SK hynix is one of the few vertically integrated manufacturers in the flash-based storage market. The company is well-established in the OEM market. A few years back, they also started exploring direct end-user products. Internal SSDs (starting with the Gold S31 and Gold P31) were the first out of the door. Late last year, the company introduced the Beetle X31 portable SSD, its first direct-attached storage product. In February, a complementary product was introduced - the Tube T31 Stick SSD.

The Beetle X31 is a portable SSD with a Type-C upstream port and a separate cable. The Tube T31 is a take on the traditional thumb drive with a male Type-A interface. The size of the Beetle X31 makes the use of a bridge solution obvious. Our investigation into the Tube T31 also revealed the use of the same internal SSD, albeit with a different bridge. Read on for a detailed look at the Tube T31, including an analysis of its internals and evaluation of its performance consistency, power consumption, and thermal profile.

Corsair has introduced a family of registered memory modules with ECC that are designed for AMD's Ryzen Threadripper 7000 and Intel's Xeon W-2400/3400-series processors. The new Corsair WS DDR5 RDIMMs with AMD EXPO and Intel XMP 3.0 profiles will be available in kits of up to 256 GB capacity and at speeds of up to 6400 MT/s.

Corsair's family of WS DDR5 RDIMMs includes 16 GB modules operating at up to 6400 MT/s with CL32 latency as well as 32 GB modules functioning at 5600 MT/s with CL40 latency. At present, Corsair offers a quad-channel 64 GB kit (4×16GB, up to 6400 MT/s), a quad-channel 128GB kit (4×32GB, 5600 MT/s), an eight-channel 128 GB kit (8×16GB, 5600 MT/s), and an eight-channel 256 GB kit (8×32GB, 5600 MT/s) and it remains to be seen whether the company will expand the lineup.

Corsair's WS DDR5 RDIMMs are designed for AMD's TRX50 and WRX90 platforms as well as Intel's W790 platform and are therefore compatible with AMD's Ryzen Threadripper Pro 7000 and 7000WX-series as well as Intel's Xeon W-2400/3400-series CPUs. The modules feature both AMD EXPO and Intel XMP 3.0 profiles to easily set their beyond-JEDEC-spec settings and come with thin heat spreaders made of pyrolytic graphite sheet (PGS), which thermal conductivity than that of copper and aluminum of the same thickness. For now, Corsair does not disclose which RCD and memory chips its registered memory modules use.

Unlike many of its rivals among leading DIMM manufacturers, Corsair did not introduce its enthusiast-grade RDIMMs when AMD and Intel released their Ryzen Threadripper and Xeon W-series platforms for extreme workstations last year. It is hard to tell what the reason for that is, but perhaps the company wanted to gain experience working with modules featuring registered clock drivers (RCDs) as well as AMD's and Intel's platforms for extreme workstations.

The result of the delay looks to be quite rewarding: unlike modules from its competitors that either feature AMD EXPO or Intel XMP 3.0 profiles, Corsair's WS DDR5 RDIMMs come with both. While this may not be important on the DIY market where people know exactly what they are buying for their platform, this is a great feature for system integrators, which can use Corsair WS DDR5 RDIMMs both for their AMD Ryzen Threadripper and Intel Xeon W-series builds, something that greatly simplifies their inventory management.

Since Corsair's WS DDR5 RDIMMs are aimed at workstations and are tested to offer reliable performance beyond JEDEC specifications, they are quite expensive. The cheapest 64 GB DDR5-5600 CL40 kit costs $450, the fastest 64 GB DDR5-6400 CL32 kit is priced at $460, whereas the highest end 256 GB DDR5-5600 CL40 kit is priced at $1,290.

Western Digital this week is previewing the industry's first 4 TB SD card. The device is being showcased at the NAB trade show for broadcasters and content creators and will be released commercially in 2025.

Western Digital's SanDisk Extreme Pro SDUC 4 TB SD card complies with the Secure Digital Ultra Capacity standard (SDUC, which enables up to 128TB). The card uses the Ultra High Speed-I (UHS-I) interface and is rated for speed Class 10, therefore supporting a minimum speed of 10 MB/s and a maximum data transfer rate of 104 MB/s when working in UHS104 (SDR104) mode (there is a catch about performance, but more on that later). WD's SD card is also rated to meet Video Speed Class V30, supporting a minimal sequential write speed of 30 MB/s, which is believed to be good enough for 8K video recording, above and beyond the 4K video market that Western Digital is primarily aiming the forthcoming card at.

For now, Western Digital is not disclosing what NAND is in the SanDisk Extreme Pro SDUC 4 TB SD card. Given the high capacity and relatively distant 2025 release date, WD may be targetting this as one of their first products to use their forthcoming BiCS 9 NAND.

And while not listed in WD's official press release, we would be surprised if the forthcoming card didn't also support the off-spec DDR200/DDR208 mode, which allows for higher transfer rates than the UHS-I standard normally allows via double data rate signaling. Western Digital's current-generation SanDisk Extreme Pro SDXC 1 TB SD card already supports that mode, allowing it to reach read speeds as high as 170 MB/s, so it would be surprising to see the company drop it from newer products. That said, the catch with DDR208 remains the same as always: it's a proprietary mode that requires a compatible host to make use of.

Western Digital has not disclosed how much will its SanDisk Extreme Pro SDUC 4 TB SD card cost. A 1 TB SanDisk Extreme Pro card costs $140, so one can make guesses about the price of a 4 TB SD card that uses cutting-edge NAND.

AMD has recently expanded its Ryzen 8000 series by introducing the Ryzen 7 8700F and Ryzen 5 8400F processors. Initially launched in China, these chips were added to AMD's global website, signaling they are available worldwide, apparently from April 1st. Built from the recent Zen 4-based Phoenix APUs using the TSMC 4nm node as their Zen 4 mobile chips, these new CPUs lack integrated graphics. However, the Ryzen 7 8700F does include the integrated Ryzen AI NPU for added capabilities in a world currently dominated by AI and moving it directly into the PC.

The company's decision to announce these chips in China aligns with its strategy to offer Ryzen solutions at every price point in the market. Although AMD didn't initially disclose the full specifications of these F-series models, and we did reach out to the company to ask about them, they refused to discuss them with us. Their listing on the website has now been updated with a complete list of specifications and features, with everything but the price mentioned.

The Ryzen 7 8700F features an 8C/16T design, with 16MB of L3 cache and the same 65W TDP as the Ryzen 7 8700G. Although the base clock speed is 4.1 GHz, it boosts to 5.0 GHz; this is 100 MHz less on both base/boost clocks than the 8700G. Meanwhile, the Ryzen 5 8400F is a slightly scaled-down version of the Ryzen 8600G APU, with 6C/12, 16MB of L3 cache, and again has a 100 MHz reduction to base clocks compared to the 8600G. Unlike the Ryzen 5 8400F, the Ryzen 7 8700F keeps AMD's Ryzen AI NPU, adding additional capability for generative AI. 

The Ryzen 5 8400F can boost up to 4.7 GHz, 300 MHz slower than the Ryzen 5 8600G. AMD also allows overclocking for these new F-series chips, which means users could potentially boost the performance of these processors to match their G-series equivalents.

Pricing details are still pending, but to remain competitive, AMD will likely need to price these CPUs below the 8700G and 8600G, as well as the Ryzen 7 7700 and Ryzen 5 7600. These CPUs offer, albeit very limited, integrated graphics and have double the L3 cache capacity, along with higher boost clocks than the 8000F series chips, so pricing is something to consider whenever pricing becomes available.

During the main keynote at Intel Vision 2024, Intel CEO Pat Gelsinger flashed a completed Lunar Lake chip off, much like EVP and General Manager of Intel's Client Computing Group (CCG) Michelle Johnston Holthaus did back at CES 2024. The contrast between the two glimpses of the Lunar Lake chip is that Pat Gelsinger gave us something juicier than just a photo op. He clarified and claimed the levels of AI performance we can expect to see when Lunar Lake launches.

According to Intel's CEO Pat Gelsinger, Lunar Lake, scheduled to be launched towards the end of this year, is set to raise the bar even further regarding on-chip AI capabilities and performance. At Intel's own Vision event, aptly named Intel Vision, current CEO of Intel Pat Gelsinger stated during his presentation that Lunar Lake will be the 'flagship SoC' for the next generation of AI PCs. Intel claims that Lunar Lake will have 3X the AI performance of their current Meteor Lake SoC, which is impressive as Meteor Lake is estimated to be running around 34 TOPS combined with the NPU, GPU, and CPU.

Factoring in the NPU within Meteor Lake, 11 of the 34 TOPS come solely from the NPU. Still, Intel claims that the NPU on Lunar Lake will hit a large 45 TOPs, akin to the Hailo-10 add-in card and similar to Qualcomm's Snapdragon X Elite processor. Factoring in the integrated graphics and the compute cores, Intel is claiming a combined total of over 100 TOPS, and with Microsoft's self-imposed guidelines of what constitutes an 'AI PC' coming in at 40 TOPS, Intel's NPU fits the bill.

Intel also alludes to how they are gaining a load of TOPS performance from the NPU, whether that be with new technologies; the NPU will likely be built in a more advanced node, perhaps Intel 18A. Another thing Intel didn't highlight was how they were measuring the TOPS performance, whether that be INT8 or INT4.

Still, one thing is clear: Intel wants to increase on-chip AI capabilities in desktop PCs and notebooks with each generation. Intel is also attempting to leverage more AI performance to help boost its goal to ship 100 million AI PCs by the end of 2025. Intel has already announced that it's shipped 5 million thus far and plans to sell another 40 million units by the end of the year.

One of the most significant talking points of the last six months in mobile computing has been Intel and their disaggregated Meteor Lake SoC architecture. Meteor Lake, along with the new Core and Core Ultra naming scheme, also heralds the dawn of their first tiled architecture for the mobile landscape on the latest Intel 4 node with Foveros packaging. In December last year, Intel unveiled their premier Meteor lake-based Core Ultra H series, with five SKUs ranging from two with 4P+8E+2LP/18T and three with 6P+8E+2LP/22T models. Since then, many vendors and manufacturers have launched notebooks capitalizing on Intel's latest multi-tiled Meteor Lake SoC architecture as the heart of power and performance, driving their latest models into 2024.

Today, we will focus on an attractive ultrabook via the ASUS Zenbook 14 OLED (UX3405MA), which features a thin and light design and is powered by Intel's latest Meteor Lake Core Ultra 7 155H processor. While much of the attention is going to come on how the Intel Core Ultra 7 155H with its 6P+8E+2LP/22T configuration and 8 Arc Xe integrated graphics cores will perform, the ASUS Zenbook 14 OLED UX3405MA has plenty of features within its sleek Ponder Blue colored shell to make it very interesting. Included is a 14" 3K (2880 x 1800) touchscreen OLED panel with a 120 Hz refresh rate, 32 GB of LPDDR5X memory (soldered), and a 1 TB NVMe M.2 SSD for storage.

In an unexpected move, Intel has announced plans to phase out the boxed versions of its enthusiasts-class 13^th Generation Core 'Raptor Lake' processors. According to a product change notification (PCN) published by the company last month, Intel plans to stop shipping these desktop CPUs by late June. In its place will remain Intel's existing lineup of boxed 14^th Generation Core processors, which are based on the same 'Raptor Lake' silicon and typically carry higher performance for similar prices.

Intel customers and distributors interested in getting boxed versions 13^th Generation Core i5-13600K/KF, Core i7-13700K/KF, and Core i9-13900K/KF/KS 'Raptor Lake' processors with unlocked multiplier should place their orders by May 24, 2024. The company will ship these units by June 28, 2024. Meanwhile, the PCN does not mention any change to the availability of tray versions of these CPUs, which are sold to OEMs and wholesalers.

The impending discontinuation of Intel's boxed 13^th Generation Core processors comes as the company's current 14^th Generation product line, 'Raptor Lake Refresh' is largely a rehash of the same silicon at slightly higher clockspeeds. Case in point: all of the discontinued SKUs are based on Intel's B0 Raptor Lake silicon, which is still being used for their 14^th Gen counterparts. So Intel has not discontinued producing any Raptor Lake silicon; only the number of retail SKUs is getting cut-down.

As outlined in our 14^th Generation Core/Raptor Lake Refresh review, the 14^th Gen chips largely make their 13^th Gen counterparts redundant, offering better performance at every tier for the same list price. And with virtually all current generation motherboards supporting both generation of chips, apparently Intel feels there's little reason to keep around what's essentially older, slower SKUs of the same silicon.

Interestingly, the retirement of the enthusiast-class 13^th Generation Core chips is coming before Intel discontinues their even older 12^th Generation Core 'Alder Lake' processors. 12^th Gen chips are still available to this day in both boxed and tray versions, and the Alder Lake silicon itself is still widely in use in multiple product families. So even though Alder Lake shares the same platform as Raptor Lake, the chips based on that silicon haven't been rendered redundant in the same way that 13^th Gen Core chips have.

Ultimately, it would seem that Intel is intent on consolidating and simplifying its boxed retail chip offerings by retiring their near-duplicate SKUs. Which for PC buyers could present a minor opportunity for a deal, as retailers work to sell off their remaining 13^th Gen enthusiast chips.

Following the magnitude 7.2 earthquake that struck Taiwan on April 3, 2024, there was immediate concern over what impact this could have on chip production within the country. Even for a well-prepared country like Taiwan, the tremor was the strongest quake to hit the region in 25 years, making it no small matter. But, according to research compiled by TrendForce, the impact on the production of DRAM will not be significant. The market tracking company believes that Taiwanese DRAM industry has remained largely unaffected, primarily due to their robust earthquake preparedness measures.

There are four memory makers in Taiwan: Micron, the sole member of the "big three" memory manufacturers on the island, runs two fabs. Meanwhile among the smaller players is Nanya (which has one fab), Winbond (which makes specialty memory at one fab), and PSMC (which produces specialty memory at one plant). The study found that these DRAM producers quickly resumed full operations, but had to throw away some wafers. The earthquake is estimated to have a minor effect on Q2 DRAM production, with a negligible 1% impact, TrendForce claims

In fact, as Micron is ramping up production of DRAM on its 1alpha and 1beta nm process technologies, it increases bit production of memory, which will positively affect supply of commodity DRAM in Q2 2025.

Following the earthquake, there was a temporary halt in quotations for both the contract and spot DRAM markets. However, the spot market quotations have already largely resumed, while contract prices have not fully restarted. Notably, Micron and Samsung ceased issuing quotes for mobile DRAM immediately after the earthquake, with no updates provided as of April 8th. In contrast, SK hynix resumed quotations for smartphone customers on the day of the earthquake and proposed more moderate price adjustments for Q2 mobile DRAM.

TrendForce anticipates a seasonal contract price increase for Q2 mobile DRAM of between 3% and 8%. This moderate increase is partly due to SK hynix's more restrained pricing strategy, which is likely to influence overall pricing strategies across the industry. The earthquake's impact on server DRAM primarily affected Micron's advanced fabrication nodes, potentially leading to a rise in final sale prices for Micron's server DRAM, according to TrendForce. However, the exact direction of future prices remains to be seen.

Meanwhile, DRAM fabs outside of Taiwan have none been directly affected by the quake. This includes Micron's HBM production line in Hiroshima, Japan, and Samsung's and SK hynix's HBM lines in South Korea, all of which are apparently operating with business as usual.

In general, the DRAM industry has shown resilience in the face of the earthquake, with minimal disruptions and a quick recovery. The abundant inventory levels for DDR4 and DDR5, coupled with weak demand, suggest that any slight price elevations caused by the earthquake are expected to normalize quickly. The only potential outlier here is DDR3, which is nearing the end of its commercial lifetime and production is already decreasing.

Google was among the first hyperscalers build custom silicon for its services, starting first with tensor processing units (TPUs) for its AI initiatives, and then video transcoding units (VCUs) for the YouTube service. But unlike its industry peers, the company has been slower to adopt custom CPU designs, prefering to stick to off-the-shelf chips from the major CPUs. This is finally changing at Google, with the announcement that the company has developed its own in-house datacenter CPU, the Axion.

Google's Axion processor is based on the Arm Neoverse V2 (Arm v9) platform, which is Arm's current-generation design for high-performance server CPUs, and is already employed in other chips such as NVIDIA's Grace and Amazon's Graviton4. Within Google, Axion is aimed at a wide variety of workloads, including web and app servers, data analytics, microservices, and AI training. Google claims that the Axion processors boast up to 50% higher performance and up to 60% better energy efficiency compared to current-generation x86-based processors, as well as offer a 30% higher performance compared to competing Arm-based CPUs for datacenters. Though as is increasingly common for the cryptic cloud side of Google's business, least for now the company isn't specifying what processors they're comparing Axion to in these metrics.

While Google is not disclosing core counts or the full specifications of its Axion CPUs, the company is revealing that they are incorporating their own secret sauce into the silicon in the form of the company's Titanium purpose-built microcontrollers. These microcontrollers are designed to handle basic operations like networking and security, as well as offload storage I/O processing to Hyperdisk block storage service. As a result of this offloading, virtually all of the CPU core resources should be available to actual workloads. As for the chip's memory subsystem, Axion uses conventional dual-rank DDR5 memory modules.

"Google's announcement of the new Axion CPU marks a significant milestone in delivering custom silicon that is optimized for Google's infrastructure, and built on our high-performance Arm Neoverse V2 platform," said Rene Haas, CEO of Arm. "Decades of ecosystem investment, combined with Google's ongoing innovation and open-source software contributions ensure the best experience for the workloads that matter most to customers running on Arm everywhere." 

Google has previously deployed Arm-based processors for its own services, including BigTable, Spanner, BigQuery, and YouTube Ads and is ready to offer instances based on its Armv9-based Axion CPUs to its customers that can use software developed for Arm architectures.

Sources: Google, Wall Street Journal

At Intel's Vision 2024 event, which is being held in Phoenix, AZ, has seen several key announcements. On the datacenter CPU front, Intel is using the show to unveil their newest branding for their venerable family of Xeon processors. Beginning with this year's sixth generation of processors, Intel is "evolving" the Xeon brand by retiring the "Xeon Scalable" branding in favor of Intel's new and simplified "Xeon 6" brand.

The Xeon 6 family is set to launch later this year with two primary variants: an all-performance (P) core chip codenamed Granite Rapids, and an all-efficiency (E) core chip codenamed Sierra Forest. Both of these chips will be sold under the Xeon 6 brand and sit on top of the same motherboard platform, with the Xeon 6 branding intended in part to underscore this shared platform. Though speaking of the chips themselves, at this time Intel isn't illustrating how the two sub-series of chips will be differentiated in terms of product numbers.

Over the last year, we've extensively covered Intel's Granite Rapids and Sierra Forest. For more information about Granite Rapids and Sierra Forest, here are some of our key pieces:

• Hot Chips 2023: Intel Details More on Granite Rapids and Sierra Forest Xeons
• Intel Previews Sierra Forest with 288 E-Cores, Announces Granite Rapids-D for 2025 Launch at MWC 2024
• IFS Reborn as Intel Foundry: Expanded Foundry Business Adds 14A Process To Roadmap

Intel debuted their Xeon Scalable branding in 2017 with the launch of the Xeon Platinum 8100 series, which was built using their Skylake microarchitecture. At the time Xeon Scalable replaced Intel's older Xeon E/EP/EX vX branding, resetting the generation count in the process.

Moving forward to 2024, Intel is looking to build an ecosystem befitting the current demands of technologies within key areas such as data centers, Edge, and the PC. Intel is laying the foundations for what it calls 'Intel Enterprise AI.' Using a vast array of frameworks and accelerators and working closely with partners, ISVs, and GSIs to create a large and open ecosystem, the newly branded Intel Xeon 6 platforms will be key in the enterprise market as we advance.

Intel has adopted a newer and simpler nomenclature for Granite Rapids and Sierra Forest, starting with the Intel Xeon 6 processors. Sierra Forest Xeon 6 processors are set to launch in Q2 of 2024, which include a chip featuring 288 E-cores. It will be the first product to adopt this new branding, which is designed to ease customer navigation between models. Meanwhile the Xeon 6 P-core Granite Rapids processors will come later.

Ultimately, the Xeon brand itself and what it entails (enterprise, workstation, server, and data center) isn't going anywhere. Instead, Intel is putting an increased focus on the generation number of the platform by moving it front and center, to more clearly highlight what generation of technology a part belongs to.

As mentioned, Intel's Xeon 6 processors, based on their Sierra Forest architecture, are set to launch in Q2 2024, while the Granite Rapids Xeon 6 platform is expected to come sometime in the second half of 2024.

Gallery: Intel Vision 2024 Press Deck

Intel this morning is kicking off the second day of their Vision 2024 conference, the company’s annual closed-door business and customer-focused get-together. While Vision is not typically a hotbed for new silicon announcements from Intel – that’s more of an Innovation thing in the fall – attendees of this year’s show are not coming away empty handed. With a heavy focus on AI going on across the industry, Intel is using this year’s event to formally introduce the Gaudi 3 accelerator, the next-generation of Gaudi high-performance AI accelerators from Intel’s Habana Labs subsidiary.

The latest iteration of Gaudi will be launching in the third quarter of 2024, and Intel is already shipping samples to customers now. The hardware itself is something of a mixed bag in some respects (more on that in a second), but with 1835 TFLOPS of FP8 compute throughput, Intel believes it’s going to be more than enough to carve off a piece of the expansive (and expensive) AI market for themselves. Based on their internal benchmarks, the company expects to be able beat NVIDIA’s flagship Hx00 Hopper architecture accelerators in at least some critical large language models, which will open the door to Intel grabbing a larger piece of the AI accelerator market at a critical time in the industry, and a moment when there simply isn’t enough NVIDIA hardware to go around.

TSMC has entered into a preliminary agreement with the U.S. Department of Commerce, securing up to $6.6 billion in direct funding and access to up to $5 billion in loans under the CHIPS and Science Act. With this latest round of support from the U.S. government, TSMC in turn will be adding a third fab to their Arizona project, with its investment in the region soaring to more than $65 billion. This move not only signifies the largest foreign direct investment in Arizona but also marks one of the biggest support packages that the U.S. government plans to make under the CHIPS Act, second only to Intel's $8.5 billion award last month.

TSMC is currently equipping its Fab 21 phase 1 and expects that it will start making chips using N4 and N5 (4 nm and 5 nm-class) process technologies in the first half of 2025. TSMC's Fab 21 phase 2 will commence operations in 2028, and will make chips on N3 and N2 (3 nm and 2 nm-class) production nodes. The newly-announced third fab (designation TBD) is set to manufacture chips on processes of 2 nm-class or beyond, with the start of production anticipated by the end of the decade.

TSMC has not announced a planned capacity for the new fab, only noting that it will be similar to the other two Arizona fabs, boasting a cleanroom space roughly twice as large as that of a typical "industry-standard logic fab." If it is sized similarly to the other Arizona fabs, then this strongly implies that the new fab will be another MegaFab-class facility – a mid-range fab producing around 25,000 wafer starts per month. TSMC does operate even larger fabs – the 100K WSPM GigaFab – though to date they've yet to build any of these outside of Taiwan.

“The CHIPS and Science Act provides TSMC the opportunity to make this unprecedented investment and to offer our foundry service of the most advanced manufacturing technologies in the United States,” said TSMC Chairman Dr. Mark Liu. “Our U.S. operations allow us to better support our U.S. customers, which include several of the world’s leading technology companies. Our U.S. operations will also expand our capability to trailblaze future advancements in semiconductor technology.”

The construction of three fabs in Arizona is poised to generate approximately 6,000 direct high-tech jobs, contributing significantly to the creation of a skilled workforce. This workforce is expected to play a crucial role in fostering a dynamic and competitive global semiconductor ecosystem. Moreover, the project is projected to create over 20,000 construction jobs, in addition to spawning tens of thousands of indirect jobs related to suppliers and consumer services.

AMD, Apple, and NVIDIA fully support TSMC's project and all of them expressed interest in using TSMC's capacities in the U.S.

“Today’s announcement highlights the strong commitment from Secretary Raimondo and the entire administration to ensure the U.S. plays a central role creating a more geographically diverse and resilient semiconductor supply chain,” said AMD Chair and CEO Lisa Su. “TSMC has a long track record of providing the leading-edge manufacturing capabilities that have enabled AMD to focus on what we do best, designing high-performance chips that change the world. We are committed to our partnership with TSMC and look forward to building our most advanced chips in U.S.”

TSMC's ventures in Arizona have encountered obstacles, such as setbacks caused by labor shortages and doubts about the U.S. governmental funding. As a result, production at the second facility has been postponed from 2026 to 2028. Moreover, Bloomberg has reported that at least one supplier for TSMC has called off its intended project in Arizona, attributing the decision to challenges in securing a workforce. The address the workforce issues, the TSMC grant includes a $50 million allocation for training of the local workforce.

Sources: TSMC, Bloomberg

In the arena of PC components, Be quiet! is a name synonymous with excellence, known for its fusion of silent functionality and exceptional performance. The company's broad range of products, from high-end power supply units (PSUs) to sophisticated cases and cooling solutions, including both air and liquid options, is crafted with a keen eye on reducing noise while maximizing efficiency. Be quiet! has earned accolades for its dedication to achieving near-silent operation across its lineup, making it a preferred choice among those in the PC enthusiast community who seek a serene computing environment. The diversity of its offerings reflects a deep understanding of the needs of tech enthusiasts and professionals alike, with each product designed to offer a blend of low noise levels and high efficiency.

Today we're looking at he Be quiet! Straight Power 12 750W PSU, a high-tier offering in Be quiet!'s PSU portfolio that exemplifies the brand's approach to product design. The Straight Power 12 series is engineered to deliver top performance and whisper-quiet operation, appealing to users who seek the optimal mix of power efficiency and sound level, without compromising on reliability and premium quality. The 750 Watt model that we are reviewing today is the weakest unit of the series, yet still enough to effortlessly power a modern gaming system with a mid-tier GPU.

SK hynix this week announced plans to build its advanced memory packaging facility in West Lafayette, Indiana. The move can be considered as a milestone both for the memory maker and the U.S., as this is the first advanced memory packaging facility in the country and the company's first significant manufacturing operation in America. The facility will be used to build next-generation types of high-bandwidth memory (HBM) stacks when it begins operations in 2028. Also, SK hynix agreed to work on R&D projects with Purdue University.

"We are excited to become the first in the industry to build a state-of-the-art advanced packaging facility for AI products in the United States that will help strengthen supply-chain resilience and develop a local semiconductor ecosystem," said SK hynix CEO Kwak Noh-Jung.

One of The Most Advanced Chip Packaging Facility Ever

The facility will handle assembly of HBM known good stacked dies (KGSDs), which consist of multiple memory devices stacked on a base die. Furthermore, it will be used to develop next-generations of HBM and will therefore house a packaging R&D line. However, the plant will not make DRAM dies themselves, and will likely source them from SK hynix's fabs in South Korea.

The plant will require SK hynix to invest $3.87 billion, which will make it one of the most advanced semiconductor packaging facilities in the world. Meanwhile, SK hynix held the investment agreement ceremony with representatives from Indiana State, Purdue University, and the U.S. government, which indicates parties financially involved in the project, but this week's event did not disclose whether SK hynix will receive any money from the U.S. government under the CHIPS Act or other funding initiatives.

The cost of the facility significantly exceeds that of packaging facilities built by other major players in the industry, such as ASE Group, Intel, and TSMC, which highlights how significant of an investment this is for SK hnix. In fact, $3.87 billion higher than advanced packaging CapEx budgets of Intel, TSMC and Samsung in 2023, based on estimates from Yole Intelligence.

Given that the fab comes online in 2028, based on SK hynix's product roadmap we'd expect that it will be used at least in part to assemble HBM4 and HBM4E stacks. Notably, since HBM4 and HBM4E stacks are set to feature a 2048-bit interface, their packaging process will be considerably more complex than the existing 1024-bit HBM3/HBM3E packaging and will require usage of more advanced tools, which is why it is poised to be more expensive than some existing advanced packaging facilities. Due to the extremely complex 2048-bit interface, many chip designers who are going to use HBM4/HBM4E are expected to integrate it directly onto their processors using hybrid bonding and not use silicon interposers. Unfortunately, it is unclear whether the SK hynix facility will be able to offer such service.

HBM is mainly used for AI and HPC applications, so it is strategically important to have its production in the U.S. Meanwhile, actual memory dies will still need to be made elsewhere, at dedicated DRAM fabs.

Purdue University Collaboration

In addition to support set to be provided by state and local governmens, SK hynix chose to establish its new facility in West Lafayette, Indiana, to collaborate with Purdue University as well as with Purdue's Birck Nanotechnology Center on R&D projects, which includes advanced packaging and heterogeneous integration.

SK hynix intends to work in partnership with Purdue University and Ivy Tech Community College to create training programs and multidisciplinary degree courses aimed at nurturing a skilled workforce and establishing a consistent stream of emerging talent for its advanced memory packaging facility and R&D operations.

"SK hynix is the global pioneer and dominant market leader in memory chips for AI," Purdue University President Mung Chiang said. "This transformational investment reflects our state and university's tremendous strength in semiconductors, hardware AI, and hard tech corridor. It is also a monumental moment for completing the supply chain of digital economy in our country through chips advanced packaging. Located at Purdue Research Park, the largest facility of its kind at a U.S. university will grow and succeed through innovation."

PCI-SIG this week released version 0.5 of the PCI-Express 7.0 specification to its members. This is the second draft of the spec and the final call for PCI-SIG members to submit their new features to the standard. The latest update on the development of the specification comes a couple months shy of a year after the PCI-SIG published the initial Draft 0.3 specificaiton, with the PCI-SIG using the latest update to reiterate that development of the new standard remains on-track for a final release in 2025.

PCIe 7.0 is is the next generation interconnect technology for computers that is set to increase data transfer speeds to 128 GT/s per pin, doubling the 64 GT/s of PCIe 6.0 and quadrupling the 32 GT/s of PCIe 5.0. This would allow a 16-lane (x16) connection to support 256 GB/sec of bandwidth in each direction simultaneously, excluding encoding overhead. Such speeds will be handy for future datacenters as well as artificial intelligence and high-performance computing applications that will need even faster data transfer rates, including network data transfer rates.

To achieve its impressive data transfer rates, PCIe 7.0 doubles the bus frequency at the physical layer compared to PCIe 5.0 and 6.0. Otherwise, the standard retains pulse amplitude modulation with four level signaling (PAM4), 1b/1b FLIT mode encoding, and the forward error correction (FEC) technologies that are already used for PCIe 6.0. Otherwise, PCI-SIG says that the PCIe 7.0 speicification also focuses on enhanced channel parameters and reach as well as improved power efficiency. 

Overall, the engineers behind the standard have their work cut out for them, given that PCIe 7.0 requires doubling the bus frequency at the physical layer, a major development that PCIe 6.0 sidestepped with PAM4 signaling. Nothing comes for free in regards to improving data signaling, and with PCIe 7.0, the PCI-SIG is arguably back to hard-mode development by needing to improve the physical layer once more – this time to enable it to run at around 30GHz. Though how much of this heavy lifting will be accomplished through smart signaling (and retimers) and how much will be accomplished through sheer materials improvements, such as thicker printed circuit boards (PCBs) and low-loss materials, remains to be seen.

The next major step for PCIe 7.0 is finalization of the version 0.7 of specification, which is considered the Complete Draft, where all aspects must be fully defined, and electrical specifications must be validated through test chips. After this iteration of the specification is released, no new features can be added. PCIe 6.0 eventually went through 4 major drafts – 0.3, 0.5, 0.7, and 0.9 – before finally being finalized, so PCIe 7.0 is likely on the same track.

Once finalized in 2025, it should take a few years for the first PCIe 7.0 hardware to hit the shelves. Although development work on controller IP and initial hardware is already underway, that process extends well beyond the release of the final PCIe specification.

Composable disaggregated data center infrastructure promises to change the way data centers for modern workloads are built. However, to fully realize the potential of new technologies, such as CXL, the industry needs brand-new hardware. Recently, Samsung introduced its CXL Memory Module Box (CMM-B), a device that can house up to eight CXL Memory Module – DRAM (CMM-D) devices and add plenty of memory connected using a PCIe/CXL interface.

Samsung's CXL Memory Module Box (CMM-B) is the first device of this type to accommodate up to eight 2 TB E3.S CMM-D memory modules and add up to 16 TB of memory to up to three modern servers with appropriate connectors. As far as performance is concerned, the box can offer up to 60 GB/s of bandwidth (which aligns with what a PCIe 5.0 x16 interface offers) and 596 ns latency. 

From a pure performance point of view, one CXL Memory Module—Box is slower than a dual-channel DDR5-4800 memory subsystem. Yet, the unit is still considerably faster than even advanced SSDs. At the same time, it provides very decent capacity, which is often just what the doctor ordered for many applications.

The Samsung CMM-B is compatible with the CXL 1.1 and CXL 2.0 protocols. It consists of a rack-scale memory bank (CMM-B), several application hosts, Samsung Cognos management console software, and a top-of-rack (ToR) switch. The device was developed in close collaboration with Supermicro, so expect this server maker to offer the product first.

Samsung's CXL Memory Module – Box is designed for applications that need a lot of memory, such as AI, data analytics, and in-memory databases, albeit not at all times. CMM-B allows the dynamic allocation of necessary memory to a system when it needs this memory and then uses DRAM with other machines. As a result, operators of datacenters can spend money on procuring expensive memory (16 TB of memory costs a lot), reduce power consumption, and add flexibility to their setups.

Rapidus, a Japan-based company developing 2nm process technology and aiming to commercialize it in 2027, will receive a huge government grant for its ongoing projects. The Japanese government will support Rapidus with subsidies totaling ¥590 billion yen ($3.89 billion). In addition to developing its 2nm production node and spending on cleanroom equipment, Rapidus will also fund the development of multi-chiplet packaging technology.

This extra funding will significantly help the company's ambitious plans. With the government's total support now at ¥920 billion ($6.068 billion), Rapidus is getting a solid push to become a significant player in the semiconductor industry. The whole project is expected to cost around ¥5 trillion ($32.983 billion), so the funding is not quite there yet. Meanwhile, the company may get enough financing with support from the Japanese government and large Japanese conglomerates like Toyota Motor and Nippon Telegraph and Telephone.

According to Atsuyoshi Koike, Rapidus's chief executive, the company is on track to start testing its production by April 2025 and aims to begin large-scale production by 2027. Commercial production of 2nm chips is set to commence sometime in 2025.

In addition to developing its 2nm fabrication process in collaboration with IBM and building its manufacturing facility, Rapidus is also working on advanced packaging technology for multi-chiplet system-in-packages (SiPs). The latest government subsidies include more than ¥50 billion ($329.85 million) for research and development in this area, the first time Japan has provided subsidies for such technologies.

It is noteworthy that Rapidus will use a section of Seiko Epson Corporation's Chitose Plant (located in Chitose City, Hokkaido) for its back-end packaging processes. This plant is near the company's fab, which is currently being built in Bibi World, an industrial park in Chitose City. This space will be dedicated to pilot-stage research and development activities.

Sources: Rapidus, Nikkei

Introspect this week introduced its M5512 GDDR7 memory test system, which is designed for testing GDDR7 memory controllers, physical interface, and GDDR7 SGRAM chips. The tool will enable memory and processor manufacturers to verify that their products perform as specified by the standard.

One of the crucial phases of a processor design bring up is testing its standard interfaces, such as PCIe, DisplayPort, or GDDR is to ensure that they behave as specified both logically and electrically and achieve designated performance. Introspect's M5512 GDDR7 memory test system is designed to do just that: test new GDDR7 memory devices, troubleshoot protocol issues, assess signal integrity, and conduct comprehensive memory read/write stress tests.

The product will be quite useful for designers of GPUs/SoCs, graphics cards, PCs, network equipment and memory chips, which will speed up development of actual products that rely on GDDR7 memory. For now, GPU and SoC designers as well as memory makers use highly-custom setups consisting of many tools to characterize signal integrity as well as conduct detailed memory read/write functional stress testing, which are important things at this phase of development. But usage of a single tool greatly speeds up all the processes and gives a more comprehensive picture to specialists.

The M5512 GDDR7 Memory Test System is a desktop testing and measurement device that is equippped with 72 pins capable of functioning at up to 40 Gbps in PAM3 mode, as well as offering a virtual GDDR7 memory controller. The device features bidirectional circuitry for executing read and write operations, and every pin is equipped with an extensive range of analog characterization features, such as skew injection with femto-second resolution, voltage control with millivolt resolution, programmable jitter injection, and various eye margining features critical for AC characterization and conformance testing. Furthermore, the system integrates device power supplies with precise power sequencing and ramping controls, providing a comprehensive solution for both AC characterization and memory functional stress testing on any GDDR7 device.

Introspects M5512 has been designed in close collaboration with JEDEC members working on the GDDR7 specification, so it promises to meet all of their requirements for compliance testing. Notably, however, the device does not eliminate need for interoperability tests and still requires companies to develop their own test algorithms, but it's still a significant tool for bootstrapping device development and getting it to the point where chips can begin interop testing.

“In its quest to support the industry on GDDR7 deployment, Introspect Technology has worked tirelessly in the last few years with JEDEC members to develop the M5512 GDDR7 Memory Test System,” said Dr. Mohamed Hafed, CEO at Introspect Technology.

Nowadays highest-capacity hard drives are typically aimed at cloud service providers (CSPs) and enterprises, but this does not mean that creative professionals or regular users do not need them. To cater to demands of more regular consumers, Western Digital has started shipments of its Red Pro 24 TB HDDs, which are aimed at high-end NAS use for creative professionals with significant storage requirements.

Western Digital's Red Pro 24 TB hard drives come approximately 20 months after their 22 TB model hit retail in 2022, offering an incremental improvement to WD's highest-capacity NAS and consumer hard drive offering. The platform uses conventional magnetic recording (CMR), feature a 7200 RPM rotating speed, are equipped with a 512 MB cache, and use OptiNAND technology to improve reliability as well as optimize performance and power consumption. The HDDs are rated for an up to 287 MB/s media to cache transfer rate, which makes them some of the fastest hard drives around (albeit, still a bit slower compared to CSP and enterprise-oriented HDDs).

Just like other high-end network-attached storage-aimed HDDs, the Red Pro 24 TB hard drives use helium-filled platforms that are very similar to those designed for enterprise drives. Consequently, the Red Pro 24 TB HDD are equipped with rotation vibration sensors to anticipate and proactively counteract disturbances caused by increased vibration and multi-axis shock sensors to detect subtle shock events and automatically offset them with dynamic fly height technology to ensure that heads to not scratch disks.

UPDATE 4/2/2024: Western Digital has notified us that WD Red Pro fully support ArmorCache capability, even though it is not listed in datasheets.

What these drives lack compared Apparently, just like WD Gold and Ultraster 22 TB and 24 TB drives for enterprises and cloud datacenters, WD Red Pro HDDs fully support the ArmorCache feature that provides protection against power loss when write-cache is enabled (WCE mode) and enhances performance when write-cache is disabled (WCD mode).

On the reliability side of matters, Western Digital's Red Pro 24 TB HDDs are designed for 24/7 operation in vibrating environments, such as enterprise-grade NAS with loads of bays, and are rated for up to 550 TB/year workloads as well as up to 600,000 load/unload cycles, which is in line with what Western Digital's WD Gold and Ultrastar hard drives offer.

As for power consumption, the WD Red Pro 24 TB consumes up to 6.4W during read and write operations, up to 3.9W in idle mode, and up to 1.2W in standby/sleep mode.

Western Digital's Red Pro 24 TB (WD240KFGX) HDDs are now shipping to resellers as well as NAS makers, and are slated to be available shortly. Expect these hard drives to be slightly cheaper than the WD Gold 24 TB model.