JPS6342543A - Packet flow controlling system - Google Patents

Abstract

PURPOSE:To realize the flow control which can cope with the overload condition of traffic, by controlling the transmission throughput by a packet terminal so that its own transmission throughput does not exceed a reported maximum throughput and abandoning excess packets or disconnecting a logical channel by an exchange if the packet terminal transmits packets with a throughput exceeding the reported value. CONSTITUTION:The number of packets is counted by a transmission packet (throughput) counter 14 in every throughput decision cycle which is a certain period reported by a throughput cycle switching report line 51, and the counted value is defined as the transmission throughput in the current cycle and is arranged with a network at the time of originating a call or the like, and it is checked by a throughput value comparator 16 whether this throughput value exceeds a maximum transmission throughput value stored in a throughput value holding device 15 or not. If it does not exceeds, a transmission permission report line 54 is set to the transmittable state and a packet transmission (throughput) controller 12 transmits packets from a transmission packet buffer 13. If it exceeds, the transmission permission report line 54 is set to the untransmittable state and the packet transmission (throughput) controller 12 stops the transmission.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a packet flow control method, and particularly to a packet flow control method between a packet switching terminal and a network switch.

[Conventional technology]

Traditionally, methods for communicating in packet format on fixed routes include, for example, statistical, switching, architecture, four, service, and service systems (Kultzer+Montgo).
merry: statistical
witching architectures
for future 5 services, IS
S' 84. There is a high-speed packet switching method described in May 1984).

In the above packet switching system, when controlling the packet flow between the packet switching terminal and the wire switch, the calling party is made to declare the maximum throughput of the call at the time of call setup, and flow control is performed based on this declaration f1α. . Note that throughput here refers to the number of packets transferred per unit time.

[Problem that the invention seeks to solve]

The above conventional technology has the following problems.

■With conventional packet switching technology, terminals have been forced to declare (declare) their throughput, which has been used to determine the window size within the network, etc., but there is no way to check whether users are adhering to this declared throughput. . For this reason, it is difficult to prevent malicious users from sending terminals that exceed the specified throughput.

■With conventional packet switching, it was not possible to change the throughput during communication. Therefore, if you want to increase the throughput, you have to call again, or if you want to decrease it, you have no choice but to waste it.

Furthermore, even when the network is congested, it is impossible to ask users to reduce their throughput.

The purpose of the present invention is to solve such conventional problems, to perform observation so that the observation cycles of both the network and the terminal match, and to enable throughput inspection, so that the throughput for each communication is within the maximum throughput value. It is an object of the present invention to provide a packet flow control method that can cope with traffic overload situations by guaranteeing communication and making it possible to change throughput during communication.

[Means for solving problems]

In order to solve the above problems, the present invention utilizes a packet communication network in which a packet terminal can communicate with multiple communication partners simultaneously on a single physical line using packet logical channel multiplexing technology, and transmits a signal to each logical channel. In a packet flow control method in which a packet terminal declares its maximum throughput in a calling message at the time of a call, the packet terminal controls its transmission throughput so that its own transmission throughput does not exceed the declared maximum throughput, and the packet communication The network exchange also monitors the throughput of each logical channel of a packet terminal, and when a packet terminal transmits a throughput that exceeds the declared value, it discards the excess packets or disconnects the logical channel. There are certain characteristics.

[Effect]

The network uses a simple counter to count the maximum number of packets sent at each predetermined period, and when this exceeds the value corresponding to the throughput declared by the user, it discards the packet or disconnects the logical channel. At this time, it is important that the starting point of the observation cycle is the same between the terminal and the network. If there is a deviation, the network will recognize it as a violation.

Therefore, in order to match the start point of this observation cycle, the transmission frame cycle is used if available.

However, since the period of the transmission frame is determined from the viewpoint of transmission characteristics, it may not be possible to match the period required for flow control. Therefore, flow control frames are introduced only when the transmission frame period is not available. This throughput is independent for each logical call. Additionally, means for changing the throughput value during communication is provided for the following events. That is, (1) If one logical call is used for multiple communications and another communication occurs during one communication, a throughput change is requested from the terminal.

■Congestion control is performed by requesting a reduction in the throughput of a certain call from the network to the terminal due to a lack of network resources.

〔Example〕

Hereinafter, one embodiment of the present invention will be described in detail with reference to the drawings.

FIG. 1 is a diagram showing the relationship between terminal side equipment and network side equipment in a packet communication network to which the present invention is applied. Normally, another terminal is connected to the other side of the network, but this is omitted.

In FIG. 1, 0 is a terminal, l is a terminal-side flow control device, 2 is a network-side flow control device, 3 is a network-to-terminal transmission path, and 4
is a network, 31 is a terminal side receiving line, 32 is a terminal side transmitting line,
100 is a receiving line on the network side, and 101 is a transmitting line on the network side.

Before explaining the embodiments at the terminal and the south side, the channel structure between the terminal and the rope (FIG. 3, described later) and the method for determining the maximum throughput (FIGS. 4 to 6, described later) will be described.

FIG. 3 shows a signal channel separation type user interface used in I5DN. Messages for call control are transferred using a signal channel (referred to as a D channel), and data packets in the data transfer phase are transferred using an information channel. This D channel uses a fixed position in the channel structure (Figure 3 (a))
There is a method of dynamically occupying an arbitrary position (FIG. 3(b)). In the case of a non-separated type of signaling channel that is used at the user interface of a network other than I5DN, signaling messages and data packets are transmitted and received using the same channel. The present invention can be applied to any of the above channel structures.

FIG. 4 shows a communication sequence for determining the maximum throughput for each call when making a call. Here, n
ni is the line throughput in the direction from the terminal (i = 1 to 5
), Tl1ni is the line throughput from the network to the terminal (
in-5), THtl≧THn2≧TlIn3≧Tl1
There is a relationship of t4=T11n5, and T11nl≧Tl1t
The relationship is 2≧THt3≧Tl1n4=Tllt5. T11ti or T! When In1 (i=1-5) is omitted, a predetermined default is taken.

At the start of communication, the calling terminal notifies the network of the maximum transmission and reception throughput (the number of transmitted and received packets per unit time) of the communication (call) in a calling message. The network notifies the terminating terminal of the maximum transmission and reception throughput in the terminating message. This value may be changed by the network from the value declared by the calling terminal. The receiving terminal may change the maximum transmission/reception throughput notified by the network. The network determines the final value based on the value reported by the terminating terminal and notifies the originating and terminating terminals. In adjusting these values, as shown in FIG. 4, the values are usually changed to become smaller. When using a predetermined default value, there is no need to explicitly notify the value to both the terminal and the network. Further, the notification of the final value to the last receiving terminal may be omitted since the notification value from the receiving terminal is usually equal to the final value. It is conceivable that these maximum throughputs may be requested to be changed from the network or terminal during communication. For example, when users themselves multiplex connections within one logical channel.

An example of this is when a new connection is required during communication of one connection, and it is necessary to add throughput for this new connection. The sequence at this time is shown in FIG. In FIG. 5(a), Tl1ti is the line throughput from the terminal to the group (i: 1 to 5), THni is the line throughput from the line to the terminal (iJ to 5), and Tl! tl≧T+1
There is a relationship of n2≧Tl1n3≧TIIt4 = TlIn5, and Tl1nl≧T11t2≧T+1t3≧THn
4=TIIt5. Tl1ti or Tl!
When n1 (i=1 to 5) is omitted, it means that the value remains the same as before. In addition, in FIG. 5(b), Tl1ti is the line throughput from the terminal to the group direction (i=1 to 6), Tl1ni is the line throughput from the line to the terminal direction (i=1-6), and THtl=TIIn2≧
Tl1t3, THtl=TIIn2≧THn4, m1n
(Tllt3.TlIn4)≧Tll [5= TlI
There is a relationship of n6, T11nl=T11t2≧TlIn
3, Tl1nl = Tllt2≧T11t4, l1in
(T11n3.TIIt4)≧Tl1n5 = Tll
The relationship is t6.

n> in which Tl1ti or Tl1ni (i; 1-6) is omitted means that the value remains the same as before.

These are used for network or terminal congestion control, etc. The above-mentioned control messages are transferred via the signaling channel (D channel) in a user interface with separate signaling channels. This transfer may be performed by transmitting as a control packet as shown in FIG. 3(b) other than via the D channel. However, this requires that the bit error control of the control packets be compensated. For high-speed packets, etc., if complete bit error control is not performed for each packet, it is not suitable because there is no compensation for accurate information transmission. However, even if error control is performed such as returning a response regarding the packet between the terminal and the network, this is not a desirable method considering that the control signal only needs to be handled by the D channel in terms of network processing.

FIG. 2 shows a terminal side flow 't showing an embodiment of the present invention.
, II is a configuration diagram of the control device. This shows the detailed configuration of the terminal-side flow control device 1 shown in FIG.

In FIG. 2, l is a terminal-side flow control device, 5 is a terminal-side line termination device that terminates the line on the terminal side, 6 is a terminal-side line terminating device for terminating the line on the terminal side, 6 is a packet-switched channel information for receiving information, 9 is a circuit-switched channel information,
and a channel separation device for separating into D channel information, 7
is a receive packet buffer that stores received packets,
8 is a D channel information separation device that separates D channel information for this device from D channel information for other devices; 9 is a throughput management device that determines the maximum transmission/reception throughput for each call; and 10 is a packet channel information 9 block. A channel assembling and transmitting device assembles and transmits line switching channel information and D channel information; 11 is a D channel information transmitting device that transmits the maximum transmission/reception throughput in a calling message during 5 calls; 12 is a packet transmitter; 13 is a transmission packet buffer that stores transmission packets, 14 is a transmission packet (throughput) counter that periodically counts the number of transmission packets for each call, and 15 is a maximum throughput at the time of call setup. Throughput value holding device that stores the value, 16 is counter 1
4 is a throughput value comparison device that permits transmission only when the counted throughput value is smaller than the maximum throughput value stored in the holding device 15; 31 is a receiving line on the terminal side;
32 is a terminal side transmission line, 35 is a reception information tA line, 36 is a transmission information line, 37 is a circuit switching channel group reception line, 38 is a circuit switching channel group transmission line, 39 is a packet reception line, 40
is a packet transmission line, 41 is a D channel information reception line, 42
4 is a D channel information transmission line, 43 is a D channel information transmission line for other equipment, 44 is a channel information receiving line originating from another equipment, and 4
5 is a throughput information reception line, 46 is a throughput information notification line, 47 is a flow control frame synchronization line, 48 is a transmission frame synchronization line, 49 is a bit synchronization line, 50 is a packet transmission notification line, 51 is a throughput judgment cycle switching notification line , 52 is a transmission packet number notification line, 53 is a specified throughput notification line, 54 is a transmission permission notification line, 55 is a packet transmission line, and 56 is a final throughput notification line.

The operation of the control device 1 will be explained below, divided into determining the logical channel number and throughput at the time of calling the information transmitting/receiving 9, and flow control in the data communication phase.

(Information Transmission/Reception) Information received from the terminal-side reception surface 8131 via the terminal-side line termination device 5 is sent to the channel separation device 6 by the channel separation device 37,
It is separated into various types of information shown in 39, 41, 47, 48, and 49. Conversely, various information (38, 40,
42, 47, 48, 49) and transmitted to the network via the channel assembly transmitter 10.

(Determination of logical channel number and throughput when making a call) The throughput management device 9 determines the maximum throughput for sending and receiving for each call, and sends a calling message via the D channel information transmitting device 11 to a calling message when making a call. and send it. When a call arrives, the throughput management device 9 receives the logical channel number and final transmission/reception throughput of the call via the D channel information separation device 8 in response to a connection notification message from the network. The value is held in the throughput value holding device 15. An example of this retention table is shown in FIG.

(Flow control in data communication phase) The transmission packet (throughput) counter 14 counts the number of packets in each throughput judgment cycle consisting of a certain period notified by the throughput judgment cycle switching notification line 51, and the value is Defined as transmission throughput,
The throughput value comparison device 16 checks whether or not this value exceeds the maximum transmission throughput value stored in the throughput value holding device 15, which is negotiated with the network at the time of a call or the like. If the transmission permission notification line 54 is not exceeded, the transmission permission notification line 54 enters the transmission permission state, and the packet transmission (throughput) control device 12 transmits from the transmission packet buffer 13. If it exceeds, the transmission permission notification line 54 becomes in a transmission disabled state, and the packet transmission (throughput) control device 12 stops transmission.

However, even in this transmission disabled state, at the next throughput cycle, the transmission packet (throughput) counter 14 is cleared, so the transmission becomes possible and transmission can be resumed.

The timing of this fixed period needs to match between the rope and the terminal. The reason for this is shown in FIG. As shown in this figure, the terminal has a maximum transmission throughput of 3 (
Even if you intend to titrate the packet/period), if the observation period deviates between the network and the terminal, the network will assume that the maximum throughput has been exceeded. To prevent this, flow control synchronization is used to match the observation period between the terminal and the network. Normally, if the transmission frame synchronization used by the transmission system can also be used as the observation period for flow control, it may be used as is. In this case, the throughput period is transmitted from the transmission frame synchronization line 48 to the transmission packet (throughput) counter 14 via the channel assembly and transmission device 10. However, when a cycle larger than a transmission frame is required as a flow control cycle, it is necessary to use multiframes for transmission synchronization.

This can be used if it exists in the transmission system, but if it does not exist or is not an integral multiple, unique flow control synchronization is required. Also, when a cycle smaller than the transmission frame is required, unique flow control synchronization is required. An example of this flow control synchronization method is shown in FIG. Here, TF indicates framing control information for transmission synchronization, FF indicates framing control information for flow control synchronization, (a) is when the flow control frame is larger than the transmission frame and is an integral multiple, and (b) is the flow control frame. is larger than the transmission frame and is not an integral multiple,
(C) shows that the flow control frame is l/n of the transmission frame.
(n is an integer) (d) shows the flow control frame being 1/n of the transmission frame (n is not an integer). In this case, the flow control frame synchronization line 47
The flow control throughput period of is transmitted to the transmission packet (throughput) counter 14 via the channel assembly and transmission device 10.

The 9th edition summarizes the information exchanged between the terminal and the network.
It is a diagram. TF is a synchronization signal for the transmission frame, FF is a synchronization signal for flow control, P is a slot for packet communication,
C is a slot for circuit switched communication, and D is a slot for commonly transmitting and receiving call control signals. P and C may be mixed. Further, D may be separated into two parts: a glue for packet switching call control and a DC for circuit switching call control. Also, P, C
.

The relative positions of D are arbitrary. Further, all slots in one frame may be exclusively occupied by P, C, or D.

FIG. 10 is a diagram showing an example of the configuration of a terminal system.

One terminal may be connected to one subscriber line, or a plurality of terminals may be connected to one subscriber line.

The present invention is also effective in accommodating multiple terminals.

FIG. 11 is a configuration diagram of a south side flow control device showing an embodiment that is self-explanatory. This shows the detailed configuration of the network side flow control cycle flf2 in FIG.

In FIG. 11, 2 is a network side flow control device.

71 is a network side line termination device that terminates the line on the network side; 72 is a transmission frame synchronization circuit that controls synchronization of transmission frames;
73 is a transmission frame synchronization abnormality control circuit that controls synchronization abnormality in the synchronization circuit 72; 74 is a channel separation device that separates received information into packet switching channel information; 9 circuit switching channel information; and D channel information; 75 is a synchronization of flow control frames. Flow control frame synchronizer that controls control, 7
Reference numeral 6 denotes a flow control frame synchronization abnormality control circuit for controlling synchronization abnormality in the synchronizer 75, 78 a reception packet buffer for storing received packets, and 79 a reception packet (throughput) counter for periodically counting the number of received packets in response to a call. , 88 is a line-compatible throughput value calculating device that calculates the number of received packets (throughput value) corresponding to the line, 8o is a throughput value holding device that stores the maximum throughput value at the time of call setup, and 89 is a device that determines an overload state. A system constant holding device 81 stores the basic value, and a device 81 holds the counting throughput value corresponding to the call by the counter 79.
A throughput value comparing device 77 compares the magnitude of the stored maximum throughput value in the receiving bucket buffer 7 only when the counted throughput value corresponding to the call is within the stored maximum throughput value according to the comparison result of the comparing device 81.
a packet reception/flow control violation control device stored in 8;
90 compares the throughput value corresponding to the line by the arithmetic unit 88 and the base value ψ for determining the overload situation in the holding circuit 89, and if the throughput value corresponding to the line is similar to the base value for determining the overload situation, For example, a congestion control device 82 issues a throughput reduction request to the terminal for all calls on the line, and 82 is a D channel information for this device and a D channel information for other devices.
D channel information separation device for separating channel information, 83
84 is a D channel information transmitting device that determines the maximum transmitting/receiving throughput for each call, 84 is a D channel information transmitting device that transmits the maximum transmitting/receiving throughput in a calling message, and 85 is a transmitting packet that stores transmitting packets. 86 is a packet transmission (throughput) control device that controls packet transmission; 87 is packet channel information 9;
100 is a network side reception line, 102 is a network side transmission line, 102 is a reception information line,
103 is a transmission information line, 104 is a reception delta information edge, 105 is a transmission flow control synchronization abnormality notification line, lO6 is a reception information line,
107 is a circuit-switched channel group reception line, 108 is a circuit-switched channel group transmission line, 109 is a packet reception line, 110 is a packet transmission line, ill is a reception flow control frame synchronization line, 112 is a transmission flow control frame synchronization line, and 113 is a transmission flow control frame synchronization line. D channel information reception line, 114 is a D channel information transmission line, 115 is a flow control frame synchronization abnormality notification line, 116
is a flow control frame synchronization notification line, 117 is a packet reception line, 118 is a packet reception notification line, 119 is a packet reception line, 120 is a received packet count violation notification line, 121 is a received packet number notification line, 122 is a throughput value notification line , 123 is a throughput value change notification line, 124 is a D channel information line for other equipment, 125 is a throughput information receiving line, 126 is a throughput information notification line, 127 is a D channel information line originating from another equipment, 128 is a packet transmission line, 129 is a packet storage line, 130 is a call corresponding throughput (, α notification line, 131 is a line corresponding throughput information notification line, 13
2 is a system constant notification line, 133 is a congestion status notification line, 1
34 is an input restriction information notification line.

The operation of the control device 2 will be explained below, divided into determining the logical channel number and throughput when the information transmitter/receiver 9 calls, and flow control in the data communication phase.

(Information Transmission/Reception) Similar to the embodiment on the terminal side, the information received from the network side receiving line 100 via the network side line termination device 71 is sent to the channel separation device 74 to send various information shown in 107, 109, 111, and 113. separated into

Conversely, various pieces of information shown at 110, 114, and 122 are assembled by the channel assembly/transmission device 87 and transmitted to the network-side transmission line 101 via the network-side line termination device 71.

(Determination of logical channel number and throughput at the time of call origination) In the call setup phase, when the logical channel number and transmission/reception maximum throughput value from the terminal side are received via the D channel information separation device 82, first, the The throughput management device r! If 183 has decided (judged) and can accept it,
Through the D channel information transmitting device 84, the reading is placed on a calling message and transmitted to the next exchange or terminal, and at the same time, the received logical channel number and the maximum transmission/reception throughput value are held in the throughput value holding device 80.

If the request cannot be accepted, the sending terminal will be notified of this fact.

(Flow control of data communication phase) The throughput of packets transmitted from the terminal side is counted (observed) in the received packet (throughput) counter 79, and the counted number of received packets is sent to the throughput value via the received packet number notification pJ 121. It is input to the comparison device 81. Further, the maximum transmission throughput value that is agreed upon with the terminal at the time of making a call and stored in the throughput value holding device 80 is input to the throughput value comparison device 81 via the throughput value notification line 122. The throughput value comparison device 81 compares the manually input number of received packets (counted throughput value) with the maximum transmission throughput value. If the throughput of the terminal is less than the declared value, the packet is stored in the reception packet buffer 78 via the packet reception/flow control violation control device (gate) 77. if,
If it exceeds the declared value, the packet reception/flow control violation control device (gate) 77 discards it. Additionally, the call itself can be disconnected or reset due to a breach of contract. The throughput cycle is determined in the same way as the terminal, and if the transmission frame cycle is available, the packet reception/flow control violation control device 77 notifies the reception packet (throughput) counter 79 of the transmission frame synchronization along with the reception packet. In addition, when transmission frame synchronization cannot be used and flow control frame synchronization is used, the information on the received flow control frame synchronization line Ill is transmitted through the flow control frame synchronization device 75 to the information on the flow control frame synchronization notification line 116 of the received packet. (Throughput) is transmitted to the counter 79.

On the other hand, the line corresponding throughput value calculating device 88 calculates the line corresponding throughput value which is logically multiplexed by a plurality of calls, and calculates the corresponding call corresponding in the received packet (throughput) counter 79 for all the calls connected at the time of observation. The calculation value is calculated by adding the counting throughput values at that point in time, and the wheel axle control device 90 determines whether or not the calculated value exceeds a predetermined reference value for determining an overload situation. If it exceeds, for example, the wheel axle control device 9
0 implements congestion control by issuing a throughput reduction request to the terminal side for all calls on the line. If it does not exceed the limit, the wheel set control device 90 notifies the throughput value comparison device 81 that the network is not overloaded and that flow control will be performed by discarding, disconnecting, or resetting packets corresponding to the throughput over at the time of violation of the contract. do.

In this way, in this embodiment, in order to control the flow of packets, a flow control signal is provided in the opposite direction to the transmission direction, and the flow control signal is used to instruct the flow rate that can be transmitted. In contrast to conventional flow control, in this embodiment,
Flow control can be performed without this reverse signal. In addition, for the network, which uses the throughput declared by the user at the time of making and receiving calls as a basis for judgment, whether to accept or reject the call, if the user does not adhere to the declared throughput, it may interfere with the control of the network, or other users may However, by using this embodiment, the second violation can be detected and dealt with by simple network control.

〔Effect of the invention〕

As explained above, according to the present invention, it is possible to perform observation so that the observation cycles of both the network and the terminal match, and it is also possible to inspect throughput, and communication is possible within the maximum throughput value for each communication. I can guarantee it. Furthermore, since it is possible to change the throughput during communication, flow control that can cope with traffic overload situations can be realized.

[Brief explanation of the drawing]

FIG. 1 is a diagram showing the relationship between a terminal side device and a rope side equipment in a packet communication network to which the present invention is applied, and FIG. 2 is a detailed configuration diagram of a terminal side flow control device showing an embodiment of the present invention. 3
The figure shows an example of the channel structure of the user interface.
Figure 1 shows the throughput notification procedure when making a call, Figure 5 shows an example of changing throughput from a communicating terminal or network, and Figure 6 shows a throughput management table for each call. , Fig. 7 is a diagram for explaining the necessity of synchronization between the network and the terminal in the throughput observation period, Fig. 8 is a diagram showing the types of flow control synchronization, Fig. 9 is a diagram showing the channel structure, and Fig. 10 This figure shows the configuration of a terminal system, and FIG. 11 is a detailed configuration diagram of a network-side flow control device showing an embodiment of the present invention. 1: Terminal side flow control device, 5: Terminal side line termination device,
6. Channel separation device, 7. Receive packet buffer, 8
．． D channel information separation device, 9-channel output management device, 10. Channel assembly and transmission device, 11: D channel information transmission device, 12: Packet transmission (throughput) control device, 13/Transmission packet buffer, 14: Transmission packet (throughput) counter, 15 Nisloopt value holding device, 16: Throughput value comparison device , 31. Terminal side receiving line, 32. Terminal side transmission line, 2: w4 side flow υj
control device, 71 network side line termination device, 72 transmission frame synchronization circuit, 73/transmission frame synchronization abnormality control circuit, 74:
Channel separation device, 75: Flow control frame synchronization device, 76: Flow control frame synchronization abnormality control circuit, 77:
Packet reception 3 flow control violation control device, 78: Reception packet buffer, 79: Reception packet (throughput)
Counter, 80.Throughput value holding device, 81.Throughput value comparison device, 82. D channel information separation device,
83 Nisroupt management device, 84: D channel information transmitting device, 85: Transmission bucket buffer, 86 Packet transmission (throughput) control 21! device, 87: channel assembly and transmission device, 88: line compatible throughput value calculation device, 89 system constant holding device, 90: wheel axle control device,
100: M4 side receiving line, 101: M4 side transmitting line. Patent Applicant: Masatoshi Isomura, Patent Attorney, Nippon Telegraph and Telephone Corporation No. 3 Fig. 4 Fig. 5 (a) Fig. 5 (b) Fig. 6r''4 No. 7 Period of one terminal Upper terminal The period of 'sloop 7) -
3 cycles/period throughput) - 3/sun, t/cycle m - copper period - 1 period - 1 throughput 4 packets/W Figure 9 Figure 10

Claims (5)

[Claims] (1) Using a packet communication network that allows packet terminals to communicate with multiple communication partners simultaneously on a single physical line using packet logical channel multiplexing technology, the maximum throughput for each logical channel is achieved when making a call message. In the packet flow control method in which packet terminals are forced to declare their own transmission throughput, the packet terminal controls its own transmission throughput so that it does not exceed the declared maximum throughput, and the switching equipment of the packet communication network also controls the transmission throughput for each logical channel of the packet terminal. A packet flow control method characterized in that when a packet terminal transmits a throughput exceeding a declared value by observing the throughput of the packet, the packets in excess of the transmitted value are discarded or the logical channel is disconnected. (2) In the packet flow control method according to claim 1, as a method for observing the throughput of each logical channel of the packet terminal, the maximum packet that the packet terminal can transmit at each predetermined period corresponding to the declared throughput is A packet flow control method characterized in that a number of packets is predetermined, and when a number of packets exceeding the maximum number of packets is input, a throughput violation is determined. (3) In the packet flow control method according to claim 1 or 2, in order to match the observation timings of the packet terminal and the switch of the packet communication network when observing the user throughput, a normal transmission method is used. A packet flow control method that uses the above frames and uses the number of packets in one frame. (4) In the packet flow control method according to claim 3, a start instruction packet for notifying the start of the observation cycle is used separately from the frame on the transmission method, and the observation cycle is notified to the other party. Characteristic packet flow control method. (5) In the packet flow control method according to claim 1, a change in maximum throughput is notified from a switching device of a packet communication network to a packet terminal during communication, or from a packet terminal to the switching device, and a response is received. A packet flow control method characterized in that after the packet is returned, the same control as in claim 1 is performed using the changed throughput.