Intel Gives Exascale A Boost
Intel’s exascale computing efforts have received a boost with the extension of the company’s research collaboration with the Barcelona Supercomputing Center.
Begun in 2011 and now extended to September 2017, the Intel-BSC work is currently looking at scalability issues with parallel applications.
Karl Solchenbach, Intel’s director, Innovation Pathfinding Architecture Group in Europe said it was important to improve scalability of threaded applications on many core nodes through the OmpSs programming model.
The collaboration has developed a methodology to measure these effects separately. “An automatic tool not only provides a detailed analysis of performance inhibitors, but also it allows a projection to a higher number of nodes,” says Solchenbach.
BSC has been making HPC tools and given Intel an instrumentation package (Extrae), a performance data browser (Paraver), and a simulator (Dimemas) to play with.
Charlie Wuischpard, VP & GM High Performance Computing at Intel said that the Barcelona work is pretty big scale for Chipzilla.
“A major part of what we’re proposing going forward is work on many core architecture. Our roadmap is to continue to add more and more cores all the time.”
“Our Knights Landing product that is coming out will have 60 or more cores running at a slightly slower clock speed but give you vastly better performance,” he said.
Is Intel Expanding?
Even if it means that it will be the first to make ARM’s 64-bit chips, Intel said that it wants to expand its contract foundry work. Intel CEO Brian Krzanich said he would expand his company’s small contract manufacturing business, paving the way for more chipmakers to tap into the world’s most advanced process technology.
Krzanich told analysts that he planned to step up the company’s foundry work, effectively giving Intel’s process technology to its rivals. He said that company’s who can use Intel’s leading edge and build computing capabilities that are better than anyone else’s, are good candidates for foundry service. Krzanich added that the slumping personal computer industry, Intel’s core market, was showing signs of bottoming out.
Intel also unveiled two upcoming mobile chips from its Atom line designed interchange features to create different versions of the component. A high-end version of the new chip, code named Broxton, and is due out in mid-2015. SoFIA, a low-end chip was shown as an example of Intel’s pragmatism and willingness to change how it does business. Krzanich said that in the interest of speed, SoFIA would be manufactured outside of Intel, with the goal of bringing it to market next year.
Intel will move production of SoFIA chips to its own 14 nanometer manufacturing lines, Krzanich added.
Intel Buys KNO Software
Intel has acquired educational software developer Kno to add to its Education division.
Speaking in the company blog, Intel Sales and Marketing Group VP John Galvin explained that in a world where kids are being bombarded by technology, Intel Education has a mission to support the rollout of technology in the classroom.
Galvin said, “The Kno platform provides administrators and teachers with the tools they need to easily assign, manage and monitor their digital learning content and assessments.”
This acquisition brings Intel’s global digital content library to over 225,000 [higher education] and K-12 titles from 74 education publishers. “We’re looking forward to combining our expertise with Kno’s rich content so that together, we can help teachers create classroom environments and personalized learning experiences that lead to student success,” Galvin added.
Intel Education has been working for the past decade with over 10 million teachers that it has assisted to integrate technology with education.
In the UK alone there have been tremendous strides in educational software over the past 30 years, dating back to the government pledge to provide a computer in every school, which led to the creation of the BBC Microcomputer designed specifically for that purpose.
Today, not only is ICT a dedicated lesson in its own right, but it forms one of the key skills that educators are expected to incorporate into all lesson plans, putting it on a par with English and Maths, showing just how far we’ve come from making Venn diagrams with ascii art.
Google Goes Quantum
When is a blink not a natural blink? For Google the question has such ramifications that it has devoted a supercomputer to solving the puzzle.
Slashgear reports that the internet giant is using its $10 million quantum computer to find out how products like Google Glass can differentiate between a natural blink and a deliberate blink used to trigger functionality.
The supercomputer based at Google’s Quantum Artificial Intelligence Lab is a joint venture with NASA and is being used to refine the algorithms used for new forms of control such as blinking. The supercomputer uses D-Wave chips kept at as near to absolute zero as possible, which makes it somewhat impractical for everyday wear but amazingly fast at solving brainteasers.
A Redditor reported earlier this year that Google Glass is capable of taking pictures by responding to blinking, however the feature is disabled in the software code as the technology had not advanced enough to differentiate between natural impulse and intentional request.
It is easy to see the potential of blink control. Imagine being able to capture your life as you live it, exactly the way you see it, without anyone ever having to stop and ask people to say “cheese”.
Google Glass is due for commercial release next year but for the many beta testers and developers who already have one this research could lead to an even richer seam of touchless functionality.
If nothing else you can almost guarantee that Q will have one ready for Daniel Craig’s next James Bond outing.
Intel Releases 16GB Xeon Phi
Intel has announced five Xeon Phi accelerators including a high density add-in card while upping memory capacity to 16GB.
Intel has managed to get its Xeon Phi accelerator cards to power the Tianhe-2 cluster to the summit of the Top 500 list, however the firm isn’t waiting around to bring out new products. At the International Supercomputing show, Intel extended its Xeon Phi range with five new products, all of which have more than one TFLOPS double precision floating point performance, and the Xeon Phi 7120P and 7120X cards, which have 16GB of GDDR5 memory.
Intel’s Xeon Phi 7120P and 7120X cards have peak double precision floating point performance of over 1.2 TFLOPS, with 352GB/s bandwidth to the 16GB of GDDR5 memory. The firm also updated its more modest Xeon Phi 3100 series with the 3120P and 3120A cards, both with more than one TFLOPS of double precision floating point performance and 6GB of GDDR5 memory with bandwidth of 240GB/s.
Intel has also brought out the Xeon Phi 5120D, a high density card that uses mini PCI-Express slots. The firm said that the Xeon Phi 5120D card offers double precision floating point performance of more than one TFLOPS and 8GB of GDDR5 memory with bandwidth greater than 300GB/s.
That Intel is concentrating on double precision floating point performance with its Xeon Phi accelerators highlights the firm’s focus on research rather than graphics rendering or workstation tasks. However the firm’s ability to pack 16GB into its Xeon Phi 7100 series cards is arguably the most important development, as larger locally addressable memory means higher resolution simulations.
Intel clearly seems to believe that there is significant money to be made in the high performance PC market, and despite early reservations from industry observers the firm seems to be ramping up its Xeon Phi range at a rate that will start to give rival GPGPU accelerator designer Nvidia cause for concern.
Haswell Refresh Coming Next Year
Intel has been executing its tick tock strategy flawlessly since January 2006 and now there is some indication that we might see the first slip in 8 years come 2014. Intel’s latest roadmap claims that in 12 months from now, in Q2 2014 Haswell will be replaced by a “Haswell refresh”.
Haswell is a tock, a 22nm new architecture and Broadwell is supposed to be based on Haswell fundamentals, but shrunk to 14nm like a proper “tock”. In case that the Haswell refresh is a tweaked 22nm core, this would mean that after 7 years of execution and billions of investments in cutting edge fabrication processes, Intel would have to slow things down.
It is not certain what would happen to 2015 Skylake, a new 14nm architecture, or the 10nm Skymont that is supposed to be the shrink, but in case Broadwell gets pushed back by a year there is a big possibility that the whole roadmap would slip a year.
When it gets ready the Haswell refresh (possibly a disguise name for Broadwell ed.) is replacing Core i7, Core i5, Core i3, Pentium and Celeron based Haswell chips, some sooner rather than later.
The chipset responsible for Haswell refresh is already branded as Z97 and H97 in desktop versions replacing the Z87 and H87 boards proving that the socket are likely to continue existing at least through 2014. It will be interesting to see the developments and if Broadwell is really delayed or this is just game of words on Intel’s part.
Intel Shows More Ivy Bridge
June 19, 2013 by admin
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Last week Intel officially released Haswell, but there’s still life in good old Ivy Bridge. The chipmaker has announced a range of low-end Ivy parts and even a Sandy Bridge based Celeron.
The Celeron G470 is possibly the last consumer Sandy Bridge we will ever see. It is a single-core 35W part clocked at 2GHz and it’s priced at just $37.
However, Ivy Bridge parts are a bit more interesting. They include the Celeron 1017, a dual-core, dua-thread chip clocked at 1.6GHz, with a TDP of just 17W. It costs $86 and should be a nice part for low-end laptops and nettops. The Celeron 1005M also costs $86, but it has a 35W TDP and a 1.9GHz clock.
There are four new G2000 Pentiums as well. The G2140 and G2030 are 55W parts, clocked at 3GHz and 3.3GHz respectively. The G2120T and G2030T are 35W chips, clocked at 2.6GHz and 2.7GHz. They cost $64 and $75 respectively. Of course, Pentiums don’t feature Hyperthreading and all four of them are dual-core parts.
The Core i3 line-up also got some speed bumps. The Core i3-3245 and 3250 are clocked at 3.4 and 3.5GHz and both have a TDP of 55W. The 3245 features HD 4000 graphics and costs $134, while the 3250 ends up with HD 2500 graphics and a price tag of $138. Lastly, the Core i3-3250T is a 3GHz part with a 35W TDP, it costs $138, just like its 55W sibling.
Does Haswell Need A Separate GPU?
Nvidia actually has a person with the catchy title of Chief Blogger and this person managed to get “an interview” with Rene Haas a VP and GM of computing products that currently takes care of Geforce mobile among other things.
Rene was asked to explain “why Gamers still need a discrete GPU with Haswell” and the answer is as logical as why do you use a seatbelt. Rene expects that Intel will continue to suck in graphics (our words not his ed.) and that that most popular games won’t play well on Haswell at standard resolution.
It seems that history really does repeat itself, as Intel had big claims for both Ivy Bridge and Sandy Bridge had been struggling to run new games of their time. Any serious gamers know that the answer is a proper discrete GPU. Haswell won’t change that, claims Rene.
It looks like Nvidia will have at least as many design wins as with Ivy Bridge, and Ivy Bridge was the record number or design wins for Nvidia. Rene claims that with this refresh Nvidia will have as much as 95 per cent of the gaming notebook which is nothing short of spectacular.
Rene also attacks Intel boldly claiming that “Their (Intel) comparison is misleading on a number of fronts.” Commenting the fact that Intel claims that GT3e will be faster than Geforce GT 650M. Intel based its claims on synthetic benchmarks, something that can be optimised, while Nvidia prefers real games, and even if GT3 wins again Geforce GT650, the new Geforce GT 750 is much faster than its predecessor and will have double the performance of GT3e in games.
Rene reminds us that GT3e is only available in top quad core mobile cores such as Core i7 4880QM that usually find their place in $3,000 notebooks. Rene tells customers that getting a Core i5 of Core i3 notebook with a better discrete GPU is the right way to get better gaming performance, although the vast majority of consumers already know that.
We remember that the last time we sat down with Rene, he said that when Intel gets faster with Integrated, Nvidia will simply gets even better with its corresponding low-end products and offers something faster. The cat and mouse game never ends.
Intel Releases More Celeron CPUs
Intel added three curious ultra-low voltage chips to its official price list and their official designations is strange.
All three are 22nm parts and their product numbers are N2805, N2810 and N2910, which seems to indicate that they are Atoms, but they are listed in the ULV Celeron M section, reports CPU World. The top SKU features four cores with no hyperthreading, which means that it is probably based on the new Valley View M core.
The N2805 is a dual-core clocked at 1.46GHz, with a single megabyte of cache. The N2810 is also a dual-core, but it’s clocked at 2GHz, while the N2910 is the previously mentioned quad-core, with 2MB of cache and a clock speed of 1.6GHz. All of them are priced at $132, which sounds like way too much for Atom branded parts.
With Temash and Kabini just around the corner, Intel needs to step up its game in the low-end low-voltage market fast, but at this point it seems that AMD be the first to market and it will enjoy at least a few months on top. Even when Intel launches its first 22nm Atoms, it won’t have an easy time matching AMD’s price or performance.
Haswell Core i7 Overclocked To 5GHz
As we draw closer to the launch of Intel’s 4th generation Core CPUs, or Haswell, it is no wonder that we are starting to see more leaks and one showing Intel’s Core i7 4770K overclocked to 5GHz at 0.9V certainly drew a lot of attention.
An impressive overclocking achievement was spotted by Ocaholic.ch and shows a CPU-Z validation of Core i7 4770K overclocked to exactly 5005.83MHz at just 0.904V. As far as we can tell, Hyper-threading was disabled and it is not clear if the CPU is actually stable enough to run anything, but in any case, it is still an impressive result, especially at such low voltage.
The rest of the specs include 4GB of DDR3 memory and ASRock’s upcoming Z87 Extreme4 motherboard.