JP2014160899A - Delay measurement method and delay measurement system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To accurately grasp a delay time and delay fluctuation of a packet while avoiding bandwidth pressure and to measure a delay distribution of the packet.SOLUTION: In a delay measurement method for measuring a delay time of a main signal packet transferred via a packet exchange network between a transmission side NE and a reception side NE where time synchronization is established, the transmission side NE has a first step to transmit a main signal packet and a reference packet setting an ID for distinguishing the main signal packets transmitted during a fixed time as one group and measures a transmission time of day of the reference packet and difference in transmission time between main signal packets. The reception side NE has: a second step to measure a reception time of day of the reference packet and measure difference in reception time between the main signal packets; and a third step to calculate the transmission time of day and reception time of day of the reference packet and a delay time of the respective main signal packets from respective data of the transmission time difference and reception time difference between the main signal packets.

Description

  The present invention relates to a delay measurement method and a delay measurement system for accurately grasping a delay time and delay fluctuation of a packet in a packet switching network and measuring a delay distribution of the packet.

  One method for measuring the delay time of a packet-switched network is a method using Ethernet (registered trademark) OAM (Ethernet Operations, Administration, Maintenance) technology. This method is defined as a DMM (Delay Measurement Message) function in ITU-T Recommendation Y.1731 (Non-Patent Document 1).

FIG. 6 shows a method of delay time measurement by OAM.
In FIG. 6, in addition to the main signal packet, a delay measurement packet is transmitted and received between the transmission NE (node) 50 and the reception NE 60 that are synchronized in time. The delay measurement packet generator 51 of the transmission side NE 50 sets a time stamp (Tx) when generating a delay measurement packet, and the delay measurement packet receiver 61 of the reception side NE 60 receives the delay measurement packet. Sometimes the reception time (Rx) is recorded. When time synchronization is established between NEs (between the delay measurement packet generator 51 and the delay measurement packet receiver 61), the delay time D can be measured by the following equation.
D = Rx−Tx (1)

  A problem of this measurement method is that the delay time of the actual main signal packet cannot be obtained because the delay time measurement target is the delay measurement packet. In addition, the delay time calculated in this measurement includes the time for generating the delay measurement packet by the delay measurement packet generator 51 and the read time by the delay measurement packet receiver 61 as error factors. Correction is necessary after calculation. In addition, the delay measurement packet by OAM has a small number of samples, and accurate delay fluctuation (difference between the maximum value and the minimum value of the delay time) cannot be obtained. In order to calculate an accurate delay fluctuation, a band equivalent to the main signal packet is required.

FIG. 7 shows a method of delay time measurement using the time stamp of the main signal packet.
In FIG. 7, the time stamp stamping unit 52 of the transmission side NE 50 adds a time stamp at the time of transmission to the main signal packet, and the time stamp reading unit 62 of the reception side NE 60 reads the time stamp to receive the stamping time Tx. The delay time is calculated by taking the difference from the time Rx. At this time, it is necessary to synchronize the time between the time stamp stamping unit 52 of the transmission side NE 50 and the time stamp reading unit 62 of the reception side NE 60. In this measurement, the delay time of the main signal packet itself can be directly measured, but time information is added to the main signal packet, so the bandwidth is compressed, the time stamp is added to each packet, and the processing load and delay increase. Can be considered. For example, regarding the increase in bandwidth, the bandwidth increase rate R (F) when the main signal packet of F [byte] is transferred through the MPLS-TP network is expressed by the following equation.
R (F) = (F + IFG + PA + SFD + L + MAC) / (F + IFG + PA + SFD) (2)

  Here, IFG is an interframe gap, PA is a preamble, SFD is Start of Frame Delimiter (frame start demarcation point), L is an MPLS-TP label, and MAC is a MAC header size.

  From equation (2), the smaller the frame size, the greater the proportion of overhead added in the MPLS-TP network, and the bandwidth increase rate R (F) increases. Therefore, the bandwidth is most required when 64 [byte], which is the minimum frame size, is input at the full rate. For example, if the MPLS-TP label is L = 12 [bytes], the relationship between the frame size and the necessary bandwidth is as shown in FIG. The number of packets transmitted per second over a path with a transmission rate of 1 [Gbps] is about 1.95 million when the minimum size is 64 [bytes]. Therefore, when the time stamp is 8 [bytes], the bandwidth occupied by the time stamp capacity is about 0.12 [Gbit] per second, and it is clear that this leads to bandwidth compression.

ITU-T G.8013 / Y.1731 (07/2011)

  In the method shown in FIG. 6, since the delay measurement packet by OAM is used, the number of samples is small, and an accurate delay time and delay fluctuation cannot be obtained for the main signal packet.

  In the method shown in FIG. 7, the delay time of the main signal packet can be measured. However, since a time stamp is added to the main signal packet, there is a problem that band compression and processing delay increase.

  An object of the present invention is to provide a delay measurement method and a delay measurement system capable of accurately grasping the delay time and delay fluctuation of a packet while avoiding band compression and measuring the delay distribution of the packet.

  A first invention is a delay measurement method for measuring a delay time of a main signal packet transferred via a packet switching network between a transmission side NE and a reception side NE in which time synchronization is established. The NE transmits a reference packet in which an ID for distinguishing a main signal packet to be transmitted in a certain time as one group is transmitted while sequentially transmitting the main signal packet, the transmission time of the reference packet, and the reference packet A first step of measuring a transmission time difference between main signal packets to be transmitted thereafter, and a receiving side NE measuring a reception time difference between main signal packets received after the reference packet and a reception time of the reference packet. Each of the transmission time difference and the reception time difference between the main packet packet following the reference packet and the transmission time and reception time of the reference packet And a third step of calculating the delay time of each main signal packet from over data.

  In the delay measurement method of the first invention, the third step includes the transmission time of the reference packet from the transmission side NE and the transmission time difference data between main signal packets transmitted after the reference packet, and the reference packet from the reception side NE. The reception time and each reception time difference between main signal packets received after the reference packet are transferred to the control device, and the control device calculates each delay time of the main signal packet.

  In the delay measurement method of the first invention, the third step transfers each data of the transmission time difference between the main signal packets transmitted after the reference packet and the transmission time of the reference packet from the transmission side NE to the reception side NE, The receiving side NE uses the data transferred from the transmitting side NE, the reception time of the reference packet, and the reception time difference between the main signal packets received after the reference packet to calculate the delay time of the main signal packet. calculate.

  In the delay measurement method according to the first aspect of the invention, the third step is a mismatch between the number of main signal packets transmitted from the transmitting side NE and the number of received main signal packets received at the receiving side NE for each group. Or when the number of data of transmission time difference between main signal packets transmitted from the transmitting side NE and the number of data of reception time difference between main signal packets received at the receiving side NE are not equal to each other, The delay time of the signal packet is not calculated.

  A second invention is a delay measurement system for measuring a delay time of a main signal packet transferred through a packet switching network between a transmission side NE and a reception side NE in which time synchronization is established. The NE transmits a reference packet in which an ID for distinguishing a main signal packet to be transmitted in a certain time as one group is transmitted while sequentially transmitting the main signal packet, the transmission time of the reference packet, and the reference packet The receiver NE includes a first means for measuring a transmission time difference between main signal packets to be transmitted thereafter, and the receiving side NE measures a reception time difference between main signal packets received after the reference packet and a reception time of the reference packet. A transmission time difference and a reception time difference between the transmission time and reception time of the reference packet and the main signal packet following the reference packet. A third means for calculating a delay time of each main signal packet from each data.

  In the delay measurement system of the second invention, the third means is a control device connected to the transmission side NE and the reception side NE via a control line, and the control device transmits the reference packet from the transmission side NE. And each data of transmission time difference between main signal packets transmitted after the reference packet and each data of reception time difference between main signal packets received after the reference packet and the reception time of the reference packet from the receiving side NE are transferred to the control device. The control device calculates each delay time of the main signal packet.

  In the delay measurement system of the second invention, the third means is provided in the reception side NE, and the reception side NE transmits the transmission time of the reference packet from the transmission side NE and transmission between main signal packets transmitted after the reference packet. Each data of the time difference is transferred to the receiving side NE, and each data of the receiving time difference between each data transferred from the transmitting side NE and the main signal packet received after the reference packet at the receiving side NE. Is used to calculate each delay time of the main signal packet.

  In the delay measurement system according to the second invention, the third means compares the number of transmissions of the main signal packet transmitted from the transmission side NE and the reception number of the main signal packet received at the reception side NE for each group, and does not agree. Or when the number of data of transmission time difference between main signal packets transmitted from the transmitting side NE and the number of data of reception time difference between main signal packets received at the receiving side NE are not equal to each other, In this configuration, the delay time of the signal packet is not calculated.

  According to the present invention, the delay time of each main signal packet can be calculated from the transmission time and reception time of the reference packet and the data of the transmission time difference and the reception time difference between the main signal packets. Each data of the transmission time difference and the reception time difference has a very small capacity as compared with the time data, so that it is possible to avoid the band compression of the control line for transferring the data. In addition, since time information (time stamp) is not added to the main signal packet, it is possible to reduce bandwidth compression and processing load due to delay measurement.

It is a figure which shows the structure of Example 1 of the delay measurement system of this invention. It is a figure which shows the relationship between a reference | standard packet and a main signal packet (no packet loss). It is a figure which shows the relationship between transmission / reception time and time difference data, and delay time. It is a figure which shows the structure of Example 2 of the delay measurement system of this invention. It is a figure which shows the relationship between a reference | standard packet and a main signal packet (with packet loss). It is a figure explaining the method of the delay time measurement by OAM. It is a figure explaining the method of the delay time measurement using the time stamp of the main signal packet. It is a figure which shows the relationship between a frame size and a required band.

FIG. 1 shows the configuration of Embodiment 1 of the delay measurement system of the present invention.
In FIG. 1, a transmission side NE 10 and a reception side NE 20 are connected via a packet switching network (for example, an MPLS network), and time synchronization is established. The transmission side NE 10 includes a main signal packet transmission unit 11, a reference packet transmission unit 12, and a transmission time / time difference data accumulation / transmission unit 13. The reception side NE 20 includes a main signal packet reception unit 21, a reference packet reception unit 22, and a reception time / time difference data accumulation / transmission unit 23. A control device 30 having a delay calculation unit 31 is connected to the transmission side NE10 and the reception side NE20 via a control line.

The main signal packet transmitter 11 of the transmission side NE 10 sequentially transmits the main signal packets input to the transmission side NE 10 to the network. The reference packet transmission unit 12 transmits a reference packet in which an ID for distinguishing main signal packets transmitted at a predetermined time as one group is set to the network. The example shown in FIG. 2 (1) shows that N _i main signal packets following a reference packet of group i (i is an integer equal to or greater than 1) are transmitted at a fixed time. The transmission time differences between the main signal packets of group i are Δt _i1 , Δt _i2 , Δt _{i3 ,.} Transmission time and time difference data storage / transmission unit 13 records the transmission time T _i of the reference packet group i, a transmission time difference Delta] t _ij between the main signal packet transmitted subsequent to the reference packet is recorded, the recording Data is transferred to the control device 30 via the control line. Here, j denotes a main signal packet groups i that is sent to a certain time, is an integer of 1 to N _i.

The main signal packet receiving unit 21 of the receiving side NE 20 receives a main signal packet arriving from the network. The reference packet receiving unit 22 identifies the ID of a packet that arrives from the network, and receives the reference packet. In the case of no packet loss shown in FIG. 2 (2), N ₁ group 1 main signal packets are received from the identification of the group 1 reference packet to the identification of the group 2 reference packet. Next, N ₂ main signal packets of group 2 are received. The reception time differences between the main signal packets of group i are Δr _i1 , Δr _i2 , Δr _i3 ,. The reception time / time difference data storage / transmission unit 23 records the reception time R _i of the reference packet, records the reception time difference Δr _ij between the main signal packets received following the reference packet, and stores each recorded data in the control line. Is transferred to the control device 30.

The present invention transmits a reference packet to which a main signal packet transmitted at a certain time is grouped and given an ID indicating its head, and the transmission time T _i of the reference packet at the transmission side NE 10 and the reference packet at the reception side NE 20 The delay time of the main signal packet is calculated from the reception time R _i , the transmission time difference Δt _ij and the reception time difference Δr _ij between the main signal packets of each group.

  In the first embodiment shown in FIG. 1, the transmission / reception time and main signal of the reference packet stored in the transmission time / time difference data storage / transmission unit 13 of the transmission side NE 10 and the reception time / time difference data storage / transmission unit 23 of the reception side NE 20 The case where the data amount of the transmission / reception time difference between packets can be transferred in the bandwidth of the control line between the transmission side NE10 and the reception side NE20 and the control device 30 is shown, and each data is processed in the following procedure.

The transmission time / time difference data accumulation / transmission unit 13 and the reception time / time difference data accumulation / transmission unit 23 include a transmission time T _i of the reference packet and a transmission time difference Δt _ij between the main signal packets, and a reception time R _{i of the} reference packet. Data of the reception time difference Δr _ij between the main signal packets is transferred to the control device 30.

The delay calculation unit 31 of the control device 30 calculates the delay time of each main signal packet based on the transferred data. The delay time D _ik of the k-th main signal packet from the group i reference packet can be obtained from the following equation.
D _ik = (R _i + Δr _i1 + Δr _i2 +... + Δr _ik ) − (T _i + Δt _i1 + Δt _i2 +... + Δt _ik )
… (3)

For example, in the example of group 1 shown in FIG. 3 (1), the transmission time T ₁ of the reference packet is 12: 00: 00.000000, and the reception time R ₁ is 12: 00: 00.000020. The transmission time differences Δt _{11 to} Δt ₁₃ between the main signal packets are 5, 7, and 8, and the reception time differences Δr _{11 to} Δr ₁₃ are ₁₃ , 15, 2. Therefore, the delay time of the reference packet of group 1 is 20 μs, and the delay times (μ seconds) of the first to third main signal packets from the reference packet are D ₁₁ = 28, D ₁₂ = 36, D ₁₃ = 30. It becomes.

  The delay calculation unit 31 of the control device 30 calculates the delay time of each main signal packet for each group, totals the frequency for each delay time as shown in FIG. 3 (2), and is shown in FIG. 3 (3). Create a delay map like this.

When the transmission time and reception time of each main signal packet are measured in microsecond order, each time difference data of the transmission time difference Δt _ij and the reception time difference Δr _ij is about one digit or two digits, and the transmission time and the reception time are The amount of data can be reduced compared with the case of transferring as data.

  For example, when a packet with a packet size of 64 [bytes] is transferred at a full rate in a bandwidth of 1 [Gbps], if all the transmission time and reception time of each main signal packet are recorded, the data amount is about 300 [Mbps]. However, the data amount at the same rate can be reduced to 30 [Mbps] by reducing the number of digits by recording the time difference data. Furthermore, when this is compressed in, for example, the Zip format, the capacity can be reduced to 30 [kbps].

  By the way, when the transmission / reception time of the reference packet stored in the transmission side NE10 and the reception side NE20 and the data amount of the transmission / reception time difference between the main signal packets exceed the bandwidth of the control line between the transmission side NE10 and the reception side NE20, or The case of occupying most of the bandwidth is handled by the configuration of the second embodiment shown in FIG.

In FIG. 4, the transmission time / time difference data accumulation / transmission unit 13 of the transmission side NE 10 stores the data of the transmission time T _i of the reference packet and the transmission time difference Δt _ij between the main signal packets using the main signal band. It is mixed with the main signal packet and transferred to the delay calculation unit 24 of the receiving side NE 20.

The delay calculation unit 24 receives each data received from the transmission time / time difference data accumulation / transmission unit 13 of the transmission side NE 10 and the reception time R of the reference packet accumulated in the reception time / time difference data accumulation / transmission unit 23 of the reception side NE 20. Using each data of _i and the reception time difference Δr _ij between the main signal packets, the delay time of each main signal packet is calculated, and a delay distribution diagram as shown in FIGS. 3 (2) and 3 (3) is created. The delay distribution map created by the delay calculation unit 24 is transferred to the control device 30 via the control line.

  In this method, since only the delay distribution diagram is transferred to the control device 30, it is possible to avoid band compression in the control line.

  Next, a case where packet loss occurs due to an error of the main signal packet in the network will be described with reference to FIG.

The reference packet transmitter 12 of the transmission side NE 10 counts the number of main signal packets transmitted in a certain time after transmitting the reference packet, and sets the number in the reference packet of the next group. In the example illustrated in FIG. 5, the number N ₁ of main signal packets of group ₁ is set in the reference packet of group 2 subsequent to group ₁ .

The reference packet receiving unit 22 of the receiving side NE 20 counts the number of main signal packets received after receiving the reference packet until the next reference packet is received. In the example without packet loss shown in FIG. 2 (2), the number of received main signal packets N1 of group ₁ is counted. In the example shown in FIG. Therefore, the number of received main signal packets (N ₁ −1) is counted. Here, the number of main signal packets received in group 1 is compared with the number of main signal packets transmitted in group 1 set as the reference packet in group 2. If they match, all main signal packets in group 1 are compared. It can be confirmed that it has been received (example in FIG. 2), and in the case of mismatch, it can be detected that packet loss has occurred (example in FIG. 5).

For example, as in FIG. 5 (3), to the transmission number N ₁ of the main signal packet group 1, if the reception number (N ₁ -1), the packet loss has occurred in the main signal packet group 1 Can be detected.

Here, for example, the transmission time difference Δt ₁₂ = 7 and the reception time difference Δr ₁₂ = 17 in the second main signal packet of the group 1, but since the reception time difference is one missing second main signal packet, If applied to equation (3), the delay time of each subsequent main signal packet will be incorrect. However, since the main signal packet with packet loss cannot be specified here, if the number of transmissions of main signal packets and the number of receptions do not match, all data relating to the group is discarded. In this case, Example 1 shown in FIG. 1 and Example 2 shown in FIG.

In the configuration of the first embodiment shown in FIG. 1, the transmitting side NE 10 does not know that a packet loss has occurred, so the transmission time T _i of the reference packet of group _i and transmission between main signal packets to the control device 30. Each data of the time difference Δt _ij is transmitted. On the other hand, the receiving side NE 20 detects the packet loss of the main signal packet of group i, and therefore discards each data of the reception time R _i of the reference packet of group _i and the reception time difference Δr _ij between the main signal packets, The data is not transmitted to the control device 30. Thereby, the delay calculation unit 31 of the control device 30 does not calculate the delay time of each main signal packet of the group i.

In the configuration of the second embodiment in FIG. 4, the transmitting side NE 10 does not know that a packet loss has occurred, so the transmission time T _i of the reference packet of group _i and transmission between main signal packets to the receiving side NE 20. Each data of the time difference Δt _ij is transmitted. On the other hand, the receiving side NE 20 detects the packet loss of the main signal packet of group i, and therefore discards each data of the reception time R _i of the reference packet of group _i and the reception time difference Δr _ij between the main signal packets, The delay calculation unit 24 does not calculate the delay time of each main signal packet of group i.

Note that, in the control device 30 or the reception side NE20, the number of data of the transmission time difference Δt _ij between main signal packets for each group transmitted from the transmission side NE10 and the reception time difference Δr between main signal packets for each group in the reception side NE20. The number of data of _ij is compared, and if they match, there is no packet loss in the main signal packet of the group, and if they do not match, it can be determined that a packet loss has occurred. This determination is performed by the control device 30 in the configuration of the first embodiment in FIG. 1, and is performed by the delay calculation unit 24 of the receiving side NE 20 in the configuration of the second embodiment in FIG. In this case, it is not necessary to count the number of main signal packets, and there is no need to notify the number of transmissions of main signal packets in the previous group from the transmission side NE 10 to the reception side NE 20 via the reference packet.

10 Sender NE
11 Main signal packet transmission unit 12 Reference packet transmission unit 13 Transmission time / time difference data storage / transmission unit 20 Reception side NE
21 main signal packet receiving unit 22 reference packet receiving unit 23 reception time / time difference data accumulation / transmission unit 24 delay calculation unit 30 control device 31 delay calculation unit

Claims (8)

In a delay measurement method for measuring a delay time of a main signal packet transferred through a packet switching network between a transmission side NE and a reception side NE in which time synchronization is established,
The transmission side NE transmits a reference packet in which an ID for distinguishing the main signal packet to be transmitted at a predetermined time as one group is transmitted while sequentially transmitting the main signal packet, and the transmission time of the reference packet And a first step of measuring a transmission time difference between main signal packets transmitted after the reference packet;
The receiving side NE measures a reception time difference between the reception time of the reference packet and the main signal packet received after the reference packet;
And a third step of calculating a delay time of each main signal packet from each data of a transmission time difference and a reception time difference between main signal packets subsequent to the reference packet. A characteristic delay measurement method. The delay measurement method according to claim 1,
The third step includes the transmission time of the reference packet from the transmission side NE and the transmission time difference data between the main signal packets transmitted after the reference packet, and the reception time of the reference packet from the reception side NE. And a method of transferring each data of a reception time difference between the main signal packets received after the reference packet to a control device, and calculating each delay time of the main signal packet by the control device. The delay measurement method according to claim 1,
The third step transfers each data of the transmission time difference between the main signal packets transmitted after the reference packet and the transmission time difference of the reference packet from the transmission side NE to the reception side NE. Each delay of the main signal packet using each data transferred from the transmission side NE and each reception time difference between the reception time of the reference packet and the main signal packet received after the reference packet. A delay measurement method characterized by calculating time. The delay measurement method according to claim 1,
In the third step, the number of transmissions of the main signal packet transmitted from the transmission side NE for each group is compared with the number of receptions of the main signal packet received at the reception side NE. When the number of data of the transmission time difference between the main signal packets transmitted from the transmission side NE and the number of data of the reception time difference between the main signal packets received at the reception side NE are compared, and there is a mismatch, the main of the group A delay measurement method characterized by not calculating a delay time of a signal packet. In a delay measurement system for measuring a delay time of a main signal packet transferred through a packet switching network between a transmission side NE and a reception side NE in which time synchronization is established,
The transmission side NE transmits a reference packet in which an ID for distinguishing the main signal packet to be transmitted at a predetermined time as one group is transmitted while sequentially transmitting the main signal packet, and the transmission time of the reference packet And a first means for measuring a transmission time difference between main signal packets transmitted after the reference packet,
The receiving side NE includes second means for measuring a reception time difference between the reception time of the reference packet and the main signal packet received after the reference packet;
A third means for calculating a delay time of each main signal packet from each data of transmission time difference and reception time difference between the main signal packets following the reference packet and the transmission time and reception time of the reference packet; Characteristic delay measurement system. The delay measurement system according to claim 5, wherein
The third means is a control device connected to the transmitting side NE and the receiving side NE via a control line;
The control device includes: a transmission time of the reference packet from the transmission side NE and transmission time difference data between the main signal packets transmitted after the reference packet; a reception time of the reference packet from the reception side NE; A delay measurement system, wherein each data of a reception time difference between the main signal packets received after a reference packet is transferred to a control device, and each delay time of the main signal packet is calculated by the control device. . The delay measurement system according to claim 5, wherein
The third means is provided in the receiving side NE,
The receiving side NE transfers each data of the transmission time difference between the main signal packets transmitted after the reference packet and the transmission time of the reference packet from the transmitting side NE to the receiving side NE. , Each delay time of the main signal packet using each data transferred from the transmission side NE and each reception time difference between the reception time of the reference packet and the main signal packet received after the reference packet A delay measurement system characterized by calculating The delay measurement system according to claim 5, wherein
The third means compares the number of transmissions of the main signal packet transmitted from the transmission side NE for each group with the number of receptions of the main signal packet received at the reception side NE, or When the number of data of the transmission time difference between the main signal packets transmitted from the transmission side NE and the number of data of the reception time difference between the main signal packets received at the reception side NE are compared, and there is a mismatch, the main of the group A delay measurement system characterized in that the delay time of a signal packet is not calculated.

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