NVIDIA Quadro P5200 Max-Q vs NVIDIA GeForce GTX TITAN Z
Comparative analysis of NVIDIA Quadro P5200 Max-Q and NVIDIA GeForce GTX TITAN Z videocards for all known characteristics in the following categories: Essentials, Technical info, Video outputs and ports, API support, Memory, Compatibility, dimensions and requirements, Technologies. Benchmark videocards performance analysis: Geekbench - OpenCL, PassMark - G3D Mark, PassMark - G2D Mark, CompuBench 1.5 Desktop - Face Detection (mPixels/s), CompuBench 1.5 Desktop - Ocean Surface Simulation (Frames/s), CompuBench 1.5 Desktop - T-Rex (Frames/s), CompuBench 1.5 Desktop - Video Composition (Frames/s), CompuBench 1.5 Desktop - Bitcoin Mining (mHash/s), GFXBench 4.0 - Car Chase Offscreen (Frames), GFXBench 4.0 - Manhattan (Frames), GFXBench 4.0 - T-Rex (Frames), GFXBench 4.0 - Car Chase Offscreen (Fps), GFXBench 4.0 - Manhattan (Fps), GFXBench 4.0 - T-Rex (Fps), 3DMark Fire Strike - Graphics Score.
Differences
Reasons to consider the NVIDIA Quadro P5200 Max-Q
- Videocard is newer: launch date 3 year(s) 8 month(s) later
- Around 87% higher core clock speed: 1316 MHz vs 705 MHz
- Around 79% higher boost clock speed: 1569 MHz vs 876 MHz
- 742.6x more texture fill rate: 251.0 GTexel/s vs 338 billion / sec
- A newer manufacturing process allows for a more powerful, yet cooler running videocard: 16 nm vs 28 nm
- 3.8x lower typical power consumption: 100 Watt vs 375 Watt
- Around 33% higher maximum memory size: 16 GB vs 12 GB
- 257.7x more memory clock speed: 1804 MHz (7216 MHz effective) vs 7.0 GB/s
- 2.4x better performance in Geekbench - OpenCL: 53854 vs 22732
Specifications (specs) | |
Launch date | 21 February 2018 vs 28 May 2014 |
Core clock speed | 1316 MHz vs 705 MHz |
Boost clock speed | 1569 MHz vs 876 MHz |
Texture fill rate | 251.0 GTexel/s vs 338 billion / sec |
Manufacturing process technology | 16 nm vs 28 nm |
Thermal Design Power (TDP) | 100 Watt vs 375 Watt |
Maximum memory size | 16 GB vs 12 GB |
Memory clock speed | 1804 MHz (7216 MHz effective) vs 7.0 GB/s |
Benchmarks | |
Geekbench - OpenCL | 53854 vs 22732 |
Reasons to consider the NVIDIA GeForce GTX TITAN Z
- 2.3x more pipelines: 2x 2880 vs 2560
Pipelines | 2x 2880 vs 2560 |
Compare benchmarks
GPU 1: NVIDIA Quadro P5200 Max-Q
GPU 2: NVIDIA GeForce GTX TITAN Z
Geekbench - OpenCL |
|
|
Name | NVIDIA Quadro P5200 Max-Q | NVIDIA GeForce GTX TITAN Z |
---|---|---|
Geekbench - OpenCL | 53854 | 22732 |
PassMark - G3D Mark | 8942 | |
PassMark - G2D Mark | 650 | |
CompuBench 1.5 Desktop - Face Detection (mPixels/s) | 66.419 | |
CompuBench 1.5 Desktop - Ocean Surface Simulation (Frames/s) | 1261.593 | |
CompuBench 1.5 Desktop - T-Rex (Frames/s) | 7.89 | |
CompuBench 1.5 Desktop - Video Composition (Frames/s) | 17.882 | |
CompuBench 1.5 Desktop - Bitcoin Mining (mHash/s) | 309.857 | |
GFXBench 4.0 - Car Chase Offscreen (Frames) | 8124 | |
GFXBench 4.0 - Manhattan (Frames) | 2413 | |
GFXBench 4.0 - T-Rex (Frames) | 2226 | |
GFXBench 4.0 - Car Chase Offscreen (Fps) | 8124 | |
GFXBench 4.0 - Manhattan (Fps) | 2413 | |
GFXBench 4.0 - T-Rex (Fps) | 2226 | |
3DMark Fire Strike - Graphics Score | 17055 |
Compare specifications (specs)
NVIDIA Quadro P5200 Max-Q | NVIDIA GeForce GTX TITAN Z | |
---|---|---|
Essentials |
||
Architecture | Pascal | Kepler |
Code name | GP104 | GK110B |
Launch date | 21 February 2018 | 28 May 2014 |
Place in performance rating | 399 | 401 |
Type | Laptop | Desktop |
Launch price (MSRP) | $2,999 | |
Price now | $1,580 | |
Value for money (0-100) | 6.46 | |
Technical info |
||
Boost clock speed | 1569 MHz | 876 MHz |
Core clock speed | 1316 MHz | 705 MHz |
Manufacturing process technology | 16 nm | 28 nm |
Peak Double Precision (FP64) Performance | 251.0 GFLOPS | |
Peak Half Precision (FP16) Performance | 125.5 GFLOPS | |
Peak Single Precision (FP32) Performance | 8.033 TFLOPS | |
Pipelines | 2560 | 2x 2880 |
Pixel fill rate | 100.4 GPixel/s | |
Texture fill rate | 251.0 GTexel/s | 338 billion / sec |
Thermal Design Power (TDP) | 100 Watt | 375 Watt |
Transistor count | 7200 million | 7,080 million |
CUDA cores | 5760 | |
Floating-point performance | 2x 5,046 gflops | |
Video outputs and ports |
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Display Connectors | No outputs | 2x DVI, 1x HDMI, 1x DisplayPort, One Dual Link DVI-I, One Dual Link DVI-D, One HDMI... |
Audio input for HDMI | Internal | |
G-SYNC support | ||
HDCP | ||
HDMI | ||
Maximum VGA resolution | 2048x1536 | |
Multi monitor support | ||
API support |
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DirectX | 12 | 12.0 (11_1) |
OpenCL | 1.2 | |
OpenGL | 4.6 | 4.4 |
Shader Model | 6.4 | |
Vulkan | ||
Memory |
||
Maximum RAM amount | 16 GB | 12 GB |
Memory bandwidth | 230.9 GB/s | 672 GB / s |
Memory bus width | 256 bit | 768-bit (384-bit per GPU) |
Memory clock speed | 1804 MHz (7216 MHz effective) | 7.0 GB/s |
Memory type | GDDR5 | GDDR5 |
Compatibility, dimensions and requirements |
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Bus support | PCI Express 3.0 | |
Height | 4.376" (11.1 cm) | |
Interface | PCIe 3.0 x16 | |
Length | 10.5" (26.7 cm) | |
Supplementary power connectors | Two 8-pin | |
Technologies |
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3D Gaming | ||
3D Vision | ||
3D Vision Live | ||
Adaptive VSync | ||
Blu Ray 3D | ||
CUDA | ||
FXAA | ||
GPU Boost | ||
TXAA |