JP2008244870A - Communication system, relay device used for the system, and measuring method of frame loss - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a communication system which determines which section a frame loss has occurred in, in the presence of a relay device on a transmission line in a communication system which measures a frame loss. <P>SOLUTION: A communication system has a pair of terminal devices MEP-A and MEP-B which transmit/receive communication frames 80f and 80b for a frame loss measurement through a transmission line, in which one terminal device MEP-A which becomes a main body of a measurement measures a frame loss based on a frame counter value written in the communication frames 80f and 80b by the terminal devices MEP-A and MEP-B. A relay device MIP which relays the communication frames 80f and 80b is provided in a measurement object section of the frame loss, and one terminal device MEP-A has a calculation portion 17 which measures a frame loss per section divided in the vicinity of the relay device MIP. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a communication system having a function of measuring a frame loss by exchanging a frame loss measurement communication frame having a frame counter value writing area, a relay device used therefor, and a frame loss measuring method. .

  For example, Non-Patent Document 1 describes a method of measuring a frame loss between a pair of terminal devices that are communicably connected via a transmission path. According to this Non-Patent Document 1, the pair of termination devices are MEPs (MEP: Maintenance Entity Group End Point) having the same MEG (Maintenance Entity Group End Point) level, and an OAM (OAM) for frame loss measurement between the MEPs. : Frames between MEPs are measured by exchanging frames.

FIG. 10 is an explanatory diagram showing the conventional frame loss measurement method.
As shown in FIG. 10, the MEP-A on the measurement subject side sends out an LMM (Loss Measurement Message) frame, which is an OAM frame for frame loss measurement, at a predetermined period, and the MEP on the opposite side that turns back this frame. -B changes the LMM frame into an LMR (Loss Measurement Reply) frame and returns the frame to MEP-A.

When transmitting the LMM frame, the MEP-A writes its own frame counter value (TxFCf) in the counter field of the frame.
On the other hand, MEP-B writes the frame counter value (RxFCf) at the time of reception of the LMM frame to the counter field of the frame, and copies the counter value as it is when converting the LMM frame to the LMR frame. Further, MEP-B writes the frame counter value (TxFCb) at the time of transmission of the LMR frame in the counter field of the frame.

MEP-A uses the frame counter value (TxFCf, RxFCf, TxFCb) described in the LMR frame returned by MEP-B and the frame counter value (RxFCl) when the LMR frame is received by itself. Based on the following equations (1) and (2), the frame loss in the transmission path that is the measurement section is obtained.
(1) Frame Loss (far-end) = | TxFCf [tc]-TxFCf [tp] |-| RxFCf [tc]-RxFCf [tp] |
(2) Frame Loss (near-end) = | TxFCb [tc]-TxFCb [tp] |-| RxFCl [tc]-RxFCl [tp] |

In the above formulas (1) and (2), “FC” means a frame counter value, “Tx” preceding “FC” is at the time of transmission, and “Rx” is at the time of reception. It means that.
Further, “f” after “FC” means a direction (forward (= far-end)) away from the MEP-A on the measurement subject side, and “b” means MEP- on the measurement subject side. This means a direction approaching A (back (= near-end)), and “l” means a counter value locally held by the receiving side. Furthermore, “c” in [tc] means that the frame counter value is “current”, and “p” in [tp] means that the frame counter value is “one or more previous frames. Means “previous”.

Accordingly, the values of the above formulas (1) and (2) have the following meanings, respectively.
TxFCf: FC value written when transmitting LMM frame
RxFCf: FC value written when receiving LMM frame
TxFCb: FC value written when transmitting an LMR frame
RxFCl: Local FC value of MEP-A when an LMR frame is received

ITU-T Recommendation Y.1731

As described above, according to the conventional frame loss measurement method, it is possible to measure a frame loss that occurs between a pair of MEPs that are termination points of the same MEG level.
However, in Non-Patent Document 1, for example, when a relay device is installed in a measurement target section of the same MEG level, and the transmission / reception unit of this relay device functions as a MIP (Maintenance Entity Group Intermediate Point), the frame loss is relayed. No consideration is given to carving which side of the device occurred.

Therefore, according to Non-Patent Document 1, even if MIP is included in the same MEG level other than a pair of MEPs, only frame loss between both MEPs can be measured. Therefore, it was not possible to determine whether a frame loss occurred, and it was not possible to provide a highly satisfactory communication system for telecommunications carriers with strict service requests.
In view of such a problem, the present invention is to determine in which section before and after a relay device a frame loss occurs in a communication system that measures frame loss when there is a relay device in a measurement target section. It is an object of the present invention to provide a communication system that can

  The present invention includes a pair of termination devices that transmit and receive a communication frame for frame loss measurement via a transmission line, and one of the termination devices that is a measurement subject based on the frame counter value that each termination device writes in the communication frame. A communication system in which a device measures a frame loss, wherein a relay device that relays the communication frame is provided in the measurement target section of the frame loss, and each of the terminal devices is separated before and after the relay device. And an arithmetic unit for measuring the frame loss.

  According to the present invention, the arithmetic unit of one of the terminal devices that is the measurement subject measures the frame loss for each section separated before and after the relay device, so that the frame loss occurs in any section before and after the relay device. I can find out. For this reason, it is possible to provide a communication system with a high degree of satisfaction even for a telecommunications carrier having a strict service request.

More specifically, as the relay device used in the communication system of the present invention, a device that writes its own frame counter value in the communication frame when relaying the communication frame can be employed.
In this case, the one termination device that is the measurement subject is a frame counter value that is written by itself in the communication frame, a frame counter value that is written by the relay device in the communication frame, and the other termination device that is in the communication frame. The frame loss for each section can be measured based on the frame counter value written by and the own frame counter value when the communication frame is received.

In this way, if the relay device writes its own frame counter value in the communication frame when relaying the communication frame, measurement of frame loss for each section using the existing communication frame (the LMM frame and the LMR frame). Is possible. For this reason, it is not necessary to drastically change the rules in order to perform frame loss separation between the sections before and after the relay apparatus, and the implementation of the present invention is simplified.
On the other hand, for example, as a means for measuring frame loss individually between a terminal device (MEP-A) and a relay device (MIP) as a measurement subject, MIP is set to a different MEG level from MEP-B, It is conceivable to measure frame loss independently between MEP-MEP and between MEP-MIP.

However, in such a measurement method that makes the MEG level independent, it is impossible to grasp where and how much frame loss occurs in the same traffic condition between MEP-MEP and between MEP-MIP. It is impossible to accurately measure the frame loss for each section.
In this regard, in the present invention, when relaying a communication frame, the relay device writes its own frame counter value in the communication frame, so the same frame loss measurement frame (the LMM frame and the LMR frame) of the same MEG level is used. Frame loss for each section can be measured at a time, and it is possible to grasp where and how much frame loss occurs under the same traffic conditions.

Further, the communication frame may be one in which an area for writing the frame counter value of the relay device is set in an empty area in an existing frame for frame loss measurement.
For example, as will be described later in the embodiment, an existing LMM frame or LMR frame has a zero-padded area after End TLV (Type, Length, and Value), and this area has a frame counter for the relay apparatus. An area for writing a value may be set.

In this case, since the write area for the relay device is arranged after the End TLV, even if there is an MEP that does not support the format change of the LMM / LMR frame, the MEP is changed as at least the previous convention. The probability of recognizing a later LMM frame and LMR frame is increased.
For this reason, it is possible to prevent as much as possible that the frame loss measurement between the MEPs cannot be performed as the LMM / LMR frame format is changed.

  As described above, according to the present invention, in a communication system that measures frame loss, it is possible to determine in which section before and after the relay device the frame loss has occurred. Can respond.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[Overall configuration of communication system]
FIG. 1 is a schematic configuration diagram of a communication system assumed by the present invention.
As shown in FIG. 1, the communication system 1 of the present embodiment enables high-speed communication by adopting an optical fiber 2 as a transmission line connecting a computer in a home or office and a communication carrier. A pair of media converters (line terminators) 3 and 4 for relaying a metal line and an optical fiber line are provided.

  The pair of media converters 3 and 4 are connected to each other by an optical fiber 2, and one converter (hereinafter referred to as “station”) of the pair of converters 3 and 4 that is installed in the central office 5 of the communication carrier. 3) is connected to the upper network 7 by the metal cable 6 via the L2 switch 11. The other converter (hereinafter referred to as “home-side terminal device”) 4 installed in a building 8 such as a home, office or the like is connected to a terminal 10 such as a personal computer via a metal cable 9.

Each of these terminators 3 and 4 is capable of bidirectional communication by passing an upstream signal and a downstream signal having different wavelengths through a single-core optical fiber 2, and the electrical signals of the metal cables 6 and 9 (example of FIG. 1). Then, 1000BASE-T) and the optical signal of the optical fiber 2 (1000BASE-SX or 1000BASE-LX in the example of FIG. 1) are exchanged alternately. Thereby, the terminal 10 on the home side can communicate with the host network 7 such as the Internet.
A management device 12 is connected to the L2 switch 11. The management device 12 is a communication device for performing various measurements such as setting of various communication parameters for each of the terminal devices 3 and 4 and frame loss measurement described later using the OAM frame.

[Configuration of management device]
FIG. 2 shows an example of the internal configuration of the management device 12.
As shown in FIG. 2, the management device 12 includes a management device port 15 including a PHY layer and a MAC layer, and a data processing unit 16.
The management device port 15 is connected to the host network 7 and the station-side terminal device 3 via the metal cable 6 and alternately converts a network signal and a general-purpose signal capable of data processing.

The data processing unit 16 includes a processor unit 17, a downstream memory unit 18, a port output unit 19, a port input unit 20, and an upstream memory unit 21.
The processor unit 17 of the management device 12 generates a downstream OAM frame (including an LMM frame 80f for frame loss measurement described later) based on a set predetermined period. The processor unit 17 does not periodically generate all OAM frames, but the LMM frame 80f is generated based on a predetermined period set when the frame loss test is started.
The downstream OAM frame is stored in the downstream memory unit 18 as the OAM output queue Q1 and sent to the OAM output processing unit 22 of the port output unit 19.

The OAM output processing unit 22 outputs the downstream OAM frame from the management device port 15 to the home-side terminal device 4. When the downstream OAM frame is the LMM frame 80f, the OAM output processing unit 22 adds a frame counter to the frame 80f. Write the value (TxFCf).
On the other hand, the upstream signal input to the port input unit 20 of the data processing unit 16 is buffered by the input FIFO 23 and sent to the input processing unit 24.

The input processing unit 24 extracts an OAM frame from the upstream signal and stores the upstream OAM frame in the upstream memory unit 21 as the OAM input queue Q2. Further, when the upstream OAM frame is an LMR frame 80b for frame loss measurement described later, the input processing unit 24 writes a frame counter value (RxFCl) in the frame 80b.
It is not always necessary to write the frame counter value in the input processing unit 24, and the frame counter value (RxFCl) at that time may be stored in a format that can be referred to by the processor unit 17.

The processor unit 17 of the management device 12 reads the OAM frame from the OAM input queue Q2, and performs predetermined management control described in the OAM frame.
For example, when the OAM frame is the LMR frame 80b, the processor unit 17 reads out each frame counter value (including the frame counter value RxFC1) described in the LMR frame 80b, and performs frame loss based on the value. Is calculated. This calculation method will be described later.

[Configuration of station side terminal equipment]
FIG. 3 shows an example of the internal configuration of the station-side terminal device 3.
As shown in FIG. 3, the station-side terminal device 3 includes an SNI (Service Node Interface) port 30 composed of a PHY layer and a MAC layer in order from the upper side (right side in FIG. 3), and a data processing unit 31 described later. And an OSU (Optical Subscriber Unit) port 32 including a PHY layer and a MAC layer.
The SNI port 30 is connected to the host network 7 and the management device 12 via the metal cable 6 and alternately converts a network signal and a general-purpose signal capable of data processing. The OSU port 32 is connected to the home-side terminal device 4 through the optical fiber 2 and alternately exchanges an optical signal and a general-purpose signal that can be processed.

The data processing unit 31 includes a downlink input unit 33 to which an input signal (downlink signal) from the SNI port 30 is input, a downlink memory unit 34 that temporarily stores various frames included in the downlink signal, and the memory unit 34. And a downstream output unit 35 that outputs various frames from the OSU port 32.
The data processing unit 31 includes an upstream input unit 36 to which an input signal (upstream signal) from the OSU port 32 is input, an upstream memory unit 37 that temporarily stores various frames included in the upstream signal, and this memory. And an upstream output unit 38 that outputs various frames from the unit 37 to the SNI port 30.

The downlink signal input to the downlink input unit 33 is buffered by the input FIFO 39 and sent to the SNI input processing unit 40.
The SNI input processing unit 40 sorts the downstream signal, the OAM frame into the OAM input queue Q3, and the user frame into the user output queue Q5. Further, when the downstream OAM frame is the LMM frame 80f, the SNI input processing unit 40 writes the frame counter value (RxFCf_mip) in the frame 80f.

  The processor unit 41 reads the OAM frame from the OAM input queue Q3 and performs predetermined management control described in the OAM frame. Further, when the OAM frame read from the OAM input queue Q3 is the LMM frame 80f, the processor unit 41 captures the frame 80f into the OSU OAM output queue Q4.

The downlink output unit 35 combines these frames with an OAM output processing unit 42 that reads a downlink OAM frame from the OSU OAM output queue Q4, a user output processing unit 43 that reads a downlink user frame from the user output queue Q5, and these frames. And an output merging unit 44 that outputs to the OSU port 32.
Further, the downlink output unit 35 includes a downlink transmission scheduler 45 that determines the transmission order and time of each frame. The scheduler 45 transmits the frames to the OSU port 32 by interrupting OAM frames (including the LMM frame 80 f) related to management communication in the downstream user frames.

On the other hand, the upstream signal input to the upstream input unit 36 is buffered by the input FIFO 46 and sent to the OSU input processing unit 47. The OSU input processing unit 47 sorts the upstream signal, the OAM frame into the OSU OAM input queue Q7, and the user frame into the user output queue Q8.
The processor unit 41 reads out the OAM frame from the OSU OAM input queue Q7 and performs predetermined management control described in the OAM frame. Further, when the OAM frame read from the OSU OAM input queue Q7 is the LMR frame 80b, the processor unit 41 captures the frame 80b into the OAM output queue Q6.

The upstream output unit 38 combines an OAM output processing unit 48 that reads an upstream OAM frame from the OAM output queue Q6, a user output processing unit 49 that reads an upstream user frame from the user output queue Q8, and combines these frames. And an output junction 40 that outputs to the port 30.
When the upstream OAM frame includes the LMR frame 80b, the OAM output processing unit 48 writes the frame counter value (TxFCb_mip) in the frame 80b.

  Further, the upstream output unit 38 includes an upstream transmission scheduler 51 that determines the transmission order and time of each frame. The scheduler 51 causes an OAM frame (including the LMR frame 80b) related to management communication to be interrupted to an upstream user frame, and transmits these frames to the SNI port 30.

[SNI input processor]
FIG. 5 shows an example of the internal configuration of the SNI input processing unit 40 of the downlink input unit 33.
As described above, the SNI input processing unit 40 has a function as a frame processing unit that writes a frame counter value in the station-side terminal device 3 for the LMM frame 80 f received from the management device 12.
As shown in FIG. 5, the SNI input processing unit 40 distributes the ETH-OAM frame according to the opcode, the demultiplexer 54 that distributes the OAM frame and the other frames, the demultiplexer 55 that distributes the ETH-OAM frame according to the MEG level. And a demultiplexer 56.

The upstream signal frame from the SNI port input FIFO 39 is typed by the demultiplexer 54. If it is an OAM frame, it is sent to the next demultiplexer 55, and if it is any other user frame, it is sent to the OSU user output queue Q5. Sent.
The next-stage demultiplexer 55 determines whether or not the MEG level of the OAM frame matches that of the measurement group including the station-side terminal device 3. In the case of an OAM frame having the same MEG level, it is further sent to the subsequent demultiplexer 56, and in the case of an inconsistent frame, it is sent to the OSU user output queue Q5.

The downstream demultiplexer 56 sorts the ETH-OAM frame and extracts the LMM frame 80f, the LBM frame (loopback test frame), and the like. The LMM frame 80f extracted by the demultiplexer 56 is written with the frame counter value (RxFCf_mip) and stored in the downstream memory unit 34 as the OAM input queue Q3.
For the LBM frame extracted by the demultiplexer 56, the subsequent demultiplexer 57 determines whether or not it is destined for the device 3, and if it is destined for itself, it is stored in the downstream memory unit 34 as the OAM input queue Q3. Otherwise it is discarded.

[OAM output processor]
FIG. 6 shows an example of the internal configuration of the OAM output processing unit 48 of the upstream output unit 38.
As described above, the OAM output processing unit 48 has a function as a frame processing unit that writes a frame counter value in the station-side terminal device 3 for the LMR frame 80b transmitted to the management device 12.
As shown in FIG. 6, the OAM output processing unit 48 includes a demultiplexer 58 that distributes the ETH-OAM frames according to the operation code. The demultiplexer 58 distributes the ETH-OAM frames read from the OAM output queue Q6. The LMR frame 80b and the LBM frame (loopback test frame) are extracted.

  The LMR frame 80b extracted by the demultiplexer 58 is written with a frame counter value (TxFCb_mip) and sent to the output junction unit 50. In addition, the LBM frame extracted by the demultiplexer 58 is also sent to the output merging unit 50 via the subsequent transmission unit, but the other frames are discarded.

[Configuration of home-side terminal equipment]
FIG. 4 shows an example of the internal configuration of the home-side terminal device 4.
As shown in FIG. 4, this home-side terminal device 4 includes an ONU (Optical Network Unit) port 61 composed of a PHY layer and a MAC layer in order from the upper side (the right side in FIG. 4), and a data processing unit 62 described later. And a UNI (User Network Interface) port 63 comprising a PHY layer and a MAC layer.
The ONU port 61 is connected to the station-side terminator 3 through the optical fiber 2 and alternately exchanges an optical signal and a general-purpose signal that can be processed. The UNI port 63 is connected to the terminal 10 via the metal cable 9 and alternately converts a network signal on the terminal 10 side and a general-purpose signal capable of data processing.

The data processing unit 62 includes a downstream input unit 64 to which an input signal (downstream signal) from the ONU port 61 is input, a downstream memory unit 65 that temporarily stores various frames included in the downstream signal, and the memory unit 65. And a downstream output unit 66 for outputting various frames from the UNI port 63 to the UNI port 63.
The data processing unit 62 also includes an upstream input unit 67 to which an input signal (upstream signal) from the UNI port 63 is input, an upstream memory unit 68 that temporarily stores various frames included in the upstream signal, and the memory And an upstream output unit 69 that outputs various frames from the unit 68 to the ONU port 61.

The downlink signal input to the downlink input unit 64 is buffered by the input FIFO 70 and sent to the ONU input processing unit 71.
The ONU input processing unit 71 sorts downstream signals, OAM frames into the OAM input queue Q9, and user frames into the UNI port output queue Q10. Further, when the downstream OAM frame is the LMM frame 80f, the ONU input processing unit 71 writes the frame counter value (RxFCf) in the frame 80f.

The processor unit 72 reads out the OAM frame from the OAM input queue Q9, and performs predetermined management control described in the OAM frame. Further, when the downstream OAM frame is the LMM frame 80f, the processor unit 72 changes the LMM frame 80f to the LMR frame 80b and takes this LMR frame 80b into the OAM output queue Q11 of the upstream memory unit 68.
The downlink output unit 66 performs an output process of reading the downlink user frame from the UNI port output queue Q10, and transmits the frame to the UNI port 63.

On the other hand, the upstream signal input to the upstream input unit 67 is buffered by the input FIFO 73 and sent to the UNI input processing unit 74. The UNI input processing unit 74 sends the user frame of the upstream signal to the upstream memory unit 68 in the subsequent stage as the UNI port input queue Q12.
The upstream output unit 69 combines these frames with an OAM output processing unit 75 that reads an upstream OAM frame from the OAM output queue Q11, a user output processing unit 76 that reads an upstream user frame from the UNI port input queue Q12, and these frames. And an output merging unit 77 that outputs to the ONU port 61.

When the upstream OAM frame is the LMR frame 80b, the OAM output processing unit 75 writes the frame counter value (TxFCb) in the frame 80b.
The uplink output unit 69 includes an uplink transmission scheduler 78 that determines the transmission order and time of each frame. The scheduler 78 interrupts OAM frames (including the LMR frame 80 b) related to management communication in the upstream user frame, and transmits these frames to the ONU port 61.

[Measurement of frame loss]
The management device 12 processor unit (calculation unit) 72 uses frame loss measurement communication frames (LMM frame 80f and LMR frame 80b), which is a kind of OAM frame exchanged with the home-side terminal device 4. To measure the frame loss.
The LMM (Loss Measurement Message) frame 80f and the LMR (Loss Measurement Reply) frame 80b basically conform to the conventions of the ITU-T recommendation (Y.1731). Is different from this rule in that the frame counter value is written. Hereinafter, the frame loss measurement method of the present embodiment will be described with reference to FIGS.

FIG. 7 is a schematic configuration diagram of the communication system 1 according to the present embodiment as viewed from the viewpoint of frame loss measurement.
As shown in FIG. 7, hereinafter, the port of the management apparatus 12 that is the measurement subject is displayed as MEP (Maintenance Entity Group End Point) -A, and the port of the home-side terminal apparatus 4 facing this is displayed as MEP-B. The station-side terminal device 3 that relays between these MEPs is displayed as MIP (Maintenance Entity Group Intermediate Point).

As shown in FIG. 8, the MEP-A transmits the LMM frame 80f for frame loss measurement to the MEP-B by relaying the MIP, and the MEP-B converts the LMM frame 80f into the LMR frame 80b. The LMR frame 80b is relayed to the MEP-A by relaying the MIP.
Here, according to the rules of the ITU-T recommendation (Y.1731), the MIP simply relays the LMM frame 80f and the LMR frame 80b as they are. Therefore, as shown in FIG. 7 and FIG. Even when MIP is present in the measurement target section between MEP-B, it is impossible to know on which side before and after MIP frame loss has occurred.

  Therefore, in this embodiment, the LMM frame 80f and the LMR frame 80b are not simply relayed, but the frame counter value written in the MEP-B is written in the frames 80f and 80b in the MIP at the time of relaying. The frame loss for each section before and after the MIP is calculated using the frame counter value written by the MIP.

By the way, as a method of writing a frame counter value in the LMM / LMR frames 80f and 80b in MIP, for example, a field for writing a frame counter value for MIP in a PDU (Protocol Data Unit) of the existing LMM frame 80f and LMR frame 80b. It is conceivable to add a new one.
Since the PDUs of the LMM / LMR frames 80f and 80b are very short, there is an extra area that is zero-padded after End TLV (Type, Length, and Value) to make the minimum frame length of Ethernet 64B. .

[PDU format of LMM and LMR]
Therefore, in the present embodiment, as shown in FIG. 9, a field for MIP in which a frame counter value is embedded is newly set in an unused area after the End TLV in the PDU of the LMM / LMR frames 80f and 80b. .
FIG. 9A shows an example of the PDU format of the LMM frame 80f, and FIG. 9B shows an example of the PDU format of the LMR frame 80b.

As shown in FIGS. 9A and 9B, in the PDU of this embodiment, the first to third areas 81 conventionally defined in the convention (Y.1731) as the frame counter value write field. ˜83, and fourth and fifth regions 84 and 85 newly secured after End TLV this time.
In the PDU format, the first area 81 is a description area of the frame counter value (TxFCf) of the MEP-A that is a measurement subject, and the second area 82 is a frame counter value (RxFCf at the time of LMM reception of the MEP-B). The third area 83 is an area for describing a frame counter value (TxFCf) during MMR-B LMR transmission.

The fourth area 84 is a description area of the frame counter value (RxFCf_mip) at the MIP LMM relay, and the fifth area 85 is a description area of the frame counter value (TxFCb_mip) at the MIP LMR relay.
9A shows a state at the time when MEP-A transmits the LMM frame 80a, the second, third and fifth areas 82, 83, 85 of the LMM frame 80a are reserved areas ( Reserved).

[Frame counter value description procedure]
FIG. 8 shows a writing procedure of frame counter values for the LMM frame 80f and the LMR frame 80b.
As shown in FIG. 8, the MIP-A transmits the LMM frame 80f to the MEP-B side at a predetermined cycle. At this time, the frame counter value (TxFCf) is written in the first area 81 of the LMM frame 80f. The frame 80f is transmitted.

Upon receiving the LMM frame 80f, the MIP writes a frame counter value (RxFCf_mip) in the fourth area 84 of the frame 80f, and transmits the written LMM frame 80f to MIP-B.
Upon receipt of the LMM frame 80f, the MEP-B writes the frame counter value (RxFCf) in the second area 82 of the same frame 80b at the time of reception, and copies the frame counter value as it is to transfer the LMM frame 80f to the LMR frame 80b. Convert to

Further, when the MEP-B transmits the LMR frame 80b, the MEP-B writes the frame counter value (TxFCb) in the third area 83 of the frame 80b.
Upon receipt of the LMR frame 80b, the MIP writes a frame counter value (TxFCf_mip) in the fifth area 85 of the frame 80b, and transmits the written LMR frame 80b to the MEP-A.
The MEP-A uses the frame counter values (TxFCf, RxFCf, TxFCb, RxFCf_mip, TxFCb_mip) described in the LMR frame 80b and the frame counter value (RxFCl) when the LMR frame 80b is received by itself. And frame loss is obtained based on the following equations (1) to (4).

[Frame loss calculation method]
That is, the processor unit 17 of the management device 12 configuring the MEP-A calculates a frame loss based on the following equations (1) to (4).
/ 1. Frame loss between MEP-A and MEP-B /
(1) Frame Loss (far-end) = | TxFCf [tc]-TxFCf [tp] |-| RxFCf [tc]-RxFCf [tp] |
(2) Frame Loss (near-end) = | TxFCb [tc]-TxFCb [tp] |-| RxFCl [tc]-RxFCl [tp] |
/ 2. Frame loss between MEP-A and MIP /
(3) Frame Loss (far-end) = | TxFCf [tc]-TxFCf [tp] |
-| RxFCf_mip [tc]-RxFCf_mip [tp] |
(4) Frame Loss (near-end) = | TxFCb_mip [tc]-TxFCb_mip [tp] |
-| RxFCl [tc]-RxFCl [tp] |

Of the above formulas (1) to (4), formulas (1) and (2) are formulas for obtaining a frame loss between both MEPs. These formulas are in accordance with the rules of the ITU-T recommendation (Y.1731), and calculate the frame loss that occurs in the entire measurement target section.
On the other hand, equations (3) and (4) are equations for obtaining the frame loss between MEP-A and MIP. These formulas are based on the present invention, and are used to calculate the frame loss that occurs in the section behind the MIP (on the MEP-A side).

  Therefore, by subtracting the frame loss obtained by the equations (3) and (4) from the frame loss obtained by the equations (1) and (2), the frame loss generated in the section ahead of the MIP (MEP-B side). Thus, it is possible to measure the frame loss for each section obtained by dividing the entire measurement target section before and after the MIP.

Note that the frame loss calculation formula is not limited to the above formulas (1) to (4). For example, according to the following formulas (5) and (6), the section ahead of the MIP (MEP-B side) The frame loss generated in step 1 may be directly calculated.
/ 3. Frame loss between MIP and MEP-B /
(5) Frame Loss (far-end) = | RxFCf_mip [tc]-RxFCf_mip [tp] |
-| RxFCf [tc]-RxFCf [tp] |
(6) Frame Loss (near-end) = | TxFCb [tc]-TxFCb [tp] |
-| TxFCb_mip [tc]-TxFCb_mip [tp] |

Thus, according to the communication system 1 of the present embodiment, the processor unit (calculation unit) 17 of the MEP-A that is the measurement subject measures the frame loss for each section divided before and after the MIP. It is possible to find out in which section before and after the frame loss has occurred.
For this reason, it is possible to provide the communication system 1 with a high degree of satisfaction even for a telecommunications carrier having a strict service request.

Further, in the communication system 1 of the present embodiment, the frame loss for each section is measured using the existing LMM frame 80f and the LMR frame 80b according to the ITU-T recommendation (Y.1731). Since it is not necessary to drastically change the rules in order to perform frame loss separation before and after MIP, implementation is simple.
Furthermore, in the communication system 1 according to the present embodiment, LMM / LMR frames 80f and 80b are exchanged between MEP-MIP-MEPs having the same MEG level, and frame loss is measured. There is also an advantage that it is possible to grasp whether a frame loss has occurred.

The present invention is not limited to the above embodiment.
For example, in the above-described embodiment, the case where there is only one MIP in the measurement target section is illustrated, but a plurality of MIPs may be included in the same section. In this case, if the MIP identification value is combined and written in the LMM frame 80f, the frame counter value can be identified. However, when the arrangement of MEP and MIP is known in advance (usually assumed to be so), it is possible to implement the MIP identification in the field order, and in particular, the MIP identification value is described. There is no need to provide a field for
The MIP identification value may be the MIP MAC address (6B), but a simpler value may be set in advance as a MIP_ID for each port.

Although the time restriction from the reception of the LMM frame 80f to the return of the LMR frame 80b is not assumed in the ITU-T recommendation (Y.1731), MEP-B receives the LMM frame 80f. Then, since the LMR frame 80b is always returned, it is considered that the return period of the LMR frame 80f is not significantly different from the transmission period of the LMM frame 80b.
For this reason, if it is assumed that the transmission interval of the LMM frame 80f is set to be short and frame loss is measured, it is not necessary to make the frame counter value area 4B wide. For example, if the frame counter value is handled with a value of 2B, it is possible to deal with a configuration in which more MIPs exist without changing the restriction that the frame length is 64B.

It is a schematic block diagram of the communication system which this invention assumes It is a block diagram which shows an example of an internal structure of a management apparatus (MEP-A). It is a block diagram which shows an example of an internal structure of a station side termination | terminus apparatus (MIP). It is a block diagram which shows an example of an internal structure of a residential side terminal apparatus (MEP-B). It is a block diagram which shows an example of an internal structure of a SNI input process part. It is a block diagram which shows an example of an internal structure of an OAM output process part. It is the schematic block diagram which looked at the said communication system from the viewpoint of the frame loss measurement. It is a schematic block diagram of a communication system for showing the writing procedure of the frame counter value with respect to an LMM frame and an LMR frame. (A) is a figure which shows an example of the PDU format of an LMM frame, (b) is a figure which shows an example of the PDU format of an LMR frame. It is explanatory drawing which shows the measuring method of the conventional frame loss.

Explanation of symbols

1 Communication system 2 Optical fiber (transmission path)
6 Metal cable (transmission path)
9 Metal cable (transmission path)
3 Station side terminal equipment (relay equipment: MIP)
4 Home-side terminal equipment (MEP-B)
12 Management device (MEP-A)
17 Processor unit (calculation unit) of management device
40 SNI input processing unit (frame processing unit) of station side terminal equipment
48 OAM output processing unit (frame processing unit) of station side terminal equipment
80f LMM frame (communication frame)
80b LMR frame (communication frame)

Claims (6)

A pair of termination devices that transmit and receive a communication frame for frame loss measurement via a transmission line, and one of the termination devices that is a measurement subject based on a frame counter value written in the communication frame by each termination device A communication system for measuring
A relay device that relays the communication frame is provided in the frame loss measurement target section, and the one terminal device has a calculation unit that measures the frame loss for each section separated before and after the relay device. A featured communication system.   The communication system according to claim 1, wherein the relay device writes its own frame counter value in the communication frame when relaying the communication frame.   The one terminal device includes a frame counter value written by itself in the communication frame, a frame counter value written by the relay device in the communication frame, and a frame counter value written by the other terminal device in the communication frame, The communication system according to claim 2, wherein a frame loss for each section is measured based on an own frame counter value when the communication frame is received.   4. The communication system according to claim 2, wherein the communication frame has an area in which a frame counter value of the relay device is written in an empty area in an existing frame for frame loss measurement. A relay device provided in a measurement target section between a pair of terminal devices capable of transmitting and receiving a communication frame for frame loss measurement,
A relay apparatus comprising: a frame processing unit that writes its own frame counter value in the communication frame when relaying the communication frame. A frame loss measurement communication frame is transmitted / received between a pair of terminal devices connected by a transmission path, and one of the terminal devices serving as a measurement subject is based on a frame counter value written to the communication frame by each terminal device. A frame loss measurement method for measuring frame loss,
A frame loss measurement method, wherein one terminal device as a measurement main body measures the frame loss for each section separated before and after the relay apparatus provided in the frame loss measurement target section.

Images