JP2022012595A - Network system and optical transceiver - Google Patents

Abstract

To provide an optical transceiver and a network system capable of normally performing discovery between a higher-level device corresponding to the IEEE 802.3ah standard and a lower-level device corresponding to the TS-1000 standard.SOLUTION: A frame conversion circuit 62 in an optical transceiver 16 mutually converts a maintenance frame based on the TS-1000 standard used with a lower-level device 17 and an OAM frame based on the IEEE 802.3ah standard used with a higher-level device 15. At this time, the frame conversion circuit 62 converts an information OAM frame FRE (IFM) used in the discovery into a state request maintenance frame FRS (SRQ) indicating a state notification request, and converts the state response maintenance frame FRS (SRS) indicating a state notification response into the information OAM frame FRE (IFM).SELECTED DRAWING: Figure 6

Description

The present invention relates to a network system and an optical transceiver, for example, a technique of a maintenance management function based on the TTC (Telecommunication Technology Committee) TS-1000 standard.

Patent Document 1 discloses a method of maintaining a plurality of media converters sequentially connected from upstream to downstream using a maintenance frame. The most upstream media converter transmits the maintenance frame containing the initial value of the counter to the downstream, and each downstream media converter sequentially transmits the maintenance frame received from the upstream to the downstream while updating the count value of the counter. ..

Japanese Unexamined Patent Publication No. 2004-120327

The TS-1000 standard is known as an optical communication standard of 100 Mbps. The TS-1000 standard has existed for a long time, and even now, there are many network systems in which each device corresponding to the TS-1000 standard is installed. As a specific example, there is a configuration in which a lower device (100 Mbps media converter, etc.) is installed in the lower network, and a higher device (100 Mbps switch device, etc.) accommodating the lower device is installed in the upper network. .. Maintenance management such as loop test and notification of failure information is usually performed between the lower device and the existing upper device by using the maintenance frame defined by the TS-1000 standard.

On the other hand, for example, in a higher-level network, an existing higher-level device (such as a switch device of 100 Mbps) may be replaced with a new higher-performance device (such as a switch device of 1 Gbps or more). In this case, the new higher-level device supports the maintenance management function of the IEEE 802.3ah standard, but often does not support the maintenance management function of the TS-1000 standard. Therefore, in order to realize maintenance management even in such a case, it is conceivable to use an optical transceiver as shown in Reference (Japanese Patent Application No. 2019-156067). The optical transceiver can convert between the IEEE 802.3ah standard supported by the new higher-level device and the TS-1000 standard supported by the lower-level device.

However, when such an optical transceiver is used, there is a possibility that communication for various maintenance management cannot be sufficiently performed between the upper device and the lower device. Specifically, in the IEEE 802.3ah standard, it is required to recognize each other by using the discovery function as a preprocessing when starting communication for various maintenance management. On the other hand, in the TS-1000 standard, such a concept of discovery does not exist. Therefore, there is a possibility that the discovery cannot be completed and, by extension, communication for various maintenance management cannot be started.

The present invention has been made in view of the above, and one of the objects thereof is between a higher-level device corresponding to the IEEE 802.3ah standard and a lower-level device corresponding to the TS-1000 standard. The purpose is to provide optical transceivers and network systems capable of successful discovery.

The above and other objects and novel features of the invention will become apparent from the description and accompanying drawings herein.

A brief description of a typical embodiment of the inventions disclosed in the present application is as follows.

The optical transceiver according to one embodiment has an optical connector that can be connected to a lower device via an optical fiber, an electric connector that can be connected to a port of the higher device, an optical signal interface, and a frame conversion circuit. The optical signal interface converts the received electric signal into an optical signal and transmits it to the optical connector, and converts the optical signal from the optical connector into an electric signal and transmits it to the electric connector side. The frame conversion circuit is provided between the optical signal interface and the electric connector, and is based on the maintenance frame based on the TS-1000 standard used between the lower device and the IEEE 802.3ah standard used between the upper device. Converts to and from the based OAM frame. At this time, the frame conversion circuit converts the information OAM frame, which is an OAM frame used in discovery, into a state request maintenance frame, which is a maintenance frame representing a status notification request, and a state response, which is a maintenance frame representing a status notification response. Convert the maintenance frame to the information OAM frame.

Among the inventions disclosed in the present application, the effect obtained by a typical embodiment will be briefly described between a higher-level device corresponding to the IEEE 802.3ah standard and a lower-level device corresponding to the TS-1000 standard. , Discovery can be performed normally.

It is a schematic diagram which shows the structural example of the network system by Embodiment 1 of this invention. (A) is a schematic diagram showing a configuration example of a maintenance frame based on the TS-1000 standard, and (b) is a schematic diagram showing a configuration example of an OAM frame (EFM) based on the IEEE 802.3ah standard. It is a block diagram which shows the schematic structure example of the optical transceiver in FIG. It is a block diagram which shows the schematic structure example of the frame processing circuit in FIG. It is a figure explaining an example of the processing content of a part of the frame conversion circuit in FIG. It is a sequence diagram which shows the operation example at the time of discovery using the frame conversion circuit of FIG. 5 in the network system of FIG. FIG. 3 is a block diagram showing a schematic configuration example of the frame processing circuit in FIG. 3 in the optical transceiver according to the second embodiment of the present invention. It is a sequence diagram which shows the operation example at the time of discovery using the frame processing circuit of FIG. 7 in the network system of FIG.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In addition, in all the drawings for explaining the embodiment, the same members are designated by the same reference numerals in principle, and the repeated description thereof will be omitted.

(Embodiment 1)
<< Outline of network system >>
FIG. 1 is a schematic diagram showing a configuration example of a network system according to the first embodiment of the present invention. The network system shown in FIG. 1 has an upper network 10 and a plurality of lower networks 11 [1] to 11 [n]. The upper network 10 and each of the lower networks 11 [1] to 11 [n] are connected by an optical fiber 12. The host network 10 is a network for a communication carrier including a plurality of host devices 15. The lower network is a network for users (corporations, etc.) including the lower device 17 and the user terminal 18.

The host device 15 is, for example, a layer 2 (L2) switch device, a layer 3 (L3) switch device, a media converter, or the like corresponding to a communication speed of 1 Gbps or more. The host device 15 comprises one or more port PTs. The port PT is, for example, an SFP (Small Form factor Pluggable) port corresponding to the 1000BASE-X standard. Here, optical transceivers 16 [1] to 16 [n] are appropriately mounted on the plurality of port PTs of the host device 15.

The optical transceivers 16 [1] to 16 [n] (collectively referred to by reference numerals 16) are, for example, SFP transceivers (SFP modules) and the like. The optical transceiver 16 has an electric connector (not shown) connected to the port (SFP port) PT of the upper device 15 and an optical connector connected to the optical fiber 12 and connected to the lower device 17 via the optical fiber 12. It has a CNo. The optical connector CNo is, for example, an LC connector or the like.

The lower device 17 is, for example, a media converter or the like, and is connected to the optical transceiver 16 (and thus the higher device 15) via the optical fiber 12. The lower device 17 is a device corresponding to the TS-1000 standard, which is an optical communication standard of 100 Mbps. The user terminal 18 is connected to the lower device 17 via, for example, an Ethernet (registered trademark) cable 19, and is connected to the optical transceiver 16 (and thus the higher device 15) via the lower device 17. An L2 switch device, an L3 switch device, or the like may be appropriately installed between the user terminal 18 and the lower device 17.

Here, it is assumed that the host device 15 is, for example, a switch device of 100 Mbps, which is a corresponding device of the TS-1000 standard. In this case, maintenance management such as loop test and notification of failure information can be performed between the upper device 15 and the lower device 17 by using the maintenance frame based on the TS-1000 standard. However, when the host device 15 is replaced with a new higher-performance device 15 such as a switch device of 1 Gbps or more, the new host device 15 often does not comply with the TS-1000 standard.

On the other hand, the new host device 15 usually has a maintenance management function using a general Ethernet frame instead of a dedicated maintenance frame as in the TS-1000 standard. Such a maintenance function is called Ethernet OAM (Operations, Administration, Maintenance). The specifications of Ethernet OAM are defined by the IEEE 802.3ah standard (also called EFM (Ethernet in First Mile)) and the like. Based on the standard, it is possible to mainly manage the communication status on a point-to-point basis by using the OAM frame (EFM) defined in the standard.

The optical transceiver 16 is for enabling maintenance management between the new higher-level device 15 corresponding to the IEEE 802.3ah standard and the lower-level device 17 corresponding to the TS-1000 standard. Specifically, the optical transceiver 16 mutually converts an OAM frame (EFM) based on the IEEE 802.3ah standard and a maintenance frame based on the TS-1000 standard.

《Frame structure》
FIG. 2A is a schematic diagram showing a configuration example of a maintenance frame based on the TS-1000 standard, and FIG. 2B is a schematic diagram showing a configuration example of an OAM frame (EFM) based on the IEEE 802.3ah standard. It is a figure. The maintenance frame FRS shown in FIG. 2A is a 12-byte frame, which is a 1-byte preamble (PRE) 22, a 2-byte control information 23, a 2-byte status information 24, and a 6-byte management information. It includes 25 and a 1-byte CRC (Cyclic Redundancy Check) 26. Briefly, the control information 23 represents an instruction, a request content, or the like, and the state information 24 represents a failure information or the like such as a power supply failure or a link failure. The management information 25 represents a vendor code and a model number for each vendor.

The OAM frame FRE shown in FIG. 2B is a kind of Ethernet frame, and includes a header 30, a payload (EFM data) 31, and a 4-byte FCS (Frame Check Sequence) 32. The header 30 includes an 8-byte preamble (PRE) 33, a 6-byte destination MAC (Media Access Control) address (DMAC) 34, a 6-byte source MAC address (SMAC) 35, and a 2-byte type (TYP). ) 36.

The payload (EFM data) 31 is 46 bytes or more, and includes a 1-byte subtype 40, a 2-byte flag 41, a 1-byte code 42, and 42-byte or more data (including padding data) 43. .. Briefly, the flag 41 represents failure information and the like, and the code 42 represents an instruction, a request content and the like. The data 43 includes a single or a plurality of TLVs (Type Length Values) 44 [1] to 44 [n] defined for each content of the code 42.

Here, in the OAM frame FRE, the destination MAC address (DMAC) 34 is defined as the multicast address “Ox0180C200002” based on the IEEE 802.3ah standard. Further, the type (TYP) 36 is defined as "Ox8809" representing a slow protocol, and the subtype 40 is defined as "Ox03" representing an OAM frame.

<< Outline of optical transceiver >>
FIG. 3 is a block diagram showing a schematic configuration example of the optical transceiver in FIG. The optical transceiver 16 shown in FIG. 3 includes an optical connector CNo, an electric connector CNe, an optical signal interface (I / F) 48, an analog front end (AFE) circuit 47, a logic circuit 46, and an electric signal interface 45. , CPU (Central Processing Unit) 49. As described in FIG. 1, the optical connector CNo is an LC connector or the like connected to the optical fiber 12, and can be connected to the lower device 17 via the optical fiber 12. Further, the electric connector CNe is connectable (in other words, detachable) to the port (for example, SFP port) PT of the host device 15.

The optical signal interface 48 includes a laser diode LD and a photodiode PD. The laser diode LD converts the received electric signal into an optical signal and transmits it to the optical connector CNo. The photodiode PD converts an optical signal from the optical connector CNo into an electric signal and transmits it to the electric connector CNe side. The analog front-end circuit 47 is provided between the logic circuit 46 and the optical signal interface 48, and includes a driver 55 and a post-amplifier 56. The driver 55 drives the laser diode LD based on the electric signal from the logic circuit 46. The post amplifier 56 amplifies the electric signal from the photodiode PD and transmits it to the logic circuit 46.

The logic circuit 46 is provided between the AFE circuit 47 and the electric signal interface 45, and includes a frame processing circuit 53. The frame processing circuit 53 is mainly used between the maintenance frame FRS (FIG. 2A) used between the lower device 17 (that is, the optical connector CNo side) and the upper device 15 (that is, the electric connector CNe side). The OAM frame FRE (FIG. 2 (b)) used in the above is mutually converted.

The electric signal interface 45 is provided between the logic circuit 46 and the electric connector CNe, and includes a speed conversion circuit 51. The speed conversion circuit 51 is, for example, an SGMII (Serial Gigabit Media Independent Interface) or the like, and mutually converts the communication speed of the electric connector CNe and the communication speed of the logic circuit 46. Specifically, the speed conversion circuit 51 converts, for example, a frame of 1.25 Gbps from the electric connector CNe to 125 Mbps and transmits it to the logic circuit 46, and converts a frame of 125 Mbps from the logic circuit 46 to 1.25 Gbps. And send it to the electric connector CNe. The CPU 49 manages / controls the entire optical transceiver 16 based on a predetermined management / control program.

In FIG. 3, the analog front-end circuit 47 is composed of an IC (Integrated Circuit) or the like, and the optical signal interface 48 is composed of an OSA (Optical SubAssembly) or the like. The logic circuit 46 is composed of an FPGA (Field Programmable Gate Array), an ASIC (Application Specific Integrated Circuit), or the like. The electric signal interface 45 is mounted in the FPGA or ASIC constituting the logic circuit 46, or is configured by another ASIC or the like. The mounting form of each part is, of course, not limited to this, and can be appropriately changed, for example, by mounting the logic circuit 46 by software processing.

<< Details of frame processing circuit >>
FIG. 4 is a block diagram showing a schematic configuration example of the frame processing circuit in FIG. The frame processing circuit 53 shown in FIG. 4 includes frame buffers 60a and 60b, a frame identification circuit 61, and a frame conversion circuit 62. The frame buffer 60a operates in synchronization with, for example, a 125 MHz clock signal, and serially receives or transmits OAM frame FRE and various frames including other Ethernet frames to and from the electric connector CNe side. The frame buffer 60b operates, for example, in synchronization with a clock signal of 125 MHz, and performs serial reception or serial transmission of various frames including a maintenance frame FRS and an Ethernet frame with the optical connector CNo side.

The frame identification circuit 61 identifies whether or not the frame received by the frame buffers 60a and 60b is an OAM frame FRE or a maintenance frame FRS. When the received frame is an OAM frame FRE or a maintenance frame FRS, the frame identification circuit 61 transmits a conversion command to the frame conversion circuit 62. The frame conversion circuit 62 mutually converts the maintenance frame and the OAM frame FRE in response to the conversion instruction.

As a specific example, it is assumed that the frame buffer 60a serially receives various frames from the electric connector CNe side. The frame identification circuit 61 excludes whether the received frame is an OAM frame FRE or an OAM frame FRE based on the values of the destination MAC address (DMAC) 34, the type (TYP) 36, and the subtype 40 of the received frame, for example. Identify whether it is an Ethernet frame.

When the received frame is an OAM frame FRE, the frame identification circuit 61 transmits a conversion command to the frame conversion circuit 62. On the other hand, when the received frame is an Ethernet frame excluding the OAM frame FRE, the frame identification circuit 61 transmits the Ethernet frame in the frame buffer 60a as it is to the frame buffer 60b (and by extension, the optical connector CNo side).

The frame conversion circuit 62 converts the OAM frame FRE into the maintenance frame FRS based on a predetermined correspondence relationship in response to the conversion command from the frame identification circuit 61. Specifically, the frame conversion circuit 62 generates a maintenance frame FRS in the format shown in FIG. 2A in the frame buffer 60b. At this time, the frame conversion circuit 62 sets the management information 25 to a predetermined value.

Further, the frame conversion circuit 62 converts the control information 23 and the state information 24 into the payload (EFM data) 31 (specifically, the flag 41, the code 42, and the data 43) in the OAM frame FRE based on a predetermined correspondence relationship. ) Corresponds to the value. The frame buffer 60b serially transmits the maintenance frame FRS thus generated to the optical connector CNo side at a communication speed of 125 Mbps.

Next, it is assumed that the frame buffer 60b serially receives various frames from the optical connector CNo side. The frame identification circuit 61 identifies whether the received frame is a maintenance frame FRS or an Ethernet frame, for example, based on whether or not the length of the preamble (PRE) 22 of the received frame is 1 byte. .. In the maintenance frame FRS, the first bit of the control information 23 is set to "0", whereby the end point of the preamble (PRE) 22 of "1010 ..." can be identified. Further, the frame identification circuit 61 is based on, for example, that the bit [4: 7] (C4-C7) of the control information 23 is a fixed value of “0000” and that the received frame is 12 bytes. It may be recognized that the received frame is a maintenance frame FRS.

When the received frame is a maintenance frame FRS, the frame identification circuit 61 transmits a conversion command to the frame conversion circuit 62. On the other hand, when the received frame is an Ethernet frame, the frame identification circuit 61 transmits the Ethernet frame in the frame buffer 60b to the frame buffer 60a (and thus the electric connector CNe side) as it is.

The frame conversion circuit 62 converts the maintenance frame FRS into an OAM frame FRE in response to a conversion command from the frame identification circuit 61 based on a predetermined correspondence. Specifically, the frame conversion circuit 62 generates an OAM frame FRE in the format shown in FIG. 2B in the frame buffer 60a. At this time, the frame conversion circuit 62 shows the destination MAC address (DMAC) 34 and the type (TYP) 36 in the header 30 and the subtype 40 in the payload (EFM data) 31 in FIG. 2 (b). Set to a value like this.

Further, the frame conversion circuit 62 determines the source MAC address (SMAC) 35 in the header 30 by using, for example, the value of the MAC address preset in the optical transceiver 16. The frame conversion circuit 62 converts the value of the management information 25 in the maintenance frame FRS into an OUI (Organizationally Unique Identifier) in TLV44 [1] to 44 [n] of the OAM frame FRE. Further, the frame conversion circuit 62 defines the payload (EFM data) 31 as values corresponding to the control information 23 and the state information 24 in the maintenance frame FRS based on a predetermined correspondence relationship. The frame buffer 60a serially transmits the OAM frame FRE generated in this manner to the electric connector CNe side at a communication speed of 125 Mbps.

Here, for convenience of explanation, a configuration is shown in which the frame buffers 60a and 60b common to the frame conversion from the optical connector CNo side to the electric connector CNe side and the frame conversion in the opposite direction are used. However, in detail, the frame buffers 60a and 60b may be provided in each direction.

<< Details of frame conversion circuit >>
FIG. 5 is a diagram illustrating an example of processing contents of a part of the frame conversion circuit in FIG. FIG. 6 is a sequence diagram showing an operation example at the time of discovery using the frame conversion circuit of FIG. 5 in the network system of FIG. As described above, the frame conversion circuit 62 mutually converts the OAM frame FRE and the maintenance frame FRS. As one of them, the frame conversion circuit 62 mutually holds the correspondence relationship as shown in FIG. 5 in a memory, a logic gate, or the like, so that the OAM frame FRE used in the discovery and the predetermined maintenance frame FRS can be exchanged with each other. Convert to.

As mentioned above, the IEEE 802.3ah standard defines discovery. Discovery is a function of mainly causing the upper device 15 to detect a lower device 17 corresponding to the IEEE 802.3ah standard as a preprocessing when starting communication for various maintenance management. When the higher-level device 15 detects the lower-level device 17 corresponding to the IEEE 802.3ah standard, the discovery is completed. Further, after that, the higher-level device 15 needs to periodically communicate with the lower-level device 17 in order to maintain the completion state of the discovery.

Here, the operation of discovery will be described on the assumption that both the upper device 15 and the lower device 17 correspond to the IEEE 802.3ah standard. The upper device 15 transmits the OAM frame FRE to the lower device 17 at a predetermined interval (for example, 1 second interval, etc.), and the lower device 17 transmits the OAM frame FRE to the upper device 15 in response to the received frame. .. The OAM frame FRE used in this discovery is referred to as an information OAM frame FRE (IFM) in the specification.

As shown in FIG. 5, the information OAM frame FRE (IFM) is a frame in which "Ox00" representing information is stored in the code 42 and the discovery state is stored in the flag 41. Further, in the data 43 of FIG. 2B, information such as corresponding functions and setting contents of the own device (and the peer device recognized by the own device) is stored.

The higher-level device 15 transmits and receives an information OAM frame FRE (IFM) including the data 43 as described above to and from the lower-level device 17, so that the lower-level device 17 complies with the IEEE 802.3ah standard. And, it recognizes the corresponding functions in it and completes the discovery. However, even after that, the higher-level device 15 periodically (for example, at 1-second intervals) transmits the information OAM frame FRE (IFM) to the lower-level device 17.

On the other hand, if the discovery is not completed, the higher-level device 15 does not start communication for various maintenance management with the lower-level device 17. Further, the higher-level device 15 also stops communication for various maintenance management even when the information OAM frame FRE (IFM) from the lower-level device 17 is not received within a predetermined time. Therefore, in order to perform communication for various maintenance management, it is necessary to perform discovery normally. That is, it is necessary to complete the discovery and respond to the received information OAM frame FRE (IFM). However, in the TS-1000 standard, there is no such concept of discovery, and the function corresponding to the discovery is not specified.

Therefore, as shown in FIGS. 5 and 6, the frame conversion circuit 62 converts the information OAM frame FRE (IFM) into a state request maintenance frame FRS (SRQ) which is a maintenance frame FRS representing a state notification request. Further, the frame conversion circuit 62 converts the state response maintenance frame FRS (SRS), which is the maintenance frame FRS representing the state notification response, into the information OAM frame FRE (IFM).

The state request maintenance frame FRS (SRQ) and the state response maintenance frame FRS (SRS) are defined by the combination of each bit in the control information 23, as shown in FIG. In the TS-1000 standard, the lower device 17 that has received the state request maintenance frame FRS (SRQ) is specified to store the state of its own device in the state information 24 and then transmit the state response maintenance frame FRS (SRS). ing. The frame conversion circuit 62 realizes the discovery in the IEEE 802.3ah standard by utilizing the state notification request / response mechanism in the TS-1000 standard.

In the example of FIG. 6, in steps S101a to S101c, the optical transceiver 16 receives the information OAM frame FRE (IFM) from the host device 15 at a predetermined interval T1 (for example, 1 second interval). The frame conversion circuit 62 converts the information OAM frame FRE (IFM) into a state request maintenance frame FRS (SRQ) and transmits it to the lower device 17.

Further, the lower-level device 17 that has received the state request maintenance frame FRS (SRQ) transmits the state response maintenance frame FRS (SRS). The frame conversion circuit 62 converts the state response maintenance frame FRS (SRS) into an information OAM frame FRE (IFM) and transmits it to the host device 15. At this time, more specifically, it is necessary to store information such as corresponding functions and setting contents of the lower-level device 17 in the data 43 in the information OAM frame FRE (IFM). The frame conversion circuit 62 may, for example, fix the information of the lower device 17 in advance.

<< Main effect of Embodiment 1 >>
As described above, by using the method of the first embodiment, typically, the discovery is normally performed between the upper device 15 corresponding to the IEEE 802.3ah standard and the lower device 17 corresponding to the TS-1000 standard. It will be possible to do it. In this case, it is not necessary to make any particular changes to the higher-level device 15 and the lower-level device 17, and such an effect can be obtained simply by mounting the optical transceiver 16 on the higher-level device 15. .. Further, for example, there is no need to replace the existing lower device 17 with a new lower device 17 corresponding to the IEEE 802.3ah standard, and the replacement cost of the lower device 16 can be reduced.

(Embodiment 2)
<< Details of frame conversion circuit >>
Using the method of the first embodiment described above, as shown in FIG. 6, the lower device 17 transmits the state response maintenance frame FRS (SRS) at predetermined intervals T1. On the other hand, according to the TS-1000 standard, when transmitting the maintenance frame FRS, the user frame may be destroyed and transmitted preferentially. As a result, an FCS error may occur in the user frame at each interval T1, and as a result, the communication quality may deteriorate. Therefore, it is useful to use the following method.

FIG. 7 is a block diagram showing a schematic configuration example of the frame processing circuit in FIG. 3 in the optical transceiver according to the second embodiment of the present invention. FIG. 8 is a sequence diagram showing an operation example at the time of discovery using the frame processing circuit of FIG. 7 in the network system of FIG. In the frame processing circuit 53b shown in FIG. 7, a dummy response circuit 65 is added to the configuration example of FIG.

In FIG. 7, first, the frame identification circuit 61 identifies whether or not the frame received in the frame buffer 60a is the OAM frame FRE, and in addition, the information OAM frame is based on the code 42 shown in FIG. Identify whether it is FRE (IFM). Further, the frame identification circuit 61 identifies whether the information OAM frame FRE (IFM) is a frame after the completion of the discovery or a frame before the completion of the discovery. Specifically, the frame identification circuit 61 may perform such identification based on the information of the flag 41 shown in FIG. 5, for example.

Then, the frame identification circuit 61 transmits a response command to the dummy response circuit 65 in the case of a frame after the completion of discovery, and transmits a conversion command to the frame conversion circuit 62 in the case of a frame before completion. The dummy response circuit 65 generates an information OAM frame FRE (IFM), and transmits the information OAM frame FRE (IFM) to the host device 15 in response to a response command from the frame identification circuit 61.

In the example of FIG. 8, first, in step S101, the upper device 15 and the lower device 17 perform discovery via the optical transceiver 16 as in the case of step S101a and the like in FIG. At this time, the information OAM frame FRE (IFMn) before the completion of the discovery is used between the host device 15 and the optical transceiver 16. Further, the frame conversion circuit 62 in the optical transceiver 16 has an information OAM frame FRE (IFMn) and a state request maintenance frame FRS (SRQ) or a state response maintenance frame FRS (SRS) in response to a conversion command from the frame identification circuit 61. ) And to each other.

Subsequently, in step S102, the host device 15 completes the discovery. After that, in steps S103a and S103b, the host device 15 transmits the information OAM frame FRE (IFMc) after the completion of the discovery at a predetermined interval T1. In this case, the dummy response circuit 65 in the optical transceiver 16 transmits the information OAM frame FRE (IFMc) to the host device 15 in response to the response command from the frame identification circuit 61.

As a result, for example, in step S103a, the lower device 17 can transmit the user frame FRU without destroying it. The optical transceiver 16 receives the user frame FRU and transmits it to the host device 15. At this time, the optical transceiver 16 is treated as having a high priority of the information OAM frame FRE (IFMc) from the dummy response circuit 65, for example. As a result, the optical transceiver 16 transmits the information OAM frame FRE (IFMc) to the host device 15 and then transmits the user frame FRU.

<< Main effect of Embodiment 2 >>
As described above, even by using the method of the second embodiment, the same effects as the various effects described in the first embodiment can be obtained. Further, in the second embodiment, in addition to such an effect, it becomes possible to improve the communication quality.

Although the invention made by the present inventor has been specifically described above based on the embodiment, the present invention is not limited to the above embodiment and can be variously modified without departing from the gist thereof. For example, the above-described embodiments have been described in detail in order to explain the present invention in an easy-to-understand manner, and are not necessarily limited to those having all the described configurations. Further, it is possible to replace a part of the configuration of one embodiment with the configuration of another embodiment, and it is also possible to add the configuration of another embodiment to the configuration of one embodiment. .. Further, it is possible to add / delete / replace a part of the configuration of each embodiment with another configuration.

10 Upper network 11 Lower network 12 Optical fiber 15 Upper device 16 Optical transceiver 17 Lower device 18 User terminal 19 Ethernet cable 22,33 Preamble 23 Control information 24 Status information 25 Management information 26 CRC
30 Header 31 Payload (EFM data)
32 FCS
34 Destination MAC address 35 Source MAC address 36 Type 40 Subtype 41 Flag 42 Code 43 Data 44 TLV
45 Electrical signal interface 46 Logic circuit 47 Analog front-end circuit 48 Optical signal interface 49 CPU
51 Speed conversion circuit 53, 53a, 53b Frame processing circuit 55 Driver 56 Post amplifier 60a, 60b Frame buffer 61 Frame identification circuit 62 Frame conversion circuit 65 Dummy response circuit CNe Electric connector CNo Optical connector FRE OAM frame FRE (IFM) Information OAM frame FRS Maintenance Frame FRS (SRQ) State Request Maintenance Frame FRS (SRS) State Response Maintenance Frame FRU User Frame LD Laser Diode PD Photodiode PT Port

Claims (6)

An optical connector that can be connected to a lower-level device via an optical fiber,
An electrical connector that can be connected to the port of the host device,
An optical signal interface that converts a received electric signal into an optical signal and transmits it to the optical connector, converts an optical signal from the optical connector into an electric signal, and transmits the optical signal to the electric connector side.
Based on the maintenance frame based on the TS-1000 standard provided between the optical signal interface and the electric connector and used between the lower device and the IEEE 802.3ah standard used between the upper device. A frame conversion circuit that converts OAM (Operations, Administration, Maintenance) frames to each other,
Have,
The frame conversion circuit converts the information OAM frame, which is the OAM frame used in the discovery, into the state request maintenance frame, which is the maintenance frame representing the status notification request, and the state response, which is the maintenance frame representing the status notification response. Converting the maintenance frame to the information OAM frame,
Optical transceiver. In the optical transceiver according to claim 1,
The received information OAM frame is identified as a frame after the completion of the discovery or a frame before the completion, a response command is transmitted in the case of the frame after the completion, and the frame conversion circuit in the case of the frame before the completion. A frame identification circuit that sends a conversion command to
A dummy response circuit that generates the information OAM frame and transmits the information OAM frame to the host device in response to the response command.
Have,
Optical transceiver. In the optical transceiver according to claim 2,
The frame identification circuit discriminates between the frame after completion and the frame before completion based on the information of the flag included in the information OAM frame.
Optical transceiver. Subordinate equipment that is compatible with the TS-1000 standard, and
A host device that has a port and is not compatible with the TS-1000 standard,
An optical transceiver that is attached to the port of the higher-level device and is connected to the lower-level device via an optical fiber.
It is a network system equipped with
The optical transceiver
An optical connector connected to the optical fiber and
An electrical connector connected to the port of the host device,
An optical signal interface that converts a received electric signal into an optical signal and transmits it to the optical connector, converts an optical signal from the optical connector into an electric signal, and transmits the optical signal to the electric connector side.
Based on the maintenance frame based on the TS-1000 standard provided between the optical signal interface and the electric connector and used between the lower device and the IEEE 802.3ah standard used between the upper device. A frame conversion circuit that converts OAM (Operations, Administration, Maintenance) frames to each other,
Have,
The frame conversion circuit converts the information OAM frame, which is the OAM frame used in discovery, into the state request maintenance frame, which is the maintenance frame representing the status notification request, and the state response, which is the maintenance frame representing the status notification response. Converting the maintenance frame to the information OAM frame,
Network system. In the network system according to claim 4,
The optical transceiver
The received information OAM frame is identified as a frame after the completion of the discovery or a frame before the completion, a response command is transmitted in the case of the frame after the completion, and the frame conversion circuit in the case of the frame before the completion. A frame identification circuit that sends a conversion command to
A dummy response circuit that generates the information OAM frame and transmits the information OAM frame to the host device in response to the response command.
Have,
Network system. In the network system according to claim 5,
The frame identification circuit discriminates between the frame after completion and the frame before completion based on the information of the flag included in the information OAM frame.
Network system.

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