Turning to optical I/O to open up computing pinch points 
Wednesday, August 18, 2021 at 11:14AM
Roy Rubenstein in AI, Ayar Labs, CW-WDM MSA, DARPA PIPES, GlobalFoundries, Hugo Saleh, Intel, MACOM, OFC 2021, TeraPHY, high-performance computing, optical I/O, silicon photonics

Getting data in and out of chips used for modern computing has become a key challenge for designers.

Hugo Saleh

A chip may talk to a neighbouring device in the same platform or to a chip across the data centre.

The sheer quantity of data and the reaches involved - tens or hundreds of meters - is why the industry is turning to optical for a chip’s input-output (I/O).

It is this technology transition that excites Ayar Labs.

The US start-up showcased its latest TeraPHY optical I/O chiplet operating at 1 terabit-per-second (Tbps) during the OFC virtual conference and exhibition held in June.

 

Evolutionary and revolutionary change

Ayar Labs says two developments are driving optical I/O.

One is the exponential growth in the capacity of Ethernet switch chips used in the data centre. The emergence of 25.6-terabit and soon 51.2-terabit Ethernet switches continue to drive technologies and standards.

This, says Hugo Saleh, vice president of business development and marketing, and recently appointed as the managing director of Ayar Labs’ new UK subsidiary, is an example of evolutionary change.

But artificial intelligence (AI) and high-performance computing have networking needs independent of the Ethernet specification.

“Ethernet is here to stay,” says Saleh. “But we think there is a new class of communications that is required to drive these advanced applications that need low latency and low power.”

 

Manufacturing processes

Ayar Labs’ TeraPHY chiplet is manufactured using GlobalFoundries’ 45nm RF Silicon on Insulator (45RFSOI) process. But Ayar Labs is also developing TeraPHY silicon using GlobalFoundries’ emerging 45nm CMOS-silicon photonics CLO process (45CLO).

The 45RFSOI process is being used because Ayar Labs is already supplying TeraPHY devices to customers. “They have been going out quite some time,” says Saleh.

But the start-up’s volume production of its chiplets will use GlobalFoundries’ 45CLO silicon photonics process. Version 1.0 of the process design kit (PDK) is expected in early 2022, leading to qualified TeraPHY parts based on the process.

One notable difference between the two processes is that 45RFSOI uses a vertical grating coupler to connect the fibre to the chiplet which requires active alignment. The 45CLO process uses a v-groove structure such that passive alignment can be used, simplifying and speeding up the fibre attachment.

“With high-volume manufacturing - millions and even tens of millions of parts - things like time-in-factory make a big difference,” says Saleh. Every second spent adds cost such that the faster the processes, the more cost-effective and scalable the manufacturing becomes.

 

Terabit TeraPHY

The TeraPHY chiplet demonstrated during OFC uses eight optical transceivers. Each transceiver comprises eight wavelength-division multiplexed (WDM) channels, each supporting 16 gigabit-per-second (Gbps) of data. The result is a total optical I/O bandwidth of 1.024Tbps operating in each direction (duplex link).

“The demonstration is at 16Gbps and we are going to be driving up to 25Gbps and 32Gbps next,” says Saleh.

The chiplet’s electrical I/O is slower and wider: 16 interfaces, each with 80, 2Gbps channels implementing Intel’s Advanced Interface Bus (AIB) technology.

Last December, Ayar Labs showcased advanced parts using the CLO process. The design was a direct-drive part - a prototype of a future-generation product, not the one demonstrated for OFC.

“The direct-drive part has a serial analogue interface that could come from the host ASIC directly into the ring resonators and modulate them whereas the part we have today is the productised version of an AIB interface with all the macros and all the bandwidth enabled,” says Saleh.

Ayar Labs also demonstrated its 8-laser light source, dubbed SuperNova, that drives the chiplet’s optics.

The eight distributed feedback (DFB) lasers are mixed using a planar lightwave circuit to produce eight channels, each comprising eight frequencies of light.

Saleh compares the SuperNova to a centralised power supply in a server that power pools of CPUs and memory. “The SuperNova mimics that,” he says. “One SuperNova or a 1 rack-unit box of 16 SuperNovas distributing continuous-wave light just like distributed voltage [in a server].”

The current 64-channel SuperNova powers a single TeraPHY but future versions will be able to supply light to two or more.

Ayar Labs is using Macom as its volume supplier of DFB lasers.

 

Significance

Ayar Labs believes the 1-terabit chip-to-chip WDM link is an industry first.

The demo also highlights how the company is getting closer to a design that can be run in the field. The silicon was made less than a month before the demonstration and was assembled quickly. “It was not behind glass and was operating at room temperature,” says Saleh. “It’s not a lab setting but a production setting.”

The same applies to the SuperNova. The light source is compliant with the Continuous-Wave Wavelength Division Multiplexing (CW-WDM) Multi-Source Agreement (MSA) Group that released its first specification revision to coincide with OFC. The CW-WDM MSA Group has developed a specification for 8, 16, and 32-wavelength optical sources.

The CW-WDM MSA promoter and observer members include all the key laser makers as well as the leading ASIC vendors. “We hope to establish an ecosystem on the laser side but also on the optics,” says Saleh.

“Fundamentally, there is a change at the physical (PHY) level that is required to open up these bottlenecks,” says Saleh. “The CW-WDM MSA is key to doing that; without the MSA you will not get that standardisation.”

Saleh also points to the TeraPHY’s optical I/O’s low power consumption which for each link equates to 5pJ/bit. This is about a tenth of the power consumed by electrical I/O especially when retimers are used. Equally, the reach is up to 2km not tens of centimetres associated with electrical links.

 

Chiplet demand

At OFC, Arista Networks outlined how pluggable optics will be able to address 102.4 terabit Ethernet switches while Microsoft said it expects to deploy co-packaged optics by the second half of 2024.

Nvidia also discussed how it clusters its graphics processing units (GPUs) that are used for AI applications. However, when a GPU from one cluster needs to talk to a GPU in another cluster, a performance hit occurs.

Nvidia is looking for the optical industry to develop interfaces that will enable its GPU systems to scale while appearing as one tightly coupled cluster. This will require low latency links. Instead of microseconds and milliseconds depending on the number of hops, optical I/O reduces the latency to tens of nanoseconds.

“We spec our chiplet as sub-5ns plus the time of flight which is about 5ns per meter,” says Saleh. Accordingly, the transit time between two GPUs 1m apart is 15ns.

Ayar Labs says that after many conversations with switch vendors and cloud players, the consensus is that Ethernet switches will have to adopt co-packaged optics. There will be different introductory points for the technology but the industry direction is clear.

“You are going to see co-packaged optics for Ethernet by 2024 but you should see the first AI fabric system with co-packaged I/O in 2022,” says Saleh.

Intel published a paper at OFC involving its Stratix 10 FPGA using five Ayar Labs’ chiplets, each one operating at 1.6 terabits (each optical channel operating at 25Gbps, not 16Gbps). The resulting FPGA has an optical I/O capacity of 8Tbps, the design part of the US DARPA PIPES (Photonics in the Package for Extreme Scalability) project.

“A key point of the paper is that Intel is yielding functional units,” says Saleh. The paper also highlighted the packaging and assembly achievements and the custom cooling used.

Intel Capital is a strategic investor in Ayar Labs, as is GlobalFoundries, Lockheed Martin Ventures, and Applied Materials.

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