Verizon 100G Quality Trial Proves Reliable Signal Performance Achievable

editor — Fri, 17 Apr 2009 12:34:11 +0000

Verizon’s 100G signal performance trial, held in late 2008, is another example of the company’s leadership in 100G technology. The trial proved that 100G performance is capable of better tolerance for signal distortion than today’s standard 10G optical transmission, an achievement that is a significant next step toward the commercialization of 100G transmission.Glenn Wellbrock , director of optical transport, network architecture and design for Verizon, discusses the importance of this trial and how each advance Verizon makes with this technology moves the company’s network closer to commercial deployment of reliable higher bandwidth speeds.

Tags: 100G, signal performance trial, optical transmission, Glenn Wellbrock, Verizon

Intel’s 45 Nanometer Process: 300 Transistors on a Red Blood Cell

Jason Lopez — Wed, 17 Jan 2007 23:59:54 +0000

You might think Moore’s Law comes with an ancillary set of steps on how to adhere to it. The Law essentially says that technology develops so swiftly that chip engineers can pack twice as many transistors on a piece of silicon every two years. Performance jumps dramatically but the business proposition is even more compelling: the price for that performance drops, which is why we can afford laptops today that have more computing power than big computers did in the 1970s. In this podcast we visit Intel’s Hillsboro, Oregon research facility and fab to talk with scientists who helped bring the newest 45 nanometer chip technology to reality.

Related Stories: IntelMooresLaw

Transcript:
Host: Jason Lopez – PodTech
Guest: Mario Paniccia – Intel
Guest: Mark Bohr – Intel
Guest: Kelin Kuhn – Intel

Jason Lopez – PodTech
I am Jason Lopez for PodTech.net. The race to make the smallest fastest chips is arguably one that has no end insight. Today’s chip companies can build transistor so small that more than 300 of them can fit on a red blood cell. The physical constraints are profound. Some of the connectors between components are made by gas and are just an atom thick. So, where to go from there? Well, here is an example, Intel uses light to test chips and it donned on engineers like Mario Paniccia, who heads the Photonic Technology Lab at Intel that lasers might be harnessed to do more than find defects.

Mario Paniccia - Intel
If we can send infrared lights through silicon to measure transistors, what if I could take silicon and send communication data through it and now do — everything we do today — modulating code to build optical components using silicon and the transmission properties of silicon. That evolution over the last couple of years has led to this program today, which we call Silicon Photonics.

Jason Lopez – PodTech
Although, laser-based chips are used away, scientists are still coming up with just-in-time innovations to build new processors that keep Moore’s Law on track, which essentially says that the number of transistors on a circuit doubles every two years as the cost to make that chip goes down.

Mark Bohr – Intel
Ten years ago many of us wondered whether we would ever get to this point.

Jason Lopez – PodTech
Mark Bohr is an Intel Senior Fellow, he spoke with me at the 45-nanometer lab at Intel’s Hillsboro, Oregon Campus.

Mark Bohr – Intel
Not only have we gotten to the point, but it probably didn’t take us quite as much time as we thought it would have.

Jason Lopez – PodTech
Now, when you say it didn’t take you quite as much time, ten years ago. How many years were you thinking?

Mark Bohr – Intel
Well, for the past ten years Intel has been developing a new generation of process technology every two years. Prior to that in the early 1990s, the pace was more of once every three years. So, we actually have picked up the pace over the past ten years. Again, we’ve gotten to this point this quickly is I think pretty impressive.

Kelin Kuhn – Intel
You don’t just walk down the street and start making transistors.

Jason Lopez – PodTech
Kelin Kuhn is the Device Manager for the Intel 45 nanometer chip in Hillsboro. She likens chips to Jumbo Jets. Just as no single person could design and construct a 400 seat plane, chip building requires massive resources and teams of people.

Kelin Kuhn – Intel
There is many years of technology innovation required; each technology builds on the previous technology. If you think about the technology today, if you compare our 45 nanometer technology to the previous technology, what you’re basically looking as a technology that takes about half the area, it’s about 20% faster and it’s about one-tenth the leakage of the previous technology. Now, keep moving that backwards, every technology generation before that built on the previous one and built on the previous one, you do that for many, many years and you can make very intrically small devices.

Jason Lopez – PodTech
The newest crop of chips from Intel is the result of some ingenuity. Mark Bohr says scientists are pushing the capabilities of traditional materials such as silicon wafers or polysilicon gate electrodes or thin oxide layers.

Mark Bohr – Intel
We’ve been scaling those dimensions, making them much smaller every couple of years, but lately we’ve been adding new materials to really enhance those transistors to get them to follow Moore’s Law. The average consumer really amazed at the amount of technology, high technology that’s in their computer at home, on their desk and their laptop. They could take a part of that chip, look inside they’d be surprised at just how much sophistication, new materials, ultra small dimensions are in that chip. The average chip may have 200 or 300 million transistors on it.

Jason Lopez – PodTech
For PodTech.net, I’m Jason Lopez at Intel’s 45-nanometer Lab in Hillsboro, Oregon.

Tags: Moore’s Law, Intel, 45 nanometer, chip technology, IntelMooresLaw

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Verizon 100G Quality Trial Proves Reliable Signal Performance Achievable

Intel’s 45 Nanometer Process: 300 Transistors on a Red Blood Cell