JP2017220832A - Transmission system, transmission device, and transmission method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To make it possible to detect a sign of a failure before occurrence of the failure in a main signal system and perform changeover of an operation system/non-operation system based on the sign of the failure to suppress influence on a main signal in a shorter period of time.SOLUTION: A transmission system having a redundant configuration of an operation system and non-operation system includes transmission devices between which a CCM frame standardized by ITU-T (Y1731) is transmitted, where transmission time is inserted into the CCM frame by a transmission device of a preceding stage. A transmission device, when receiving the CCM frame into which the transmission time is inserted from the transmission device of the preceding stage, detects its reception time and extracts the transmission time from the CCM frame. A delay amount (=reception time-transmission time) is calculated on the basis of the reception time and the transmission time; on the basis of the delay amount, whether or not to execute changeover of the operation system and non-operation system is determined.SELECTED DRAWING: Figure 7

Description

  The present invention relates to a transmission system, a transmission apparatus, and a transmission method.

  Conventionally, a transmission system using an L2 switch has a redundant configuration of an active system and a non-operating system, and when a failure such as an abnormality or failure occurs in the operating system, the operating system and the non-operating system are switched. Thus, there is a technique capable of avoiding a continuous state where the main signal is not communicated.

  Further, as a prior art, there is a technology relating to preventive maintenance of optical line equipment, in which the state of the dispersion value / bit error rate value of a line is monitored, and when a predetermined value is exceeded, the line is switched to a line having a normal value ( For example, see the following Patent Document 1.)

JP2015-115863A

  However, in the above prior art, the operation / non-operation system is switched after the abnormality or failure is detected, so the main signal influence is in the time from the detection of the abnormality or failure until the switching is completed. There is a problem in that there is a risk of the occurrence of a large amount.

  Further, in the above prior art, it is only possible to monitor a failure such as a deterioration of a transmission path, and for example, it is not possible to monitor the entire network of the transmission system due to a failure such as an abnormality or a failure of a memory of a transmission device. However, there was a problem that perfect preventive maintenance could not be performed.

  In one aspect, the present invention aims to suppress the influence of the main signal in a shorter time.

  According to one aspect of the present invention, when transmitting a monitoring frame between transmission apparatuses in a transmission system having a redundant configuration of an active system and a non-operating system, the monitoring frame in which the first time is inserted in the previous transmission apparatus A delay amount calculated from the first time and the second time by detecting the second time received from the previous transmission apparatus and detecting the monitoring frame, extracting the first time from the monitoring frame Based on the above, a transmission system, a transmission apparatus, and a transmission method for determining whether to perform switching between the active system and the non-active system are proposed.

  According to one aspect of the present invention, there is an effect that the influence of the main signal can be suppressed in a shorter time.

FIG. 1 is an explanatory diagram of an example of a configuration of the transmission system according to the embodiment. FIG. 2 is an explanatory diagram of an example of a hardware configuration of the transmission apparatus according to the embodiment. FIG. 3A is an explanatory diagram illustrating an example of a format configuration of a CCM frame. FIG. 3B is an explanatory diagram illustrating an example of a TLV type of a CCM frame. FIG. 3C is an explanatory diagram illustrating an example of a TLV format of a CCM frame. FIG. 4 is an explanatory diagram of an example of a functional configuration of the transmission apparatus according to the embodiment. FIG. 5 is an explanatory diagram of another example of the functional configuration of the transmission apparatus according to the embodiment. FIG. 6 is an explanatory diagram of another example of the functional configuration of the transmission apparatus according to the embodiment. FIG. 7 is an explanatory diagram of an example of delay amount calculation in the transmission system according to the embodiment. FIG. 8 is a flowchart illustrating an example of a CCM transmission process in the transmission apparatus according to the embodiment. FIG. 9 is a flowchart illustrating an example of CCM reception processing in the transmission apparatus according to the embodiment. FIG. 10 is a flowchart illustrating another example of the CCM transmission process in the transmission apparatus according to the embodiment.

  Exemplary embodiments of a transmission system, a transmission apparatus, and a transmission method according to the present invention will be explained below in detail with reference to the accompanying drawings.

(Embodiment)
(Configuration of transmission system)
A network using an IP network, for example, Ethernet (registered trademark), accommodates a plurality of transmission devices, and has a maintenance function such as checking continuity between transmission devices and identifying a failure point on the network. doing. As a technology having this maintenance function, for example, there is Ethernet OAM (Operation Administration Management). The Ethernet OAM is standardized by, for example, ITU-T (Y1731) or IEEE (802.1ag).

  For example, the Ethernet OAM mainly transmits and receives CCM (Continuity Check Messages) frames mainly for the purpose of confirming continuity between transmission apparatuses. Thereby, a continuity check function for quickly detecting a failure is provided. Specifically, in the continuity check function, the transmission apparatus periodically transmits a CCM frame to the opposite transmission apparatus. The opposite transmission device detects a failure (LOC: Loss of Connectivity) between the transmission device and the opposite transmission device when the CCM frame cannot be received periodically. Can do.

  FIG. 1 is an explanatory diagram of an example of a configuration of the transmission system according to the embodiment. In FIG. 1, the transmission system 100 includes PTNs (Packet Transport Networks) 101 to 104. Among them, the PTN 102 is an active PTN, and the PTN 104 is a non-active PTN. The active path constitutes the working path, and the non-active path constitutes the backup path.

  In FIG. 1, PTNs 101 to 104 each include a transmission device and a switch (SW). Specifically, the PTN 101 includes transmission apparatuses 105, 107, 111, and SW 115, the PTN (active system) 102 includes transmission apparatuses 108, 109, and SW 117, and the PTN 103 includes transmission apparatuses 106, 110. , 114 and SW 116, and the PTN (non-operational system) 104 includes transmission devices 112, 113 and SW 118.

  The transmission apparatus 105 and the transmission apparatus 106 are MEP (Maintenance End Point) transmission apparatuses that transmit and receive CCMs. The transmission apparatus 105 and the transmission apparatus 106 are opposite transmission apparatuses, and the transmission apparatus 105 transmits a CCM. The transmission device 106 receives the CCM. The other transmission apparatuses 107 to 114 are MIP (Maintenance Intermediate Point) transmission apparatuses that allow the CCM to pass therethrough.

  “Transmission device 105 (MEP)” → “SW115” → “Transmission device 107 (MIP)” → “Transmission device 108 (MIP)” → “SW117” → “Transmission device 109 (MIP)” → “Transmission device 110 (MIP) ) ”→“ SW116 ”→“ Transmission device 106 (MEP) ”constitutes an active transmission path. Also, it is not operated by “transmission device 111 (MIP)” → “transmission device 112 (MIP)” → “SW118” → “transmission device 113 (MIP)” → “transmission device 114 (MIP)” from SW 115 to SW 116. The system transmission path is configured.

  Further, the transmission system includes an OpS (Operation System) device 120. The OpS device 120 performs time synchronization between the transmission devices and switching of the operation system by a failure sign across the transmission devices. Details of the OpS (Operation System) apparatus 120 will be described later.

(Hardware configuration of transmission equipment)
FIG. 2 is an explanatory diagram of an example of a hardware configuration of the transmission apparatus according to the embodiment. In FIG. 2, transmission apparatuses 105 to 114 include a line card 200. The line card 200 includes a CPU (Central Processing Unit) 201, an L2 switch 202, an input interface 203, and an output interface 204. Furthermore, the line card 200 may have various memories such as a ROM (Read Only Memory) and a RAM (Random Access Memory) (not shown).

  A CPU (Central Processing Unit) 201 controls the entire transmission apparatuses 105 to 114 and reads a CCM processing program stored in a ROM (not shown) to execute a CCM processing function.

  The L2 switch 202 switches and connects the input interface 203 and the output interface 204 and executes various processes at the layer 2 level. The input interface 203 is connected to a cable on the network and inputs a CCM frame or the like from another transmission apparatus in the transmission system. The output interface 204 is connected to a cable and outputs a CCM frame or the like to other transmission apparatuses in the transmission system.

  In addition, various programs such as a transmission program are stored in a ROM (not shown). The RAM (not shown) can store various types of information including information regarding the calculated delay amount.

(Configuration of CCM frame)
FIG. 3A is an explanatory diagram illustrating an example of a format configuration of a CCM frame. As shown in FIG. 3A, for example, CCM frames standardized by ITU-T (Y1731) are “DA”, “SA”, “VLAN header”, “Ether Type”, “MEL”, “Version”, “Opcode”, “RDI Bit”, “Period”, “TLV Offset”, “All′0x00 ′”, “MEP ID”, “MEG ID”, “TxFCf” And “RxFCb”, “TxFCb”, “Reserved”, “TLV type”, “TLV length”, “Value”, “End TLV”, and “FCS”.

  “DA (Multicast or Unicast)” is an area for storing a multicast or unicast transmission destination address. “SA” is an area for storing the MAC address of the own device. “VLAN header” is an area for storing a header. “Ether Type (ETH OAM)” is an area for storing OAM as an Ethernet type. “MEL” is an area for storing a MEG (Maintenance Entity Group) level of the source MEP. MEG indicates a collection of ME (Maintenance Entity) indicating one section in which maintenance is performed using a CCM frame.

  “Version” is an area for storing data for identifying whether or not reception should be discarded. “Opcode” is an area for storing an opcode for identifying an instruction. “RDI Bit” is an area for storing RDI information of a bit string for identifying a failure content. “Period” is an area for storing a transmission / reception interval used for transmission / reception of the CCM frame. “TLV Offset” is an area for storing offset values of Type, Length, and Value of the CCM frame. “All′0x00” ”is an area for storing a state where the sequence number is not used. “MEP ID” is an area for storing an ID for identifying the MEP of the transmission source. The “MEG ID” is an area for storing an ID for identifying the MEG of the source MEP.

  “TxFCf” is an area for storing a local counter at the time of CCM frame transmission. “RxFCb” is an area for storing a local counter at the time of reception of the final CCM frame from the opposite MEP. “TxFCb” is an area for storing the final TxFCf value received from the CCM frame from the opposite MEP. “Reserved” is a reserved area. In the figure, “(All‘ 0x00 ’)” is unused in “TxFCf”, “RxFCb”, “TxFCb”, and “Reserved”.

  “TLV type” is an area for storing the frame type in the reserved area. “TLV length” is an area for storing the frame size in the reserved area. “Value” is an area for storing a value in the reserved area. “FCS” is an area for error detection using a checksum for error detection.

  FIG. 3B is an explanatory diagram illustrating an example of a TLV type of a CCM frame. FIG. 3C is an explanatory diagram illustrating an example of a TLV format of a CCM frame. As shown in FIG. 3B, each of the transmission apparatuses 105 and 107 to 114 uses a “Reserved” Type Value (“33-66” in the case of ITU-T), and will be described later in that Value area. Stores information related to transmission time.

  The stored transmission time information includes, for example, date and time information, and the time is preferably information up to, for example, milliseconds. However, date information need not be included.

(Functional configuration of transmission equipment)
4 to 6 are explanatory diagrams illustrating an example of a functional configuration of the transmission apparatus according to the embodiment. FIG. 4 shows an example of a functional configuration of the transmission apparatus (MEP) 105. In FIG. 4, a transmission apparatus (MEP) 105 includes a transmission processing unit 402 that performs CCM frame transmission processing, and a device management unit 403 that performs management within the apparatus. The transmission apparatus (MEP) 105 may also include a reception processing unit, but the illustration and description of the reception processing unit are omitted in FIG.

  The transmission processing unit 402 includes a CCM frame generation unit 410, a time insertion unit 411, and a CCM frame transmission unit 412. The device management unit 403 includes an in-device operating system switching unit 431 and an in-device time management unit 432. In FIG. 4, the OpS device 120 connected to the transmission device (MEP) 105 includes an inter-device operation system switching unit 441 and an inter-device time management unit 442.

  The CCM frame generation unit 410 generates a CCM frame having the format shown in FIG. 3A, for example. Specifically, the CCM frame generation unit 410 can realize its function by, for example, the CPU 201 shown in FIG.

  The time insertion unit 411 manages the time when the CCM frame generated by the CCM frame generation unit 410 is transmitted to the next stage transmission apparatus (specifically, for example, the transmission apparatus (MIP) 107 in FIG. 1). The time is acquired from the unit 432 and inserted (stored) in the TLV value of the CCM frame. The time when the CCM frame is actually transmitted is later than the time (by the time for inserting the time into the CCM frame), but this time is referred to as “transmission time” for convenience of explanation. It is desirable to acquire the transmission time at the same reference timing in each transmission apparatus. Specifically, the function of the time insertion unit 411 can be realized by, for example, the CPU 201 shown in FIG.

  The CCM frame transmission unit 412 transmits the CCM frame in which the transmission time is inserted by the time insertion unit 411 to the next transmission device (transmission device (MIP) 107 in FIG. 1). Specifically, the CCM frame transmission unit 412 can realize its function by, for example, the output interface 204 shown in FIG.

  The in-device operation system switching unit 431 controls a switch or the like (not shown) in the transmission apparatus (MEP) 105 to control operation system switching in the apparatus. Specifically, the in-device operation system switching unit 431 can realize its function by the CPU 201 shown in FIG. 2, for example.

  The in-device time management unit 432 manages the time of each unit in the transmission device (MEP) 105 in synchronization with the inter-device time management unit 442 of the OpS device 120. In response to the time acquisition request from the time insertion unit 411, the time at the requested time is passed to the time insertion unit 411. Specifically, the in-device time management unit 432 can realize its function by the CPU 201 shown in FIG. 2, for example.

  The inter-apparatus operation system switching unit 441 of the OpS apparatus 120 is connected to each transmission apparatus of the transmission system 100. The intra-apparatus operation system switching unit 431 in each transmission apparatus including the SWs 115 to 118 and the in-apparatus operation system switching unit 431. And switching control of the operation system in the entire transmission system 100 based on a failure sign across the transmission apparatuses. Specifically, the inter-apparatus operation system switching unit 441 can realize its function by a CPU (not shown) included in the OpS apparatus 120.

  The inter-device time management unit 442 of the OpS device 120 manages the time in the transmission system 100 in synchronization with the in-device time management device in each transmission device including the in-device time management unit 432. Therefore, the in-device time management unit in each transmission device including the in-device time management unit 432 acquires the time information from the inter-device time management unit 442 and sets the time in the in-device time management unit 432 as a transmission device. Time synchronization can be achieved. Specifically, the inter-device time management unit 442 can realize its function by a CPU (not shown) included in the OpS device 120.

  FIG. 5 shows an example of the functional configuration of the transmission apparatus (MEP) 106. In FIG. 5, the transmission apparatus (MEP) 106 includes a reception processing unit 501 that performs CCM frame reception processing and a device management unit 503 that performs management within the apparatus. The transmission apparatus (MEP) 106 may also include a transmission processing unit, but the illustration and description of the transmission processing unit are omitted in FIG.

  The reception processing device 501 includes a CCM frame reception unit 511, a reception time detection unit 512, an insertion time extraction unit 513, a delay amount calculation unit 514, a delay amount information storage unit 515, and a failure sign determination unit 516. Have.

  The CCM frame receiving unit 511 receives the CCM frame in which the transmission time is inserted in the previous transmission apparatus (transmission apparatus (MIP) 110 in FIG. 1) from the previous transmission apparatus. The CCM frame receiving unit 511 extracts a CCM frame from the received packet. Specifically, the CCM frame receiving unit 511 can realize its function by, for example, the input interface 203 shown in FIG.

  The reception time detection unit 512 detects the reception time when the CCM frame is received from the previous transmission apparatus (transmission apparatus (MIP) 110). The reception time detection unit 512 detects the reception time by, for example, obtaining the time when the CCM frame is received from the in-device time management unit 532. The received reception time may be the arrival time when the CCM frame arrives at the transmission apparatus (MEP) 106, or may be the time when the CCM frame is extracted from the received packet. This time is referred to as “reception time” for convenience of explanation. It is desirable to obtain the reception time at the same reference timing in each transmission apparatus. Specifically, the reception time detection unit 512 can realize its function by the CPU 201 shown in FIG. 2, for example.

  The insertion time extraction unit 513 transmits from the CCM frame received from the transmission apparatus (transmission apparatus (MIP) 110) in the transmission apparatus (transmission apparatus (MIP) 110), for example, the transmission time inserted in the TLV Value of the CCC format. To extract. Specifically, the insertion time extraction unit 513 can realize its function by, for example, the CPU 201 shown in FIG.

  The delay amount calculation unit 514 calculates a delay amount based on the transmission time extracted by the insertion time extraction unit 513 and the reception time detected by the reception time detection unit 512. The amount of delay is calculated, for example, by subtracting the transmission time from the reception time (delay time = reception time−transmission time). Specifically, the delay amount calculation unit 514 can realize its function by, for example, the CPU 201 shown in FIG.

  The delay amount information storage unit 515 stores information regarding the delay amount calculated by the delay amount calculation unit 514. The delay amount information storage unit 515 realizes its function by, for example, a RAM (not shown).

  The failure sign determination unit 516 determines whether to perform switching between the active system and the non-operational system based on the delay amount calculated by the delay amount calculation unit 514 and stored in the delay amount information storage unit 515. Specifically, the failure sign determination unit 516 can realize its function by, for example, the CPU 201 shown in FIG.

  Specifically, the failure sign determination unit 516 may determine to perform switching between the active system and the non-operating system when the delay amount exceeds a predetermined threshold value. In other words, when the value extension exceeds a predetermined threshold even once, switching between the active system and the non-operating system is executed.

  Further, the failure sign determination unit 516 operates when the number of times that the delay amount exceeds a predetermined threshold reaches a predetermined number based on the information about the delay amount stored in the delay amount information storage unit 515. It may be determined to perform switching between the active system and the non-operating system. That is, for example, when the predetermined number of times is three, even if the amount of delay applied to the information stored in the delay amount information storage unit 515 exceeds a predetermined threshold value once or twice, the operation system is not It may be determined that the switching between the active system and the non-operating system is executed only after a predetermined threshold value is exceeded for the third time without switching the active system.

  In this case, even if the delay amount exceeds the predetermined threshold value once or twice, when the predetermined amount of CCM frames is received thereafter, the delay amount is continuously below the predetermined value. May be reset once or twice.

  In addition, the failure sign determination unit 516 determines that the number of times that the delay amount exceeds a predetermined threshold has reached a predetermined number of times based on the information about the delay amount stored in the delay amount information storage unit 515. In addition, it may be decided to perform switching between the active system and the non-active system. That is, if the predetermined number of times is 3, the third time even if the delay amount of the information stored in the delay amount information storage unit 515 exceeds the predetermined threshold value once or twice continuously. If the predetermined threshold value is not exceeded, the switching between the active system and the non-operating system may not be performed, and the counting may be performed again from the first time. Then, it is determined that switching between the active system and the non-active system is executed only when the threshold value is exceeded three times in succession.

  The failure sign determination unit 516 may combine these methods. Specifically, for example, when a plurality of threshold values are provided and the first threshold value is exceeded more than once in succession, it is decided to perform switching between the active system and the non-active system To do. In the case of the second threshold value having a larger delay amount than the first threshold value, it is determined that switching between the active system and the non-operating system is executed when a plurality of times are exceeded. In the case of the third threshold value having a delay amount that is larger than the second threshold value, it may be determined to perform switching between the active system and the non-operating system if it exceeds even once. .

  In addition, these threshold values may be set differently for each transmission apparatus. For example, the threshold value may be set lower in the transmission apparatus in a place where high reliability is required than in other transmission apparatuses. Further, these threshold values can be made variable depending on, for example, the operating time of the transmission apparatus. For example, since the reliability of the transmission apparatus decreases as the operating time increases, the threshold value is set low. If the threshold value is lowered, switching between the active system and the non-operating system is facilitated. Therefore, when higher reliability is required, the threshold value may be set low.

  In any case, the failure predictor determination unit 516 monitors a change in the delay amount calculated by the delay amount calculation unit 514 or stored in the delay amount information storage unit 515, thereby indicating a failure sign based on the change. This is to determine whether or not to switch between the active system and the non-active system.

  The device management unit 503 includes an in-device operating system switching unit 531 and an in-device time management unit 532. Here, the in-device operating system switching unit 531 controls a switch or the like not shown in the transmission device (MEP) 106 based on the determination result by the failure sign determining unit 516, so that the operating system in the device Perform switching control. Specifically, the in-device operation system switching unit 531 can realize its function by the CPU 201 shown in FIG. 2, for example.

  The in-device time management unit 532 manages the time of each unit in the transmission device (MEP) 106 in synchronization with the inter-device time management unit 542 of the OpS device 120. In response to the time acquisition request from the reception time detection unit 512, the time at the requested time is passed to the reception time detection unit 512. Specifically, the in-device time management unit 532 can realize its function by the CPU 201 shown in FIG. 2, for example.

  The OpS device 120 connected to the transmission device (MEP) 106 includes an inter-device operation system switching unit 541 and an inter-device time management unit 542. The inter-apparatus operation system switching unit 541 of the OpS apparatus 120 and the inter-apparatus time management section 542 of the OpS apparatus 120 are the inter-apparatus operation system switching section 441 of the OpS apparatus 120 and the inter-apparatus time management of the OpS apparatus 120 shown in FIG. It has the same configuration and function as the portion 442. Therefore, the description is omitted.

  FIG. 6 shows an example of the functional configuration of the transmission apparatuses (MIP) 107 to 114. 6, transmission apparatuses (MIP) 107 to 114 include a reception processing unit 601 that performs CCM frame reception processing, a transmission processing unit 602 that performs CCM frame transmission processing, and a device management unit 603 that performs internal management. And have.

  The reception processing device 601 includes a CCM frame reception unit 611, a reception time detection unit 612, an insertion time extraction unit 613, a delay amount calculation unit 614, a delay amount information storage unit 615, and a failure sign determination unit 616. Have. The CCM frame reception unit 611, the reception time detection unit 612, the insertion time extraction unit 613, the delay amount calculation unit 614, the delay amount information storage unit 615, and the failure sign determination unit 616 include the CCM frame reception unit 511 illustrated in FIG. The reception time detection unit 512, the insertion time extraction unit 513, the delay amount calculation unit 514, the delay amount information storage unit 515, and the failure sign determination unit 516 have the same configuration and function. Therefore, the description is omitted.

  The transmission processing unit 602 includes a time insertion unit 621 and a CCM frame transmission unit 622. The time insertion unit 621 obtains the time (transmission time) when transmitting the CCM frame received by the CCM frame reception unit 611 to the transmission device at the next stage from the in-device time management unit 632, and the transmission time is obtained from the CCM frame. Insert into the TLV Value.

  At that time, it is inserted so as to overwrite the transmission time already inserted in the preceding transmission apparatus. Therefore, the transmission time inserted in the previous transmission apparatus is deleted. Or you may make it add transmission time, leaving the transmission time already inserted in the transmission apparatus of the front | former stage. It is desirable to acquire the transmission time at the same reference timing in each transmission apparatus (MIP) 107-114.

  Further, the time insertion unit 621 may insert the reception time detected by the reception time detection unit 612 into the CCM frame instead of the transmission time. By doing so, it is possible to save processing (time) for newly acquiring the transmission time from the in-device time management unit 632.

  Further, the time insertion unit 621 may insert both the transmission time and the reception time into the CCM frame. By inserting both times into the CCM frame in this way, processing abnormality in the transmission devices (MIP) 107 to 114 (whether the processing has taken a predetermined time or more) is also checked. Can do. Further, when there is an acquisition error of transmission time or reception time, the acquisition error can be checked.

  Specifically, the function of the time insertion unit 621 can be realized by, for example, the CPU 201 shown in FIG.

  The CCM frame transmission unit 622 has the same configuration and function as the CCM frame transmission unit 412 illustrated in FIG. Therefore, the description is omitted.

  Further, the in-device operation system switching unit 631 and the in-device time management unit 632 of the device management unit 603 are the same as the in-device operation system switching unit 431 and the in-device time management unit 432 of FIG. 2 has the same configuration and function as the in-device operation system switching unit 531 and the in-device time management unit 532 of the device management unit 503 shown in FIG. Therefore, the description is omitted.

  Further, the OpS device 120 connected to the transmission devices (MIP) 107 to 114 includes an inter-device operating system switching unit 641 and an inter-device time management unit 642. The inter-device operation system switching unit 641 of the OpS device 120 and the inter-device time management unit 642 of the OpS device 120 are the inter-device operation system switching unit 441 of the OpS device 120 and the inter-device time management unit of the OpS device 120 shown in FIG. 442, having the same configuration and function as the inter-operation system switching unit 541 of the OpS device 120 and the inter-device time management unit 542 of the OpS device 120 shown in FIG. Therefore, the description is omitted.

(Delay amount calculation method)
FIG. 7 is an explanatory diagram of an example of delay amount calculation in the transmission system according to the embodiment. As shown in FIG. 7, a section (a) is defined between the transmission apparatus (MEP) 105 and the transmission apparatus (MIP) 107 (transmission apparatus (MIP) 111). Similarly, a section (b) is defined between the transmission apparatus (MIP) 107 (transmission apparatus (MIP) 111) and the transmission apparatus (MIP) 108 (transmission apparatus (MIP) 112), and the transmission apparatus (MIP) 108 (transmission apparatus). (MIP) 112) -Transmission device (MIP) 109 (Transmission device (MIP) 113) is defined as section (c), and Transmission device (MIP) 109 (Transmission device (MIP) 113) -Transmission device (MIP) 110 A section (d) is defined between (transmission apparatus (MIP) 114), and a section (e) is defined between transmission apparatus (MIP) 110 (transmission apparatus (MIP) 114) and transmission apparatus (MEP) 106.

  FIG. 7 shows an example of calculating the delay amount in the section (b). That is, when the CCM frame A into which the transmission device (MIP) 107 has inserted the transmission time A is the time (reception time) A when the transmission device (MIP) 108 is reached, the delay amount is the reception time A−the transmission time A. It becomes. Similarly, the delay amount of the CCM frame B received by the transmission apparatus (MIP) 108 is reception time B−transmission time B. The same applies to the CCM frame C and the CCM frame D.

  In this way, each time a CCM frame is received, the delay amount calculation unit 614 calculates the delay amount, and the delay amount information storage unit 615 can store information regarding the calculated delay amount. This is the same as the section (b) not only in the section (b) but also in the section (a) and the sections (c) to (e). Therefore, since the delay amount can be acquired within the PTN and between the PTNs, it is possible to determine a failure sign in each section based on the delay amount only by the processing in the transmission apparatuses 105 to 114 without using the OpS device 120. it can.

(Relationship between delay amount and failure sign)
Next, the relationship between the calculated delay amount and the failure sign will be described. In a transmission apparatus using a general L2 switch, a priority (ABS, H, M, L) is provided for each packet to be transmitted, thereby performing packet priority processing. The CCM frame is transmitted as the highest priority ABS (minimum delay).

  Accordingly, when the performance of reading from the memory is deteriorated due to a hardware failure or other failure in the transmission apparatus, packets including CCM frames are accumulated in the memory, so that transmission delay is gradually increased. Will increase. Eventually, a packet error occurs beyond the maximum capacity of the memory.

  Also, when the usable memory area is reduced due to a memory failure in the transmission apparatus, the time until packet reading increases, and accordingly, transmission delay gradually increases. After that, the memory failure area expands, and eventually a packet error occurs when the maximum capacity of the usable memory is exceeded.

  Thus, before a packet error finally occurs, a transmission delay occurs first, and the transmission delay gradually increases. Therefore, by calculating the amount of delay between each transmission device, by judging the failure sign based on this transmission delay, it is possible to detect the sign in advance before a packet error actually occurs It is.

(Transmission device processing procedure)
FIG. 8 is a flowchart illustrating an example of a CCM transmission process in the transmission apparatus according to the embodiment. The flowchart of FIG. 8 shows an example of CCM transmission processing in the transmission apparatus (MEP) 105 shown in FIG. In the flowchart of FIG. 8, it is first determined whether or not the CCM frame transmission timing has come (step S801).

  The CCM frame transmission timing is determined by agreement between MEPs. After waiting for the CCM frame transmission timing (step S801: No), when the CCM frame transmission timing is reached (step S801: Yes), the transmission time is acquired from the in-device time management unit 432 (step S802). .

  Then, the acquired transmission time is inserted into the generated CCM frame (step S803), and the CCM frame into which the transmission time is inserted is transmitted to the next stage transmission apparatus (transmission apparatus (MEP) 105 shown in FIG. 4). The next-stage transmission device transmits to the transmission device (MIP) 107) (step S804). Thereafter, the process returns to step S801 to wait for the next CCM frame transmission timing.

  FIG. 9 is a flowchart illustrating an example of CCM reception processing in the transmission apparatus according to the embodiment. The flowchart in FIG. 9 illustrates an example of CCM transmission processing in the transmission apparatus (MEP) 106 illustrated in FIG. 5 or the transmission apparatuses (MIP) 107 to 114 illustrated in FIG.

  In the flowchart of FIG. 9, it is determined whether or not a packet has been received from the previous transmission apparatus (step S901). Here, after waiting for reception of a packet (step S901: No), when a packet is received (step S901: Yes), a CCM frame is extracted from the received packet (step S902). Then, the reception time is acquired from the in-device time management unit 532 or 632 (step S903).

  Next, the transmission time is extracted from the CCM frame (step S904). Then, the transmission time extracted in step S904 is subtracted from the reception time acquired in step S903 (reception time-transmission time), a delay amount is calculated (step S905), and the delay amount (information related thereto) is accumulated. (Step S906).

  Then, it is determined whether or not the delay amount exceeds a threshold value (step S907). It may be determined whether or not the delay amount has exceeded a threshold value a predetermined number of times, or whether or not the delay amount has continuously exceeded the threshold value a predetermined number of times. Here, when the delay amount does not exceed the threshold value (step S907: No), the process returns to step S901, and thereafter, the processes after step S901 are repeated.

  On the other hand, if the delay amount exceeds the threshold value in step S907 (step S907: Yes), it is determined as a failure sign (step S908), and switching between the active system and the non-operating system is executed (step S909). Thereafter, the process returns to step S901.

  The processing shown in the flowchart of FIG. 9 is performed individually in each of the transmission apparatuses 106 to 114, and when a failure sign is determined in any of the transmission apparatuses, switching between the operating system and the non-operating system is executed individually. The The processing shown in the flowchart of FIG. 9 is performed not only in the active transmission devices (MIP) 107 to 110 but also in the non-active transmission devices (MIP) 111 to 114 at the present time. ing. Then, since the failure sign is determined in the non-operational transmission apparatus, it is possible to determine the appropriateness of the switching when executing the switching.

  FIG. 10 is a flowchart illustrating another example of the CCM transmission process in the transmission apparatus according to the embodiment. The flowchart in FIG. 10 illustrates an example of CCM transmission processing in the transmission apparatus (MEP) 106 illustrated in FIG. 5 or the transmission apparatuses (MIP) 107 to 114 illustrated in FIG.

  In the flowchart of FIG. 10, it is determined whether or not a packet has been received from the previous transmission apparatus (step S1001). Here, after waiting for reception of a packet (step S1001: No), when a packet is received (step S1001: Yes), a CCM frame is extracted from the received packet (step S1002). Then, the transmission time is acquired from the in-device time management unit 532 or 632 (step S1003).

  Then, the acquired transmission time is inserted into the extracted CCM frame (step S1004), and the CCM frame into which the transmission time is inserted is transmitted to the transmission device (for example, the transmission device (MEP) 105 shown in FIG. 4). Then, the transmission device at the next stage transmits to the transmission device (MIP) 107) (step S1005). Thereafter, the process returns to step S1001 to wait for the next CCM frame transmission timing.

  As described above, according to the transmission system, the transmission device, and the transmission method according to the embodiment, the monitoring frame in which the first time (the transmission time from the previous transmission device to the own device) is inserted in the previous transmission device. (CCM frame) is received from the preceding transmission device, the second time (reception time) when the monitoring frame is received is detected, the first time is extracted from the monitoring frame, and the first time and the second time Based on the time, the delay amount is calculated, and based on the delay amount, it is determined whether or not to switch between the active system and the non-operating system.

  As a result, a failure sign can be detected before a failure occurs in the main signal system, and the effect of the main signal is suppressed in a shorter time by switching between the active and non-operational systems based on the failure sign. be able to.

  Then, a third time (transmission time from the own apparatus to the next stage transmission apparatus) is inserted into the monitoring frame, and the monitoring frame with the third time inserted is transmitted to the next stage transmission apparatus. As a result, the transmission device at the next stage can determine a sign of failure based on the delay amount from the own device. In this way, each transmission device can independently determine a failure sign based on the delay amount from the previous transmission device. Therefore, since it is not necessary to use the OpS device 120 that performs control between the transmission devices in determining the sign of a failure, the load on the entire transmission system can be reduced accordingly.

  Specifically, when the delay amount exceeds a predetermined threshold, switching between the active system and the non-operating system is executed. As a result, a sign of failure can be determined more precisely. Alternatively, information on the delay amount is stored, and when the number of times that the delay amount exceeds a predetermined threshold reaches a predetermined time based on the stored information on the delay amount, switching between the active system and the non-operating system is performed. Execute. Or, information on the delay amount is stored, and when the number of times that the delay amount exceeds a predetermined threshold reaches a predetermined number of times based on the stored information on the delay amount, the operation system and the non-operation Decide to perform system switchover. As a result, it is possible to distinguish whether the increase in the delay amount is a transient phenomenon or a sign of a failure, and to suppress switching between useless and non-use systems.

  In this way, it is possible to more reliably determine a sign of a failure that cannot be detected only by transmitting and receiving a CCM frame, and to switch between active and non-active based on the sign of the failure. By suppressing it, it is possible to improve the reliability of communication in the entire network of the transmission system.

  The following additional notes are disclosed with respect to the embodiment described above.

(Supplementary note 1) A transmission system including a first transmission device and a second transmission device and having a redundant configuration of an active system and a non-operating system,
The first transmission device is
An insertion unit for inserting the first time into the generated monitoring frame;
A transmission unit for transmitting the monitoring frame in which the first time is inserted to the second transmission device;
Have
The second transmission device is
A receiving unit that receives from the first transmission device a monitoring frame in which the first time is inserted;
A detection unit for detecting a second time when the monitoring frame is received;
An extraction unit for extracting the first time from the monitoring frame;
A calculating unit that calculates a delay amount based on the first time and the second time;
A determination unit that determines whether to perform switching between the active system and the non-active system based on the delay amount;
A transmission system comprising:

(Supplementary note 2) When the delay amount exceeds a predetermined threshold, the determination unit of the second transmission apparatus determines to perform switching between the active system and the non-operating system. The transmission system according to Supplementary Note 1, wherein the transmission system is characterized.

(Supplementary Note 3) The second transmission device includes a storage unit that stores information on the delay amount,
The determination unit of the second transmission device, when the number of times that the delay amount exceeds a predetermined threshold reaches a predetermined time, based on information on the delay amount stored in the storage unit, The transmission system according to appendix 1, wherein switching between the active system and the non-active system is determined to be performed.

(Supplementary Note 4) The second transmission device includes a storage unit that stores information on the delay amount,
The determination unit of the second transmission device, when the number of times that the delay amount exceeds a predetermined threshold has reached a predetermined number of times based on information on the delay amount stored in the storage unit The transmission system according to appendix 1, wherein switching between the active system and the non-active system is determined.

(Supplementary Note 5) A transmission system including a first transmission device, a second transmission device, and a third transmission device, and having a redundant configuration of an operational system and a non-operational system,
The first transmission device is
An insertion unit for inserting the first time into the generated monitoring frame;
A transmission unit for transmitting the monitoring frame in which the first time is inserted to the second transmission device;
Have
The second transmission device is
A receiving unit that receives from the first transmission device a monitoring frame in which the first time is inserted;
A detection unit for detecting a second time when the monitoring frame is received;
An extraction unit for extracting the first time from the monitoring frame;
A calculating unit that calculates a delay amount based on the first time and the second time;
A determination unit that determines whether to perform switching between the active system and the non-active system based on the delay amount;
An insertion unit for inserting a third time into the monitoring frame;
A transmission unit for transmitting the monitoring frame in which the third time is inserted to the third transmission device;
Have
The third transmission device is
A receiving unit that receives the monitoring frame in which the third time is inserted from the second transmission device;
A detection unit for detecting a fourth time at which the monitoring frame is received;
An extraction unit for extracting the third time from the monitoring frame;
A calculation unit that calculates a delay amount based on the third time and the fourth time;
A determination unit that determines whether to perform switching between the active system and the non-active system based on the delay amount;
A transmission system comprising:

(Supplementary note 6) The transmission system according to any one of supplementary notes 1 to 5, wherein the monitoring frame is a CCM (Continuity Check Messages) frame.

(Supplementary note 7) A transmission apparatus in a transmission system having a redundant configuration of an active system and a non-operating system,
A receiving unit that receives the monitoring frame in which the first time is inserted in the previous transmission device from the previous transmission device;
A detection unit for detecting a second time when the monitoring frame is received;
An extraction unit for extracting the first time from the monitoring frame;
A calculating unit that calculates a delay amount based on the first time and the second time;
A determination unit that determines whether to perform switching between the active system and the non-active system based on the delay amount;
A transmission apparatus comprising:

(Supplementary note 8) The supplementary note 7, wherein the determination unit determines to perform switching between the active system and the non-active system when the delay amount exceeds a predetermined threshold value. Transmission equipment.

(Additional remark 9) It has a storage part which memorizes information about the amount of delay,
When the number of times the delay amount exceeds a predetermined threshold reaches a predetermined number based on the information about the delay amount stored in the storage unit, the determination unit and the non-operational system 8. The transmission apparatus according to appendix 7, wherein it is determined to perform the switching.

(Additional remark 10) It has a memory | storage part which memorize | stores the information regarding the said delay amount,
When the number of times that the delay amount has exceeded a predetermined threshold has reached a predetermined number of times based on information on the delay amount stored in the storage unit, the determination unit and the active system and the The transmission apparatus according to appendix 7, wherein it is determined to perform non-operational switching.

(Supplementary Note 11) An insertion unit that inserts a third time into the monitoring frame;
A transmission unit that transmits the monitoring frame in which the third time is inserted to a transmission device in the next stage;
The transmission apparatus according to any one of appendices 7 to 10, wherein the transmission apparatus includes:

(Supplementary note 12) The transmission apparatus according to any one of Supplementary notes 7 to 11, wherein the monitoring frame is a CCM (Continuity Check Messages) frame.

(Supplementary note 13) A transmission method for transmitting a monitoring frame between transmission apparatuses in a transmission system having an active and non-operating redundant configuration,
A computer of the transmission device;
The monitoring frame in which the first time is inserted in the transmission device in the previous stage is received from the transmission device in the previous stage,
Detecting a second time when the monitoring frame is received;
Extracting the first time from the monitoring frame;
Based on the first time and the second time, a delay amount is calculated,
A transmission method characterized by determining whether to perform switching between the active system and the non-active system based on the delay amount.

(Additional remark 14) The computer of the said transmission apparatus is,
14. The transmission method according to appendix 13, wherein when the delay amount exceeds a predetermined threshold value, it is determined to perform switching between the active system and the non-active system.

(Additional remark 15) The computer of the said transmission apparatus,
The information about the delay amount is stored, and when the number of times the delay amount exceeds a predetermined threshold reaches a predetermined time based on the stored information about the delay amount, the active system and the non-operating system 14. The transmission method according to appendix 13, characterized in that it is determined to execute the switching.

(Supplementary Note 16) A computer of the transmission apparatus is
The information about the delay amount is stored, and when the number of times that the delay amount exceeds a predetermined threshold reaches a predetermined number of times based on the stored information about the delay amount, the operational system and the 14. The transmission method according to appendix 13, wherein it is determined to perform non-operational switching.

(Supplementary Note 17) A computer of the transmission apparatus is
Inserting a third time in the monitoring frame;
The transmission method according to any one of appendices 13 to 16, wherein the monitoring frame in which the third time is inserted is transmitted to a transmission device in the next stage.

(Supplementary note 18) The transmission apparatus according to any one of supplementary notes 13 to 17, wherein the monitoring frame is a CCM (Continuity Check Messages) frame.

100 Transmission system 101-104 PTN (Packet transport networks)
105, 106 Transmission equipment (MEP)
107-114 Transmission equipment (MIP)
115-118 Switch (SW)
120 OpS (Operation System) Device 200 Line Card 201 CPU (Central Processing Unit)
202 L2 switch 203 Input interface 204 Output interface 402, 602 Transmission processing unit 403, 503, 603 Device management unit 410 CCM (Continuity Check Messages) frame generation unit 411, 621 Time insertion unit 412, 622 CCM frame transmission unit 431, 531, 631 Intra-device operation system switching unit 432, 532, 632 Intra-device time management unit 441, 541, 641 Inter-device operation system switching unit 442, 542, 642 Inter-device time management unit 501, 601 Reception processing unit 511, 611 CCM frame reception Unit 512, 612 Reception time detection unit 513, 613 Insertion time extraction unit 514, 614 Delay amount calculation unit 515, 615 Delay amount information storage unit 516, 616 Fault sign determination unit

Claims (8)

A transmission system including a first transmission device and a second transmission device, and having a redundant configuration of an active system and a non-operating system,
The first transmission device is
An insertion unit for inserting the first time into the generated monitoring frame;
A transmission unit for transmitting the monitoring frame in which the first time is inserted to the second transmission device;
Have
The second transmission device is
A receiving unit that receives from the first transmission device a monitoring frame in which the first time is inserted;
A detection unit for detecting a second time when the monitoring frame is received;
An extraction unit for extracting the first time from the monitoring frame;
A calculating unit that calculates a delay amount based on the first time and the second time;
A determination unit that determines whether to perform switching between the active system and the non-active system based on the delay amount;
A transmission system comprising:   The determination unit of the second transmission device determines to perform switching between the active system and the non-operating system when the delay amount exceeds a predetermined threshold value. Item 4. The transmission system according to Item 1. The second transmission device includes a storage unit that stores information on the delay amount,
The determination unit of the second transmission device, when the number of times that the delay amount exceeds a predetermined threshold reaches a predetermined time, based on information on the delay amount stored in the storage unit, The transmission system according to claim 1, wherein it is determined to perform switching between the active system and the non-active system. The second transmission device includes a storage unit that stores information on the delay amount,
The determination unit of the second transmission device, when the number of times that the delay amount exceeds a predetermined threshold has reached a predetermined number of times based on information on the delay amount stored in the storage unit 2. The transmission system according to claim 1, further comprising: performing switching between the active system and the non-active system. A transmission system including a first transmission device, a second transmission device, and a third transmission device, and having a redundant configuration of an operation system and a non-operation system,
The first transmission device is
An insertion unit for inserting the first time into the generated monitoring frame;
A transmission unit for transmitting the monitoring frame in which the first time is inserted to the second transmission device;
Have
The second transmission device is
A receiving unit that receives from the first transmission device a monitoring frame in which the first time is inserted;
A detection unit for detecting a second time when the monitoring frame is received;
An extraction unit for extracting the first time from the monitoring frame;
A calculating unit that calculates a delay amount based on the first time and the second time;
A determination unit that determines whether to perform switching between the active system and the non-active system based on the delay amount;
An insertion unit for inserting a third time into the monitoring frame;
A transmission unit for transmitting the monitoring frame in which the third time is inserted to the third transmission device;
Have
The third transmission device is
A receiving unit that receives the monitoring frame in which the third time is inserted from the second transmission device;
A detection unit for detecting a fourth time at which the monitoring frame is received;
An extraction unit for extracting the third time from the monitoring frame;
A calculation unit that calculates a delay amount based on the third time and the fourth time;
A determination unit that determines whether to perform switching between the active system and the non-active system based on the delay amount;
A transmission system comprising:   The transmission system according to claim 1, wherein the monitoring frame is a CCM (Continuity Check Messages) frame. A transmission device in a transmission system having a redundant configuration of an active system and a non-operating system,
A receiving unit that receives the monitoring frame in which the first time is inserted in the previous transmission device from the previous transmission device;
A detection unit for detecting a second time when the monitoring frame is received;
An extraction unit for extracting the first time from the monitoring frame;
A calculating unit that calculates a delay amount based on the first time and the second time;
A determination unit that determines whether to perform switching between the active system and the non-active system based on the delay amount;
A transmission apparatus comprising: A transmission method for transmitting a monitoring frame between transmission devices in a transmission system having a redundant configuration of an active system and a non-active system,
A computer of the transmission device;
The monitoring frame in which the first time is inserted in the transmission device in the previous stage is received from the transmission device in the previous stage,
Detecting a second time when the monitoring frame is received;
Extracting the first time from the monitoring frame;
Based on the first time and the second time, a delay amount is calculated,
A transmission method characterized by determining whether to perform switching between the active system and the non-active system based on the delay amount.

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