The signing ceremony was held at Samsung’s most advanced chip manufacturing complex in Pyeongtaek, Korea, attended by Dr. Lisa Su, Chair and CEO of AMD, and Young Hyun Jun, Vice Chairman & CEO of Samsung Electronics.

“Samsung and AMD share a commitment to advancing AI computing, and this agreement reflects the growing scope of our collaboration,” said Young Hyun Jun, Vice Chairman & CEO of Samsung Electronics. “From industry-leading HBM4 and next-generation memory architectures to cutting-edge foundry and advanced packaging, Samsung is uniquely positioned to deliver unrivaled turnkey capabilities that support AMD’s evolving AI roadmap.”

“Powering the next generation of AI infrastructure requires deep collaboration across the industry,” said Dr. Lisa Su, Chair and CEO of AMD. “We are thrilled to expand our work with Samsung, bringing together their leadership in advanced memory with our Instinct GPUs, EPYC CPUs and rack-scale platforms. Integration across the full computing stack, from silicon to system to rack, is essential to accelerating AI innovation that translates into real-world impact at scale.”

Under the MOU, Samsung and AMD will align on primary HBM4 supply for the next-generation AMD AI accelerator, the AMD Instinct MI455X GPU, as well as advanced DRAM solutions for 6^th Gen AMD EPYC CPUs, codenamed “Venice.” These technologies will support next-generation AI systems combining AMD Instinct GPUs, AMD EPYC CPUs and rack-scale architectures such as the AMD Helios platform.

Samsung and AMD are closely collaborating on advanced memory technologies for AI and data center workloads. As memory bandwidth and power efficiency become increasingly critical to system-level performance, this collaboration will help deliver more optimized AI infrastructure for customers.

An industry-first to enter mass production, Samsung’s HBM4 is built on its most advanced 6th-generation 10-nanometer (nm)-class DRAM process (1c) and a 4nm logic base die, featuring processing speeds of up to 13 gigabits-per-second (Gbps) and maximum 3.3 terabytes-per-second (TB/s) bandwidth that exceeds industry standards.

Powered by Samsung HBM4’s industry-leading performance, reliability and energy efficiency, the AMD Instinct MI455X GPU is expected to be the optimum solution for high-performance systems handling AI model training and inference.

The MI455X GPU will serve as a key building block for the AMD Helios rack-scale architecture, designed to deliver the performance and scalability required for next-generation AI infrastructure.

As part of their collaboration, Samsung and AMD will also work together on high-performance DDR5 memory optimized for the 6^th Gen AMD EPYC CPUs. The companies aim to deliver industry-leading DDR5 memory solutions for systems built on the AMD Helios rack-scale architecture.

The two companies will also discuss opportunities for foundry partnership, through which Samsung would provide foundry services for next-generation AMD products.

Samsung and AMD have collaborated for nearly two decades across graphics, mobile and computing technologies, including Samsung serving as the primary HBM3E partner to AMD, powering the latest AMD Instinct MI350X and MI355X AI accelerators.

About AMD
AMD (NASDAQ: AMD) drives innovation in high-performance and AI computing to solve the world’s most important challenges. Today, AMD technology powers billions of experiences across cloud and AI infrastructure, embedded systems, AI PCs and gaming. With a broad portfolio of AI-optimized CPUs, GPUs, networking and software, AMD delivers full-stack AI solutions that provide the performance and scalability needed for a new era of intelligent computing. Learn more at www.amd.com.

Recently, Samsung was selected by Videotron to deploy its 5G Non-Standalone (NSA) and 4G LTE Core gateway solutions, powered by AMD EPYC 9005 Series CPUs. Through this project, Samsung is expanding its presence across Canada and beyond, accelerating its cloud-native AI core footprint while retaining operator confidence in Samsung’s proven partner ecosystem and network solutions.

At MWC 2026, Samsung will demonstrate its AI-RAN breakthrough developments by leveraging its AI-powered vRAN with AMD EPYC processors. Following last year’s validation milestone, both companies will introduce the successful results of multi-cell testing conducted at Samsung’s R&D Lab, enabling scalable deployments and greater processor flexibility within software-based network environments. 

This achievement highlights Samsung’s ability and commitment to reach commercial-grade, AI-powered vRAN performance using a fully virtualized software stack on the latest AMD CPU without additional accelerators. It underscores Samsung’s ongoing shift toward software-driven architectures designed to reduce hardware dependency and provide operators with greater choice and adaptability. 

“Samsung’s accomplishment with AMD emphasizes what’s possible when AI-native, open and virtualized architectures meet advanced compute innovations,” said Keunchul Hwang, Executive Vice President and Head of Technology Strategy Group, Networks Business at Samsung Electronics. “We’re making headway to help operators fully scale AI-native networks today with commercial-grade performance and greater infrastructure optionality, ensuring their networks are ready to evolve with emerging technologies and use cases.”

“AMD EPYC CPUs are built to handle the intensive compute requirements of modern telecommunications infrastructure,” said Derek Dicker, corporate vice president, Enterprise Business Group. “Our latest multi-cell vRAN testing with Samsung demonstrates how our latest generation EPYC processors deliver the performance, efficiency and scalability that network operators and enterprises need to build next-generation networks that are ready for AI, automation and future innovations.”

The companies have also expanded their joint efforts for AI-driven enterprise solutions. At MWC, Samsung will present its Network in a Server (NIS) — a fully virtualized next-generation, Edge-AI solution powered by AMD’s CPU. This solution helps operators easily incorporate AI into their networks, reduce operational complexity and unlock new opportunities. Samsung will demonstrate various AI on RAN use cases using NIS verified in real-world environments with a major Japanese operator. These use cases span video analysis, sensor and radar detection services based on Integrated Sensing and Communication (ISAC) technology, and hyperconnectivity for next-generation devices. 

Samsung is committed to embracing a robust, technology forward ecosystem of chipset partners, providing operators with diverse optionality to accelerate a flexible, AI-powered and cloud-native network evolution.

Samsung Networks has pioneered the successful delivery of 5G end-to-end solutions, including chipsets, radios and cores. Through ongoing research and development, Samsung drives the industry to advance 5G networks with its market-leading product portfolio, from purpose-built RAN, virtualized RAN, Open RAN, AI-RAN, Cloud-native AI core to private network solutions and AI-powered automation tools and applications. The company currently provides innovative network solutions to mobile operators that deliver boundless connectivity to hundreds of millions of users worldwide.

Conducted in Samsung’s R&D lab in Korea, the first call was completed using Samsung’s versatile, O-RAN-compliant, virtualized RAN (vRAN) software, powered by AMD EPYC 8004 Series processors on Supermicro’s Telco/Edge servers, supported by Wind River Studio Container-as-a-Service (CaaS) platform. This demonstration aimed to verify optimized performance, energy efficiency and interoperability among partners’ solutions.

The joint demonstration represents Samsung and Vodafone’s ongoing commitment to reinforce their position in the Open RAN market and expand their ecosystem with industry-leading partners. This broader and growing Open RAN ecosystem helps operators to build and modernize mobile networks with greater flexibility, faster time-to-market (TTM), and unmatched performance.

“Open RAN represents the forthcoming major transformation in advancing mobile networks for the future. Reaching this milestone with top industry partners like Samsung and AMD shows Vodafone’s dedication to delivering on the promise of Open RAN innovation,” said Nadia Benabdallah, Network Strategy and Engineering Director at Vodafone Group. “Vodafone is continually looking to innovate its network by exploring the potential and diversity of the ecosystem.”

“This collective effort marks a key milestone for the mobile network industry to steer Open RAN forward, by embracing multiple providers at every layer of the network stack. The demo illustrates Samsung’s commitment to delivering the full potential of mobile networks by embracing openness,” said June Moon, Executive Vice President & Head of R&D, Networks Business at Samsung Electronics. “Samsung is constantly working with other technology frontrunners to offer operators the means to transform their networks and capitalize on the diversity of the Open RAN ecosystem.”

“The telco industry continues to demand new levels of performance and energy efficiency with increasingly complex workloads and stringent efficiency targets,” said Kumaran Siva, corporate vice president, Strategic Market Development, AMD. “AMD EPYC 8004 Series CPUs are optimized for modern edge and vRAN deployment models to enable the telco industry’s current evolution toward truly end-to-end open, virtualized networks. We are extremely proud of our collaboration with Samsung and Vodafone, leveraging our latest data center processors to modernize legacy telco infrastructure and deliver the leadership Open RAN performance, efficiency and scalability needed to build highly innovative mobile networks.”

“As the telecom industry continues to rapidly evolve, Samsung and its ecosystem partners are at the forefront of innovation and transformation,” said Prakash Sangam, Founder & Principal of Tantra Analyst. “This technical achievement between Samsung, Vodafone and AMD validates the enhanced capabilities among all three companies’ solutions and supports new vendors in the evolving Open RAN ecosystem.”

The companies will demonstrate its test result exceeding 1Gbps throughput for multi UE on multi-cell configuration at MWC 2024.

In June 2021, Samsung became a strategic partner for Vodafone to carry out its Open RAN vision to modernize legacy networks and grow a strong Open RAN ecosystem. Since then, the companies have been expanding their collaboration, recently marking a milestone of kicking off the largest Open RAN rollout in the U.K. in August 2023. Samsung announced a new collaboration with AMD as well to advance 5G vRAN and virtualized Open RAN for network transformation.

Samsung’s strong ecosystem illustrates its leadership in offering vRAN and Open RAN solutions that are reliable and sustainable, exceeding telco-grade performance. With the goal of pre-testing and integrating, Samsung has sought to validate its vRAN and Open RAN solutions, to offer network operators an efficient path to market. Samsung has proven its extensive expertise in commercial networks for Tier 1 operators in North America, Europe and Asia.

Samsung has pioneered the successful delivery of 5G end-to-end solutions, including chipsets, radios and cores. Through ongoing research and development, Samsung drives the industry to advance 5G networks with its market-leading product portfolio, from vRAN 3.0, Open RAN, Core to private network solutions and AI-powered automation tools. The company currently provides network solutions to mobile operators that deliver connectivity to hundreds of millions of users worldwide.

▲ From left, Junehee Lee (Samsung Electronics), June Moon (Samsung Electronics), Nadia Benabdallah (Vodafone Group), Yago Tenorio (Vodafone Group), Alberto Ripepi (Vodafone Group), Woojune Kim (Samsung Electronics)

“Together with AMD, Samsung has been revolutionizing mobile graphics, including our recent collaboration that brought ray tracing capability to mobile processors for the first time in the industry,” said Seogjun Lee, Executive Vice President of Application Processor (AP) Development at Samsung Electronics. “Drawing on our technological know-how in designing ultra-low-power solutions, we will continue to drive ongoing innovation in the mobile graphics space.”

“We are excited Samsung selected multiple generations of our leadership high-performance Radeon graphics to advance the next generation of Samsung Exynos solutions,” said David Wang, Senior Vice President of the Radeon Technologies Group at AMD. “The extension of our work with Samsung is a testament to our strong technology partnership and commitment to bring the best experiences possible to mobile users.”

Samsung and AMD first announced their partnership to license AMD RDNA graphics architecture in 2019, leading to the co-development of Samsung Xclipse, a mobile graphics processing unit (GPU) based on the AMD RDNA 2 architecture in 2022. Xclipse was the industry’s first mobile GPU with hardware-accelerated ray tracing and variable rate shading features for console-like gameplay on mobile devices.

Exynos: The Technology Intensive System Semiconductor

In the first installment of this series, Samsung Newsroom shares the importance of the graphics processing unit (GPU) and image signal processor (ISP) in the Exynos mobile processor (SoC). Before meeting with the seven IP development leaders, Samsung Newsroom first met with the SoC Development Head and Senior Vice President Mingoo Kim, who oversees system-on-chip (SoC) design in the System LSI Business.

Kim first explained the fundamental reason behind the concept of SoC, in which various features are all incorporated into a single chip. “When chips are divided, it becomes difficult to manage their power consumption completely,” Kim said. “When each feature consumes power separately, the battery efficiency also decreases. In addition, the bandwidth limit and transfer time latency will affect data transmission between chips, which can lead to reduction in performance.” Consuming minimal power is very important for smartphones because, unlike desktop computers, smartphones are not continuously supplied with power.

“SoC has high efficiency due to comprehensive power control. And as a single chip, it also takes up less space within a smartphone,” Kim explained. “When all functions are performed by a single chip, performance is significantly improved.” Modern mobile phones go beyond simply sending and receiving calls and texts and have evolved to perform a multitude of advanced functions, including taking videos, mobile gaming and accessing financial services. The SoC, which is smaller than a thumb nail, has played a big role in making this possible.

As the SoC is the epitome of all main types of information technology that exist today, Kim described it as the “flower of system semiconductors.” “SoC is not an easy field to work in, but it’s an optimistic field that any engineer would aspire to become a part of,” Kim said. “The role of SoC will be limitless in future industries, such as the metaverse, autonomous driving and 6G.”

Samsung will continue to focus on developing proprietary IP, including GPUs, NPUs, ISPs, modems, RF and more. Samsung strives to take another step forward in chip design to become a platform solution company. “With our competitiveness in SoC, we aim to see Exynos recognized as the best mobile processor brand available,” Kim said. “Through this feature series, we hope the role and importance of SoC, the characteristics and advantages of Exynos as well as its developmental direction will be shared with more people.”

Expanding the Possibilities of Mobile Gaming: GPU for More Enhanced Graphics

In general, graphics processing requires large-scale computation, and it is faster and more efficient if processed in parallel (parallel processing). However, the structure of a central processing unit (CPU) is specialized for fast, serial processing. As such, graphics processing with a CPU would cause important computations to be delayed due to this constant computational performance by CPU. One example of this can be seen when playing a game. It’s possible that your character may not be able to avoid an enemy due to the touch input being delayed while graphics are being rendered on the display.

To address these issues, GPU was developed. Before there were GPUs, CPUs took care of everything. However, GPU was conceived to increase efficiency as a separate accelerator for similar computations that are frequently used. In short, CPU is like a general-purpose calculator while GPU is a large-scale parallel calculator specializing in graphics processing. This is how GPU came to be, and it is one of the key components in graphics processing. It receives commands from CPU and displays an object’s shape, location, color and texture on the monitor.

The Xclipse 920 equipped in the Exynos 2200 is the first mobile GPU Samsung jointly developed with AMD, a U.S. based global company that specializes in semiconductor products like GPU for PC and consoles. The name ‘Xclipse’ is a combination of the ‘X’ from Exynos and the word ‘eclipse.’ The name represents Samsung’s goal to go beyond the limits of mobile gaming and carry out performance on the level of console games, ushering in a new era of gaming.

▲Vice President Sungboem Park, a mobile processor design expert who oversees GPU development

In line with this, Samsung collaborated with AMD to develop a power efficient, console-level GPU for mobile devices. AMD’s GPUs are designed specifically for PCs or consoles, meaning they had to be redesigned to fit the mobile environment. Specifically, it was redesigned to accommodate the memory bandwidth of mobile, which is relatively limited, in addition to managing heat dissipation. “Based on our rich knowledge of low-power design, acquired from developing mobile SoCs, we were able to successfully achieve power efficiency and miniaturization in the first-generation product,” said Vice President Sungboem Park, a mobile processor design expert who oversees GPU development. “We focused heavily on minimizing heat, because mobile devices do not have fans like gaming consoles, while also maintaining performance so that the frames do not lag.”

The main role of the GPU in Exynos is to display objects in a 3D virtual space on a 2D smartphone screen, a role that is especially important when playing graphically demanding games on mobile devices. In particular, the Xclipse 920 is the first mobile GPU to support hardware-accelerated ray tracing (RT). Ray tracing is a technology which produces realistic lighting effects by simulating light rays reflected from 3D objects. By being accelerated by hardware rather than software, Xclipse 920 is able to perform real-time computations faster. In addition, variable rate shading (VRS) technology adjusts the amount of GPU computation depending on changes in color, shade, movement and other variables of the objects on screen to reduce GPU overload.

▲The Xclipse 920 has its own hardware support for ray tracing (RT) technology, which produces realistic lighting effects by simulating light rays reflected from 3D objects.

As the number of game users grows and graphics become more detailed, the development direction of GPU is becoming increasingly more important. This includes increasing the performance level to that of high-performance consoles while lowering battery consumption. By improving these two crucial areas, users are able to experience high fidelity graphics on mobile devices similarly to how they are experienced on consoles. “In general, mobile tends to lag around five years or so behind consoles when it comes to graphics technology, however, we were able to incorporate the latest console technologies in the Exynos 2200 mobile processor quickly through our collaboration with AMD. The SoC is applied to the Galaxy S22,” Park said. “We plan to continue to implement other features in the RDNA series by working closely with AMD going forward.”

“As the performance of smartphones has become enhanced overall, it’s true that it’s not easy to create a performance edge that is significant enough for consumers to notice,” Park answered when asked about the future direction of mobile GPUs. “From now on, the reason for flagship smartphone users to purchase the latest smartphones will most likely be dependent on gaming performance,” he said. This means that the possibility of the further advancement of GPUs, which determines a smartphone’s gaming performance, is high.

He also predicted that mobile GPUs will become even more important in the fields of AR and VR as well. “For AR, GPUs will need to be equipped in lightweight devices, such as glasses, so a low-power design is very important,” Park said. “Performance requirements are much more demanding in the field of VR, as the entire visible virtual world needs to be rendered instantly. As such, we need to satisfy various development requirements while also generating more realistic images at a much faster rate than we currently can. So, the advancement of mobile GPU is crucial going ahead and will have limitless applications,” he emphasized.

Elevating the Level of Satisfaction in Camera Performance: ISP for More Natural and Vivid Images

An ISP corrects raw data transferred from an image sensor and creates a photo or video to a form preferred by the user. ISP also corrects the potential physical limitations of a camera module — comprised of an optical system and an image sensor — interpolates red, green and blue (R/G/B) and removes noise. In addition, it carries out post processing, such as adjusting the brightness of a video and emphasizing detailed areas. Simply put, through fine tuning and post processing, ISP generates the picture or video that is most desirable by the users.

▲ Whole process of ISP in Mobile Camera

In earlier smartphone models, ISP was equipped as a separate chip. However, due to market demand, embedded ISP soon became the norm. “At first, we cooperated with research institutes overseas to develop a high-performing ISP that can be used for digital cameras,” said Jongseong Choi, a project leader (PL) in the Multimedia Development Team who has been working in the video processing field for more than 20 years. “As a result, our first embedded ISP solution was utilized in the Galaxy S4’s main camera.” Since 2012, the Exynos mobile processor has been contributing to a substantial advancement in smartphone cameras’ video image quality through the internalization of ISP, enabling performance at the level of digital single-lens reflex (DSLR) cameras.

▲Jongseong Choi, Project Leader of the Multimedia Development Team, has been working in the video processing field for more than 20 years.

With a high-performing ISP, consumers are able to enjoy higher video image quality as well as faster processing speeds. “It’s difficult to explain in specific numbers how great a photo is because photography is subjective, but we are conducting various research studies such as video evaluation using deep learning and ISP tuning technique to create natural and sharp photos and videos,” Choi explained. In addition, ISP also determines the speed of the burst rate in continuous shooting and is responsible for the fast-processing of high-resolution photos and videos.

The high-performing ISP equipped in the latest Exynos can process up to 200 million pixels. Up to seven image sensors are supported, and videos and images from up to four image sensors can be processed simultaneously. Also included is the ability to apply different parameters per each element, such as sky, bushes, skin and so on by incorporating semantic segmentation technology that recognizes the scenes being captured with the help of NPU. The AI feature detects and marks a person’s face and adjusts the brightness, focus and color of the video based on the face’s coordinates.

▲ Example of contents aware image processing using semantic segmentation

When asked about the future direction of ISP, Choi answered that development will be focused on maintaining low-power usage and improving video image quality. “The data transferred from the image sensor is processed in real-time by ISP, but the amount of data is increasing exponentially,” Choi said. “So, a significant amount of power is consumed in writing the data into memory and then in retrieving it later. ISP in Exynos, however, is designed to save data in memory only once, thereby minimizing power consumption,” he emphasized.

“The era of videos has arrived faster than expected and, because of this, we’re focusing on improving the video image quality,” Choi said. “In particular, we’re making efforts to increase our competitiveness by improving the video image quality, even those taken in dark, low-light environments.”

* All images shown are provided for illustrative purposes only and may not be an exact representation of the product or images captured with the product. All images are digitally edited, modified or enhanced.

Samsung Electronics, the world leader in advanced memory technology, today announced that it has successfully developed a second generation of its pioneering SmartSSD.

The new proprietary computational storage incorporates data processing functionality within a high-performance SSD. Unlike existing SSDs, Samsung’s SmartSSD can process data directly, thereby minimizing data transfers between the CPU, GPU and RAM. This technology can avoid the bottlenecks that often occur when moving data between storage devices and CPUs, resulting in markedly improved system performance and much higher energy efficiency.

The SmartSSD is playing an increasingly important role, especially with the growth of next-generation technologies such as AI, machine learning and 5G/6G, which require large amounts of data processing.

Leveraging software and intellectual property (IP) developed by customers, along with in-built Arm cores, Samsung’s second-generation SmartSSD enables much more efficient data processing. Compared to conventional data center solid-state drives, processing time for scan-heavy database queries can be slashed by over 50%, energy consumption by up to 70% and CPU utilization by up to 97%.

Since its development in 2020 through the joint efforts of Samsung and AMD, the first-generation SmartSSD is being supplied to global IT companies including video communications platform providers. The first-generation SmartSSD was recognized as an Innovation Awards Honoree at CES 2021 for its outstanding performance and energy efficiency.

“Commercialization of the first-generation SmartSSD, in collaboration with AMD, established that the computational storage market has great potential,” said Jin-Hyeok Choi, Executive Vice President and Head of Memory Solution Product & Development at Samsung Electronics. “With the upgraded processing functionality of the second-generation SmartSSD, Samsung will be able to easily address increasing customer needs in the database and video transcoding sectors, as we expand the boundaries of the next-generation storage market.”

“Powered by Xilinx Versal Adaptive SoCs from AMD, second-generation Samsung SmartSSDs enable improved CPU efficiency and greatly reduced energy consumption by efficiently integrating the computing and storage functions in data centers,” said Sina Soltani, Corporate Vice President of Sales, AECG, Data Center and Communication Group at AMD. “As data-intensive applications continue to grow, second-generation Samsung SmartSSDs will deliver the superior performance and efficiency required for this expanding market.”

Samsung Electronics is leading efforts to standardize SmartSSD technology through close collaboration with the Storage Networking Industry Association (SNIA) and with NVM Express, while seeking to expand the boundaries of SmartSSD devices through technological validation for a wide variety of applications.

“Built on the most advanced 4-nanometer (nm) EUV (extreme ultraviolet lithography) process, and combined with cutting-edge mobile, GPU and NPU technology, Samsung has crafted the Exynos 2200 to provide the finest experience for smartphone users. With the Xclipse, our new mobile GPU built with RDNA 2 graphics technology from the industry leader AMD, the Exynos 2200 will redefine mobile gaming experience, aided by enhanced graphics and AI performance,” said Yongin Park, President of System LSI Business at Samsung Electronics. “As well as bringing the best mobile experience to the users, Samsung will continue its efforts to lead the journey in logic chip innovation.”

The Industry’s First Hardware-Accelerated Ray Tracing on Mobile for the Ultimate Gaming Experience

The Xclipse GPU is a one-of-a-kind hybrid graphic processor that is positioned between the console and the mobile graphic processor. Xclipse is the combination of ‘X’ that represents Exynos, and the word ‘eclipse’. Like an eclipse, the Xclipse GPU will bring an end to the old era of mobile gaming and mark the start of an exciting new chapter.

With the high-performance AMD RDNA 2 architecture as its backbone, the Xclipse inherits advanced graphic features such as hardware accelerated ray tracing (RT) and variable rate shading (VRS) that were previously only available on PCs, laptops and consoles.

Ray tracing is a revolutionary technology that closely simulates how light physically behaves in the real world. By calculating the movement and the color characteristic of light rays as they bounce off the surface, ray tracing produces realistic lighting effects for graphically rendered scenes. To offer the most immersive graphics and user experiences even on mobile, Samsung has collaborated with AMD to realize the industry’s first ever hardware-accelerated ray tracing on mobile GPU.

Variable rate shading is a technique that optimizes GPU workload by allowing developers to apply lower shading rate in areas where overall quality will not be affected. This gives GPU more room to work on areas that matter most to the gamers and improve frame-rate for smoother gameplay.

In addition, the Xclipse GPU comes with various technologies such as advanced multi-IP governor (AMIGO) that enhance overall performance and efficiency.

“AMD RDNA 2 graphics architecture extends power-efficient, advanced graphics solutions to PCs, laptops, consoles, automobiles and now to mobile phones. Samsung’s Xclipse GPU is the first result of multiple planned generations of AMD RDNA graphics in Exynos SoCs,” said David Wang, Senior Vice President of Radeon Technologies Group at AMD. “We can’t wait for mobile phone customers to experience the great gaming experiences based on our technology collaboration.”

Enhanced 5G Connectivity and Ironclad Security Features

The Exynos 2200 is one of the first in the market to integrate Arm’s latest Armv9 CPU cores which offer a substantial improvement over Armv8 in terms of security and performance, the two areas that are becoming critically important in today’s mobile communications devices.

The octa-core CPU of Exynos 2200 is designed in a tri-cluster structure made up of a single powerful Arm Cortex^®-X2 flagship-core, three performance and efficiency balanced Cortex-A710 big-cores and four power-efficient Cortex-A510 little-cores.

“The digital experiences of tomorrow require new levels of performance, security and efficiency,” said Rene Haas, President of IP Products Group (IPG) at Arm. “As one of the first processors to incorporate the new Armv9 CPU cores, Samsung’s Exynos 2200 takes advantage of Arm’s Total Compute strategy and key security features, like Memory Tagging Extension (MTE), to deliver the purpose-built compute and specialized processing needed to power future mobile experiences.”

The Exynos 2200 offers more powerful on-device artificial intelligence (AI) with an upgraded NPU. The NPU’s performance has doubled compared to its predecessor, allowing more calculations in parallel and enhancing the AI performance. The NPU now offers much higher precision with FP16 (16bit floating point) support in addition to power efficient INT8 (8bit integer) and INT16.

Also, the Exynos 2200 integrates a fast 3GPP Release 16 5G modem supporting both sub-6GHz and mmWave (millimeter Wave) spectrum bands. With E-UTRAN New Radio – Dual Connectivity (EN-DC), which utilizes both 4G LTE and 5G NR signals, the modem can boost the speed up to 10Gbps.

For safekeeping, the Exynos 2200 comes with Integrated Secure Element (iSE) to store private cryptographic keys as well as to play a role as RoT (Root of Trust). Also, an inline encryption HW for UFS and DRAM has been reinforced to have user data encryption safely shared only within the secure domain.

Providing Enhanced Visual Experience and Professional-Level Quality Images

The Exynos 2200’s image signal processor (ISP) architecture has been redesigned to support the latest image sensors for ultra-high resolution of up to 200 megapixel (MP). At 30 frames-per-second (fps), the ISP supports up to 108 MP in single camera mode, and 64+36 MP in dual camera mode. It can also connect up to seven individual image sensors and drive four concurrently for advanced multi-camera setups. For video recording, the ISP supports up to 4K HDR (or 8K) resolution.

Together with the NPU, the ISP utilizes an advanced content-aware AI camera for more refined and realistic results. When taking a photograph, the machine learning based AI camera recognizes multiple objects, the environment and faces within the scene. It then applies optimal settings for color, white balance, exposure, dynamic range and more to produce professional-level quality images.

With 8K resolution support, the Exynos 2200’s advanced multi-format codec (MFC) makes videos truly come to life. It decodes videos up to 4K at 240fps or 8K at 60fps and encodes up to 4K at 120fps or 8K at 30fps. In addition, the MFC integrates power efficient AV1 decoder enabling longer playback time. The advanced display solution features HDR10+ adding more dynamic range and depth to the picture and offers refresh rates of up to 144Hz for a more responsive and smoother transitioning experience when scrolling or playing games.

The Exynos 2200 is currently in mass production. Click here to learn more about the Exynos 2200.

For more information about Samsung’s Exynos products, please visit http://www.samsung.com/exynos.

^* Actual performance may vary depending on device and user environment.

AMD and Samsung Electronics today announced a multi-year strategic partnership in ultra low power, high performance mobile graphics IP based on AMD Radeon graphics technologies. As part of the partnership, Samsung will license AMD graphics IP and will focus on advanced graphics technologies and solutions that are critical for enhancing innovation across mobile applications, including smartphones.

“As we prepare for disruptive changes in technology and discover new opportunities, our partnership with AMD will allow us to bring groundbreaking graphics products and solutions to market for tomorrow’s mobile applications,” said Inyup Kang, president of Samsung Electronics’ S.LSI Business. “We look forward to working with AMD to accelerate innovations in mobile graphics technologies that will help take future mobile computing to the next level.”

“Adoption of our Radeon graphics technologies across the PC, game console, cloud and HPC markets has grown significantly and we are thrilled to now partner with industry leader Samsung to accelerate graphics innovation in the mobile market,” said Dr. Lisa Su, AMD president and CEO. “This strategic partnership will extend the reach of our high-performance Radeon graphics into the mobile market, significantly expanding the Radeon user base and development ecosystem.”

Key terms of the partnership include:

• AMD will license custom graphics IP based on the recently announced, highly-scalable RDNA graphics architecture to Samsung for use in mobile devices, including smartphones, and other products that complement AMD product offerings.
• Samsung will pay AMD technology license fees and royalties.