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Wednesday, 4 August 2010

Computing at the Speed of Light

Replacing metal wiring with fiber optics could change everything from supercomputers to laptops.
By Tom Simonite



The world of computing could change rapidly in coming years thanks to technology that replaces the metal wiring between components with faster, more efficient fiber-optic links.

Seeing the light: A chip in the center of this circuit board contains four lasers that convert electrical signals into light pulses. The pulses travel at high speeds along a fiber-optic link.
Credit: Intel 
  

"All communications over long distance are driven by lasers, but you've never had it inside devices," says Mario Paniccia, director of Intel's photonics lab in Santa Clara, CA. "Our new integrated optical link makes that possible."

Paniccia's team has perfected tiny silicon chips capable of encoding and decoding laser signals sent via fiber optics. Today, when data arrives at a computer via a fiber optic connection it has to be moved from a separate photonic device to an electronic circuit. This new system promises to speed things up because everything works in silicon.

Last week, Paniccia's team demonstrated the first complete photonic communications system made from components fully integrated into silicon chips. Electronic data piped into one chip is converted into laser light that travels down an optical fiber and is transferred back into electrical signals a few fractions of a second later. The system can carry data at a rate of 50 gigabytes per second, enough to transfer a full-length HD movie in less than a second.

The silicon photonic chips could replace the electronic connections between a computer's key components, such as its processors and memory. Copper wiring used today can carry data signals at little more than 10 gigabytes per second. That means critical components like the central processing unit and the memory in a server cannot be too far apart, which restricts how computers can be built.

The new Intel setup has four lasers built into its transmitter chip that shine data into a single optical fiber at slightly different wavelengths, or "colors." Chips with even more lasers should make it possible to communicate at 1,000 gigabytes per second, or one terabit per second.

"Having a chip the size of your fingernail that can deliver a terabit per second changes the way you can think about design," says Paniccia. Such chips could make a big difference inside the sprawling data centers operated at great expense by Web giants like Google, Microsoft, and Facebook. "Data centers today are big piles of copper--that imposes the limits on how you arrange components inside a server," Paniccia says.

 "If I could just move the memory a foot away [from the processors], I could add a whole board of memory for a single CPU instead," says Paniccia, whose team is experimenting with prototype servers to work out how to build them with photonics links inside.

Moving a server's memory away from the CPUs would also make ventilating them easier. Since roughly half the cost of running a data center, used for everything from services like Facebook to banking records, comes from cooling, that could have a significant impact.

Further savings may come from the fact that optical links require less power to operate, says Keren Bergman, who leads a silicon photonics research group at Columbia University. "With electrical wires, the longer you go, the more energy you spend in an exponential fashion," she says. Optical fiber allows low-power signals to travel farther faster. Bergman's group has used data on the performance of computers at Lawrence Berkeley and MIT's Lincoln Laboratories to simulate how systems with optical interconnects might perform. "You can get an order of magnitude gain in energy efficiency," she says, with the largest gains seen for applications such as high-bandwidth image processing and video streaming, she says.

Data centers aren't the only things that may see their insides lit up with lasers. "We've developed this technology to be low-cost so we can take it everywhere, not just into high-performance computing or the data center," says Paniccia. The components of the Intel system, including the lasers, are made with the same silicon-sculpting methods used to construct computer chips in vast quantities. "I'm drafting Moore's law," says Paniccia. "We've enabled the benefits of using light with the low-cost, high-volume, scalability of silicon."In consumer computers like laptops, that would allow innovations in industrial design. I could put the memory in the display instead, and change the design of the whole thing."

This could make it easier to swap in new components without having to open up a machine. It would also allow core components to be installed in peripherals. Extra memory could, for example, be hidden in a laptop or smart phone dock to increase a portable device's computing power when plugged in.

Fully exploiting the benefits of the optical age will, however, means changes to the components being linked up. "It's not just a case of whip out the electrical wires and replace them with optical fiber," says Bergman.
Ajay Joshi, an assistant professor at Boston University, who is also exploring design options for high-performance computers with optical interconnects, agrees. "If we speed up the channel between logic [processors] and memory, we need to rethink the way you design that memory."

The speed gap between processors and optical links is smaller, but ultimately, that too will likely change. "It would be nice to also see processors that work optically instead of electronically," Joshi says.

Tuesday, 3 August 2010

Latest Launch Brings China Closer to ‘GPS’ of Its Own

Latest Launch Brings China Closer to ‘GPS’ of Its Own


At 5:30 on Sunday morning, the Chinese government fired a Long March 3A rocket into orbit. It carried a navigation satellite — the fifth in a planned constellation of 30 or more Beidou orbiters that Beijing hopes will soon rival America’s Global Positioning System.

For years, the U.S. Air Force has owned and operated the system that the rest of the world uses to find its way home, synch its financial transactions (thanks to the GPS timing service), and bring its ships to port. That’s given America a huge military advantage; GPS enables America’s bombs to be targeted with incredible precision. It’s also made other countries nervous: What if the Pentagon decided to mess with the GPS signal in the middle of a war?

Enter Beidou (“Compass”), China’s GPS alternative. “A global positioning system is crucial to any country’s national security and defense,” the Chinese official in charge of the program tells People’s Daily Online. “It is unimaginable for China to go without such a system.”

Sunday’s satellite makes the fifth orbiter in the Beidou constellation, and the third launched this year. Another eight to 10 are supposed to be into space by 2012, providing regional coverage. By 2020, Beidou is supposed to ring the globe.

Which means China can get its own satellite-guided weapons — ones that hit within feet of their target, and stay on track in any weather.


“GPS has become so embedded in much of the world’s day-to-day commerce and activities, it is very unlikely that the U.S. would ever turn off the precision signal. However, given the immense military benefits from such a system, there is a strong motivation for China to develop its own system, under its own control,” says Brian Weeden, a former Air Force Space and Missile officer and a Technical Advisor to the Secure World Foundation.

Beidou is one of three potential GPS competitors currently under construction. The European Union’s Galileo project, which was supposed to have been up and running by 2008, has only managed to put in orbit a couple of test satellites.

Russia had its 24-satellite GLONASS navigation constellation up and running by 1995. Six years later, only six of the satellites were still working, and system was disabled, RBC Daily notes. But Russia has launched a rebuilding effort — one that is just about finished. 21 satellites are now operational, according to the Moscow government. On Friday, Russia that three more will be sent into orbit by September.

In 2008, Moscow opened up GLONASS access to civilians. Russian boss-for-life Vladmir Putin celebrated by giving his black labrador a GLONASS-enabled collar, so he could track the dog’s movements.

“She looks sad,” Deputy Prime Minister Sergei Ivanov said. “Her free life is over.”
“She is wagging her tail,” Putin answered. “That means she likes it.”

If China starts to depend on its home-grown navigation system, it may actually undermine a key tenet of Beijing’s military planning: to threaten America’s reliance on the fragile GPS constellation. (Remember how China blew up a satellite in 2007?) “As China becomes increasingly reliant and invested in space,” Weeden observes, “it becomes vulnerable to the same sort of asymmetric anti-satellite weapon it used to shock the United States.”

By Noah ShachtmanNewscribe : get free news in real time 

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10 ways of doing without FDI

A Question of Business
By P. GUNASEGARAM

A STIR of sorts has been caused by the story that foreign direct investment (FDI) into the country for 2009 fell 81% to US$1.4bil (about RM4.5bil) from US$7.3bil (RM24bil).

But really it should not. If we want higher value-added, then labour-intensive industries are not our target. This is the area which many foreign investors like because they can get tremendous cost savings by using cheap labour in places like China, Vietnam etc.

If greater value-added is what we are after, then increasingly more investments have to be made in the services area – think tourism or education for instance. That does not necessarily need foreign investment – we can use local money.

We have plenty of money in Malaysia – as much as RM250bil at last count. That’s roughly the excess of deposits over loans sitting with the banks throughout the country.

All that money and nowhere to go within the country, is our problem. The money is not chasing investments in the country. And that can mean only one thing – there is a lack of opportunity here.

The question then is what is it that is reducing business opportunities in Malaysia? Is there too much red tape? Are approvals not forthcoming? Are there too many equity strictures? Do we have sufficient workers?

FDI flows in any particular year into Malaysia pales in comparison to the amount of idle money in the system. What we have to do is to find ways to use that and we will more than mitigate the effects of reduced FDI. Here are 10 ways we can do that.

1) Shift from manufacturing to services. This is inevitable if you want to move towards higher income. Our manufacturing is low value-added. Much of it is low-end assembly. Things like tourism and education offer so much more opportunities and are already large contributors to foreign exchange savings;

2) Reduce export dependence. Old habits die hard and we must realise that we cannot continue to export ourselves out of trouble all the time. What we must do is create a market for ourselves right here. Get our consumers, who seem to have a lot of money, to spend – think restaurants, entertainment, lifestyle etc;

3) Identify and target the high growth areas. Old-style low-cost manufacturing is out. We need to identify some areas for good growth in the future and focus on this. We could easily become a quality education hub for the region for instance and benefit ourselves in the process. We could set aside areas for international universities to be set up;

4) Make incentives the same for both domestic and foreign investors. The days of giving more incentives, latitude and preference to foreign investors must end once and for all and the playing field levelled. In fact, greater encouragement and incentives must be given for the development of local enterprises based on the simple premise that we must help ourselves more;

5) Cut tariffs and taxes. Tariffs are non-competitive and cutting them increases competitiveness of all industries as they are able to source supplies and services which are the cheapest and of the best quality. Cutting taxes provides incentives for making money. Our taxes are still relatively high;

6) Do away with equity targets altogether. With bumiputra equity targets probably already met if we measure using the right techniques, there is no need to force non-bumiputra industries to continue to enter Ali Baba-style partnerships to do this, a highly inefficient process that benefits very few bumiputras in any case;

7) Cut red tape. For all the lip service made to cutting red tape over the years, this is still very much with us. As long as officialdom puts all kinds of barriers in the way of genuine enterprise, expect enterprise to be hobbled;

8) Do away with yearly renewal of licences. If you already have a licence, why renew it yearly? Why can’t it be given to you indefinitely unless you flout licence requirements? Doing away with licence approvals on a yearly basis helps cut bureaucracy;

9) Improve educational standards. We can’t emphasise this enough and the steady decline in educational standards both at schools and universities has not, so far, elicited a strong enough response from the Government which will stop the slide; and

10) Cut corruption. This insidious, widespread problem is eventually the cause for much bottleneck, inefficiency, higher costs and a downright hindrance to improving productivity at all levels. It’s incredible how little we have done to stop this scourge.

Yes, FDI has dropped and it may continue to drop. But really, that’s not the end of the world. Anyway, it’s high time we reduced dependence on FDI and did something to pump up domestic investment instead. And there are many more imaginative ways to do that.

·Managing editor P. Gunasegaram is amazed that some foreign companies are taxed by their home countries for the taxes they don’t pay here; in other words, the tax incentives given to them here goes to a foreign country instead.