AMD has always promised that Zen is a core suitable form entry level x86 computers all the way up to high-performance server parts. Within that scale so far, AMD has launched EPYC for servers, Ryzen 7 for high-end desktop and Ryzen 5 for mainstre…
The focus for AMD’s AM4 platform is to span a wide range of performance and price points. We’ve had the launch of the Ryzen CPU family, featuring quad cores up to octa-cores with the new Zen microarchitecture, but AM4 was always designed to be a platform that merges CPUs and integrated graphics. We’re still waiting for the new Zen cores in products like Ryzen to find their way down into the desktop in the form of the Raven Ridge family, however those parts are going through the laptop stack first and will likely appear on the desktop either at the end of the year or in Q1 next year. Until then, users get to play with Bristol Ridge, originally released back in September 2016, but finally making its way to retail.
Back in 2016, AMD released Bristol Ridge to OEMs only. These parts were the highest performing iteration of AMD’s Bulldozer design, using Excavator v2 cores on an AM4 motherboard and using DDR4. We saw several systems from HP and others that used proprietary motherboard designs (as the major OEMs do) combined with these CPUs at entry level price points. For example, a base A12-9800 system with an R7 200-series graphics card was sold around $600 at Best Buy. Back at launch, Reddit user starlightmica saw this HP Pavilion 510-p127c in Costco:
$600 gets an A12-9800, 16GB of DDR4, a 1TB mechanical drive, an additional R7 2GB graphics card, 802.11ac WiFi, a DVDRW drive, and a smattering of USB ports.
Initially AMD’s focus on this was more about B2B sales. AMD’s reasoning for going down the OEM only route was one of control and marketing, although one might suggest that by going OEM only, it allowed distributors to clear their stocks of the previous generation APUs before Ryzen hit the shelves.
Still, these were supposed to be the highest performing APUs that AMD has ever made, and users still wanted a piece of the action. If you were lucky, a part might pop up from a broken down system on eBay, but for everyone else, the question has always been when AMD would make them available through regular retail channels. The answer is today, with a worldwide launch alongside Ryzen 3. AMD states that the Bristol Ridge chips aren’t designed to be hyped up as the biggest thing, but fill in the stack of CPUs below $130, an area where AMD has had a lot of traction in the past, and still provide the best performance-per-dollar APU on the market.
The eight APUs and three CPUs being launched f spans from a high-frequency A12 part to the A6, and they all build on the Bristol Ridge notebook parts that were launched in 2016. AMD essentially skipped the 6th Gen, Carrizo, for desktop as the Carrizo design was significantly mobile focused (for Carrizo we ended up with one CPU, the Athlon X4 845 (which we reviewed), with DDR3 support but no integrated graphics). Using the updated 28nm process from TSMC, AMD was able to tweak the microarchitecture and allow full on APUs for desktops using a similar design.
The table of ‘as many specifications as we could get our hands on’ is as follows:
| AMD 7th Generation Bristol Ridge Processors | |||||
| Modules/ Threads |
CPU Base / Turbo (MHz) |
GPU | GPU Base / Turbo (MHz) |
TDP | |
| A12-9800 | 2M / 4T | 3800 / 4200 | Radeon R7 | 800 / 1108 | 65W |
| A12-9800E | 2M / 4T | 3100 / 3800 | Radeon R7 | 655 / 900 | 35W |
| A10-9700 | 2M / 4T | 3500 / 3800 | Radeon R7 | 720 / 1029 | 65W |
| A10-9700E | 2M / 4T | 3000 / 3500 | Radeon R7 | 600 / 847 | 35W |
| A8-9600 | 2M / 4T | 3100 / 3400 | Radeon R7 | 655 / 900 | 65W |
| A6-9550 | 1M / 2T | 3800 / 4000 | Radeon R5 | 576 / 800 | 65W |
| A6-9500 | 1M / 2T | 3500 / 3800 | Radeon R5 | 720 / 1029 | 65W |
| A6-9500E | 1M / 2T | 3000 / 3400 | Radeon R5 | 576 / 800 | 35W |
| Athlon X4 970 | 2M / 4T | 3800 / 4000 | – | – | 65W |
| Athlon X4 950 | 2M / 4T | 3500 / 3800 | – | – | 65W |
| Athlon X4 940 | 2M / 4T | 3200 / 3600 | – | – | 65W |
AMD’s new entry-level processors will hit a maximum of 65W in their official thermal design power (TDP), with the launch offering a number of 65W and 35W parts. There was the potential to offer CPUs with a configurable TDP, as with previous APU generations, however much like the older parts that supported 65W/45W modes, it was seldom used, and chances are we will see system integrators stick with the default design power windows here. Also, the naming scheme: any 35W part now has an ‘E’ at the end of the processor name, allowing for easier identification.
Back when these CPUs were first launched, we were able to snag a few extra configuration specifications for each of the processors, including the number of streaming processors in each, base GPU frequencies, base Northbridge frequencies, and confirmation that all the APUs launched will support DDR4-2400 at JEDEC sub-timings.
The A12-9800 at the top of the stack is an interesting part on paper. If we do a direct comparison with the previous high-end AMD APUs, the A10-7890K, A10-7870K and A10-7860K, a lot of positives end up on the side of the A12.
| AMD Comparison | |||||||||
| Ryzen 3 1200 | A12-9800 | A10-7890K | A10-7870K | A10-7860K | A10-9700 | ||||
| MSRP | $109 | ? | $165 | $137 | $117 | ? | |||
| Platform | Ryzen | Bristol | Kaveri Refresh | Bristol | |||||
| uArch | Zen | Excavator | Steamroller | Excavator | |||||
| Threads | 4C / 4T | 2M / 4T | 2M / 4T | 2M / 4T | |||||
| CPU Base | 3100 | 3800 | 4100 | 3900 | 3600 | 3500 | |||
| CPU Turbo | 3400 | 4200 | 4300 | 4100 | 4000 | 3800 | |||
| IGP SPs | – | 512 | 512 | 384 | |||||
| GPU Turbo | – | 1108 | 866 | 866 | 757 | 1029 | |||
| TDP | 65W | 65W | 95W | 95W | 65W | 65W | |||
| L1-I Cache | 4×64 KB | 2×96 KB | 2×96 KB | 2×96 KB | |||||
| L1-D Cache | 4×32 KB | 4×32 KB | 4×16 KB | 4×32 KB | |||||
| L2 Cache | 4×512 KB | 2×1 MB | 2×2 MB | 2×1 MB | |||||
| L3 Cache | 8 MB | – | – | – | – | – | |||
| DDR Support | DDR4-2667 DDR4-2400 |
DDR4-2400 | DDR3-2133 | DDR4-2400 | |||||
| PCIe 3.0 | x16 | x8 | x16 | x16 | x16 | x8 | |||
| Chipsets | B350 A320 X/B/A300 |
B350 A320 X/B/A300 |
A88X A78 A68H |
B350 A320 X/B/A300 |
|||||
The frequency of the A12-9800 gives it a greater dynamic range than the A10-7870K (having 3.8-4.2 GHz, rather than 3.9-4.1), but with the Excavator v2 microarchitecture, improved L1 cache, AVX 2.0 support and a much higher integrated graphics frequency (1108 MHz vs. 866 MHz) while also coming in at 30W less TDP. The 30W TDP jump is the most surprising – we’re essentially getting better than the previous A10-class performance at a lower power, which is most likely why they started naming the best APU in the stack an ‘A12’. Basically, the A12-9800 APU will be an extremely interesting one to review given the smaller L2 cache but faster graphics and DDR4 memory.
One thing users will notice is the PCIe support: these Bristol Ridge APUs only have PCIe 3.0 x8 for graphics. This means that most X370 motherboards that have two GPU slots will leave the second slot useless. AMD suggests moving to B350 instead, which only allows one add-in card.
For the A-series parts, integrated graphics is the name of the game. AMD configures the integrated graphics in terms of Compute Units (CUs), with each CU having 64 streaming processors (SPs) using GCN 1.3 (aka GCN 3.0) architecture, the same architecture as found in AMD’s R9 Fury line of GPUs. The lowest processor in the stack, the A6-9500E, will have four CUs for 256 SPs, and the A12 APUs will have eight CUs, for 512 SPs. The other processors will have six CUs for 384 SPs, and in each circumstance the higher TDP processor typically has the higher base and turbo frequency.
| AMD 7th Generation Bristol Ridge Processors | ||||||
| GPU | GPU SPs | GPU Base | GPU Turbo | TDP | NB Freq | |
| A12-9800 | Radeon R7 | 512 | 800 | 1108 | 65W | 1400 |
| A12-9800E | Radeon R7 | 512 | 655 | 900 | 35W | 1300 |
| A10-9700 | Radeon R7 | 384 | 720 | 1029 | 65W | 1400 |
| A10-9700E | Radeon R7 | 384 | 600 | 847 | 35W | 1300 |
| A8-9600 | Radeon R7 | 384 | 655 | 900 | 65W | 1300 |
| A6-9550 | Radeon R5 | 384 | 576 | 800 | 65W | 1400? |
| A6-9500 | Radeon R5 | 384 | 720 | 1029 | 65W | 1400 |
| A6-9500E | Radeon R5 | 256 | 576 | 800 | 35W | 1300 |
| Athlon X4 970 | – | – | – | – | 65W | 1400? |
| Athlon X4 950 | – | – | – | – | 65W | 1400 |
| Athlon X4 940 | – | – | – | – | 65W | ? |
The new top frequency, 1108 MHz, for the A12-9800 is an interesting element in the discussion. Compared to the previous A10-7890K, we have a +28% increase in raw GPU frequency with the same number of streaming processors, but a lower TDP. This means one of two things – either the 1108 MHz frequency mode is a rare turbo state as the TDP has to be shared between the CPU and APU, or the silicon is sufficient enough to maintain a 28% higher frequency with ease. Obviously, based on the overclocking results seen previously, it might be interesting to see how the GPU might change in frequency without a TDP barrier and with sufficient cooling. For comparison, when we tested the A10-7890K in Grand Theft Auto at a 1280×720 resolution and low-quality settings, we saw an average 55.20 FPS.
Bearing in mind the change in the cache configuration moving to Bristol Ridge, moving from a 4 MB L2 to a 2 MB L2 but increasing the DRAM compatibility from DDR3-2133 to DDR4-2400, that value should move positive, and distinctly the most cost effective part for gaming.
Each of these processors supports the following display modes:
– DVI, 1920×1200 at 60 Hz
– DisplayPort 1.2a, 4096×2160 at 60 Hz (FreeSync supported)
– HDMI 2.0, 4096×2160 at 60 Hz
– eDP, 2560×1600 at 60 Hz
Technically the processor will support three displays, with any mix of the above. Analog video via VGA can be supported by a DP-to-VGA converter chip on the motherboard or via an external dongle.
For codec support, Bristol Ridge can do the following (natively unless specified):
– MPEG2 Main Profile at High Level (IDCT/VLD)
– MPEG4 Part 2 Advanced Simple Profile at Level 5
– MJPEG 1080p at 60 FPS
– VC1 Simple and Main Profile at High Level (VLD), Advanced Profile at Level 3 (VLD)
– H.264 Constrained Baseline/Main/High/Stereo High Profile at Level 5.2
– HEVC 8-bit Main Profile Decode Only at Level 5.2
– VP9 decode is a hybrid solution via the driver, using CPU and GPU
AMD still continues to support HSA and the arrangement between the Excavator v2 modules in Bristol Ridge and the GCN graphics inside is no different – we still get Full 1.0 specification support. With the added performance, AMD is claiming equal scores for the A12-9800 on PCMark 8 Home with OpenCL acceleration as a Core i5-6500 ($192 tray price), and the A12-9800E is listed as a 17% increase in performance over the i5-6500T. With synthetic gaming benchmarks, AMD is claiming 90-100% better performance for the A12 over the i5 competition.
Back when Bristol Ridge first launched to OEMs, several users managed to benchmark the processors to get some data. We cannot confirm these results, but it paints an interesting picture.
NAMEGT, a South Korean overclocker with ties to ASUS, has pushed the A12-9800 APU to 4.8 GHz by adjusting the multiplier. To do this, he used an early ASUS AM4 motherboard and AMD’s 125W Wraith air cooler.
NAMEGT ran this setup on multi-threaded Cinebench 11.5 and Cinebench 15, scoring 4.77 and 380 respectively for a 4.8 GHz overclock. If we compare this to our Bench database results, we see the following:
For Cinebench 15, this overclocked score puts the A12-9800 above the Haswell Core i3-4360 and the older AMD FX-4350, but below the Skylake i3-6100TE. The Athlon X4 845 at stock frequencies scored 314 while running at 3.5 GHz, which would suggest that a stock A12-9800 at 3.8 GHz would fall around the 340 mark.
Prices were not disclosed at the time of writing, although all the chips should be in the $50-$110 range. Certain models will be shipped with AMD’s 65W and 95W near-silent coolers, as we saw on the Kaveri refresh CPUs early last year.
AMD’s main competition in this space will be Intel’s Kaby Lake Pentium and Celeron lines, with AMD pushing the integrated graphics performance being on a much higher level. Intel would counter with a stronger single-thread performance in more office type workloads.
AMD is planning to launch Raven Ridge for desktops sometime at the end of the year or Q1, after the laptop launch. These processors fill in that hole for the time being, although we’re all ready to experience Zen in an APU.
Some parts of this news were posted when Bristol Ridge originally launched. We’re still waiting on some of the processor specifications and will update when we get them.
Toshiba has announced their first retail SSDs to use 3D NAND. The new TR200 series will use Toshiba’s 64-layer BiCS3 3D TLC NAND, the first generation of their 3D NAND flash technology to be suitable for mainstream mass-market use. The TR200 series is the successor to the OCZ Trion 100 and Trion 150 SSDs, the latter of which was renamed TR150 when Toshiba began assimilating the OCZ brand identity. The TR200 series will not bear the OCZ name, but Toshiba is not completely abandoning the OCZ brand.
Where the previous Trion/TR series SSDs served as Toshiba’s entry-level SATA offering and split the market with their MLC-based Vector/VT 180 and VX500, the TR200 will be Toshiba’s only retail SATA SSD for this generation. As with most other SSD vendors, Toshiba is no longer using MLC for new mainstream consumer SSDs based on 3D NAND flash. Unusually, Toshiba’s TR200 will feature a DRAM-less controller design, which typically restricts the performance to only be competitive in the entry-level segment of the SATA market. The controller may be a descendant of the Toshiba controller used in the OCZ VX500, updated to support TLC and larger capacities. However, it’s possible that like previous generations of the TR series, the TR200 is using a re-badged Phison controller—Phison’s S11 this time instead of the S10 used in the earlier generations. The ultra-low-end and low-capacity TL100 that was introduced last year is also not getting a direct successor.
Toshiba’s OCZ VX500 high-end SATA SSD isn’t getting a direct successor based on 3D NAND, but it is not being retired yet either. It remains to be seen whether Toshiba will introduce a NVMe SSD using 3D MLC, but their most likely strategy will be a retail version of the OEM-only XG5 NVMe SSD with 3D TLC. The XG5 is the successor for both the TLC-based XG4 and the MLC-based XG3 whose retail counterpart was the OCZ RD400.
| Toshiba SATA SSD Specifications | |||||
| TR200 | TR150 | VX500 | |||
| Capacities | 240-960GB | 120-960GB | 128-1024GB | ||
| NAND Flash | 64-layer 3D TLC | 15nm TLC | 15nm MLC | ||
| Sequential Read | 550MB/s | 550MB/s | 550MB/s | ||
| Sequential Write | 525MB/s | 530MB/s | 515MB/s | ||
| 4KB Random Read | 80k IOPS | 90k IOPS | 92k IOPS | ||
| 4KB Random Write | 87k IOPS | 64k IOPS | 65k IOPS | ||
| Endurance | 60-240 TB | 30-240TB | 74-592TB | ||
| Warranty | Three years | Three years | Five Years | ||
The TR200 carries the same three-year warranty and write endurance ratings as its predecessor. Performance specifications have only changed slightly, with the most significant difference being substantially improved random write performance. Pricing has not yet been announced. The TR200 series will start shipping to retailers this fall. It will compete against Western Digital’s SATA SSDs using the same BiCS3 3D TLC NAND, the new WD Blue and SanDisk Ultra 3D. Intel’s SSD 545s is already available. Most other SSD vendors can also be expected to soon announce new products featuring 64-layer 3D NAND to ship late this year.
This morning at the ChinaJoy expo, HTC is announcing their first shipping VIVE standalone VR headset, specifically for the Chinese market. The aptly named VIVE Standalone is based on Qualcomm’s recently launched Snapdragon 835 SoC, and for the first time brings the Viveport store and its content to the Chinese market.
The HTC VIVE Standalone VR headset is a yet another device of this kind to be powered by Qualcomm’s Snapdragon 835 SoC, which is one of the highest-performing mobile processors available today. The VR headset does not require a PC or a smartphone, is completely standalone and will get content from the Viveport store in China. Since Google’s Daydream content is not available in China due to national regulations barring Google’s services, HTC had to design a separate headset for the country rather than to sell its Daydream-compatible VR hardware.
HTC is not disclosing much in the way of details about the specifications of the VIVE Standalone VR headset for China, but its design and some other factors indicate that the product has quite a lot in common with HTC’s previously-announced Daydream VR-compatible headset. The dimensions of the product hint that we are dealing with a device featuring a 5” or better panel, though it’s anyone’s guess on whether the resolution is FHD or higher at this point. Finally, content developed for the HTC VIVE Standalone VR headset will be created using tools compatible with Qualcomm’s VR platform.
Meanwhile, for customers outside of China who will have access to Daydream content, HTC is also making it very clear that this headset has no bearing or impact on their previously announced standalone Daydream headset. That product is still being developed and will be released to the market later this year.
HTC did not specify pricing of its VIVE Standalone VR headset, but said that the device was designed to enable “a more affordable, yet high-quality VR experience”.
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The USB 3.0 Promoters Group announced an update to the existing USB 3.1 standard in order to double the maximum possible bandwidth from 10 Gbps to 20 Gbps. This USB 3.2 specification is currently in the final draft review phase. USB 3.2 will remain backward compatible with existing USB devices.
The new specifications will retain the USB 3.1 physical layer data rates and encoding techniques. The doubling of bandwidth is achieved by going in for a two-channel operation (current USB 3.1 Gen 1/2 devices use only one ‘super-speed’ channel).The use of two channels is possible only if a certified USB 3.1 Type-C cable is used to connect the host and the device.
To understand this further, it is helpful to take a look at the layout of the pins in a Type-C connector.
In addition to USB transfers, the Type-C connector also supports ‘alternate modes’. In these modes, the cable can carry Display Port, Thunderbolt, MHL, or HDMI signals. There are two high-speed channels in the Type-C specifications, (TX1+/TX1-, RX1+/RX1) and (TX2+/TX2-, RX2+/RX2-). USB 3.1 uses only one of these channels to achieve the required bandwidth, with the other channel (four pins) dedicated to the alternate mode signals. In some cases, if all high-speed channels are used for the alternate mode, USB transfers are restricted to using the legacy pins for USB 2.0 speeds. USB 3.2 will allow both channels (eight pins) to become available for USB transfers. Obviously, both host and client devices need to be updated to use both channels. Note that the usage of any alternate mode automatically negates the availability of the second channel between the host and the device for USB transfers.
Finally, a certified USB 3.1 Type-C cable is necessary between the USB 3.2 host and device in order to get the full performance benefits with dual lane operation. For passive cables, the USB 3.1 Gen 2 (10 Gbps) speeds are supported only if the length is 1m or shorter. The Type-C cable market is a mess, with many products in the market not carrying the proper certification, and the requisite logo (which is supposed to be in place only after the USB-IF testing process) not being prominent enough even in certified products. To make matters worse, most of the Type-C cables supplied with smartphones are limited to supporting USB 2.0 speeds only. So, consumers are advised to do proper research before purchasing Type-C cables for use with current USB 3.1 Gen 2 and future USB 3.2 systems.
The USB 3.2 update is consumer-friendly, since backwards compatibility is retained and there is no need for any new cables. Thunderbolt 3 also uses Type-C, and can go up to 40 Gbps. Its specifications are being opened up, and that makes future developments in the USB Type-C space worth keeping an eye on.
