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  • Express the exceptional
    Express the exceptional
    Express the exceptional
    Image of the Samsung Exynos 2600 chipset positioned on a smartphone, representing next-generation mobile processing and on-device AI performance
Get ready for a new mobile experience. Based on the industry’s first 2nm GAA process, the Exynos 2600 delivers enhanced AI and gaming experiences by integrating powerful CPU, NPU, and GPU into a single compact chip. With it, you can do more, with less. Get ready for a new mobile experience. Based on the industry’s first 2nm GAA process, the Exynos 2600 delivers enhanced AI and gaming experiences by integrating powerful CPU, NPU, and GPU into a single compact chip. With it, you can do more, with less. Get ready for a new mobile experience. Based on the industry’s first 2nm GAA process, the Exynos 2600 delivers enhanced AI and gaming experiences by integrating powerful CPU, NPU, and GPU into a single compact chip. With it, you can do more, with less.
  • Black CPU microchip icon representing multi-core processor architecture
    Deca-core CPU with the latest Arm®v9.3 architecture
    CPU
  • Black smartphone icon representing on-device AI processing
    On-device AI
    AI
  • Black arrow icon indicating dynamic visual processing
    Ray Tracing & ENSS
    Gaming
  • Black camera icon representing advanced image processing features
    DVNR & VPS technology
    Camera
  • Black thermometer icon representing thermal management
    Heat Path Block
    Package
  • Black lightning icon representing power efficiency
    Industry’s first 2nm GAA & Low power design
    Power Efficiency
Smartphone screen displaying multiple floating cards with images, messages, translation text, photo editing, and document summaries against a blue background

What real performance looks like What real performance looks like What real performance looks like

Utilizing Arm’s latest cores—Arm® C1-Ultra and C1-Pro—along with Arm’s compute subsystem, the Exynos 2600 delivers powerful performance. Whereas its predecessor¹ was outfitted with a tri-cluster structure of big, middle, and little cores, it upgrades the little cores to middle cores to cover a broader performance envelope — improving efficiency without compromising peak performance. On top of that, the latest Arm®v9.3 architecture empowers on-CPU machine learning performance. With support for the Scalable Matrix Extension 2 (SME2) instruction, AI computation efficiency and processing speed have been further improved, minimizing response latency during on-device AI execution to improve the overall user experience. This enhancement improves overall CPU computing performance up to 39% and boosts power efficiency.²

Utilizing Arm’s latest cores—Arm® C1-Ultra and C1-Pro—along with Arm’s compute subsystem, the Exynos 2600 delivers powerful performance. Whereas its predecessor¹ was outfitted with a tri-cluster structure of big, middle, and little cores, it upgrades the little cores to middle cores to cover a broader performance envelope — improving efficiency without compromising peak performance. On top of that, the latest Arm®v9.3 architecture empowers on-CPU machine learning performance. With support for the Scalable Matrix Extension 2 (SME2) instruction, AI computation efficiency and processing speed have been further improved, minimizing response latency during on-device AI execution to improve the overall user experience. This enhancement improves overall CPU computing performance up to 39% and boosts power efficiency.²

Utilizing Arm’s latest cores—Arm® C1-Ultra and C1-Pro—along with Arm’s compute subsystem, the Exynos 2600 delivers powerful performance. Whereas its predecessor¹ was outfitted with a tri-cluster structure of big, middle, and little cores, it upgrades the little cores to middle cores to cover a broader performance envelope — improving efficiency without compromising peak performance. On top of that, the latest Arm®v9.3 architecture empowers on-CPU machine learning performance. With support for the Scalable Matrix Extension 2 (SME2) instruction, AI computation efficiency and processing speed have been further improved, minimizing response latency during on-device AI execution to improve the overall user experience. This enhancement improves overall CPU computing performance up to 39% and boosts power efficiency.²

Bring the power of AI Bring the power of AI Bring the power of AI


The Exynos 2600 provides a major improvement in AI performance, featuring a powerful NPU that improves generative AI performance by 113% compared to its predecessor.³ These enhancements enable the execution of larger and more diverse on-device AI models, making the Exynos 2600 a premier on-device AI SoC. Additional improvements in the NPU architecture significantly enhance generative AI computational efficiency by reducing both power consumption and latency. Thanks to these improvements, you can perform more on-device AI tasks — such as intelligent image editing and AI assistant functions — quicker and more efficiently. Beyond performance, on-device privacy strengthens through virtualization security and hardware-backed hybrid Post-Quantum Cryptography (PQC), which is the first in mobile SoCs, enabling ROM-rooted protection for future-proof security.


The Exynos 2600 provides a major improvement in AI performance, featuring a powerful NPU that improves generative AI performance by 113% compared to its predecessor.³ These enhancements enable the execution of larger and more diverse on-device AI models, making the Exynos 2600 a premier on-device AI SoC. Additional improvements in the NPU architecture significantly enhance generative AI computational efficiency by reducing both power consumption and latency. Thanks to these improvements, you can perform more on-device AI tasks — such as intelligent image editing and AI assistant functions — quicker and more efficiently. Beyond performance, on-device privacy strengthens through virtualization security and hardware-backed hybrid Post-Quantum Cryptography (PQC), which is the first in mobile SoCs, enabling ROM-rooted protection for future-proof security.


The Exynos 2600 provides a major improvement in AI performance, featuring a powerful NPU that improves generative AI performance by 113% compared to its predecessor.³ These enhancements enable the execution of larger and more diverse on-device AI models, making the Exynos 2600 a premier on-device AI SoC. Additional improvements in the NPU architecture significantly enhance generative AI computational efficiency by reducing both power consumption and latency. Thanks to these improvements, you can perform more on-device AI tasks — such as intelligent image editing and AI assistant functions — quicker and more efficiently. Beyond performance, on-device privacy strengthens through virtualization security and hardware-backed hybrid Post-Quantum Cryptography (PQC), which is the first in mobile SoCs, enabling ROM-rooted protection for future-proof security.

Woman using a smartphone outdoors, with on-device AI assistant conversation and image-based recommendations shown on the screen
Fantasy gaming scene showing a knight battling a dragon inside a dark stone hall, highlighting detailed lighting and visual effects Fantasy gaming scene showing a knight battling a dragon inside a dark stone hall, highlighting detailed lighting and visual effects Fantasy gaming scene showing a knight battling a dragon inside a dark stone hall, highlighting detailed lighting and visual effects

Get your head in the game

Get your head in the game

Get your head in the game

Thanks to a new architecture, the computing performance of the Exynos Xclipse 960 GPU is twice as high as that of its predecessor.⁴ This drives a ray tracing performance improvement of up to 50%.⁵ Additionally, the Exynos 2600 now includes Exynos Neural Super Sampling (ENSS™) technology, which delivers AI-based resolution upscaling and frame generation — boosting gaming experiences that feel up to three times smoother,⁶ even under limited power budgets. Finally, the Exynos 2600 refines its power domain structure to further enhance efficiency, resulting in smoother, more immersive gaming for longer. Thanks to a new architecture, the computing performance of the Exynos Xclipse 960 GPU is twice as high as that of its predecessor.⁴ This drives a ray tracing performance improvement of up to 50%.⁵ Additionally, the Exynos 2600 now includes Exynos Neural Super Sampling (ENSS™) technology, which delivers AI-based resolution upscaling and frame generation — boosting gaming experiences that feel up to three times smoother,⁶ even under limited power budgets. Finally, the Exynos 2600 refines its power domain structure to further enhance efficiency, resulting in smoother, more immersive gaming for longer. Thanks to a new architecture, the computing performance of the Exynos Xclipse 960 GPU is twice as high as that of its predecessor.⁴ This drives a ray tracing performance improvement of up to 50%.⁵ Additionally, the Exynos 2600 now includes Exynos Neural Super Sampling (ENSS™) technology, which delivers AI-based resolution upscaling and frame generation — boosting gaming experiences that feel up to three times smoother,⁶ even under limited power budgets. Finally, the Exynos 2600 refines its power domain structure to further enhance efficiency, resulting in smoother, more immersive gaming for longer.
Group selfie displayed on a smartphone screen, showing clear faces and balanced lighting

Smarter, sharper photos Smarter, sharper photos Smarter, sharper photos

Supporting AI-based image processing, the Exynos 2600 delivers a premium mobile photography experience. In particular, the introduction of an AI-based Visual Perception System (VPS) allows the ISP to recognize a variety of detailed elements — even blinking — within images and videos, and process them in real time, while reducing power consumption by up to 50% compared to its predecessor.⁷ Moreover, the Exynos 2600 brings additional enhancements that serve to vastly improve the overall camera experience, including Deep learning Video Noise Reduction (DVNR), which enhances video quality in low-light conditions at low power. This AI-based improvement enables you to get the best results with just one capture. The Exynos 2600 also supports cameras of up to 320MP and newly adopts the APV⁸ codec, which further improves detail and color precision in videos to a professional level.

Supporting AI-based image processing, the Exynos 2600 delivers a premium mobile photography experience. In particular, the introduction of an AI-based Visual Perception System (VPS) allows the ISP to recognize a variety of detailed elements — even blinking — within images and videos, and process them in real time, while reducing power consumption by up to 50% compared to its predecessor.⁷ Moreover, the Exynos 2600 brings additional enhancements that serve to vastly improve the overall camera experience, including Deep learning Video Noise Reduction (DVNR), which enhances video quality in low-light conditions at low power. This AI-based improvement enables you to get the best results with just one capture. The Exynos 2600 also supports cameras of up to 320MP and newly adopts the APV⁸ codec, which further improves detail and color precision in videos to a professional level.

Supporting AI-based image processing, the Exynos 2600 delivers a premium mobile photography experience. In particular, the introduction of an AI-based Visual Perception System (VPS) allows the ISP to recognize a variety of detailed elements — even blinking — within images and videos, and process them in real time, while reducing power consumption by up to 50% compared to its predecessor.⁷ Moreover, the Exynos 2600 brings additional enhancements that serve to vastly improve the overall camera experience, including Deep learning Video Noise Reduction (DVNR), which enhances video quality in low-light conditions at low power. This AI-based improvement enables you to get the best results with just one capture. The Exynos 2600 also supports cameras of up to 320MP and newly adopts the APV⁸ codec, which further improves detail and color precision in videos to a professional level.

Diagram-style image showing DRAM and HPB memory blocks connected through a shared die, with data flow visualized Diagram-style image showing DRAM and HPB memory blocks connected through a shared die, with data flow visualized Diagram-style image showing DRAM and HPB memory blocks connected through a shared die, with data flow visualized

Pure thermal innovation

Pure thermal innovation

Pure thermal innovation

The Exynos 2600 pioneers heat management by adopting the Heat Path Block (HPB) — a first in the mobile SoC industry — and improves thermal dissipation efficiency through the application of High-k EMC. The HPB optimizes the heat-transfer path to disperse heat more efficiently, helping the Exynos 2600 sustain high performance within a size suitable for mobile devices. That improved heat flow lowers thermal resistance up to 16%,⁹ allowing internal heat to move outward more quickly so the SoC’s internal temperature remains stable, even under heavy loads. As a result, overall performance is enhanced, giving you consistently smooth and reliable experiences in demanding scenarios like high-end gaming and AI processing. The Exynos 2600 pioneers heat management by adopting the Heat Path Block (HPB) — a first in the mobile SoC industry — and improves thermal dissipation efficiency through the application of High-k EMC. The HPB optimizes the heat-transfer path to disperse heat more efficiently, helping the Exynos 2600 sustain high performance within a size suitable for mobile devices. That improved heat flow lowers thermal resistance up to 16%,⁹ allowing internal heat to move outward more quickly so the SoC’s internal temperature remains stable, even under heavy loads. As a result, overall performance is enhanced, giving you consistently smooth and reliable experiences in demanding scenarios like high-end gaming and AI processing. The Exynos 2600 pioneers heat management by adopting the Heat Path Block (HPB) — a first in the mobile SoC industry — and improves thermal dissipation efficiency through the application of High-k EMC. The HPB optimizes the heat-transfer path to disperse heat more efficiently, helping the Exynos 2600 sustain high performance within a size suitable for mobile devices. That improved heat flow lowers thermal resistance up to 16%,⁹ allowing internal heat to move outward more quickly so the SoC’s internal temperature remains stable, even under heavy loads. As a result, overall performance is enhanced, giving you consistently smooth and reliable experiences in demanding scenarios like high-end gaming and AI processing.
Split-screen image showing a person using a smartphone for messaging in daylight and gaming at night, with a power efficiency indicator displayed between the scenes Split-screen image showing a person using a smartphone for messaging in daylight and gaming at night, with a power efficiency indicator displayed between the scenes Split-screen image showing a person using a smartphone for messaging in daylight and gaming at night, with a power efficiency indicator displayed between the scenes

Pump up the power efficiency

Pump up the power efficiency

Pump up the power efficiency

Through its unprecedented 2nm GAA process, the Exynos 2600 achieves high marks in both performance and power efficiency. Another crucial driver behind these capabilities is the precise optimization of each IP. With an enhanced CPU architecture and optimized implementation, power consumption is improved across diverse operational workloads. By adopting a new power structure and ENSS™, the GPU enables more efficient use of limited power budgets based on usage conditions. With upgraded on-device AI performance and the addition of VPS and DVNR in the ISP, power efficiency is further optimized under more complex and sophisticated user scenarios. From manufacturing process to individual IP design, the Exynos 2600 represents continuous efforts to boost power efficiency. Through its unprecedented 2nm GAA process, the Exynos 2600 achieves high marks in both performance and power efficiency. Another crucial driver behind these capabilities is the precise optimization of each IP. With an enhanced CPU architecture and optimized implementation, power consumption is improved across diverse operational workloads. By adopting a new power structure and ENSS™, the GPU enables more efficient use of limited power budgets based on usage conditions. With upgraded on-device AI performance and the addition of VPS and DVNR in the ISP, power efficiency is further optimized under more complex and sophisticated user scenarios. From manufacturing process to individual IP design, the Exynos 2600 represents continuous efforts to boost power efficiency. Through its unprecedented 2nm GAA process, the Exynos 2600 achieves high marks in both performance and power efficiency. Another crucial driver behind these capabilities is the precise optimization of each IP. With an enhanced CPU architecture and optimized implementation, power consumption is improved across diverse operational workloads. By adopting a new power structure and ENSS™, the GPU enables more efficient use of limited power budgets based on usage conditions. With upgraded on-device AI performance and the addition of VPS and DVNR in the ISP, power efficiency is further optimized under more complex and sophisticated user scenarios. From manufacturing process to individual IP design, the Exynos 2600 represents continuous efforts to boost power efficiency.

Specifications

Explore more about Exynos 2600

  • 1. Predecessor model refers to the Exynos 2500.
  • 2. Based on internal testing in comparison to the Exynos 2500. Results may vary depending on operating conditions and other factors.
  • 3. Based on internal testing in comparison to the Exynos 2500. Results may vary depending on operating conditions and other factors.
  • 4. Based on internal testing in comparison to the Exynos 2500. Results may vary depending on operating conditions and other factors.
  • 5. Based on internal testing in comparison to the Exynos 2500. Results may vary depending on operating conditions and other factors.
  • 6. Refers to simultaneous use of Neural Super Sampling and Neural Frame Generation. Based on internal testing in comparison to the Exynos 2500. Results may vary depending on operating conditions and other factors.
  • 7. Based on internal testing in comparison to the Exynos 2500. Results may vary depending on operating conditions and other factors.
  • 8. Advanced Professional Video.
  • 9. Based on internal testing in comparison to the Exynos 2500. Results may vary depending on operating conditions and other factors.

  • * All functionality, features, specifications and other product information provided in this document including, but not limited to, the benefits, components, performance, availability, and capabilities of the product are subject to change without notice or obligation.
  • * All product specifications reflect internal test results and are subject to variations by user’s system configuration. Actual performance may vary depending on use conditions and environment.
  • * All the depicted devices and features are fictitious creations. No simulation of any real product is intended.
  • * 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 reserves the right to change images and specifications at any time without notice. Measurements are approximate. All data were deemed correct at time of creation. Samsung is not liable for errors or omissions.
  • * Arm and Cortex are trademarks or registered trademarks of Arm Limited (or its subsidiaries) in the US and/or elsewhere.
  • * Images and videos in this content were created using generative AI.