ASRock NUC BOX-N97 and GMKtec NucBox G2 Specs

Industrial NUC Box-N97 from ASRock

Since the release of Intel Skylake (6th Gen) and Braswell, ASRock Industrial has provided tiny boards and mini-PCs to the industrial systems market. After assuming ASRock’s Beebox design, the business has maintained a consistent cycle for its product launches in this area.

The business has been keeping up a line of 4 in. x 4 in. NUC BOX systems that are actively cooled and based on Intel’s low power microarchitecture. The business unveiled the Elkhart Lake-based NUC BOX-J6412 during the Tremont period. This served as the NUC BOX-3xx0’s replacement and was powered by Braswell SoCs. The business’s newest offering is the NUC BOX-N97. The ADL-N Intel Processor N97 is used in the Gracemont version. The system is available as a barebone, similar to previous NUC BOX devices, and can support either a 2.5″ SATA disk or an M.2 2280 SATA / NVMe SSD, as well as a single DDR4-3200 SODIMM.

The NUC BOX-N97 box also includes a 65W (19V @ 3.42A) power adapter, a VESA mount, and the appropriate screws. Along with a product description and installation documentation, a geospecific power cord is also included. The unit’s underbelly, which must be disassembled in order to install the RAM and disk drive, has a slot for a 2.5″ drive. As can be seen in one of the gallery images, the SATA cable is attached to the bottom.

We decided to add a 16 GB Crucial DDR4-3200 CL 22 SODIMM and an SK hynix Gold P31 NVMe SSD to the system. The M.2 slot is capable of accommodating both SATA and NVMe SSDs, with the latter running at PCIe 3.0 x1.

Every NUC BOX system we’ve evaluated so far has two SODIMM slots. The ADL-N SoCs only have one memory channel, hence the NUC BOX-N97 only has one slot. The internals of the NUC BOX-N97 are essentially identical to those of the other NUC BOX systems we’ve previously tested, with the exception of the DRAM slot. The system makes use of a cooler similar to one seen in laptops. There are no frills, and the thermal solution and chassis design are tried-and-true models.

GMKtec NucBox G2 Specifications

The successor to the still operational NucBox 7, manufactured by GMKtec in Jasper Lake, is the NucBox G2. The ports-all-around design of this micro-PC family is similar to what we observed in the ACEMAGIC T8 Plus evaluation from the previous week. The soldered LPDDR5 RAM in the NucBox G2 is identical to that in the ACEMAGIC system. The usage of an M.2 2242 SATA SSD maintains some level of upgradeability. The system cannot be purchased as a basic kit. A 1 TB SATA SSD with Windows 11 Pro pre-installed and 12 GB of LPDDR5-4800 RAM were included in our evaluation setup.

The NucBox G2 kit also includes a 36W (12V @ 3A) geo-specific wall wart with a Type-C output, an HDMI cable, a wall mount and matching screws, an instruction booklet, and a warranty card. The wall wart can’t be utilized consistently with other devices that comply with USB-PD sink specifications since this is a non-conforming USB Type-C application. Only the NucBox G2’s Type-C power input port may be utilized with the adapter. To access the M.2 2242 SATA SSD slot, just pry off the top portion of the main device. A colorful top panel option is also provided by GMKtec.

A ribbon connection connects the LED lighting base to the main board, which may be seen by unscrewing the bottom. There is also a tiny notebook-style fan and a copper heat spreader nearby. The fan may draw air in via the open vents in the LED lighting base and expel it over the heat spreader fins. The ADL-N package and a single DRAM package with four 24 Gbit Micron dice are visible after removing the heat sink and fan.

The soldered RAM cannot be upgraded by the user. However, behind the M.2 SATA SSD slot lies the M.2 2230 slot for the WLAN component. The pre-installed SSD is from FuturePath, and it seems that the FPT310 SSD featured in the ACEMAGIC T8 Plus review has the same SSD controller.

To maintain a consistent testing environment across several systems, we had to erase the Windows Pro OS that was pre-installed on the NucBox G2 and install Windows 11 Enterprise instead. The table below provides a summary of the complete specifications of the two review samples (as tested).

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Because EA's Godawful DRM renders the Steam version quite literally unplayable. Which is fucking ironic considering the pirated version is literally one of the best optimized games I've ever played and despite its immense graphical fidelity it ran at a clean 60+ FPS even on a Skylake i7 mobile and a 960M off spinning rust.

Glossary

Skylake: The microarchitecture used in all 6th Gen Intel Core products. Often used as a blanket term to refer to all 6th Gen Intel Core CPUs.

960M: The Nvidia GeForce GTX 960M, the laptop version of the GTX 960. Significantly weaker than its desktop counterpart due to limitations on how much heat it was allowed to kick out since if it's too hot it ends up burning your girldick and that's very unpleasant.

Spinning Rust: A rather dated term for a mechanical hard disk drive, or HDD. Refers to the fact that back in the day the magnetic platters used for data storage within these drives had a rust-coloured metal oxide coating. However, this has not been the case for a couple of decades now, as modern HDDs use a glass substrate for their magnetic platters. HDDs are significantly slower than a solid state drive, or an SSD, because an HDD has a mechanical read-write head which needs to move over the surface of the platter in order to read or write data from it. This is far slower than a solid state drive, which uses integrated circuits or ICs (one of the most important inventions in human history) to store bits, and can read them without the need for any kind of mechanical action. This also lends SSDs a far greater degree of resilience than HDDs, as there is no fragile glass platter that may be shattered or a sensitive mechanical head which may be disrupted by drops, shakes, and shocks.

The infinite cycle of wanting to play an fps game, downloading one, realizing that everyone else is so much better at aiming and map knowledge, and eventually uninstalling

Former Intel employee claims this to be the main reason why Apple moved to ARM - Times of India

Former Intel employee claims this to be the main reason why Apple moved to ARM – Times of India

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Apple announced its “historic day for Mac” at WWDC 2020 when CEO Tim Cook revealed that it will no longer use Intel processors and will switch to ARM for Mac devices. While Apple did not reveal the exact reason, a former Intel employee named François Piednoëltold PCGamer that Apple started to dislike Intel processors after Skylake architecture was launched in 2015. The report claims…

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Intel Xeon is a series of server and workstation CPUs (central processing units) designed and manufactured by Intel. These processors are specifically built for demanding workloads, such as those commonly used in data centers, enterprise-level computing tasks, and high-performance computing. Xeon processors typically have higher core counts, larger cache sizes, and support for more memory than consumer-grade CPUs, as well as features that enhance reliability and security for mission-critical applications. Certainly! Here's an ultimate guide about Intel Xeon processors: Overview: Intel Xeon processors are designed for server and workstation environments, emphasizing performance, reliability, and scalability. Xeon processors are part of Intel's lineup of high-performance CPUs and are optimized for demanding workloads, such as data centers, cloud computing, virtualization, scientific research, and professional applications. Performance and Architecture: Xeon processors are built on the x86 architecture, which provides compatibility with a wide range of software applications. They feature multiple cores and threads, allowing for parallel processing and improved multitasking capabilities. Xeon processors often have larger cache sizes compared to consumer-grade processors, enabling faster access to frequently used data. They support technologies like Turbo Boost, which dynamically increases clock speeds for improved performance, and Hyper-Threading, which allows each physical core to handle multiple threads simultaneously. Generational Improvements: Intel releases new generations of Xeon processors regularly, introducing enhancements in performance, power efficiency, and feature sets. Each generation may be based on a different microarchitecture, such as Haswell, Broadwell, Skylake, Cascade Lake, Ice Lake, etc. Newer generations often offer higher core counts, improved clock speeds, larger cache sizes, and support for faster memory and storage technologies. Enhanced security features, such as Intel Software Guard Extensions (SGX) and Intel Trusted Execution Technology (TXT), are also introduced in newer Xeon processors. Product Segments: Intel categorizes Xeon processors into various product segments based on performance and capabilities. Entry-level Xeon processors provide basic server functionality and are suitable for small businesses, low-demand workloads, and cost-sensitive environments. Mid-range and high-end Xeon processors offer more cores, higher clock speeds, larger caches, and advanced features like support for multiple sockets, massive memory capacities, and advanced virtualization capabilities. Intel also offers specialized Xeon processors for specific workloads, such as Xeon Phi processors for high-performance computing (HPC) and Xeon Scalable processors for data centers and cloud computing. Memory and Connectivity: Xeon processors support various generations of DDR memory, including DDR3, DDR4, and, in more recent models, DDR5. They typically offer support for large memory capacities, allowing servers to accommodate extensive data sets and run memory-intensive applications efficiently. Xeon processors feature multiple high-speed PCIe lanes for connecting peripherals like storage devices, network cards, and GPUs, facilitating high-performance data transfer. Software Ecosystem and Support: Xeon processors are compatible with a wide range of operating systems, including Windows Server, Linux distributions, and virtualization platforms like VMware and Hyper-V. They are well-supported by software vendors and have extensive compatibility with server-class applications, databases, and enterprise software. Intel provides regular firmware updates, software optimization tools, and developer resources to ensure optimal performance and compatibility with Xeon processors. When choosing an Intel

Xeon processor, consider factors such as workload requirements, core counts, clock speeds, memory support, and specific features needed for your application. It's also important to check Intel's product documentation and consult with hardware experts to select the appropriate Xeon processor model for your server or workstation setup.

BX806736138 Intel Xeon Gold 6138 2.00GHz Server Processor Review

BX806736138 Intel Xeon Gold 6138 2.00GHz Server Processor Review

EMulti-Socket High Performance Server Processor The X806736138 Intel Xeon Gold 6138 20 Cores 2.00GHz Server Processor is designed to deliver high-end performance that supports the highest memory speeds, improved four socket scalability, and built-in workload acceleration. The Gold 6138 process is based on the server configuration, built with Skylake microarchitecture and is manufactured on a 14…

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Intel Core i7 9700K review: Proof gamers don’t need Hyper-Threading

In an effort to match the pace of change, Intel has stuffed another two cores into its mainstream Coffee Lake silicon. Enter: the Intel Core i7 9700K, one of only three 9th Gen processors on the market and the irregular successor to the Core i7 8700K. Introduced alongside the Core i9 9900K and Core i5 9600K, Intel’s 9th Gen launched as it was fighting off a shortfall in production due to overcapacity of its 14nm fabs. But since then Chipzilla has confirmed it intends on launching 10nm mainstream desktop processors sometime toward the end of the year, codename: Intel Sunny Cove. That means these could be the last chips in the high-end gaming space to reuse the Skylake microarchitecture. AMD has been rustling Intel’s jimmies ever since it first launched its Ryzen CPUs. Suddenly Intel’s four-core/eight-thread strategy, which had been the norm for many years, was old fashioned and lagging behind. The resulting core-vs-core showdown that followed has led to the need for this very chip. from https://www.pcgamesn.com/intel/intel-core-i7-9700k-review-performance-coffee-lake-cpu

Intel Continues To Rehire Veterans: At Some Point They'll Run Out

Intel has rehired 28-year veteran Shlomit Weiss into the position of Senior VP and Co-General Manager of Intel's Design Engineering Group (DEG), a position recently vacated by Uri Frank who left to head up Google's SoC development. "Weiss is the latest in an ever-growing list of 're-hiring' Intel veterans, which leads to the problem that at some point Intel will run out of ex-employees to rehire and instead nurture internal talent for those roles," writes Dr. Ian Cutress via AnandTech. From the report: As reported in Tom's Hardware and confirmed in her own LinkedIn announcement, Weiss will be working at Intel's Israel design center alongside Sunil Shenoy and is "committed to ensuring that the company continues to lead in developing chips." [...] In her first 28-year stint at Intel, Weiss is reported to have lead the team that developed both Intel Sandy Bridge and Intel Skylake, arguably two of the company's most important processor families over the last decade: Sandy Bridge reaffirmed Intel's lead in the market with a new base microarchitecture and continues in its 6+th generation in Comet Lake today, while Skylake has been Intel's most profitable microarchitecture ever. Weiss also received Intel's Achievement Award, the company's highest offer, but is not listed as an Intel Fellow, while CRN reports that Weiss also founded the Intel Israel Women Forum in 2014. Weiss left Intel in September 2017 to join Mellanox/NVIDIA, where she held the role of Senior VP Silicon Engineering and ran the company's networking chip design group. In her new role at Intel, Tom's is reporting that Weiss will lead all of Intel's consumer chip development and design, while the other Co-GM of Intel DEG Sunil Shenoy will lead the data center design initiatives. AnandTech goes on to note that Intel has hired 12 veterans since Dec. 20th of last year. "Of these named hires (plenty of other people hired below the role of VP), seven are listed as ex-Intel employees being rehired into the company, mostly into engineering-focused positions," writes Cutress. He continues: It should be noted however that number of engineers that Intel could rehire is limited -- going after key personnel critical to Intel's growth in the last few decades, despite their lists of successful products and accolades, can't be the be-all and end-all of Intel's next decade of growth. If we're strictly adhering to typical retirement ages as well, a number of them will soon be at that level within the next ten years. Intel can't keep rehiring veteran talent into key positions to get to the next phase in its product evolution -- at some level it has to reignite the initial passion from within. [I]f Intel is having to rehire those who enabled former glory for the company, one has to wonder exactly what is going on such that talent already within the company isn't stepping up. At some point these veterans will retire, and Intel will be at a crossroads. In a recent interview with former Intel SVP Jim Keller, he stated that (paraphrased) "building a chip design team at a company depends on volume -- you hire in if you don't have the right people, but if you have a team of 1,000, then there are people there and it's a case of finding the right ones." In a company of 110,000 employees, it seems odd that Intel feels it has to rehire to fill those key roles. Some might question if those rehires would have left in the first place if Intel's brain drain had never occurred, but it poses an interesting question nonetheless.

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Why Should You Go for The 16Gbit DDR4 RAM?

In late 2019, the DRAM semiconductor industry introduced the latest generation high-density DRAM for DDR4. The newer chips stand out because of their wafer lithography, trimmed below 20 nanometres. As a result, DRM has transitioned to 16Gbit density (from 8Gbit), which has resulted in expanded capacities for each module. Now, the total chips needed to meet the previous capacities have been halved.

  Fewer components and nascent wafer technologies on a memory module have minimized power consumption for different types of devices. The benefits of this development have been countless: laptops will receive increased battery life, and data centers and desktops-related costs in offices and homes will drop significantly. Experts believe that this breakthrough will provide a much-needed boost to 5G networks, edge data centers, cloud computing, and other in-demand technologies.

Is This An End of 8Gbit?

The latest development means that manufacturers will ultimately phase out 8Gbit RAM as they turn their focus to 16Gbit RAM. Therefore, it is essential to go for the best computer ram upgrades accordingly.

As a Kingston reseller, Buy Kingston intends to sell 8Gbit RAM for as long as they are available. We prioritize client satisfaction, and for that, we will continue to support your legacy systems for as long as we can.

 Whether you are building an IT infrastructure for your organization or setting up a PC for your home, system lifespan is a key consideration. That is why we recommend you get components that support 16Gbit DRAM. Send us a message to get a high-quality 16Gbit RAM.

    By doing this, you can make sure that your system can be upgraded easily. Here is what you get in return:

Increase the density for RAM capacity by twice

Minimize power consumption

Save money for data centers

Create efficient applications and systems

So, what are the new RAM capacities? Let’s take a look:

Is the New RAM Compatible with the Existing Hardware?

Keep in mind that the newer DRM is not compatible with all systems. Most existing chipsets, such as Intel 9th gen and AMD Ryzen, support it. However, older microarchitectures may or may not be compatible with it.

Intel

The Purley with Cascade Lake (Xeon x2xx Series) supports 16Gbit RAM. However, the Purley with Skylake (Xeon x1xx Series) does not support it.

    Legacy Intel Systems

If you have an Intel system that precedes the 9th generation, view your motherboard or system manufacturer for the latest BIOS and find if the 16Gbit RAM can be used.

AMD Platforms

From mobiles to PCs to servers, AMD platforms provide uniform support for 16Gbit modules. Still, you may have to make some tweaks and update your BIOS, depending on your make and model. Review your motherboard or system manufacturer details for more information.

Do you want to make sure your systems run reliably for a long time? Get in touch with Buy Kingston and get high-quality DDR4 rams. For starters, you can go with this one.

Blog Resource: buykingston.blogspot.com

Which has better processors for gaming

AMD Ryzen 3 3200G

AMD Ryzen 3 3200G.The Ryzen 3 3200 G is a quad-center PC microchip and can measure or access 64-piece of information at once. It is dispatched by the AMD in 2019. This processor depends on the microarchitecture of AMD Zen+ and is produced utilizing 12 nm. The Ryzen 3 3200 G has all the earmarks of resembling its progenitor as a quad-center processor without the concurrent multi-stringing (SMT) innovations. Be that as it may, it accompanies a few amazements, for example, higher tickers, and more store. The Ryzen 3 3200 G is the best spending processor for gaming outfitted with a 3.6 GHz base clock, a 4 GHz support clock, and a 6 MB store.

Attributes

The Ryzen 3 3200 G work area chip comprises of inherent illustrations handling so you don't need to spend extra on a devoted designs card in the event that you are utilizing it in another spending PC construct. Most coordinated designs processors (IGPs, for example, the capacity to show recordings and run applications, offer fundamental usefulness.

The Ryzen 3 3200 G comprises of an Integrated Graphic Processor ("Radeon RX Vega 8"), which is more remarkable than you as a rule find in a processor with the spending plan. It can go about as a substitute for an extremely low-end discrete GPU, similar to the Nvidia GeForce MX250. It offers help for both DisplayPort and video-yield HDMI.

Execution

The chip Ryzen 3 3200 G is viable with most AM4 attachments. The chips additionally have a sensibly evaluated 65-watt power utilization (known as warm plan force, or TDP), which means additionally cost reserve funds as far as both power costs and the alternative to buy a more essential force flexibly for your new development.

The Ryzen 3 3200 G is an amazing processor for building a passage level PC. The chip likewise has better illustrations execution, which is one of the principle purposes behind first choosing a chip from the Ryzen G-arrangement (G is for "designs").

Check also best motherboard for gaming.

Intel Core i5-9400F

Intel Core i5-9400F.The Core i5-9400F is a 64-piece hexa-center PC chip delivered by Intel in mid 2019, which is planned utilizing Intel's improved third era 14nm++ innovation.

Attributes

The Core i5-9400F processor involves six hyper-strung centers running at 2.9 – 4.1 GHz, 9 MB of store L3, memory uphold DDR4-2666, and a 65 W TDP determination.

The Intel Core i5-9400F is one of Intel's six-center work area processors and furthermore the most moderate 6-center CPU.

Execution

The I5-9400F Intel Core is a patched up i5-8400 with an improvement in clock speed of 100 MHz however does exclude a coordinated realistic card.

SmartCache 9 MB is accessible. Intel SmartCache alludes to the design which permits all centers to share each other's admittance to the last store. The Level 3 store is a static memory bank of the processor and is utilized for giving directions. This processor underpins even DDR4-based RAMs with a memory limit of up to 64 GB.

AMD Ryzen 7 2700

AMD Ryzen 7 2700.The AMD Ryzen 7 2700 expands on all that made Ryzen CPUs of the first Generation astounding. It has quicker clock speeds, a calibrated memory regulator, a quicker reserve with lower latencies and performing multiple tasks limit of heavenly 8 center in a 65W bundle. In the second era Ryzen processor family, this is the reasonable eight-center alternative of AMD. It replaces the Ryzen 7 1700, which from a business viewpoint was the most famous Ryzen 7 SKU as a result of its cost and on the grounds that it contains a cooler.

Attributes

The Ryzen 7 2700 highlights 8 centers altogether and 16 strings costing a decent cost. However regardless of these fascinating highlights and hopeful AMD guarantees, this Ryzen 7 2700 is the most ideal alternative for gaming or stringing appropriately.

The Ryzen 7 2700 highlights the Wraith Spire Cooler, which has a RGB LED ring around the fan. You'll locate the new 12-nm Pinnacle Ridge silicon at the center of this Ryzen chip, which additionally originates from AMD. The chip depends on the pristine Zen+ microarchitecture in which the + represents refinement, instead of a critical building update.

The Ryzen 7 2700 has a 20 MB reserve; 16 strings, 8 centers, in addition to a base of 3.2GHz with a 4.1Ghz lift.

The Ryzen 7 2700 can likewise be fitted with 65 Watt TDP, fueled by Extended Frequency Range 2, AVX 2.0, 14 nm semiconductor innovation and DDR-4 smash, AMD SenseMI innovation, AMD virtualization, and FMA4.

Execution

This Ryzen 7 2700 processor from AMD accompanies a pinnacle turbo recurrence of 4.1GHz and a clock speed of 3.2GHz, as the processor is worked for improved multiprocessing execution for the two designers and gamers. Since it is likewise essential for the second era of Ryzen processors, it shows up with 16 MB of reserved L3 memory.

With Ryzen 7 2700 processor, in light of your inclinations, you will have the option to tweak the presentation of the framework. The organization permits you to exploit the Master usefulness that presently includes the Dynamic Local Mode, another component selective to AMD Ryzen and other AMD processors.

AMD Ryzen 5 3600

The AMD Ryzen 5 3600 is an amazing hexa-center processor. This 7 nm processor is the ideal blend of speed and worth dependent on Zen 2 engineering. The Ryzen 5 3600 is a prime silicon piece for gamers point of fact. For the AMD 2019 work area line-up, the Zen 2 design works phenomenally and benefits from the 7 nm measure hub.

Qualities

The processor Ryzen 5 3600 comprises of the X570 chipset that bolsters the new PCIe 4.0 standard. This offers a colossal lift in data transfer capacity to PCIe SSDs and AMD's new Navi cards.

AMD Ryzen 5 3600 Processor additionally offers it's Precision Boost Overdrive (PBO) highlight, a computerized overclocking gadget that will change your processor to its ideal feasible exhibition dependent on its refrigeration, motherboard and power conveyance abilities.

Execution

The Ryzen 5 3600 work area processor has taken a greater jump on account of AMD's Zen 2 engineering. The change moves the CPU from an assembling cycle of 12 nm to a cycle of 7 nm which empowers AMD to improve proficiency, increment directions per clock (or IPC) and drive the velocities of the clock.

The Ryzen 5 3600 is a noteworthy processor that incorporates a lot of intensity into a 65 W TDP shell, a gift for lovers with little structure factor, you can likewise overlock it and accomplish comparable productivity in numerous applications.

AMD Ryzen 5 2400G

Our Initial desires for coordinated designs are re-imagined by the Ryzen 5 2400 G is that it is a lot for best spending gaming CPU and for buying a solitary chip without the additional expense of a GPU. You can change the CPU, memory, and Vega illustrations, and similarity to support execution with the current 300-arrangement motherboard environment is a reward, however you'll have to ensure that the BIOS is viable.

Qualities

It has Great AMD AM4 motherboards similarity. It gives great ongoing interaction execution and overclocking for the coordinated illustrations processor.

The Ryzen 5 2400 G underpins Precision Boost 2. Accuracy Boost is the programmed overclocking innovation utilized by Ryzen which lifts clock speed contingent upon the remaining task at hand. There was either a double center lift recurrence or an all-center lift recurrence in the first form, however with the new form, the lift would differ by the number of the processor's centers are under burden.

Execution

On more seasoned realistic games, for example, Tomb Raider and Sleeping Dogs, the Ryzen 5 2400 G performs phenomenally. At 1080p goal and Standard quality settings, you can arrive at 69 casings for each second (fps) in the in-round of Tomb Raider. That is marginally better than the 60fps (Ryzen 3 2200 G).

The Ryzen 5 2400 G is difficult to beat in the event that you have a little space in your spending plan and need better finished – the-board productivity yet expect to utilize your PC predominantly for little, heritage gaming or non-serious esports passage. In all actuality, for such a modest PC, it is practically ideal, seeing as its gaming-execution advantage.

Intel BX80662G4400

Intel has dispatched the Intel BX80662G4400 Pentium or Pentium G4400 processor. It is a 64bit double center work area PC chip. This processor, which depends on the Skylake microarchitecture and created utilizing a 14 nm measure, has a 3.3 GHz base recurrence with a 54 W TDP. The Pentium G4400 particulars are really normal for a normal home client. It is a double center processor with two strings timed at 3.3GHz and can take 54W of TDP. Other than that numerous highlights of the old arrangement have been viewed as help for 64GB of DDR4 memory.

The Pentium has coordinated illustrations given by the Intel HD Graphics 510 which will utilize a limit of 1.7GB of Ram. The presentation goals can go from 1920×1080 up to 4096×2304 @60Hz utilizing DisplayPort and HDMI. It can likewise uphold up to 3 concurrent showcases. The Pentium G4400 underpins new and up and coming not completely created at this point actually working innovations like Virtualization and Secure Key.

The Pentium G4400 doesn't uphold Turbo Boost and Hyper-Threading. The Pentium G4400 is a spending work area microchip containing 2 centers and 86 piece design and came to advertise in late 2015. The G4400 base recurrence is 3.3 GHz. Likewise, it can draw 54 W of TDP.

If you want to know more about gaming processors.read here

Attributes

It is a double center processor ready to deal with 2 strings at 3.3GHz at once with a 54W TDP. What's more, this likewise has some better highlights, for example, DDR4 or DDR3L double channel 64 GB uphold.

The G4400 comprises of 1 GHz turbo recurrence and 350 MHz running HD Graphics.

The Pentium G4400 underpins new and forthcoming not completely created at this point actually working innovations like Virtualization and Secure Key. The Pentium G4400 doesn't uphold Turbo Boost and Hyper-Threading.

The Pentium G4400 is the best spending gaming processor containing 2 centers and 86 piece design and came to showcase in late 2015. The G4400 base recurrence is 3.3 GHz.

Intel Xeon Cascade Lake CPU Features

The 2nd Generation Xeon Scalable (Cascade Lake) brand of processors will no longer be manufactured by Intel. This news comes after the company made the announcement. It is incredible that Cascade Lake has been around for as long as it has, given that it is two generations behind the CPUs that Intel is now producing (4th Generation Xeon Scalable Sapphire Rapids), yet it has. When this is taken into consideration, it is not hard to understand why the former has been around for such a long time.

Features of the Intel Xeon Cascade Lake CPU

Cascade Lake has been around since 2019, which is the year that it was released by Intel to replace the Skylake microarchitecture, which had been around for a very long period. Cascade Lake is intended to be an improvement over Skylake in a number of ways. You poor thing, Cascade Lake, have gone through a lot of trouble in your life.

Due to the unrelenting competition presented by AMD’s 7nm EPYC Rome CPUs, Intel was forced to make a hasty decision to discontinue several of the Cascade Lake Xeon SKUs that it had previously released. At the same time, it was necessary for the corporation to lower the pricing of the products that were still available. Cascade Lake underwent a refresh not long after that, and not long after that, Xeon Cascade Lake Refresh components were released with a price reduction of up to sixty percent for each core.

Those of you who are familiar with Intel are surely aware that the manufacturer of chips does not make it a practice to cut the costs of its CPUs, much less to issue an update in such a short amount of time. Those of you who are not familiar with Intel may not be aware that Intel has released an update to its processors in such a short period of time.

Cascade Lake’s widely fragmented feature set was a contributor to the collapse of the microarchitecture, which was caused by a combination of factors. One example is that not all Cascade Lake chips were able to support the same amount of memory or Optane DC Persistent Memory DIMMs. On the other hand, AMD’s EPYC Rome product line offered consumers a consistent experience across all of the company’s several product iterations by providing the same feature set.

The manufacturing of Intel’s Cascade Lake-X (high-end desktop) and Cascade Lake-W (workstation) processors was halted in July of this year. The Xeon chips are the next component that will be removed from the system, as was to be expected given the circumstances. Both the tray and packaged forms of the Cascade Lake Xeon CPU will be discontinued as a result of the decision to halt production of the device. PCN is an abbreviation for “Product Change Notification,” and the document that Intel provided featured a list of 68 different Cascade Lake models.

Customers of the semiconductor company have until April 2024 to finalize their purchases with a local Intel representative if they want to do so. Cascade Lake won’t be completely taken off the market for at least another few of years, as Intel has guaranteed that it will fulfill all outstanding orders for Cascade Lake Xeon by October 2026. This date is the latest that Cascade Lake will be completely removed off the market.

Intel stressed in a related PCN report that the company’s attitude toward embedded customers has not changed and that there has been no modification to that policy. Therefore, the 22 people who are still alive today who are considered to be part of the Cascade Lake bloodline are those who have Cascade Lake in their processors.

It should not come as a surprise that the Cascade Lake embedded SKUs will be around for a little bit longer than their socket counterparts because embedded products have a longer life cycle than their socket equivalents. This is because embedded products have a longer life cycle than their socket equivalents. Finally, the transition of Intel’s Cascade Lake embedded chips to the Intel Embedded Architecture has been finished. This change, which will take effect after October 2026 and ensure continued support, will take place.

Intel’s 10th Gen Comet Lake for Desktops: Skylake-S Hits 10 Cores and 5.3 GHz - Today we get the full range of its Intel’s 10th Generation processors for desktops. These chips, which fall under the banner of ‘Comet Lake’, will now go up to 10 cores and offer turbo speeds up to 5.3 GHz. Comet Lake is the fifth iteration of Intel’s very profitable Skylake microarchitectur... / https://ift.tt/2VNfXxA , 2020-05-02T19:16:34.000Z

Hinge presents an anthology of love stories almost never told. Read more on https://no-ordinary-love.co

Watch In 2017, Intel reacted to the threat of Threadripper by pumping out high core count (HCC) Skylake-X processors in the consumer space. And, while processors like the Core i9-7980XE outperformed the highest-end Ryzen Threadripper 1950X, they were also much more expensive, leading more enthusiast consumers to go with AMD’s high-end desktop (HEDT) solution. We expected Intel to follow Skylake-X with Cascade Lake-X, but while Cascade Lake seemed to be destined to exist as a microarchitecture for server-grade hardware, Cascade Lake-X leaks have hinted at a future HEDT release. We’ve already seen some Cascade Lake processors in the small business-focused Intel Core Xeon E processors, so we can’t wait to see what Cascade Lake-X turns into. Just because Cascade Lake is focusing on server chips right now, doesn’t mean that there isn’t excitement to be had, or that it won’t turn into HEDT products later on down the line. So, keep this page bookmarked, as we’ll update it with all the latest infor.. video

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ARM versus x86 IPC (Skylake, Zen, N1, ThunderX2)

I just took Anandtech SPECint single thread scores

https://images.anandtech.com/graphs/graph13959/106739.png

And I got IPC, using the GHz for each core

https://pbs.twimg.com/media/D0vVB0KXgAItXEQ.png

I noticed latter than the ThunderX2 score uses GCC7 compiler, not GCC8. With GCC8 the ThunderX2 score would be slightly bigger. So add about 5--10% to ThunderX2 on both plots.

The conclusion however remains, not only Apple ARM microarchitectures have surpassed Intel on IPC. A N1 chip on 7HPC node could do a more-than-decent desktop machine, specially considering the design scales above 128 cores.

CVE-2018-5407 (Flaw in the Intel processor execution engine sharing on SMT (e.g. Hyper-Threading) architectures.) POC ,

CVE-2018-5407 (Flaw in the Intel processor execution engine sharing on SMT (e.g. Hyper-Threading) architectures.) POC ,

Summary

This is a proof-of-concept exploit of the PortSmash microarchitecture attack, tracked by CVE-2018-5407.

Setup Prerequisites

A CPU featuring SMT (e.g. Hyper-Threading) is the only requirement.

This exploit code should work out of the box on Skylake and Kaby Lake. For other SMT architectures, customizing the strategies and/or waiting times in spy is likely needed.

OpenSSL

Download and…

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Intel CPUs fall to new hyperthreading exploit that pilfers crypto keys

Enlarge (credit: Intel)

Over the past 11 months, the processors running our computers, and in some cases phones, have succumbed to a host of attacks. Bearing names such as Meltdown and Spectre, BranchScope, TLBleed, and Foreshadow, the exploits threaten to siphon some of our most sensitive secrets—say passwords or cryptographic keys—out of the silicon microarchitecture in ways that can’t be detected or stopped by traditional security defenses. On Friday, researchers disclosed yet another leak that has already been shown to exist on a wide range of Intel chips and may also affect other makers, too.

PortSmash, as the new attack is being called, exploits a largely overlooked side-channel in Intel’s hyperthreading technology. A proprietary implementation of simultaneous multithreading, hyperthreading reduces the amount of time needed to carry out parallel computing tasks, in which large numbers of calculations or executions are carried out simultaneously. The performance boost is the result of two logical processor cores sharing the hardware of a single physical processor. The added logical cores make it easier to divide large tasks into smaller ones that can be completed more quickly.

Port contention as a side channel

In a paper scheduled for release soon, researchers document how they were able to exploit the newly discovered leak to recover an elliptic curve private key from a server running an OpenSSL-powered TLS server. The attack, which was carried out on servers running Intel Skylake and Kaby Lake chips and Ubuntu, worked by sending one logical core a steady stream of instructions and carefully measuring the time it took for them to get executed.

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Intel CPUs fall to new hyperthreading exploit that pilfers crypto keys published first on https://medium.com/@HDDMagReview

Security Researchers Detail New 'BlindSide' Speculative Execution Attack

"Security researchers from Amsterdam have publicly detailed 'BlindSide' as a new speculative execution attack vector for both Intel and AMD processors," reports Phoronix: BlindSide is self-described as being able to "mount BROP-style attacks in the speculative execution domain to repeatedly probe and derandomize the kernel address space, craft arbitrary memory read gadgets, and enable reliable exploitation. This works even in face of strong randomization schemes, e.g., the recent FGKASLR or fine-grained schemes based on execute-only memory, and state-of-the-art mitigations against Spectre and other transient execution attacks." From a single buffer overflow in the kernel, researchers claim three BlindSide exploits in being able to break KASLR (Kernel Address Space Layout Randomization), break arbitrary randomization schemes, and even break fine-grained randomization. There's more information on the researcher's web site, and they've also created an informational video. And here's a crucial excerpt from their paper shared by Slashdot reader Hmmmmmm: In addition to the Intel Whiskey Lake CPU in our evaluation, we confirmed similar results on Intel Xeon E3-1505M v5, XeonE3-1270 v6 and Core i9-9900K CPUs, based on the Skylake, KabyLake and Coffee Lake microarchitectures, respectively, as well as on AMD Ryzen 7 2700X and Ryzen 7 3700X CPUs, which are based on the Zen+ and Zen2 microarchitectures. Overall, our results confirm speculative probing is effective on a modern Linux system on different microarchitectures, hardened with the latest mitigations.

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