With the launch of the Ryzen 5000 series of processors, AMD has set a goal to put its Zen 3 cores everywhere. Starting from desktop, mobile, and soon server space, AMD is delivering its best products. However, AMD is also preparing to satisfy another segment. The OEMs are in need of processors that are specifically designed for their purposes and their clients, that don't require as many features as the desktop segment does. Usually, that means some overclocking capability is cut off. Today, thanks to the two hardware leakers Patrick Schur and Momomo_US we get to see the first sightings of AMD's upcoming Zen 3 offerings for OEMs.

The first in the lineup is the Ryzen 9 5900 processor. It features 12 cores with 24 threads, running at unknown frequencies for now. All we know is that the CPU is a bit lower-clocked than its 105 W "X" Ryzen 9 5900X variant. Unlike the "X" variant, this CPU is supposed to bring TDP down to 65 Watts. Another differentiator is the cache configuration. The Ryzen 9 5900 features 64 MB of L3 cache and 2 MB of L2 cache. The "X" version for desktops features 64 MB of L3, however, there is 6 MB of L2 cache present there. Next up comes the smaller eight-core variant - Ryzen 7 5800. Featuring 8 cores and 16 threads running at an also unknown frequency. The chip features a TDP of 65 Watts and cache configuration with 32 MB of L3 cache and 4 MB of L2, with the only difference from the Ryzen 7 5800X being the lower frequency.

Today, thanks to the ServeTheHome forum member "111alan", we have the first pictures of the alleged Intel Sapphire Rapids Xeon processor. Pictured is what appears to be a dual-die design similar to Cascade Lake-SP design with 56 cores and 112 threads that uses two dies. The Sapphire Rapids is a 10 nm SuperFin design that allegedly comes even in the dual-die configuration. To host this processor, the motherboard needs an LGA4677 socket with 4677 pins present. The new LGA socket, along with the new 10 nm Sapphire Rapids Xeon processors are set for delivery in 2021 when Intel is expected to launch its new processors and their respective platforms.

The processor pictured is clearly a dual-die design, meaning that Intel used some of its Multi-Chip Package (MCM) technology that uses EMIB to interconnect the silicon using an active interposer. As a reminder, the new 10 nm Sapphire Rapids platform is supposed to bring many new features like a DDR5 memory controller paired with Intel's Data Streaming Accelerator (DSA); a brand new PCIe 5.0 standard protocol with a 32 GT/s data transfer rate, and a CXL 1.1 support for next-generation accelerators. The exact configuration of this processor is unknown, however, it is an engineering sample with a clock frequency of a modest 2.0 GHz.

Today, in the latest GeekBench 5 submission by ASUS, we have discovered something rather interesting. Intel's Ice Lake-SP processors were rumored to arrive with up to 28 cores and 56 threads at maximum, on a single chip. That was due to the 10 nm process used to make these chips, with suspicions that the yield of the node was not good enough to make any higher core count parts. Thanks to the GB5 listing, discovered by Leakbench on Twitter, the Intel Ice Lake-SP CPU engineering sample appeared with an amazing 36 cores with 72 threads. This is supposedly Intel's efforts to try and match the 64 cores and 128 threads of AMD's EPYC "Rome" CPUs, which are winning many server applications due to their performance.

The 36C/72T chip was paired with another similar chip in a 2P dual-socket configuration, which made the total core count rise to 72 cores and 144 threads, running inside of Asustek's Y4R-A1-ASUS-G1 server. The system was reporting a clock frequency of 3.6 GHz base speed, which means that the possible boost clocks could be higher. The CPU features a 1.25 MB level two (L2) cache per core (45 MB in total) and 54 MB of unified level three (L3) cache. That makes this CPU core quite an improvement over the past Cooper Lake generation. We are waiting for more information about these CPUs, and we are going to report on it in the coming time.

AMD has launched its RDNA 2 based graphics cards, codenamed Navi 21. These GPUs are set to compete with NVIDIA's Ampere offerings, with the lineup covering the Radeon RX 6800, RX 6800 XT, and RX 6900 XT graphics cards. Until now, we have had reviews of the former two, but not the Radeon RX 6900 XT. That is because the card is coming at a later date, specifically on December 8th, in just a few days. As a reminder, the Radeon RX 6900 XT GPU is a Navi 21 XTX model with 80 Compute Units that give a total of 5120 Stream Processors. The graphics card uses a 256-bit bus that connects the GPU with 128 MB of its Infinity Cache to 16 GB of GDDR6 memory. When it comes to frequencies, it has a base clock of 1825 MHz, with a boost speed of 2250 MHz.

Today, in a GeekBench 5 submission, we get to see the first benchmarks of AMD's top-end Radeon RX 6900 XT graphics card. Running an OpenCL test suite, the card was paired with AMD's Ryzen 9 5950X 16C/32T CPU. The card managed to pass the OpenCL test benchmarks with a score of 169779 points. That makes the card 12% faster than RX 6800 XT GPU, but still slower than the competing NVIDIA GeForce RTX 3080 GPU, which scores 177724 points. However, we need to wait for a few more benchmarks to appear to jump to any conclusions, including the TechPowerUp review, which is expected to arrive once NDA lifts. Below, you can compare the score to other GPUs in the GeekBench 5 OpenCL database.

Today at AWS re:Invent 2020, AWS CEO Andy Jassy announced EC2 instances that will leverage up to eight Habana Gaudi accelerators and deliver up to 40% better price performance than current graphics processing unit-based EC2 instances for machine learning workloads. Gaudi accelerators are specifically designed for training deep learning models for workloads that include natural language processing, object detection and machine learning training, classification, recommendation and personalization.

"We are proud that AWS has chosen Habana Gaudi processors for its forthcoming EC2 training instances. The Habana team looks forward to our continued collaboration with AWS to deliver on a roadmap that will provide customers with continuity and advances over time." -David Dahan, chief executive officer at Habana Labs, an Intel Company.

Researchers at the University of California, Berkeley in 2010 have started an interesting project. They created a goal to develop a new RISC-like Instruction Set Architecture that is simple and efficient while being open-source and royalty-free. Born out of that research was RISC-V ISA, the fifth iteration of Reduced Instruction Set Computing (RISC) ideology. Over the years, the RISC-V ISA has become more common, and today, many companies are using it to design their processors and release new designs every day. One of those companies is Micro Magic Inc., a provider of silicon design tools, IP, and design services. The company has developed a RISC-V processor that is rather interesting.

Apart from the RISC-V ISA, the processor has an interesting feature. It runs at the whopping 5 GHz frequency, a clock speed unseen on the RISC-V chips before, at the power consumption of a mere one (yes that is 1) Watt. The chip ran at just 1.1 Volts, which means that a very low current needs to be supplied to the chip so it can achieve the 5 GHz mark. If you are wondering about performance, well the numbers show that at 5 GHz, the CPU can produce a score of 13000 CoreMarks. However, that is not the company's highest-performance RISC-V core. In yesterday's PR, Micro Magic published that their top-end design can achieve 110000 CoreMarks/Watt, so we are waiting to hear more details about it.

Apple's silicon design team has recently launched its "fastest" CPU core ever, found inside the company's M1 processor designed for laptops and mini-PCs. Featuring an eight-core processor, where four cores are represented by low power small configurations, and four big, high-performance design cores, the M1 processor proved to be extremely fast. However, the Apple Silicon processor doesn't seem to cover anything higher than the 13-inch MacBook Pro. And that is about to change. When it comes to higher-end models like the 16-inch MacBook Pro, which provides more cooling area, it is logical that the processor for those designs is a higher performance design.

Enter the world of the Apple M1X processor. Designed for high-end laptops and the most demanding workloads, the new processor aims to create a new performance level. Featuring a 12-core CPU with eight big and four small cores, the M1X processor is going to deliver much better performance than M1. The graphics and memory configuration are currently unknown, so we have to wait and see how it will look like. The M1X is set to arrive sometime in Q1 of 2021, according to the source of the leak, so be patient and remember to take this information with a grain of salt.

The security of PCs has been an issue in the past few years as cyber-attack methods have been undergoing a transformation to hardware-specific malware that exploits different vulnerabilities of CPUs. That is why Microsoft, the developer of the most popular operating system, Windows 10, decided to engineer a hardware processor that will protect the OS and its user by having a specific job of maintaining the platform security. In collaboration with AMD, Intel, and Qualcomm, Microsoft is today introducing the Pluton security processor. The collaborator companies are going to integrate the new Pluton processor inside their CPUs and thus embed a new level of security in their PCs.

MicrosoftOur vision for the future of Windows PCs is security at the very core, built into the CPU, where hardware and software are tightly integrated in a unified approach designed to eliminate entire vectors of attack. This revolutionary security processor design will make it significantly more difficult for attackers to hide beneath the operating system, and improve our ability to guard against physical attacks, prevent the theft of credential and encryption keys, and provide the ability to recover from software bugs.

Intel has launched its Tiger Lake-U lineup of products back in September, with the availability of the first products in October. The launched lineup was part of the "U" variant of ultra-portable devices that stretched only to four core, eight threaded configurations. However, given that the new competitor in mobile space, AMD, has a wide portfolio of offerings that are coming with up to 8C/16T variants, Intel needs a proper response to that. Despite having a better single-threaded performance, the multi-threaded capability of the Ryzen 4000 series is delivering better performance. Thanks to the popular hardware leaker, TUM APISAK, we have the first appearance of Intel's 11th generation Tiger Lake-H processor.

Appearing in Userbenchmark, the processor was tested on a platform codenamed "Insyde TigerLake". The processor was spotted running 8 cores and 16 threads, at the average frequency of 2.75 GHz. This is only an engineering sample, meaning that these clocks do not represent the final frequencies of the processor. As a reminder, Intel's Tiger Lake CPU is a Willow Cove based design manufactured on Intel's 10 nm SuperFin silicon node. We are yet to see the capabilities of the new node and how the chip performs once the reviews arrive.

AMD today launched a new product in its high-performance Embedded processor family, the AMD Ryzen Embedded V2000 Series processor. Built on the innovative 7 nm process technology, "Zen 2" cores and high-performance AMD Radeon graphics, the AMD Ryzen Embedded V2000 Series provides a new class of performance with 7 nm technology, incredible power efficiency and continues to deliver enterprise-class security features for embedded customers.

The AMD Embedded Ryzen V2000 family is designed for embedded applications such as Thin Client, MiniPC and Edge systems. Equipped with up to eight CPU cores and seven GPU compute units, a single AMD Ryzen Embedded V2000 Series processor provides 2x the multi-threaded performance-per-watt, up to 30 percent better single-thread CPU performance and up to 40 percent better graphics performance over the previous generation. For customers and applications that need high-performance display capabilities, the Ryzen Embedded V2000 series can power up to four independent displays in 4K resolution.

In the past few years, the Windows-on-Arm (WoA) market has gotten some momentum has with companies trying to develop their WoA PCs, primarily laptops. One example of that is Microsoft. The company has launched a Surface notebook powered by a custom chip from Snapdragon, called Surface Pro X. This device is being powered by the Snapdragon SQ2 processor. However, what seemed to be missing for a while was the lack of support from the Arm itself for this type of market. That is what the company decided to change and make a brand new processor IP dedicated to "on-the-go" devices as they call it, translating into laptops.

The Cortex-A78C is a new design direction which Arm thinks is a good way for laptops, to get some more serious work done. Unlike the regular Cortex-A78 which is a heterogeneous design of big and little cores (Arm's famous big.LITTLE architecture), the new Cortex-A78C revision aims to change that. The "C" version of the processor is actually a homogeneous structure made up of all the big cores. Where you would typically use four big and four little cores for a design, Arm has decided to go all big with this design. For multithreaded purposes, this is the right decision to boost performance. The level three (L3) cache has seen a boost as well, translating to 8 MB of L3$ found on the die. We are eagerly awaiting to see the first designs based on this configuration and see how it performs.

Since AMD announced its next-generation Ryzen 5000 series desktop processors based on Zen 3 core, everyone has been wondering how the new processors perform. For a detailed review and performance numbers, you should wait for official reviews. However, today we have the scores of Ryzen 5 5600X CPU. Thanks to the popular hardware leaker @TUM_APISAK, the Ryzen 5 5600X performance numbers in the SiSoftware Sandra benchmark suite have been leaked. When digging under the hood, the new Ryzen CPU contains six of Zen 3 cores with 12 threads, paired with as much as 32 MB of level three (L3) cache. These cores are running at 3.7 GHz base frequency, while the boost speeds are reaching 4.6 GHz.

In the test results, the AMD Ryzen 5 5600X CPU has scored Processor Arithmetic and Processor Multi-Media scores of 255.22 GOPS and 904.38 Mpix/s. These scores are not much on their own until we compare them to some of the Intel offerings. When compared to the Intel Core i5-10600K CPU, which is likely its targeted competing category, it scores 224.07 GOPS and 662.33 Mpix/s for Processor Arithmetic and Processor Multi-Media tests respectively. This puts the AMD CPU ahead 13.9% and 36.5% in these tests, indicating the possibility of Zen 3. Another important note here is the thermal headroom both of these CPUs run. While the Intel model is constrained withing 125 W TDP, the AMD model runs at just 65 W TDP. This could be an indication of the efficiency that these new processors harness.

Intel 10 nm products have seen massive delays over the years, and Intel has built many IPs on the new node, however, not many of them have seen the light of the day due to problems the company has experienced with the manufacturing of the new node. That has caused delays in product shipments in the past, meaning that the time for 10 nm is just ahead. According to the latest DigiTimes Taiwan report, we have information that Intel is going to delay its Ice Lake-SP server processors manufactured on a 10 nm node. And it is going to be a whole quarter late according to the report. Instead of launching in Q4 this year, we can expect to see new processors in Q1 of 2021. It is yet unknown whatever the launch will happen at the beginning of Q1 or its end, however, we will report on it as we hear more information.

Update: DigiTimes has also released another report regarding server shipments. It is reported that server vendors are decelerating the shipments as they are making fewer orders in Q4 to wait for the new Intel CPUs. Judging by this move, the demand for these new processors is going to be rather high and the supply chain is preparing slowly for it.

SiFive, Inc., the leading provider of commercial RISC-V processor IP and silicon solutions, today announced that Dr. Yunsup Lee, CTO of SiFive, and Dr. Krste Asanovic, Chief Architect of SiFive, will present at the technology industry's premier processor conference, the Linley Fall Virtual Processor Conference. The conference will be held on October 20th - 22nd and 27th - 29th, 2020 and will feature high-quality technical content from leading semiconductor companies worldwide.

"Industry demand for AI performance has skyrocketed over the last few years driven by rapid adoption from the data center to the edge. This year's Linley Fall Processor Conference will feature our biggest program yet and will introduce a host of new technology disclosures and product announcements of innovative processor architectures and IP technologies," said Linley Gwennap, principal analyst and conference chairperson. "In spite of the challenges posed by the pandemic, development of these technologies continues to accelerate and we're excited to be sharing these presentations with a global audience via our live-streamed format."

There is expected to be more than 79 zettabytes of IoT data in 2025, but the real value of this data is found in the insights it generates. The closer to the data source we can produce these insights the better, because of the improved security, latency and energy efficiency enabled. Computational storage is emerging as a critical piece of the data storage puzzle because it puts processing power directly on the storage device, giving companies secure, quick and easy access to vital information.

Our expertise and legacy in storage puts Arm in a strong position to address the changing needs of this market - with around 85% of hard disk drive controllers and solid-state drive controllers based on Arm, we are already a trusted partner for billions of storage devices. Today, we're announcing Arm Cortex-R82, our first 64-bit, Linux-capable Cortex-R processor designed to accelerate the development and deployment of next-generation enterprise and computational storage solutions.

IBM today revealed the next generation of its IBM POWER central processing unit (CPU) family: IBM POWER10. Designed to offer a platform to meet the unique needs of enterprise hybrid cloud computing, the IBM POWER10 processor uses a design focused on energy efficiency and performance in a 7 nm form factor with an expected improvement of up to 3x greater processor energy efficiency, workload capacity, and container density than the IBM POWER9 processor.

Designed over five years with hundreds of new and pending patents, the IBM POWER10 processor is an important evolution in IBM's roadmap for POWER. Systems taking advantage of IBM POWER10 are expected to be available in the second half of 2021. Some of the new processor innovations include:

In a sign of AMD's answer to Intel Hybrid tech being quite far away from implementation in a product, the company filed patents to a rival/similar technology only as recently as June 30, 2020, with the patent application being dug up by Underfox. The patent calls for a multi-core processor topology with two kinds of CPU cores - a "high-feature" core (big core), and a "low-feature" one (small core).

Here's where AMD's design is different: it calls for closely integrated groups of the two kinds of cores (one big core, and one small core), called "Processor Clusters." The dedicated L1 caches of the big and small cores in each group shadow data, while an L2 cache is shared between the two cores. Several such big+small Processor Clusters sit across a die, sharing the chip's last-level cache (L3 cache). This is unlike Intel's Hybrid design, where the big and small cores are spread apart on the die, with little cache coherency (Lakefield die-shot by le Comptoir du Hardware below). The patent also details the workflow of how the processor reconciles the ISA differences between the two core types.

Intel became the official PC hardware partner for the PC version of Marvel's Avengers last year and it seems like Intel is looking to take advantage of that with new limited edition "KA" Avengers series processors. Trusted leaked @momomo_us recently discovered listings for several of these Intel "KA" series processors on a Vietnamese retailer. It appears Intel is preparing to release 4 processors across their i5, i7, and i9 lineups these being the i5-10600KA, i7-10700KA, i9-10850KA and i9-10900KA. These processors should be identical to their K series counterparts apart from the commemorative packaging and the possible inclusion of Marvel's Avengers game codes. These processors will likely see a global release in the coming weeks/months in preparation for the launch of Marvel's Avengers on September 4th.

ASUS today launched VivoBook Flip 14 (TM420), a boldly styled convertible touchscreen laptop with a 360° hinge that allows it to be used in laptop, stand, tent and tablet modes - or anything in between. It also supports the ASUS Pen active stylus for natural writing and response feel, along with accurate input.

Everything's a breeze with VivoBook Flip 14, thanks to its powerful AMD Ryzen 7 4700U Mobile Processor with 8 GB memory and up to 512 GB PCIe SSD. It's also full of personality, sporting a sleek Bespoke Black finish and a color-blocked Enter key with yellow edges and text. The compact VivoBook Flip 14 is the perfect on-the-go laptop for productivity or entertainment anywhere.

AMD has quietly added two new mobile processors to its lineup, the AMD 3015e and AMD 3020e are 6 W dual-core Zen chips with Vega 3 graphics. The AMD 3015e features dual 14 nm Zen cores with multi-threading running at a base frequency of 1200 MHz with a turbo frequency of 2300 MHz. The onboard Vega 3 GPU runs at 600 MHz and the chip can support 1600 MHz DDR4 memory. The AMD 3020e keeps the same dual 14 nm Zen cores but loses multi-threading, the base clock remains the same at 1200 MHz but the turbo frequency gets a bump to 2600 MHz. The Vega 3 GPU also gets a boost to 1000 MHz along with the addition of 2400 MHz DDR4 memory support.

Lenovo has recently unveiled two new laptops utilizing the AMD 3015e, the Lenovo 100e 2nd Gen and 300e 2nd Gen. The Lenovo 100e 2nd Gen features 4 GB DDR4 memory, 64 GB eMMC, Wi-Fi 6, 11.6" 720p screen, and runs Windows 10. The Lenovo 300e 2nd Gen has a similar build with the addition of a 360° hinge, pen support, and optional 128 GB SSD. The new AMD 3015e processor found in the laptops should perform ~20% faster than the Intel Celeron N4120. The Lenovo 100e 2nd Gen and 300e 2nd Gen will be available in September for 219 USD and 299 USD respectively.

Tachyum Inc. announced that its Prodigy Universal Processor has successfully completed software emulation testing across x86, ARM and RISC-V binary environments. This important milestone demonstrates that Prodigy will enable customers to run their legacy applications transparently at launch with better performance than any contemporary or future ARM or RISC-V processors. Coupled with hyperscale data center workhorse programs such as Hadoop, Apache and more, which Tachyum is recompiling to Prodigy native code, this capability will ensure that Prodigy customers can run a broad spectrum of applications, right out of the box. Tachyum customers consistently indicate that they would run 100% native applications within 9-18 months of transitioning to the Tachyum platform to exceed performance of the fastest Xeon processor. The emulation is to smoothly transition to native software for Tachyum Prodigy.

A Linux kernel patch contributed and signed off by Intel confirms that its upcoming Core "Alder Lake" processor will feature a hybrid core topology, much like Core Hybrid "Lakefield." The patch references "Lakefield" and "Alder Lake" under "Hybrid Core/Atom Processors." The patch possibly gives the Linux kernel awareness of the hybrid core topology, so it can schedule its work between the two types of cores on the silicon accordingly, and avoid rotating between the two core groups. Under the Android project, Linux has been aware of a similar tech from Arm since 2013.

Analogous with Arm big.LITTLE, the Intel Hybrid Core technology involves two kinds of CPU cores on a processor die, the first kind being "high performance," and the second being "low power." On "Lakefield," Intel deployed one "Sunny Cove" high performance core, and four "Tremont" low power cores. The low power cores keep the machine ticking through the vast majority of time when processing workloads requiring the high performance cores aren't present. With "Alder Lake," Intel is expected to scale up this concept, with the silicon rumored to feature eight "Golden Cove" high performance cores, and eight "Gracemont" low power ones. The chip is also expected to feature a Gen12 Xe iGPU.

ECS today rolled out the SF110 Q470 line of mini-PC barebones designed for 10th Gen Core "Comet Lake-S" desktop processors. The SF110 Q470 comes in two variants based maximum processor TDP supported - a 35-Watt model, and a 65-Watt model. The former includes a 90 W power brick, while the latter comes with a 120 W power brick and a meatier CPU cooling solution inside. Both barebones are based in the Intel Q470 chipset.

Inside, you'll get two DDR4 SODIMM slots supporting up to 64 GB of dual-channel DDR4-2933 memory, an M.2-2280 slot with both PCI-Express 3.0 x4 and SATA 6 Gbps wiring, and a 2.5-inch drive bay with a SATA 6 Gbps backplane. USB connectivity includes two 10 Gbps USB 3.2 gen 2 ports on the front panel, one 10 Gbps USB 3.2 gen 2 type-C port, and four 5 Gbps USB 3.2 gen 1 type-A ports on the rear panel. Networking includes a 1 GbE connection driven by an Intel i219-V controller, and 802.11ac + Bluetooth 4.2 WLAN card (you can opt for a newer AX201 card with 802.11ax + Bluetooth 5). Both the 35 W and 65 W variants physically measure 205 mm x 176 mm x 33 mm (HxDxW). Display outputs include an HDMI 2.0, two DisplayPorts, and a D-Sub. A COM port covers legacy connectivity. The company didn't reveal pricing.

Huawei has been readying the entire new breed of desktop PCs with a custom motherboard, custom processor, and even a custom operating system. Being that Huawei plans to supply Chinese government institutions with these PCs, it is logical to break away from US-made technology due to security reasons. And now, thanks to the YouTube channel called "二斤自制" we have the first look at the new PC system. Powered by Huawei D920S10 desktop motherboard equipped with Kunpeng 920 7 nm Arm v8 processor with 8 cores, the PC was running the 64-bit UOS operating system, which is a Chinese modification of Linux. In the test, the PC was assembled by a third-party provider and it featured 16 GB of 2666 MHz DDR4 memory and 256 GB SSD.

The YouTube channel put it to test and in the Blender BMW render test, it has finished in 11 minutes and 47 seconds, which is quite slow. The system reportedly managed to stream 4K content well but has struggled with local playback thanks to poor encoding. Being that it runs a custom OS with a custom processor, app selection is quite narrow. The app store for the PC is accessible only if you pay an extra 800 Yuan (~$115), while the mentioned system will set you back 7,500 Yuan (~$1,060). At the heart of this system is eight-core, eight threaded Kunpeng 920 2249K processor. It features a clock speed of 2.6 GHz, has 128K of L1 cache (64K instruction cache and 64K data cache), 512K of L2, and 32 MB of L3 cache.

Ampere today announced further roadmap details of its Ampere Altra server processor family. In March the company announced Ampere Altra, the world's first cloud native processor, featuring 80 cores. Today, Ampere unveiled preliminary details of the expansion of the cloud-native processor family by adding Ampere Altra Max, which has 128 cores, providing customers with another cloud-optimized processor to maximize overall performance and cores-per-rack density.

Ampere Altra Max is ideal for applications that take advantage of scale-out and elastic cloud architectures. Compatible with the 80-core Ampere Altra and also supporting 2-socket platforms, Ampere Altra Max offers the industry's highest socket-level performance and I/O scalability. It will be sampling in the fourth quarter and additional details will be provided later this year.