Intel’s Bartlett Lake-S CPUs: No 12 P-Cores for Desktop PCs

February 8, 2024 by our News Team

Intel's upcoming Bartlett Lake-S processors will feature 24 cores, including 8 P-cores and 16 E-cores, and improved iGPU, but a 12 P-core variant for desktop PCs is unlikely.

  • 24 cores, with 8 P-cores and 16 E-cores
  • 32 integrated GPU (iGPU) cores (EUs)
  • Potential for improved AI performance

Intel’s Bartlett Lake-S CPUs: No 12 P-Cores for Desktop PCs

Intel enthusiasts were buzzing with excitement when rumors started circulating about the upcoming Bartlett Lake-S processors. Speculations suggested that these processors would mark a significant milestone for Team Blue, as they were rumored to be the first hybrid processors with more than 8 cores. However, it seems that the initial information was a bit off.

According to Benchlife, Bartlett Lake-S is actually identical to the 14th Gen Raptor Lake Refresh and is being developed for Network and Edge applications under the Intel NEX (Network and Edge) business group. This means that desktop PC users hoping for a 12 P-core variant will be disappointed.

So, what can we expect from Bartlett Lake-S? Well, it will feature a total of 24 cores, with 8 P-cores and 16 E-Cores. Additionally, it will come equipped with 32 integrated GPU (iGPU) cores (EUs). While it supports both DDR4 and DDR5 memory, the possibility of a 12 P-core variant is highly unlikely.

The iGPU on Bartlett Lake-S will be no slouch either, featuring up to a UHD Graphics 770 with support for up to four monitors. This is great news for users who rely on integrated graphics for their display needs.

One area where Bartlett Lake-S may shine is in AI performance. While details are scarce, it is expected to offer slightly higher AI performance compared to its predecessor, Raptor Lake. How exactly Intel plans to achieve this remains a mystery, but it’s an exciting prospect nonetheless.

Now, the big question remains: Will these chips make their way to the DIY market? While there’s no guarantee, there is a possibility that these region-restricted processors could eventually find their way into the hands of PC enthusiasts. However, for now, their primary focus seems to be on the Network and Edge applications.

Looking beyond Bartlett Lake-S, Intel has more in store for us. The 15th Gen Arrow Lake-S processors are expected to launch in the latter half of this year. These processors will boast 24 cores, but interestingly, they will not feature hyper-threading. Instead, they will come with a dedicated NPU (Neural Processing Unit), catering to the growing demand for AI-related tasks.

What’s even more exciting is that the CPU tiles of the Arrow Lake-S processors will be manufactured using Intel’s 20A node. This will make them the first processors to feature backside power delivery and RibbonFET (GAA) transistors. These advancements are expected to bring improvements in power efficiency and overall performance.

For those looking for low-power computing options, Intel’s Lunar Lake processors are worth keeping an eye on. These processors will be manufactured on TSMC’s 3nm-class process and will target low-power notebooks and convertibles.

In conclusion, while the initial rumors about Intel’s Bartlett Lake-S processors may have been slightly off, there’s still plenty to be excited about. With its 24 cores, improved iGPU, and potential AI performance enhancements, Bartlett Lake-S promises to be a formidable option for Network and Edge applications. And with Intel’s future roadmap including the Arrow Lake-S and Lunar Lake processors, it’s clear that Team Blue is committed to pushing the boundaries of performance and innovation.

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Background Information

About Intel: Intel Corporation, a global technology leader, is for its semiconductor innovations that power computing and communication devices worldwide. As a pioneer in microprocessor technology, Intel has left an indelible mark on the evolution of computing with its processors that drive everything from PCs to data centers and beyond. With a history of advancements, Intel's relentless pursuit of innovation continues to shape the digital landscape, offering solutions that empower businesses and individuals to achieve new levels of productivity and connectivity.

Intel website  Intel LinkedIn

About TSMC: TSMC, or Taiwan Semiconductor Manufacturing Company, is a semiconductor foundry based in Taiwan. Established in 1987, TSMC is a important player in the global semiconductor industry, specializing in the manufacturing of semiconductor wafers for a wide range of clients, including technology companies and chip designers. The company is known for its semiconductor fabrication processes and plays a critical role in advancing semiconductor technology worldwide.

TSMC website  TSMC LinkedIn

Technology Explained

CPU: The Central Processing Unit (CPU) is the brain of a computer, responsible for executing instructions and performing calculations. It is the most important component of a computer system, as it is responsible for controlling all other components. CPUs are used in a wide range of applications, from desktop computers to mobile devices, gaming consoles, and even supercomputers. CPUs are used to process data, execute instructions, and control the flow of information within a computer system. They are also used to control the input and output of data, as well as to store and retrieve data from memory. CPUs are essential for the functioning of any computer system, and their applications in the computer industry are vast.

DDR4: DDR4 is a generation of Double Data Rate (DDR) dynamic random access memory (RAM) technology. It is a type of RAM that utilizes a higher clock frequency and is more power-efficient than its predecessors. As a result, it is capable of processing data more quickly than other RAM in the computer industry. Its increased speed and power efficiency are beneficial for applications such as gaming, rendering, and machine learning. It is designed for high-performance computing and enables faster access to stored information, resulting in better overall performance for the user. Furthermore, because of its low voltage requirements it requires less power consumption, making it an attractive option for many computer systems. DDR4 is set to become the primary RAM in most computer systems as the industry transitions away from its predecessors.

DDR5: DDR5 (Double Data Rate 5) is the next generation of memory technology for the computer industry. It is a modern day improvement on earlier DDR technologies, with faster speeds, greater bandwidth and higher capacities. DDR5 enables higher resolution, seamless gaming experiences and faster data transfer rates, making it an ideal choice for high-performance computing and 4K gaming. With its greater RAM compatibility, DDR5 provides faster buffering times and raised clock speeds, giving users an improved overall work system. DDR5 is also optimized for multi-tasking, allowing users to multitask without experiencing a significant drop in performance, increasing the productivity of digital tasks. As an ever-evolving technology, DDR5 is paving the way for the computer industry into a new and powerful era.

E-Cores: E-Cores (Efficiency Cores) are a type of technology used in the computer industry to provide a more efficient and reliable way of powering and cooling computer components. They are made up of a combination of copper and aluminum, and are designed to be more efficient than traditional copper cores. E-Cores are used in a variety of applications, such as in CPUs, GPUs, and other computer components. They are also used in servers, laptops, and other electronic devices. The technology is designed to reduce heat and power consumption, while also providing a more reliable and efficient way of powering and cooling computer components.

GPU: GPU stands for Graphics Processing Unit and is a specialized type of processor designed to handle graphics-intensive tasks. It is used in the computer industry to render images, videos, and 3D graphics. GPUs are used in gaming consoles, PCs, and mobile devices to provide a smooth and immersive gaming experience. They are also used in the medical field to create 3D models of organs and tissues, and in the automotive industry to create virtual prototypes of cars. GPUs are also used in the field of artificial intelligence to process large amounts of data and create complex models. GPUs are becoming increasingly important in the computer industry as they are able to process large amounts of data quickly and efficiently.

iGPU: An integrated Graphics Processing Unit (iGPU) is a component built into a computer's central processing unit (CPU) or system-on-chip (SoC) that handles graphical tasks. Unlike dedicated graphics cards, which are separate components, an iGPU shares system resources with the CPU, allowing for basic graphics capabilities without the need for an additional card. While typically less powerful than dedicated GPUs, iGPUs are energy-efficient and well-suited for everyday computing tasks

NPU: NPU, or Neural Processing Unit, is a type of specialized processor that is designed to handle complex artificial intelligence tasks. It is inspired by the structure and function of the human brain, with the ability to process and analyze large amounts of data simultaneously. In the computer industry, NPU technology is being used in various applications such as speech recognition, image and video processing, and natural language processing. This allows computers to perform tasks that were previously only possible for humans, making them more efficient and intelligent. NPU technology is also being integrated into smartphones, self-driving cars, and other devices, making them smarter and more responsive to user needs. With the increasing demand for AI-driven technology, the use of NPU is expected to grow and revolutionize the way we interact with computers in the future.

P-Cores: P-Cores (Performance Cores) are a type of processor technology developed by Intel that is designed to improve the performance of computer systems. This technology is based on the concept of multi-core processors, which are processors that contain multiple cores or processing units. P-Cores are designed to increase the speed and efficiency of computer systems by allowing multiple cores to work together in parallel. This technology is used in a variety of applications, including gaming, video editing, and data analysis. P-Cores are also used in servers and other high-performance computing systems. The technology is also used in mobile devices, such as smartphones and tablets, to improve battery life and performance. P-Cores are an important part of the computer industry, as they allow for faster and more efficient computing.

UHD: Ultra High Definition (UHD) is a technology that revolutionizes the quality of digital display with resolutions much higher than standard HD. UHD offers sharper images and higher resolutions in order to provide the user with better clarity and detail. UHD is widely used in gaming, media streaming, and HDTVs, as it offers superior viewing experience. In the computer industry, UHD is used to create high-end visuals for gaming, video conferencing, and streaming of 4K content. UHD also enables users to extend their desktop workspace and multitask better with multiple screens. With UHD, computer users can also enjoy an improved multimedia experience that provides more depth and vivid colors. UHD gives users more options for connecting their monitors and TV displays to their computers for enhanced gaming and streaming experience.

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