A Look at Photonic Clocking 130
zymano writes "In an article on the Electronic Engineering Times site James Siepmann shares a few thoughts about Photonic Clocking. Siepmann states: 'Copper interconnects are reaching their limit as data-transmission bandwidth and processor speed continue to rise. [..] Photonic clocking not only solves the limitations of electronic clocking, but also reduces jitter, skew, delay, crosstalk and power consumption while maintaining clock signal integrity for longer distances.'" Are Photonic Processors the next logical step, or will the almighty buck shuffle them aside because of cost?
Slashdot economics... (Score:5, Funny)
Yeah, 'cause technology never gets cheaper. Hey, I've got an AT&T 8086 PC with a lovely green monitor that you can have for $5000, if you act now...
Ooooo! (Score:4, Funny)
Hang on to it. In a few years, you can haul it down to Antiques Roadshow and have 'em tell you it's "worth between $2000 and $4000, but for insurance purposes..."
OT: Re:Ooooo! (Score:2)
I hate to comment on this but feel compelled due to boredom. WTF is with these antique shows?
I suspect that they edit the parts where the "evaluator" says, "this is just shit from your grandma's basement". And yet people apparently gobble this stuff up like wannabe lottery winners.
Knowing current TV production tactics, it wouldn't surprise me that multiple takes are done to get the "perfect" reaction shot.
FYI, the "reaction shot" is the 21st century's version of the laugh track.
Re:Slashdot economics... (Score:1)
Re:Slashdot economics... (Score:2)
Economics? What's that? (Score:1, Insightful)
You tell us. Ultimately it's your present purchases that will fund it.
--
The "are you a script" word for today is rubbers.
Did we skip microwaves? Millimeterwaves? (Score:2, Interesting)
just fine for at least 3 or 4 of those. So how is it that we are "reaching the limitations" of copper?
It's all just waveguides (Score:5, Informative)
The problem might be that usually wave guides have to be the size of the wavelength to work right. ghz wavelength are larger than the chip. Thus you get forced towards the optical region by this considerarion.
But you can beat this two ways.
1) use negative index of refraction materials. Then the waveguide can be smaller than the wave length
2) use near field waveguides with amplification. When the wavelength is a lot larger than the waveguide then the wave becomes evanscent (decaying). So it can't propagate very far. But hey, that's okay because the chip is not very wide either, so we can tolerate some loss of signal. And we could toss in some amplification to offset it.
Photonic Clock (Score:4, Funny)
Re:It's all just waveguides (Score:4, Informative)
Err, actual wave speed never was a problem. Electromagnetic force already propagates at the speed of light in an electric conductor.
It's the modulation speed (e.g. how fast you can vary the signal inside the channel) that is much higher in photonic devices. In conductors, losses are very high for rapidly varying signals, and as you said it, microwave guides are much too large for chips. Evanescent fields are also a problem since they can spread very far from small guides.
This is even true when you light: for example, a standard coupler ("Y") for visible or IR wavelengths must normally be several centimeters long. However, so-called photonic-bandgap devices are solving this problem.
I disagree (Score:2)
Re:I disagree (Score:3, Informative)
I still disagree (Score:2)
Re:It's all just waveguides (Score:2)
No, it doesn't. I'll assume when you say "speed of light" you intend the common shorthand for "speed of light in a vacuum". A signal in an electrical conductor propagates at a substantial fraction of "the speed of light", somewhere in the 40%-60% range IIRC. And even light itself travels more slowly than "the speed of light" through any medium other than a vacuum, I think abou
Re:It's all just waveguides (Score:2)
For the record, the whole point of my post was that the speed of light (be it in the vacuum or in a dielectric medium, or the propagation speed inside a waveguide) never was the limiting f
Re:It's all just waveguides (Score:2)
It may cause delay problems on large distances (which isn't related), but I doubt that chipmakers are bitching about the slowness of c (then again I'll admit I know nothing about chip design).
So, what do we have so far:
Potentially a good idea, but only that. (Score:4, Interesting)
Not to mention... (Score:4, Insightful)
Reminder: this comment is on topic.
Re:Not to mention... (Score:3, Insightful)
Re:Not to mention... (Score:2)
Uh, (Score:5, Informative)
Re:Uh, (Score:1, Informative)
Re:Uh, Yes They Do (Score:4, Informative)
Ethernet does rely on synchronised clocks. You might be misstating that Ethernet doesn't have a clock line, meaning there is no dedicated wire with a clock signal on it.
There is a high-precision clock on every Ethernet card. An Ethernet frame has a 64-bit preamble with Manchester encoding. That preamble adjusts the skew of the receiver clock so that it's synchronised with the transmitter clock. If the synchronisation didn't occur, you wouldn't know when to latch the data on the line and you couldn't receive a frame. The synchronisation occurs on every Ethernet frame and the precision of the clock must be high enough that the synchronisation lasts for the length of a frame.
Async architectures will likely use a similar technique. The subsystems won't be driven by a system-wide clock line, as in the existing synchronous architectures, but the various clocks in subsystems will certainly be synchronised.
Re:Uh, Yes They Do (Score:1)
Re:Uh, Yes They Do (Score:2)
Hint: Relativity has nothing to do with why faster ethernet cards might use a faster clock. Think "Frequency" instead.
--S
Re:Uh, (Score:1, Interesting)
Asynchronous Circuit Design (Score:2, Interesting)
The real questions are:
- why these tecniques never gained importance (the first studies are from S.Unger in 1969)?
- what about the EDA industry?
Re:Asynchronous Circuit Design (Score:2)
- why these tecniques never gained importance (the first studies are from S.Unger in 1969)?
Probably because at all points through history the chip companies had other, cheaper techniques to get their next generation of chips out of the door, without getting down in costly research that had to make them redesign everything...
- what about the EDA industry?
Probably because they reasoned their customers went with the previous answer...
Re:Asynchronous Circuit Design (Score:1)
At current level of understanding, this
Re:Not to mention... (Score:1, Interesting)
With standard clocked CPUs, you can draw a box around the chip, or part of it, and treat it like a black box. Signal in, signal out, clock: change any and all of these to guarantee/profile your behavior. That doesn't work on async design. There's no way you could test it all and have any confidence that you did it right.
Re:Not to mention... (Score:2)
Re:Not to mention... (Score:1)
Re:Potentially a good idea, but only that. (Score:1)
Whereas an electrical pulse on a copper wire travels at
Wait. What's the advantage of photonics?
Re:Potentially a good idea, but only that. (Score:2, Informative)
to name a few...
Re:Potentially a good idea, but only that. (Score:3, Insightful)
Indeed. You've hit the nail on the head. Of course, the majority of jokesters around here will probably continue to ridicule the concept in other threads, mostly because they don't know what they're talking about. The difference between current processor technology and photonic processors is the same as the difference between copper wire network connections and fiberoptic connections.
Fiberoptics are superior to purely
Re:Potentially a good idea, but only that. (Score:2)
Re:Potentially a good idea, but only that. (Score:1)
da Vinci designed a flying machine in 1500, some 400 years before the Wright brothers took off.
What? (Score:5, Insightful)
If photonic processors go into widespread usage, it will probably be because of the almighty buck and companies deciding that they can make more of it by producing photonic processors.
Profits and competition are the main reason for a lot of the recent advances in processor performance. Look at the processor introductions back when 486 and pentium processors were around and Intel didn't have any credible competition.
No credible competition? (Score:3, Informative)
Back in the day, "real" computer manufacturers scoffed at Intel. IBM would only let them produce the chips for the PC after Intel found another manufacturer willing to produce the part in case Intel tanked. The PC was nothing to boast about compared to the mainframes of the day.
Slowly but surely, Intel grew to become the monster they are today. The turning point was somewhere near the Pentium II, when Intel machines were beginning to be used as engineering workstations. Profits tru
Re:No credible competition? (Score:2)
Re:What? (Score:2)
Wow. Only on Slashdot would THIS be considered insightful.
There were *MORE* options for chips back then, not less. MIPS. Alpha. Power. 680x0. AMD 486. Cx 486.
No innovation here... (!)
Intel has pretty much always "pushed it". Their projected timelines for Mhz improvement has be
Re:What? (Score:2)
In the consumer market you had a choice between Intel and it's clones (Cyrix, IDT, AMD). By the time the Pentium and PII processors were around only Intel offered reasonable performance. Alpha, power, mips weren't an option for consumer systems. The 680x0 systems were only used for apple systems.
The situation now is about the same, for consumer pcs you have a choice between power and intel/amd. The d
Re:What? (Score:2)
There is no reason for much faster processing outside of specialty applications. The only possible use (for the average computer owner) is digitizing video more fastly.
Then again, marketing can be an amazing thing and convince people that they NEED something that they really don't. This type of hype will be going down the tubes as more and more people discover that what's being tossed at them is just more blinky lights and fancy buzzwords.
huh? slow news day? then I troll for fun and pro.. (Score:3, Insightful)
This makes it sound like "the almighty buck" is the bad guy. I think this is one of those times when that's not the case. If fully photonic processors turn out to work best, then that's what we'll see. If they're not, and if the article claim that copper interconnects are reaching their limit is true, then we'll seem some hybrids. Rock on.
This whole article seems like an attempt to pad out a slow news day. Maybe we can turn this article into something useful, or at least more entertaining. We could start a flamewar! Yeah!
----------
<enganging fake troll mode>It's gotta be Photonic chips all the way man!!! Copper procs, yer all gonna burn in silicon hell!! yeah, burn baby burn! I unleash light-based clocking on all you 1nf1d3l5!!
(etc)
Re:huh? slow news day? then I troll for fun and pr (Score:3, Funny)
No, this isn't just a copper out, I'm serious. You photonic people seem to think that we're living in a dark age. If photonic processors were at all realistic, we all would have seen the light long ago.
Anyway, take your Star Wars chip and put it in a country where people have never seen George Lucas's masterpiece, Episode 1.
Re:huh? slow news day? then I troll for fun and pr (Score:1)
Re:huh? slow news day? then I troll for fun and pr (Score:1)
But we all know newer is always better, and we never, ever have problems with emerging technologies [wikipedia.org]. Light is faster than electricity. Photon-folks are faster (therefore better) than copper commies!
And let's not forget, movies are fundamentally made up of just two things, and one of those is light.
(may as well turn it into a proper holy war)
When the glorious Flying Spaghetti Monster [wikipedia.org] created all things out of a plate of linguini, I'm sure one of His first creations was light probably.
Re:huh? slow news day? then I troll for fun and pr (Score:3, Funny)
Judging by what's coming out of Hollywood lately, the other thing must be shit.
--S
Re:huh? slow news day? then I troll for fun and pr (Score:1)
Anyway, who cares about Hollywood? It's not like it's the only source for movies in the whole world.
Re:huh? slow news day? then I troll for fun and pr (Score:2)
True. There's always Kazaa, Napster, Bittorrent...
(I suppose I should run away now)
--S
I bow down to our Almighty Buck overlords (Score:1, Funny)
Re:I bow down to our Almighty Buck overlords (Score:4, Funny)
"I for one welcome our Almighty Buck overlords... personally. Just keep sending them my way."
Article light on details (Score:5, Informative)
So, I'll quickly fill in what I know. To do clock distribution you need two types of components: waveguides and detectors. Let's assume you are going to work in silicon...
Waveguides function as the optical wiring, and includes things like bends and splitters. Although perhaps not trivial, it is relative straight-forward to make waveguides in or on silicon. Detectors, on the other hand, are not so easy, at least at the wavelength most people are interested in, 1550 nm. There's a number of people researching Ge growth for detectors on Si, and this does have promise, but it's not ready yet. Another option would be bonding InGaAs, but that might always be too expensive.
Now, if you want to do full up optical communication, on chip, you'll want modulators, too. These have been demonstrated by Intel and Cornell in silicon, but only at speeds around 1 Ghz. Optical amplifiers would be nice, too, and this has been demonstrated (using Raman amplification) by Intel and UCLA. (I'm not sure Raman amplification can give you the sorts of amplification and efficiency you really need, though).
(Sorry, I won't be able to respond to any replies; at least not until Monday. I'm off to bed and I'm not planning to be near a computer tomorrow).
Re:Article light on details (Score:3, Informative)
Too true. However, this page [photonics.com] says LightTime LLC, whose Chief Research Officer wrote the article being discussed, is working with mode-locked lasers centered at 860 nanometers. That's a piece of cake for silicon to detect (although making those lasers cheap, reliable, and phase-lockable will be a nice trick.)
Re:Article light on details (Score:1)
I did some research on this about 10 years ago which has come a long way since. Here's [ucl.ac.uk] the first paper in bulk optics. We created both homodyne and heterodyne phase lock loops with two semiconductor lasers. In the heterodyne case we could lock with up to 24 GHz frequency offset.
A lot of the original work for this was done at UCL, check out [ucl.ac.uk] their list of papers looking for 'phase-lock loop'. I believe they have al
Re:Article light on details (Score:1)
Why not the whole chip... (Score:3, Insightful)
Re:Why not the whole chip... (Score:2)
Seriously, while it is possible to do optical switching, methods either are inefficient or need hugely powerful light sources. There is some research to alleviate the problem _in Si_, but it's still only research, years away from practical use. As it is, I think that using optics only for interconnects is an already doable way of improving performance, and not just within the chip. Content associative memories (which can be built with SLMs, passive optics and cameras) can greatly help tasks li
New Laptop (Score:1)
Photonic logic could work.....but (Score:4, Insightful)
The evolved state of computing uses Boolean logic to mosh states together into integer algebraic, then other kinds of math transformations.
Now, consider what light does, and how it flows. Light (actually this segment of the electromagnetic spectra) has different frequencies, at about the same data rate depending on media. No information there, except frequency differences and blendings of frequencies... lambda moshing.
You can modulate light, like any other electromagnetic phenomena. You can modulate information, therefore, onto light. It's done all the time. By adding information, you can blend things together, then demodulate them to see what happened as the change in information. This modulation mimics how ALUs/accumulators/CPUs work with logic states in some ways, but now we have to multiply the effect to get to significant digits and significant logic handling-- math by light modulation and the devices that can do that. But not densely, so far, in the calculative/logic-state change tracking sense.
What of these devices-- aye, thar's the rub. Is there an advantage to using light to do math? Not yet, really. It doesn't meet the state change efficiency model. One day, it might. Today, we lack the ability to make things dense enough. That's why photonic logic may fall short of expectations.
light based processors could do decimal math? (Score:2)
Re:light based processors could do decimal math? (Score:2)
2) Your other points are wrong, wrong, and incredibly silly, in order. Working with decimal would be an order of magnitude harder than binary, not easier. It's been tried, a long time ago
Re:light based processors could do decimal math? (Score:1)
Re:light based processors could do decimal math? (Score:1)
Re:light based processors could do decimal math? (Score:2)
No, it wouldn't be more efficient, either. The most efficient base for numerical representation is e. You know, good ol' 2.718281828...
The farther you get from this number, the less efficient your number system is. Since it's kind of hard to represent numbers in base e with anything other than an analog circuit, this means that base 3 is the best you can do. Not base 2, and certainly n
Re:light based processors could do decimal math? (Score:2)
mod parent down (Score:1)
"Consider the semiconductor."
Ok, here is the parent posts first fundamental misconception. Digital doesn't necessarily mean semiconductor. Say, for example CDs which encode digital data using light.
"By adding information, you can blend things together, then demodulate them to see what happened as the change in information."
that isn't how light works, the waves superpose
Re:mod parent down (Score:2)
Re:mod parent down (Score:3, Informative)
Oh? Read on.
>"Consider the semiconductor."
>>Ok, here is the parent posts first fundamental misconception. Digital doesn't necessarily mean semiconductor. Say, for example CDs which encode digital data using light.
No, you misconstrue it. Transistor logic is what's used to do state changes that amount to the various relationships that form what a CPU does
Obligatory Star Trek dialogue... (Score:3, Funny)
Data: RocketIO is rated at 9.8 Gbps and PCI-X6 is rated at even slower rate of 8 Gbps aggregated.
LaForge: Yeah, right. Nothing compare to our photonic bus of 980 THz over each of the 2^1024 channels.
Scotty: Ayie! Why don't they get with the program, laddies? I kin nev'r understind them, bloody buses.
Re:Obligatory Star Trek dialogue... (Score:2)
LaForge: Let's try reversing the polarity.
Re:Obligatory Star Trek dialogue... (Score:2)
The Almighty Buck? (Score:3, Funny)
The "almighty buck" won't shuffle it aside...people will. If the processor is not cost-effective then it won't catch on. However, the processor may become the SUV of chips. It may not be the most cost-effective solution but a purchaser may feel it helps him compensate for his undersized penis.
You know, when I started writing this post that's honestly not where I was going. I was going to make some point about how marketing may overcome the possible lack of value of the chip (a la VHS vs Beta) but then the post just headed south...
More realistic than you think. (Score:3, Insightful)
Re:More realistic than you think. (Score:2)
oscilating nanomagnets... (Score:1, Informative)
http://physicsweb.org/articles/news/9/9/9/1 [physicsweb.org]
the headline (talking chips) (Score:1, Informative)
Design (Score:3, Insightful)
Photons can achieve frequencies in vast excess of current processor speeds. The function of a photonic logic gate would be measured by simple amplitude modulation. A photon has a frequency and an amplitude. Using a photon with the energy of a gamma ray would be _FAST_, have negligable heat loss due to the friction which plagues electronic processors, and the amplitude of the photon could be easily modulated by passing through different materials. Different materials of different refractive indeces and transparencies (see fiberoptics) would be the photonic equivalent of electronic resistors and capacitors.
I can only wait for the development of photonic processors.
Optical Computing: Myeh (Score:2)
A photon has a wavefunction, that's it. Assuming the photon has a relatively sharp energy, you can then say it has a frequency (energy) and a phase. Amplitude is meaningless when speaking about a single photon.
I can only wait for the development of photonic processors.
You'll be waiting a long time, I think. People have been trying this foolhardy idea of optical computing for a long time, and the field is pretty much dead. The problem is that to get light to modu
Re:Optical Computing: Myeh (Score:2)
All particles have wavefunctions, even electrons. It's the derivation of the math for the particle-in-a-box which yields that wavefunction. I suppose you'll probably continue to argue until I pull "Quantum Chemistry and Molecular Spectroscopy" off the shelf and start quoting lines and lines from the derivation.
This is about photonic computing, not quantum computing. Just as in fiberoptics we're not t
Re:Optical Computing: Myeh (Score:2)
Re:Optical Computing: Myeh (Score:2)
The field isn't so much dead. What is "dead in the water" (at least for now, and as long as there is no further breaktrough) is the idea of building processors using photons the sale way as the current processors are using electrons.
However, optical processing has other applications that could be put into good use. Computing Fourier transforms like
Re:Optical Computing: Myeh (Score:2)
gamma rays... (Score:1)
At first... (Score:3, Funny)
Note to self: Don't read Slashdot too late at night..
It will be available when people can buy it. (Score:2, Insightful)
Re:It will be available when people can buy it. (Score:2)
Until new architectures cease to offer even slightly significant increases to performance and response time, I will continue to buy new systems with more power every couple years.
What are you talking about!?!? (Score:2, Funny)
AMD will also sue Intel now, in fear that the last part comes true.
Screw Photonic Clocking (Score:3, Funny)
Quantum First (Score:3, Interesting)
100GHz clock signal??? (Score:1)
Hope they've figured out how to make things really really small also.
Re:100GHz clock signal??? (Score:1)
Re:Anyone else... (Score:3, Funny)
Re:Anyone else... (Score:1)
Re:Anyone else... (Score:2)
Re:All this Technical Mumbo-Jumbo (Score:3, Funny)
Re:All this Technical Mumbo-Jumbo (Score:1)
Re:All this Technical Mumbo-Jumbo (Score:1)
This is why you should never use real units in technobabble.
Re:All this Technical Mumbo-Jumbo (Score:3, Interesting)
* Neutronium may not even be physically possible, and certainly would be instantly highly explosive in Earth-conditions. It certainly wouldn't "alloy", and has nothing to do with the theoretical Dirac Sea.
* Zero-point energy is not related to processors
* You can "channel" photons, but not a "photonic current", which is at best a term to de
Re:All this Technical Mumbo-Jumbo (Score:2)