Meizu is expected to be one of the first companies to use the X25. Last year it was also the first to use MTK 6795T for its Meizu MX5 phone. In that case the “T” suffix stood for Turbo. This phone was 200 MHz faster than the standard Helio X10 “non T” version.

In 2016 is that MediaTek decided to use the new Helio X25 name because of a commercial arrangement. MediaTek didn’t mention any of the partners, but confirmed that the CPU and GPU will be faster. They did not mention specific clock speeds. Below is a diagram of the Helio X20, and we assume that the first “eXtreme performance” cluster will get a frequency boost, as well as the GPU.

The Helio X25 will not have any architectural changes, it is just a faster version of X20, just like MTK 6795T was faster version of MTK 6795. According to the company, the Helio X25 will be available in May.

This three cluster Helio X25 SoC has real potential and should be one of the most advanced mobile solutions when it hits the market.The first leaked scores of the Helio X20 suggest great performance, but the X25 should have even better scores. There should be a dozen design wins with Helio X20/ X25 and most of them are yet to be announced. There should be a few announcements for the Helio X25 soon, but at least we do know that now there will be a even faster version of three cluster processor.

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According to Digitimes it fell to less than 30 million units in 2015 and the outfit suffering most was  AMD. The largest graphics card player Palit Microsystems, which has several brands including Palit and Galaxy, shipped 6.9-7.1 million graphics cards in 2015, down 10 per cent  on year. Asustek Computer shipped 4.5-4.7 million units in 2015, while Colorful shipped 3.9-4.1 million units, and is aiming to raise its shipments by 10 per cent  on year in 2016.

Micro-Star International (MSI) enjoyed healthy graphics card shipments at 3.45-3.55 million in 2015, up 15 per cent  on year, and EVGA, which has tight partnerships with Nvidia, also saw a significant shipment growth, while Gigabyte suffered from a slight drop on year. Sapphire and PowerColor suffered dramatic drops in shipments in 2015.

There are fears that several of the smaller GPU makers could be forced out of the market after AMD gets its act together with the arrival of Zen and Nvidia’s next-generation GPU architectures launch later in 2016.

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The SDK gives developers access to advanced VR features, according to Qualcomm, allowing them to simplify development and attain improved performance and power efficiency with Qualcomm’s Snapdragon 820 processor, found in Android smartphones such as the Galaxy S7 and tipped to feature in upcoming VR headsets.

In terms of features, the development kit offers tools such as digital signal processing (DSP) sensor fusion, which allows devs to use the “full breadth” of technologies built into the Snapdragon 820 chip to create more responsive and immersive experiences.

It will help developers combine high-frequency inertial data from gyroscopes and accelerometers, and there’s what the company calls “predictive head position processing” based on its Hexagon DSP, while Qualcomm’s Symphony System Manager makes easier access to power and performance management for more stable frame rates in VR applications running on less-powerful devices.

Fast motion to photon will offer single buffer rendering to reduce latency by up to 50 percent, while stereoscopic rendering with lens correction offers support for 3D binocular vision with color correction and barrel distortion for improved visual quality of graphics and video, enhancing the overall VR experience.

Stereoscopic rendering with lens correction supports 3D binocular vision with color correction and barrel distortion for improved visual quality of graphics and video, enhancing the overall VR experience.

Rounding off the features is VR layering, which improves overlays in a virtual world to reduce distortion.

David Durnil, senior director of engineering at Qualcomm, said: “We’re providing advanced tools and technologies to help developers significantly improve the virtual reality experience for applications like games, 360 degree VR videos and a variety of interactive education and entertainment applications.

“VR represents a new paradigm for how we interact with the world, and we’re excited to help mobile VR developers more efficiently deliver compelling and high-quality experiences on upcoming Snapdragon 820 VR-capable Android smartphones and headsets.”

The Snapdragon VR SDK will be available to developers in the second quarter through the Qualcomm Developer Network.

The launch of Qualcomm’s VR SDK comes just moments after AMD also entered the VR arena with the launch of the Sulon Q, a VR-ready wearable Windows 10 PC.

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The plan is not official yet but appears to have been leaked to the Wall Street Journal. Achin Bhowmik, who oversees RealSense as vice president and general manager of Intel’s perceptual computing group, declined to discuss unannounced development efforts.

But he said Intel has a tradition of creating prototypes for products like laptop computers to help persuade customers to use its components. We have to build the entire experience ourselves before we can convince the ecosystem,” Bhowmik said.

Intel appears to be working on an augmented-reality headset when it teamed up with IonVR to to work on an augmented-reality headset that could work with a variety of operating systems, including Android and iOS. Naturally, it had a front-facing RealSense camera.

RealSense depth camera has been in development for several years and was shown as a viable product technology at the Consumer Electronics Show in 2014. Since then, nothing has happened and Microsoft’s Kinect sensor technology for use with Windows Hello in the Surface Pro 4 and Surface Book knocked it aside.

Intel’s biggest issue is that it is talking about making a consumer product which is something that it never got the hang of.

RealSense technology is really good at translating real-world objects into virtual space. In fact a lot better than the HoloLens because it can scan the user’s hands and translate them into virtual objects that can manipulate other virtual objects.

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Revealed back during the 2015 Flash Memory Summit in August last year, the now available Samsung PM1633a enterprise SSD series is based on a standard 2.5-inch form factor and features a 12Gbps Serial Attached SCSI (SAS) interface. It also uses Samsung new controller as well as Samsung’s own 3rd generation 256Gb 48-layer TLC V-NAND.

As noted, the Samsung PM1633a lineup is based on Samsung’s 256Gb V-NAND flash chips. The 256Gb dies are stacked in 16 layers to form a single 512GB package and by adding up a total of 32 NAND packages, you get the 15.36TB model. According to Samsung, the 3rd generation 256Gb V-NAND will provide both significant performance as well as reliability improvements compared to the PM1633 drive which used 2nd generation 32-layer 128Gb V-NAND flash.

The controller has also been upgraded to concurrently access large amounts of high-density NAND flash and the PM1633a 15.36TB model comes with no less than 16GB of cache.

When it comes to performance, the Samsung PM1633a provides sequential read and write performance of up to 1,200MB/s while random 4K performance is set at up to 200,000 IOPS for read and up to 32,000 IOPS for write. The new Samsung PM1633a enterprise SSD also offers high high reliability date with 1DWPD (drive writes per day), adding up to 15.36TB that can be written every day without failure, which is quite important in the enterprise market.

While the 15.36TB model of the Samsung P1633a is already shipping to select enterprise customers, Samsung is also promising a wide range of capacities, including 480GB, 960GB, 1.92TB, 3.84TB and 7.68TB. According to Samsung, enterprise managers can now fit twice as many drives in a standard 19-inch 2U rack compared to a 3.5-inch storage drive.

Unfortunately, Samsung did not reveal any details regarding the price but we doubt that such high capacity and performance will have a low price tag.

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The new Toshiba SG5 SSD series will be available in 128GB, 256GB, 512GB and 1TB capacities as well as a couple of different form-factors, standard 2.5-inch and two different M.2 form-factors.

As noted, the Toshiba SG5 SSD series is based on 15nm TLC NAND with yet to be details controller and will offer sequential performance of up to 545MB/s for read and up to 388MB/s for write.

The 2.5-inch version of the Toshiba SG5 SSD series will be available in all aforementioned capacities, the M.2 2280-S2 (single side) form-factor version will be available in 128GB, 256GB and 512GB capacities and the M.2 2280-D2 (double side) version will only come in 1TB capacity.

The rest of the features are pretty standard for a consumer-grade SSD so you are looking at a power consumption 4.5W to 5.6W under load and 0.65W in idle and it includes Toshiba’s QSBC (Quadruple Swing-By Code) error correction technology.

Unfortunately, Toshiba did not unveil any details regarding the actual price of the new SG5 series SSDs but did say that it should be available sometime during this quarter.

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The advert, which was spotted by the Motley Fool has since been taken down, said the company’s 10-nanometer chip manufacturing technology would begin mass production “approximately two years” from the posting date.

Intel has said that the advert was wrong and confirmed that its “first 10-nanometer product is planned for the second half of 2017.”

It is not expected that Intel will roll out server chips in 2017. At the moment the plan appears to be introducing its second-generation 14-nanometer server chip family in early to mid-2017. But instead Intel will be trying to get its process ramped at high yields experimenting on the PC market so that 10-nanometer server processors will be ready for the first half of 2018.

This follows Intel’s traditional pattern of a having a few parts released as it experiments with the new tech. This is what happened in the first year of Intel’s 14-nanometer availability.

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According to the Gizchina website, the company the three new SoCs carry the catchy titles of MT6739, MT6750 and MT6750T. .

The MT6739 will probably replace the MT6735. Both have quad A53 cores but it will mean that the MT6739 will get a Cat 6 upgrade from Cat 4. The MT6739 supports speeds of up to 1.5GHz, 512 KB L2 cache, 1280×720 at 60fps resolution, and video decode to 1080p 30fps with H.264 and 13 megapixel camera. This means it is an entry level SoC for phones that might fit into the $100 price range.

The MT6750 and MT6750T look like twins, only the T version supports full HD 1920×1080 displays. The MT6750 has eight cores, four A53 clocked at 1.5Ghz and four A53 clocked at 1.0GHz and is manufactured on TSMC’s new 28nm High Performance Mobile Computing manufacturing mode. This is the same manufacturing process MediaTek is using for the Helio P10 SoC. The new process allows lower leakage and better overall transistor performance at lower voltage.

The MT6750 SoC supports single channel LPDDR3 666MHz and eMCP up to 4GB. The SoC supports eMMC 5.1, 16 megapixel camera, 1080p 30 fps with both H.264 and H.265 decoding. It comes with an upgraded ARM Mali T860 MP2 GPU with 350 MHz and display support of 1280×720 HD720 ready with 60 FPS. This means the biggest upgrade is the Cat 6 upgrade and it makes sense – most of European and American networks now are demanding a Cat 6 or higher modem that supports carrier aggregation.

This new SOc looks like a slowed down version of Helios P10 and should be popular for entry level Android phones.

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It is starting to look sales teams for the pair are each trying to show that they can use the technology to reduce the most electricity consumption and production costs.

In its yearly result for 2015, TSMC made an announcement that it is planning to enter mass-production system of chips produced by 16-nano FinFET Compact (FFC) process sometime during 1st quarter of this year. TSMC had finished developing 16-nano FFC process at the end of last year. During the announcement TSMC talked up the fact that its 16-nano FFC process focuses on reducing production cost more than before and implementing low electricity.

TSMC is apparently ready for mass-production of 16-nano FFC process sometime during 1st half of this year and secured Huawei’s affiliate called HiSilicon as its first customer.

HiSilicon’s Kirin 950 that is used for Huawei’s premium Smartphone called Mate 8 is produced by TSMC’s 16-nano FF process. Its A9 Chip, which is used for Apple’s iPhone 6S series, is mass-produced using the 16-nano FinFET Plus (FF+) process that was announced in early 2015. By adding FFC process, TSMC now has three 16-nano processors in action.

Samsung is not far behind it has mass-produced Gen.2 14-nano FinFET using a process called LPP (Low Power Plus). This has 15 per cent lower electricity consumption compared to Gen.1 14-nano process called LPE (Low Power Early).

Samsung Electronics’ 14-nano LPP process was seen in the Exynos 8 OCTA series that is used for Galaxy S7 and Qualcomm’s Snapdragon 820. But Samsung Electronics is also preparing for Gen.3 14-nano FinFET process.

Vice-President Bae Young-chang of Samsung’s LSI Business Department’s Strategy Marketing Team said it will use a process similar to the Gen.2 14-nano process.

Both Samsung and TSMC might have a few problems. It is not clear what the yields of these processes are and this might increase the production costs.

Even if Samsung Electronics and TSMC finish developing 10-nano process at the end of this year and enter mass-production system next year, but they will also have to upgrade their current 14 and 16-nano processes to make them more economic.

Even if 10-nano process is commercialized, there still will be many fabless businesses that will use 14 and 16-nano processes because they are cheaper. While we might see a few flagship phones using the higher priced chips, it might be that we will not see 10nm in the majority of phones for years.

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Guru 3D found a slide which suggest that Chipzilla will not be sticking to its traditional “tick-tock model.” To be fair Intel has been using the 14nm node for two generations so far – Broadwell and Skylake. Kaby Lake processor architecture that is due later this year, will also use 14nm .

The slide tells us pretty much what we expected. The first processor family to be manufactured on a 10nm node will be Cannonlake, expected to launch in the year 2017. The following year, Intel will reportedly launch Icelake processors, again using the same 10nm node. Icelake will be succeeded by Tigerlake in 2019, the third generation of Intel processors using a 10nm silicon fab process. The codename for Tigerlake’s successor is unknown.  When it comes out in 2020 it will use 5nm.

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