JPH11298528A - Packet exchange system and communication terminal - Google Patents

Abstract

PROBLEM TO BE SOLVED: To suppress reduction in throughput of a non-voice packet due to transmission of a voice packet. SOLUTION: A traffic threshold value, a transmission threshold value and a CODEC to be used are set in advance, and when voice data are given, whether or not the traffic given from a load detection section 31a exceeds the traffic amount threshold value is discriminated, and when the traffic exceeds, the total amount of voice data is suppressed by changing the transmission threshold value and the setting of the CODEC. Then the voice data to be sent are received by a prescribed length to discriminate whether or not the received voice data level exceeds the transmission threshold value and when not in excess, the voice data are sent to the set CODEC.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a packet switching system and a communication terminal for performing data transmission by packet switching, and more particularly to a packet switching system and a communication terminal for transmitting voice data.

[0002]

2. Description of the Related Art Packet switching is a communication system in which data to be delivered to a destination is divided into data blocks of a predetermined size called packets, and a required header and footer are added to each packet and transmitted to a communication line. . The header contains information such as the address of the destination communication terminal, the transmission time and the sequence number, and the footer contains information such as data attributes and error check codes.

In a packet switching system that performs data transmission by packet switching, a communication line is owned by a communication terminal that transmits a packet during transmission, but can be used for transmission of another packet during transmission. That is, the packet exchange has an effect of improving the use efficiency of the communication line in a form in which a specific communication line is shared among a plurality of communication terminals. The packet switching has a possibility of causing a packet arrival delay on the communication terminal side when the traffic volume of the communication line is large. The packet arrival delay means that the time from when a packet is transmitted to when it is delivered to its destination address is longer than that in a normal case.

[0004] With the expansion of networks, a technique of transmitting data generated continuously as real-time (real-time) data, for example, voice data obtained by digitizing telephone voice by packet switching, has attracted attention. I have. Telephone voice data generally has a larger data size than non-voice data, and moreover, since real-time performance is emphasized, it is necessary to transmit the voice data with higher priority than non-voice data. However, when a large amount of voice data is transmitted preferentially on a communication line, a problem arises that the throughput of non-voice data is reduced accordingly.

[0005] Therefore, by adjusting the total amount of voice data transmitted to the communication line according to the traffic amount of the communication line, a reduction in the throughput of non-voice data is suppressed while real-time performance of voice data is ensured. A "composite data packet switching system" is proposed in Japanese Patent Application Laid-Open No. 58-201449.

FIG. 6 is a block diagram showing the configuration of a system according to the "complex data packet switching system". The telephone 8 is connected to one end of an audio data line 9 via an audio / digital converter 7 for converting an analog audio signal into digital audio data. Voice data line 9
The other end is connected to the complex data packet switch 2 via a voice data communication control device 5 which performs packetization processing on given voice data under predetermined conditions. The complex data packet switch 2 includes a traffic monitoring module 3 for monitoring the traffic volume of a communication line. Further, the complex data packet switch 2 is connected to the non-voice data line 1 via the non-voice data communication control device 4 for performing packetization processing of non-voice data.

[0007] Voice data communication control device 5 determines packetizing whether conditions perform packet processing condition check module 6 has a built-in, packetized condition determination value V _E to be used for the condition determination Is given from the traffic monitoring module 3 as appropriate. Traffic monitoring module 3 provides in accordance with an increase of the traffic amount in the communication line increases the value of the packet conditions determination value V _E to packetized condition check module 6.

[0008] The packetization condition determination module 6
The amplitude information of the audio data given from the digital conversion device 7
Report value V and the packetization condition judgment value V_EAnd V
> V _EIn case of given packet processing of given voice data
Decide to do. Also, V <V_EWhen is given
Does not perform packetization processing of the audio data
A decision is made to discard the audio data. Audio data
The communication control device 5 transmits the audio data according to the above-described determination.
When packetized, it is converted to a complex data packet switch 2
Transmit to

With the above-described configuration, when the traffic volume of the communication line measured in the complex data packet switch 2 increases, the above-described system sets the packetization condition determination value _VE to be large to reduce the probability of generating voice packets. Therefore, a decrease in the throughput of non-voice data can be suppressed.

[0010]

In order to realize two-way real-time transmission / reception like a telephone, adaptive control should be performed based on the traffic volume of the communication line between the source and destination communication terminals. . However, in the above-described system, since the traffic amount of the communication line between the two communication terminals is conveniently determined based on the traffic amount measured in a specific packet switch, for example, a situation where a packet is transmitted through a plurality of packet switches is used. Below, there is a possibility that a sufficient effect cannot be obtained.

Further, if the discard amount of voice data increases with an increase in the packetization condition determination value relating to the total amount of voice data regulation, it will hinder the understanding of the content. It is necessary to set an upper limit that does not hinder the understanding of. That is, the effect reaches the limit at the set upper limit of the packetization condition determination value.

The present invention has been made in view of such circumstances, and provides a packet switching system and a communication terminal capable of expecting a sufficient effect even in a situation where packets are transmitted via a plurality of packet switches. With the goal.
Another object of the present invention is to provide a packet switching system and a communication terminal that do not hinder the understanding of the content due to the restriction on the total amount of voice data.

[0013]

A packet switching system according to a first aspect of the present invention has a plurality of data compression units having different compression efficiencies, and compresses data to be transmitted by using any one of the data compression units. Connecting a plurality of communication terminals and packet switches that generate packets of data,
In a packet switching system for transmitting a packet generated by one of communication terminals to another communication terminal specified in a header portion of the packet, communication from a communication terminal of a packet transmission source to a communication terminal of a transmission destination is performed. Detecting means for detecting the traffic amount of the line, selecting means for selecting data compressing means having a higher compression efficiency when the traffic amount detected by the detecting means increases, and data selected by the selecting means And a communication terminal of the transmission source set to use the compression means.

[0014] A packet switching system according to a second aspect of the present invention comprises:
A plurality of communication terminals and a packet switch which can set any one of a plurality of packet generation conditions defining a packet occurrence probability and generate a packet when data to be transmitted satisfies a predetermined packet generation condition In a packet switching system for transmitting a packet generated by any communication terminal to another communication terminal specified in the header part of the packet, the packet switching system Detecting means for detecting the amount of traffic on the communication line up to the communication terminal, and when there is an increase in the amount of traffic detected by the detecting means,
It is characterized by comprising a condition selecting means for selecting a packet generation condition so as to reduce a packet occurrence probability, and a communication terminal of a transmission source for setting the packet generation condition selected by the condition selecting means.

[0015] A packet switching system according to a third aspect of the present invention comprises:
The detecting means obtains the number of discarded packets based on the number of packets transmitted from the source communication terminal and the number of packets received by the destination communication terminal, and determines the traffic volume based on the number. Is detected.

[0016] A packet switching system according to a fourth aspect of the present invention comprises:
The detecting means obtains the time required for transmitting the packet based on the transmission time of the packet transmitted from the communication terminal of the transmission source and the reception time at which the packet was received by the communication terminal of the transmission destination. It is characterized in that the traffic amount is detected on the basis of the traffic amount.

[0017] A packet switching system according to a fifth aspect of the present invention comprises:
The detecting means sets a time required for packet transmission as a first transmission time based on a transmission time of a packet transmitted from a communication terminal of a transmission source and a reception time of reception of the packet by a communication terminal of a transmission destination. The time required for transmission of the packet received by the communication terminal after the reception of the packet is determined as a second transmission time.
The transmission time is subtracted to obtain a delay time, and the traffic amount is detected based on the delay time.

A communication terminal according to a sixth aspect of the present invention has a plurality of data compression means having different compression efficiencies, compresses data to be transmitted using any of the data compression means, and generates a packet of the compressed data. In a communication terminal intended to transmit to a predetermined communication terminal, there is a detecting means for detecting a traffic amount of a communication line to a communication terminal of a packet destination, and an increase in the traffic amount detected by the detecting means. And means for setting to use data compression means having higher compression efficiency.

The communication terminal according to the seventh aspect of the present invention can set any one of a plurality of packet generation conditions for defining the probability of occurrence of a packet, and when data to be transmitted satisfies a predetermined packet generation condition. To generate a packet,
In a communication terminal adapted to transmit to a predetermined communication terminal,
A detecting means for detecting a traffic amount of a communication line to a communication terminal to which a packet is to be transmitted; and a packet generation condition for reducing a probability of generating a packet when the traffic amount detected by the detecting means increases. Setting means.

According to an eighth aspect of the present invention, a communication terminal includes means for receiving the number of received packets notified from the communication terminal of the transmission destination, and the detecting means includes the number of transmitted packets and the number of received packets notified. , The number of discarded packets is obtained, and the traffic amount is detected based on the number.

A communication terminal according to a ninth aspect of the present invention includes means for receiving a reception time of a packet notified from the communication terminal of the transmission destination, wherein the detecting means determines the transmission time of the transmitted packet and the transmission time of the packet. The time required for transmitting a packet is obtained based on the reception time received by the communication terminal, and the traffic amount is detected based on the obtained time.

A communication terminal according to a tenth aspect of the present invention comprises a means for receiving a reception time of a packet notified from a communication terminal of a transmission destination, wherein the detection means detects a transmission time of a transmitted packet and the transmission time of the packet. Based on the reception time received by the communication terminal, the time required for transmission of the packet is determined as a first transmission time, and the time required for transmission of the packet received by the communication terminal after the reception of the packet is determined as a second transmission time. The transmission time is obtained, the first transmission time is subtracted from the second transmission time to obtain a delay time, and the traffic amount is detected based on the delay time.

The packet switching system and the communication terminal according to the present invention are provided with RTP / RTCP (Real Time Protocol / Real T
ime Control Protocol). In the packet exchange by RTP / RTCP, it is defined that information on the number of transmitted packets is notified from the communication terminal on the transmission side to the communication terminal on the reception side by RTCP. Therefore, the communication terminal on the packet receiving side can know the number of discarded packets by subtracting the number of received packets from the number of transmitted packets.

FIG. 4 is a time chart for explaining the transmission time and the delay time. In the figure, t1 is the communication terminal A
The time at which the first packet was transmitted from
t2 indicates the time when the communication terminal B receives the first packet. The time from time t1 to time t2 is the first transmission time. t3 indicates the time when the second packet was transmitted from the communication terminal A to the communication terminal B, and t4 indicates the time when the communication terminal B received the second packet. The time from time t3 to time t4 is the second transmission time. Furthermore, the difference obtained by subtracting the first transmission time equivalent (from time t3 to time a) from the second transmission time is the delay time (from time a to time t3).

FIG. 5 is an explanatory diagram showing a communication procedure for calculating the delay time. In the figure, the lapse of time is shown from left to right. RT from communication terminal A to communication terminal B
The first and second packets are transmitted by P (R1,
R2). The communication terminal B receiving the first and second packets calculates the delay time (R3). The communication terminal B notifies the communication terminal A of the calculated delay time by RTCP (R4). Upon receiving the notification of the delay time, the communication terminal A regulates the total amount of data (R5).

The packet switching system according to the first to fifth inventions and the communication terminal according to the sixth to tenth inventions regulate the total amount of voice data based on the traffic amount from the communication terminal of the transmission source to the communication terminal of the transmission destination. Thus, even in a situation where a packet is transmitted via a plurality of packet switches, a decrease in the throughput of non-voice data is suppressed.

Further, the packet switching system according to the first invention and the communication terminal according to the sixth invention suppress the total amount of voice data by selectively using data compression means having a high compression efficiency when detecting an increase in traffic volume. Thus, the amount of discarded audio data can be reduced. Also, the packet switching systems of the third to fifth inventions and the communication terminals of the eighth to tenth inventions monitor the number of discarded packets or the transmission time or delay time, and when detecting the increase, By controlling to reduce the total amount of the non-voice data, a decrease in the throughput of the non-voice data is suppressed.

[0028]

FIG. 1 is a block diagram showing a configuration of a packet switching system according to the present invention. In the figure, 11 is a communication terminal for transmitting and receiving voice packets,
The generated voice packet is provided to the gateway 13 via the public line network 12. The gateway 13 is connected to communication terminals 14 and 15 for transmitting and receiving voice packets and a router 16 for controlling communication related to packet exchange, and a LAN (Local Area Network) 17 is formed by this connection relationship. Router
16 is another router 19 via a wide area network 18
To the router and receives the packet from the router 19. The router 19 is a communication terminal 20 for transmitting and receiving voice packets.
And the LAN 21 is formed by this connection relationship.

FIG. 2 is a block diagram showing a configuration of the communication terminal 14, 15, or 20 according to the present invention. In the following description, it is assumed that the audio packet is packetized audio data that has been compressed. In the figure,
A connection 31 with the LAN is a protocol control unit for performing a protocol control relating to packet switching, and includes a load detection unit 31a for detecting a LAN traffic amount based on the number of discarded packets, transmission time or delay time. The protocol control unit 31 converts the received packet into a communication control unit 32 that controls the start / end of a session and selects a packet.
Give to. When starting a session, the communication control unit 32 sets data compression / decompression means commonly used between two communication terminals, specifically, setting of a CODEC and the like. When a session is started, it is determined whether or not a given packet is a voice packet.
The packet is provided to the voice input / output control unit 33.

The voice input / output control unit 33 extracts voice data from a given voice packet and gives it to one of the CODECs 34, 35 or 36 specified in the voice packet to instruct expansion. CODEC34,35
And 36 have different compression ratios from each other. Further, the voice input / output control unit 33 is connected to the LAN detected by the load detection unit 31a.
A CODEC selector 33a for selecting a CODEC to be used for compressing audio data in accordance with the traffic volume of the data. When the traffic volume of the LAN exceeds a predetermined value, the CODEC selection unit 33a sets the CO set at that time.
It is designed to select a CODEC having a higher compression ratio than the DEC. The CODECs 34, 35 and 36 supply the expanded audio data to the D / A converter 37. The D / A converter 37 converts the given audio data into an electric signal and outputs the electric signal to the speaker 38.

On the other hand, the electric signal supplied from the microphone 39 to the A / D converter 40 is converted into audio data and supplied to the audio input / output controller 33. The voice input / output control unit 33
The audio data is given to the CODEC selected by the C selection unit 33a, and the compression is commanded. The CODECs 34, 35 and 36 supply the compressed audio data to the audio packet processing unit 41. The voice packet processing unit 41 generates a packet by adding a header to the provided voice data, and supplies the packet to the protocol control unit 31.

FIG. 3 is a flowchart showing a processing procedure in the CODEC selecting section 33a. A traffic volume threshold, which is used as a reference for controlling the total amount of voice data, a transmission threshold, which is used as a reference for selecting voice data, and a CODEC to be used for data compression are set in advance. When voice data is provided, it is determined whether or not the traffic amount provided from the load detector 31a exceeds a traffic amount threshold (S1). If it exceeds, the setting of the transmission threshold value and the CODEC is changed to suppress the total amount of audio data (S2).

When it is determined in S1 that the traffic volume does not exceed the threshold value or after the processing in S2, the audio data to be transmitted is fetched for a predetermined length (S3), and the level of the fetched audio data is set to the transmission threshold value. Determine if it exceeds
(S4). If it does not exceed, the CODE in which the audio data is set
Send to C (S5). At S4, when it is determined that the transmission threshold value is exceeded, or after the processing at S5, it is determined whether or not there is unprocessed audio data (S6). When there is unprocessed audio data, the process proceeds to S3. And repeat the subsequent steps. When it is determined in S6 that there is no audio data,
The process ends.

The following is a specific example of a function relating to a change in the setting of the sending threshold and CODEC in S2. Equation 1
Is a function related to a change in the setting of the transmission threshold when detecting the traffic amount based on the number of discarded packets. Lv _TH : = Lv _TH + K ₁ (lp−lp _TH ) (Equation 1) In Equation 1, Lv _TH represents a transmission threshold, and lp _TH represents a discarded packet threshold. K ₁ represents a coefficient, and lp represents an actually measured value of the number of discarded packets. That is, sent to threshold Lv _TH, predetermined discard packet threshold lp
Added value obtained by multiplying the coefficient K ₁ to the number of packets discarded exceeds the _TH, it is to set a new delivery threshold.

Equation 2 is a function relating to a change in the CODEC setting when detecting the traffic amount based on the number of discarded packets. Co: = Co + K ₂ (lp−lp _TH ) (Equation 2) In Equation 2, Co represents the compression efficiency of CODEC and lp _TH
Represents a discarded packet threshold. K ₂ is a coefficient,
lp represents the measured value of the number of discarded packets. That is, a predetermined discarded packet threshold lp is added to the compression efficiency Co.
Added value obtained by multiplying the coefficient K ₂ to the number of packets discarded exceeds the _TH, it is to set a new compression efficiency.

Equation 3 is a function related to a change in the setting of the transmission threshold when detecting the traffic amount based on the transmission time. Lv _TH : = Lv _TH + K ₃ (dt−dt _TH ) (Equation 3) In Equation 3, Lv _TH represents a transmission threshold, and dt _TH represents a transmission time threshold. K ₃ represents a coefficient, and dt represents an actual measured transmission time. That is, the transmission threshold Lv
To _TH, adds the value obtained by multiplying the coefficient K ₃ to the transmission time elapsed exceeds a predetermined transmission time threshold lp _TH, is to set a new delivery threshold.

Equation 4 is a function relating to a change in the setting of the CODEC when detecting the traffic amount based on the transmission time. Co: = Co + K ₄ (dt−dt _TH ) (Equation 4) In Equation 4, Co represents the compression efficiency of CODEC and dt _TH
Represents a transmission time threshold. K ₄ is a coefficient, dt
Represents the measured value of the transmission time. That is, the compression efficiency Co
, In addition a value obtained by multiplying the coefficient K ₄ to the transmission time elapsed exceeds a predetermined transmission time threshold dt _TH, it is to set a new compression efficiency.

Equation 5 is a function relating to a change in the setting of the transmission threshold when detecting the traffic volume based on the delay time. Lv _TH : = Lv _TH + K ₅ (jt−jt _TH ) (Equation 5) In Equation 5, Lv _TH represents a transmission threshold, and jt _TH represents a delay time threshold. Also, K ₅ is a coefficient, jt denotes the measured value of the delay time. That is, the transmission threshold Lv
To _TH, adds the value obtained by multiplying the coefficient K ₅ on the delay time has elapsed exceeds a predetermined delay time threshold lp _TH, is to set a new delivery threshold.

Equation 6 is a function related to a change in the setting of the CODEC when detecting the traffic amount based on the delay time. Co: = Co + K ₆ (jt−jt _TH ) (Equation 6) In Equation 6, Co represents the compression efficiency of CODEC and jt _TH
Represents a delay time threshold. K ₆ is a coefficient, jt
Represents the measured value of the delay time. That is, the compression efficiency Co
Is added to a value obtained by multiplying the delay time exceeding a predetermined delay time threshold value jt _TH by a coefficient K ₆ to set a new compression efficiency.

The communication terminal and the packet switching system using the same according to the present invention having the above-described configuration are described in
When the traffic volume of the AN is high, the total amount of voice data is suppressed by setting the compression efficiency of voice data high. Although the packet switching system for transmitting audio data has been described as an embodiment of the present invention, image data for which real-time performance is important as in the case of the audio data, for example, image data for a live broadcast of sports is transmitted. It is needless to say that the same effect can be obtained even when the present invention is applied to a packet switching system.

[0041]

According to the packet switching system and the communication terminal of the present invention as described above, the total amount of voice data is regulated based on the traffic amount of the communication line from the communication terminal of the transmission source to the communication terminal of the transmission destination. A sufficient effect can be expected even in a situation where packets are transmitted via a plurality of packet switches.

In some cases, the packet switching system of the first invention and the communication terminal of the sixth invention regulate the total amount of voice data by setting the compression efficiency of voice data based on the traffic volume of the communication line. Deterioration of quality can be suppressed. Therefore, there is no problem in understanding the contents of the audio data.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a configuration of a packet switching system according to the present invention.

FIG. 2 is a block diagram illustrating a configuration of a communication terminal according to the present invention.

FIG. 3 is a flowchart illustrating a processing procedure in a CODEC selection unit.

FIG. 4 is a time chart for explaining a transmission time and a delay time.

FIG. 5 is an explanatory diagram showing a communication procedure for calculating a delay time.

FIG. 6 is a block diagram showing a configuration of a conventional system.

[Explanation of symbols]

 31 Protocol control unit 31a Load detection unit 33 Voice input / output control unit 33a CODEC selection unit 34, 35, 36 CODEC

────────────────────────────────────────────────── ─── Continuing on the front page (51) Int.Cl. ⁶ Identification symbol FI H04Q 11/04 H04Q 11/04 R (72) Inventor Masahiro Matsuda 4-1-1, Kamiodanaka, Nakahara-ku, Kawasaki-shi, Kanagawa Fujitsu Stock Within the company (72) Inventor Kazuyuki Otsu 4-1-1 Kamikadanaka, Nakahara-ku, Kawasaki-shi, Kanagawa Fujitsu Limited

Claims (10)

[Claims] 1. A plurality of communication terminals and a packet switch having a plurality of data compression means having different compression efficiencies, compressing data to be transmitted using any one of the data compression means, and generating a packet of the compressed data. In a packet switching system for transmitting a packet generated by one of the communication terminals to another communication terminal specified in the header part of the packet, Detecting means for detecting the traffic amount of the communication line up to the communication terminal of the communication terminal; selecting means for selecting a data compression means having higher compression efficiency when the traffic amount detected by the detecting means increases; And a source communication terminal for setting to use the data compression means selected by the means. 2. A method according to claim 1, wherein one of a plurality of packet generation conditions defining a packet generation probability is set, and a plurality of packets are generated when data to be transmitted satisfies a predetermined packet generation condition. In a packet switching system in which a communication terminal and a packet switch are connected and a packet generated by one of the communication terminals is transmitted to another communication terminal specified in the header of the packet, a packet transmission source Detecting means for detecting a traffic amount of a communication line from a communication terminal to a communication terminal of a transmission destination; and selecting a packet generation condition to reduce a probability of generating a packet when the traffic amount detected by the detecting means increases. Condition selecting means for setting, and a communication terminal of a transmission source for setting a packet generation condition selected by the condition selecting means. A packet switching system. 3. The method according to claim 1, wherein the detecting unit determines the number of discarded packets based on the number of packets transmitted from the source communication terminal and the number of packets received by the destination communication terminal. The packet switching system according to claim 1 or 2, wherein the traffic amount is detected based on the following. 4. The method according to claim 1, wherein the detecting unit determines a time required for transmitting the packet based on a transmission time of the packet transmitted from the communication terminal of the transmission source and a reception time of the packet received by the communication terminal of the transmission destination. 3. The packet switching system according to claim 1, wherein a traffic amount is determined based on the obtained traffic amount. 5. The detecting means determines a time required for transmitting a packet based on a transmission time of a packet transmitted from a transmission source communication terminal and a reception time at which the packet is received by a transmission destination communication terminal. The first transmission time is obtained, and the time required for transmitting the packet received by the communication terminal after the reception of the packet is obtained as the second transmission time, and the first transmission time is subtracted from the second transmission time to obtain a delay time. In search of
3. The packet switching system according to claim 1, wherein a traffic amount is detected on the basis of the information. 6. A data compression means having a plurality of data compression means having different compression efficiencies, compressing data to be transmitted using one of the data compression means, generating a packet of the compressed data,
Detecting means for detecting a traffic amount of a communication line to a communication terminal to which a packet is to be transmitted in a communication terminal adapted to transmit to a predetermined communication terminal; and when the traffic amount detected by the detecting means increases. Means for setting to use data compression means having higher compression efficiency. 7. It is possible to set any one of a plurality of packet generation conditions defining a packet occurrence probability, and generate a packet when data to be transmitted satisfies a predetermined packet generation condition. Detecting means for detecting a traffic amount of a communication line to a communication terminal to which a packet is to be transmitted, when the traffic amount detected by the detecting means is increased, Means for selecting and setting a packet generation condition so as to reduce the probability of occurrence of a packet. 8. A receiving means for receiving the number of received packets notified from a communication terminal of a transmission destination, wherein the detecting means discards the received packets based on the number of transmitted packets and the notified number of received packets. 8. The communication terminal according to claim 6, wherein the number of packets is obtained, and the traffic amount is detected based on the number. 9. A communication apparatus comprising: means for receiving a reception time of a packet notified from a communication terminal of a transmission destination;
Based on the transmission time of the transmitted packet and the reception time at which the packet was received by the destination communication terminal, the time required for transmitting the packet was obtained, and the traffic amount was detected based on the time. The communication terminal according to claim 6 or 7, wherein 10. A device for receiving a reception time of a packet notified from a communication terminal of a transmission destination, wherein the detection unit detects a transmission time of a packet transmitted and a reception time of the packet received by the communication terminal of the transmission destination. A time required for transmission of the packet is determined as a first transmission time based on the time, and a time required for transmission of the packet received by the communication terminal after the reception of the packet is determined as a second transmission time;
8. The communication terminal according to claim 6, wherein the first transmission time is subtracted from the transmission time to obtain a delay time, and the traffic amount is detected based on the delay time.