to 90% of the amount of packets created up to that point.

FIG. 6 shows a third embodiment of a packet transmitting device according to the present invention. In the third embodiment, as shown in FIG. 6, the functions of the buffer control circuit 405 and the packet transmission interval setting circuit 402 of the second embodiment are configured as follows.

The buffer control circuit 405 sends a control signal 408 to the packet sending interval setting circuit 402 according to the number B of packets in the buffer and intra-network traffic information, for example, the number Q of packets in the exchange. The control signal 408 is determined using, for example, the Bmax and Qmax according to the table shown in FIG. 9.

The packet transmission interval setting circuit 402 sets the transmission interval T to be smaller than the previous value when the control signal 408 is UP, and resets it to a larger value when the control signal 408 is DOWN. Furthermore, when the status is HOLD, the previous value is maintained. For example, during the period when the control signal 408 is UP, the new transmission interval T' is set to T'=T-1, and the DO
The period of WN is assumed to be T'=T+1. However, in general, if a sending rate R is declared to the network, it is prohibited to send packets at a rate exceeding that rate, so T'
It is necessary to prevent the value from falling below the initial setting value Tin1t.

FIG. 7 shows a fourth embodiment of a packet transmitting device according to the present invention. In the fourth embodiment, as shown in FIG. 7, the functions of the buffer control circuit 405, packet generation source 401, and packet sending interval setting circuit 402 of the second embodiment are configured as follows.

The buffer control circuit 405 sends a control signal 4 to the packet generation source 401 and the packet transmission interval setting circuit 402, respectively, according to the number B of packets in the buffer and intra-network traffic information, for example, the number Q of packets in the exchange.
09 and control signal 408. The control signals 409 and 408 are determined using, for example, the Bmax and Qmax according to the tables shown in FIGS. 8 and 9, respectively. In addition, in FIG. 9, ORD is ordinary
And STP shows 5TOP.

The packet sending interval setting circuit 402 resets the sending interval T to be smaller than the previous value when the control signal 408 is UP, and resets it to be larger when the control signal 408 is DOWN. Furthermore, when the status is HOLD, the previous value is maintained.

Note that the value of the packet transmission rate R declared in advance by the packet generation source 401 is generally determined by the packet generation source itself depending on the balance between communication quality such as end-to-end delay required by the packet generation source and communication charges. It is considered to be a choice. Even when sending the same amount of information, the higher the transmission rate, the greater the load on the network.
This is because communication charges are likely to be set higher accordingly. However, the minimum value of R is the average packet transmission rate of the packet generation source.

(Effects of the Invention) According to the present invention, the delay in the multiplexing device,
Since the waste rate is reduced, high-quality communication can be achieved.

By transmitting packets at intervals, for example, if the model described in the conventional technology is used, packets are transmitted according to the packet transmission interval that is set in advance at the time of packet transmission, so the transmission interval is set to S slots. Then, there is an S-1 slot between the preceding and succeeding packets on the transmission path. Therefore, in the multiplexer, L
Even if L-1 simultaneous arrivals occur, no packets arrive between the S-1 slots immediately after, so the L-1 queue that has occurred (increased) over time gradually decreases. Since the decreasing speed is 1 packet and 11 slots, S
On arrival at the next simultaneous slot after the slot, the queue is L
-It has decreased to 8 pieces. If this is repeated for T packets, the queue length will increase by (L-8)XT.

Now, transmission path L=32, number of packets T=10.5=20
Assuming this, the maximum increase in communication delay time is 110 slots, which is a significant improvement in delay time compared to the maximum value of 310 slots in the conventional system described in the prior art section.

[Brief explanation of the drawing]

Fig. 1 is a diagram showing the principle of the present invention, Fig. 2 is an explanatory diagram showing the problems of the multiplexing method in the conventional technology, and Fig. 3 is a diagram showing the characteristics of the multiplexing method in the technology of the present invention. The explanatory drawings shown in FIG. 4, FIG. 5, FIG. 6 and FIG. 7 are diagrams showing the first, second, third and fourth embodiments of the present invention, respectively.
9 are explanatory diagrams showing an example of the packet transmission control method in the second, third, and fourth embodiments. In the figure, 401...Packet generation source, 501...Packet generation source, 606...Packet transmission interval calculation circuit, 712
... Buffer control circuit, 402 ... FIFO buffer, 403 ... Gate, 511 ... Buffer usage monitoring circuit, 404 ... Transmission path.

Claims (5)

[Claims] (1) Setting a packet transmission interval according to a data generation rate declared in advance, storing generated packets in a temporary packet buffer, and sequentially transmitting the packets from the packet buffer to a transmission path according to the packet transmission interval. A packet transmission method characterized by: (2) A packet transmission interval setting circuit for setting the packet transmission interval, a packet buffer circuit for accumulating packets, and a packet transmission for extracting packets from the packet buffer circuit and transmitting the packets to the transmission path according to the transmission interval. A packet transmitting device comprising a control circuit. (3) The packet transmitting device according to claim 2, further comprising means for monitoring the number of packets accumulated in the packet buffer circuit in the device or means for obtaining information on the traffic state in the network from the network, and Alternatively, a packet transmitting device comprising a circuit that generates a control signal for controlling the amount of packet generation to a packet generation source in the device according to the intra-network traffic information. (4) The packet transmitting device according to claim 2, further comprising means for monitoring the amount of packets accumulated in the packet buffer circuit in the device or means for obtaining information on the traffic state within the network from the network, and 1. A pallet transmitting device comprising: a circuit for generating a control signal for requesting a transmitting interval setting circuit in the device to reset the transmitting interval in accordance with the number or the intra-network traffic information. (5) The packet transmitting device according to claim 2, further comprising means for monitoring the number of packets accumulated in the packet buffer circuit in the device or means for obtaining information on the traffic state in the network from the network, and generates a control signal C1 for controlling the amount of packet generation to a packet generation source in the device according to the number of packets or traffic information in the network, and causes a transmission interval setting circuit in the device to reset the transmission interval; A packet transmitting device comprising a circuit that generates a requested control signal C2.