Transcription of NVIDIA AMPERE GA102 GPU ARCHITECTURE
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NVIDIA AMPERE GA102 GPU ARCHITECTURE
NVIDIA AMPERE GA102 GPU ARCHITECTURE Second-Generation RTX NVIDIA AMPERE GA102 GPU ARCHITECTURE ii Table of Contents Introduction 5 GA102 Key Features 7 2x FP32 Processing 7 Second-Generation RT Core 7 Third-Generation Tensor Cores 8 GDDR6X and GDDR6 Memory 8 Third-Generation NVLink 8 PCIe Gen 4 9 AMPERE GPU ARCHITECTURE In-Depth 10 GPC, TPC, and SM High-Level ARCHITECTURE 10 ROP Optimizations 11 GA10x SM ARCHITECTURE 11 2x FP32 Throughput 12 Larger and Faster Unified Shared Memory and L1 Data Cache 13 Performance Per Watt 16 Second-Generation Ray Tracing Engine in GA10x GPUs 17 AMPERE ARCHITECTURE RTX Processors in Action 19 GA10x GPU Hardware Acceleration for Ray-Traced Motion Blur 20 Third-Generation Tensor Cores in GA10x GPUs 24 Comparison of Turing vs GA10x GPU Tensor Cores 24 NVIDIA AMPERE ARCHITECTURE Tensor Cores Support New DL Data Types 26 Fine-Grained Structured Sparsity 26 NVIDIA DLSS 8K 28 GDDR6X Memory 30 RTX IO 32 Introducing NVIDIA RTX IO 33 How NVIDIA RTX IO Works 34 Display and Video Engine 38 DisplayPort with DSC 38 HDMI with DSC 38 Fifth Generation NVDEC - Hardware-Accelerated Video Decoding 39 AV1 Hardware Decode 40 Seventh Generation NVENC.
GeForce RTX 3090, GeForce RTX 3080, NVIDIA RTX A6000, and the NVIDIA A40 data center GPU. The GeForce RTX 3070 GPU uses the new GA104 GPU. The GeForce RTX 3090 is the highest performing GPU in the GeForce RTX lineup and has been built for 8K HDR gaming. With 10496 CUDA Cores, 24GB of GDDR6X memory, and the
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