The Optical Internetworking Forum (OIF) continues to play a key role in achieving industry consensus to promote coherent transmission interoperability. Although 800G coherent pluggables that address both OIF 800ZR and 800G ZR+ based on interoperable probabilistic constellation shaping (PCS) defined in OpenROADM have only recently been announced, the OIF is already making progress towards interoperable 1600ZR and 1600ZR+ implementation agreements.
The Path Towards Robust, Interoperable 1600ZR/ZR+ Interfaces
With 200G per lane electrical PAM4 solutions recently introduced, network operators now have a path towards supporting 1600G host router I/O ports by using eight parallel electrical lanes (Figure 1). Similar to 400G and 800G generations, this is a key motivator in developing coherent pluggable modules to be plugged into these 1600G router ports for inter-data center optical links. However, along with the progress on the host interface side, there is still much work to be done to ensure a technically feasible and robust interoperable design for 1600ZR/ZR+ coherent pluggable modules.
Figure 1. Simple illustration of how advances in achieving 200G PAM4 can be leveraged for 1600ZR/ZR+ coherent optical transmission.
OIF Defining Both 1600ZR and 1600ZR+ Standards
Unlike previous coherent standardization efforts at 400G and 800G, in which enhanced 鈥淶R+鈥 performance links were defined outside of OIF, the OIF has launched initiatives to define both 1600ZR and 1600ZR+. Having both efforts occurring simultaneously enables the OIF to make decisions with both 1600ZR and 1600ZR+ in the same scope of discussions. This helps keep the two implementations as aligned as possible, which is beneficial for the industry considering the large investments of technology required. The focus of these investments includes advanced CMOS nodes to maintain low power consumption within the envelope of QSFP-DD and OSFP form-factor requirements, and advanced designs in high-speed RF/mixed-signal as the modulation approaches the Class 4 240Gbaud range (Figure 2).
Figure 2. Charting the course towards Class 4 baud rate standardization efforts.
As we saw in both the 400G and 800G generations, the foundation of 16QAM (4 bits/symbol) modulation was adopted and this is likely to also happen with the 1600G generation. For 1600G transmission, 16QAM modulation implies ~236+Gbaud data rate operation.
In addition to modulation order, the type of forward error correction (FEC) has also been a key parameter that required industry agreement. At 400G, the OIF adopted concatenated FEC (CFEC) as the 400ZR FEC and OpenZR+ MSA adopted oFEC (a high-performance FEC) for 400G ZR+. At 800G, the OIF decided to adopt oFEC for ZR, aligning it with ZR+ modes. To provide an enhanced performance mode beyond 800ZR, OpenROADM MSA defined an interoperable PCS for 800G ZR+ (Figure 3). It is likely that oFEC will be similarly adopted for both 1600ZR and combined with some interoperable PCS for 1600ZR+ modes.
Figure 3. 400G to 800G evolution of ZR vs. ZR+ implementations; how will 1600G ZR vs. ZR+ implementations be different?
What Will Be the Industry Consensus for 1600ZR/ZR+?
Every new generation of speeds-and-feeds encounters challenges around industry consensus and technology achievements that push the envelope 鈥 and 1600ZR/ZR+ is no different. There is currently great momentum driving these efforts forward, especially in anticipation of advances in generative AI that are pushing optical interconnect needs to higher bandwidths. Evidence of this momentum is apparent by other industry efforts beyond the OIF that are currently active. In addition to the OIF 1600ZR/ZR+ efforts, the IEEE has also begun working on 1.6TbE electrical and optical interface standards within the IEEE 802.3dj working group, anticipated to be ready by the second half of 2026.
In light of this progress, the question is 鈥渉ow does the industry reach consensus for 1600ZR/ZR+?鈥 We eagerly await the outcome.