1 Speed and power efficiency metrics are in comparison to the GDDR7 predecessor, GDDR6.
Samsung’s GDDR7 offers the fastest available performance of any standardized graphics memory product.
This performance is made possible through the industry’s first application of PAM3 signaling2.
PAM3 transmits 1.5 times more data in the same signal cycle than the conventional NRZ method 3,
giving GDDR7 a 30% performance improvement over its predecessor.
2 Pulse Amplitude Modulation 3 (PAM3) is a signal transmission technology.
3 Non return to zero (NRZ) modulation encodes data using two signal levels, while PAM3 uses three signal levels.
Benefit from higher reliability. GDDR7 achieves a 70% decrease in thermal resistance4 by using new package materials and an optimized circuit design. This allows it to avoid excessive heat generation, which prevents product degradation, performance loss and other potential hardware issues.
4 In comparison to the GDDR7 predecessor, GDDR6.
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All product specifications reflect internal test results and are subject to variations by the user's system configuration
All product images shown are for illustration purposes only and may not be an exact representation of the product
Samsung reserves the right to change product images and specifications at any time without notice
For further details on product specifications, please contact the sales representative of your region.
GDDR7 is a next-generation high-speed memory optimized for speed,
power efficiency, and cost-effectiveness in current graphics and AI computing environments.
- Speed: Suitable for data-intensive tasks like 4K–8K graphics, high-refresh-rate gaming, and AI inference.
- Power efficiency: Uses PAM3 signaling for higher transfer efficiency, reducing power consumption and heat.
- Cost efficiency: Provides high bandwidth at lower cost than HBM, making it an attractive alternative for performance-demanding
but budget-sensitive systems.
GDDR7 is a next-generation high-speed memory optimized for speed,
power efficiency, and cost-effectiveness in current graphics
and AI computing environments.
- Speed: Suitable for data-intensive tasks like 4K–8K graphics,
high-refresh-rate gaming, and AI inference.
- Power efficiency: Uses PAM3 signaling for higher transfer efficiency,
reducing power consumption and heat.
- Cost efficiency: Provides high bandwidth at lower cost than HBM,
making it an attractive alternative for performance-demanding
but budget-sensitive systems.
GDDR7 is a next-generation high-speed memory optimized for speed, power efficiency, and cost-effectiveness in current graphics and AI computing environments.
- Speed: Suitable for data-intensive tasks like 4K–8K graphics, high-refresh-rate gaming, and AI inference.
- Power efficiency: Uses PAM3 signaling for higher transfer efficiency, reducing power consumption and heat.
- Cost efficiency: Provides high bandwidth at lower cost than HBM, making it an attractive alternative for performance-demanding but budget-sensitive systems.
GDDR7 is a next-generation graphics DRAM designed for high bandwidth,
high efficiency, and low power—targeting graphics, AI, and high-performance systems.
It serves as a key enabler for future computing environments such as
high-resolution image processing, AI inference acceleration, and sensor fusion in autonomous driving.
GDDR7 is a next-generation graphics DRAM designed for high bandwidth,
high efficiency, and low power—targeting graphics, AI, and high-performance systems.
It serves as a key enabler for future computing environments such as
high-resolution image processing, AI inference acceleration,
and sensor fusion in autonomous driving.
GDDR7 is a next-generation graphics DRAM designed for high bandwidth, high efficiency, and low power—targeting graphics, AI, and high-performance systems.
It serves as a key enabler for future computing environments such as high-resolution image processing, AI inference acceleration, and sensor fusion in autonomous driving.
GDDR is designed for parallelism and bandwidth as a high-speed graphics memory,
whereas standard DDR is designed for general-purpose use and higher capacity as system memory.
Both belong to the DRAM family, but differ fundamentally in architecture, clocking,
bus structure, and I/O design to suit their respective purposes.
GDDR is designed for parallelism and bandwidth as a high-speed graphics memory,
whereas standard DDR is designed for general-purpose use
and higher capacity as system memory.
Both belong to the DRAM family, but differ fundamentally in architecture, clocking,
bus structure, and I/O design to suit their respective purposes.
GDDR is designed for parallelism and bandwidth as a high-speed graphics memory, whereas standard DDR is designed for general-purpose use and higher capacity as system memory.
Both belong to the DRAM family, but differ fundamentally in architecture, clocking, bus structure, and I/O design to suit their respective purposes.
The main differences between GDDR7 and GDDR6 are improvements in bandwidth, data transfer speed, and signaling technology.
GDDR7 is designed to deliver significantly higher performance, offering faster data rates and greater bandwidth than GDDR6,
even within similar interface widths.
One of the key advancements is the use of PAM3 (Pulse Amplitude Modulation 3-level) signaling,
which allows GDDR7 to transmit more data per clock cycle compared to the NRZ signaling used in GDDR6.
GDDR7 also provides better power efficiency, enabling higher performance while reducing overall power consumption.
The main differences between GDDR7 and GDDR6 are improvements in bandwidth,
data transfer speed, and signaling technology.
GDDR7 is designed to deliver significantly higher performance,
offering faster data rates and greater bandwidth than GDDR6,
even within similar interface widths.
One of the key advancements is the use of PAM3 (Pulse Amplitude Modulation 3-level)
signaling, which allows GDDR7 to transmit more data per clock cycle
compared to the NRZ signaling used in GDDR6.
GDDR7 also provides better power efficiency,
enabling higher performance while reducing overall power consumption.
The main differences between GDDR7 and GDDR6 are improvements in bandwidth, data transfer speed, and signaling technology.
GDDR7 is designed to deliver significantly higher performance, offering faster data rates and greater bandwidth than GDDR6, even within similar interface widths.
One of the key advancements is the use of PAM3 (Pulse Amplitude Modulation 3-level) signaling, which allows GDDR7 to transmit more data per clock cycle compared to the NRZ signaling used in GDDR6.
GDDR7 also provides better power efficiency, enabling higher performance while reducing overall power consumption.
GDDR7 is not a type of system memory that is installed on a standard PC motherboard.
Instead, it is a high-bandwidth graphics DRAM that is soldered directly onto GPUs, AI accelerators,
and high-performance computing modules. Because GDDR7 provides extremely high bandwidth and fast data transfer,
it is used in environments that require rapid memory processing, such as advanced graphics rendering, real-time visualization,
machine learning inference, and large-scale parallel computing.
In other words, GDDR7 is a memory technology used on GPUs and accelerator hardware, not on general-purpose motherboards.
GDDR7 is not a type of system memory that is installed on a standard PC motherboard.
Instead, it is a high-bandwidth graphics DRAM that is soldered directly onto GPUs, AI accelerators,
and high-performance computing modules. Because GDDR7 provides extremely high bandwidth
and fast data transfer, it is used in environments that require rapid memory processing,
such as advanced graphics rendering, real-time visualization, machine learning inference,
and large-scale parallel computing.
In other words, GDDR7 is a memory technology used on GPUs and accelerator hardware,
not on general-purpose motherboards.
GDDR7 is not a type of system memory that is installed on a standard PC motherboard.
Instead, it is a high-bandwidth graphics DRAM that is soldered directly onto GPUs, AI accelerators, and high-performance computing modules. Because GDDR7 provides extremely high
bandwidth and fast data transfer, it is used in environments that require rapid memory processing, such as advanced graphics rendering, real-time visualization,machine learning inference, and large-scale parallel computing.
In other words, GDDR7 is a memory technology used on GPUs and accelerator hardware, not on general-purpose motherboards.
* All product specifications reflect internal test results and are subject to variations by user’s system configuration.
* All product images shown are for illustration purposes only and may not be an exact representation of the product.
* Samsung reserves the right to change product images and specifications at any time without notice.
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