Optical Transceiver Modules to Double in Density
Boston — An announcement this week involving some 14 companies will result in specifications that double the data rates for small form-factor pluggable (SFP) modules used in many datacenters. The SFP-DD Multisource Agreement (MSA) Group has set out to develop the electrical, optical and mechanical specifications to double today’s top data rate without increasing size.sfp module transceiver
Currently, SFP modules can handle data rates of 25 Gbps using non-return-to-zero (NRZ) modulation or 56 Gbps using four-level pulse-amplitude modulation (PAM4). Now that PAM4 is well into deployment, it’s no longer fast enough. To further increase speeds while we wait for the next technology (possibly PAM8), the double-density SFP modules will use two lanes instead of one. That will increase throughput to 50 Gbps and 112 Gbps, respectively. SFP-DD should double data rates without consuming more precious front-panel space on server blades, routers and switches. Figure 1 shows the cage on a PCB and how optical modules insert.
To accommodate the new row of contacts and retain backward compatibility, the SFP-DD plug and receptable will be longer than the current SFP configuration. That’s so the existing row of connections will make contact first, followed by the additional row. Existing SFP plug won’t make contact the the additional connector row.
In addition, PCB designs will need an additional set of traces to accommodate the second row. Connections inclue two for data plus power and control lines. The additional lines will surely design challenges when it comes to crosstalk, jitter and other issues that affect signal integrity.
The second connector row of contacts inside the case means that for designers of both the modules their boards will also have to deal with additional heat issues caused by two channels of optical and electrical component power dissipation where they used to be a single channel. Other form factors have addressed the solution to heat in the module is to by adding fins as shown on a microQSFP module at DesignCon 2017 (Figure 3).