NVIDIA RTX A2000 12GB
Compact Design, Unmatched Performance:
NVIDIA RTX™ technology has fundamentally changed computer graphics, fusing the power of real-time ray tracing, AI, and advanced graphics and compute to drive the next wave of innovation in visual computing. The NVIDIA Ampere architecture is the second generation of NVIDIA RTX—delivering new levels of power and performance to professional workflows, accelerating time to decision, time to market, and time to solution.
NVIDIA Ampere Architecture:
NVIDIA RTX A2000 | RTX A2000 12GB (RTX A2000 series GPUs) is the most powerful dual slot, low profile GPU solution offering high performance real-time ray tracing, AI-accelerated compute, and professional graphics rendering, all of this in a compact design with unmatched performance. Building upon the major SM enhancements from the Turing GPU, the NVIDIA Ampere architecture enhances ray tracing operations, tensor matrix operations, and concurrent executions of FP32 and INT32 operations.
CUDA Cores:
The NVIDIA Ampere architecture-based CUDA cores bring up to 2.7X the single-precision floating point (FP32) throughput compared to the previous generation, providing significant performance improvements for graphics workflows such as 3D model development and compute for workloads such as desktop simulation for computer-aided engineering (CAE). The RTX A2000 series GPUs enable two FP32 primary data paths, doubling the peak FP32 operations.
2nd Generation RT Cores:
Incorporating 2nd generation ray tracing engines, NVIDIA Ampere architecture-based GPUs provide incredible ray traced rendering performance. For the first time NVDIA is introducing RT Cores into a low profile form factor GPU. A single RTX A2000 series board can render complex professional models with physically accurate shadows, reflections, and refractions to empower users with instant insight. Working in concert with applications leveraging APIs such as NVIDIA OptiX, Microsoft DXR and Vulkan ray tracing, systems based on RTX A2000 series GPUs will power truly interactive design workflows to provide immediate feedback for unprecedented levels of productivity. RTX A2000 series GPUs are up to 5X faster in ray tracing compared to the previous generation. This technology also speeds up the rendering of ray-traced motion blur for faster results with greater visual accuracy.
3rd Generation Tensor Cores:
Purpose-built for deep learning matrix arithmetic at the heart of neural network training and inferencing functions, RTX A2000 series GPUs include enhanced Tensor Cores that accelerate more datatypes and includes a new Fine-Grained Structured Sparsity feature that delivers up to 2X throughput for tensor matrix operations compared to the previous generation. New Tensor Cores will accelerate two new TF32 and BFloat16 precision modes. Independent floating-point and integer data paths allow more efficient execution of workloads using a mix of computation and addressing calculations.
PCIe Gen 4:
The RTX A2000 series GPUs supports PCI Express Gen 4, which provides double the bandwidth of PCIe Gen 3, improving data-transfer speeds from CPU memory for data-intensive tasks like AI and data science.
Higher Speed GDDR6 Memory:
Available with 6GB or 12GB of GDDR6 memory, the RTX A2000 series GPUs provide an ideal memory footprint to address datasets and models in latency-sensitive professional applications and at volume.
Error Correcting Code (ECC) on Graphics Memory:
Meet strict data integrity requirements for mission critical applications with uncompromised computing accuracy and reliability for workstations.
5th Generation NVDEC Engine:
NVDEC is well suited for transcoding and video playback applications for real-time decoding. The following video codecs are supported for hardware-accelerated decoding: MPEG-2, VC-1, H.264 (AVCHD), H.265 (HEVC), VP8, VP9, and AV1.
7th Generation NVENC Engine:
NVENC can take on the most demanding 4K or 8K video encoding tasks to free up the graphics engine and the CPU for other operations. The RTX A2000 series GPUs provide better encoding quality than software-based x264 encoders.
Graphics Preemption:
Pixel-level preemption provides more granular control to better support time-sensitive tasks such as VR motion tracking.
Compute Preemption:
Preemption at the instruction-level provides finer grain control over compute tasks to prevent long-running applications from either monopolizing system resources or timing out.
NVIDIA RTX IO:
Accelerating GPU-based lossless decompression performance by up to 100x and 20x lower CPU utilization compared to traditional storage APIs using Microsoft's new DirectStorage for Windows API. RTX IO moves data from the storage to the GPU in a more efficient, compressed form, and improving I/O performance.
Specifications:
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GPU Architecture
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NVIDIA Ampere Architecture
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CUDA Parallel Processing cores
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3,328
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NVIDIA Tensor Cores
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104
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NVIDIA RT Cores
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26
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Single-Precision Performance1
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8 TFLOPS
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RT Core Performance
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15.6 TFLOPS
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Tensor Performance
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63.9 TFLOPS2
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GPU memory
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6 GB GDDR6 with ECC | 12 GB GDDR with ECC
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Memory Interface
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192-bit
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Memory Bandwidth
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288 GB/s
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Max Power Consumption
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70 W
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Graphics Bus
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PCI Express 4.0 x 16
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Display Connectors
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mDP 1.4 (4)3
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Form Factor
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2.713”H x 6.6”L Dual Slot
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Product Weight
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294 g (Low Profile Bracket)
306 g (ATX Bracket)
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Thermal Solution
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Active
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NVENC | NVDEC
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1x | 1x (+AV1 decode)
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