NVIDIA T1000 – Full Performance in a Small Form Factor Solution

NVIDIA GPUs power the world’s most advanced desktop workstations, providing the visual computing power required by millions of professionals as part of their daily workflow. All phases of the professional workflow, from creating, editing, and viewing 2D and 3D models and video, to working with multiple applications across several displays, benefit from the power that only a discreet GPU solution can provide. NVIDIA entry level professional GPUs provide advanced features and performance far beyond what is available with integrated GPU solutions - all in a low-profile package, enabling deployment in a wide range of small form factor workstations. Step up to the power of an NVIDIA discreet professional GPU.

The NVIDIA Turing architecture provides significant performance improvements with NVIDIA T1000, resulting in more than 50% graphics performance, compared to the previous generation P1000. Ultra-fast GDDR6 graphics memory technology provides twice the memory bandwidth of the previous generation.

• 4 miniDisplayPort connectors
• PCIe 3.0 x16 low profile
• Active fansink thermal solution
• 4GB GDDR6 memory
• 128-bit
• Up to 160 GB/s memory bandwidth

Turing GPU Architecture

Based on state-of-the-art 12nm FFN (FinFET NVIDIA) high-performance manufacturing process customized for NVIDIA to incorporate 896 CUDA cores, the NVIDIA T1000 GPU is the most powerful low-profile single slot professional solution for CAD, DCC, financial service industry (FSI) and visualization professionals in general looking to reach excellence performance in a compact and efficient form factor. The Turing GPU architecture enables the biggest leap in computer real-time graphics rendering since NVIDIA’s invention of programmable shaders in 2001.

Advanced Shading Technologies

The Turing GPU architecture features the following new advanced shader technologies. Mesh Shading: Compute-based geometry pipeline to speed geometry processing and culling on geometrically complex models and scenes. Mesh shading provides up to 2x performance improvement on geometry-bound workloads.

Advanced Streaming Multiprocessor (SM) Architecture

Combined shared memory and L1 cache improve performance significantly, while simplifying programing and reducing the tuning required to attain best application performance. Each SM contains 96 KB of L1 shared memory, which can be configured for various capabilities depending on compute or graphics workload. For compute cases, up to 64KB can be allocated to the L1 cache or shared memory, while graphics workload can allocate up to 48 KB for shared memory; 32 KB for L1 and 16KB for texture units. Combining the L1 data cache with the shared memory reduces latency and provide higher bandwidth.

High Performance GDDR6 Memory

Built with Turing's vastly optimized 4GB GDDR6 memory subsystem for the industry's fastest graphics the NVIDIA T1000 features 4 GB of frame buffer capacity and 160 GB/s of peak bandwidth for double the throughput from previous generation. NVIDIA T1000 is the ideal platform for 3D professionals working with larger models and datasets and multi display environments.

Single Instruction, Multiple Thread (SIMT)

New independent thread scheduling capability enables finer-grain synchronization and cooperation between parallel threads by sharing resources among small jobs.

Mixed-Precision Computing

With independent parallel integer and floating-point data paths, the Turing SM is more efficient on workloads with a mix of computation and addressing calculations.

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 GPU BOOST 4.0

Automatically maximize application performance without exceeding the power and thermal envelope of the card. Allows applications to stay within the boost clock state longer under higher temperature threshold before dropping to a secondary temperature setting base clock.

H.264 and HEVC Encode/Decode Engines

Deliver faster than real-time performance for transcoding, video editing, and other encoding applications with two dedicated H.264 and HEVC encode engines and a dedicated decode engine that are independent of 3D/compute pipeline.

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