The new Mali-470 GPU has half the power consumption and two times the energy efficiency of the Mali-400, and is designed for next-generation wearables and IoT devices such as industrial control panels and healthcare monitors that rely on low-cost and low-power chips.

The Mali-470 supports OpenGL ES 2.0, used by Android and Android Wear, hinting that the GPU could also find its way into low-cost smartphones. If not, ARM promises that the chip will bring smartphone-quality visuals to wearable and IoT devices, supporting screen resolutions of up to 640×640 on single-core devices, and higher resolutions for multi-core configurations.

ARM envisions the new GPU paired with its efficient Cortex-A7 or A53 CPU designs for a low-power SoC.

“ARM scrutinises every milliwatt across the entire SoC to enable OEMs to optimize energy efficiency and open up new opportunities,” said Mark Dickinson, vice president and general manager of ARM’s multimedia processing group.

“Tuning efficiency is particularly relevant for devices requiring sophisticated graphics on a low power budget such as wearables, entry-level smartphones and IoT devices. The Mali-470 has been designed to meet this demand by enabling a highly capable user interface while being extremely energy efficient.”

ARM expects the first SoCs using the GPU be ready by the end of 2016, meaning that the chip will start showing up in devices the following year.

The launch of the Mali-470 GPU comes just hours after ARM announced plans to pick up the product portfolio and other business assets of Carbon Design Systems, a supplier of cycle-accurate virtual prototyping solutions.

The deal will see Carbon’s staff transfer to ARM, where the chip firm will make use of the Massachusetts-based outfit’s expertise in virtual prototypes. This will enable ARM to iron out any bugs and make improvements to chips before they move to foundries for production.

ARM also said that Carbon will help the firm enhance its capability in SoC architectural exploration, system analysis and software bring-up.

Courtesy-TheInq

Chief executive Lisa Su admitted that ARM-based server chips have experienced slower-than-expected reception from the owners of data centres and server farms.

AMD delayed its own ARM-based Opteron microprocessor, code-named Seattle, until the fourth quarter of this year. ARM was having a harder time proving itself to the multibillion-dollar market for high-end server chips.

An engineering sample of AMD’s long awaited 8 core server SOC code named “Hierofalcon” has been spotted and tested and according to WCCTech it looked pretty good. Itis based around 8 ARM-64bit A57 cores running at 2.0Ghz. And although Hierofalcon maxes out at frugal TDP of 30W.

So even the promising reviews aren’t enough for AMD to be optimistic about the ARM based gear.

Su said in an analyst conference call that the company expects to see “modest production shipments” of Seattle in the fourth quarter. Meanwhile, AMD’s Intel-compatible “x86″ server chips will be the company’s mainstay product offering for data centres.

She said that AMD was continuing its ARM efforts and is seeing them as a longer term bet.

Source-http://www.thegurureview.net/computing-category/amds-bet-on-arm-does-not-appear-to-be-helping.html

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

According to EETimes Paul Boudre, who claimed that SOI is already being used by Apple and Intel even though neither company is broadcasting it. SOI appears to be on track to major market penetration even while the rest of the industry is talking FinFETs.

GlobalFoundries general manager Rutger Wijburg told the SEMICON Europa 2015 that his outfit’s 22-nanometer “22FDX” SOI platform delivers FinFET-like performance but at a much lower power point and at a cost comparable to 28-nanometer planar technologies.

The 300-millimeter $250 million FD-SOI foundry here in the “Silicon Saxony” area of Germany, builds on 20 years of GlobalFoundries’ investments in Europe’s largest semiconductor fabs.

GlobalFoundries said it will extend Moore’s Law by using fully-deleted silicon-on-insulator (FD-SOI) transistors on wafers bought from Soitec.

Many had thought that if GloFlo’s FD-SOI gamble paid off then it would be a while before FinFET would have a serious rival. But Boudre’s claims suggests that SOI is already being used.

Customers like Intel and OEMs supplying fully-deleted silicon-on-insulator (FD-SOI) RF transistors to Apple proves that SOI and Soitec are past the cusp of the growth curve, destined to ramp up exponentially.

The problem for Soitec is no one is really talking about it. Chipzilla is committed to the FinFET, because it is higher performance than FD-SOI, even though it is higher power too.
Boudre said that it was supplying SOI wafers to Intel for other applications that don’t require high-performance. For instance, our wafers are very good for their silicon photonics projects.

Apple is already using SOI for several radio frequency (RF) chips in their front-ends, because they use 20-times less power. The iPhone is still using gallium arsenide (GaAs) for its power amplifier (PA) because it needs the high-power device for good connections, but for other RF front-end chips, and in fact for all the chips that they want to keep “always on,” the lower power consumption of FD-SOI is pushing the smartphone makers to Soitec, Boudre said.

SOI wafers cost three-times as much as bulk silicon but the cost per die is less because of the simplified processing steps including fewer masks.

Normally GPS chips run on 0.8 volts and consume over 20 milliamps, so they must be turned off most of the time. But when they are made with SOI wafers, they can run on 0.4 volts and consume only 1 milliamp. The mobile device to leave them on all the time and new and more accurate location sensing and new kinds of location-based applications can be developed.

What is amusing then is that Intel’s reason for going with FinFETs was that SOI wafers were too expensive but it did find a use for it.

GlobalFoundries’ Saxony fab will offer four varieties of its 22FDX process.

FDX-ulp for the mainstream and low-cost smartphone market. This will use body-biasing to beat FinFETs on power, but equal them in performance.

FDX-uhp for networking applications using analogue integration to match FinFETs while minimizing energy consumption

FDX-ull for ultra-low power required by wearables and Internet of Things applications. This will have a 1 picoamp per micron leakage

DDX-rfa for radio frequency (RF) analogue applications delivering 50 percent lower power and reduced system costs for LTE-A cellular transceivers, high-order multiple-input/multiple-output (MIMO) WiFi combo chips and millimeter wave radar.

Courtesy-http://www.thegurureview.net/computing-category/ibm-and-intel-going-goflo-soi.html

Actually AMD is pretty cheap right now and if it was not for the pesky arrangement that prevents AMD’s buyer getting its x86 technology then it would have been snapped up a while ago. But with, or without AMD, Samsung could still make a good fist of chipmaking if it put its mind to it. At the moment its chipmaking efforts are one of the better things on its balance sheet.

Its high-margin semiconductor business is more than making up for the shortfall in smartphones. Selling chips to rivals would be more lucrative if they were not spinning their own mobile business. The products it have are worth $11.7 billion this year, more than half the company’s total.

Growing demand for chips and thin-film displays is probably the main reason that Samsung now expects operating profit to have reached $6.3 billion. After applying Samsung’s 16 percent corporate tax rate, its chip division is likely to bring in net income of slightly less than $10 billion.

To put this figure into perspective Intel expects to earn $10.5 billion in this year. Samsung is also sitting on a $48 billion net cash pile. Samsung could see its handset and consumer electronics business as a sideline and just focus on bumping off Intel.

The two sides of such a war would be fascinating. Intel has its roots in the PC chip market which is still suffering while Samsung is based in the mobile chip market which is growing. Intel has had no luck crossing into the mobile market, but Samsung could start looking at server and PC chips.

AMD is still dying and unable to offer Intel any challenge but there is a large market for those PC users who do not want to buy Intel. What Samsung should have done is use its huge cash pile to buy its way into the PC market. It might have done so with the IBM tech which went to Lenovo. It is still not out of the running on that front. Lenovo might be happy to sell IBM tech to Samsung.

Another scenario is that it might try to buy an x86 licence from Intel. With AMD dying, Intel is sitting on a huge monopoly for PC technology. It is only a matter of time before an anti-trust suit appears. Intel might think it is worthwhile to get a reliable rival to stop those allegations taking place. Samsung would be a dangerous rival, but it would take a while before it got itself established. Intel might do well to consider it. Of course Samsung might buy AMD which could sweeten that deal for Intel.

Samsung could try adapting its mobile chip technology for the PC/server market – it has the money to do it. Then it has a huge job marketing itself as the new Intel.

Source-http://www.thegurureview.net/computing-category/can-samsung-compete-with-intel-in-the-x86-chip-space.html

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

The cunning plan is to install electric generating equipment at its factories or even building its own power plant.

Apparently, the company’s electricity bill will go up by 50 per cent over the next ten years as it moves to more-advanced technologies.

Taiwan is already facing power shortage problems and TSMC is worried that its plans could be stuffed up.

TSMC has asked Taiwan’s Ministry of Economic Affairs (MOEA) and government-owned Taiwan Power Company (Taipower) about the feasibility of building its own power generators and related regulatory matters.

According to Digitimes companies can set up power generating equipment for use at their own factory sites, but the law has to be revised to allow TSMC to build its own power plant.

TSMC previously pointed out that it does not necessarily need nuclear power unless there is an alternative. We really hope that quote does not mean that TSMC is considering going nuclear.

Source-http://www.thegurureview.net/computing-category/is-electricity-in-tsmcs-future.html

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