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Will AMD’s Newest SoC Save The Company?
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The troubled chipmaker AMD thinks it is onto a winner with its new AMD Embedded R-Series SOC processors.
Designed for demanding embedded needs, the processors incorporate the newest AMD 64-bit x86 CPU core (“Excavator”), plus third-generation Graphics Core Next GPU architecture, and better power management for reduced energy consumption.
AMD tells us that combined, these chips provide industry-leading graphics performance and key embedded features for next-generation designs. The SOC architecture enables simplified, small form factor board and system designs from AMD customers and a number of third party development platform providers.
What AMD brings to the party is its graphics and multimedia performance, including capability for hardware-accelerated decode of 4K video playback and support for the latest DDR4 memory.
Jim McGregor, principal analyst, TIRIAS Research said that AMDs push into x86 embedded platforms is paying off with an increasing number of customers and applications.
“There is a need for immersive graphics, high-quality visualization, and parallel computing in an increasing number of embedded applications. Across these fronts, the AMD Embedded R-Series SOC is a very compelling solution.”
Scott Aylor, corporate vice president and general manager, AMD Embedded Solutions said that his outfit’s AMD Embedded R-Series SOC is a strong match for these needs in a variety of industries including digital signage, retail signage, medical imaging, electronic gaming machines, media storage, and communications and networking.
“The platform offers a strong value proposition for this next generation of high-performance, low-power embedded designs.”
The new AMD Embedded R-Series SOCs offer 22 percent improved GPU performance when compared to the 2nd Generation AMD Embedded R-Series APU2 and a 58 percent advantage against the Intel Broadwell Core i7 when running graphics-intensive benchmarks.
AMD released some of the specs for its integrated AMD Radeon graphics including:
Up to eight compute units4 and two rendering blocks
GPU clock speeds up to 800MHz resulting in 819 GFLOPS
•DirectX 12 support
Fully HSA Enabled
The AMD Embedded R-Series SOC was architected with embedded customers in mind and includes features such as industrial temperature support, dual-channel DDR3 or DDR4 support with ECC (Error Correction Code), Secure Boot, and a broad range of processor options.
It has a configurable thermal design power (cTDP) allows designers to adjust the TDPs from 12W to 35W in 1W increments for greater flexibility.
The SOC also has a 35 percent reduced footprint when compared to the 2nd Generation AMD Embedded R-Series APU, making it an excellent choice for small form factor applications.
AMD said that the range is the first embedded processor with dual-channel 64-bit DDR4 or DDR3 with Error-Correction Code (ECC), with speeds up to DDR4-2400 and DDR3-2133, and support for 1.2V DDR4 and 1.5V/1.35V DDR3.
Its dedicated AMD Secure Processor supports secure boot with AMD Hardware Validated Boot (HVB) and initiates trusted boot environment before starting x86 cores
It has a high-performance Integrated FCH featuring PCIe Gen3 USB3.0, SATA3, SD, GPIO, SPI, I2S, I2C, and UART
The AMD Embedded R-Series SOC provides industry-leading ten-year longevity of supply. The processors support Microsoft Windows 7, Windows Embedded 7 and 8 Standard, Windows 8.1, Windows 10, and AMD’s all-open Linux driver including Mentor Embedded Linux from Mentor Graphics and their Sourcery CodeBench IDE development tools.
It will be interesting to see if AMD can make up the ground it has lost on PCs and higher ticket items. Most of the company still appears to be in a holding pattern until Zen arrives.
Courtesy-http://www.thegurureview.net/computing-category/will-amds-newest-soc-save-the-company.html
Is AMD Losing Top Scientist To nVidia?
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AMD is reeling after the high profile exit of one its top CPU brains Phil to rival Nvidia.
The outfit has been going through hell lately. Last month AMD ace CPU architect Jim Keller stepped away from the company after completing his work on Zen.
Rogers was one of AMD’s high-ranking technology and engineering corporate fellows, and been responsible for helping to develop the software ecosystem behind AMD’s heterogeneous computing products and the Heterogeneous System Architecture.
He was a public figure for AMD and active on the software development and evangelism side, frequently presenting the latest HSA tech and announcements for AMD at keynotes and conferences.
While he is not the only person working on the software side of HSA at AMD, Rogers’ role in its development is important. Rogers was a major contributor to the HSA Foundation, helping to initially found it in 2012. He served as the Foundation’s president until he left AMD.
It seems his defection was kept secret, and took place sometime this quarter and did not manage to leak.
According to his LinkedIn profile Phil Rogers is now Nvidia’s “Chief Software Architect – Compute Server” which is similar to what he was doing over at AMD. Nvidia is not a member of the HSA Foundation, but they are currently gearing up for the launch of the Pascal GPU family, which has some features that overlap well with Phil Rogers’ expertise.
Pascal’s NVLink CPU & GPU interconnect would allow tightly coupled heterogonous computing similar to what AMD has been working on. It makes a fair bit of sense for Nvidia to bring over a heterogeneous compute specialist makes a great deal of sense.
Rogers’ departure from AMD will have to be mentioned on the earnings call on the 15th. AMD’s Gregory Stoner will probably replace him. Stoner is AMD’s current Senior Director of Compute Solutions Technology and long-time Vice President of the HSA Foundation.
Source-http://www.thegurureview.net/computing-category/is-amd-losing-top-scientist-to-nvidia.html
AMD Increases FM2+ Lineup
AMD will expand its socket FM2+ chip lineup with three new parts – the A10-7890K and A8-7690K APUs, and the Athlon X4 880K CPU.
The new parts showed up on the compatibility list of socket FM2+ motherboards by BIOSTAR and it is not clear when they will be in the shops.
The architecture mentioned is “Kaveri,” but the silicon could be “Godavari” which is a Kaveri refresh.
The top of the range will be the A10-7890K, which has CPU clock speeds of 4.10 GHz out of the box. We do not know what the TurboCore frequency will be, but the current A10-7870K offers 3.90 GHz with 4.10 GHz TurboCore. The A8-7690K has a CPU clocks of 3.70 GHz. We are not sure what the iGPU clock speeds of the two chips.
The Athlon X4 880K is the most interesting. It has 4.00 GHz CPU clocks. The Athlon X4 FM2+ series lack integrated graphics that means that they are good for those who will buy discrete GPUs, on the FM2+ platform.
All three chips offer unlocked base-clock multipliers, enabling CPU overclocking.
Source-http://www.thegurureview.net/computing-category/amd-increases-fm2-lineup.html
Both AMD And nVidia Preparing For 14nm
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AMD and Nvidia both appear to be certain to get their “14 nm” out next year.
According to TweakTown Nvidia is apparently dotting the “I” and working out where to put in the semi-colons for its Pascal GPU using TSMC’s 16nm FinFet node. AMD rumored has been wining and dining its old chums at GlobalFoundries to use its 14nm process for its Greenland GPU.
Although these sound like different technologies the “14nm and 16nm” is difference how you measure a transistor. The outcome of both 14 and 16 should be a fairly same sized transistor with similar power features. TSMC calls its process 16nm FinFet, while Samsung and GloFo insist on calling it 14nm FinFet.
The dark satanic rumor mill suggests that the Greenland GPU, which has new Arctic Islands family micro-architecture, will have HBM2 memory. There will be up to 32GB of memory available for enthusiast and professional users. Consumer-oriented cards will have eight to 16GB of HBM2 memory. It will also have a new ISA (instruction set architecture).
It makes sense, AMD moved to HBM with its Fury line this year. Nvidia is expected to follow suit in 2016 with cards offering up to 32GB HBM2 as well.
Both Nvidia and AMD are drawn to FinFET which offers 90 percent more density than 28nm. Both will boost the transistors on offer with their next-generation GPUs, with 17 to 18 billion transistors currently being rumored.
Source- http://www.thegurureview.net/computing-category/are-both-amd-and-nvidia-readying-to-release-a-14nm-gpu.html
AMD’s Quantum Has Intel Inside
AMD’s Project Quantum PC system, with graphics powered by two of the new Fiji GPUs may have got the pundits moist but it has been discovered that the beast has Intel inside
KitGuru confirmed that the powerful tiny system, as shown at AMD’s own event, was based upon an Asrock Z97E-ITX/ac motherboard with an Intel Core i7-4790K ‘Devil’s Canyon’ processor.
Now AMD has made a statement to explain why it chose to employ a CPU from one of its competitor in what is a flagship pioneering gaming PC.
It told Tom’s Hardware that users wanted the Devil’s Canyon chip in the Project Quantum machine.
Customers “want to pick and choose the balance of components that they want,” and the machine shown off at the E3 was considered to be the height of tech sexiness right now.
AMD said Quantum PCs will feature both AMD and Intel CPUs to address the entire market, but did you see that nice Radeon Fury… think about that right now.
IT is going to be ages before we see the first Project Quantum PCs will be released and the CPU options might change. We would have thought that AMD might want to put its FinFET process ZEN CPUs in Project Quantum with up to 16 cores and 32 threads. We will not see that until next year.
Will Intel Challenge nVidia In The GPU Space?
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Intel has released details of its next -generation Xeon Phi processor and it is starting to look like Intel is gunning for a chunk of Nvidia’s GPU market.
According to a briefing from Avinash Sodani, Knights Landing Chief Architect at Intel, a product update by Hugo Saleh, Marketing Director of Intel’s Technical Computing Group, an interactive technical Q&A and a lab demo of a Knights Landing system running on an Intel reference-design system, Nvidia could be Intel’s target.
Knights Landing and prior Phi products are leagues apart and more flexible for a wider range of uses. Unlike more specialized processors, Intel describes Knights Landing as taking a “holistic approach” to new breakthrough applications.
The current generation Phi design, which operates as a coprocessor, Knights Landing incorporates x86 cores and can directly boot and run standard operating systems and application code without recompilation.
The test system had socketed CPU and memory modules was running a stock Linux distribution. A modified version of the Atom Silvermont x86 cores formed a Knights Landing ’tile’ which was the chip’s basic design unit consisting of dual x86 and vector execution units alongside cache memory and intra-tile mesh communication circuitry.
Each multi-chip package includes a processor with 30 or more tiles and eight high-speed memory chips.
Intel said the on-package memory, totaling 16GB, is made by Micron with custom I/O circuitry and might be a variant of Micron’s announced, but not yet shipping Hybrid Memory Cube.
The high-speed memory is similar to the DDR5 devices used on GPUs like Nvidia’s Tesla.
It looks like Intel saw that Nvidia was making great leaps into the high performance arena with its GPU and thought “I’ll be having some of that.”
The internals of a GPU and Xeon Phi are different, but share common ideas.
Nvidia has a big head start. It has already announced the price and availability of a Titan X development box designed for researchers exploring GPU applications to deep learning. Intel has not done that yet for Knights Landing systems.
But Phi is also a hybrid that includes dozens of full-fledged 64-bit x86 cores. This could make it better at some parallelizable application categories that use vector calculations.
Can MediaTek Take On Qualcomm?
While Qualcomm’s 20nm Snapdragon 810 SoC might be the star of upcoming flagship smartphones, it appears that MediaTek has its own horse for the race, the octa-core MT6795.
Spotted by GforGames site, in a GeekBench test results and running inside an unknown smartphone, MediaTek’s MT6795 managed to score 886 points in the single-core test and 4536 points in the multi-core test. These results were enough to put it neck to neck with the mighty Qualcomm Snapdragon 810 SoC tested in the LG G Flex 2, which scored 1144 points in the single-core and 4345 in the multi-core test. While it did outrun the MT6795 in the single-core test, the multi-core test was clearly not kind on the Snapdragon 810.
The unknown device was running on Android Lollipop OS and packed 3GB of RAM, which might gave the MT6795 an edge over the LG G Flex 2.
MediaTek’s octa-core MT6795 was announced last year and while we are yet to see some of the first design wins, recent rumors suggested that it could be powering Meizu’s MX5, HTC’s Desire A55 and some other high-end smartphones. The MediaTek MT6795 is a 64-bit octa-core SoC clocked at up to 2.2GHz, with four Cortex-A57 cores and four Cortex-A53 cores. It packs PowerVR G6200 graphics, supports LPDDR3 memory and can handle 2K displays at up to 120Hz.
As we are just a few days from Mobile World Congress (MWC) 2015 which will kick off in Barcelona on March 2nd, we are quite sure that we will see more info as well as more benchmarks as a single benchmark running on an unknown smartphone might not be the best representation of performance, it does show that MediaTek certainly has a good chip and can compete with Qualcomm and Samsung.
AMD’s Fiji GPU Goes High Bandwidth
New evidence coming from two LinkedIn profiles of AMD employees suggest that AMD’s upcoming Radeon R9 380X graphics card which is expected to be based on the Fiji GPU will actually use High-Bandwidth Memory.
Spotted by a member of 3D Center forums, the two LinkedIn profiles mention both the R9 380X by name as well as describe it as the world’s firts 300W 2.5D discrete GPU SoC using stacked die High-Bandwidth Memory and silicon interposer. While the source of the leak is quite strange, these are more reliable than just rumors.
The first in line is the profile of Ilana Shternshain, an ASIC Physical Design Engineer, which has been behind the Playstation 4 SoC, Radeon R9 290X and R9 380X, which is described as the “largest in ‘King of the hill’ line of products.”
The second LinkedIn profile is the one from AMD’s System Architect Manager, Linglan Zhang, which was involved in developing “the world’s first 300W 2.5D discrete GPU SOC using stacked die High Bandwidth Memory and silicon interposer.”
Earlier rumors suggest that AMD might launch the new graphics cards early this year as the company is under heavy pressure from Nvidia’s recently released, as well as the upcoming, Maxwell-based graphics cards.
Is AMD’s FreeSync Coming In 2015?
Last week in San Francisco we spent some time with Richard Huddy, AMD’s Chief gaming scientist to get a glimpse what is going on in the world of AMD graphics. Of course we touched on Mantle, AMD’s future in graphics and FreeSync, the company’s alternative to Nvidia G-Sync.
Now a week later AMD is ready to announce that MStar, Novatek and Realtek scaler manufactures are getting ready with DisplayPort Adaptive-Sync and AMD’s Project FreeSync. They should be done by end of the year with monitors shipping in Q1 2015.
FreeSync will prevent frame tearing as the graphic card often pushes more (or fewer) frames than the monitor can draw and this lack of synchronisation creates quite annoying frame tears.
FreeSync will allow Radeon gamers to synchronize display refresh rates and GPU frame rates to enable tearing and stutter-free gaming along with low input latency. We still do not have the specs or names of the new monitors, but we can confirm that they will use robust DisplayPort receivers from MStar, Novatek and Realtek in 144Hz panels with QHD 2560×1440 and UHD 3840×2160 panels up to 60 Hz.
It took Nvidia quite some time to get G-Sync monitors off the ground and we expect to see the first 4K G-Sync monitors shipping shortly, while QHD 2560×1440 ones have been available for a few months. Since these are gaming monitors with a 144Hz refresh rate they don’t come cheap, but they are nice to look at and should accompany a high end graphic card such as Geforce GTX 980 or a few of them.
Radeon lovers will get FreeSync, but monitors will take a bit more time since AMD promises Project FreeSync-ready monitors through a media review program in 1Q 15 and doesn’t actually tells us much about retail / etail availability.
FreeSync Only For New AMD Chips
AMD has explained that its new FreeSync technology will only work in new silicon.
FreeSync is AMD’s initiative to enable variable-refresh display technology for smoother in-game animation and was supposed to give Nvidia’s G-Sync technology a good kicking.
G-Sync has already resulted in some top production gaming monitors like the Asus ROG Swift PG278Q.
However AMD said that the only the newest GPU silicon from AMD will support FreeSync displays. Specifically, the Hawaii GPU that drives the Radeon R9 290 and 290X will be compatible with FreeSync monitors, as will the Tonga GPU in the Radeon R9 285.
The Bonaire chip that powers the Radeon R7 260X and HD 7790 cards could support FreeSync, but that is not certain yet.
Now that would be OK if the current Radeon lineup is populated by a mix of newer and older GPU technology. What AMD is saying is that there are some brand-new graphics cards selling today that will not support FreeSync monitors when they arrive.
The list of products that won’t work with FreeSync includes anything based on the older revision of the GCN architecture used in chips like Tahiti and Pitcairn.
So if you have splashed out on the the Radeon R9 280, 280X, 270, and 270X hoping that it will be FreeSync-capable you will be out of luck. Nor will any older Radeons in the HD 7000 and 8000 series.
Nvidia’s G-Sync works with GeForce graphics cards based on the Kepler architecture, which include a broad swath of current and past products dating back to the GeForce GTX 600 series.