opinion
Charles Beeler, El Dorado Ventures and Craig Partridge, BBN
We’re a venture capitalist and a communications researcher, and we come bearing bad news: optical computers and all-optical networks aren’t going to happen anytime soon. All those well-intentioned stories about computers operating at the speed of light, computers that would free us from Internet delays and relieve us from the tyranny of slow and hot electronic devices were, alas, overoptimistic. We won’t be computing or routing at the speed of light anytime soon. (In truth, we probably should have told you this about two years ago, but we only recently met, compared notes, and realized our experiences were consistent.)
You see, building an optical computer or router entails a critical step called optical regeneration, which nobody knows how to do. After at least two decades of research and well over a billion dollars of venture-capital spending on promising potential breakthroughs, it is pretty clear that we’ve tried all the obvious ways and a fair number of the nonobvious ways to do optical regeneration. It appears that solving the problem is not a matter of top-class engineering; rather, it’s beginning to look like Nobel-Prize-winning physics, such as high-temperature superconductivity where ingenuity leads to a completely new approach. Those kinds of results are rare and unpredictable, and thus all signs suggest optical computing is an innovation that will likely have to wait a generation or two or three to come to fruition.
The past two decades have seen a profusion of optical logic that can serve as memories, comparators, or other similar bits of logic that we would need to build an optical computer. Much like traditional silicon logic, this optical logic suffers from signal loss—that is, in the process of doing the operation or computation, some number of decibels is lost. In optics, the loss is substantial—an optical signal can traverse only a few circuits before it must be amplified.
We know how to optically amplify a signal. Indeed, optical amplification is one of the great innovations of
the past 20 years and has tremendously increased the distances over which we can send an optical signal.
Unfortunately, amplifying a signal adds noise. After a few amplifications, we need to regenerate the signal: we need a device that receives a noisy signal and emits a crisp clean signal. Currently the only way to build regenerators is to build an OEO ( optical-electronic-opti-cal) device: the inbound signal is translated from the optical domain into a digitized sample; the electronic component removes the noise from the digitized sample and then uses the cleaned-up digitized sample to drive a laser that emits a clean signal in the optical domain. OEO regenerators work just fine, but they slow us down by forcing us to work at the speed of electronics.
There has been no shortage of attempts to create all-optical regenerators. Many approaches have shown some promise in the laboratory, but ultimately, to date, all have failed the transition from promise to product. As we observed in the introduction, all the likely—and many unlikely—approaches have been tried.
So, if we are going to assemble the wonderful optical circuits into an optical computer, right now and for the foreseeable future, for every handful of circuits we will need a regenerator, and the only regenerators we have require slow electronics. Oops!
Compounding the frustration is that the photonic logic community has recently achieved breakthroughs in PICs (photonic integrated circuits). Until recently, each optical circuit was its own chip (much as we relied on individual transistors in electronic devices in the 1960s), but now we can lay out densely packed optical chips. We can envision replacing electronic chips with optical chips—but the optical chips won’t run any faster because every few circuits, inside the chips, we’ll have to do electrical regeneration.
Similar problems crop up in building all-optical networks. There have to be some optical switches in that network to direct the data. The optical logic in those optical switches has the same problems as optical computers: every few circuits you need OEO regeneration.
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