JP6007138B2 - Transmission system, transmission apparatus, and transmission quality detection method - Google Patents

Description

  The present invention relates to a technique for detecting signal degradation due to a failure occurring between transmission apparatuses or in a transmission system in a transmission system such as Ethernet (registered trademark).

  In recent years, traffic on the network continues to increase due to an increase in the capacity of mobile services and an increase in demand for distribution services such as video and audio. Against this backdrop, the transition from existing networks such as SDH (Synchronous Digital Hierarchy) / SONET (Synchronous Optical Network) to networks using IP (Internet Protocol) packets has been promoted. It is required to ensure the same communication quality as the / SDH network. However, there are the following differences in the transmission quality monitoring method between the SONET / SDH network and the packet network.

  In the signal degradation detection method in SONET / SDH, in order to monitor the transmission quality, the B1 / B2 byte in the section overhead of the SONET / SDH frame and the B3 byte in the path overhead are monitored for code errors (for example, Non-patent document 1).

  On the other hand, in Ethernet (registered trademark), error detection is performed by FCS (Frame Check Sequence) of a MAC frame (Media Access Control Frame). Further, in Ethernet (registered trademark) OAM (operations, administration, maintenance), a failure is detected by a CCM (Continuity Check Message) periodically transmitted to switch between a standby system and an active system (for example, patents). Reference 1). Alternatively, in a transmission method using CEP (Circuit. Emulation over Packet) that packetizes a SONET / SDH signal, the lack of frames is monitored by monitoring the continuity of sequence numbers (for example, non-patent) Reference 2).

JP 2000-174815 A

ITU-T G.707 / Telcordia GR-253-CORE RFC 4842 on Synchronous Optical Network / Synchronous Digital Hierarchy (SONET / SDH) Circuit Emulation over Packet (CEP) (http://datatracker.ietf.org/doc/rfc4842)

  In normal SDH, the frame size, main signal speed, etc. are determined, and B1 / B2 / B3 bytes are added within the overhead of all frames, so it is possible to detect the degree of signal degradation by calculating the BER. Yes. And the signal degradation state can be made into one of the failure factors at the time of performing path switching in a ring network.

  However, in a transmission system such as Ethernet (registered trademark), if the frame is discarded due to failure detection due to missing of the monitoring frame (CCM), missing frame monitoring in CEP, or FCS error of the main signal frame, how much It cannot be detected whether the signal is degraded. Further, there is a problem that FCS error cannot be detected when all the main signal frames are missing.

  In particular, transmission systems using Ethernet (registered trademark) have become widespread, and communication quality equivalent to SONET / SDH has been required. However, the method of monitoring signal degradation like SONET / SDH is The current situation is not yet fully defined.

  In view of the above problems, an object of the present invention is to provide a transmission system, a transmission apparatus, and a transmission quality detection method capable of ensuring communication quality equivalent to SONET / SDH even in a transmission system such as Ethernet (registered trademark). .

In the transmission system according to the present invention, the transmission apparatus on the transmission side assigns the added value of the frame length of the frame to be transmitted continuously in time and the sequence number given to the frame as the sequence number of the next frame to be sent. The transmission apparatus on the receiving side receives the frame to which the sequence number is assigned, calculates the expected value by adding the frame length of the frame and the sequence number of the frame, and have a sequence number monitoring unit for detecting a difference between the sequence number of the frame received with the expected value as a missing frame length, the sequence number monitoring unit, preset first sum of the frame length that arrived within the monitoring time And the second total value of missing frame lengths that did not arrive within the monitoring time, (first total value) / ((first total value) + (second total If the calculated value of)) exceeds a predetermined threshold value, and detects the deterioration of the signal quality.

The transmission apparatus according to the present invention includes a sequence number giving unit that gives an addition value of a frame length of a frame transmitted continuously in time and a sequence number given to the frame as a sequence number of a frame to be transmitted next; Receives a frame with a sequence number, adds the frame length of the frame and the sequence number of the frame to obtain the expected value, and calculates the difference between the sequence number and the expected value of the next frame to be received as the missing frame length have a sequence number monitoring section for detecting a sequence number monitoring unit, a preset first sum of the frame length that arrived within the monitoring time, the missing frame length did not arrive within the monitoring time the When the calculated value of (first total value) / ((first total value) + (second total value)) exceeds a preset threshold value using two total values And detecting the deterioration of signal quality.

In the transmission quality detection method according to the present invention, the transmission apparatus on the transmission side transmits a sequence of frames in which an addition value between a frame length of a frame to be transmitted continuously in time and a sequence number assigned to the frame is transmitted next was given as number, the transmission apparatus on the reception side successively in time received to Resid sequence number is the sum of the frame length and the sequence number of the frame of the frame granted seeking expected value, then detecting a difference between the sequence number and the expected value of the frame to be received as a missing frame length, a preset first sum of the frame length that arrived within the monitoring time, the missing frame has not arrived within the monitoring time Signal quality degradation when the calculated value of (first total value) / ((first total value) + (second total value)) exceeds a preset threshold value using the second total value of the length to detect And wherein the door.

  The transmission system, the transmission apparatus, and the transmission quality detection method according to the present invention can ensure communication quality equivalent to SONET / SDH even in a transmission system such as Ethernet (registered trademark).

It is a figure which shows the ring network example of SONET / SDH. It is a figure which shows the example of an Ethernet (trademark) MAC frame. It is a figure which shows the example of CC function of Ethernet (trademark) OAM. It is a figure which shows the header format example of a CEP frame. It is a figure showing an example of transmission system 100 concerning this embodiment. It is a figure which shows an example of the provision rule of sequence number SN. It is a figure which shows the example of provision of the sequence number SN with respect to an input frame. It is a figure which shows the flowchart which shows the process example of SN monitoring. It is a figure which shows an example of the calculation method of missing frame length and expected value. It is a figure which shows the example of main signal degradation generation | occurrence | production in a ring network. It is a figure which shows an example of the SD detection of a section and a path | pass.

  Hereinafter, embodiments of a transmission system, a transmission apparatus, and a transmission quality detection method according to the present invention will be described in detail with reference to the drawings.

  First, a transmission quality monitoring method in the current SONET / SDH and Ethernet (registered trademark) will be described so that the characteristics of the quality detection method in the transmission system 100 according to the present embodiment can be understood well.

  As explained briefly in the prior art, SONET / SDH uses the B1 / B2 byte in the section overhead of the SONET / SDH frame and the B3 byte in the path overhead to monitor the transmission quality in order to monitor the transmission quality. Is going. As this monitoring method, a monitoring method called BIP (Bit Interleaved Parity) is adopted. In this method, the transmission side inserts the calculation result in the specified calculation range of the SONET / SDH frame into the B1 / B2 / B3 byte of the next frame, and the reception side stores the calculation result stored in B1 / B2 / B3 and the received frame. To compare the transmission quality. A BER (Bit Error Rate) is calculated by this monitoring, and if the BER is equal to or higher than the threshold defined in ITU-TG.806, it can be determined that the transmission line is faulty or the transmission line quality is deteriorated.

  The SONET / SDH ring network redundancy switching system is defined by ITU and the like. For example, in the SONET / SDH ring network of FIG. 1, when a transmission line failure occurs in a section between the transmission device b and the transmission device d, the main signal is interrupted in the transmission device d (according to the signal degradation detection method described above). Detects deterioration of main signal. Then, the ring network path can be switched from the active system to the standby system so that the main signal is not cut off.

  On the other hand, an error detection method for MAC frames used in Ethernet (registered trademark) for packet transmission is defined in the IEEE 802.3 standard. As shown in FIG. 2, the result of the frame error check checksum calculation for the range from the DA of the MAC frame to the user data (including PAD) is stored in an FCS (Frame Check Sequence). The checksum calculation uses a 32-bit CRC (Cyclic Redundancy Check) method. At the time of transmission, the calculation result is given in the FCS of the MAC frame, and the same calculation is performed on the receiving side to determine whether both values match. judge. If both values do not match, the MAC frame is regarded as having a bit error during transmission, and the MAC frame is discarded.

  Further, a failure detection method using Ethernet (registered trademark) OAM (Operation Administration and Maintenance) is defined by ITU-T Y.1731 or IEEE 802.1ag. OAM is a method for providing a means of maintenance management, and performs failure detection and failure notification using the CC (Continuity Check) function defined by OAM. For example, in the CC function, as shown in FIG. 3, MEP (Maintenance End Point) is set at the A end point and the Z end point in the packet ring. Then, CCM (CC Message) is periodically sent from the MEP at one end, and the continuity of the CCM is constantly monitored by the MEP at the other end, for example, between MEP and MEP (for example, from the A end point to the Z end point) It is possible to check connectivity and to detect erroneous connections.

  Further, in the ring network redundancy switching method in Ethernet (registered trademark), the MEP at one end detects a failure when the CCM that has been flowing regularly in the main signal disconnection or the CC function of OAM is interrupted. Then, the transmission quality of the main signal can be maintained by switching the ring network path from the active system to the standby system.

  However, in Ethernet (registered trademark), the frame size is not fixed when the frame is discarded due to failure detection due to failure of the monitoring frame (CCM) as described above or FCS error of the main signal frame. Cannot detect signal degradation. In addition, there is a problem that an FCS error cannot be detected when all the main signal frames are missing.

  Furthermore, in the failure detection method by monitoring the sequence number of CEP (Circuit Emulation over Packet) that packetizes the SONET / SDH signal, the sequence number of the packet is assigned to the Sequence Number in the header format of the CEP frame as shown in FIG. . Then, by monitoring the continuity of the sequence numbers, it is possible to monitor missing frames. However, in Ethernet (registered trademark), if there is a bit error, the frame is discarded, and there is a problem that there is no method for grasping the current accurate BER (Bit Error Rate).

  In contrast, in SONET / SDH, the frame size, main signal speed, etc. are determined, and B1 / B2 / B3 bytes are added within the overhead of all frames, so BER can be calculated and signal degradation can be detected. . Then, it is possible to relieve the main signal by switching the link according to the signal deterioration.

  As described above, Ethernet (registered trademark) does not sufficiently define a method for monitoring signal deterioration similar to SONET / SDH, although communication quality equivalent to SONET / SDH is required.

Therefore, in the transmission system 100 according to the present embodiment, communication quality equivalent to SONET / SDH can be ensured even in a transmission system such as Ethernet (registered trademark).
[Transmission system 100 according to this embodiment]
Hereinafter, the transmission system 100 according to the present embodiment will be described in detail.

  In the example of FIG. 5, in the transmission system 100 according to the present embodiment, the transmission apparatus 101a and the transmission apparatus 101b are connected by a 10 Gbps ring network of the active system and the standby system. Then, on the transmission apparatus 101a side, a 1 Gbps Ethernet (registered trademark) frame (hereinafter referred to as 1GE) is added / dropped, and a 10 Gbps Ethernet (registered trademark) frame (hereinafter referred to as 10GE) is included in the ring network. Is transmitted to. On the other hand, on the transmission apparatus 101b side, addition / drop is performed from the 10GE ring network to the 1 Gbps (1GE) transmission path. In addition, the 10GE ring network has a redundant configuration, and when the operation system fails, the 10GE ring network is switched to the standby system to rescue the disconnection of the main signal.

  Here, in the following description, when the matters common to the transmission apparatus 101a and the transmission apparatus 101b are described, the alphabet symbol at the end of the code is omitted and the transmission apparatus 101 is represented. In addition, when a specific transmission apparatus 101 is indicated, an alphabetic symbol is added to represent the transmission apparatus 101, for example, as a transmission apparatus 101a. Other blocks with the same name (such as the SN assigning unit 301 and the SN monitoring unit 302) are also represented by the same rule.

  Next, a description will be given of a method of performing SD detection for confirming the degree of deterioration in the transmission apparatus 101 on the reception side when an Ethernet (registered trademark) signal deteriorates (SD: Signal Dagrade) due to a transmission path failure.

  In FIG. 5, the transmission apparatus 101a includes a GE_I / F 201a, a 10GE_I / F 202a, and a 10GE_I / F 202b. The GE_I / F 201a transmits and receives user frames to and from user devices (not shown) at a transmission rate of 1 Gbps. The 10GE_I / F 202a transmits / receives a frame at a transmission rate of 10 Gbps to / from the transmission apparatus 101b via an active route. Similarly, the 10GE_I / F 202b transmits / receives a frame to / from the transmission apparatus 101b via a backup path at a transmission rate of 10 Gbps.

  On the other hand, the transmission apparatus 101b includes a GE_I / F 201b, a 10GE_I / F 202c, and a 10GE_I / F 202d. The GE_I / F 201b transmits and receives user frames to and from user devices (not shown) at a transmission rate of 1 Gbps. The 10GE_I / F 202c transmits and receives a frame at a transmission rate of 10 Gbps to and from the transmission apparatus 101a via an active route. Similarly, the 10GE_I / F 202d transmits / receives a frame to / from the transmission apparatus 101a via a backup path at a transmission rate of 10 Gbps.

  Here, the user frame is transmitted and received between the transmission apparatus 101a and the transmission apparatus 101b. In the description of FIG. 5, a case where the user frame is transmitted from the one-way transmission apparatus 101a to the transmission apparatus 101b will be described. To do.

  The GE_I / F 201a of the transmission apparatus 101a that has received the user frame from the user apparatus assigns the sequence number SNa as the header information of the user frame by the SN assignment unit 301a (referred to as an SN header in the figure). This sequence number SNa is used for SD detection of a path until it is output again as a 1GE user frame by the GE_I / F 201b of the transmission apparatus 101b.

  The frame to which the sequence number SNa is assigned by the GE_I / F 201a of the transmission apparatus 101a is converted into a 10GE frame by the active 10GE_I / F 202a on the active side. At this time, the SN assigning unit 301b further assigns a sequence number SNb to the frame to which the sequence number SNa is added as header information, and transmits the frame to the transmission apparatus 101b side via the 10GE operating system path.

  On the other hand, the transmission apparatus 101b receives the frame to which the sequence number SNb and the sequence number SNa are assigned from the transmission apparatus 101a by 10GE_I / F 202c. Then, the SN monitoring unit 302a monitors the sequence number SNb, and performs SD detection of the section between the 10GE_I / F 202a and the 10GE_I / F 202c using the sequence number SNb. Thereafter, a frame having the sequence number SNa from which the sequence number SNb is removed as header information is output to the GE_I / F 201b. The GE_I / F 201b monitors the sequence number SNa with the SN monitoring unit 302c. Then, the user frame from which the sequence number SNa is removed is output to the 1GE transmission line.

  In this way, the user frame is transmitted from the transmission apparatus 101a connected through the redundant path to the transmission apparatus 101b.

  In FIG. 5, when the operation system is switched to the standby system, a 10GE signal is transmitted and received between the 10GE_I / F 202b of the transmission apparatus 101a and the 10GE_I / F 202d of the transmission apparatus 101b. Here, the SN adding unit 301c of the 10GE_I / F 202b assigns the sequence number SNb and transmits it. Then, the SN detection unit 302b of the 10GE_I / F 202d performs SD detection of the section between the 10GE_I / F 202b and the 10GE_I / F 202d using the sequence number SNb. Thereafter, a frame having the sequence number SNa from which the sequence number SNb is removed as header information is output to the GE_I / F 201b. The GE_I / F 201b monitors the sequence number SNa with the SN monitoring unit 302c. Then, the user frame from which the sequence number SNa is removed is output to the 1GE transmission line.

  In this way, the user frame is transmitted from the transmission apparatus 101a connected through the redundant path to the transmission apparatus 101b.

  Here, a rule for assigning the sequence number SN will be described with reference to FIG. In the example of FIG. 6, the header size to which the sequence number SN is assigned is, for example, 4 bytes, but may be other than 4 bytes. The insertion position of the header including the sequence number SN is assumed to be the beginning of the input frame, but may be other than the beginning.

  The sequence number SN is generated by adding the frame length of the previous frame to the sequence number SN of the previous frame. For example, if the sequence number SN of the current frame is 50 and the frame length is 100 bytes, the sequence number SN of the next frame is 150. Note that the initial value of the sequence number SN is 1. FIG. 6 is an example, and the initial value of the header size, header insertion position, or sequence number SN may be set to an arbitrary value. Here, the frame length may be the total frame length including the header length of the sequence number SN, or may be the frame length of the user frame not including the header length.

  Next, an example of assigning the sequence number SN to frames that are continuously input in time will be described with reference to FIG.

  The example of FIG. 7 is a diagram showing a state in which a sequence number SN is assigned when a user frame has a length of 100 bytes, 200 bytes, 500 bytes, and 500 bytes, and the frames flow from the right side to the left side of the page. The initial value of the sequence number SN is 1.

  In FIG. 7, the first frame 401 has a frame length of 100 bytes and a sequence number SN of “1” (initial value). The sequence number SN of the second frame 402 is “101” obtained by adding the sequence number SN “1” of the first frame 401 and the frame length “100”. Similarly, the sequence number SN of the third frame 403 is “301” obtained by adding the sequence number SN “101” of the second frame 402 and the frame length “200”. Further, the sequence number SN of the fourth frame 404 is “801” obtained by adding the sequence number SN “301” of the third frame 403 and the frame length “500”.

  Here, an example of calculating the sequence number SN when the frame 402 is missing is shown.

  (1) Since the sequence number SN assigned to the received frame 401 is “1”, the expected value of the next received frame is updated to 1 + 100 = 101.

  (2) The frame 402 is not reached due to some failure.

  (3) Since the sequence number SN assigned to the received frame 403 is “301”, the missing frame length is 200 bytes (the frame length of (2)) from the difference from the expected value “101” obtained in (1). And can be calculated. In addition, the expected value of the next received frame is updated to 301 + 500 = 801.

  (4) Since the sequence number SN assigned to the received frame 404 is “801”, it matches the expected value “801” obtained in (3), and it is determined that there is no omission. Then, the expected value of the next received frame is updated to 801 + 500 = 1301.

  In this way, since the frame length of the previous frame and the addition value of the sequence number SN are used as header information of frames transmitted continuously in time, even if the frame is discarded, the length of the discarded frame (missing Frame length). If the header length of sequence number SN is not included in the frame length, for example, a predetermined header length (4 bytes or the like) may be added separately to obtain a missing frame length.

  Next, the process for obtaining the missing frame length will be described with reference to the flowchart of FIG. Note that the expected value of the sequence number SN of the first frame is determined in advance, for example, the initial value of the expected value = 1.

  (Step S101) The SN monitoring unit 302 reads the frame length and sequence number SN of the arrived frame.

  (Step S102) The SN monitoring unit 302 determines whether or not the sequence number SN read in step S101 matches the expected value. If the sequence number SN matches the expected value, the process proceeds to step S104. If the sequence number SN does not match, the process proceeds to step S103.

  (Step S103) The SN monitoring unit 302 integrates the missing frame length. Here, a method for integrating the missing frame length will be described with reference to FIG. In FIG. 9, the missing frame length is accumulated by subtracting the expected value from the sequence number SN of the received frame as the missing frame length. For example, in FIG. 7 described above, when the frame 402 is missing and the third frame 403 is received, the sequence number SN of the received frame is “301”. However, since the expected value is the expected value “101” of the frame 402 received second, (301−101) = 200 bytes is obtained as the missing frame length. Further, when the frame 402 and the frame 403 are continuously lost and the frame 404 is received after the frame 401, the sequence number SN of the received frame is “801”. However, since the expected value is the expected value “101” of the frame 402 that is received second, (801-101) = 700 bytes is obtained as the missing frame length. The missing frame length of 700 bytes matches the integrated value of the frame lengths of the missing frame 402 (200 bytes) and frame 403 (500 bytes).

  (Step S104) The SN monitoring unit 302 updates the expected value of the next frame to be received. Here, an expected value updating method will be described with reference to FIG. In FIG. 9, the expected value of the sequence number SN of the next frame to be received is a value obtained by adding the frame length of the received frame to the sequence number SN of the current received frame acquired in step S101. For example, in FIG. 7 described above, the expected value of the frame 403 to be received next to the frame 402 is the sequence number SN “101” of the current frame 402 set to the frame length “200 (Byte)” of the received frame. The added value is “301”.

  In this way, the SN monitoring unit 302 determines whether or not the sequence number SN given to the received frame matches the expected value every time a frame arrives. If the expected value does not match, the difference value between the received frame sequence number SN and the expected value can be calculated as the missing data length, so that the missing frame length can be accurately known instead of the number of missing frames as in the prior art. And SD detection like SONET / SDH becomes possible.

[Example of application to a ring network]
Next, an example in which the transmission system 100 according to the present embodiment is applied to a 10 Gbps (10 GE) ring network will be described. The transmission system 100 shown in FIG. 10 connects a transmission apparatus 101a and a transmission apparatus 101b that terminate a main signal of 1 Gbps (1GE) through a ring network 400 of 10 Gbps (10GE). The ring network 400 has two redundant paths of an operation system 401 and a standby system 402. In the operation system 401, the transmission device 101c and the transmission device 101d are arranged as relay devices between the transmission device 101a and the transmission device 101b. In the standby system 402, a transmission device 101e is arranged as a relay device between the transmission device 101a and the transmission device 101b. Further, the five transmission apparatuses 101 included in the transmission system 100, that is, the transmission apparatus 101a, the transmission apparatus 101b, the transmission apparatus 101c, the transmission apparatus 101d, and the transmission apparatus 101e, are connected to the monitoring control apparatus 403 via the monitoring control network and are in operation. Status monitoring and control are performed. For example, the monitoring control device 403 performs control such as receiving an alarm notifying the abnormality from each transmission device 101 or switching the route of the ring network 400 from the active system 401 to the standby system 402.

  In FIG. 10, the same reference numerals as those in FIG. The difference between FIG. 10 and FIG. 5 is that a transmission device 101c, a transmission device 101d, and a transmission device 101e are arranged in the ring network 400 as relay devices.

  In FIG. 10, the transmission apparatus 101a assigns the sequence number SNa to the received user frame by the SN assignment unit 301a of the GE_I / F 201a as described in FIG. Further, the SN adding unit 301b of the 10GE_I / F 202a assigns the sequence number SNb and transmits it to the operational system 401 of the ring network 400. Then, the transmission apparatus 101c of the relay apparatus receives the frame to which the sequence number SNb and the sequence number SNa are assigned from the transmission apparatus 101a by 10GE_I / F 251a. The sequence number SNb is monitored by the SN monitoring unit 302d, and the SD detection of the section between the 10GE_I / F 202a and the 10GE_I / F 251a is performed by the sequence number SNb. Further, a frame using the sequence number SNa from which the sequence number SNb is removed as header information is output to the 10GE_I / F 252a, and the SN addition unit 301d assigns the sequence number SNc again to the transmission device 101d on the ring network 400.

  The transmission apparatus 101d of the relay apparatus receives the frame to which the sequence number SNc and the sequence number SNa are assigned from the transmission apparatus 101c with 10GE_I / F 251b. Then, the SN monitoring unit 302e monitors the sequence number SNc, and performs SD detection of the section between the 10GE_I / F 252a and the 10GE_I / F 251b using the sequence number SNc. Thereafter, a frame having the sequence number SNa from which the sequence number SNc is removed as header information is output to the 10GE_I / F 252b, and the SN number is added again by the SN adding unit 301e and transmitted to the transmission apparatus 101b via the ring network 400. .

  The transmission apparatus 101b receives the frame to which the sequence number SNd and the sequence number SNa are assigned from the transmission apparatus 101d with 10GE_I / F 202c. Then, the sequence number SNd is monitored by the SN monitoring unit 302a, and the SD detection of the section between the 10GE_I / F 252b and the 10GE_I / F 202c is performed by the sequence number SNd. Thereafter, a frame having the sequence number SNa from which the sequence number SNd is removed as header information is output to the GE_I / F 201b. The GE_I / F 201b monitors the sequence number SNa with the SN monitoring unit 302c, and performs SD detection of the path between the transmission apparatus 101a and the transmission apparatus 101b with the sequence number SNa. Then, the user frame from which the sequence number SNa is removed is output to the 1GE transmission line.

  In this way, the user frame is transmitted from the transmission apparatus 101a connected through the redundant path to the transmission apparatus 101b.

  Here, when signal degradation occurs due to some factor (such as a temporary failure of the optical fiber) in the path between the transmission device 101c and the transmission device 101d (signal degradation occurrence point 404 in FIG. 10), the signal degradation occurrence point At 404, the frame being transmitted is lost. In this case, according to the SD detection method described above, the SN monitoring unit 302e of the 10GE_I / F 251b of the transmission apparatus 101d performs SD detection of the section between the transmission apparatus 101c and the transmission apparatus 101d using the sequence number SNc, and is missing. You can know the frame length. Then, an SD monitoring time (Ts) and an SD detection threshold (Sd) are set in advance, and the SD detection value (Sdet) is calculated using the integrated value of the missing frame length during the SD monitoring time and the arrival frame length. calculate. When the SD detection value (Sdet) during the SD monitoring time exceeds the SD detection threshold (Sd), an alarm is notified to the monitoring control device 403. As a result, the monitoring control apparatus 403 can instruct each transmission apparatus 101 forming the ring network 400 to switch the path from the active system 401 to the standby system 402.

  When the path to the standby system 402 is switched, the transmission apparatus 101a transmits a frame to the transmission apparatus 101b via the transmission apparatus 101e of the relay apparatus. Even in this case, the 10GE_I / F 202b of the transmission apparatus 101a assigns the sequence number SNb by the SN assigning unit 301c and transmits it to the standby system 402 of the ring network 400. Then, the transmission apparatus 101e of the relay apparatus receives the frame to which the sequence number SNb and the sequence number SNa are assigned from the transmission apparatus 101a by 10GE_I / F 251c. Then, the SN monitoring unit 302f monitors the sequence number SNb, and performs SD detection of the section between the 10GE_I / F 202b and the 10GE_I / F 251c using the sequence number SNb. Thereafter, a frame having the sequence number SNa from which the sequence number SNb is removed as header information is output to the 10GE_I / F 252c, and the sequence number SNc is assigned again by the SN assigning unit 301f and transmitted to the transmission apparatus 101b via the ring network 400. .

  In this way, when signal degradation occurs in the operational system 401, SD detection can be performed with high accuracy, so that the path is appropriately switched to the backup system 402 and the user frame is transmitted from the transmission apparatus 101a to the transmission apparatus 101b. be able to.

Next, the SD detection threshold will be described. As described above, since the missing frame length of the main signal can be calculated, the determination of SD detection can be SD detection when the following conditional expression is satisfied.
(Detection threshold) ≦ Σ (missing frame length within monitoring time) / (Σ (arriving frame length within monitoring time) + Σ (missing frame length within monitoring time)) (Expression 1)
Here, the detection threshold and the monitoring time can be arbitrarily set by the user. The non-delivery frame length is a value obtained by integrating the missing frame length of each frame within the monitoring time.

Next, a specific example in which SD detection is performed according to (Equation 1) will be described with reference to FIG. FIG. 11 is a diagram illustrating a state of a frame transmitted and received among the transmission apparatus 101c, the transmission apparatus 101d, and the transmission apparatus 101b illustrated in FIG. The same reference numerals as those in FIG. 10 denote the same elements. Here, it is assumed that the main signal is a signal having the following frame length and transmission rate. In practice, frames of various lengths are transmitted and received. In the following example, the frame length and the transmission rate are fixed so that the calculation is easy to understand.
・ Frame Length: 100Byte
・ Transmission rate (Bit Rate): 800Mbit / sec
Further, it is assumed that a monitoring frame (Ethernet (registered trademark) OAM CCM frame) is periodically sent between the transmission apparatuses 101a and 101b.

Furthermore, the user settings for SD detection are as follows.
-SD monitoring time setting: 10 sec
-SD detection threshold setting: 1.0 × 10 ^-6
SD monitoring between each section and between paths is performed with the above settings.

Here, the number of discarded frames determined to be SD detection will be described. Since the frame length of the main signal is 100 bytes and the transmission speed of the main signal is 800 Mbit / sec, the number of frames flowing per second is 1,000,000 frames. The number of discarded frames when the SD detection threshold setting (1.0 × 10 ⁻⁶ ) is exceeded is 11 frames or more in 10 seconds according to the following calculation using (Expression 1).
Substituting the above condition in correspondence with (detection threshold) ≤ Σ (missing frame length within monitoring time) / (Σ (arriving frame length within monitoring time) + Σ (missing frame length within monitoring time))
1.0 × 10 ^-6 ≤ (a × 100Byte) / ((1,000,000 × 10sec × 100Byte) + (a × 100Byte))
(1.0 × 10 ^-6 ) × ((1,000,000 × 10 sec × 100 Byte) + (a × 100 Byte)) ≤ (a × 100 Byte)
1,000 + (1.0 × 10 ^-6 ) × (a × 100 Byte) ≤ a × 100
From 1,000 ≤ a × (100 − (1.0 × 10 ^-4 ))
1,000 ≤ a × 99.9999.
The number of non-delivery frames per 10 sec for SD detection is a ≧ 11 (frames).

  Thus, by determining the threshold for SD detection, it is possible to perform SD detection with high accuracy corresponding to the frame length. In the above example, since the frame length is fixed, the amount of discarded data can be obtained if the number of discarded frames is known. However, in the case of Ethernet (registered trademark), the frame length is actually fixed. Therefore, the exact amount of data cannot be obtained from the number of discarded frames. On the other hand, in the present embodiment, since the data amount of the discarded frame can be known, it becomes possible to detect the error rate (SD detection) with high accuracy.

Next, the case where the method of this embodiment is used and the case where it is not used will be compared. First, in the example of FIG. 11, a case will be described in which the transmission apparatus 101c, the transmission apparatus 101d, and the transmission apparatus 101b apply the conventional method without assigning or monitoring the sequence number SN.
In case of performing error detection method (error detection by FCS) in Ethernet (registered trademark) MAC frame In this case, when a bit error in the frame occurs between the transmission apparatus 101c and the transmission apparatus 101d, the transmission apparatus 101d Detects an FCS error, the transmission apparatus 101d discards the frame and does not transmit it to the transmission apparatus 101b. For this reason, the transmission apparatus 101b cannot detect an FCS error by missing every frame. In this case, it can be used only for section error monitoring between the transmission apparatus 101c and the transmission apparatus 101d, and can be used for path error monitoring between the transmission apparatus 101c (or the transmission apparatus 101a in FIG. 10) and the transmission apparatus 101b. There is no problem. In addition, in the case of Ethernet (registered trademark) in which the frame length of the missing frame is not fixed, an accurate error rate cannot be known.
In the case of the failure detection method using Ethernet (registered trademark) OAM In FIG. 11, in the case of the failure detection method using Ethernet (registered trademark) OAM, the CCM frame is periodically sent from the transmission device 101c to the transmission device 101b. Can be detected by the transmission apparatus 101d. However, in the previous example, the number of frames that flow per second is 1,000,000 frames, whereas CCM frames are sent out every 3.3 ms in the OAM standard, so 3000 frames in 10 seconds (300 frames in 1 second) Only a degree is sent out. For this reason, when SD detection is performed when about 11 non-delivery frames occur in 10 seconds, it is probabilistic that as many as 11 CCM frames are lost in 10 seconds. In addition, in order to prevent erroneous detection, there is a problem that the probability of detection is further reduced when the transmission apparatus 101b side has a detection condition in which failure detection is performed only when the CCM frame does not arrive consecutively. is there.
・ In case of failure detection method by CEP sequence number monitoring
When a bit error in a frame also occurs in a CEP packet signal, the transmission apparatus 101d detects an FCS error in the frame and discards the frame. Then, it is possible to detect error degradation (detection of the main signal frame loss) by detecting missing sequence numbers of frames discarded when the SONET / SDH signal is extracted from the packet signal. However, when the discarded frame size is not fixed as in Ethernet (registered trademark), the frame length is unknown, so that there is a problem that main signal deterioration cannot be detected with high accuracy.

  As described above, in the case of Ethernet (registered trademark) or the like in which the frame length of the missing frame is not fixed, there is a problem that an accurate error rate cannot be known by the conventional method.

  On the other hand, in the case of the transmission system 100 according to the present embodiment, since the size of the discarded frame is known, signal degradation can be detected with high detection accuracy even when the frame length is not fixed. In the example of FIG. 11, when a bit error in a frame or a missing frame occurs, the transmission apparatus 101c detects the SD of the section by the sequence number SNb assigned by the transmission apparatus 101 as the transmission source. Then, the transmission apparatus 101c again adds the sequence number SNc to the frame having the sequence number SNa as a header, and transmits the frame to the transmission apparatus 101d. The transmission apparatus 101d can detect the SD of the section between the transmission apparatus 101c and the transmission apparatus 101d by monitoring the sequence number SNc. In the example of FIG. 11, since a frame loss has occurred in the section between the transmission apparatuses 101c and 101d, the transmission apparatus 101d performs SD detection, and the signal degradation point is between the transmission apparatuses 101c and 101d. It can be specified that the route is between. Furthermore, the transmission apparatus 101d again assigns the sequence number SNd to the frame having the sequence number SNa as a header, and transmits the frame to the transmission apparatus 101b. The transmission apparatus 101b can detect the SD of the section between the transmission apparatus 101d and the transmission apparatus 101b by monitoring the sequence number SNd. Also, the transmission apparatus 101b detects the SD of the path between the transmission apparatus 101a and the transmission apparatus 101b that is the transmission source of the user frame by monitoring the path sequence number SNa given to the user frame by the transmission apparatus 101a. can do.

  Furthermore, for example, as shown in FIG. 10, when there is a redundant path in the Ethernet (registered trademark) ring network, the SD of the path is set as a path switching factor. Accordingly, the monitoring control apparatus 403 that has received the notification of the SD detection of the path in the transmission apparatus 101b switches the path from the active system 401 to the standby system 402, and the main signal deteriorated in the active system 401 is replaced with the standby system. 402 can be bypassed.

  As described above, the transmission system, the transmission apparatus, and the transmission quality detection method according to the present embodiment can detect signal degradation with high accuracy in a network such as Ethernet (registered trademark) in which the frame length is not fixed. . In addition, it is possible to specify the signal degradation location, switch the route appropriately using SD as a switching factor in a redundant network such as a ring network, and relieve the path that transmits the main signal when the signal degrades . Thereby, a high-quality network can be maintained.

  The transmission system, the transmission apparatus, and the transmission quality detection method according to the present invention have been described with reference to the embodiments. However, the transmission system, the transmission apparatus, and the transmission quality detection method may be implemented in various other forms without departing from the spirit or main features thereof. Can do. For this reason, the above-described embodiment is merely an example in all respects and should not be interpreted in a limited manner. The present invention is defined by the claims, and the present invention is not limited to the text of the specification. Further, all modifications and changes belonging to the equivalent scope of the claims are within the scope of the present invention.

DESCRIPTION OF SYMBOLS 100 ... Transmission system 101 ... Transmission apparatus 201 ... GE_I / F
202,251,252 ... 10GE_I / F
301 ... SN assigning unit 302 ... SN monitoring unit 400 ... ring network 401 ... active system 402 ... standby system 403 ... monitoring control device

Claims (5)

The transmission device on the transmission side has a sequence number assigning unit that assigns a frame length of a frame to be transmitted continuously in time and a sequence number added to the frame as a sequence number of a frame to be transmitted next. ,
The transmission apparatus on the receiving side receives the frame to which the sequence number is assigned, adds the frame length of the frame and the sequence number of the frame, obtains an expected value, and receives the sequence number of the next frame to be received and the frame have a sequence number monitoring unit for detecting a difference between the expected value as a missing frame length,
The sequence number monitoring unit uses a first total value of frame lengths that arrived within a preset monitoring time and a second total value of the missing frame lengths that did not arrive within the monitoring time, Deterioration of signal quality is detected when a calculated value of (first total value) / ((first total value) + (second total value)) exceeds a preset threshold value . The transmission system according to claim 1 , wherein
Between the transmission device on the transmission side and the transmission device on the reception side, there is at least two paths of an active system and a standby system, and a monitoring control device is provided for instructing each transmission device to switch the path,
The monitoring control apparatus switches a path from the active system to the standby system when the sequence number monitoring unit of the transmission apparatus on the receiving side detects deterioration of signal quality. A sequence number giving unit for giving an addition value of a frame length of a frame to be transmitted continuously in time and a sequence number given to the frame as a sequence number of a frame to be transmitted next
The frame with the sequence number is received, the frame length of the frame and the sequence number of the frame are added to obtain the expected value, and the difference between the sequence number of the next frame to be received and the expected value is missing have a sequence number monitoring section for detecting a frame length,
The sequence number monitoring unit uses a first total value of frame lengths that arrived within a preset monitoring time and a second total value of the missing frame lengths that did not arrive within the monitoring time, Deterioration of signal quality is detected when a calculated value of (first total value) / ((first total value) + (second total value)) exceeds a preset threshold value . The transmission apparatus on the transmission side assigns an addition value of the frame length of the frame to be transmitted continuously in time and the sequence number given to the frame as the sequence number of the frame to be transmitted next,
The transmission apparatus on the receiving side adds the frame length of the frame to which the sequence number is received continuously in time and the sequence number of the frame to obtain an expected value, and then receives the sequence number of the next frame to be received And the expected value is detected as a missing frame length , and the first total value of the frame lengths that arrived within a preset monitoring time and the second of the missing frame lengths that did not arrive within the monitoring time When the calculated value of (first total value) / ((first total value) + (second total value)) exceeds a preset threshold using the total value, signal quality degradation is detected . A transmission quality detection method characterized by the above. In the transmission quality detection method according to claim 4 ,
Between the transmission device on the transmission side and the transmission device on the reception side, there is at least two paths of an active system and a standby system, and a monitoring control device is provided for instructing each transmission device to switch the path,
The monitoring and control apparatus switches a path from the active system to the backup system when the transmission apparatus on the receiving side detects deterioration of signal quality .

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