JP6450176B2 - Packet transmission equipment - Google Patents

Description

  The present invention relates to a packet transmission apparatus that transmits a packet such as an IP (Internet protocol) packet or an Ethernet (registered trademark) packet via a communication path whose transmission speed can be switched. The present invention relates to a packet transmission apparatus that efficiently transmits packets by using a transmission capacity of a communication path using a wireless communication path that switches speeds.

  In data communication using the Internet protocol (IP), data is transmitted by storing data in an IP packet and transmitting the IP packet via a packet transmission device and a communication path. FIG. 4 shows a schematic configuration example of a network in the case where the transmitting terminal 50 and the receiving terminal 53 at remote points perform data communication via the packet transmission device 51 and the packet transmission device 52 via the communication path 12 and the communication path 21. Indicates. Here, the transmission terminal 50 and the packet transmission device 51 are interconnected via the communication channel 01 and the communication channel 10, and the communication channel 23 and the communication channel 32 are connected between the reception terminal 53 and the packet transmission device 52. Shall be interconnected via

  In order to effectively transmit the packet by effectively using the transmission capability of the communication path 12, the output speed of the packet output from the transmission terminal 50 to the packet transmission device 51 is as high as possible within the range of the transmission speed of the communication path 12. Need to control to speed.

  In devices that perform data communication using IP, in order to reliably transmit data, the data transmitted in discarded packets is recovered, and the packet output speed is controlled according to the transmission speed of the communication path. Data communication is performed using a data communication protocol provided with a function (congestion control function). TCP (Transmission Control Protocol) is widely used as a data communication protocol for these devices.

  First, in the case where the transmission rate does not change, it will be described that the packet output rate of the transmission terminal 50 is controlled as high as possible within the range of the transmission rate of the communication path 12 by the TCP congestion control function.

  FIG. 5 is a block diagram showing an example of a conventional packet transmission apparatus. The packet transmission devices 51 and 52 in FIG. 4 can have the same configuration, and the packet transmission device 51 will be described as a representative. The packet transmission apparatus 51 includes packet input units 511 and 515, a packet transfer unit 512, packet standby control units 513 and 516, and packet output units 514 and 517.

  The packet input unit 511 receives the packet output from the transmission terminal 50 via the communication path 01 and inputs it to the packet transfer unit 512. The packet input unit 515 receives a packet transmitted from the opposite packet transmission device 52 via the communication path 21 and inputs the packet to the packet transfer unit 512.

  The packet transfer unit 512 analyzes the destination of the input packet to determine the output destination of the packet, and inputs the packet to the packet standby control unit 516 connected to the determined packet output unit 517. Accordingly, the packet transfer unit 512 is configured as a hub or a switch, for example, and is configured to determine the output destination of the packet for the plurality of packet standby control units 516 connected to each of the plurality of packet output units 517. (Not shown).

  Each of the packet standby control unit 513 and the packet standby control unit 516 has a function of temporarily holding the input packet in a buffer, and receives packets to be transmitted from the packet output unit 514 and the packet output unit 517, respectively. The packets are temporarily held in the respective buffers until transmission is possible from the communication paths 12 and 10 to which the respective packet output units 514 and 517 are connected.

  The packet standby control unit 513 and the packet standby control unit 516 determine whether or not the number of packets or the amount of data that can be stored in the buffer has reached a fixed upper limit (predetermined buffer size) when the packet is stored in the buffer. If the buffer size has been reached, it is determined that the packet cannot be stored, and either the input packet or the packet being stored is discarded.

  The packet output unit 514 takes out the packet from the packet standby control unit 513 and transmits the packet to the communication path 12 at the set transmission rate. The packet output unit 517 extracts the packet from the packet standby control unit 516 and transmits the packet to the communication path 10.

  Therefore, the packet transmission apparatus 51 is not able to transmit immediately even if a packet is input because the communication path is in use for transmitting a previously transmitted packet or the communication path cannot be used. In order to prevent the packet from being discarded, the packet is stored in the buffers of the packet standby control units 513 and 516 and held until it can be transmitted to the communication paths 12 and 10. However, the conventional packet transmission device 51 has a fixed upper limit on the number of packets and the amount of data that can be stored in the buffer. When this fixed upper limit (predetermined buffer size) is exceeded, the packet is discarded.

  Next, TCP congestion control will be described. TCP is known as a technique that makes it possible to control the output speed of a packet using a congestion window (cwnd) (see, for example, Patent Document 1).

  When the receiving terminal 53 based on TCP can confirm that the packet output from the transmitting terminal 50 is input to the receiving terminal 53 and correctly transmitted, the position information referring to the data to be received next is acknowledged (ACK). It transmits to the transmission terminal 50 as information. The transmitting terminal 50 performs flow control for outputting data in a range from the position specified by the ACK information to cwnd instead of outputting all data at once. This mechanism limits the maximum packet output rate to the congestion window / round trip delay time. The round trip delay time (RTT) is the time from when a packet is transmitted until the acknowledgment packet for that packet is received.

  In TCP congestion control, the packet sending speed is made to follow the transmission speed of the communication path by adjusting the size of this cwnd. There are several TCP congestion control methods. Loss-based congestion control techniques that gradually increase cwnd until packet loss is detected and rapidly decrease cwnd when packet loss is detected are widely used. (For example, refer to Patent Document 1).

  In TCP New Reno, which is a typical loss-based congestion control technique, the amount of increase in cwnd is 1 packet per RTT, and the amount of decrease is controlled to be ½ of cwnd. FIG. 6 shows an example of the time change of cwnd in TCP New Reno.

  With this congestion control function, the packet output speed of the transmitting terminal 50 gradually increases as cwnd increases. When this output speed exceeds the transmission speed of the communication path 12, the packet speed input to the packet transmission apparatus 51 exceeds the packet speed transmitted by the packet transmission apparatus 51, and the amount of packets stored in the buffer in the packet standby control unit 513 is increased. Over time, the accumulated amount of packets reaches the fixed upper limit (predetermined buffer size), and packet discard occurs. When detecting a packet loss from the ACK information, the transmitting terminal 50 decreases cwnd and decreases the packet output rate. By repeating this, the packet output speed of the transmitting terminal 50 is controlled to be close to the transmission speed of the communication path by the TCP congestion control function.

  As described above, the output speed of the packet of the transmission terminal 50 is controlled to be close to the transmission speed of the communication path 12 by the TCP congestion control function.

  Here, even when the transmission rate of the communication path 12 is switched by the conventional packet transmission device 51, the data transmission rate is automatically adjusted by the congestion control function.

  That is, when the transmission rate is increased, initially, the packet transmission rate of the packet transmission device 51 exceeds the packet output rate of the transmission terminal 50, and the packet storage amount of the buffer in the packet standby control unit 513 decreases. If the switching occurs when the cwnd value at the time of switching the transmission rate is small and the packet accumulation amount is small, the buffer is depleted and there is no packet to transmit, and the next packet is input to the packet transmission device 51. Until the communication path 12 becomes empty. The phenomenon in which the communication path 12 is vacant and packet transmission is intermittent is that cwnd gradually expands, the packet rate to be transmitted increases, reaches a new transmission rate, and packets are continuously buffered. Continue until it accumulates. While this phenomenon continues, no packet loss occurs.

Japanese Patent Laying-Open No. 2005-151202

  As described above, even when the transmission rate of the communication path 12 is switched by the conventional packet transmission device 51, the data transmission rate is automatically adjusted by the congestion control function. However, since the expansion of cwnd is performed slowly, even if the transmission rate is increased, the output rate of the packet of the transmission terminal 50 does not immediately increase to the new transmission rate, and a period in which the communication path 12 is vacant. There is a problem that becomes longer. Therefore, the conventional packet transmission device 51 has a problem that this problem is likely to occur because the maximum value of cwnd is small when the transmission speed is low.

  When the transmission rate is increased, the packet input interval to the receiving terminal 53 is shortened, the output interval of ACK information transmitted to the transmitting terminal 50 is also shortened, and the packet output rate at the transmitting terminal 50 is automatically increased.

  However, the interval of the ACK information to the transmitting terminal 50 changes after the RTT has elapsed since the transmission rate increased. During this time, the packet output speed at the transmission terminal 50 remains unchanged before the transmission speed is changed. For this reason, the transmission waiting packets of the packet transmission device 51 are rapidly reduced. As a result, in the conventional packet transmission apparatus 51, the packet stored in the buffer in the packet standby control unit 513 may be exhausted.

  In the conventional packet transmission apparatus 51, even if the transmission rate of the communication path 12 is increased, the cwnd of the transmission terminal 50 using the loss-based congestion control technique does not increase immediately. Therefore, the value of cwnd at the time of switching the transmission rate Is small, there is a problem that the buffer depletion state continues for a long time and the communication path 12 cannot be used effectively.

  Therefore, the present invention has been made in view of the above-described problems, and an object of the present invention is to enable continuous transmission of packets even when the transmission speed of the communication path 12 is increased. It is an object of the present invention to provide a packet transmission apparatus that has a function of changing the transmission rate of the packet and performs packet standby control according to the range of change of the transmission rate.

A packet transmission apparatus according to the present invention is a packet transmission apparatus having a function of changing a transmission speed of a communication path in a communication system that performs loss-based congestion control for following the transmission speed of the communication path with the transmission speed of the packet. A packet output unit that transmits a packet at a transmission rate and a packet that is transmitted from the packet output unit are temporarily held in a buffer, and when the packet is stored in the buffer, the number of packets or the amount of data can be changed. The maximum and minimum speeds that are predetermined for the buffer threshold that defines the upper limit, and the round-trip delay time between the transmitting terminal that is connected to the packet transmission apparatus and the receiving terminal that receives the packet from the transmitting terminal, or the packet defined time that the add certain margin to the round trip time between the transmission apparatus opposing the packet transmission device Based on, the initial buffer threshold consisting product of the maximum speed and the predetermined time, determined by adding the buffer correction value consisting of the product of the difference between the maximum speed and minimum speed and the specified time, the packet standby control And a speed control setting unit for setting a set value including the maximum speed, the minimum speed, and a specified time in the packet standby control part.

In the packet transmission apparatus according to the present invention, the packet standby control unit determines the maximum threshold and the minimum speed as the buffer threshold with respect to the initial buffer value of the buffer threshold adapted to the communication on the communication path. A value obtained by adding a predetermined fixed correction value to a value obtained by adding the buffer correction value obtained by the product of the speed change range and the specified time is used.

Also, the packet transmission device according to the present invention, the packet standby control unit, as the initial buffer value of the buffer threshold adapted for communication with the communication path, predetermined fixed correction factor to the product of the maximum speed and the specified time It is set as the value which multiplied by.

  According to the present invention, the maximum value of cwnd of a transmission terminal using loss-based congestion control can be maintained high even when the transmission speed of the communication path is reduced, and the transmission speed of the communication path is switched from low speed to high speed. Sometimes, packet transmission can be prevented from being intermittent, and efficient packet transmission that effectively utilizes the transmission capability of the communication path can be realized. In particular, according to the present invention, it is possible to prevent the depletion of packets to be transmitted when the transmission rate is increased, thereby improving the transmission efficiency.

It is a block diagram of the packet transmission apparatus of one Embodiment by this invention. It is a flowchart of the packet standby control in the packet transmission apparatus of one embodiment according to the present invention. (A), (b) is a figure which shows the operation example of the transmission rate at the time of packet standby control in the packet transmission apparatus of one Embodiment by this invention, and buffer amount (buffer packet / data storage amount), respectively. It is a figure which shows the example of schematic structure of a network in case a transmission terminal and a receiving terminal perform data communication via a packet transmission apparatus and a packet transmission apparatus. It is a block diagram which shows an example of the conventional packet transmission apparatus. It is a figure which shows the example of the time change of the congestion window (cwnd) in TCP New Reno.

  Hereinafter, a packet transmission apparatus according to an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a block diagram of a packet transmission device 51a according to an embodiment of the present invention.

  As shown in FIG. 4, a network is assumed in which a transmitting terminal 50 and a receiving terminal 53 at remote locations perform data communication via the packet transmission device 51 and the packet transmission device 52 via the communication path 12 and the communication path 21. The packet transmission device 51a according to the present invention will be described as being provided in place of the conventional packet transmission device 51. It is assumed that the communication path 12 has the slowest transmission speed among the communication paths 01, 12, and 23 that transmit packets in the direction from the transmission terminal 50 to the reception terminal 53. Each device performs data communication using TCP.

  In the packet transmission apparatus 51a according to the embodiment of the present invention shown in FIG. 1, the same components as those of the conventional packet transmission apparatus 51 shown in FIG. That is, the packet transmission device 51a according to an embodiment of the present invention includes packet input units 511 and 515, a packet transfer unit 512, packet standby control units 513a and 516, packet output units 514 and 517, and a speed control setting unit 518. The packet standby control unit 513a is different from the conventional packet transmission device 51 in that a specific control operation is performed based on the set value by the speed control setting unit 518.

  The packet input unit 511 receives the packet output from the transmission terminal 50 via the communication path 01 and inputs it to the packet transfer unit 512. The packet input unit 515 receives a packet transmitted from the opposite packet transmission device 52 via the communication path 21 and inputs the packet to the packet transfer unit 512.

  The packet transfer unit 512 analyzes the destination of the input packet to determine the output destination of the packet, and inputs the packet to the packet standby control unit 516 connected to the determined packet output unit 517. Accordingly, the packet transfer unit 512 is configured as a hub or a switch, for example, and is configured to determine the output destination of the packet for the plurality of packet standby control units 516 connected to each of the plurality of packet output units 517. (Not shown).

  The packet standby control unit 513a and the packet standby control unit 516 have a function of temporarily storing the input packets in the buffers, and receive packets to be transmitted from the packet output unit 514 and the packet output unit 517, respectively. The packets are temporarily held in the respective buffers until transmission is possible from the communication paths 12 and 10 to which the respective packet output units 514 and 517 are connected.

  However, the packet standby control unit 513a determines whether or not the number of packets or the amount of data that can be stored in the buffer has reached a variable upper limit (hereinafter referred to as “buffer threshold”) when the packet is stored in the buffer. If this buffer threshold is reached, it is determined that the packet cannot be stored, and either the input packet or the packet being stored is discarded.

  On the other hand, when storing the packet in the buffer, the packet standby control unit 516 determines whether or not the number of packets or the amount of data that can be stored in the buffer has reached a fixed upper limit (predetermined buffer size). If it has reached, it is determined that the packet cannot be stored, and either the input packet or the packet being stored is discarded.

  The packet output unit 514 takes out the packet from the packet standby control unit 513a, and transmits the packet to the communication path 12 at a set transmission rate that can be changed. The packet output unit 517 extracts the packet from the packet standby control unit 516 and transmits the packet to the communication path 10.

  Therefore, the packet transmission device 51a cannot transmit immediately even when a packet is input due to reasons such as when the communication path is being used for transmission of a previously transmitted packet or because the communication path cannot be used. In order to prevent the packet from being discarded, the packet is stored in the buffers of the packet standby control units 513a and 516 and held until it can be transmitted to the communication paths 12 and 10. In the packet transmission device 51a according to the present invention, the packet standby control unit 513a performs packet standby control with a certain upper limit (buffer threshold) on the number of packets and the amount of data that can be stored in the buffer. Sometimes the packet is discarded.

  Hereinafter, operations of the packet standby control unit 513a and the speed control setting unit 518 will be described in detail. FIG. 2 is a flowchart of packet standby control in the packet transmission apparatus according to the embodiment of the present invention.

  Referring to FIG. 2, the packet standby control unit 513a inputs a set value from the speed control setting unit 518 at the time of initial setting and setting change (step S1), and holds the set value (step S2). The speed control setting unit 518 sets a predetermined maximum speed, minimum speed, and specified time in the packet standby control unit 513a as the set values. The speed control setting unit 518 can be configured as an external interface that operates to set the setting value in the packet standby control unit 513a by an external operation by an administrator of the packet transmission device 51a. Alternatively, the setting by the speed control setting unit 518 may be configured so that it can be remotely set via a communication path.

  Further, the maximum speed and the minimum speed to be set can be set to, for example, the maximum transmission speed and the minimum transmission speed of the communication path 12 used in the packet transmission device 51a, and the specified time is a predetermined round-trip delay time (for example, RTT). However, the maximum speed and the minimum speed to be set, and the speed change range composed of the difference between them are a speed change range having a speed smaller than the maximum transmission speed of the communication path 12 and a speed higher than the minimum transmission speed of the communication path 12, respectively. Also good.

  The packet standby control unit 513a sets a value obtained by adding the initial buffer threshold and the buffer correction value as the buffer threshold. Here, “the value to add the buffer correction value to the initial buffer threshold” means that when the buffer correction value becomes a negative value, the absolute value of the buffer correction value is subtracted from the initial buffer threshold. pay attention to. On the other hand, in order to enhance the understanding of the present invention, when “add” is specifically described, it is assumed that the absolute value of the target value is added.

First, the packet standby control unit 513a determines the initial buffer threshold as the maximum speed set by the speed control setting unit 518 × the specified time × α (step S3). The initial buffer threshold is an initial value of a buffer threshold adapted to the communication on the communication path 12. For example, the initial buffer threshold is the maximum transmission speed of the communication path 12 set by the speed control setting unit 518 and the speed control. When communication is performed within a specified time set by the setting unit 518, a value designed so as not to cause buffer depletion is preferable. Further, as will be described later, the specified time can be a value obtained by “adding” a certain margin to the RTT.

  A suitable initial buffer threshold value can be the product of the maximum transmission rate of the communication path 12 and the specified time. In TCP New Reno, the product of the transmission rate and the specified time is known as the minimum buffer amount that does not cause buffer depletion. However, the fixed correction coefficient α is not limited to this value, but a correction based on a transmission experiment at the maximum transmission speed and specified time of the communication path 12 or a value based on past transmission results, or a congestion control algorithm other than TCP New Reno. Can be added. Therefore, the packet standby control unit 513a determines the initial buffer threshold as the maximum speed set by the speed control setting unit 518 × the specified time × α, and the value of the fixed correction coefficient α may be “1”. The value may be “a value less than 1” or “a value greater than 1”, and is a predetermined value.

  Subsequently, the packet standby control unit 513a determines the buffer correction value as (maximum speed−minimum speed) × specified time + β (step S4). That is, the packet standby control unit 513a calculates the difference as a speed change range from the maximum speed and the minimum speed set by the speed control setting unit 518, and the difference between the difference and the specified time set by the speed control setting unit 518. A predetermined fixed correction value β of 0 or more is “added” to the product value to obtain a buffer correction value.

  That is, for example, a large jitter may occur in the communication channel 01, the communication channel 12, the communication channel 23, the communication channel 32, the communication channel 21, and the communication channel 10. In such a case, it is preferable to “add” the fixed correction value β to the buffer correction value in accordance with the magnitude of jitter. Therefore, the value of the fixed correction value β may be “0” or “a value exceeding 0”, which is a predetermined value.

  Subsequently, the packet standby control unit 513a determines, as a buffer threshold, a value obtained by adding the determined buffer correction value to the determined initial buffer threshold (step S5), and executes packet standby control using the determined buffer threshold.

FIGS. 3A and 3B are diagrams showing an example of the operation of the transmission rate and the buffer amount (buffer packet / data storage amount) at the time of packet standby control in the packet transmission apparatus according to the embodiment of the present invention. is there. FIG. 3A illustrates a case where the transmission rate on the communication path 12 decreases from S0 to S1 at time t0 and increases to S2 at time t2. FIG. 3B shows a change in the buffer amount (buffer packet / data storage amount) at that time. For example, the packet storage amount q at time t from the time t0 until the specified time (Trtt) elapses, since the packet input rate exceeds the transmission rate by (S0-S1), the packet storage amount q0 at time t0. (S0-S1) increased by × (t-t0), the transition to the maximum storage quantity _{q Max} vicinity example. The maximum storage amount q _Max is a packet obtained by adding (maximum speed × specified time × fixed correction coefficient α) in the communication path 12 to (the difference between the maximum speed and the minimum speed) × the specified time and a fixed correction value β. This amount is the maximum packet storage amount, and corresponds to the buffer threshold value determined by the packet standby control unit 513a based on the setting value by the speed control setting unit 518 according to the present invention.

Conversely, at time t2, since the transmission speed increases, the packet storage amount q decreases by the speed difference. This state continues for almost the specified time (Trtt). If the input speed of the packet during this period is maintained at the speed before the change, the amount of decrease of the packet storage amount in the buffer is the product of the speed difference and the specified time. Therefore, the buffer threshold is the amount less device, a buffer is exhausted, the transmission of the packet is reduced is intermittent next transmission efficiency, the packet transmission device 51a according to the present invention, the maximum storage amount of the q _Max Can be made larger than the product of the speed difference and the specified time, so that when the transmission speed in the communication path 12 increases, it does not become 0 even if the packet storage amount decreases (depletion) Without), it is possible to prevent a decrease in transmission efficiency.

  In the above example, it has been described that the speed control setting unit 518 sets the predetermined maximum speed, the minimum speed, and the specified time in the packet standby control unit 513a as the set values, but the fixed correction coefficient α, The fixed correction value β may be added to the set value, or the packet standby control unit 513a may be configured to hold the fixed correction coefficient α and the fixed correction value β in advance.

  The “specified time” is desirable to generalize the round-trip delay time between the transmission terminal 50 and the reception terminal 53 that actually perform data communication. However, the transmission delay of the communication path 12 and the communication path 21 is When the transmission delay is extremely larger than the transmission delay of the other communication path, it becomes more accurate by adding a certain margin to the round-trip delay time between the packet transmission device 51a and the packet transmission device 52.

  If the buffer threshold is the same value, the lower the transmission speed, the smaller the maximum value of cwnd. However, by changing the buffer threshold by the buffer correction value based on the speed control setting by external setting, the transmission speed can be changed. It is possible to prevent a decrease in the maximum value of cwnd when it is lowered and maintain cwnd during high-speed transmission. With this effect, even if packet transmission becomes intermittent due to a shortage of cwnd that occurs when the transmission speed of the communication path 12 is switched from low speed to high speed, this can be prevented from continuing for a long time.

  The present invention has been described with reference to specific embodiments. However, the present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the technical idea thereof. For example, if it is necessary to update a part of a packet such as a packet header at the time of packet transfer according to the regulation of the packet communication protocol, the packet transfer unit 512 can be configured to perform this process.

  In addition, the packet transfer unit 512 is not included in the application in which the packet received by the packet input unit 511 is always output as it is from the packet output unit 514, and the packet received by the packet input unit 515 is always output from the packet output unit 517 as it is. It can be. In this case, the packet input unit 511 directly inputs the received packet to the packet standby control unit 513a, and the packet input unit 515 directly inputs the received packet to the packet standby control unit 516.

  Further, a transmission side packet transmission device configured by a packet input unit 511, a packet standby control unit 513a and a packet output unit 514, and a reception side packet transmission device configured by a packet input unit 515, a packet standby control unit 516 and a packet output unit 517 A network may be configured by the two packet transmission apparatuses. In this configuration, a transmission side packet transmission apparatus that transmits a packet to the communication path 12 capable of changing the transmission speed is an object of the present invention, and a conventional packet transmission apparatus may be used as the reception side packet transmission apparatus.

  According to the present invention, it is possible to realize efficient packet transmission that effectively uses the transmission capability of the communication path, which is useful for a packet transmission apparatus having a function of changing the transmission speed of the communication path.

DESCRIPTION OF SYMBOLS 50 Transmission terminal 51 Conventional packet transmission apparatus 51a Packet transmission apparatus according to the present invention 52 Conventional packet transmission apparatus 53 Reception terminal 511, 515 Packet input unit 512 Packet transfer unit 513, 513a, 516 Packet standby control unit 514, 517 Packet output Section 518 Speed control setting section

Claims (3)

A packet transmission apparatus having a function of changing the transmission speed of a communication path in a communication system that performs loss-based congestion control that follows the transmission speed of the packet to the transmission speed of the communication path,
A packet output unit for transmitting packets at a set transmission rate;
The packet to be transmitted from the packet output unit is temporarily held in a buffer, and when the packet is stored in the buffer, a predetermined maximum speed and minimum for a buffer threshold that defines a variable upper limit for the number of packets or the amount of data Speed and round-trip delay time between the transmitting terminal that is communicatively connected to the packet transmission apparatus and the receiving terminal that receives packets from the transmitting terminal, or the round-trip delay between the packet transmission apparatus and the opposite packet transmission apparatus Based on the specified time with a certain margin added to the time, the buffer correction consisting of the product of the difference between the maximum speed and minimum speed and the specified time to the initial buffer threshold value consisting of the product of the specified maximum speed and the specified time A packet standby control unit that determines the packet standby control by adding values, and
A speed control setting unit for setting a set value including the maximum speed, the minimum speed, and a specified time in the packet standby control unit;
A packet transmission apparatus comprising: The packet standby control unit, as the buffer threshold, the product of the maximum speed for that initial buffer value of the buffer threshold adapted for communication with the communication path and the velocity change range determined by the minimum speed the prescribed time 2. The packet transmission apparatus according to claim 1, wherein a predetermined fixed correction value is added to a value obtained by adding the buffer correction value obtained in step (1). The packet standby control unit, and characterized in that as the initial buffer value of the buffer threshold adapted for communication with the communication path, a value obtained by multiplying a predetermined fixed correction factor to the product of the maximum speed and the specified time The packet transmission device according to claim 2.