NVIDIA GeForce RTX 3060 Max-Q vs NVIDIA Quadro RTX 5000
Vergleichende Analyse von NVIDIA GeForce RTX 3060 Max-Q und NVIDIA Quadro RTX 5000 Videokarten für alle bekannten Merkmale in den folgenden Kategorien: Essenzielles, Technische Info, Videoausgänge und Anschlüsse, Kompatibilität, Abmessungen und Anforderungen, API-Unterstützung, Speicher, Technologien. Benchmark-Videokarten Leistungsanalyse: PassMark - G3D Mark, PassMark - G2D Mark, Geekbench - OpenCL, 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.
Unterschiede
Gründe, die für die Berücksichtigung der NVIDIA GeForce RTX 3060 Max-Q
- Grafikkarte ist neuer: Startdatum 2 Jahr(e) 4 Monat(e) später
- Ein neuerer Herstellungsprozess ermöglicht eine leistungsfähigere, aber dennoch kühlere Grafikkarte: 8 nm vs 12 nm
- 3.3x geringere typische Leistungsaufnahme: 60 Watt vs 200 Watt
- Etwa 50% bessere Leistung in CompuBench 1.5 Desktop - Face Detection (mPixels/s): 339.841 vs 226.447
- Etwa 6% bessere Leistung in CompuBench 1.5 Desktop - T-Rex (Frames/s): 27.109 vs 25.476
- Etwa 31% bessere Leistung in CompuBench 1.5 Desktop - Video Composition (Frames/s): 155.642 vs 118.544
- Etwa 6% bessere Leistung in CompuBench 1.5 Desktop - Bitcoin Mining (mHash/s): 1167.569 vs 1106.12
- Etwa 7% bessere Leistung in GFXBench 4.0 - Car Chase Offscreen (Frames): 21278 vs 19811
- 2.4x bessere Leistung in GFXBench 4.0 - Manhattan (Frames): 8913 vs 3719
- 2.4x bessere Leistung in GFXBench 4.0 - T-Rex (Frames): 8054 vs 3358
- Etwa 7% bessere Leistung in GFXBench 4.0 - Car Chase Offscreen (Fps): 21278 vs 19811
- 2.4x bessere Leistung in GFXBench 4.0 - Manhattan (Fps): 8913 vs 3719
- 2.4x bessere Leistung in GFXBench 4.0 - T-Rex (Fps): 8054 vs 3358
Spezifikationen | |
Startdatum | 12 Jan 2021 vs 13 August 2018 |
Fertigungsprozesstechnik | 8 nm vs 12 nm |
Thermische Designleistung (TDP) | 60 Watt vs 200 Watt |
Benchmarks | |
CompuBench 1.5 Desktop - Face Detection (mPixels/s) | 339.841 vs 226.447 |
CompuBench 1.5 Desktop - T-Rex (Frames/s) | 27.109 vs 25.476 |
CompuBench 1.5 Desktop - Video Composition (Frames/s) | 155.642 vs 118.544 |
CompuBench 1.5 Desktop - Bitcoin Mining (mHash/s) | 1167.569 vs 1106.12 |
GFXBench 4.0 - Car Chase Offscreen (Frames) | 21278 vs 19811 |
GFXBench 4.0 - Manhattan (Frames) | 8913 vs 3719 |
GFXBench 4.0 - T-Rex (Frames) | 8054 vs 3358 |
GFXBench 4.0 - Car Chase Offscreen (Fps) | 21278 vs 19811 |
GFXBench 4.0 - Manhattan (Fps) | 8913 vs 3719 |
GFXBench 4.0 - T-Rex (Fps) | 8054 vs 3358 |
Gründe, die für die Berücksichtigung der NVIDIA Quadro RTX 5000
- Etwa 98% höhere Kerntaktfrequenz:1620 MHz vs 817 MHz
- Etwa 42% höhere Boost-Taktfrequenz: 1815 MHz vs 1282 MHz
- 9.3x mehr Speichertaktfrequenz: 14000 MHz vs 1500 MHz, 12 Gbps effective
- Etwa 20% bessere Leistung in PassMark - G3D Mark: 16059 vs 13388
- Etwa 27% bessere Leistung in PassMark - G2D Mark: 749 vs 589
- Etwa 33% bessere Leistung in Geekbench - OpenCL: 105171 vs 79058
- Etwa 7% bessere Leistung in CompuBench 1.5 Desktop - Ocean Surface Simulation (Frames/s): 4161.764 vs 3898.264
- Etwa 30% bessere Leistung in 3DMark Fire Strike - Graphics Score: 10685 vs 8234
Spezifikationen | |
Kerntaktfrequenz | 1620 MHz vs 817 MHz |
Boost-Taktfrequenz | 1815 MHz vs 1282 MHz |
Speichertaktfrequenz | 14000 MHz vs 1500 MHz, 12 Gbps effective |
Benchmarks | |
PassMark - G3D Mark | 16059 vs 13388 |
PassMark - G2D Mark | 749 vs 589 |
Geekbench - OpenCL | 105171 vs 79058 |
CompuBench 1.5 Desktop - Ocean Surface Simulation (Frames/s) | 4161.764 vs 3898.264 |
3DMark Fire Strike - Graphics Score | 10685 vs 8234 |
Benchmarks vergleichen
GPU 1: NVIDIA GeForce RTX 3060 Max-Q
GPU 2: NVIDIA Quadro RTX 5000
PassMark - G3D Mark |
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PassMark - G2D Mark |
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Geekbench - OpenCL |
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CompuBench 1.5 Desktop - Face Detection (mPixels/s) |
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CompuBench 1.5 Desktop - Ocean Surface Simulation (Frames/s) |
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CompuBench 1.5 Desktop - T-Rex (Frames/s) |
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CompuBench 1.5 Desktop - Video Composition (Frames/s) |
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CompuBench 1.5 Desktop - Bitcoin Mining (mHash/s) |
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GFXBench 4.0 - Car Chase Offscreen (Frames) |
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GFXBench 4.0 - Manhattan (Frames) |
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GFXBench 4.0 - T-Rex (Frames) |
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GFXBench 4.0 - Car Chase Offscreen (Fps) |
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GFXBench 4.0 - Manhattan (Fps) |
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GFXBench 4.0 - T-Rex (Fps) |
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3DMark Fire Strike - Graphics Score |
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Name | NVIDIA GeForce RTX 3060 Max-Q | NVIDIA Quadro RTX 5000 |
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PassMark - G3D Mark | 13388 | 16059 |
PassMark - G2D Mark | 589 | 749 |
Geekbench - OpenCL | 79058 | 105171 |
CompuBench 1.5 Desktop - Face Detection (mPixels/s) | 339.841 | 226.447 |
CompuBench 1.5 Desktop - Ocean Surface Simulation (Frames/s) | 3898.264 | 4161.764 |
CompuBench 1.5 Desktop - T-Rex (Frames/s) | 27.109 | 25.476 |
CompuBench 1.5 Desktop - Video Composition (Frames/s) | 155.642 | 118.544 |
CompuBench 1.5 Desktop - Bitcoin Mining (mHash/s) | 1167.569 | 1106.12 |
GFXBench 4.0 - Car Chase Offscreen (Frames) | 21278 | 19811 |
GFXBench 4.0 - Manhattan (Frames) | 8913 | 3719 |
GFXBench 4.0 - T-Rex (Frames) | 8054 | 3358 |
GFXBench 4.0 - Car Chase Offscreen (Fps) | 21278 | 19811 |
GFXBench 4.0 - Manhattan (Fps) | 8913 | 3719 |
GFXBench 4.0 - T-Rex (Fps) | 8054 | 3358 |
3DMark Fire Strike - Graphics Score | 8234 | 10685 |
Vergleichen Sie Spezifikationen
NVIDIA GeForce RTX 3060 Max-Q | NVIDIA Quadro RTX 5000 | |
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Essenzielles |
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Architektur | Ampere | Turing |
Codename | GA106 | TU104 |
Startdatum | 12 Jan 2021 | 13 August 2018 |
Platz in der Leistungsbewertung | 130 | 154 |
Typ | Laptop | Workstation |
Einführungspreis (MSRP) | $2,299 | |
Technische Info |
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Boost-Taktfrequenz | 1282 MHz | 1815 MHz |
Kerntaktfrequenz | 817 MHz | 1620 MHz |
Fertigungsprozesstechnik | 8 nm | 12 nm |
Peak Double Precision (FP64) Performance | 153.8 GFLOPS (1:64) | |
Peak Half Precision (FP16) Performance | 9.846 TFLOPS (1:1) | |
Peak Single Precision (FP32) Performance | 9.846 TFLOPS | |
Leitungssysteme | 3840 | |
Pixel fill rate | 61.54 GPixel/s | |
Texturfüllrate | 153.8 GTexel/s | |
Thermische Designleistung (TDP) | 60 Watt | 200 Watt |
Anzahl der Transistoren | 12000 million | 13,600 million |
Videoausgänge und Anschlüsse |
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Display-Anschlüsse | Portable Device Dependent | 3x DisplayPort, 1x USB Type-C |
DisplayPort-Unterstützung | ||
G-SYNC-Unterstützung | ||
HDMI | ||
Kompatibilität, Abmessungen und Anforderungen |
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Schnittstelle | PCIe 4.0 x16 | PCIe 3.0 x16 |
Laptop-Größe | large | |
Zusätzliche Leistungssteckverbinder | None | 1x 6-pin + 1x 8-pin |
Länge | 267 mm | |
API-Unterstützung |
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DirectX | 12 Ultimate (12_2) | 12.0 (12_1) |
OpenCL | 3.0 | |
OpenGL | 4.6 | 4.6 |
Shader Model | 6.7 | |
Vulkan | ||
Speicher |
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Maximale RAM-Belastung | 6 GB | |
Speicherbandbreite | 288.0 GB/s | |
Breite des Speicherbusses | 192 bit | |
Speichertaktfrequenz | 1500 MHz, 12 Gbps effective | 14000 MHz |
Speichertyp | GDDR6 | |
Technologien |
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GPU Boost | ||
VR Ready |