Sounds like some marketing guy blowing smoke out his...er...circular rear exhaust port to me. Vague as hell.
Obviously you missed (or are simply ignoring) my point. It is easier to improve from a low level than from a high level. Even with all those improvements, the construction cores never came close to intel in ipc and efficiency. I don't really fault intel for lack of improvement in ipc and clock speed. What I do fault them for is not increasing core counts and making hyperthreading more available on the mainstream platform.frozen even when AMD had a horrible architecture with Bulldozer they had decent updates every 12-18 months with Piledriver, Steamroller and Excavator. I think AMD will keep pushing the Zen core at the same rate with reasonably good IPC improvements of 5-10% every 12 months. I think will see Zen 2 based Pinnacle Ridge in Q1 2018 on an improved 14LPP process and a GF 7nm based Zen 3 in H1 2019. It will be much easier to make significant improvements for the first couple of generations with a brand new architecture especially with such a unique CCX design. Improving memory support for high speed DDR4, improving fabric speeds, improving cache performance are some of the most obvious areas for Zen improvements.
Is there any reason to trust that result? I think a dual core Phenom chip beats it...This chip looks like a dud, Kaby Lake Refresh-U is a better product. I think CNL-U will not see the light of day.
I vote for a 10nm+ unlocked desktop i3, for $74. C'mon Intel, you know that you want to.
They're not going to do that, that would be a 50% price cut or so from the current unlocked i3s.
But whatever Intel does sell for $74 at the 10nm+ generation should be quite nice.
It's 14nm++.
So what exactly is "performance" in Intel's chart? Max clock speed? And it's not like 10 nm is worse than 14 nm+ in that respect. I imagine the focus would be more on the 5.2 W models, which should be very popular with OEMs for fanless laptops.
This chip looks like a dud, Kaby Lake Refresh-U is a better product. I think CNL-U will not see the light of day.
frozen even when AMD had a horrible architecture with Bulldozer they had decent updates every 12-18 months with Piledriver, Steamroller and Excavator. I think AMD will keep pushing the Zen core at the same rate with reasonably good IPC improvements of 5-10% every 12 months. I think will see Zen 2 based Pinnacle Ridge in Q1 2018 on an improved 14LPP process and a GF 7nm based Zen 3 in H1 2019. It will be much easier to make significant improvements for the first couple of generations with a brand new architecture especially with such a unique CCX design. Improving memory support for high speed DDR4, improving fabric speeds, improving cache performance are some of the most obvious areas for Zen improvements.
This chip looks like a dud, Kaby Lake Refresh-U is a better product. I think CNL-U will not see the light of day.
ES in the wild is a good indication for its existence, especially a recent entry. It would be very unusual for Intel if they canceled a product so late in development. I guess the Gen10 entry from gfxbench is also from CNL-U because both were clocked at 2.4 Ghz. There is no indication that CNL-U is cancelled. Given that Intel is doing only SoC variants for CNL it makes perfect sense that KBL-Y and KBL-U will be replaced by CNL, there is no Coffe Lake replacement for those. CNL-U also should have a much more capable GT2 than KBL-R.
Based on SYSmark* 2014 v1.5 (Windows Desktop Application Performance). Comparing 6th Gen (Skylake): i7-6600U, PL1=15W TDP, 2C4T, Turbo up to 3.4GHz, Memory: 2x4GB DDR4-2133, vs. 7th Gen (Kaby Lake): i7-7600U, PL1=15W TDP, 2C4T, Turbo up to 3.9GHz, Memory: 2x4GB DDR4-2133, vs. Estimates for 8th Gen (Kaby Lake U42): PL1=15W and PL2=44W TDP, 4C8T, Turbo up to 4.0GHz. Additional config details: Storage: Intel SSD, Display Resolution: 1920x1080, OS: Windows* 10 TH2. Note: Kaby Lake U42 performance estimates are Pre-Silicon, apply to top bin, and are subject to change. Pre-Si projections have +/- 7% margin of error.
The way I see it:
KBL-U 2+2 -> KBL-U 4+2
KBL-U 2+3e -> CFL-U 4+3e
KBL-H 4+2 -> CFL-H 6+2
KBL-Y 2+2 -> CNL-Y 2+2
Intel Optane SSD 900P sequential read speed of up to 2,500MB / s, while the maximum sequential write is 2,000MB / s; 4K random reading part of the maximum to 550K IOPS, and 4K random write is the maximum to 500K IOPS The Although the capacity is different, but the Intel Optane SSD 900P and Intel Optane SSD DC P4800X performance is roughly the same.
So, basically retail version of P4800X. We'll see, maybe folks forking out for 960 PRO will consider adding that one to their collection.BenchLife just leaked details about their new Optane product.
Hum I must be missing something because some Samsung NVMe drives are getting more than 3 GB/s sequential read.BenchLife just leaked details about their new Optane product.
Intel Optane SSD 900P: Read speeds up to 2,500MB/s
https://benchlife.info/intel-optane-ssd-900p-03312017
Hum I must be missing something because some Samsung NVMe drives are getting more than 3 GB/s sequential read.
Exactly what I was thinking.
The P4800X can do 550,000 read IOPS and 500,000 write IOPS, but critically, Intel says it achieves this even at low queue depths. The spec sheet figure has a queue depth of 16, and the company says that a queue depth of about 8 tends to be about the limit seen in the real world.
Moreover, Intel says that the latency of each I/O operation remains low even under heavy load. 99.999 percent of operations have a read or write latency below 60 or 100 microseconds (respectively) with a queue depth of 1, rising to 150 or 200 microseconds with a queue depth of 16. Under a comparable load, Intel's own P3700 NAND SSD can only serve 99 percent of operations with a latency below about 2,800 microseconds.
Likewise, under sustained write workloads, the P4800X retains its low latency for reads, whereas the read latency of the P3700 NAND steadily deteriorates as the write bandwidth increases.
While 3 GB/s is nothing to sneeze at, that isn't the main advantage of Optane. The main advantage is if you want a responsive system. Opening a program may need several hundred small files. That doesn't require much bandwidth. But at several milliseconds per small file (at least, sometimes far more), even the fastest SSD will take a while to load most programs that are more that just a simple executable. But at only several microseconds per small file, Optane should feel instantaneous for most tasks even when loading complex programs with thousands of small files.Hum I must be missing something because some Samsung NVMe drives are getting more than 3 GB/s sequential read.
While 3 GB/s is nothing to sneeze at, that isn't the main advantage of Optane. The main advantage is if you want a responsive system. Opening a program may need several hundred small files. That doesn't require much bandwidth.
Same goes when saving or loading any data that is scattered amongst many small files.
Agreed. I was just suprised Sweepr highlighted the BW rather than other characteristicsWhile 3 GB/s is nothing to sneeze at, that isn't the main advantage of Optane. The main advantage is if you want a responsive system. Opening a program may need several hundred small files. That doesn't require much bandwidth. But at several milliseconds per small file (at least, sometimes far more), even the fastest SSD will take a while to load most programs that are more that just a simple executable. But at only several microseconds per small file, Optane should feel instantaneous for most tasks even when loading complex programs with thousands of small files.
Same goes when saving or loading any data that is scattered amongst many small files.
We think the general sweet spot is around the Intel Xeon E3-1240 V6CPU. It provides Hyper-threading as well as giving access to the overall Intel Xeon E3-1200 V6 platform at a reasonable price. The performance delta between the E3-1280 V6 and the E3-1270 V6 should be relatively minor for an overall increase of almost double, or an impact of 4-13% of total system costs. For those looking at low-cost appliances, the Intel Xeon E3-1220/ E3-1225 V6 CPUs still reign supreme. We looked at the overall hardware costs but there is one more important component to the equation, software license costs. For applications that are licensed on a per-core basis, license costs can easily eclipse hardware costs. For those applications, the Intel Xeon E3-1280 V6 may be worth every penny for the speed bump over lower-end models.