Samsung Electronics Targeting Mass Production of 2nm Chips by 2025, 1.4nm by 2027

Samsung Electronics Targeting Mass Production of 2nm Chips by 2025, 1.4nm by 2027

Samsung’s chip contract manufacturing business said on Tuesday it plans to more than triple its advanced chips production capacity by 2027 to meet strong demand despite current global economic headwinds. The world’s second-largest foundry after Taiwan Semiconductor Manufacturing Co (TSMC) is targeting mass production of advanced 2-nanometre technology chips by 2025 and 1.4-nanometre chips by…

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China has made a major breakthrough in microchip manufacturing, undermining US President Joe Biden’s efforts to block Beijing from accessing the most advanced technology. Chips in Huawei’s latest smartphone appear to have been made using cutting-edge techniques developed in Europe, using technology that is now subject to trade restrictions. Research company TechInsights analysed the Mate 60’s main processor chip and concluded it was manufactured using what is known as EUV, or extreme ultraviolet lithography. EUV is an advanced manufacturing technique used to etch a chip’s inner workings into its silicon.[...]

The Kirin 9000S chip in its new Mate 60 appears to use a so-called “7 nanometre” process node – a measure of how small, and thus powerful, a chip’s circuitry is.[...]

Current US sanctions prohibit China from importing manufacturing equipment for process nodes smaller than 14nm, a technology that was considered cutting-edge in 2015.[...]

“SMIC’s technology advances are on an accelerated trajectory.”

Me [Joe Brandon] sowing vs me [Still Joe Brandon] reaping [4 Sep 23]

The Evolving Display Driver Market: Trends, Innovations, and Future Outlook

Introduction

The Display Driver Market is projected to grow at a compound annual growth rate (CAGR) of 7.3% throughout the forecast period from 2022 to 2027.

The display driver industry is an essential yet often underappreciated part of our digital ecosystem. Display drivers, or driver integrated circuits (ICs), bridge the interface between processors and display panels in a wide variety of devices—from smartphones and laptops to large TVs and automotive screens. With an increase in demand for high-resolution displays, improvements in mobile technology, and the rise of smart, connected devices, the display driver market has experienced significant growth and transformation. This blog will explore the key trends, challenges, and future directions for the display driver market, providing insights into an industry that is foundational to today's tech-driven society.

Market Size and Growth Drivers

The global display driver market is poised for consistent growth, driven by advancements in display technology and the proliferation of consumer electronics. Some of the primary growth drivers include:

Demand for High-Resolution Displays: Consumers are increasingly seeking better visual experiences on their devices. Display drivers are critical to supporting resolutions like 4K, 8K, and beyond, particularly in smartphones, tablets, and televisions.

Rise in Consumer Electronics: The smartphone and television markets remain the largest consumers of display drivers, with tablets, laptops, and wearables also contributing significantly. As these products evolve to include features like foldable and flexible screens, the demand for specialized display drivers rises.

Expansion in Automotive and Industrial Applications: With the rise of digital dashboards, heads-up displays (HUDs), and infotainment systems, the automotive sector has become a major adopter of display drivers. Similarly, industrial equipment now relies on advanced display technologies, driving the need for reliable and high-performance display drivers.

Growth of the IoT Ecosystem: Smart home devices, wearables, and other IoT products increasingly include small screens, creating demand for compact, energy-efficient display drivers.

According to recent market research, the display driver IC market could exceed USD 10 billion by the mid-2020s, with growth fueled by consumer electronics, automotive advancements, and IoT expansion.

Key Industry Trends

a. OLED and AMOLED Technologies

Organic Light Emitting Diode (OLED) and its advanced variant, AMOLED, have become the preferred display technologies for smartphones and high-end televisions. Unlike traditional LCDs, OLEDs provide richer colors, deeper blacks, and faster response times. However, OLEDs require specialized display drivers that are more complex and costlier to manufacture than LCD drivers. As a result, the demand for OLED-compatible display drivers is rapidly increasing.

b. Shift Toward Smaller Process Nodes

To keep up with the miniaturization of devices, display driver manufacturers are working on smaller process nodes, such as 28nm and 14nm technology. These smaller nodes allow for more energy-efficient and powerful drivers, which is especially important for battery-powered devices like smartphones, tablets, and wearables.

c. Mini and MicroLED Displays

As MiniLED and MicroLED technologies gain traction, display driver manufacturers are responding with new designs tailored to the unique demands of these displays. These technologies offer higher brightness, longer life spans, and energy savings, positioning them as potential game-changers in applications where longevity and power efficiency are critical, such as automotive displays and public signage.

d. Enhanced Functionality for Automotive Applications

As more vehicles incorporate digital dashboards and advanced infotainment systems, automotive-grade display drivers are now essential. These drivers are designed to handle extreme temperatures, maintain reliable performance over extended periods, and support larger, high-resolution displays. Some drivers are even equipped with safety-critical features like fault detection and real-time error correction.

e. Low-Power Consumption and Sustainability Focus

Power-efficient designs are now a standard in display drivers, given the increasing focus on sustainability and the need to prolong battery life in portable devices. Manufacturers are using innovative materials and efficient architectures to minimize power draw, which not only benefits end-users but also aligns with eco-conscious initiatives.

Market Challenges

Despite its growth, the display driver industry faces several challenges:

Supply Chain and Component Shortages: The semiconductor industry has experienced significant shortages, affecting the availability of display drivers and impacting various sectors, including automotive and consumer electronics.

Manufacturing Complexity and Cost: Advanced displays such as AMOLED and MicroLED require complex and costly driver designs. This can pose challenges for smaller players in the market, leading to consolidation and monopolization.

Technological Fragmentation: With the rapid pace of new display technologies, manufacturers must often design specialized drivers for each new standard (LCD, OLED, MiniLED, etc.). This fragmentation adds to development costs and reduces scalability.

Environmental Impact: Producing display drivers at scale involves resource-intensive processes. Companies are being pressured to adopt greener practices, use recycled materials, and reduce waste, all of which can add to production costs.

Future Outlook

The future of the display driver market is bright, with innovation in display technologies, IoT adoption, and automotive applications likely to drive demand for more advanced and diverse display drivers. Key projections include:

Higher Resolutions Across All Devices: As 8K TVs and high-definition smartphone screens become more accessible, manufacturers will need display drivers capable of handling higher pixel densities and refresh rates.

Flexible and Foldable Screens: Foldable devices require specially designed drivers that can adapt to changes in screen orientation and size. This trend is expected to grow, particularly in the smartphone and tablet markets.

Integration with AI and ML: AI and machine learning may play a larger role in display driver technology, particularly for automotive applications, where real-time processing is essential for safety and user experience.

Greener Technologies: Sustainable practices will become a competitive differentiator as companies and consumers alike prioritize environmentally friendly technologies. Expect to see more recycled materials and energy-efficient designs in future display drivers.

Emerging Markets Growth: While developed markets remain strong, emerging markets are set to fuel growth in lower-cost, high-volume products like smartphones and TVs. Companies that can balance affordability with quality in display driver ICs will find significant opportunities in these regions.

Conclusion

The display driver industry sits at the intersection of multiple fast-evolving technologies and sectors. As screens become more ubiquitous and central to our daily experiences, the demand for innovative, high-performance, and sustainable display drivers will only continue to grow. Industry players who can keep up with the technological demands and navigate the supply chain challenges will be well-positioned to lead in this dynamic market.

Whether it’s the next foldable phone or a futuristic car dashboard, the future is bright—and the display driver market will be an essential part of this digital transformation.

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‘Capture the Real You’, a tagline synonymous with the brand. Oppo is a brand that prides itself on its cameras and markets them heavily.  As a matter of fact, the camera is marketed so heavily by the brand that it has had a good amount of success with people looking for a camera-centric smartphone. However, Oppo’s biggest competitor in the Indian scene is Xiaomi and its own sister brand Vivo, and they both have incredibly strong contenders across a range of price brackets. Oppo recently launched the F5 which is their brand new device keeping in line with the ideology of their previous devices.  It is a direct competitor to the Vivo V7+ and the Mi A1. Like all previous devices, it too is a camera-centric smartphone and is marketed as such. So how does the F5 differentiate itself from the competition? Let’s find out in this in-depth spec analysis. Design and Display Well to start, the Oppo F5 and the Vivo V7+ share identical body designs. They both have metal bodies and a big screen which incidentally happen of the same size more or less.  They are quite in terms of overall dimensions, too but the differentiating factor between the two is that the Oppo F5 has rounded edges in the corners of the display, more or less like the LG Q6. Also, another key differentiating factor is the shape of the fingerprint sensor which is a bit oval on the back of the Oppo and squared off at the back of the Vivo.  The fingerprint sensor is very fast and accurate. Other key differences include placement of cameras and the antenna lines on both the devices. Overall, the design is quite generic and doesn’t do much in the way to stand out. The Oppo F5 also comes with a 5.99 inch LTPS-LCD display with a 1080p+ resolution which basically is 1080x2160 pixels. It dictates to about 402ppi which is really sharp and is considerably higher than Vivo V7+’s screen which has a low resolution of just 720p on its panel.  The display too is one of the best that you would find in this price bracket and has nice colors and contrast. However, the display in the Huawei Honor 9i remains the leader in this price bracket. Performance Now, this is one area where both the Oppo F5 and the Vivo V7 Plus undercut heavily. We can’t really tell why but both of these manufacturers seem reluctant to use better chips on their devices.  Where the Vivo V7+ came with a Snapdragon 450 SoC, the Oppo comes with a MediaTekHelio P23 Octa Core SoC. It is made using the 16nm fabrication process which isn’t very efficient as the FinFet 14nm chips from Snapdragon but these cost low too.  Other than that, these are power hungry chips and although it is faster than the Snapdragon 450, it isn’t really as efficient. Also, the embedded Mali G71-MP2 dual-core graphics chip doesn’t help with gaming either. General day-to-day performance is fine but heavy gaming is off the list. It also has 4GB of included RAM which is quite standard for all devices across this price bracket. Software On the Software front, the Oppo F5 runs a heavily skinned version of Android called the Colour OS. It has Android 7.1.1 as its base, and the UI tries to mimic the UX of the iOS. This is a trend that really needs to stop because it’s just blatant copyright theft and points towards an inability to create a better UI on the company’s side.  In my opinion, Oppo should simply pay the royalty to Google and get stock android for its devices. But that aside, the color OS doesn’t have a lot of bloat for the Chinese version, and there are customisability options like applying custom themes and so on. Camera and Storage Now, this is the area which should, in theory, be the ultimate selling point for the F5 but I’ll argue otherwise, and this goes for the Vivo V7+ as well. The Oppo comes with a 16MP primary camera with a CMOS sensor and an f/1.8 aperture. It is accompanied by a single tone LED flash. The camera is fairly okay but cannot come near the performance of the Honor 9i.  The colors are good, and we get a revamped camera app that can control various aspects of the camera.

Also, the f/1.8 aperture enables a nice bokeh effect, but it isn’t as profound as the dedicated telephoto camera setup on the Honor 9i and the Mi A1. Coming to the front, we have a 20MP shooter with an f/2.0 aperture and a large 1/2.8 sensor to accommodate for the loss for the dual camera setup with the F3. The Front camera is also good and takes good pictures across a range of lighting conditions. However, the device has some glaring and serious flaws like no Image stabilization of any sort, no 4K video recording (courtesy of the Helio P23) and no dual tonne LED flash. Storage wise, the device comes with 32 and 64 GB variants with the ability to expand it further to 256GB via an SD card. Battery and Connectivity The Oppo F5 gets a 3200mAh battery which is almost similar to the Vivo V7 plus. There is no fast charging support so charging up that battery might prove to be a lengthy process. Connectivity wise, the Oppo F5 has already launched in India, and so it supports Indian network bands including 4G VOLTE. It also features Wi-Fi a/b/g/n 5GHz, Bluetooth v4.2, micro USB 2.0 (no USB type-C) and GPS with A-GPS. Conclusion It’s hard, to sum up, the Oppo F5. The biggest problem with this and the Vivo V5 plus is that both of them don’t feel special in any regard. Also, advertising the camera to cover up the Phone’s apparent lack of proper hardware is simply misleading.  Also, the omissions like no USB Type-C connector, No image stabilization, and lack of fast charging doesn’t supplement the phone in the least in this price bracket. The Oppo F5 price in India is approximately Rs.19,000-22,000of which there are a lot of other alternatives that you can check out. For more in-depth reviews,

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Components4All Intel Coffee Lake Core i9 9900K 3.6GHz (5.0GHz Turbo) CPU, Asus TUF Z390 Pro Gaming Motherboard, 32GB 3000MHz Corsair DDR4 RAM & BeQuiet Pure Rock 120mm CPU Cooler Pre-Built Bundle

Price: Buy Now Last Updated: The Intel 9th generation CoffeeLake refresh series of CPU is built on the same 14nm process as the previous 2 generation Intel CPU’s but with more cores, this gives them a performance benefit over the previous generations. This generation of processors benefit from higher clock speeds and more physical cores. The Intel Core I9 9900K Is considered the Best Consumer…

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Intel inside

2013 年：22nm｜LGA 1150｜Haswell｜Intel 3th Gen Core

2014 年：22nm｜LGA 1150｜Haswell Refresh｜Intel 4th Gen Core

2015 年：14nm｜LGA 1150｜Broadwell｜Intel 5th Gen Core

2016 年：14nm｜LGA 1151｜Skylake｜Intel 6th Gen Core

2017 年：14nm+｜LGA 1151｜Kaby Lake｜Intel 7th Gen Core

2018 年：14nm++｜LGA 1151｜Coffee Lake｜Intel 8th Gen Core

2019 年：14nm++｜LGA 1151｜Coffee Lake Refresh｜Intel 9th Gen Core

2020 年：14nm+++｜LGA 1200｜Comet Lake｜Intel 10th Gen Core

2021 年：14nm+++｜LGA 1200｜Rocket Lake｜Intel 11th Gen Core

2022 年：Intel 7｜LGA 1700｜Raptor Lake｜Intel 13th Gen Core

2023 年：Intel 7｜LGA 1700｜Raptor Lake Refresh｜Intel 14th Gen Core

2024 年：？？？？｜LGA 1851｜Arrow Lake｜Intel Core Ultra 2 Series

2025 年：？？？？｜LGA 1851｜Arrow Lake｜Intel Core Ultra 3 Series

The Intel Core i9-14901KE for Content Creators and Gamers

Intel Raptor Lake processors

 Intel stealthily launched the “14001” series of 14th-Gen Raptor Lake Refresh processors. The chips lack Intel’s current microarchitectures‘ Efficiency cores (E-cores) and have just Performance cores (P-cores). This new CPU series is aimed for embedded applications and includes Intel’s first overclockable embedded processor, the Core i9-14901KE.

Intel has stealthily introduced 14th-Gen Raptor Lake Refresh processors ahead of its Arrow Lake-S desktop CPUs. The unusual 14001 series chips have just Performance cores (P-cores) and no Efficiency cores (E-cores) like Intel’s latest architectures. These  CPUs, designed for embedded applications, have an intriguing overclockable top model.

The downside is that these CPUs are embedded (soldered-in). They are not user-replaceable and must be purchased with an industrial motherboard. This makes them unattainable for most fans and consumers.

The new E-core-free portfolio from Intel includes three Core i9 models, two Core i7 models, and four Core i5 models. The flagship Core i9-14901KE appears to be an overclockable K-series chip, a rarity for embedded Intel processors.

This series is Intel’s first E-core-free series since the 11th generation, departing from their hybrid architecture plan. Intel can reuse Raptor Lake dies with damaged E-cores but otherwise working components.

New processors have benefits. They eliminate hybrid architecture difficulties like workload scheduling between core types. Many applications don’t need E-cores and work best with six to eight physical cores of any type.

Each Core i9 model has eight Raptor Cove P-cores, 16 threads, and 36MB L3 cache. They differ mostly in clock speeds and power targets. The top-tier Core i9-14901KE has a 5.8GHz turbo clock, 3.8GHz base clock, and 125W long-term TDP. The Core i9-14901E decreases long-term power usage to 65W with a minor performance trade-off, while the 45W variant is the most power-efficient.

Like the i9, the Core i7 has eight cores and 16 threads, but lower speeds and smaller L3 caches. Core i7-14701E and TE run at 65W and 45W, respectively. The worst Core i5 versions have six cores, 12 threads, and 24MB L3 cache. The Core i5-14501 and Core i5-14401 series match their desktop equivalents. Boost clocks and integrated graphics performance differ most.

Intel UHD 770 Graphics with 32 execution units are on all versions except the Core i5-14501. The Core i5-14501 series uses 24 execution units for UHD 730 Graphics.

Intel’s surprising revelation shows its capacity to innovate inside product lines, potentially opening new markets for specialised computer solutions.

The i9-11900K is a good CPU for Intel E-core sceptics. Amazon.com currently sells it for $260.

Intel’s most recent portfolio of 14th-Gen CPUs represents another step forward in chip technology. The overclockable Core i9-14901KE is one of the best of them, providing both pros and hobbyists with great performance and versatility. This post explores the capabilities, features, and potential of the Core i9-14901KE, emphasising the reasons it represents a noteworthy upgrade to Intel’s CPU lineup.

Introducing the Core i9-14901KE

Among Intel’s latest E-core-less CPUs, the Core i9-14901KE delivers optimal performance for demanding applications. Its ability to overclock, which boosts performance, makes it stand out.

Design and Execution

The high-performance Core i9-14901KE uses Intel’s 14nm production process to skip E-cores and use P-cores. Perfect for 3D rendering, video editing, and gaming, this architecture prioritises processing speed and power.

Important details:

Speed of Base Clock: 3.7 GHz

Peak Turbo-Boost Speed: 5.3 GHz

Number of Cores: 10 P-cores

There are 20 threads.

20 MB of L3 cache

Thermal Design Power (TDP): 125 watts

Core i9-14901KE Potential Overclocking

One of the most attractive aspects of the Core i9-14901KE is that it can be overclocked. By adjusting the CPU’s parameters, enthusiasts can unlock more performance by reaching faster clock rates. With the help of its Extreme Tuning Utility (XTU),  Intel offers strong overclocking support. Users may tweak voltages, clock rates, and other settings to achieve the ideal compromise between performance and stability.

Cooling Factors

To handle the higher heat output from overclocking the Core i9-14901KE, efficient cooling solutions are needed. It is advised to use specialised water cooling loops or high-quality AIO (All-in-One) liquid coolers to maintain ideal temperatures and guarantee dependable operation during demanding workloads.

E-core-less Design: An Innovative Approach

The Core i9-14901KE‘s decision to forgo E-cores is a reflection of Intel’s strategy emphasis on optimising both single and multi-threaded performance. This CPU provides improved performance for programmes that benefit from higher clock speeds and more core counts by allocating all resources to P-cores.

Benefits of Architecture Without an E-Core:

Better Single-Core Performance

P-cores perform better for single-threaded applications since they are designed for high clock speeds and minimal latency.

Improved Multi-Core Efficiency

Since every core is high-performance, multi-threaded programmes may take advantage of the entire processing capacity without having to deal with the mixed workload that E-cores handle.

Simplified Power Management

Power delivery and thermal management are simplified in the absence of E-cores, which may result in more reliable performance under load.

Comparing and Observing Actual Performance

The Core i9-14901KE has shown considerable performance gains over its predecessors, according to early benchmarks. The CPU shows excellent single-core and multi-core results on artificial benchmarks, indicating its potential in practical applications. Benchmarks for gaming demonstrate notable gains in responsiveness and frame rates, especially in CPU-bound a game.

Productivity and Content Creation:

Professionals and content makers should use the Core i9-14901KE for software development, 3D rendering, and video editing. It reduces rendering times and boosts productivity in demanding processes due to its high clock rates and core count.

Harmony and Prospective-Looking

PCIe 5.0, DDR5 memory , and enhanced networking are supported by Intel’s Z790 chipset in the Core i9-14901KE. Build a cutting-edge system using the newest technology to future-proof your investment.

Upgrade Route and Duration

Users may anticipate continuing compatibility with new technologies and updates because to Intel’s commitment to maintaining the 14th-Gen platform. Because of this, the Core i9-14901KE is a wise option for anyone wishing to construct a high-performance system that will last for many years.

Conclusion: A Novel Standard in High-Efficiency Computing

A new benchmark in high-performance computing is set by the overclockable Core i9-14901KE, which provides unmatched power and versatility. Its E-core-less design and strong overclocking potential set it apart as a top option for professionals, gamers, and enthusiasts looking for extreme performance. With its dramatic advancement in CPU technology, the Core i9-14901KE promises outstanding performance for a variety of demanding workloads, demonstrating Intel’s continued innovation.

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The Refurbished HPE 872012-B21 is a processor kit designed for the Gen10 HPE ProLiant BL460c server, featuring an Intel Xeon-S 4110 processor. It ensures powerful performance and compatibility with DDR4 memory, SAS/SATA HDDs, SSDs, and NVMe SSDs. Ideal for data-intensive applications, it integrates seamlessly with the server's dual-port 10Gb Ethernet for robust networking capabilities.

HPE 872012-B21 OVERVIEW:

HPE Intel Xeon 8-Core Silver 4110, 2.1Ghz, 11MB L3 Cache, 9.6Gt/s Ultra-path interconnect speed, socket type FCLGA3647, processor kit for the Gen10 HPE ProLiant BL460c server. This processor kit includes the processor with sled and the heatsink.

HPE 872012-B21 SPECIFICATIONS:

Part Number: 872012-B21 Manufacturer: HPE Processor Series: Silver 4100 Clock Speed: 2.10Ghz Max Turbo Frequency: 3.00Ghz Processor Cores: 8-Core Threads: 16 Cache: 11MB L3 Cache Ultra-Path Interconnect Speed: 9.6Gt/s UPI Links: 2 Lithography: 14NM Thermal Design Power (TDP): 85W Socket type: FCLGA3647

Advance Technologies:

Intel Speed Shift Technology Intel vPro Technology Intel Hyper Threading Technology Intel Virtualization Technology (VT-X) Intel Virtualization Technology for Direct I/O (VT-D) Intel 64 Bit Support Enhanced Intel SpeedStep Technology Intel Volume Management Device (VMD)

Security Features:

Intel Advanced Encryption Standard AES New Instructions Intel Trusted Execution Technology Execute Disable Bit

HPE 872012-B21 COMPATIBILITY:

The 872012-B21 is compatible with the following Gen10 HPE ProLiant Servers:

HPE PROLIANT BL460C G10

NiPoGi Mini PC,6GB Ram 128GB Rom Windows 10 Pro (64 bit) Celeron J3455 Micro Desktop Computer, Support 2.5" SSD, mSATA SSD, Dual-Band WiFi, 4K HD Business Home Office Desktop PC We have a great collection of WFH products in our online shop. Our shop includes other essential remote home working devices like Webcams, Chairs, Tables and much more. Lets improve your WFH enrolment today with the NiPoGi Mini PC,6GB Ram 128GB Rom Windows 10 Pro (64 bit) Celeron J3455 Micro Desktop Computer, Support 2.5" SSD, mSATA SSD, Dual-Band WiFi, 4K HD Business Home Office Desktop PC. https://www.remoteworkingoffice.com/product/nipogi-mini-pc6gb-ram-128gb-rom-windows-10-pro-64-bit-celeron-j3455-micro-desktop-computer-support-2-5-ssd-msata-ssd-dual-band-wifi-4k-hd-business-home-office-desktop-pc/?feed_id=4818&_unique_id=668ea5235557d #homeoffice #remoteworking #ratemyoffice #homeworking #rwo #remoteworkingoffice

Huawei, litografi cihazı gelişmek için Ar-Ge Tesisi kuruyor

SMIC ve Huawei, gelecekteki yonga setleri için 5nm sürecini başarılı bir şekilde geliştirmiş olabilir , ancak Çinli firmanın mevcut DUV makinelerine güvenmeye devam etmesi halinde aşamalı olarak takılacağı teknolojik bir tavan var. ASML gibi şirketlerin son teknoloji ürünü EUV yonga yapım araçlarını ele geçirmesinin hiçbir yolu olmayan yeni bir rapor, Huawei'nin işleri kendi eline aldığını ve gelişmiş çip üretim cihazları geliştirmek amacıyla bir Ar-Ge tesisine yoğun yatırım yapmayı planladığı belirtiliyor. Tamamlandığında Huawei'nin gelişmiş Ar-Ge tesisinin 224 futbol sahası büyüklüğünde bir alanı kapsayacağı söyleniyor ABD'nin ticaret yasağı Huawei'yi kendi kendine yetme yoluna soktu ancak bu yol çukurlarla, barikatlarla ve diğer engellerle dolu olacak ve şirketin rotasının gerektireceği yoğun sermayeden bahsetmeye bile gerek yok. Nikkei'ye göre, Şanghay yakınlarında yeni bir Ar-Ge merkezi inşa ediliyor. Buradaki asıl amaç, ASML, Canon ve Nikon tarafından üretilen makinelerle rekabet edebilecek çip yapım araçları geliştirmek. Şu anda, Huawei'nin dökümhane ortakları SMIC ve Hua Hong'un, 14nm FinFET ve 16nm FinFET süreçlerinde çip üretmelerine olanak tanıyan araçları satın almaları yasaktır. Bunun yerine, her iki yarı iletken üretim firması da yalnızca 28nm litografi sistemlerini ele geçirebiliyor ve bu da onları ABD ile karşılaştırıldığında ciddi bir dezavantaja sokuyor. Diğer sorun ise bu pazarın yüzde 90'ının ASML tarafından kontrol ediliyor olması ve Huawei'nin bu Ar-Ge tesisini geliştirme çabasının nedeni de bu. Şirket şu ana kadar yaklaşık 12 milyar Yen veya 1,66 milyar dolar yatırım yaptı ve tamamlandığında alanı 224 futbol sahasına eşdeğer olacak ve 35.000'den fazla çalışana ev sahipliği yapacak. Ayrıca Huawei'nin yarı iletken alanında en iyi yetenekleri kazanmak için cazip maaş paketleri sunduğu söyleniyor. Ancak hiçbir Çinli şirket, yeşil kart sahibi ABD vatandaşlarını işe alamıyor ve Huawei'nin yerel yetenekleri işe almasına izin veriyor. Tesis tamamlandığında SMIC ile Huawei arasındaki ortaklığın sağlıklı olup olmayacağı bilinmiyor ancak kendi sahasında galibiyet serisini sürdürmek istiyorsa şimdilik alabileceği her türlü yardıma ihtiyacı var. Read the full article

SOYO Graphics Card AMD GPU Radeon RX 550 4G GDDR5 128Bit 14nm Computer PC RX550 PCI-E 3.0 Gaming Video Cards Full New

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Intel Core i5 11400 Desktop Processor Intel Core i5 2.60 GHz processor offers hyper-threading architecture that delivers high performance for demanding applications with improved onboard graphics and turbo boost The Socket LGA-1200 socket allows the processor to be placed on the PCB without soldering 12 MB of L3 cache rapidly retrieves the most used data available to improve system performance, Max Turbo Frequency 4.40 GHz 14 nm design offers great efficiency for computing, delivers nimble processing with balanced cost, performance, and power Built-in Intel UHD Graphics 730 controller for improved graphics and visual quality. Supports up to 3 monitors. Intel Core i5 11400 Desktop Processor Overview : Power up your productivity, gaming, and content creation experiences by installing the Intel Core i5-11400 2.6 GHz Six-Core LGA 1200 Processor into your computer system. Built using a 14nm process, this 11th generation desktop processor features a base clock frequency of 2.6 GHz and a 4.4 GHz turbo frequency with 12MB of cache, six cores, and twelve threads for fast and reliable performance. The Core i5-11400 also includes support for PCI Express 4.0 and dual-channel DDR4 memory at 3200 MHz to help run and multitask a variety of demanding applications and games using technologies such as built-in AI acceleration. Performance can be further enhanced by installing Intel Optane memory to cache frequently accessed data. The Core i5-11400 features integrated Intel UHD 730 Graphics driven by the powerful Xe architecture. A thermal solution is included to help maintain optimal temperatures and the processor is backed by a 3-year warranty. PCIe 4.0 This processor supports up to 20 PCIe 4.0 lanes, delivering exceptional data throughput with compatible devices. AI Acceleration Intel Deep Learning Boost (VNNI) technologies help to enhance the performance of deep learning workloads. Thunderbolt 4 & USB4 With Thunderbolt 4 technology, this processor supports data transfer speeds of up to 40 Gb/s with compatible devices and you can connect up to two 4K monitors simultaneously. USB4 technology supports a 20 Gb/s throughput with compatible devices and up to one 4K monitor. Intel Iris Xe Graphics The integrated graphics deliver fast, rich 3D performance for high-quality visuals. Intel Core I5 11400 Desktop Processor

Chinese chipmaker launches 14nm AI processor that's 90% cheaper than GPUs — $140 chip's older node sidesteps US sanctions | Tom's Hardware