Huawei OptiX OSN 8800 is a high-performance, intelligent optical transport platform used for building next-generation telecommunication networks. A crucial component of this platform are the Optical Transponder (OTU) boards responsible for converting client-side services (Ethernet, SDH, etc.) into standard optical signals for transmission over fiber optic cables.
The OSN8800 offers various OTU boards catering to different needs and speeds:
- OTU2 boards: Support 10G Ethernet or 10G SDH services and are ideal for cost-effective short-haul and metro network applications.
- OTU4 boards: Handle 100G Ethernet or 100G SDH services, delivering high bandwidth for data center backhauls and long-haul networks.
- OTUC boards: These cutting-edge boards offer support for future 400G Ethernet and 400G SDH services, future-proofing your network infrastructure.
Now, we will introduce the LSC boards on Huawei OSN8800, which is a wavelength conversion board and applies to coherent systems. In the receive direction, the board receives one 100GE/OTU4 optical signal from the client equipment, maps the optical signal into an OTU4 signal, and converts the OTU4 signal into a standard WDM wavelength.
There are different versions of LSC boards, TN12, TN13, TN15, TN17, TN18 and TN19. The mappings between the board and equipment are as below:
Board | Initial Versiona(a) | General 8800 T64 Subrack | Enhanced 8800 T64 Subrack | General 8800 T32 Subrack | Enhanced 8800 T32 Subrack | 8800 T16 Subrack | 8800 Universal Platform Subrack | 6800 Subrack | 3800 Chassis |
TN12LSC | V100R006C03 | Y | Y | Y | Y | Y | Y | Y | Yb |
TN13LSC | V100R008C00 | Y | Y | Y | Y | Y | Y | N | Yb |
TN15LSC | V100R008C10 | Y | Y | Y | Y | Y | Y | N | T01: Yb
The others: N |
TN17LSC | V100R010C00 | Y | Y | Y | Y | Y | Y | Y | N |
TN18LSC | V100R011C00 | Y | Y | Y | Y | Y | Y | N | N |
TN19LSC | V100R013C10 | Y | Y | Y | Y | Y | Y | Ya | N |
a: When the TN19LSC board is installed in an OSN 6800 subrack, the first generation T5U, T62, and T65 pluggable modules without heat dissipation holes are not supported.b: To use a TN12LSC/TN13LSC/TN15LSCT01 board in the OptiX OSN 3800 chassis, meet the following requirements:
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We list the differences of different hardware version in below chart:
Function:
Board | FEC Encoding |
TN12LSC | HFEC/SDFEC |
TN13LSC | HFEC/SDFEC |
TN15LSC | HFEC/SDFEC2 |
TN17LSC | SDFEC2 |
TN18LSC | SDFEC2/HFEC PLUS |
TN19LSC | SDFEC2 |
Specification:
Board | Client-Side Pluggable Optical Module | WDM-Side Fixed Optical Module | WDM-Side Pluggable Optical Module |
TN12LSC | 100G BASE-10×10G-10 km-CFP
100G BASE-LR4-10 km-CFP (100G BASE-4×25G)/(OTU4-4×28G)-10 km-CFP |
40000 ps/nm-C Band-Tunable Wavelength-ePDM-QPSK(HFEC)-PIN
55000 ps/nm-C Band-Tunable Wavelength-ePDM-QPSK(SDFEC)-PIN |
N/A |
TN13LSC | 100G BASE-LR4-10 km-CFP
100G BASE-10×10G-10 km-CFP (100G BASE-4×25G)/(OTU4-4×28G)-10km-CFP |
40000 ps/nm-C Band-Tunable Wavelength-ePDM-QPSK(HFEC)-PIN
55000 ps/nm-C Band-Tunable Wavelength-ePDM-QPSK(SDFEC)-PIN |
N/A |
TN15LSC | 100G BASE-LR4-10 km-CFP
100G BASE-10×10G-10 km-CFP (100G BASE-4×25G)/(OTU4-4×28G)-10km-CFP
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40000 ps/nm-C Band-Tunable Wavelength-ePDM-QPSK(HFEC)-PIN
150000 ps/nm-C Band-Tunable Wavelength-ePDM-QPSK(SDFEC2, wDCM-Enhanced)-PIN 150000 ps/nm-C Band-Tunable Wavelength-ePDM-QPSK(SDFEC2)-PIN 55000 ps/nm-C Band-Tunable Wavelength-ePDM-QPSK(SDFEC2)-PIN 40000 ps/nm-C Band-Tunable Wavelength-ePDM-QPSK(SDFEC2)-PIN 150000 ps/nm-C Band-Tunable Wavelength-ePDM-QPSK(SDFEC2, wDCM)-PIN 12000 ps/nm-C Band-Tunable Wavelength-ePDM-QPSK(SDFEC2,wDCM-Metro)-PIN |
N/A |
TN17LSC | 100G BASE-LR4-10 km-CFP
100G BASE-10×10G-10 km-CFP (100G BASE-4×25G)/(OTU4-4×28G)-10 km-CFP
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150000 ps/nm-C Band-Tunable Wavelength-ePDM-QPSK(SDFEC2)-PIN
55000 ps/nm-C Band-Tunable Wavelength-ePDM-QPSK(SDFEC2)-PIN 40000 ps/nm-C Band-Tunable Wavelength-ePDM-QPSK(SDFEC2)-PIN 150000 ps/nm-C Band-Tunable Wavelength-ePDM-QPSK(SDFEC2, wDCM)-PIN 12000 ps/nm-C Band-Tunable Wavelength-ePDM-QPSK(SDFEC2,wDCM-Metro)-PIN 120000 ps/nm-C Band-Tunable Wavelength-ePDM-QPSK(SDFEC2)-PIN 120000 ps/nm-C Band-Tunable Wavelength-ePDM-QPSK(SDFEC2, wDCM)-PIN 40000 ps/nm-C Band-Tunable Wavelength-ePDM-QPSK(SDFEC2, wDCM, LH)-PIN 150000 ps/nm-C Band-Tunable Wavelength-ePDM-QPSK(SDFEC2, Enhanced)-PIN |
N/A |
TN18LSC | (100 GBASE-4×25G)/(OTU4-4×28G)-10 km-CFP2
100G BASE-ER4-40 km-CFP2 100G BASE-SR10-100 m-CFP2 QSFP28-100G(4x25G)-850nm(SR4)-MMF-0.1kma (100GBASE-4×25G)-CLR4-2km-QSFP28a |
N/A | 40000ps/nm-Extended C band-Tunable Wavelength-ePDM-QPSK(SDFEC2, ULH+, T5U)-100G CFP
40000ps/nm-Extended C band-Tunable Wavelength-ePDM-QPSK(SDFEC2 , wDCM, LH, T62)-100G CFP 12000ps/nm-Extended C band-Tunable Wavelength-ePDM-QPSK(SDFEC2 , wDCM-Metro, T65)-100G CFP 40000ps/nm-Extended C band-Tunable Wavelength-ePDM-QPSK (configurable FEC, coherent/wDCM, ULH+, TxA)-100G CFP NOTE:
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TN19LSC | (100GBASE-4×25G)/(OTU4-4×28G)-10km-CFP2
100GBASE-ER4-40km-CFP2 100GBASE-SR10-100m-CFP2 QSFP28-100G(4x25G)-850nm(SR4)-MMF-0.1kma (100GBASE-4×25G)-CLR4-2km-QSFP28a |
N/A | 100000ps/nm-Extended C band-Tunable Wavelength-ePDM-QPSK(SDFEC2, SLH+, T50)-100G CFP
100000ps/nm-Extended C band-Tunable Wavelength-ePDM-QPSK(SDFEC2, SLH, T51)-100G CFP 100000ps/nm-Extended C band-Tunable Wavelength-ePDM-QPSK(SDFEC2, SLH, high optical power, T51)-100G CFP 55000ps/nm-Extended C band-Tunable Wavelength-ePDM-QPSK(SDFEC2, ULH, T52)-100G CFP 55000ps/nm-Extended C Band-Tunable Wavelength-ePDM-100G QPSK(SDFEC2, ULH, High optical power, T52)-CFP 40000ps/nm-Extended C band-Tunable Wavelength-ePDM-QPSK(SDFEC2, LH, T53)-100G CFP 40000ps/nm-Extended C Band-Tunable Wavelength-ePDM-100G QPSK(SDFEC2, LH, High optical power, T53)-CFP CFP-100G-(1529.17nm to 1567.1nm)(DWDM,Tunable, T5U)-SMF 100000ps/nm-Extended C band-Tunable Wavelength-ePDM-QPSK(SDFEC2, wDCM, ULH, T61)-100G CFP 100000ps/nm-Extended C band-Tunable Wavelength-ePDM-QPSK(SDFEC2, wDCM, ULH, high optical power, T61)-100G CFP CFP-100G-(1529.17nm to 1567.1nm)(DWDM,Tunable, T62)-SMF 16000ps/nm-Extended C band-Tunable Wavelength-ePDM-QPSK(SDFEC2 , wDCM, Metro+, T63)-100G CFP 16000ps/nm-Extended C Band-Tunable Wavelength-ePDM-100G QPSK wDCM(SDFEC2, Metro+, High optical power, T63)-CFP CFP-100G-(1529.17nm to 1567.1nm)(DWDM,Tunable, T65)-SMF |
And the board substitution relation among different versions as below:
Original Board | Substitute Board | Substitution Rules |
TN12LSC | TN13LSC
TN15LSC |
TN13LSC can be created as 12LSC on the NMS. The former can substitute for the latter, without any software upgrade. After the substitution, the TN13LSC board functions as the TN12LSC board.
TN15LSC can be created as 12LSC on the NMS. The former can substitute for the latter, without any software upgrade. After the substitution, the TN15LSC board functions as the TN12LSC board. A TN13LSC/TN15LSC board occupies two slots, and a TN12LSC board occupies four slots. To use a TN13LSC/TN15LSC board to substitute for a TN12LSC board, install the TN13LSC/TN15LSC board into the left-side slot of the four slots that the TN12LSC board originally occupies and keep the right-side slot of them vacant. NOTE: When both the receive and transmit boards use HFEC, the TN12LSC board can be replaced with the TN15LSC board. In an OptiX OSN 6800 subrack, the TN12LSC board cannot be replaced with the TN13LSC board. In an OptiX OSN 6800 subrack, the TN12LSC board cannot be replaced with the TN15LSC board. |
TN13LSC | TN15LSC | TN15LSC can be created as 13LSC on the NMS. The former can substitute for the latter, without any software upgrade. After the substitution, the TN15LSC board functions as the TN13LSC board.
NOTE: When both the receive and transmit boards use HFEC, the substitution applies. |
TN15LSC | TN17LSC | TN17LSC can be created as 15LSC on the NMS. The former can substitute for the latter, without any software upgrade. After the substitution, the TN17LSC board functions as the TN15LSC board.
NOTE: When both the receive and transmit boards use SDFEC2, the substitution applies. The TN15LSC board cannot be replaced with the TN17LSCT62 and TN17LSCT50 boards. |
TN15LSC | TN19LSC | TN19LSC can be created as 15LSC on the NMS. The former can substitute for the latter, without any software upgrade. After the substitution, the TN19LSC board functions as the TN18LSC board.
A TN15LSC board occupies two slots, and a TN19LSC board occupies one slot. To use a TN19LSC board to substitute for a TN15LSC board, install the TN19LSC board into the left-side slots of the two slots that the TN15LSC board originally occupies and keep the right-side slot of them vacant. |
TN17LSC | TN19LSC | TN19LSC can be created as 17LSC on the NMS. The former can substitute for the latter, without any software upgrade. After the substitution, the TN19LSC board functions as the TN17LSC board.
A TN17LSC board occupies two slots, and a TN19LSC board occupies one slot. To use a TN19LSC board to substitute for a TN17LSC board, install the TN19LSC board into the left-side slots of the two slots that the TN17LSC board originally occupies and keep the right-side slot of them vacant. |
TN18LSC | TN19LSC | TN19LSC can be created as 18LSC on the NMS. The former can substitute for the latter, without any software upgrade. After the substitution, the TN19LSC board functions as the TN18LSC board. |
TN19LSC | None | – |
By understanding the differences of LSC boards on the Huawei OSN8800, you can make informed decisions and choose the right hardware to build a robust, flexible, and high-performance optical transport network.
I hope this introduction provides a comprehensive overview of Huawei OSN8800 LSC boards. Feel free to contact us if you have any further questions or need more specific information about their functionalities or applications.