JP4870742B2 - Optical transmission equipment - Google Patents

Description

  The present invention relates to an optical transmission apparatus that transmits a signal through an optical transmission line such as an optical cable.

  In an optical transmission system, SDH (Synchronous Digital Hierarchy) is internationally standardized as a digital hierarchy for multiplexing existing service signals. In the United States, SONET (Synchronous 0ptica1 Network) similar to SDH is the de facto standard. As the current optical transmission system, an optical transmission system compliant with the SONET / SDH specification has become the mainstream, and has been introduced in large quantities all over the world.

  Based on the premise of Wavelength Division Multiplex (WDM) that can cope with the explosive increase of Internet traffic in recent years, not only SDH / SONET but also various clients such as ATM and Ethernet (registered trademark) are transparent. OTN (Optical Transport Network) has been standardized as a platform for transmission to the Internet, and is expected to become the mainstream of future optical transmission systems (see Non-Patent Document 1).

  In recent years, with the explosive spread of the Internet, the number of Ethernet (registered trademark) interfaces has increased rapidly. In IEEE802.3ba, standardization of 40 GbE and 100 GbE LAN interfaces has started, and standardization will be established in 2010. Expectation. Against this background, 40 Gb / s POS (PPP over SONET) has been put into practical use as an interface for current electrical routers.

  FIG. 13 is a diagram illustrating a configuration of a conventional 40 Gb / s optical transmission system. The optical transmission system shown in FIG. 13 is configured by connecting an optical transmission device 500A and an optical transmission device 500B through an optical transmission line 11 such as an optical cable. The optical transmission device 500A and the optical transmission device 500B have the same configuration.

  The optical transmission device 500A receives the 40 Gb / s POS signal from the router by the client signal transmission / reception unit 111A. In the client signal transmission / reception unit 111A, the 40 Gb / s POS signal from the router is photoelectrically converted by the O / E conversion unit 113, and the 40 Gb / s serial signal is converted to a 2.5 Gb / s class 16 parallel signal by the DES unit 511. Convert to The 16 parallel signals are input to the frame accommodating / processing unit 121A. In the frame accommodating / processing unit 121A, the SDH / SONET monitor unit 521 monitors the quality of the input signal and the alarm state. Thereafter, the input signal is mapped to a 40 Gb / s class OTN (Optical Transport Network) frame OTU3 by an OTU3 mapping (OTU3 mapping) unit 522, and this signal is output to the network signal transmitting / receiving unit 131A. In the network signal transmission / reception unit 131A, the SER unit 531 serializes and outputs a 2.7 Gb / s × 16 parallel signal. The E / O converter 132 converts the electrical signal into an optical signal and outputs the 43 Gb / s OTU3 optical signal to the optical transmission line 11 such as an optical cable.

  The 43 Gb / s OTU3 signal transmitted through the optical transmission line 11 is received by the network signal transmission / reception unit 131A in the optical transmission apparatus 500B. The signal input to the network signal transmission / reception unit 131 </ b> A is subjected to photoelectric conversion by the O / E conversion unit 135 and then serial / parallel conversion by the DES unit 532. The serial-parallel converted 2.7 Gb / s × 16 parallel signal is input to the frame accommodating / processing unit 121A.

In the frame accommodation / processing unit 121, the OTU3 / ODU3-OH is terminated by the OTU3 demapping unit 523, and an error due to optical transmission is corrected by the error correction code by the SOH / SONET monitor unit 524. The later quality is monitored, and the 40 Gb / s POS signal as the client is extracted by removing the overhead (OH). The quality of the client signal is also monitored using SONET / SDH OH. Thereafter, the 2.5 Gb / s × 16 parallel signal is input to the client signal transmitting / receiving unit 111A. In the client signal transmission / reception unit 111A, the SER unit 512 serializes the 2.5 Gb / s × 16 parallel signal, the E / O conversion unit 114 performs electro-optical conversion, and sends it to the client side as a 40 Gb / s serial signal. Is done.
“Interfaces for the Optical Transport Network (OTN)”, ITU-T (International Telecommunication Union Telecommunication Standardization Sector), Recommendation G.709

  As described above, in a conventional optical transmission system, a 40 Gb / s client signal is mapped to a 43 Gb / s OTU3 frame, and a long distance transmission is performed as a 43 Gb / s serial signal. However, since electrical parts and optical parts that handle a 40 Gb / s serial signal are expensive, it has been desired to provide means for economically transferring a 40 Gb / s signal over a long distance.

  The present invention has been made in view of the above problems, and an object of the present invention is to use inexpensive LAN components without using electrical components and optical components that handle expensive 40 Gb / s serial signals. Thus, an object of the present invention is to provide an optical transmission device that can transfer a 40 GbE signal or the like over a long distance.

The present invention has been made to solve the above problems, an optical transmission apparatus accommodates the client signal, an optical transmission apparatus for transmitting the optical Transmission path by converting the client signal to the network side of the signal The phase difference between the parallel signal of the client signal receiving unit that receives the parallel type client signal and the parallel type client signal is adjusted, and the parallel type client signal is restored to the bulk client signal. A parallel signal skew adjusting unit, a first monitor unit for monitoring the quality of the bulk client signal, and separating the bulk client signal into a parallel client signal, and the separated parallel client signal A network transmission signal in parallel format by mapping each of the Each of the generated inverse multiplexer unit and the parallel-type network transmission signal generated by the inverse multiplexer unit is converted into an optical signal of a different wavelength, and the optical signal of the different wavelength is wavelength-multiplexed to the optical transmission line And a network signal transmission unit for transmitting as a network signal.

  According to the present invention, an optical transmission device accommodates a client signal, converts the client signal into a signal on the network side and sends it to an optical transmission line, and transmits an optical signal from the network side through the optical transmission line. An optical transmission apparatus having a reception system unit for receiving and extracting a client signal from the optical signal, wherein the transmission system unit includes a client signal reception unit for receiving a parallel type client signal, and the parallel type client A parallel signal skew adjusting unit that adjusts a phase shift between the parallel signals of the signals and restores the parallel type client signal to a bulk client signal, and a first monitor unit that monitors the quality of the bulk client signal Separating the bulk client signal into parallel client signals and separating the parallel client signals The inverse multiplexer unit that maps each of the client signals to the network transmission frame to generate a parallel network transmission signal, and the parallel network transmission signal generated by the inverse multiplexer unit has different wavelengths. A network signal transmission unit that converts the optical signal into a wavelength signal and transmits the optical signal of the different wavelength as a network signal to the optical transmission line, and the reception system unit is wavelength-multiplexed from the optical transmission line. A network signal receiving unit that receives the network signal, separates the wavelength-multiplexed network signal for each wavelength, and photoelectrically converts the signals separated for each wavelength to generate a parallel network signal; , Network transmission frame of the network signal of the parallel format A frame termination unit that extracts a client signal mapped to the parallel format and extracts a client signal in a parallel format; a signal coupling unit that restores a bulk client signal from the parallel format client signal; and a signal coupling unit that is restored by the signal coupling unit A second monitoring unit that monitors the quality of the bulk client signal; a signal distribution unit that converts the bulk client signal whose quality is monitored by the second monitoring unit into a parallel-type client signal; and the signal distribution unit A client signal transmission unit that transmits the client signal in parallel format output from the client to the client side.

  Further, the present invention provides an ITU-T (International Telecommunication Union Telecommunication Standardization Sector) for transmitting information used to restore the original bulk signal in the bulk client signal separation and multiplexing in the optical transmission apparatus described above. The network transmission frame overhead defined in G.709 is used.

An optical transmission apparatus according to the present invention is an optical transmission apparatus that receives a client signal, converts the client signal into a signal on the network side, and transmits the signal to an optical transmission line, and receives the client signal in parallel format. A receiving unit, a first monitor unit that monitors the quality of each of the parallel- type client signals without returning the parallel-type client signal to a bulk client signal, and each of the parallel- type client signals, A frame accommodating unit that maps to a network transmission frame to generate a parallel network transmission signal, and converts each of the parallel network transmission signals generated by the frame accommodating unit into optical signals having different wavelengths, and Optical signals of different wavelengths are wavelength multiplexed and a network is connected to the optical transmission line. Characterized by comprising a network signal transmitting section for transmitting a signal.

The optical transmission apparatus according to the present invention also includes a transmission system unit that receives a client signal, converts the client signal into an optical signal, and transmits the optical signal to a network-side optical transmission line, and transmits the optical signal from the network side through the optical transmission line. An optical transmission apparatus having a reception system unit for receiving and extracting a client signal from the optical signal, wherein the transmission system unit includes a client signal reception unit for receiving a parallel type client signal, and the parallel type client A first monitor unit that monitors the quality of each of the parallel- type client signals without returning the signal to a bulk client signal, and each parallel- type client signal is mapped to a network transmission frame in parallel format A frame receiving unit for generating a network transmission signal, and the frame receiving unit A network signal transmission unit that converts each of the parallel network transmission signals into optical signals of different wavelengths, wavelength-multiplexes the optical signals of different wavelengths, and transmits the optical signals to the optical transmission line as network signals. The receiving system unit receives a wavelength-multiplexed network signal from the optical transmission line, separates the wavelength-multiplexed network signal for each wavelength, and separates the wavelength-separated signal for each of the optical signals. A network signal receiving unit that generates a network signal in parallel format by converting, a frame termination unit that extracts a client signal mapped to a network transmission frame of the network signal in parallel format as a client signal in parallel format, and the parallel A second monitor for monitoring the quality of the format client signal; Serial and client signal transmitting unit quality by the second monitor unit transmits a client signal of the monitored parallel form on the client side, characterized in that it comprises a.

  An optical transmission apparatus according to the present invention is an optical transmission apparatus that receives a client signal, converts the client signal into a signal on the network side, and transmits the signal to an optical transmission line, and receives the client signal in parallel format. Each of a receiving unit, a first skew adjusting unit that adjusts a phase shift between the parallel client signals, and a parallel client signal that is adjusted in phase shift by the first skew adjusting unit, A mapping unit that maps to a network transmission frame to generate a parallel-type network transmission signal, and converts each of the parallel-type network transmission signal generated by the mapping unit into an optical signal of a different wavelength, and the different wavelength A wavelength-multiplexed optical signal is sent to the optical transmission line as a network signal. Characterized in that it comprises a chromatography click signal transmitting unit.

  The optical transmission apparatus according to the present invention also includes a transmission system unit that accommodates a client signal, converts the client signal into an optical signal on the network side, and sends the optical signal to the optical transmission line, and transmits the optical signal from the network side through the optical transmission line. An optical transmission apparatus having a reception system unit for receiving and extracting a client signal from the optical signal, wherein the transmission system unit includes a client signal reception unit for receiving a parallel type client signal, and the parallel type client A first skew adjusting unit that adjusts a phase shift between signals and a parallel type client signal in which the phase shift is adjusted by the first skew adjusting unit are mapped to a network transmission frame to form a parallel type. A mapping unit for generating a network transmission signal, and a parallel network generated by the mapping unit. A network signal transmission unit that converts each of the transmission signals into optical signals of different wavelengths, wavelength-multiplexes the optical signals of different wavelengths, and transmits the optical signals to the optical transmission line as a network signal, the receiving system The unit receives a wavelength-multiplexed network signal from the optical transmission line, separates the wavelength-multiplexed network signal for each wavelength, and performs photoelectric conversion on the signals separated for each wavelength in parallel form. Between the network signal receiving unit that generates the network signal, the frame termination unit that extracts the client signal mapped to the network transmission frame of the network signal in the parallel format as a client signal in the parallel format, and the client signal in the parallel format A second skew adjustment unit for adjusting the phase shift of the second skew, and the second skew Characterized in that it comprises a client signal transmitting unit for transmitting a client signal in parallel form which are phase-adjusted to the client side, a by chromatography adjuster.

  According to the present invention, in the above optical transmission apparatus, the network transmission frame is an ITU-T G.264. ITU-T G.709, and its bit rate is ITU-T G.709. It is a network transmission frame of OTU2e (11.096 Gb / s) or OTU1e (11.049 Gb / s) defined in sup43.

In the optical transmission apparatus of the present invention, the phase shift of the parallel type client signal is adjusted, and once returned to the bulk signal, the quality is monitored, and then the bulk client signal is separated into a plurality of parallel type signals, Each of the parallel signals is mapped to a network transmission frame, each of the mapped parallel frame signals is converted into an optical signal of a different wavelength, wavelength-multiplexed, and sent to the optical transmission line as a network signal.
Thereby, it is possible to transfer a 40 GbE signal or the like over a long distance using a low-speed parallel signal (parallel type signal) instead of a high-speed serial signal. For this reason, components for low-speed transmission can be used, and an optical transmission device excellent in economic efficiency can be provided. In addition, an optical transmission system that performs long-distance transfer of 40 GbE signals and the like can be economically configured using this optical transmission apparatus.

In the optical transmission apparatus of the present invention, the transmission system section adjusts the phase shift of the parallel-type client signal, temporarily returns to the bulk signal, monitors the quality, and then converts the bulk client signal into a plurality of parallel client signals. Each of the signals in the parallel format is mapped to a network transmission frame, each of the mapped parallel format frame signals is converted into an optical signal of a different wavelength, and wavelength multiplexed. To the optical transmission line. The receiving system section photoelectrically converts the network signal received from the network side, extracts the client signal mapped to the network transmission frame, and restores the original bulk client signal from the extracted parallel client signal. The quality is then monitored, and then the parallel client signal is returned to the client side.
As a result, long-distance transfer of 40 GbE signals or the like is possible using low-speed parallel signals instead of high-speed serial signals. For this reason, components for low-speed transmission can be used, and an optical transmission device excellent in economic efficiency can be provided. In addition, an optical transmission system that performs long-distance transfer of 40 GbE signals and the like can be economically configured using this optical transmission apparatus.

Further, in the optical transmission apparatus of the present invention, a frame defined in G.709 of ITU-T is used for transmission of information necessary for restoring a bulk signal based on separation and multiplexing of bulk client signals. The overhead of
This makes it easy to separate and multiplex bulk client signals using the frame overhead specified in G.709.

In the optical transmission apparatus of the present invention, the parallel type client signal is received, the quality of the client signal is monitored without changing the parallel type client signal back to the bulk signal, and then the parallel type client signal is monitored. The signal in the format is mapped to the network transmission frame, and each of the mapped parallel format frame signals is converted into an optical signal of a different wavelength, wavelength-multiplexed, and sent to the optical transmission line.
As a result, long-distance transfer such as 40GbE signals can be performed with low-speed parallel signals instead of high-speed serial signals, and further, the client-side signals are transferred as parallel signals without returning to bulk signals. Therefore, it is possible to provide an optical transmission apparatus with further improved economic efficiency. In addition, an optical transmission system that performs long-distance transfer of 40 GbE signals and the like can be economically configured using this optical transmission apparatus.

Further, the optical transmission apparatus of the present invention receives the parallel-type client signal in the transmission system unit, monitors the quality of the client signal as it is in the parallel-type signal without returning to the parallel-type client signal bulk signal, Thereafter, the parallel format signals are mapped to the network transmission frame, and the mapped parallel format frame signals are converted into optical signals of different wavelengths, wavelength-multiplexed, and sent to the optical transmission path. The receiving system section photoelectrically converts the network signal received from the optical transmission path, extracts the parallel client signal mapped to the network transmission frame of the network signal, and monitors the quality of the client signal while maintaining the parallel signal. Then, it is sent to the client side as it is as a parallel client signal.
As a result, long-distance transfer such as 40GbE signals can be performed with low-speed parallel signals instead of high-speed serial signals, and further, the client-side signals are transferred as parallel signals without returning to bulk signals. Therefore, it is possible to provide an optical transmission apparatus with further improved economic efficiency. In addition, an optical transmission system that performs long-distance transfer of 40 GbE signals and the like can be economically configured using this optical transmission apparatus.

In the optical transmission apparatus of the present invention, parallel type client signals are received, phase adjustment between the parallel signals is performed, each of the parallel type client signals is mapped to a network transmission frame, and the mapped parallel Each format frame signal is converted into an optical signal of a different wavelength, wavelength-multiplexed, and sent to the optical transmission line.
As a result, long-distance transfer such as 40GbE signals can be performed with low-speed parallel signals instead of high-speed serial signals, and further, the client-side signals are transferred as parallel signals without returning to bulk signals. Therefore, it is possible to provide an optical transmission apparatus with further improved economic efficiency. In addition, an optical transmission system that performs long-distance transfer of 40 GbE signals and the like can be economically configured using this optical transmission apparatus.

Further, in the optical transmission apparatus of the present invention, the transmission system unit receives the parallel type client signal, adjusts the phase between the parallel signals, and maps each of the parallel type client signals to the network transmission frame. Each of the mapped parallel frame signals is converted into an optical signal having a different wavelength, wavelength-multiplexed, and sent to the optical transmission line as a network signal. The receiving system unit photoelectrically converts the network signal received from the optical transmission line, extracts the parallel-type client signal mapped to the network transmission frame, adjusts the phase shift between the parallel signals, and continues in parallel Is sent to the client side as a client signal.
As a result, long-distance transfer such as 40GbE signals can be performed with low-speed parallel signals instead of high-speed serial signals, and further, the client-side signals are transferred as parallel signals without returning to bulk signals. Therefore, it is possible to provide an optical transmission apparatus with further improved economic efficiency. In addition, an optical transmission system that performs long-distance transfer of 40 GbE signals and the like can be economically configured using this optical transmission apparatus.

In the optical transmission apparatus of the present invention, the network transmission frame is an ITU-T G. ITU-T G.709, and its bit rate is ITU-T G.709. This is a network transmission frame of OTU2e (11.096 Gb / s) or OTU1e (11.049 Gb / s) defined in sup43.
As a result, client signals such as 40 GbE signals are parallelized (parallelized), and each of the parallel signals is converted into a network transmission frame of OTU2e (11.096 Gb / s) or OTU1e (11.049 Gb / s). Can be mapped to and transmitted in parallel format. For this reason, it is possible to transfer a 40 GbE signal or the like over a long distance using a low-speed parallel signal instead of a high-speed serial signal.

  Embodiments of the present invention will be described below with reference to the accompanying drawings.

[First Embodiment]
FIG. 1 is a block diagram showing a configuration of an optical transmission apparatus 100 according to the first embodiment of the present invention. FIG. 2 shows an example in which the optical transmission system 1 is configured by the optical transmission device 100A and the optical transmission device 100B using the two optical transmission devices 100 shown in FIG. The optical transmission devices 100A and 100B are collectively referred to as the optical transmission device 100.

  For a 40 GbE interface that is being standardized by IEEE 802.3ba, a wavelength multiplexed signal of 10.3125 Gb / s × 4 lanes is one of the candidates. Therefore, in the optical transmission device 100 shown in FIG. 1 and the optical transmission system 1 shown in FIG. 2, an example of a long-distance transmission system of 10.3125 Gb / s × 4 parallel LAN signals will be described.

  As shown in FIG. 1, the optical transmission device 100 receives a client signal from the client side, converts this client signal into a signal on the network side, and outputs it to the optical transmission line 11 (on the upper side in the figure). (A part of a circuit system surrounded by a broken line) 101 and a reception system unit (in the figure) that receives a signal on the network side from the optical transmission line 11 and extracts a client signal from the signal on the network side and outputs it to the client side Circuit portion surrounded by a broken line shown on the lower side) 102.

  That is, in the optical transmission apparatus 100, the transmission system unit 101 is a part of a circuit system surrounded by a broken line shown on the upper side, and includes a wavelength multiplexing / demultiplexing unit 112, an O / E conversion unit (optical / Electric conversion unit) 113, MLD (Multi Lane Distribution) skew adjustment unit (MLD termination) 122 in the frame accommodation / processing unit 121, 40 GbE / PCS / MAC monitor unit 123, inverse multiplexer unit (Inverse / MUX unit) 124, The network signal transmission / reception unit 131 includes an E / O conversion unit (electrical / optical conversion unit) 132 and a wavelength multiplexing unit (WDM-MUX) 133.

  The reception system unit 102 is a part of a circuit system surrounded by a broken line shown on the lower side in the optical transmission apparatus 100, and includes a wavelength multiplexing unit 115, an O / E conversion unit 114 in the client signal transmission / reception unit 111, MLD processing unit (VL insertion) 128 in frame accommodation / processing unit 121, 40GbE / PCS / MAC monitor unit 127, virtual concatenation unit (VCAT / MUX) 126, OTU2e termination unit 125, O in network signal transmission / reception unit 131 / E conversion unit 135 and wavelength demultiplexing unit (WDM-DEMUX) 134.

  In the above configuration, on the transmission system unit 101 side, a 40 GbE / LAN signal (4 parallel optical signals of 10.3125 Gb / s) multiplexed at four wavelengths transmitted from the client side is transmitted by the client signal transmission / reception unit 111. Receive. The 40 GbE / LAN signal is subjected to wavelength multiplexing separation in a wavelength multiplexing / demultiplexing unit (WDM-DEMUX) 112. Thereafter, optical / electrical conversion is performed by the O / E conversion unit 113 and output as 10.3125 Gb / s × 4 four parallel electric signals. The 10.3125 Gb / s × 4 four parallel electric signals are input to the frame accommodation / processing unit 121.

  The frame accommodating / processing unit 121 adjusts the phase relationship (phase shift) between four parallel signals of 10.3125 Gb / s × 4 by the MLD skew adjusting unit 122 that performs MLD skew adjustment, and obtains a bulk 40 GbE signal. Restore. The bulk 40 GbE signal is input to the 40 GbE • PCS / MAC monitor unit 123.

  The 40 GbE / PCS / MAC monitor unit 123 receives a bulk 40 GbE signal and performs quality monitoring using a 64B / 66B code monitor in a PCS (Physical Coding Sublayor) layer. The 40 GbE / PCS / MAC monitor unit 123 performs MAC frame monitoring using an FCS (frame check sequence) checker in a MAC (Media Access Control) layer, and performs quality monitoring such as frame length counting and frame number counting. .

  The bulk client signal whose quality is monitored by the 40 GbE • PCS / MAC monitor unit 123 is input to the inverse multiplexer 124. In this inverse multiplexer unit 124, the bulk 40 GbE signal (42.25 Gb / s ± 100 ppm) is converted into a signal of 10.3125 Gb / s ± 100 ppm so that it can be restored by virtual concatenation (VCAT). Divided.

  Further, in the inverse multiplexer unit 124, the four parallel client signals are G. The OTU2 frame defined in 709 is mapped to the payloads of four OTU2e (specified in ITU-T G.sup43) network transmission frames. In the case of VCAT using the synchronous mapping method, the bit rate of OTU2e is 11.096 Gb / s ± 100 ppm. Information necessary for restoration by virtual concatenation is added to the overhead portion of the network transmission frame.

  The electric signal of the OTU2e frame that has been parallelized (parallelized) into four is input to the network signal transmission / reception unit 131. In the network signal transmission / reception unit 131, each of the four electric signals of the OTU2e frame parallelized by the E / O conversion unit 132 that converts the electric signal into an optical signal is transmitted at a bit rate of 11.096 Gb / s ± 100 ppm. It converts into an optical signal having four different wavelengths. Thereafter, in order to input optical signals of different wavelengths to one fiber, multiplexing at the wavelength level is performed in the wavelength multiplexing unit (WDM-MUX) 133, and the wavelength-multiplexed optical signal is converted into VCAT (virtual concatenation). ) · It is output to the optical transmission line 11 on the network side as a 40 GbE optical signal (an OTU2e × 4 optical signal).

  The optical signal (OTU2e × 4) transmitted from the optical transmission apparatus 100 through the optical transmission path 11 is transmitted through the optical transmission path 11 to the opposite optical transmission apparatus. For example, as illustrated in FIG. 2, transmission is performed from the optical transmission device 100 </ b> A toward the optical transmission device 100 </ b> B.

  In the opposite-side optical transmission device 100, reception of an optical signal transmitted from the network side is performed by the reception system unit 102 shown in FIG. In this reception system unit 102, a network signal transmission / reception unit 131 in the optical transmission apparatus 100 receives an optical signal from the optical transmission line 11, and the wavelength multiplexing and demultiplexing unit (WDM-DEMUX) 134 multiplexes the optical signal. The signal is separated for each wavelength (in this example, it is separated into four parallel signals). The O / E converter 135 converts the optical signal for each wavelength into an electrical signal of the OTU2e frame, and the four parallel signals converted into the electrical signal are converted into the OTU2e termination in the frame accommodation / processing unit 121. Output to the unit 125.

  The OTU2e termination unit 125 in the frame accommodation / processing unit 121 is a termination unit having a configuration (in this example, a 4-parallel configuration) corresponding to the parallel number of input signals. The OTU2e termination unit 125 extracts overhead (OTU2e-OH) from each signal of the four parallel OTU2e frames converted into electrical signals, and monitors the quality of each signal using the overhead (OTU2e-OH). Detect faults and identify faults. The OTU2e termination unit 125 extracts a client signal mapped to the payload of the OTU2e network transmission frame, and generates four parallel client signals. The four parallel client signals are output to the virtual concatenation unit (VCAT / MUX) 126.

  The virtual concatenation unit (VCAT / MUX) 126 uses the OTU2e overhead (OTU2e-OH) to restore a bulk client signal (40 GbE signal) based on four parallel client signals.

  The restored bulk client signal (40 GbE signal) is again monitored for quality in the 40 GbE • PCS / MAC monitor unit 127. Thereafter, the data passes through the MLD processing unit (VL insertion) 128, is converted into a 10.3125 Gb / s × 4 parallel client signal by a virtual lane (VL), and is input to the client signal transmission / reception unit 111. .

  In the client signal transmitting / receiving unit 111, the 10.3125 Gb / s × 4 parallel electric signals of 10.3125 Gb / s × 4 are converted into optical signals having different wavelengths by the E / O conversion unit 114, and a wavelength multiplexing unit (WDM-MUX) unit 115, multiplexing processing at the wavelength level is performed, and 10.3125 Gb / s × 4 parallel signals are output to the client side.

  In the first embodiment shown in FIGS. 1 and 2, an example in which a client signal is mapped to a network transmission frame of an OTU2e of 11.0696 Gb / s is shown. However, an OTU1e (ITUT of 11.049 Gb / s) is shown. It is also possible to use a network transmission frame (specified in -T G.sup43).

  1 shows an example in which the transmission system unit 101 and the reception system unit 102 are included in one unit. However, the transmission system unit 101 and the reception system unit 102 are respectively configured. It can also consist of independent units.

(40GbE_LAN system configuration example and skew adjustment)
Here, as an example supplementing the first embodiment shown in FIGS. 1 and 2, a configuration example of a 40 GbE_LAN system and an example of skew adjustment will be described. FIG. 3 is a diagram illustrating a configuration example of a 40 GbE_LAN system. FIG. 4 shows an example of inter-lane skew adjustment by an MLD (multi-lane distribution) architecture that is being standardized at 40 GbE.

  The 40 GbE_LAN system 2 shown in FIG. 3 is configured by connecting optical transmission apparatuses 200 </ b> A and 200 </ b> B through an optical transmission line 11. The optical transmission device 200A and the optical transmission device 200B have the same configuration, and the same components are denoted by the same reference numerals. Note that, unlike the optical transmission system 1 shown in FIG. 1, the 40 GbE_LAN system 2 shown in FIG. 3 does not perform mapping processing to an OTU2e frame necessary for transmitting an optical signal over a long distance. When long-distance transmission is required, it is performed with the optical transmission device 100 shown in FIG. 1 interposed.

  In the optical transmission device 200 </ b> A, a 40G MAC signal (40.0 Gb / s) output from a MAC (media access control) processing unit 211 is input to the PCS (TX) processing unit 212. The PCS (TX) processing unit 212 performs 64B / 66B encoding on the 40G MAC signal and converts it to a 41.25 Gb / s signal.

  The MLD (TX) processing unit 213 separates the signal input from the PCS (TX) processing unit 201 into four 4 × 10 Gb / s lane 64B / 66B blocks. In addition, the MLD (TX) processing unit 202 inserts an alignment signal for performing phase adjustment of four lanes in the 64B / 66B block of 4 × 10 Gb / s lanes, and sends it to the 40 GbE transmission / reception unit 231.

  In the 40 GbE transmission / reception unit 231, the signal input from the MLD processing unit 213 is converted from an electric signal to an optical signal by the O / E conversion unit 232, and is output to the wavelength multiplexing unit (WDM-MUX) unit 233. The wavelength multiplexing unit (WDM-MUX) 233 multiplexes the wavelengths by assigning different wavelengths to the four lanes, and outputs them to the optical transmission line 11. The wavelength-multiplexed optical signal is received by the opposite optical transmission device 200B through the optical transmission path 11.

  In the optical transmission device 200B, the optical signal transmitted from the optical transmission device 200A through the optical transmission line 11 is received by the 40 GbE transceiver 231. In the 40 GbE transceiver 231 in the optical transmission apparatus 200B, the wavelength multiplexed signal is wavelength separated by the wavelength demultiplexing unit (WDM-DEMUX) 234, and the signal of each lane is photoelectrically converted by the O / E conversion unit 235. Input to the MLD (Rx) processing unit 214.

  Here, as shown in FIG. 4, since a phase shift (skew) occurs for each lane, the phase shift is adjusted by an alignment signal (shown as A in the figure) embedded in the 40 GbE signal, and PCS (Rx ) Is input to the processing unit 215. The PCS (Rx) processing unit 215 terminates 64B / 66B encoding, and the MAC processing unit 211 extracts a MAC frame.

  As described above, the phase adjustment between the lanes in the first embodiment uses the skew adjustment by the MLD that will be standardized in the 40 GbE LAN. As for the wavelength multiplexing optical transceiver module, the optical transceiver module for the 40 GbE LAN system system (bit rate 10.3125 Gb / s × 4) is set to 11.996 Gb / s × 4 or 11.0949 Gb / s × 4, and the wavelength Can be used by changing to a 1.5 μm band for long-distance transmission. By adopting such a configuration, an inexpensive system can be constructed using an optical transceiver module equivalent to that for 40 GbE signals.

(Explanation about virtual concatenation)
Next, virtual concatenation (VCAT) will be described. Virtual concatenation is a method in which a plurality of transmission paths are virtually combined to form one transmission path.

  In FIG. 7 shows an example of mapping of 40G signal (STM-256) defined in 709 to OPU2-4v. For reference, an example of mapping to a 10G signal (STM-64) OPU2 is also shown.

  Comparing the two, the reserve byte (RES) in the OPU-OH (the part indicated by shading in the figure) is arranged in the form of four OPUs 2 except that 3 bytes replaces the overhead VCOH for virtual concatenation. I understand that. Accordingly, since the data area is four times and STM-256 has a capacity four times that of STM-64, OPU2-4v can accommodate a data capacity four times that of OPU2. NJO, PJO, and JC absorb the difference between the client speed accommodated during asynchronous mapping and the network speed on the accommodating side. In 709, the accuracy of the client speed is ± 20 ppm, and the accuracy on the network side is ± 20 ppm.

  Details of the overhead (OH) of virtual concatenation are shown in FIG. Here, MFI1 and MFI2 (MFI: Multi Frame indication) are multi-frame indications, and are used to measure the delay time difference between each OPU2 frame and adjust the delay time difference. SQ is a byte indicating a sequence number, and can indicate a sequence number in virtual concatenation up to 256 in 8 bits. The Member Status is a byte indicating which virtual concatenation group belongs to. Therefore, since it is possible to know which virtual concatenation group belongs to which virtual concatenation group, and what frame number belongs to it by using these overheads, the OPU− In the case of 4v, a 40G signal can be transferred using four OPUs 2 to restore the original signal.

(Problem of speed accuracy between 40GbE signal and OPU2 signal defined by G.709 standard)
The accuracy of the signal speed of the 40 GbE signal is It is worse than the signal speed accuracy of the OPU2 signal specified in the 709 standard, and is an accuracy of ± 100 ppm. When the speed accuracy on the network side is ± 20 ppm, when using the asynchronous mapping method, the relative accuracy is equivalent to ± 120 ppm. It is necessary to accommodate the signal. Therefore, G. A part of the standard of 709 is extended to deal with signals with poor clock accuracy quality.

  7 and 8 show examples of accommodating 40 GbE signals in the extended OPU 2-4v. In FIG. 7, part of the JC byte is assigned to NJO, and part of the data area is assigned to PJO. In FIG. 8, a part of the fixed stack area is allocated to the NJO, and a part of the data area is allocated to the PJO. Since a signal speed equivalent to 65 ppm per byte of the OPU frame can be absorbed, a signal with an accuracy of ± 130 ppm can be absorbed by increasing NJO and PJO by 1 byte each. In other words, at the time of asynchronous mapping, the overclock OTU2e frame of 11.0996 Gb / s ± 20 ppm is used to accommodate and transmit the NJO and PPJO shown in FIGS. 7 and 8 and restore the original signal after transmission. It becomes like this.

  Although the first embodiment of the present invention has been described above, in the optical transmission device 100 according to the first embodiment, the transmission system unit described above is the transmission system unit 101 and the reception system unit 102 is the reception system unit 102. Respectively. The client signal receiving unit described above corresponds to the wavelength demultiplexing unit 112 and the O / E conversion unit 113 in the client signal transmitting / receiving unit 111. The parallel signal skew adjustment unit described above corresponds to the MLD skew adjustment unit 122. The first monitor unit corresponds to the 40 GbE • PCS / MAC monitor unit 123, and the inverse multiplexer unit corresponds to the inverse multiplexer unit (Inverse MUX unit) 123. The network signal transmission unit described above corresponds to the E / O conversion unit 132 and the wavelength multiplexing unit 133 in the network signal transmission / reception unit 131.

  The network signal receiving unit described above corresponds to the wavelength demultiplexing unit (WDM-DEMUX) 134 and the O / E converting unit 135 in the network signal transmitting / receiving unit 131. The frame termination unit is the OTU2e termination unit 125, the signal connection unit is the virtual concatenation unit (VCAT / MUX) 126, the second monitor unit is the 40GbE / PCS / MAC monitor unit 127, and the signal distribution unit is The MLD processing unit 128 corresponds to each. The client signal transmission unit described above corresponds to the E / O conversion unit 114 and the wavelength multiplexing unit (WDM-MUX) 115 in the client signal transmission / reception unit 111.

  And in the optical transmission apparatus 100 of 1st Embodiment, it can be set as the structure containing only the function of the transmission system | strain part 101. FIG. In this case, the optical transmission device 100 includes a client signal receiving unit (the wavelength multiplexing / demultiplexing unit 112 and the O / E conversion unit 113) that receives a parallel type client signal and a phase between the parallel signals of the parallel type client signal. A parallel signal skew adjustment unit (MLD skew adjustment unit 122) that adjusts the deviation and restores the parallel-type client signal to a bulk client signal, and a first monitor unit (40 GbE) that monitors the quality of the bulk client signal PCS / MAC monitor unit 123) and bulk client signals are separated into parallel client signals, and each of the separated parallel client signals is mapped to a network transmission frame to perform parallel network transmission. Inverse multiplexer unit that generates signals (inverse multiplex Each of the parallel-type network transmission signals generated by the lexer unit (Inverse / MUX unit) 124 and the inverse multiplexer unit is converted into an optical signal of a different wavelength, and the optical signal of the different wavelength is wavelength-multiplexed. And a network signal transmission unit (E / O conversion unit 132 and wavelength multiplexing unit 133) that transmits the signal to the optical transmission line as a network signal.

  Further, when the optical transmission apparatus 100 includes the functions of both the transmission system unit 101 and the reception system unit 102, in addition to the configuration of the transmission system unit 101 described above, the reception system unit 102 further includes an optical Receives a wavelength-multiplexed network signal from the transmission line, separates the wavelength-multiplexed network signal for each wavelength, and generates a parallel network signal by photoelectrically converting the signals separated for each wavelength. A network signal receiving unit (wavelength multiplexing / demultiplexing unit 134 and O / E conversion unit 135) for extracting the client signal mapped to the network transmission frame of the parallel network signal and extracting the parallel client signal Unit (OTU2e termination unit 125) and a parallel client signal to a bulk client signal The quality is monitored by the signal linking unit (virtual concatenation unit 126) to be restored, the second monitor unit (40 GbE / PCS / MAC monitor unit 127) for monitoring the quality of the bulk client signal, and the second monitor unit. A signal distribution unit (MLD processing unit 128) that converts the bulk client signal into a parallel type client signal, and a client signal transmission unit (E /) that transmits the parallel type client signal output from the signal distribution unit to the client side O conversion unit 114 and wavelength multiplexing unit 115).

  With the above-described configuration, it is possible to transfer a 40 GbE signal or the like over a long distance using a low-speed parallel signal instead of a high-speed serial signal. For this reason, components for low-speed transmission can be used, and an optical transmission device excellent in economic efficiency can be provided. In addition, an optical transmission system that performs long-distance transfer of 40 GbE signals and the like can be economically configured using this optical transmission apparatus.

[Second Embodiment]
In the first embodiment, for a parallel 40 GbE signal, after absorbing the phase shift between the parallel signals, the quality is monitored for the bulk signal of the 40 GbE PCS layer, the bulk signal is divided, and the original parallel format An inverse multiplexer and virtual concatenation were used to return the signal.

  On the other hand, in the second embodiment, simple parallel quality monitoring is performed by using a 64B / 66B code monitor without changing the parallel type client signal into the bulk signal, and the parallel type signal is converted into the parallel type signal. An example of mapping to an OTU2e frame as it is will be shown.

  FIG. 9 is a block diagram showing a configuration of an optical transmission apparatus 300 according to the second embodiment of the present invention. FIG. 10 shows an example in which the two optical transmission apparatuses 300 shown in FIG. 9 are used and the optical transmission system 3 is configured by the optical transmission apparatus 300A and the optical transmission apparatus 300B. The optical transmission apparatuses 300A and 300B are collectively referred to as the optical transmission apparatus 300.

  9 is different from the optical transmission device 100 shown in FIG. 1 in that the configuration of the frame accommodation / processing unit 121 shown in FIG. 1 is the same as that of the frame accommodation / processing unit 301 shown in FIG. The changes are different. The other components (client signal transmission / reception unit 111 and network signal transmission / reception unit 131 shown in FIG. 9) have the same configuration as in FIG. Therefore, the same reference numerals are given to the same components.

  The optical transmission device 300 shown in FIG. 9 receives a client signal from the client side, converts this client signal into a network side signal, and outputs it to the optical transmission line 11 (broken line shown on the upper side in the figure). Circuit system part 302) and a network system signal from the optical transmission line 11, and a receiving system unit (extracted from the lower side in the figure) that extracts the client signal from the network signal and outputs it to the client side. Circuit portion enclosed by a broken line shown in FIG.

  That is, the transmission system unit 302 includes a wavelength demultiplexing unit 112 in the client signal transmission / reception unit 111, an O / E conversion unit 113, a 64B / 66B monitoring unit 311 in the frame accommodation / processing unit 301, an OTU2e accommodation unit 312, a network signal The transmission / reception unit 131 includes an E / O conversion unit 132 and a wavelength multiplexing unit (WDM-MUX) 133.

  The reception system unit 303 includes a wavelength multiplexing unit (WDM-MUX) 115 in the client signal transmission / reception unit 111, an O / E conversion unit 114, a 64B / 66B monitoring unit 314 in the frame accommodation / processing unit 301, and an OTU2e termination unit. 313, an E / O conversion unit 135 in the network signal transmission / reception unit 131, and a wavelength demultiplexing unit (WDM-DEMUX) 134.

  In the above configuration, in the transmission system unit 302, the client signal transmission / reception unit 111 receives 40GbE / LAN signals (4. parallel signals of 10.3125Gb / s × 4) multiplexed at four wavelengths transmitted from the client side. To do. The 40 GbE / LAN signal is subjected to wavelength multiplexing separation by a wavelength multiplexing / demultiplexing unit (WDM-DEMUX) 112. Thereafter, the O / E converter 113 converts the optical signal into an electrical signal (O / E conversion), and outputs it as 10.3125 Gb / s × 4 four parallel electrical signals. The 10.3125 Gb / s × 4 four parallel electric signals are input to the frame accommodation / processing unit 301.

  The 10.3125 Gb / s × 4 four parallel electric signals input to the frame accommodation / processing unit 301 are simply monitored by the 64B / 66B monitor unit 311 using the 64B / 66B code.

  The 10.3125 Gb / s × 4 four parallel electric signals are input to the OTU2e accommodating unit 312 after quality monitoring is performed by the 64B / 66B monitoring unit 311. Each of the 10.3125 Gb / s × 4 four parallel electric signals is mapped to the payload of the 11.006 Gb / s OTU2e frame by the OTU2e accommodating unit 312 and output as the four parallel signals of the OTU2e frame. The four parallel signals of the OTU2e frame are output to the network signal transmission / reception unit 131.

  In the network signal transmission / reception unit 131, the E / O conversion unit 132 converts the four parallel signals of the 11.996 Gb / s OTU2e frame into optical signals having different wavelengths, and the wavelength multiplexing unit (WDM-MUX) unit 133 Performs multiplexing processing at the wavelength level. The wavelength-multiplexed optical signal is output to the optical transmission line 11 on the network side through the optical transmission line 11. For example, in the optical transmission system 3 illustrated in FIG. 10, transmission is performed from the optical transmission device 300 </ b> A toward the opposite optical transmission device 300 </ b> B.

  In the optical transmission apparatus 300, an optical signal is received from the network side by the reception system section 303 (the circuit system portion on the lower side of FIG. 9) shown in FIG. In the reception system unit 303, the network signal transmission / reception unit 131 in the optical transmission apparatus 300 receives an optical signal from the optical transmission line 11, and the optical signal is wavelength-multiplexed by a wavelength multiplexing / demultiplexing unit (WDM-DEMUX) 134. The signal is separated for each wavelength (in this example, it is separated into four parallel signals). Further, the O / E conversion unit 135 converts the optical signal for each wavelength into an electrical signal of the OTU2e frame, and outputs the four parallel signals converted into the electrical signal to the frame accommodation / processing unit 121. That is, in the reception system unit 303, the network signal transmission / reception unit 131 extracts four parallel electrical signals of OTU2e (11.996 Gb / s × 4) frames from the optical signal and outputs them to the frame accommodation / processing unit 301.

  In the frame accommodation / processing unit 301, the OTU2e termination unit 313 having a 4-parallel configuration performs termination processing of the 4-parallel OTU2e frame signal to monitor the occurrence of errors and failures on the network side, and 10.3125 Gb / s The client signal is extracted from the payload, and four parallel client signals of 10.3125 Gb / s × 4 are extracted.

  The 10.3125 Gb / s × 4 4-parallel client signals extracted by the OTU2e termination unit 313 are monitored by the 64B / 66B monitor unit 314 for the overhead of 64B / 66B, thereby performing simple quality monitoring. The 10.3125 Gb / s × 4 4-parallel client signals whose quality is monitored by the 64B / 66B monitor unit 314 are output to the client signal transmitting / receiving unit 111.

  In the client signal transmitting / receiving unit 111, the E / O conversion unit 114 converts each of 10.3125 Gb / s × 4 parallel electric signals into optical signals having different wavelengths, and a wavelength multiplexing unit (WDM-MUX) unit 115, multiplexing processing at the wavelength level is performed on optical signals having different wavelengths, and 10.3125 Gb / s × 4 four parallel signals are output to the client side.

  As described above, in the optical transmission apparatus 300 according to the second embodiment, the parallel signal can be transferred in parallel without returning the client-side signal to the bulk signal. Compared with this form, it is more economical. On the other hand, since the transfer adjustment (skew adjustment) between the parallel signals is not performed so that it can be handled as a bulk signal at the time of conversion to the network side frame, the skew between the parallel signals accumulates. This skew is adjusted between clients.

    In the second embodiment shown in FIG. 9 and FIG. 10, the client signal is mapped to the OTU2e network transmission frame of 11.0696 Gb / s. However, the network of 11.0949 Gb / s OTU1e is shown. It is also possible to use a transmission frame.

  9 shows an example in which the transmission system unit 302 and the reception system unit 303 are included in one unit. However, the transmission system unit 302 and the reception system unit 303 are respectively configured. It can also consist of independent units.

  The second embodiment of the present invention has been described above. In the second embodiment, the transmission system unit corresponds to the transmission system unit 302, and the reception system unit corresponds to the reception system unit 303. The client signal receiving unit described above corresponds to the wavelength demultiplexing unit 112 and the O / E conversion unit 113 in the client signal transmitting / receiving unit 111. The first monitor unit described above corresponds to the 64B / 66B monitor unit 311, and the frame storage unit corresponds to the OTU2e storage unit 312. The network signal transmission unit described above corresponds to the E / O conversion unit 132 and the wavelength multiplexing unit 133 in the network signal transmission / reception unit 131.

  The network signal receiving unit described above corresponds to the wavelength demultiplexing unit (WDM-DEMUX) 134 and the O / E converting unit 135 in the network signal transmitting / receiving unit 131. Further, the OTU2e termination unit 313 corresponds to the frame termination unit, and the 64B / 66B monitor unit 314 corresponds to the second monitoring unit. The client signal transmission unit described above corresponds to the E / O conversion unit 114 and the wavelength multiplexing unit (WDM-MUX) 115 in the client signal transmission / reception unit 111.

  And in the optical transmission apparatus 300 of 2nd Embodiment, it can be set as the structure containing only the function of the transmission system | strain part 302. FIG. In this case, the optical transmission apparatus 300 returns the client signal receiving unit (the wavelength multiplexing / demultiplexing unit 112 and the O / E conversion unit 113) that receives the client signal in the parallel format, and returns the client signal in the parallel format to the bulk client signal. The first monitor unit (64B / 66B monitor unit 311) for monitoring the quality of each of the parallel signal client signals and the parallel signal client signals are mapped to a network transmission frame to form a parallel format. Each of the frame accommodating unit (OTU2e accommodating unit 312) that generates the network transmission signal and the parallel-type network transmission signal generated by the frame accommodating unit are converted into optical signals having different wavelengths, and the optical signals having the different wavelengths are also converted. Is wavelength-multiplexed and sent to the optical transmission line 11 as a network signal. Configured to have the network signal transmitting section and the (E / O conversion unit 132 and the wavelength multiplexing section 133), the.

  When the optical transmission apparatus 300 includes both functions of the transmission system unit 302 and the reception system unit 303, in addition to the configuration of the transmission system unit 302 described above, the reception system unit 303 further includes a wavelength. Receiving a multiplexed network signal, separating the wavelength-multiplexed network signal for each wavelength, and optoelectrically converting the signals separated for each wavelength to generate a parallel network signal. Unit (wavelength demultiplexing unit 134 and O / E conversion unit 135), and a frame termination unit (OTU2e termination) that extracts a client signal mapped to a network transmission frame payload of a parallel network signal as a parallel client signal Part 313) and the first to monitor the quality of each client signal in parallel form Monitor unit (64B / 66B monitor unit 314), and a client signal transmission unit (converting the parallel-type client signals into optical signals of different wavelengths, wavelength-multiplexing the optical signals of different wavelengths and transmitting them to the client side) An E / O converter 114 and a wavelength multiplexer 115).

  With such a configuration, since the parallel format signal can be transferred in the parallel format without returning the client side signal to the bulk signal, it is more economical than the first embodiment. An optical transmission device can be realized.

[Third Embodiment]
In the first embodiment, for a parallel 40 GbE signal, after absorbing the phase shift between the parallel signals, the quality is monitored for the bulk signal of the 40 GbE PCS layer, the bulk signal is divided, and the original parallel format An inverse multiplexer and virtual concatenation were used to return the signal.

  On the other hand, in the third embodiment, the phase shift between the parallel signals is absorbed and returned to the state without the phase shift, but the parallel state of the 10 G × 4 client signal of the 40 GbE signal is maintained, and this parallel An example in which each format client signal is mapped to the payload of an OTU2e frame overclocked in units of 10G will be described.

  FIG. 11 is a block diagram showing a configuration of an optical transmission apparatus 400 according to the third embodiment of the present invention. FIG. 12 shows an example in which the optical transmission system 4 is configured with the optical transmission apparatus 400A and the optical transmission apparatus 400B using two optical transmission apparatuses 400 shown in FIG. The optical transmission apparatuses 400A and 400B are collectively referred to as the optical transmission apparatus 400.

  11 is different from the optical transmission device 100 shown in FIG. 1 in that the configuration of the frame accommodation / processing unit 121 shown in FIG. 1 is the same as that of the frame accommodation / processing unit 401 shown in FIG. The changes are different. The other components (client signal transmission / reception unit 111 and network signal transmission / reception unit 131 shown in FIG. 11) have the same configuration as in FIG. Therefore, the same reference numerals are given to the same components.

  An optical transmission apparatus 400 shown in FIG. 11 receives a client signal from the client side, converts this client signal into a signal on the network side, and outputs it to the optical transmission line 11 (broken line shown on the upper side in the figure). Circuit portion surrounded by) 402 and a reception system section that receives a signal on the network side from the optical transmission line 11, extracts a client signal from the signal on the network side, and outputs it to the client side (on the lower side in the figure) 403) of the circuit system surrounded by a broken line.

  That is, the transmission system unit 402 includes a wavelength demultiplexing unit 112 in the client signal transmission / reception unit 111, an O / E conversion unit 113, an MLD skew adjustment unit (no termination) 411 in the frame accommodation / processing unit 401, and an OTU2e mapping unit 412. 40 GbE / PCS / MAC monitor unit 413. The network signal transmission / reception unit 131 includes an E / O conversion unit 132 and a wavelength multiplexing unit (WDM-MUX) 133.

  The reception system unit 403 includes a wavelength multiplexing unit (WDM-MUX) 115 in the client signal transmission / reception unit 111, an E / O conversion unit 114, an MLD processing unit (no termination) 415 in the frame accommodation / processing unit 401, and an OTU2e. The terminal unit 414, 40 GbE / PCS / MAC monitor unit 416, O / E conversion unit 135 in the network signal transmission / reception unit 131, and wavelength demultiplexing unit (WDM-DEMUX) 134 are configured.

  In the above configuration, in the transmission system unit 402, the client signal transmission / reception unit 111 receives 40 GbE / LAN signals (4. parallel signals of 10.3125 Gb / s × 4) multiplexed at four wavelengths transmitted from the client side. Receive. The 40 GbE / LAN signal is subjected to wavelength multiplexing separation by a wavelength multiplexing / demultiplexing unit (WDM-DEMUX) 112. Thereafter, the optical signal is converted into an electrical signal (O / E conversion) by the O / E conversion unit 113 and output as 10.3125 Gb / s × 4 4 parallel electrical signals. The 10.3125 Gb / s × 4 4 parallel electric signals are input to the frame accommodation / processing unit 401.

  The 10.3125 Gb / s × 4 4-parallel electrical signals input to the frame accommodation / processing unit 401 are absorbed by the MLD skew adjustment unit (without MLD termination) 411 so that the phase shift between the parallel signals is absorbed. It is returned to the state that is not. Regarding the quality monitoring of 40 GbE bulk signals, the MLD skew adjustment unit 411 absorbs the phase difference between the 10.3125 Gb / s × 4 parallel signals and then transmits the frame by the 40 GbE / PCS / MAC monitoring unit 413. Perform in parallel with processing.

  The 10.3125 Gb / s × 4 4-parallel electric signals are adjusted to have no phase shift by the MLD skew adjustment unit 411 and then mapped to the payload of the 11.006 Gb / s OTU2e frame by the OTU2e mapping unit 412 And output as four parallel signals of the OTU2e frame. The four parallel signals of the OTU2e frame are output to the network signal transmission / reception unit 131.

  In the network signal transmission / reception unit 131, the E / O conversion unit 132 converts the 4 parallel signals of the 11.006 Gb / s OTU2e frame into optical signals having different wavelengths, and a wavelength multiplexing unit (WDM-MUX) unit 133. Thus, multiplexing processing at the wavelength level is performed. The wavelength-multiplexed optical signal is output toward the client side through the optical transmission line 11. For example, as shown in the optical transmission system 4 of FIG. 12, the transmission is performed from the optical transmission apparatus 400A toward the opposite optical transmission apparatus 400B.

  In the optical transmission apparatus 400, an optical signal is received from the network side by a reception system unit 403 (a circuit system part surrounded by a broken line on the lower side of the figure) shown in FIG.

  In this reception system unit 403, the network signal transmission / reception unit 131 receives an optical signal from the optical transmission line 11, and the wavelength division multiplexing signal (WDM-DEMUX) 134 separates this optical signal for each wavelength. (In this example, it is separated into four parallel signals). The O / E converter 135 converts the optical signal for each wavelength into an electrical signal of the OTU2e frame, and outputs the parallel signals of the four OTU2e frames converted into the electrical signal to the frame accommodation / processing unit 121. . That is, in the reception system unit 303, the network signal transmission / reception unit 131 extracts an electrical signal of a parallel OTU2e frame (11.96 Gb / s × 4) from the optical signal and outputs the electrical signal to the frame accommodation / processing unit 301.

  In the frame accommodation / processing unit 401, the parallel OTU2e termination unit 414 performs termination processing of the parallel OTU2e frame signal, and 10.3125 Gb / s × 4 mapped to the payload of the OTU2 frame by this termination processing. The four parallel client signals are extracted. Further, after the MLD skew adjustment unit 415 performs processing for absorbing the phase difference for the 10.3125 Gb / s × 4 four parallel signals, the 10.3125 Gb / s × 4 four parallel signals are transmitted to the client signal transmitting / receiving unit. 111 is output. For the quality monitoring of 40 GbE bulk signals, the MLD skew adjustment unit 415 absorbs the phase difference of 10.3125 Gb / s × 4 parallel signals, and then the 40 GbE / PCS / MAC monitoring unit 416 performs frame transmission processing. Do in parallel.

  The 10.3125 Gb / s × 4 4 parallel signals output from the MLD skew adjustment unit 415 are input to the client signal transmission / reception unit 111. In the client signal transmitting / receiving unit 111, the E / O conversion unit 114 converts each of 10.3125 Gb / s × 4 parallel electric signals into optical signals having different wavelengths, and a wavelength multiplexing unit (WDM-MUX) unit 115 performs multiplexing processing at the wavelength level for optical signals having different wavelengths, and outputs 10.3125 Gb / s × 4 parallel signals to the client side.

  In the third embodiment, an example in which the 10.3125 Gb / s signal is mapped to the payload of the OTU2e frame (11.096 Gb / s) is shown. However, the mapping to the payload of the OTU1e (11.049 Gb / s) frame is performed. It is also possible to do.

  Further, in the optical transmission device 400 illustrated in FIG. 11, the transmission system unit 402 and the reception system unit 403 are included in one unit. However, the transmission system unit and the reception system unit are independent of each other. Can be composed of units.

  As described above, in the optical transmission apparatus 400 according to the third embodiment, the parallel signal can be transferred in parallel without returning the client-side signal to the bulk signal. It is possible to realize an optical transmission device that is more economical than the embodiment.

  Although the third embodiment of the present invention has been described above, in the third embodiment, the transmission system unit corresponds to the transmission system unit 402, and the reception system unit corresponds to the reception system unit 403. The client signal receiving unit described above corresponds to the wavelength demultiplexing unit 112 and the O / E conversion unit 113 in the client signal transmitting / receiving unit 111. The first skew adjustment unit described above corresponds to the MLD skew adjustment unit 411, and the mapping unit corresponds to the OTU2e mapping unit 412. The network signal transmission unit described above corresponds to the E / O conversion unit 132 and the wavelength multiplexing unit 133 in the network signal transmission / reception unit 131.

  The network signal receiving unit described above corresponds to the wavelength demultiplexing unit (WDM-DEMUX) 134 and the O / E converting unit 135 in the network signal transmitting / receiving unit 131. Further, the OTU2e termination unit 414 corresponds to the above-described frame termination unit, and the MLD skew adjustment unit 415 corresponds to the second skew adjustment unit. The client signal transmission unit described above corresponds to the E / O conversion unit 114 and the wavelength multiplexing unit (WDM-MUX) 115 in the client signal transmission / reception unit 111.

  And in the optical transmission apparatus 400 of 3rd Embodiment, it can be set as the structure containing only the function of the transmission system | strain part 402. FIG. In this case, the optical transmission apparatus 400 adjusts the phase shift between the client signal receiving unit (the wavelength demultiplexing unit 112 and the O / E conversion unit 113) that receives the client signal in parallel format and the client signal in parallel format. The first skew adjustment unit (MLD skew adjustment unit 411) that performs the above and the parallel-type client signals, the phase deviation of which is adjusted by the first skew adjustment unit, are mapped to the network transmission frame, and the parallel-type network transmission is performed. A mapping unit (OTU2e mapping unit 412) that generates a signal and a parallel-type network transmission signal generated by the mapping unit are converted into optical signals of different wavelengths, and the optical signals of different wavelengths are wavelength-multiplexed. Network signal transmitter for transmitting as a network signal to the optical transmission line 11 E and / O conversion unit 132 and the wavelength multiplexing section 133), and a.

  Further, when the optical transmission device 400 includes the functions of both the transmission system unit 402 and the reception system unit 403, in addition to the configuration of the transmission system unit 402 described above, the reception system unit 403 further includes an optical Receives a wavelength-multiplexed network signal from the transmission line, separates the wavelength-multiplexed network signal for each wavelength, and generates a parallel network signal by photoelectrically converting the signals separated for each wavelength. A network signal receiving unit (wavelength multiplexing / demultiplexing unit 134 and O / E conversion unit 135), and a frame termination unit that extracts a client signal mapped to a network transmission frame of a parallel network signal as a parallel client signal ( OTU2e termination unit 414) and a second type for adjusting the phase shift between the parallel type client signals A queue adjustment unit (MLD skew adjustment unit 415) and a client signal transmission unit (E / O conversion unit 114 and wavelength multiplexing unit 115) that transmit to the client signal client side in parallel format that is phase-adjusted by the second skew adjustment unit And is configured.

  With the above configuration, since the parallel signal can be transferred in parallel without returning the client-side signal to the bulk signal, the optical transmission device is more economical than the first embodiment. Can be realized.

  As described above, as described in the first, second, and third embodiments of the present invention, the optical transmission apparatus of the present invention can transfer a 40 GbE signal over a long distance using a low-speed parallel signal. Thereby, since components for low speed can be used, an optical transmission device excellent in economic efficiency can be realized, and an optical transmission system can be configured economically.

  Although the embodiments of the present invention have been described above, the optical transmission apparatus of the present invention is not limited to the above illustrated examples, and various modifications can be made without departing from the scope of the present invention. Of course.

It is a figure which shows the structure of the optical transmission apparatus which concerns on the 1st Embodiment of this invention. It is a figure which shows the structural example of the optical transmission system using the optical transmission apparatus shown in FIG. It is a figure which shows the structural example of a 40GbE_LAN system. It is a figure for demonstrating the skew adjustment between lanes by MLD. It is a figure which shows the example of mapping of 40G signal (STM-256) to OPU2-4v. It is a figure for demonstrating the overhead (OH) of virtual concatenation. It is a figure which shows the accommodation example (the 1) to OPU2-4v of a 40GbE signal. It is a figure which shows the accommodation example (the 2) to OPU2-4v of a 40GbE signal. It is a figure which shows the structure of the optical transmission apparatus which concerns on the 2nd Embodiment of this invention. It is a figure which shows the structural example of the optical transmission system using the optical transmission apparatus shown in FIG. It is a figure which shows the structure of the optical transmission apparatus which concerns on the 3rd Embodiment of this invention. It is a figure which shows the structural example of the optical transmission system using the optical transmission apparatus shown in FIG. It is a figure which shows the structural example of the conventional 40 Gb / s optical transmission system.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1, 3, 4 ... Optical transmission system, 2 ... 40GbE_LAN system, 11 ... Optical transmission line, 100, 100A, 100B ... Optical transmission apparatus, 111 ... Client signal transmission / reception part, 111A. ..Client signal transmission / reception unit 112, 134... Wavelength demultiplexing unit (WDM-DEMUX) 113 113 135 O / E conversion unit 114 114 132 E / O conversion unit 115 133 ... Wavelength multiplexing unit (WDM-MUX), 121,121A ... Frame accommodation / processing unit, 122 ... MLD skew adjustment unit (MLD termination), 123,127 ... 40GbE / PCS / MAC monitor unit , 124: Inverse multiplexer (Inverse / MUX), 125: OTU2e termination, 126: Virtual concatenation (VC) AT / MUX) unit, 128... MLD processing unit (VL insertion), 131, 131A, network signal transmitting / receiving unit, 200A, 200B, optical transmission device, 211, MAC processing unit, 212. PCS processing unit (TX), 213 ... MLD processing unit (TX), 214 ... MLD processing unit (RX), 215 ... PCS processing unit (RX), 231 ... 40GbE transmission / reception unit, 232... E / O conversion unit, 233... Wavelength multiplexing unit, 234 .. wavelength demultiplexing unit, 235... O / E conversion unit, 300, 300A, 300B. ... Frame accommodation / processing section, 302 ... Transmission system section. 303 ... Receiving system unit, 311, 314 ... 64B / 66B monitor unit, 312 ... OTU2e accommodating unit, 313 ... OTU2e termination unit, 400A, 400B ... optical transmission device, 401 ... Frame accommodating / processing unit, 402 ... transmission system unit, 403 ... reception system unit, 411,415 ... MLD skew adjustment unit (without MLD termination), 412 ... OTU2e mapping unit, 413,416,・ ・ 40GbE ・ PCS / MAC monitor part, 414 ... OTU2e termination part

Claims (8)

It accommodates the client signal, an optical transmission apparatus for transmitting the optical Transmission path by converting the client signal to the network side of the signal,
A client signal receiver for receiving a parallel-type client signal;
A parallel signal skew adjustment unit that adjusts a phase shift between parallel signals of the parallel-type client signal and restores the parallel-type client signal to a bulk client signal;
A first monitor for monitoring the quality of the bulk client signal;
Demultiplexing the bulk client signal into parallel client signals and mapping each of the separated parallel client signals to a network transmission frame to generate a parallel network transmission signal; and
A network signal that converts each of the parallel-type network transmission signals generated by the inverse multiplexer unit into optical signals of different wavelengths, and multiplexes the optical signals of different wavelengths and sends them to the optical transmission line as network signals. A transmission unit;
An optical transmission device comprising: A transmission system unit that accommodates a client signal, converts the client signal into a signal on the network side and sends it to an optical transmission line, receives an optical signal from the network side through the optical transmission line, and converts the client signal from the optical signal. An optical transmission device having a receiving system part to be extracted,
The transmission system section is
A client signal receiver for receiving a parallel-type client signal;
A parallel signal skew adjustment unit that adjusts a phase shift between parallel signals of the parallel-type client signal and restores the parallel-type client signal to a bulk client signal;
A first monitor for monitoring the quality of the bulk client signal;
Demultiplexing the bulk client signal into parallel client signals and mapping each of the separated parallel client signals to a network transmission frame to generate a parallel network transmission signal; and
A network signal that converts each of the parallel-type network transmission signals generated by the inverse multiplexer unit into optical signals of different wavelengths, and multiplexes the optical signals of different wavelengths and sends them to the optical transmission line as network signals. A transmission unit;
With
The receiving system section is
A network signal of a parallel type is received by receiving a wavelength-multiplexed network signal from the optical transmission line, separating the wavelength-multiplexed network signal for each wavelength, and photoelectrically converting the signals separated for each wavelength. A network signal receiver for generating
A frame termination unit that extracts a client signal mapped to a network transmission frame of the parallel network signal, and extracts a parallel client signal;
A signal linking unit for recovering a bulk client signal from the parallel client signal;
A second monitoring unit for monitoring the quality of the bulk client signal restored by the signal coupling unit;
A signal distribution unit for converting a bulk client signal whose quality is monitored by the second monitoring unit into a client signal in a parallel format;
A client signal transmission unit that transmits a client signal in parallel format output from the signal distribution unit to the client side; and
An optical transmission device comprising: In the separation and multiplexing of the bulk client signal, the overhead of the network transmission frame defined in G.709 of ITU-T (International Telecommunication Union Telecommunication Standardization Sector) is used for transmission of information used to restore the original bulk signal. The optical transmission device according to claim 1, wherein the optical transmission device is used. An optical transmission apparatus that accommodates a client signal, converts the client signal into a signal on the network side, and sends the signal to an optical transmission line,
A client signal receiver for receiving a parallel-type client signal;
A first monitoring unit that monitors the quality of each of the parallel- type client signals without returning the parallel-type client signals to a bulk client signal;
A frame accommodating unit that maps each of the parallel format client signals to a network transmission frame to generate a parallel format network transmission signal; and
A network that converts each of the parallel-type network transmission signals generated by the frame accommodating unit into optical signals of different wavelengths, and multiplexes the optical signals of different wavelengths and sends them to the optical transmission line as network signals A signal transmitter;
An optical transmission device comprising: A transmission system unit that accommodates a client signal, converts the client signal into an optical signal, and transmits the optical signal to a network-side optical transmission path; receives an optical signal from the network side through the optical transmission path; An optical transmission device having a receiving system part for extracting
The transmission system section is
A client signal receiver for receiving a parallel-type client signal;
A first monitoring unit that monitors the quality of each of the parallel- type client signals without returning the parallel-type client signals to a bulk client signal;
A frame accommodating unit that maps each of the parallel format client signals to a network transmission frame to generate a parallel format network transmission signal; and
A network that converts each of the parallel-type network transmission signals generated by the frame accommodating unit into optical signals of different wavelengths, and multiplexes the optical signals of different wavelengths and sends them to the optical transmission line as network signals A signal transmitter;
With
The receiving system section is
A network signal of a parallel type is received by receiving a wavelength-multiplexed network signal from the optical transmission line, separating the wavelength-multiplexed network signal for each wavelength, and photoelectrically converting the signals separated for each wavelength. A network signal receiver for generating
A frame termination unit that extracts a client signal mapped to a network transmission frame of the parallel network signal as a parallel client signal;
A second monitoring unit for monitoring the quality of the parallel client signal;
A client signal transmitter for transmitting a client signal in parallel format whose quality is monitored by the second monitor to the client;
An optical transmission device comprising: An optical transmission apparatus that accommodates a client signal, converts the client signal into a signal on the network side, and sends the signal to an optical transmission line,
A client signal receiver for receiving a parallel-type client signal;
A first skew adjustment unit that adjusts a phase shift between the parallel client signals;
A mapping unit that maps each of the parallel-type client signals adjusted in phase shift by the first skew adjustment unit to a network transmission frame to generate a parallel-type network transmission signal;
A network signal for converting each of the parallel-type network transmission signals generated by the mapping unit into an optical signal of a different wavelength, and wavelength-multiplexing the optical signal of the different wavelength and sending it to the optical transmission line as a network signal A transmission unit;
An optical transmission device comprising: A transmission system unit that accommodates a client signal, converts the client signal into an optical signal on the network side, and transmits the optical signal to an optical transmission line; receives an optical signal from the network side through the optical transmission line; An optical transmission device having a receiving system part for extracting
The transmission system section is
A client signal receiver for receiving a parallel-type client signal;
A first skew adjustment unit that adjusts a phase shift between the parallel client signals;
A mapping unit that maps each of the parallel-type client signals adjusted in phase shift by the first skew adjustment unit to a network transmission frame to generate a parallel-type network transmission signal;
A network signal for converting each of the parallel-type network transmission signals generated by the mapping unit into an optical signal of a different wavelength, and wavelength-multiplexing the optical signal of the different wavelength and sending it to the optical transmission line as a network signal A transmission unit;
With
The receiving system section is
A network signal of a parallel type is received by receiving a wavelength-multiplexed network signal from the optical transmission line, separating the wavelength-multiplexed network signal for each wavelength, and photoelectrically converting the signals separated for each wavelength. A network signal receiver for generating
A frame termination unit that extracts a client signal mapped to a network transmission frame of the parallel network signal as a parallel client signal;
A second skew adjustment unit for adjusting a phase shift between the parallel-type client signals;
A client signal transmission unit that transmits a client signal in a parallel format phase-adjusted by the second skew adjustment unit to the client side;
An optical transmission device comprising: The network transmission frame is ITU-T G.264. ITU-T G.709, and its bit rate is ITU-T G.709. 8. The optical transmission device according to claim 1, 2, 4 to 7, wherein the optical transmission device is an OTU2e (11.068 Gb / s) or OTU1e (11.049 Gb / s) network transmission frame defined in sup43.

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