Overview
NVIDIA RTX 5000 Ada Generation, unlocks generative AI and performance for today's professional workflows. 100 Gen3 RT Cores, 400 Gen4 Tensor Cores, 12800 CUDA cores, and 32 GB of GPU memory, let RTX 5000 excel in rendering, AI, graphics, and FP32 HPC.
  • NVIDIA Ada Lovelace architecture
  • CUDA cores
  • Third-generation RT cores
  • Fourth-generation tensor cores
  • Encoding and decoding engines
  • PCIe Gen 4
  • GPU memory
  • Virtualization-ready
  • Multi-display
  • Expanded reality
  • Form factor and energy efficiency
  • Motion BVH
  • NVIDIA DLSS 3.0
  • NVIDIA RTX broadcast engine
  • NVIDIA-certified systems for accelerated computing
NVIDIA Ada Lovelace architecture Benefit from fast interactive performance thanks to the latest NVIDIA GPU based on the Ada Lovelace architecture, ultra-fast on-board graphics memory technology and software drivers optimized for professional applications. The SER (Shader Execution Reordering) system allows workloads to be organized and reorganized on the fly, grouping threads with similar performance so that the streaming multiprocessor (SM) and RT Core can operate more efficiently. CUDA cores CUDA cores based on NVIDIA's Ada Lovelace architecture offer up to twice the single-precision floating-point throughput (FP32) of the previous generation, dramatically improving performance in graphics workflows such as 3D model development and computation for workloads such as desktop simulation for CAE. Third-generation RT cores Third-generation RT cores offer up to twice the throughput of the previous generation, and the ability to run ray tracing simultaneously with shading or denoising capabilities. This speeds up rendering for M&E content creation, AECO design evaluations and virtual manufacturing prototyping. Third-generation RT cores deliver up to twice the ray tracing performance of the previous generation, enabling unprecedented performance for photorealistic rendering. Enhanced RT cores combined with SER technology dynamically reorganize inefficient workloads, dramatically improving shader performance to accelerate end-to-end performance in ray-tracing image rendering. Fourth-generation Tensor Cores Fourth-generation Tensor Cores deliver AI training performance up to 5 times faster than the previous generation, with FP16 accuracy. Support for the FP8 data format for inference delivers more than 5 times the performance of the previous generation, and cuts data memory usage in half (compared with the FP16 data format). Encoding and decoding engines RTX 5000 includes two video encoding engines and two video decoding engines, including support for the AV1 video format and the performance required for multi-stream video applications for security and video service. PCIe Gen 4 RTX 5000 supports PCIe Gen4, which doubles the bandwidth of PCIe Gen3 from 15.75GB/s to 31.5GB/s for x16 connections, improving data transfer speeds from CPU memory for data-intensive tasks such as AI, data science, and the creation of large 3D models and scenes. Faster PCIe performance also accelerates GPU DMA transfers, offering faster video data transfers from GPUDirect for video-compatible peripherals and faster I/O with GPUDirect Storage. GPU memory The RTX 5000 features large GDDR6 memory, providing the memory needed for rendering, data science, engineering simulation and other memory-hungry GPU applications. With greater memory bandwidth than the previous generation, the RTX 5000 can move data between the GPU and GPU memory faster, resulting in better graphics, computing and rendering performance. Ready for virtualization Virtualization support enables a personal workstation to be transformed into multiple instances of high-performance virtual workstations. Remote users can share resources to run high-end design, AI and compute workloads. Multi-display Four DisplayPort 1.4a connectors, support for multiple 8K monitors, NVIDIA Quadro Sync, Mosaic, Warp and Blend enable massive immersive environments for CAVEs, video walls and location-based entertainment deployments. Expanded reality Support for the latest high-resolution HMD devices, high-performance graphics and GPU memory create incredible AR and VR experiences for training, product validation, building tours and engaging entertainment. Form factor and energy efficiency With a dual-slot, energy-efficient design, the RTX 5000 fits a wide range of workstation chassis, offering professionals a generous selection of compatible workstations from OEM suppliers worldwide. Motion BVH Hardware acceleration of motion blur rendering - a common cinematic effect that is difficult to render - means that artists no longer need to resort to traditional methods of using motion vectors to achieve motion blur. Motion vectors offer the artist the possibility of adjusting motion blur in post-production, but require visual corrections for reflections and translucency. NVIDIA DLSS 3.0 The Ada Lovelace GPU architecture includes a new optical flow gas pedal and an AI-based DLSS Super Resolution system with a DL denoiser that boosts DLSS 3.0 refresh rates by a factor of 4 over the previous version, while maintaining or exceeding native image quality. NVIDIA RTX broadcast engine The NVIDIA RTX broadcast engine turns desktops into broadcast studios, transforming standard webcams and microphones into high-end intelligent devices thanks to the power of AI. Enhance the video and audio quality of livestreams with AI capabilities such as virtual backgrounds, automatic webcam framing and microphone noise suppression. Thanks to dedicated AI processors called Tensor Cores on NVIDIA RTX GPUs, AI networks can work in real time with applications. NVIDIA-certified systems for accelerated computing NVIDIA RTX 5000 brings revolutionary performance to professionals in design, content creation, engineering, research and data science. The RTX 5000 GPUs in NVIDIA-certified workstations feature third-generation RTX technology and enable fast photorealistic and ray-traced rendering, AI-accelerated graphics, computation and workflows. Certified workstations have been validated for optimal GPU utilization. Well-balanced designs that take into account aspects such as thermal management and PCIe configuration, ensure that system resources are used to their full potential.