Subject: General Tech | August 18, 2016 - 02:20 PM | Jeremy Hellstrom
Tagged: Intel, joule, iot, IDF 2016, SoC, 570x, 550x, Intel RealSense
Intel has announced the follow up to Edison and Curie, their current SoC device, called Joule. They have moved away from the Quark processors they previously used to a current generation Atom. The device is designed to compete against NVIDIA's Jetson as it is far more powerful than a Raspberry Pi and will be destined for different usage. It will support Intel RealSense, perhaps appearing in the newly announced Project Alloy VR headset. Drop by Hack a Day for more details on the two soon to be released models, the Joule 570x and 550x.
"The high-end board in the lineup features a quad-core Intel Atom running at 2.4 GHz, 4GB of LPDDR4 RAM, 16GB of eMMC, 802.11ac, Bluetooth 4.1, USB 3.1, CSI and DSI interfaces, and multiple GPIO, I2C, and UART interfaces."
Here is some more Tech News from around the web:
- Microsoft Windows UAC can be bypassed for untraceable hacks @ The Inquirer
- Microsoft PowerShell Goes Open Source and Lands On Linux and Mac @ Slashdot
- The Witcher 3: Wild Hunt Enables NVIDIA Ansel Support For 3D Stereo Screenshots @ Techgage
- ech support scammers mess with hacker's mother, so he retaliated with ransomware @ The Register
- 90 per cent of people ignore security notices because their brains are too busy @ The Inquirer
- NikKTech With Kingston HyperX It's All About Speed Global Giveaway
Subject: Systems | August 17, 2016 - 04:37 PM | Ryan Shrout
Tagged: UHD, SFF, IDF 2016, idf, gigabyte, gaming, brix
While wandering around the exhibit area at this year’s Intel Developers Forum, I ran into our friends at Gigabyte a brand new BRIX small form factor PC. The BRIX Gaming UHD takes the now-standard NUC/BRIX block shape and literally raises it up, extending the design vertically to allow for higher performance components and the added cooling capability to integrate them.
The design of the BRIX Gaming UHD combines a brushed aluminum housing with a rubber base and bordering plastic sections to create a particularly stunning design that is both simple and interesting. Up top is a fan that pulls air through the entire chassis, running over the heatsink for the CPU and GPU. This is similar in function to the Mac Pro, though this is a much more compact device with a very different price point and performance target.
Around the back you’ll find all the connections that the BRIX Gaming UHD supplies: three (!!) mini DisplayPort connections, a full size HDMI output, four USB 3.0 ports, a USB 3.1 connection, two wireless antennae ports, Gigabit Ethernet and audio input and output. That is a HUGE amount of connectivity options and is more than many consumer’s current large-scale desktops.
The internals of the system are impressive and required some very custom design for cooling and layout.
The discrete NVIDIA graphics chip (in this case the GTX 950) is on the left chamber while the Core i7-6500HQ Skylake processor is on the left side along with the memory slot and wireless card.
Gigabyte measures the size of the BRIX Gaming UHD at 2.6 liters. Because of that compact space there is no room for hard drives: you get access to two M.2 2280 slots for storage instead. There are two SO-DIMM slots for DDR4 memory up to 2133 MHz, integrated 802.11ac support and support for quad displays.
Availability and pricing are still up in the air, though early reports are that starting cost will be $1300. Gigabyte updated me and tells me that the BRIX Gaming UHD will be available in October and that an accurage MSRP has not been set. It would not surprise me if this model never actually saw the light of day and instead Gigabyte waited for NVIDIA’s next low powered Pascal based GPU, likely dubbed the GTX 1050. We’ll keep an eye on the BRIX Gaming UHD from Gigabyte to see what else transpires, but it seems the trend of small form factor PCs that sacrifice less in terms of true gaming potential continues.
IDF 2016: ScaleMP Merges Software-Defined Memory With Storage-Class Memory, Makes Optane Work Like RAM
Subject: Storage | August 16, 2016 - 04:05 PM | Allyn Malventano
Tagged: Virtual SMP, SMP, SDM-S, SDM-F, ScaleMP, IDF 2016, idf
ScaleMP has an exciting announcement at IDF today, but before we get into it, I need to do some explaining. Most IT specialists know how to employ virtualization to run multiple virtual environments within the same server, but what happens when you want to go the other way around?
You might not have known it, but virtualization can go both ways. ScaleMP make such a solution, and it enables some amazing combinations of hardware all thrown at a single virtualized machine. Imagine what could be done with a system containing 32,768 CPUs and 2048TB (2PB) of RAM. Such a demand is actually more common than you might think:
List of companies / applications of ScaleMP.
ScaleMP's tech can fit into a bunch of different usage scenarios. You can choose to share memory, CPU cores, IO, or all three across multiple physical machines, all combined into a single beast of a virtualized OS, but with the launch of 3D XPoint there's one more thing that might come in handy as a sharable resource, as there is a fairly wide latency gap between NAND and RAM:
Alright, now that we've explained the cool technology and the gap to be filled, onto the news of the day, which is that ScaleMP has announced that their Software Defined Memory tech has been optimized for Intel Optane SSDs. This means that ScaleMP / Optane customers will be able to combine banks of XPoint installed across multiple systems all into a single VM. Another key to this announcement is that due to the way ScaleMP virtualizes the hardware, the currently developing storage-class (NVMe) XPoint/Optane solutions can be mounted as if they were system memory, which should prove to be a nice stopgap until we see second generation 3D XPoint in DIMM form.
More to follow from IDF 2016. ScaleMP's press blast appears after the break.
Subject: Storage | August 16, 2016 - 02:00 PM | Allyn Malventano
Tagged: XPoint, Testbed, Optane, Intel, IDF 2016, idf
IDF 2016 is up and running, and Intel will no doubt be announcing and presenting on a few items of interest. Of note for this Storage Editor are multiple announcements pertaining to upcoming Intel Optane technology products.
Optane is Intel’s branding of their joint XPoint venture with Micron. Intel launched this branding at last year's IDF, and while the base technology is as high as 1000x faster than NAND flash memory, full solutions wrapped around an NVMe capable controller have shown to sit at roughly a 10x improvement over NAND. That’s still nothing to sneeze at, and XPoint settles nicely into the performance gap seen between NAND and DRAM.
Since modern M.2 NVMe SSDs are encroaching on the point of diminishing returns for consumer products, Intel’s initial Optane push will be into the enterprise sector. There are plenty of use cases for a persistent storage tier faster than NAND, but most enterprise software is not currently equipped to take full advantage of the gains seen from such a disruptive technology.
XPoint die. 128Gbit of storage at a ~20nm process.
In an effort to accelerate the development and adoption of 3D XPoint optimized software, Intel will be offering enterprise customers access to an Optane Testbed. This will allow for performance testing and tuning of customers’ software and applications ahead of the shipment of Optane hardware.
I did note something interesting in Micron's FMS 2016 presentation. QD=1 random performance appears to start at ~320,000 IOPS, while the Intel demo from a year ago (first photo in this post) showed a prototype running at only 76,600 IOPS. Using that QD=1 example, it appears that as controller technology improves to handle the large performance gains of raw XPoint, so does performance. Given a NAND-based SSD only turns in 10-20k IOPS at that same queue depth, we're seeing something more along the lines of 16-32x performance gains with the Micron prototype. Those with a realistic understanding of how queues work will realize that the type of gains seen at such low queue depths will have a significant impact in real-world performance of these products.
The speed of 3D XPoint immediately shifts the bottleneck back to the controller, PCIe bus, and OS/software. True 1000x performance gains will not be realized until second generation XPoint DIMMs are directly linked to the CPU.
The raw die 1000x performance gains simply can't be fully realized when there is a storage stack in place (even an NVMe one). That's not to say XPoint will be slow, and based on what I've seen so far, I suspect XPoint haters will still end up burying their heads in the sand once we get a look at the performance results of production parts.
Leaked roadmap including upcoming Optane products
Intel is expected to show a demo of their own more recent Optane prototype, and we suspect similar performance gains there as their controller tech has likely matured. We'll keep an eye out and fill you in once we've seen Intel's newer Optane goodness it in action!