Friday, 19 July 2013

Ivy Bridge-E: Core i7-4960X details

Disclaimer: The following preview is based on an early engineering sample Core i7-4960X. Intel was not involved in the story, and was not asked for comment prior to its publication. In fact, starting with our Haswell preview, the company started a policy of excluding us from certain discussions. So yeah. There’s always more of that to look forward to.
Recently, Gartner published numbers showing that shipments of PCs dropped a staggering 11 percent in the second quarter of this year, primarily attributed to tablets replacing entry-level machines. Wall Street, at least, is all doom and gloom about the PC’s future prospects.
But the boutique builders I talk to say that interest in super-fast gaming systems is at an all-time high thanks to the efficiency of certain processor and graphics architectures. So, while now might be a bad time to get stoked about mainstream hardware, performance-oriented power users have some pretty quick components to choose from.
None of this is news to enthusiasts. In fact, two and a half years ago, Intel’s sandy bridge architecture  was serving up compelling performance under 100 W. Those were exciting times. The Ivy Bridge architecture that followed nudged our benchmark results forward a bit, but dropped power to less than 77 W. That was pretty cool, too. More recently, Haswell added another few percentage points to the performance picture, but bumped maximum consumption back up to 84 W.
Now, if you’re upgrading an old Core 2- or Phenom II-based machine with a $5000 boutique build, the latest parts are going to feel wicked-fast, no matter how incremental the previous two or three generations look on paper. The difference is simply less perceptible to those of us working with these components day in and out.
The point is that, for a do-it-yourselfer like me, Sandy Bridge was exciting, Ivy Bridge a little less so, and Haswell…well, I called that one The Core i7-4770K Review: Haswell Is Faster; Desktop Enthusiasts Yawn.
We all know where Intel’s collective mind is: the mobile space where those Gartner guys are telling us the low-end PCs continue getting slaughtered. In that context, spending $350 on a -4770K and another $250 on an LGA 1150-capable Motherboard just to keep up with the Kardashians doesn't sound so hot.
If, a year and a half ago, you snagged a Core i7-3930K (which won a very rare Best Of award from us in Intel Core i7-3930K And Core i7-3820: Sandy Bridge-E, Cheaper), you’d still be sitting pretty, potentially overclocked to 4.5 or 4.6 GHz, and outclassing the just-released -4770K in a great many threaded applications. You’d also be using the same X79-based platform. And, with the revelation that Intel’s upcoming Ivy Bridge-E architecture will drop into an LGA 2011 interface, you’re also going to face your first opportunity in two years to buy something faster.

Meet Ivy Bridge-E, The Upgrade Path For X79 Express

Right now it looks like Ivy Bridge-E-based processors will launch in September, putting us a couple of months out. Multiple models are expected, but I’ve only seen official specifications for two: the Core i7-4960X and Core i7-4820K. Earlier leaks showed thatthe -4960X would be a six-core CPU, while the -4820K hosts four cores. Purportedly there’s a Core i7-4930K in there as well, though I haven’t received one yet.
From most angles, the Ivy Bridge-E-based parts look a lot like Sandy Bridge-E, except for the adoption of Intel’s Ivy Bridge architecture. That means a handful of IPC-oriented improvements in the core, cache, and memory controller, similar to what we described in Intel Core i7-3770K Review: A Small Step Up For Ivy Bridge. Of course, gone is the emphasis on graphics. That means Ivy Bridge-E is really about the updated core, a memory controller rated for 1866 MT/s (instead of 1600), official PCI Express 3.0 compliance (remember, Sandy Bridge-E only claimed 8 GT/s signaling support), and 22 nm manufacturing. Ivy Bridge-E-based CPUs should also be unlocked up to 63x multipliers (versus SNB-E's 57x), you should be able to hit memory data rates beyond 2400 MT/s, Ivy Bridge-E supports XMP 1.3 (compared to SNB-E's XMP 1.2), and you'll have access to real-time ratio, voltage, and power limit settings.
You still get 40 lanes of PCI Express connectivity, divisible into as many ports as you need for four-way CrossFire and SLI. You’re still dealing with a quad-channel memory controller, though the higher data rate increases peak bandwidth to 59.7 GB/s from 51.2 GB/s. And you’re dropping Ivy Bridge-E into the aging X79 Express platform. The good news is that your old motherboard still works; you don’t have to buy a new one. Unfortunately, the chipset only offers two SATA 6Gb/s ports, it doesn’t feature native USB 3.0, and you don’t get to enjoy new capabilities like SATA Express, which will surface alongside Haswell-based 9-series chipsets early in 2014.

Core i7-4960XCore i7-4820KCore i7-3970X
Code NameIvy Bridge-EIvy Bridge-ESandy Bridge-E
Base Clock rate3.6 GHz3.7 GHz3.5 GHz
Maximum Turbo Boost4 GHz GHz3.9 GHz4 GHz
PCI Express Link Speed8 GT/s8 GT/s8 GT/s
TDP130 W130 W150 W
Processor Cores646
Shared L3 Cache15 MB10 MB15 MB
Max. Memory Data RateDDR3-1866DDR3-1866DDR3-1600
Processor InterfaceLGA 2011LGA 2011LGA 2011
Again, Core i7-4960X is going to be a six-core part with 15 MB of shared L3 cache. No doubt that’ll disappoint the folks who were hoping a 22 nm process would make it easier for Intel to arm enthusiasts with eight or 12 cores. But, assuming the company plans to charge the same $1000, there’s really no reason to give you a more complex CPU when it’s already charging $1900 for an eight-core Xeon E5-2687W. And so, anyone considering a move from today’s Core i7-3970X can expect an additional 100 MHz base frequency, the same 4 GHz peak Turbo Boost clock rate, and the other incremental improvements.
The Core i7-4820K is a little more interesting. Realizing that there was almost no reason at all anyone would want a multiplier-locked, quad-core -3820, Intel gives its successor an unlocked ratio. It’s still a quad-core chip with 10 MB of shared L3 cache based on a previous-gen architecture in a previous-gen platform. But perhaps the additional PCI Express connectivity, memory bandwidth, and L3 cache, coupled with the ability to overclock, makes the -4820K a little more competitive against Intel’s Haswell-based Corei7-4770K.  
Curiously, both planned Ivy Bridge-E-based parts are accompanied by 130 W thermal design power limits. Remember that the move from Sandy to Ivy Bridge yielded a more complex CPU with a significantly lower power ceiling, thanks in no small part to a shift from 32 to 22 nm manufacturing. Here, we have the same process transition, but no real change in complexity—and yet the same 130 W rating as Core i7-3960X and -3930K. Keep an eye on this. Power may just become Ivy Bridge-E’s greatest strength.

No comments:

Post a Comment

Thanx for all your Feedback .... and don't post to promote your site's ...

I kept the option as Comment moderation mode. So if you try to promote your site from here.. I do delete your comment's ..