New OSFP-XD form factor could challenge co-packaged optics

June 10, 2021
Such modules could supply sufficient connectivity to support the requirements of a 51.2T switch chip in a 1RU box via 32 modules. The creation of 3.2-Tbps versions of the OSFP-XD would accommodate 102.4T switches in the same form factor.

During an OFC 2021 workshop Sunday, June 6, Arista Networks Founder, Chief Development Officer, and Chairman Andy Bechtolsheim introduced the OSFP-XD (for “extra dense”) form factor. The form factor will leverage twice the number of electrical channels of the current 800G OSFP while maintaining the same module size. The increase in the number of channels would enable the OSFP-XD to support 1.6 Tbps with current 100G-per-lane SerDes technology and a power efficiency commensurate with expectations expected to arise with 51.2T switch chips, as well as 3.2 Tbps for the needs of 104.4T switching devices with the advent of 200G SerDes. And it will do so while offering a faceplate density similar to that which co-packaged optics promises.

The OSFP-XD specifications will feature a power envelope of 33 W and a (2x8) 16-lane electrical interface, with optical interfaces that vary by module scheme. Bechtolsheim described five 1.6T variants during his talk as part of the “Which Device Technologies Will Get Us Beyond 400G?” workshop. Two, the 1.6T-ZR2 (for 100 km at 30 W via fixed-wavelength lasers) and 1.6T-LR2 (for 10 km at 28 W), will leverage dual-channel 16QAM coherent transmission technology with dual LC connectors. The other three will be based on 200G PAM4 and offer 1 to 2 km of reach. The 1.6T-CWDM8 will feature an LC connector, the 1.6T-2FR4 will feature dual LCs, and the 1.6T-DR8 an octal SN/MDC connector. The power consumption for this last module is targeted at 21 W, while the other two have a 22-W target.

Such modules could supply sufficient connectivity to support the requirements of a 51.2T switch chip in a 1RU box via 32 modules. The creation of 3.2-Tbps versions of the OSFP-XD would either supply further faceplate density for 51.2T switches or handle the needs of 102.4T switches in the same 1RU form factor. Such pluggable modules would thus offer an alternative to co-packaged optics, Bechtolsheim argued at this workshop and on other panels during the week, while obviating some of the concerns and uncertainty about the creation of an entirely new technology. Speakers from Google during the week and in other forums (including a speaker who immediately followed Bechtolsheim on Sunday) have expressed doubts about whether co-packaged optics technology can be perfected in time for the arrival of 51.2T switches, so at least one hyperscaler may agree with Bechtolsheim’s viewpoint.

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About the Author

Stephen Hardy | Editorial Director and Associate Publisher, Lightwave

Stephen Hardy is editorial director and associate publisher of Lightwave and Broadband Technology Report, part of the Lighting & Technology Group at Endeavor Business Media. Stephen is responsible for establishing and executing editorial strategy across the both brands’ websites, email newsletters, events, and other information products. He has covered the fiber-optics space for more than 20 years, and communications and technology for more than 35 years. During his tenure, Lightwave has received awards from Folio: and the American Society of Business Press Editors (ASBPE) for editorial excellence. Prior to joining Lightwave in 1997, Stephen worked for Telecommunications magazine and the Journal of Electronic Defense.

Stephen has moderated panels at numerous events, including the Optica Executive Forum, ECOC, and SCTE Cable-Tec Expo. He also is program director for the Lightwave Innovation Reviews and the Diamond Technology Reviews.

He has written numerous articles in all aspects of optical communications and fiber-optic networks, including fiber to the home (FTTH), PON, optical components, DWDM, fiber cables, packet optical transport, optical transceivers, lasers, fiber optic testing, and more.

You can connect with Stephen on LinkedIn as well as Twitter.

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