Nexus 6P vs iPhone 6S Plus
Buy Nexus 6P
Buy iPhone 6S Plus
Google decided to take its Nexus smartphone line down a new path with the Nexus 6, a premium device that unfortunately featured a price tag to match its quality. Continuing on that path, the Nexus 6P is the most premium Nexus device yet, and comes at a lower price tag than its predecessor.
In the other camp is the latest large display smartphone from Apple. Even though this is an “S” year for the series, this device strays for the standard formula by bringing to the table some new and useful additions and upgrades. How does these large display flagships compare? We find out, in this comprehensive look at the Nexus 6P vs iPhone 6S Plus!
Design
As far as the design is concerned, its clear that metal is the order of the day with both smartphones.
The iPhone 6S Plus, as the name suggests, is the larger of Apple’s two new smartphones of this year, and given that it is an “S” iteration, it’s not surprising that the design language of its predecessor has been retained, bringing back the metal unibody construction seen with last year’s iPhone 6. Rounded sides and corners keep the phone feeling really smooth in the hand, maybe too much so however, resulting in a somewhat slippery handling experience, which isn’t great news for a device with a large display.
2.5D glass adorns the front, with the signature home button the only real blemish to be seen here, once again featuring an embedded fingerprint scanner. The sides retain the classic layout as well, with the volume rocker under the silence toggle, and at the bottom is the Lightning port, flanked by the single speaker and the headphone jack. On the back, the only clear lines on the phone outline a rectangle in the middle, and there is also the protruding camera at the top left corner.
On the other hand, the Nexus 6P features a big departure from the way Nexus smartphones have been constructed in the past. While Nexus manufacturers have tended to borrow design cues from their own flagship offerings, things are a little different this year. With Huawei at the helm, there has been a distinct re-imagining of what a premium Nexus smartphone should be.
Metal encompasses a more boxy design, with the flat sides contributing to the handling experience. The volume rocker and power button are all placed on the right side, with the latter placed to be within easy reach and featuring a textured pattern to make it easy to locate by feel. The front face of the device is dominated by the large display, and there is not much else to be found here, save for the front-facing camera, and the dual speaker setup. The headphone jack is up top, and at the bottom is the USB Type-C port, that brings a new standard to the world of Android.
On the back is where the unique design element is to be found, with the black bar up top that houses the camera package. It might look a little odd, but it certainly grows on you, and looks much better than what the initial press renders may have suggested. If nothing else, it serves the purpose of keeping the camera physically protected. On the back is also where you will find the new fingerprint reader, powered by Nexus Imprint, in the middle, placed within comfortable reach of your index finger.
Deciding between these two designs is obviously a matter of personal choice, but the choice can be pretty easy when looking at such different devices. The iPhone 6S Plus feels like the sleeker of the two, but the Nexus 6P takes the series to new premium heights with a sturdy feel and industrial look. While both smartphones do look great, it is worth mentioning here that while the iPhone 6S Plus is simply a much larger version of its flagship counterpart, the Nexus 6P stands alone, with only the plastic clad Nexus 5X as its smaller alternative.
Display
Displays on these two devices brought higher resolutions than what were found in previous iterations, even if Apple still doesn’t try to match up to the standards currently set by the Android powerhouses.
The iPhone 6S Plus features a 5.5-inch IPS LCD display with a Full HD resolution, resulting in a pixel density of 401 ppi. 1080p was a development that wasn’t made available to Apple users until the arrival of the Plus line, but the company has always done a good job with their displays, regardless of their comparatively lower resolutions. Colors are nice and vivid, and the translucent effects in iOS help showcase how well the IPS display can perform. Brightness is of no concern either, even if it has to be pumped up to the highest level in daylight for optimal viewing, and while sharpness might be slightly lacking in comparison, reading text is of no issue on this Full HD screen.
1080p is a thing of the past when looking at the latest and greatest in the world of Android however, with Quad HD becoming the accepted flagship standard. The 5.7-inch AMOLED display of the Nexus 6P features a 2560 x 1440 resolution, resulting in a pixel density of 518 ppi. AMOLED is always a good choice if you’re looking for deep backs and high contrast, that really make the colors pop. The high resolution makes everything from media to text look great, with everything as sharp as ever.
The spec hungry will obviously prefer the Quad HD display, but we know that 1080p is still considered the bare standard, and performs just fine for the vast majority of people. Apple does a good job leveraging the IPS display for good quality viewing, but its Android competitor not only brings a higher resolution, but also an AMOLED construction, that allows for a very enjoyable experience of its own.
Performance
A by-the-numbers comparison is not indicative of performance capabilities here, given the two very different ecosystems these processing packages have to power, but in both cases, we are dealing with the pure version of the respective software experiences, resulting in performances that are as high as it should be.
Apple makes its own processing packages, and the iPhone 6S Plus packs a dual-core Apple A9 processor, clocked at 1.84 GHz and backed by the PowerVR GT7600 GPU and 2 GB of RAM. Android fans will consider this really paltry compared to what dominates in the Android world, but for iOS, this processing package works just fine. Moving in and out of screens and applications is smooth and easy, all applications thus far have run without incident, and the gaming experience remained very good during our testing as well.
On the other hand, the Nexus 6P comes with an octa-core Qualcomm Snapdragon 810 processor, clocked at 2 GHz, and backed by the Adreno 430 GPU and 3 GB of RAM. This processing package is the current flagship standard, and with the stock software experience to be found on-board, performance is definitely as good as ever. There were no problems getting just about anything done on the Nexus 6P, and gaming has been a wonderful experience as well, further enhanced by the availability of a high resolution display and great sounding front-facing speakers.
All said and done, regardless of which device you may pick, you will certainly not have a difficult time getting things done with these smartphones.
Hardware
Hardware is one area in which the separation between Android and Apple smartphones has gradually been decreasing, with similar features being added (or omitted) in both cases.
The iPhone 6S Plus brings back the fingerprint reader from previous generations, but in an even faster iteration, so much so that the finger used to press the home button doesn’t even need to rest there to unlock the device. Just the actual press of the button itself is more than enough for the sensor to register a fingerprint. Though there is only a single bottom-mounted speaker to be had, the sound coming from it is actually fairly robust, even if not particularly loud.
The Lightning port, when it was first introduced, was a pretty big change for plenty of Apple users, and this is a growing pain that Android users will now have to contend with when it comes to USB Type-C. Finally, in battery, the 2,750 mAh unit of the iPhone 6S Plus is large enough to provide only about a day and half in total with low overall usage, though the standby time is impressive on the Apple phones. Also worth mentioning here is the fact that fast charging has yet to come to the Apple world.
A new hardware addition with the Nexus 6P is the fingerprint reader that is mounted on the back, and is the main point of reference for the new Nexus imprint portion of Android 6.0 Marshmallow. The scanner does work very well, even if it is a little slower than Apple’s, but an index finger on the back wakes the phone and gives you direct access to the homescreens. The Nexus 6P also goes above and beyond with the availability of dual front-facing speakers, that do a great job of bringing pretty loud, full, stereo sound to whatever you are doing, making gaming and media-consumption very fun experiences.
USB Type-C is the new standard for Android, and while it is kind of hard to remember to bring the cord along when heading out, the benefit here is the fast charging, that allows for the large 3,450 mAh battery of the Nexus 6P to fully charge in around 90 minutes. Battery life also benefits from the new Doze feature of Android 6.0 Marshmallow, allowing for standby times that now rival that of the iPhone. It does require the phone to be sitting flat without any sensors being triggered at all, but the bottom line is that, with typical moderate usage, users could get the device to last for as long as 2 days fairly easily.
Simply put, the Nexus 6P is the phone that will appeal to the power user, with its front-facing speakers, reliable fast charging, and big battery that can go the distance. Plenty of users have been able to get power usage of the iPhones, but without these extras, it falls just short, and will definitely need a tether faster than its Android competitor.
Camera
Moving on to the camera, the iPhone 6S Plus features an upgraded 12 MP rear camera with a f/2.2 aperture, along with a 5 MP front-facing unit. The main addition with the rear camera is the ability to record 4K video, which puts it on par with plenty of current generation Android smartphone cameras. Optical image stabilization is also something the iPhone can boast over the Nexus 6P, which surprisingly left it out.
Taking selfies gets an extra feature with a screen-powered flash, and while this does tend to wash out subjects no matter what kind of picture it is, users can at least get some light in really dark situations. As far as the camera application is concerned, the features are fairly robust, but without much manual control. Swiping on the view finder brings up the photo, video, timelapse, and hyperlapse options, but the main focus here is on offering a good default camera interface, and it works pretty well in that regard.
On the other hand, the Nexus 6P also comes with a 12 MP rear camera, which – as Google made sure to tout – has a bigger sensor size than most other Android smartphones, but also the iPhone 6S Plus. OIS is missing here, but the larger sensor should still be able to get in a little more light than typical. The front-facing camera is 8 MP, so pictures will be larger on the 6P than they are on the iPhone, but without a secondary light source, selfies in poorly-lit conditions will be a pain.
Nexus 6P camera samples
Google’s own camera application is also focused on being an automatic shooter, so there aren’t really manual controls to be seen here either. Other than the ability to make HDR+ automatic or not, use Lens Blur for a depth of field look, or capture a Photo Sphere, the app is pretty simplistic, and doesn’t come with too many bells and whistles.
iPhone 6S Plus camera samples
Of course, what matters the most here is the quality of the shots possible with these cameras, and in this case, the two phones are on an even playing field. The iPhone family has always been lauded for bringing good camera experiences, and that continues with the iPhone 6S Plus. OIS does a good job of getting in a little more light in poorly-lit conditions, and it does get a bit more than the Nexus. While previous Nexus devices were infamous for their average camera quality, the Nexus 6P marks new territory with a larger sensor, that, even without OIS, does a great job in photos. To that end, we actually found plenty of photos to be a toss-up in terms of detail and visuals.
Software
Finally, on the software side of things, we return to the age-old comparison of Android vs iOS, that might have admittedly been much easier to conduct only a couple of years ago.
iOS is still aesthetically about the same as its past few iterations. The homescreens contain all the installed applications, and while widgets are still unavailable, a few additions over the last couple of years have made a difference. The notification dropdown is similar to Android’s original creation, but a secondary screen can bring up a few extra shortcuts and glances at some contextual information, and a swipe up from the bottom opens the Control Center, where a number of controls and toggles are easily accessible.
Of course, the biggest addition with the iPhone 6S Plus is 3D Touch, which leverages a layer of sensors underneath the screen to sense any harder than normal presses. By doing so, shortcuts will appear from icons on the homescreens, and previews pop up in various built-in applications. This is a level of input that Apple has effectively added in, and adds a new dimension to what has been a very familiar software experience over the years. Apple’s design prowess permeates through iOS, with all the elements shown in a very smooth and pleasing way. Such is the benefit of a focused, unitary ecosystem, that anyone who gets an iPhone will get this kind of experience without fail.
That is also why the Nexus family is so important to Android lovers. If the purest software experience is what you’re looking for, the Nexus is where one will have to go to get it. Android 6.0 Marshmallow is the latest iteration of Android the way that Google wants it to be experienced, and while it is as smooth and snappy as ever, it is also a robust package in and of itself.
You can, of course, fill up your homescreen with icons, but this being Android, a variety of widgets are available. On the side is Google Now, and the notification dropdown here includes its own version of Quick Settings, so that everything you may need remains within easy reach. Marshmallow has refined some of the well-known aspects, like adding a frequently used apps line in the now vertical scrolling app drawer. App permissions bring a certain level of security to daily tasks, similar to how iOS might constantly notify users that other apps are being triggered or opened, but a whole page for deeper insight is now available too.
Google Now on Tap is an easy way to quickly do a search based on what is on the screen, though it might seem a little fickle at times. Though Material Design arrived a couple of versions ago, the overall Android experience has been refined, and made not only easier on the eyes, but also easier on workflow. Multi-tasking might be a little bare, but you won’t have any trouble with work or play on this mature operating system.
People that are already entrenched in the Android or iOS camp will have little reason to move to the other ecosystem. In the past, app support for iOS used to be more robust than on Android, but that gap is all but closed.
Specs comparison
| Moto X Style / Pure Edition | iPhone 6s Plus | |
|---|---|---|
| Display | 5.7-inch AMOLED display Quad HD resolution, 518 ppi |
5.5-inch IPS LCD display Full HD resolution, 401 ppi |
| Processor | 2 GHz octa-core Qualcomm Snapdragon 810 Adreno 430 GPU |
1.8 GHz dual-core Apple A9 PowerVR GT7600 GPU |
| RAM | 3 GB | 2 GB |
| Storage | 32/64/128 GB no expansion |
16/64/128 GB no expansion |
| Camera | 12 MP rear camera, 1.55 micron pixel size, laser auto focus, dual LED flash 5 MP front-facing camera |
12 MP rear camera with OIS 5 MP front-facing camera |
| Connectivity | Wi-Fi 802.11 a/b/g/n/ac Bluetooth 4.1 GPS + GLONASS NFC USB 2.0, USB Type-C |
a/b/g/n/ac Bluetooth 4.2 GPS + GLONASS NFC ( with Apple Pay only) USB 2.0 |
| Software | Android 6.0 Marshmallow | iOS 9 |
| Battery | 3,450 mAh | 2,750 mAh |
| Dimensions | 159.3 x 77.8 x 7.3 mm 178 grams |
158.2 x 77.9 x 7.3 mm 192 grams |
Gallery
Pricing and final thoughts
Prices for both of these devices reach the premium brackets, but the iPhone is notorious for being a very expensive phone, especially when a higher storage capacity is factored in. $749 total in payments to T-Mobile gets you the 16 GB version, with the 64 GB iteration setting you back and additional $100. On the other hand, the Nexus 6P is more aggressively priced, but given its unlocked nature, requires a full payment. $499 will get you the base model, requiring another $50 for the 64 GB edition.
So there you have it for this in-depth look at the Nexus 6P vs iPhone 6S Plus! These are the bigger quintessential devices of their respective lines, and they both certainly bring a lot to the table. Apple jumped into the large form factor game only last year, and with the 6S Plus, it is more about refining the formula, aside from the one main addition in 3D Touch. The Nexus 6P is Google’s latest attempt to not only provide a great reference point, but rather be a device that is worthy of claiming the flagship crown. With a design overhaul, Marshmallow additions, and an improved camera, it is worthy of being considered as such.
If you want a larger display with performance to match, either of these devices will do. Purists will stick to what they know and love, and in this comparison, we see that the grass is greener on the other side, in either case.
Android 5.1.1 Lollipop update is now available for the Honor 4X in the UK
It’s always a great feeling finding out that your handset has an update waiting for it, meaning that Honor 4X owners in the UK are in for a treat. @UKHonor has just announced via Twitter that the Lollipop update is now available for the Honor 4X, which means that the handset will no longer have to languish on Android 4.4.2 KitKat.
The 4X Lollipop update will bump the firmware all the way up to Android 5.1.1, with EMUI version 3.1 in tow. For the moment, the Lollipop update is a manual install only, which means you must download the firmware package from the Honor site, which comes to around 1.4GB in size. My contact at Honor UK says the Lollipop update will either install, or fail, with no chance of bricking (yes, I have that in writing). So, the big question is, how do you perform the update? Well, here are the instructions that should be followed to the letter, straight from the horse’s mouth.
Before continuing, as always when updating to a new version of Android, it’s good practice to perform a full backup, with Honor UK recommending the Huawei Backup tool that can be found on your device which will backup all the apps, settings, and media from the handset. The contact said the update shouldn’t wipe the device in the process, but sometimes things can go pear-shaped, so it’s better to be safe than sorry.
Instructions:
- Ensure the handset has at least 30% battery and at least 4GB of space on the SD card before continuing
- Download the update from here (the Honor 4X CherryPlus L11C432B310 package)
- Copy the update over to the SD card
- Make a new folder on the SD card called dload, and then extract the update.app file to the newly created dload folder
- Navigate to the Update section in Settings, select Local Update from the menu and then select the UPDATE.APP file you have previously extracted
- The Honor 4X will then reboot into recovery and automatically find and flash the Lollipop update
Source: @HonorUK (Twitter)
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Huawei Nexus 6P now available to buy at Carphone Warehouse
The Huawei-made Nexus 6P is now available to purchase through Carphone Warehouse in the UK. Those of you that are interested can pick up the latest and greatest from Google, starting at £34.99 per month in addition to an up-front fee of £29, administered both in-store and online.
Alternatively, those that want to ditch the contracts can pick up the Nexus 6P from Carphone Warehouse outright for £439.99. As far as pricing goes, there’s definitely some savings in buying it outright in the long-term picture.
Keep in mind that if you purchase the 5.7-inch device, you’ll not only be rocking the latest version of Google’s mobile operating system, Android 6.0, but you’ll also get three months of free Google Play Music, which is something Carphone Warehouse is offering on any Android smartphone through the end of the year.
As a quick refresher, the Nexus 6P is featuring a 5.7-inch display, an Octa-core Snapdragon 810 CPU, 3GB of RAM, and a gorgeous 13-megapixel rear camera. Google has recently been frustrating customers, saying that Nexus 6P orders are being shipped out on a first-come, first-served basis.
The Nexus 6P is undoubtedly one of the hottest smartphones to launch this season, and due to the popularity, there’s no telling when customers will begin receiving their new devices on a normal shipping basis.
source: Carphone Warehouse
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SoC showdown: Snapdragon 810 vs Exynos 7420 vs MediaTek Helio X10 vs Kirin 935
Which is the best Android smartphone SoC? We test the Snapdragon 810, the Exynos 7420, the MediaTek Helio X10, the Kirin 935, and the Snapdragon 801. But before looking at these chips, let’s start with a high level look of mobile processing technology.
What is a SoC?
The SoC defines what a smartphone can and can’t do.
Traditionally, the “brains” of a computer were found in the CPU (Central Processing Unit), and other necessary peripherals were found in auxiliary chips which were dotted around the CPU. These auxiliary chips included things like the GPU (Graphics Processing Unit), the memory controllers, and any specialized video or audio chips (like DSPs). In fact, way back when the Intel 386 and 486 CPUs were the talk of the town, even the FPU (Floating Point Unit) was considered an optional extra. Since then, more and more stuff has been included on the same silicon as the CPU, first the FPU, then various memory controllers, and now the GPU and DSPs as well.
A single chip, which includes lots of different functions, is known as a SoC or a System-on-a-Chip. The chips which power our smartphones are no longer just CPUs, but a CPU plus a GPU plus a memory controller plus a DSP plus a radio for GSM, 3G and 4G LTE comms. But it doesn’t stop there, on top of all that lot, you will find discrete bits of silicon for the GPS, USB, NFC, Bluetooth and for the camera.
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In many ways, the SoC defines what a smartphone can and can’t do, plus it determines the device’s performance and battery efficiency. In other words, it is important to know what SoC is in your smartphone.
At the moment there are four major smartphone SoC makers: Qualcomm, with its Snapdragon range; Samsung with its Exynos chips; MediaTek with its MT and Helio processors; and Huawei’s Kirin chips made by its subsidiary HiSilicon.
Each of these manufacturers produces a variety of chips for the low-, mid- and high-end smartphone markets. And it is at the high-end that the competition is the toughest, at least in terms of perceptions. In terms of actual units shipped, the low- and mid-range SoCs are just as important, however, the glory is in the flagship devices.
So that leads us to our question, what is the best SoC? To try and answer this question we will take a look at five key processors: the Snapdragon 810, the Exynos 7420, the MediaTek Helio X10, the HiSilicon Kirin 935, and the Snapdragon 801. I have included the last one for comparison. Released in 2013 and 2014 respectively, the Snapdragon 800 and 801 SoCs are almost legendary in terms of their performance and reliability.
| Snapdragon 810 | Exynos 7420 | MediaTek Helio X10 (MT6795) | HiSilicon Kirin 935 | Snapdragon 801 | |
|---|---|---|---|---|---|
| Cores | 8 | 8 | 8 | 8 | 4 |
| CPU | 4x Cortex-A57 + 4x Cortex-A53 | 4x Cortex-A57 + 4x Cortex-A53 |
8x Cortex-A53 | 8x Cortex-A53 | 4x Krait 400 |
| CPU clock | A57 – 2.0GHz A53 – 1.5GHz |
A57 – 2.1GHz A53 – 1.5GHz |
Up to 2.2GHz | 4x A53 – 2.2GHz 4x A53 – 1.5GHz |
Up to 2.45 GHz |
| Arch | ARMv8-A (32 / 64-bit) | ARMv8-A (32 / 64-bit) | ARMv8-A (32 / 64-bit) | ARMv8-A (32 / 64-bit) | ARMv7-A (32-bit) |
| GPU | Adreno 430 @ 630MHz | ARM Mali-T760 MP8 @ 772 Mhz | PowerVR G6200 @ 700Mhz | Mali-T628 MP4 | Adreno 330 @ 578 GHz |
| Memory | LPDDR4 1600MHz 64-bit | 1552MHz LPDDR4 | LPDDR3 933MHz | LPDDR3 1600 MHz | LPDDR3 933MHz 32-bit |
| Process | 20nm | 14nm FinFET | 28nm | 28 nm | 28nm |
Core count
Octa-core is the norm today, but things may change next year.
Look across the table above and you will see that octa-core processors are the order of the day. With the exception of the Snapdragon 801, which is here for comparison, we can see that every major SoC uses 8 CPU cores. To support 8 CPU cores, these chips use a technology from ARM called big.LITTLE. The idea behind big.LITTLE is that not all the cores are equal. You generally find a cluster of Cortex-A57 cores and a cluster of Cortex-A53 cores. The A57 is a high performance core, while the A53 has greater energy efficiency.
When tasks are run on the LITTLE cores they use less power, they drain the battery less, however they may run a little slower. When tasks are run on the big cores, they finish sooner but they use more battery to do so.
The only exceptions to this among the octa-core processes in our lineup are the Kirin 935 and the MediaTek Helio X10, both of which use one cluster of Cortex-A53 cores clocked at a higher clock speed than another cluster of Cortex-A53 cores clocked at a lower speed.
See also: Why the quad-core Snapdragon 820 won’t bring an end to the core wars
Although this is the way things are today, the core count is going to change. The next generation CPU from Qualcomm, the Snapdragon 820, will go back to using four cores, with a core design cooked up by Qualcomm’s engineers rather than using the core designs from ARM. At the other end, MediaTek will be releasing a SoC with 10 CPU cores, the Helio X20.
GPUs
Samsung’s latest flagships all sport the formidable Mali-T760 GPU
There are three major designers of mobile GPUs: ARM, Qualcomm and Imagination. ARM’s range of GPUs are known as Mali and includes the Mali-T760, as found in the Exynos 7420, and the Mali T628, as found in the Kirin 935. Qualcomm’s GPUs are branded under the Adreno name with the Snapdragon 810 using an Adreno 430 and the Snapdragon 801 using a Adreno 330. The third player in the GPU space is Imagination with its PowerVR range. Imagination has had the most success on mobile with Apple, as every iPhone since the 3GS has used a PowerVR GPU. However, Imagination has also had some success on Android, and the MediaTek Helio X10 uses the PowerVR G6200.
It is difficult to make a comparison between these GPUs just from the specifications. They all support OpenGL ES 3.1, they all support RenderScript, and they all boast high gigaFLOP numbers. The real test comes when running actual 3D games.
Fabrication technology
Processors are fabricated out of silicon wafers such as this HiSilicon one
The fabrication of “silicon chips” isn’t easy. In fact it is a highly complex process that involves a lot of expensive machinery. To make a chip from silicon wafer to chips ready to sell, it takes several weeks. One of the parameters of fabrication system is known as the “process node” and it defines how small the transistors are and how small the gaps are between transistors. The Helio X10, the Kirin 935 and the Snapdragon 801 are all built using a 28nm (nanometer) process. The Snapdragon 810 uses a 20nm process, while the Exynos 7420 uses a 14nm process, known as 14nm FinFET.
The original, from 1971, the 4-bit Intel C4004 CPU
As you can imagine, the smaller you make a chip the harder it gets. The original Intel 4004 CPU, which was launched in 1971, was manufactured using a 10 µm (10,000 nanometers) process. By 1989, that had dropped to 800nm, the process used for the Intel 486 and the lower speed Pentium CPUs. By 2001, the process node was down to 130nm and was used by companies like Intel, Texas Instruments, IBM, and TSMC for a variety of processors including the Pentium III, the Athlon XP and back when Motorola made chips, the PowerPC 7447.
By the time the smartphone revolution was underway, chips like the Samsung Exynos 3 Single, used in the original Google Nexus S, were made using 45nm technology. Today, that number is down to between 28nm and 14nm (FinFET). The key thing about process nodes is that, although it gets harder to reach these smaller and smaller targets, the benefit is that the chips need less power and produce less heat, both of which are very important for mobile devices.
However there is one caveat, the process node is just one factor in many which defines the performance and power usage of a SoC. Although it might seem that a chip made using a 28nm process node will be half as efficient as a chip made using a 14nm FinFET process, it isn’t, things are just more complicated than that!
Snapdragon 810
The Snapdragon 810 is Qualcomm’s flagship 64-bit processor. It has eight cores in total, four Cortex-A53 cores and four Cortex-A57 cores. The SoC uses ARM’s big.LITTLE technology, which means that the more power efficient Cortex-A53 cores are used for easier tasks and the Cortex-A57 cores are activated when some heavy lifting is required. Bundled with the CPU is the Adreno 430 GPU, the Hexagon V56 DSP, and an integrated X10 LTE modem.
The history of the Snapdragon 810 has been rocky at best. Samsung didn’t pick it for the Galaxy S6 range, nor for the Note 5, instead opting for its home-grown Exynos 7420. The chip has also been dogged with stories of overheating and CPU throttling. Qualcomm tried to fix the chip’s perceived image by releasing a new stepping known as V2.1, however, with the 4K video overheating issues of phones like the Sony Xperia Z5 Compact, the Snapdragon 810 is still seen negatively by some consumers.
Having said that, my testing of the Snapdragon 810 has shown it to be a fast and reliable SoC for the most part, and it has been picked-up by several top smartphone makers including Huawei for the Nexus 6P, OnePlus for the OnePlus 2, HTC for the One M9 and LG for the LG G Flex 2.
Exynos 7420
This is one of the most popular smartphone processors at the moment, mainly because it is the processor used by Samsung for its current range of high-end devices including the Samsung Galaxy S6, the Samsung Galaxy S6 Edge +, and the Samsung Galaxy Note 5. Like the Snapdragon 810 it uses four Cortex-A53 cores and four Cortex-A57 cores. But rather than the Adreno 430, we find a ARM Mali-T760 MP8.
The Mali-T760 has 8 shader cores while boasting a 400% increase in energy efficiency over the ARM Mali-T604. One of the tricks in the Mali-T760’s architecture is the use of bandwidth reduction techniques, which minimizes the amount of data shifted around and hence reduces the amount of power used by the GPU. Such techniques include ARM Frame Buffer Compression (AFBC), which compresses the data as it is passed from one part of the SoC to another; and Smart Composition, which only renders the parts of the frame which have changed.
See also: Up close and personal: how the Samsung Galaxy S6 uses its octa-core processor
Thanks to the smaller 14nm FinFET manufacturing process, Samsung has been able to up its clock speeds by 200MHz on the CPU side and by 72MHz on the GPU side, when compared to the Exynos 5433. It is also Samsung’s first SoC with LPDDR4 memory support, which runs in a 32-bit dual-channel configuration with a clock speed of 1552MHz. Peak bandwidth reaches 25.6 GB/s.
MediaTek Helio X10
Earlier this year MediaTek launched its new Helio brand of SoCs. Unlike the bland sounding MTxxxx range of SoCs, the Helio branding brings MediaTek into line with Samsung and Qualcomm with their Exynos and Snapdragon brands. The first MediaTek Helio SoC is the Helio X10, an octa-core processor with four 2.0 GHz Cortex-A53 cores and four 2.2 GHz Cortex-A53 cores, backed by a PowerVR 6200 GPU. If that setup sounds familiar it is because that was also the specs of the MediaTek MT6795 and, as far as I can tell, the Helios X10 is in fact just a rebrand of the MT6795.
The multimedia features of the X10 are quite interesting and include video recording at 480 frames per second with 1/16th speed slow-motion playback, support for 120Hz smartphone displays, and H.265 Ultra HD 4K2K video encoding at 30 fps.
Kirin 935
Smartphones using the Kirin range of SoCs started to appear during mid-2014, almost exclusively from Huawei. HiSilicon is a fully owned subsidiary of Huawei and its first Kirin processors were quad-core Cortex-A9 based, as found in phones like the Huawei Ascend P7. Since then, HiSilicon has produced increasingly more powerful processors including 32-bit octa-core processors with Cortex-A15 and Cortex-A7 cores, and 64-bit processors using Cortex-A53 cores. The company has also just announced its new SoC: the Kirin 950. The Kirin 950 uses four Cortex-A72 cores (the successor to the Cortex-A57) and four Cortex A53 CPU cores, combined with a Mali-T880 GPU.
The Kirin 935 uses four Cortex-A53 cores clocked at 2.2 GHz, and another four Cortex-A53 cores clocked at 1.5 GHz. The GPU is the ARM Mali-T628 MP4.
Snapdragon 801
The Snapdragon 801 is quite different to the other SoCs listed here. First, it is a 32-bit processor using the ARMv7 instruction set architecture (ISA), rather than the 64-bit ARM v8 ISA. Second, it is a quad-core processor rather than an octa-core processor. Third, it uses Qualcomm’s own ARM compatible core design (Krait) and not a core design from ARM.
The reason I have included it is as a baseline reference. The Snapdragon 800 and the Snapdragon 801 SoCs were very popular and marked the heyday of Qualcomm’s reign at the top. You can find the Snapdragon 801 in devices like the Sony Xperia Z3, the LG G3, the Samsung Galaxy S5, the HTC One M8 and the OnePlus One.
The Phones
For these tests, I got hold of different phones using these SoCs. The phones are:
- Snapdragon 810 – Sony Xperia Z5 Compact
- Exynos 7420 – Samsung Galaxy Note 5
- MediaTek Helio X10 – Redmi Note 2
- Kirin 935 – Huawei Mate S
- Snapdragon 801 – ZUK Z1
Before looking at the test results, there is one caveat: there are likely other handsets available that could utilize these SoCs better than the handsets I have used. In other words, maybe the RedMi Note 2 isn’t the best performing Helio X10 handset, or maybe there are better Snapdragon 801 devices than the ZUK Z1, etc. However the variations between models shouldn’t be so large as to alter the overall results.
It is also worth noting that the screen resolution plays a big factor for benchmarks that include GPU tests. Pushing around those pixels on a phone with a Full HD display is less taxing for the CPU and GPU than on a phone with a 2K display.
Performance tests
Performance testing is a complex science in that it is hard to replicate the exact same conditions for each test run. Even variations in temperature can alter test results. One popular way to test the performance of a phone is to use benchmarks like AnTuTu and Geekbench. Another is to simulate real world scenarios like launching a game while monitoring the performance. As a third way to test the performance I have written a couple of apps. The first one tests the SoCs processing power by calculating a large number of SHA1 hashes, performing a large bubblesort, shuffling a large table and then calculating the first 10 million primes. The second app uses a 2D physics engine to simulate water being poured into a container and measuring the number of droplets that can be processed in 90 seconds. At 60 frames per second the maximum score is 5400.
AnTuTu
AnTuTu is one of the “standard” benchmarks for Android. It tests both CPU performance and GPU performance and then presents a final score. AnTuTu is good for getting a general feel for how well a SoC can perform, however the test loads used by the benchmark are completely artificial and don’t reflect real life scenarios at all. However, as long as we take that into consideration then the numbers can be useful.
I performed two tests with AnTuTu. First, I just run the test on the device from a fresh boot, then I run the 3D demo game Epic Citadel for 30 minutes (in the hope of heating up the phones a bit) and then I re-ran the benchmark. The results are below:
AnTuTu – Higher is better.
As you can see the Exynos 7420 comes out on top followed by the Snapdragon 810. Third is the Kirin 935, and fourth is the Snapdragon 801 beating the Helio X10. After running Epic Citadel for 30 minutes the performance dropped for all of the devices except for the Mate S and its Kirin 935. However the order remains the same.
Geekbench
I performed two tests with Geekbench. First I just ran the test on the device from a fresh boot, then I ran the 3D demo game Epic Citadel for 30 minutes for the AnTuTu test (see above). Straight after re-running AnTuTu, I then re-ran Geekbench. Here are the results, one graph for the single-core tests and one for the multi-core:
Geekbench single-core – Higher is better.
The single core tests show the speed of an individual core, regardless of how many cores there are on the SoC. The Exynos 7420 comes in first with 1504, followed closely by the Snapdragon 810. The other three are fairly evenly matched which shows the difference in core level performance between the Cortex-A57 and the Cortex-A53. It also shows us that the Krait core in the Snapdragon 801 is faster than the Cortex-A53 cores of the Kirin and Helio.
Geekbench multi-core – Higher is better.
The multi-core tests run the benchmark across all the available cores. As such the Snapdragon 801 is bound to come in last as it only has four cores. At the top we find the Exynos 7420 again, this time followed by the Helio X10, quite a jump from its last place in the single-core tests! After running Epic Citadel for half an hour the Snapdragon 801 and the Kirin 935 actually perform slightly better, however the overall positions remain unchanged.
CPU Prime Benchmark
As with the previous two benchmarks, I ran CPU Prime Benchmark twice. The first run was performed when the device was cool and had no other apps running. Then I set each phone to record Full HD video (not 4K) for 10 minutes. After than I re-ran the benchmark. The results are surprising:
CPU Prime Benchmark – Higher is better.
In first place again we find the Exynos 7420, followed by the Snapdragon 810. Next the Helio X10, the Kirin 935 and the Snapdragon 801 respectively. After recording Full HD video for 10 minutes, the Exynos manages to achieve the same score, as does the Snapdragon 801. Interestingly the Kirin 935 manages a better score, which pushes it above the X10, while the Snapdragon 810 takes quite a hit dropping from 20771 to 18935.
Real world
For the real world tests I picked two scenarios. The first is how long does it take to startup the Need For Speed No Limits game, and secondly how well do the phones handle the Kraken Javascript benchmark. Kraken was created by Mozilla and measures the speed of several different test cases extracted from real-world applications and libraries. In each case, I used the same version of Chrome downloaded from the Play Store. But first, the Need for Speed startup times:
Need For Speed No Limits – Lower is better.
The Sony Xperia Z5 Compact makes quite a poor showing in this test, coming in last. First place is tied between the Exynos 7420 and the Kirin 935, while the X10 and the Snapdragon 801 are only one second apart. It is worth mentioning here that there are likely other factors which influence the outcome of these tests including the speed of the flash memory, so the poor performance by the Z5 Compact might not be due to the Snapdragon 810.
And now for Kraken:
Kraken- Lower is better.
Things return to “normal” with the Kraken test: First the Exynos 7420, then the Snapdragon 810, and in third the Snapdragon 801. The two Cortex-A53 based devices perform quite poorly here with scores over 9500.
Hashes, bubble sorts, tables and primes
The first of my custom benchmarks tests the CPU without using the GPU. It is a four stage test that first calculates 100 SHA1 hashes on 4K of data, then it performs a large bubble sort on an array of 9000 items. Thirdly, it shuffles a large table one million times, and lastly it calculates the first 10 million primes. The total time needed to do all those things is displayed at the end of the test run. The results are below:
Hashes and sorts – Lower is better.
This is the one test that the Exynos 7420 didn’t win. If it didn’t win the second of my benchmarks as well then I would start to suspect foul play, however it does win the next test (see below) and its second place here is acceptable. However, a great performance by the Snapdragon 810, as well as a strong result for the Snapdragon 801.
Water simulation
The second of my two custom benchmarks uses a 2D physics engine to simulate water being poured into a container. The idea here is that while the GPU will be used slightly for the 2D graphics, most of the work will be carried out by the CPU. The complexity of so many droplets of water will exercise the CPU. One drop of water is added every frame and the game is designed to run at 60 frames per second. The benchmark measures how many droplets are actually processed and how many are missed. The maximum score is 5400, a number which the Exynos 7420 almost hits, but not quite. The full results follow:
2D Physics – Higher is better.
The Exynos 7420 scores 5359, just slightly shy of the maximum score. Surprisingly, the 32-bit, quad-core Snapdragon 801 comes in second followed by the Helio X10 and the Snapdragon 810. Last was the Kirin 935.
Wrap-up
In a nutshell, the Exynos 7420 is the best Android SoC at this time, the Snapdragon 810 comes in a close second, while the Helio X10 and Kirin 935 are good for high mid-end phones. Finally, the Snapdragon 801 still has plenty of life in it.
Before we look at the 64-bit processors, it is worth applauding Qualcomm for the Snapdragon 801. The 801 consistently scored well in the benchmarks and was on average equivalent to the Kirin 935 or to the Helio X10. Like I said during my ZUK Z1 review, I would rather have a quad-core 32-bit Snapdragon 801 than a slower quad-core Cortex-A53 based SoC, like the Snapdragon 410. The Snapdragon 801 also gives us a good baseline from which to judge the results from the other processors.
Overall, the Exynos 7420 is the clear winner. It performs well across all of the tests and it doesn’t seem to be affected much by overheating or throttling. Close behind it is the Snapdragon 810. Both the Exynos 7420 and the Snapdragon 810 use the same Cortex-A57/A53 cores in a big.LITTLE configuration, however they use different GPUs. Although the performance of the Snapdragon 810 is close to that of the Exynos, the 810 is affected more by heat. The drop in performance for the 810 was 8% during the CPU Prime Benchmark test after recording Full HD video for 10 minutes.
As for the other two processors, there seems to be little to choose between them. Sometimes the X10 was faster than the Kirin 935 (e.g. for the CPU Prime Benchmark and the 2D water simulation), while for other benchmarks like AnTuTu and the Geekbench single-core tests, the Kirin 935 was the faster of the pair.
Now read and watch: History of the Nexus family
In a nutshell, the Exynos 7420 is the best Android SoC at this time, the Snapdragon 810 comes in a close second while the Helio X10 and Kirin 935 are good for high mid-end phones. Finally, the Snapdragon 801 still has plenty of life in it.
Now, watch the reviews!
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Huawei officially unveils the Kirin 950 processor
At a press briefing in Beijing today, Huawei officially unveiled their next high-end chipset, the Kirin 950. Huawei has gone with a big.LITTLE architecture using four ARM Cortex-A72 chips and four ARM Cortex A53 chips, along with a Mali-T880 gpu, to step up the performance of the processor compared to previous generation chips resulting in a processor speed of 2.53 GHz, which is better than previous reports had suggested. Although Huawei did not provide specifics as to which device may be the first to get the new Kirin 950, many believe the Huawei Mate 8 is in line for the distinction.
Besides utilizing the ARM big.LITTLE architecture, Huawei implemented a 16nm FinFET manufacturing process to produce the chips. Similar to recent chips in their Kirin line, the 950 fully supports 4G LTE and adds support for VoLTE. Huawei implemented some Heuristic Scheduling Algorithms (HSA) to better predict when a performance boost is needed. Altogether, Huawei is trying to ensure top-line performance while more efficiently managing heat and battery usage. They estimate idle power consumption has been reduced from 90mA to only 6.5mA, which should be able to greatly improve standby times. A new processor call the i5, not to be confused with Intel’s line, is also included to provide an always-on sensing mode. The i5 also handles some functions like real-time location services.
The Kirin 950 should provide some good competition for Qualcomm and Exynos chips that are expected to power some flagship devices in 2016. Typically Huawei has been using their Kirin line in Asian markets, but as they expand into the North American and European markets, we may have a chance to see devices powered by the Kirin 950.
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Key Messages of Kirin950 Press Briefing
On November 5, 2015, Huawei showcased its latest smartphone SoC, the Kirin950, at
a press briefing in Beijing.
1. Kirin SoCs powers 4G+ commercialization around the world
In June 2014, Huawei released the world’s first 4G+ SoC, the Kirin920, and the first
LTE+ smartphone, the Honor 6. Today, all Kirin 900 series chips can support 4G+,
including the Kirin920, Kirin930, Kirin950. More than 50 percent of smartphones in
China are powered by Kirin SoCs today.
2. Kirin950 supports VoLTE, delivering a better HD voice experience
With the debut of the Kirin 930, Kirin SoCs continued to enhance the user experience
on 4G+ networks. The Kirin 930 further optimized 4G+ Internet browsing and the Kirin
950 now delivers an HD voice experience to users via 4G+ networks.
Upgraded 4G+ networks and increased bandwidth have created more opportunities
for HD voice applications. Voices can be transmitted with higher integrity, making
them sound more realistic. Kirin 9xx SoCs support VoLTE technology, which has
doubled the voice sampling rate, increased the spectral range by 100 percent,
improved video call quality by 10 times, and enabled users to make calls while surfing
the Internet. Compared with legacy voice technologies, Kirin 950 VoLTE delivers a
much higher call quality and much lower network latency, to better meet the needs for
multi-party calls and ensure call quality.
To provide users with a better voice experience, the Kirin SoC team worked with
leading mobile operators in China, Europe and Korea to complete a two-year VoLTE
test. CMCC’s VoLTE commercialization pace is the fastest in China. Kirin950 received
the earliest VoLTE verification from CMCC. China Mobile has announced that VoLTE
will be put into commercial operation across its entire network by the end of 2015, and
Kirin 920/930/950 SoCs support VoLTE. Among VoLTE devices put into commercial use
lately across various provinces, the Kirin 920-based Mate 7 is a benchmark model.
3. Kirin 950 achieves a breakthrough in energy efficiency.
Managing power consumption is one of the smart phone industry’s biggest challenges.
Kirin SoCs take a balanced approach to managing performance and power
consumption, and the Kirin 950 has achieved breakthroughs both in performance and
user experience compared with its predecessors.
3.1 16nm FinFET plus process technology
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The process technology is the foundation for user experience. The Kirin 950 is among
the first SoCs to employ the 16nm FinFET plus process node, and is the first SoC in the
industry to commercialize the TSMC 16nm FinFET plus technology. The
commercialization of the 16nm FinFET plus technology faced major challenges:
The number of transistors on a single chip has increased from 2 billion to 3
billion, thus doubling the difficulty of metal interconnection
The 3D transistor structure makes the process much more complex
The photolithography limitation entails the dismantling of the mask, thus
increasing the mask layers by nearly 30 percent
The number of design constraints has increased from 10000+ to 40000.
The decision to move to a cutting-edge process means overcoming many engineering
challenges before commercialization. At the end of 2013, the Kirin SoC team started to
work closely with TSMC to solve the mass production issues for the advanced process.
The process taped out in April, 2014 and entered mass production in January, 2015.
3.2 Outstanding performance
To achieve a breakthrough in performance, Kirin 950 features the industry’s first ARM
4*A72+4*A53 big.LITTLE architecture and its new MaliT880 GPU. Compared with A57,
the performance of the new ARM Cortex A72 core has improved by 11 percent, and its
power consumption has decreased by 20 percent. The graphic rendering capacity of
Kirin 950’s new GPU ARM MaliT880 is 100 percent higher than its predecessor, and its
GFLOPS is also 100 percent higher than its predecessor. In addition, the Kirin 950’s
new architecture also includes a new LPDDR4, a new GIC500, and a new bus and FBC
applications, providing the Kirin 950 with a more powerful hardware performance
foundation.
3.3 Fine tuning
Kirin 950 focuses on the user’s actual performance experience. A study shows that
quick responses and smooth operations are two key factors that affect user experience.
Quick responses depend on an SoC’s boost performance, while smooth operations
depend on its continuous performance. The Kirin SoC team optimized boost and
continuous performance. When the user triggers an operation, the SoC can respond to
it within 100ms, thus enabling a quick-response experience to the user. In active mode,
each frame can be rendered within 1/60 second to deliver a smooth-operation
experience.
In addition to its powerful hardware performance, the Kirin 950 employs Heuristic
Scheduling Algorithm (shortened for HSA) to fine-tune the system to address
Android’s native issues and two performance requirements: when the boost
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performance is required, it can make an accurate prediction and recover quickly; and
in normal scenarios, it can make most accurate performance predictions without
generating additional heat. Compared with its predecessor, the Kirin 950’s boost
performance has improved by 100 percent, and its continuous performance has
improved by 56 percent.
4 i5, the co-processor, enable chip-level intelligent positioning
The Kirin 950 contains a newly upgraded i5 co-processor which is based on the latest
M7 cores. Compared with M3, the performance of M7 has improved by 4 times, making
it the most powerful co-processor in the industry. As the tiny core of the Kirin 950’s
innovative big.LITTLE plus tiny core architecture, i5 can collaborate with big A72 cores
and little A53 cores to share resources. Under the intelligent scheduling by the main
system, when the master CPU is required, i5 in always-sensing mode can quickly wake
up the main CPU, thus greatly reducing the CPU start-up time. The i5 can put the
phone in always-sensing mode with an ultra-low power, and can receive data from
sensors continuously even if the phone is in sleep mode. Its power consumption is
much lower than that of the main CPU.
The algorithmic strength of a location service is much higher than that of a calculator
application. Specifically, its real-time requirements for floating point arithmetic cannot
be fulfilled by the previous M4/M3-based solutions. The M7-based i5 processor is
highly scalable in terms of architecture, making the Kirin 950 the first SoC that can
provide real-time location services for combined GPS, base station, WiFi and sensor
positioning in indoor environments, on viaducts and among buildings. It is a
hardware-based solution, reducing the power by 90 percent from 90mA to 6.5mA.
5 The self-developed ISP enhances Kirin 950’s camera feature.
With the Kirin 950, Huawei has introduced its own ISP technology to achieve a
premium level of performance. It supports 14bit dual ISPs, increasing the throughput
by 4 times to 960MPixel/s for quicker focusing. It also supports online dual 13M Pixel
Sensors, up to a 32MPixel Sensor, and can collect more complete image information.
The dedicated image post-processing DSP can deliver the best image quality and
effects. It integrates a high-end FD for fast and accurate face scanning, which can
identify up to 35 faces continuously in automatic face-scanning mode.
6 A new in-house RF chip supports more bands for global roaming.
Huawei’s new in-house RF chip provides features that could only be delivered by two
previous-generation chips. A single chip can support carrier aggregation with higher
integration and lower power. Compared with its predecessor, the new RF chip
supports more bands from 450MHz to 3.5G which satisfies roaming demands in more
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countries.
It is reported that Huawei’s latest flagship deviced based on Kirin 950 will be launched
soon.
Come comment on this article: Huawei officially unveils the Kirin 950 processor
Huawei Watch now available to buy in the UK
Huawei’s new Android Wear-powered smartwatch, the Huawei Watch, has been creating a lot of buzz with its premium design, but unfortunately, it hasn’t been available for our friends over in the UK. That changes today, as the Huawei Watch will be available to buy at vMall and Selfridges starting at £289.
The Huawei Watch is also available to buy through the UK Google Store. It goes without saying, these three options don’t provide a whole lot of availability, but Huawei says a much wider selection of stores will carry the new smartwatch starting at the end of November.
Huawei’s first Android Wear-powered smartwatch is undeniably one of the most beautiful smartwatches on the market today. However, there are many different premium options available for it, with prices starting at £289 and going all the way up to £599, not including VAT.
Anyone plan on picking one up?
source: vMall
via: Pocket-Lint
Come comment on this article: Huawei Watch now available to buy in the UK
Kirin 950 announced: What you need to know
Mobile chip developers have been lining up their next generation hardware for a few months now and Huawei’s HiSilicon has just announced its new high-end Kirin 950, and it’s a beast.
We’ll start with the main processing components, the CPU and GPU. The Kirin 950 is the first SoC based on ARM’s big.LITTLE technology to make use of four Cortex-A72 and four Cortex A53 CPU cores, combined with a Mali-T880 GPU for some serious all-around performance.
Architecturally, it’s quite a fair comparison to make to the octa-core A57/A53 big.LITTLE chips that have proven popular this generation. The Cortex-A72 found in the Kirin 950 offers an 11 percent performance boost and 20 percent reduction in power consumption when compared with an A57, while HiSilicon is boasting a 100 percent increase in GPU performance over its last chip that used a Mali-T760.
Power consumption should see a notable improvement as chips move over to ARM’s Cortex-A72
Some of these gains also come from the chip’s move on down to TSMC’s 16nm FinFET manufacturing process, marking another industry first for the Kirin 950. This puts the chip ahead of this generation’s Snapdragon 810, which was produced at 20nm, and on par with Samsung’s 14nm process. It is also a notable jump from the Kirin 930’s 28nm design.
Huawei has also done some major work on task scheduling and eking out additional performance. As many mobile tasks are burst like in nature, the Kirin 950 employs Heuristic Scheduling Algorithms (HSA) to predict when to boost performance for these type of workloads without causing the chip to overheat. As a result, HiSilicon boasts that the 950’s boost performance is up by 100 percent compared with its predecessor, while continuous performance is up by 56 percent. The Kirin 950 also includes support for LPDDR4 memory and is designed with ARM’s GIC500 controller and a new bus to tie the system together.
Co-processors and more
The Kirin 950 certainly has it where it counts in terms of performance capabilities, and it is packed full of extra features too.
4G LTE is included as standard, as is support for VoLTE for enhanced call quality. VoLTE is expected to arrive at China Mobile by the end of 2015, so the Kirin 950 and other chips in the line-up will be ready to take advantage. The new RF chip also supports more bands from 450MHz to 3.5G, which satisfies roaming demands.
The Kirin 950 is manufactured on TSMC’s 16nm FinFET process, rivalling Samsung’s 14nm chips.
Huawei has also implemented a new co-processor technology on the chip, which it calls the i5. The chip is based on ARM’s high performance Cortex-M7 microcontroller. This extra core can share resources with the main A72 and A53 CPU cores and is designed to quickly power up the main CPU cores when they are needed using an “always-sensing mode”, while also allowing a very low power sleep state. Overall, HiSilicon estimates that idle power has been reduced by 90 percent, from 90mA to just 6.5mA. The i5 co-processor can also be used to provide real-time location services, by combining GPS, WiFi and sensor positioning.
Huawei has also introduced its own image signal processing technology with this chip. The Kirin 950 supports 14-bit dual ISPs, allowing for a 960MPixel/s throughput, dual 13 megapixel sensors or a single 31 megapixel sensor. The integrated DSP also boasts fast facial recognition technology that can detect up to 35 faces in an image.
With new chips from Qualcomm and Samsung expected to hit devices next year, high-end handsets packing the Kirin 950 look set to offer some serious competition.
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Key Messages of Kirin950 Press Briefing
On November 5, 2015, Huawei showcased its latest smartphone SoC, the Kirin950, at
a press briefing in Beijing.
1. Kirin SoCs powers 4G+ commercialization around the world
In June 2014, Huawei released the world’s first 4G+ SoC, the Kirin920, and the first
LTE+ smartphone, the Honor 6. Today, all Kirin 900 series chips can support 4G+,
including the Kirin920, Kirin930, Kirin950. More than 50 percent of smartphones in
China are powered by Kirin SoCs today.
2. Kirin950 supports VoLTE, delivering a better HD voice experience
With the debut of the Kirin 930, Kirin SoCs continued to enhance the user experience
on 4G+ networks. The Kirin 930 further optimized 4G+ Internet browsing and the Kirin
950 now delivers an HD voice experience to users via 4G+ networks.
Upgraded 4G+ networks and increased bandwidth have created more opportunities
for HD voice applications. Voices can be transmitted with higher integrity, making
them sound more realistic. Kirin 9xx SoCs support VoLTE technology, which has
doubled the voice sampling rate, increased the spectral range by 100 percent,
improved video call quality by 10 times, and enabled users to make calls while surfing
the Internet. Compared with legacy voice technologies, Kirin 950 VoLTE delivers a
much higher call quality and much lower network latency, to better meet the needs for
multi-party calls and ensure call quality.
To provide users with a better voice experience, the Kirin SoC team worked with
leading mobile operators in China, Europe and Korea to complete a two-year VoLTE
test. CMCC’s VoLTE commercialization pace is the fastest in China. Kirin950 received
the earliest VoLTE verification from CMCC. China Mobile has announced that VoLTE
will be put into commercial operation across its entire network by the end of 2015, and
Kirin 920/930/950 SoCs support VoLTE. Among VoLTE devices put into commercial use
lately across various provinces, the Kirin 920-based Mate 7 is a benchmark model.
3. Kirin 950 achieves a breakthrough in energy efficiency.
Managing power consumption is one of the smart phone industry’s biggest challenges.
Kirin SoCs take a balanced approach to managing performance and power
consumption, and the Kirin 950 has achieved breakthroughs both in performance and
user experience compared with its predecessors.
3.1 16nm FinFET plus process technology
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The process technology is the foundation for user experience. The Kirin 950 is among
the first SoCs to employ the 16nm FinFET plus process node, and is the first SoC in the
industry to commercialize the TSMC 16nm FinFET plus technology. The
commercialization of the 16nm FinFET plus technology faced major challenges:
The number of transistors on a single chip has increased from 2 billion to 3
billion, thus doubling the difficulty of metal interconnection
The 3D transistor structure makes the process much more complex
The photolithography limitation entails the dismantling of the mask, thus
increasing the mask layers by nearly 30 percent
The number of design constraints has increased from 10000+ to 40000.
The decision to move to a cutting-edge process means overcoming many engineering
challenges before commercialization. At the end of 2013, the Kirin SoC team started to
work closely with TSMC to solve the mass production issues for the advanced process.
The process taped out in April, 2014 and entered mass production in January, 2015.
3.2 Outstanding performance
To achieve a breakthrough in performance, Kirin 950 features the industry’s first ARM
4*A72+4*A53 big.LITTLE architecture and its new MaliT880 GPU. Compared with A57,
the performance of the new ARM Cortex A72 core has improved by 11 percent, and its
power consumption has decreased by 20 percent. The graphic rendering capacity of
Kirin 950’s new GPU ARM MaliT880 is 100 percent higher than its predecessor, and its
GFLOPS is also 100 percent higher than its predecessor. In addition, the Kirin 950’s
new architecture also includes a new LPDDR4, a new GIC500, and a new bus and FBC
applications, providing the Kirin 950 with a more powerful hardware performance
foundation.
3.3 Fine tuning
Kirin 950 focuses on the user’s actual performance experience. A study shows that
quick responses and smooth operations are two key factors that affect user experience.
Quick responses depend on an SoC’s boost performance, while smooth operations
depend on its continuous performance. The Kirin SoC team optimized boost and
continuous performance. When the user triggers an operation, the SoC can respond to
it within 100ms, thus enabling a quick-response experience to the user. In active mode,
each frame can be rendered within 1/60 second to deliver a smooth-operation
experience.
In addition to its powerful hardware performance, the Kirin 950 employs Heuristic
Scheduling Algorithm (shortened for HSA) to fine-tune the system to address
Android’s native issues and two performance requirements: when the boost
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performance is required, it can make an accurate prediction and recover quickly; and
in normal scenarios, it can make most accurate performance predictions without
generating additional heat. Compared with its predecessor, the Kirin 950’s boost
performance has improved by 100 percent, and its continuous performance has
improved by 56 percent.
4 i5, the co-processor, enable chip-level intelligent positioning
The Kirin 950 contains a newly upgraded i5 co-processor which is based on the latest
M7 cores. Compared with M3, the performance of M7 has improved by 4 times, making
it the most powerful co-processor in the industry. As the tiny core of the Kirin 950’s
innovative big.LITTLE plus tiny core architecture, i5 can collaborate with big A72 cores
and little A53 cores to share resources. Under the intelligent scheduling by the main
system, when the master CPU is required, i5 in always-sensing mode can quickly wake
up the main CPU, thus greatly reducing the CPU start-up time. The i5 can put the
phone in always-sensing mode with an ultra-low power, and can receive data from
sensors continuously even if the phone is in sleep mode. Its power consumption is
much lower than that of the main CPU.
The algorithmic strength of a location service is much higher than that of a calculator
application. Specifically, its real-time requirements for floating point arithmetic cannot
be fulfilled by the previous M4/M3-based solutions. The M7-based i5 processor is
highly scalable in terms of architecture, making the Kirin 950 the first SoC that can
provide real-time location services for combined GPS, base station, WiFi and sensor
positioning in indoor environments, on viaducts and among buildings. It is a
hardware-based solution, reducing the power by 90 percent from 90mA to 6.5mA.
5 The self-developed ISP enhances Kirin 950’s camera feature.
With the Kirin 950, Huawei has introduced its own ISP technology to achieve a
premium level of performance. It supports 14bit dual ISPs, increasing the throughput
by 4 times to 960MPixel/s for quicker focusing. It also supports online dual 13M Pixel
Sensors, up to a 32MPixel Sensor, and can collect more complete image information.
The dedicated image post-processing DSP can deliver the best image quality and
effects. It integrates a high-end FD for fast and accurate face scanning, which can
identify up to 35 faces continuously in automatic face-scanning mode.
6 A new in-house RF chip supports more bands for global roaming.
Huawei’s new in-house RF chip provides features that could only be delivered by two
previous-generation chips. A single chip can support carrier aggregation with higher
integration and lower power. Compared with its predecessor, the new RF chip
supports more bands from 450MHz to 3.5G which satisfies roaming demands in more
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countries.
It is reported that Huawei’s latest flagship deviced based on Kirin 950 will be launched
soon.
Huawei’s first smartwatch finally goes on sale in the UK
It’s taken a while, but companies are finally getting better at smartwatch design. Following the original Moto 360, we’re starting to see some stylish Android Wear devices, like the long-awaited Huawei Watch. We first clapped eyes on this circular timepiece at Mobile World Congress in Barcelona, more than eight months ago. Why it’s taken so long to arrive in the UK is anyone’s guess, but anyway — starting today, you can order one from vMall and select Selfridges stores. That premium design will cost you though — the Huawei Watch starts at £289 for a silver model with a leather band. You’ll pay extra for the ceramic black model and the price climbs higher if you prefer a dressier link or mesh strap. Finally, Wareable reports that the rose gold model will set you back an eye-watering £599.
Via: Wareable
Source: vMall
Huawei’s next chipset may give competitors a run for their money
Huawei is now Europe’s second largest Android brand, according to Kantar, but there’s just no time for celebration. Not too long after launching the Huawei Mate S and the Nexus 6P, the Chinese telecom giant is already teasing the launch of the Mate 8 on November 26. Little is known about this new smartphone so far, but it’ll likely be using Huawei’s upcoming Kirin 950 chipset announced today, which joins the Apple A9 chip to be one of the first to use TSMC’s 16nm FinFET Plus process for improved efficiency. Like its predecessor, the Kirin 950 has an octa-core processor but with much improved performance: 4 x Cortex-A72 and 4 x Cortex-A53 instead of the old mid-range offering of just eight Cortex-A53 cores. It also uses ARM’s flagship Mali-T880 GPU so gaming should be blast on the phone.
The Nexus 6P, after another bend test, truly has some structural flaws
YouTuber JerryRigEverything earlier posted a video of him doing a scratch, burn, and bend test on the Huawei-made Nexus 6P. It wasn’t received very well, particularly because of users questioning the legitimacy of the video. Some claimed it was “fake” because they couldn’t see any logos on the back as well as other reasons. As a result, JerryRigEverything is back with yet another bend test video to clear the air.
In this new video, he thoroughly explains why the Nexus 6P’s structural integrity is so poor, which is because of the use of dovetails and a couple free-floating pieces of aluminum. When it comes to actually bending the handset a second time around, guess what? He breaks it yet again with little effort. Who knew?
Click here to view the embedded video.
There are two takeaways from this video. The first being that when you set out to break something, you’re going to break something. After all, what do you expect to happen when taking a hammer to a car window or a wrecking ball to a tower?
Secondly, some of this is Google and Huawei’s error. Sure, you cannot expect to design your phone in a way to stop people from bending it or taking a hammer to it, but it should be designed in a way that there aren’t any major structural flaws, simply to prevent bending in the pocket or from any other real-world encounters.
All in all, the Nexus 6P bends, but that doesn’t make it a bad smartphone. It’s uniquely designed, but sports some of the best specifications on the market. Not to even mention how clean and slick the stock interface is. If you’re looking for the Google experience, the Nexus 6P might be something you want to consider. If you’re looking for something that has plenty of durability, then looking for a more rugged device will suit your needs.
source: JerryRigEverything (YouTube)
Come comment on this article: The Nexus 6P, after another bend test, truly has some structural flaws
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