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List of Nvidia graphics processing units

January 01, 1970

This list contains general information about graphics processing units (GPUs) and video cards from Nvidia, based on official specifications. In addition some Nvidia motherboards come with integrated onboard GPUs. Limited/Special/Collectors' Editions or AIB versions are not included.

Field explanations edit

The fields in the table listed below describe the following:

  • Model – The marketing name for the processor, assigned by The Nvidia.
  • Launch – Date of release for the processor.
  • Code name – The internal engineering codename for the processor (typically designated by an NVXY name and later GXY where X is the series number and Y is the schedule of the project for that generation).
  • Fab – Fabrication process. Average feature size of components of the processor.
  • Bus interface – Bus by which the graphics processor is attached to the system (typically an expansion slot, such as PCI, AGP, or PCI-Express).
  • Memory – The amount of graphics memory available to the processor.
  • SM Count – Number of streaming multiprocessors.[1]
  • Core clock – The factory core clock frequency; while some manufacturers adjust clocks lower and higher, this number will always be the reference clocks used by Nvidia.
  • Memory clock – The factory effective memory clock frequency (while some manufacturers adjust clocks lower and higher, this number will always be the reference clocks used by Nvidia). All DDR/GDDR memories operate at half this frequency, except for GDDR5, which operates at one quarter of this frequency.
  • Core config – The layout of the graphics pipeline, in terms of functional units. Over time the number, type, and variety of functional units in the GPU core has changed significantly; before each section in the list there is an explanation as to what functional units are present in each generation of processors. In later models, shaders are integrated into a unified shader architecture, where any one shader can perform any of the functions listed.
  • Fillrate – Maximum theoretical fill rate in textured pixels per second. This number is generally used as a maximum throughput number for the GPU and generally, a higher fill rate corresponds to a more powerful (and faster) GPU.
  • Memory subsection
    • Bandwidth – Maximum theoretical bandwidth for the processor at factory clock with factory bus width. GHz = 109 Hz.
    • Bus type – Type of memory bus or buses used.
    • Bus width – Maximum bit width of the memory bus or buses used. This will always be a factory bus width.
  • API support section
    • Direct3D – Maximum version of Direct3D fully supported.
    • OpenGL – Maximum version of OpenGL fully supported.
    • OpenCL – Maximum version of OpenCL fully supported.
    • Vulkan – Maximum version of Vulkan fully supported.
  • Features – Added features that are not standard as a part of the two graphics libraries.

Desktop GPUs edit

Pre-GeForce edit

Further information: Fahrenheit (microarchitecture)
Model Launch Code name Fab (nm)[2] Transistors (million) Die size (mm2) Bus interface Core clock (MHz) Memory clock (MHz) Core config[a] Fillrate Memory MFLOPS FP32 [citation needed] Latest API support
MOperations/s MPixels/s MTexels/s MVertices/s Size (MB) Bandwidth (GB/s) Bus type Bus width (bit) Direct3D OpenGL
STG-2000 May 22, 1995 NV1 SGS
500 nm 		1[3] 90 PCI 12
75 		50
60 		1:1:1 12 12 12 0 1
2
4 		0.4
0.48 		FPM
EDO
VRAM 		64 24.0
150.0 		1.0 n/a
Riva 128 August 25, 1997 NV3 SGS 350 nm 4[4] 90 AGP 1x,[5] PCI 100 100 100 100 100 4 1.6 SDR 128 200.0 5.0 1.0
Riva 128ZX February 23, 1998 SGS/TSMC 350 nm AGP 2x, PCI 8
Riva TNT June 15, 1998 NV4 TSMC 350 nm 7[6] 90 90 110 2:2:2 180 180 180 8
16 		1.76 360.0 6.0 1.2
Vanta March 22, 1999 NV6 TSMC 250 nm AGP 4x, PCI 100 125 200 200 200 8
16 		1.0 64 400.0
Vanta LT March 2000 AGP 2x 80 100 160 160 160 8
16 		0.8 320.0
Riva TNT2 M64 October 1999 AGP 4x, PCI 125 150 250 250 250 8
16
32 		1.2 500.0
Riva TNT2 March 15, 1999 NV5 15[7] 90 16
32 		2.4 128
Riva TNT2 Pro October 12, 1999 TSMC 220 nm 143 166 286 286 286 16
32 		2.656 572.0
Riva TNT2 Ultra March 15, 1999 TSMC 250 nm 150 183 300 300 300 16
32 		2.928 600.0
Model Launch Code name Fab (nm)[2] Transistors (million) Die size (mm2) Bus interface Core clock (MHz) Memory clock (MHz) Core config[a] MOperations/s MPixels/s MTexels/s MVertices/s Size (MB) Bandwidth (GB/s) Bus type Bus width (bit) MFLOPS FP32 Direct3D OpenGL
Fillrate Memory Latest API support
  1. ^ a b Pixel pipelines: texture mapping units: render output units

GeForce 256 series edit

Further information: GeForce 256 and Celsius (microarchitecture)
  • All models are made via TSMC 220 nm fabrication process
  • All models support Direct3D 7.0 and OpenGL 1.2
  • All models support hardware Transform and Lighting (T&L) and Cube Environment Mapping
Model Launch
Code name
Transistors (million)
Die size (mm2)
Core clock (MHz)
Memory clock (MHz)
Core config[a]
 Fillrate Memory MFLOPS
FP32
MOperations/s
MPixels/s
MTexels/s
MVertices/s
Size (MB)
Bandwidth (GB/s)
Bus type
Bus width (bit)
GeForce 256 SDR[8] Oct 11, 1999 NV10 17 139 AGP 4x, PCI 120 166 4:4:4 480 480 480 0 32
64 		2.656 SDR 128 960
GeForce 256 DDR[9] Dec 13, 1999 150 4.800 DDR
  1. ^ Pixel pipelines: texture mapping units: render output units

GeForce2 series edit

Further information: GeForce 2 series and Celsius (microarchitecture)
  • All models support Direct3D 7 and OpenGL 1.2
  • All models support TwinView Dual-Display Architecture, Second Generation Transform and Lighting (T&L), Nvidia Shading Rasterizer (NSR), High-Definition Video Processor (HDVP)
  • GeForce2 MX models support Digital Vibrance Control (DVC)
Model Launch Fab (nm)[2]
Transistors (million)
Die size (mm2)
Core clock (MHz)
Memory clock (MHz)
Core config[a]
 Fillrate Memory GFLOPS
FP32
MOperations/s
MPixels/s
MTexels/s
MVertices/s
Size (MB)
Bandwidth (GB/s)
Bus type
Bus width (bit)
GeForce2 MX IGP + nForce 220/420 June 4, 2001 NV1A (IGP) / NV11 (MX) TSMC
180 nm 		20[10] 64 FSB 175 133 2:4:2 350 350 700 0 Up to 32 system RAM 2.128
4.256 		DDR 64
128 		0.700
GeForce2 MX200 March 3, 2001 AGP 4x, PCI 166 32
64 		1.328 SDR 64
GeForce2 MX June 28, 2000 2.656 128
GeForce2 MX400 March 3, 2001 200 166,200 (SDR)
166 (DDR) 		400 400 800 1.328 3.200 2.656 SDR
DDR 		64/128 (SDR)
64 (DDR) 		0.800
GeForce2 GTS April 26, 2000 NV15 25[11] 88 AGP 4x 166 4:8:4 800 800 1,600 5.312 DDR 128 1.600
GeForce2 Pro December 5, 2000 200 6.4
GeForce2 Ti October 1, 2001 TSMC
150 nm 		250 1,000 1,000 2,000 2.000
GeForce2 Ultra August 14, 2000 TSMC
180 nm 		230 64 7.36
  1. ^ Pixel pipelines: texture mapping units: render output units

GeForce3 series edit

Further information: GeForce 3 series and Kelvin (microarchitecture)
  • All models are made via TSMC 150 nm fabrication process
  • All models support Direct3D 8.0 and OpenGL 1.3
  • All models support 3D Textures, Lightspeed Memory Architecture (LMA), nFiniteFX Engine, Shadow Buffers
Model Launch
Transistors (million)
Die size (mm2)
Core clock (MHz)
Memory clock (MHz)
Core config[a]
 Fillrate Memory GFLOPS
FP32
MOperations/s
MPixels/s
MTexels/s
MVertices/s
Size (MB)
Bandwidth (GB/s)
Bus type
Bus width (bit)
GeForce3 Ti200 October 1, 2001 NV20 57 128 AGP 4x, PCI 175 200 4:1:8:4 700 700 1400 43.75 64
128 		6.4 DDR 128 8.750
GeForce3 February 27, 2001 200 230 800 800 1600 50 64 7.36 10.00
GeForce3 Ti500 October 1, 2001 240 250 960 960 1920 60 64
128 		8.0 12.00
  1. ^ Pixel shaders: vertex shaders: texture mapping units: render output units

GeForce4 series edit

Further information: GeForce 4 series and Kelvin (microarchitecture)
  • All models are manufactured via TSMC 150 nm manufacturing process
  • All models support Accuview Antialiasing (AA), Lightspeed Memory Architecture II (LMA II), nView
Model Launch
Transistors (million)
Die size (mm2)
Core clock (MHz)
Memory clock (MHz)
Core config[a]
 Fillrate Memory Supported API version GFLOPS
FP32
MOperations/s
MPixels/s
MTexels/s
MVertices/s
Size (MB)
Bandwidth (GB/s)
Bus type
Bus width (bit)
GeForce4 MX IGP + nForce2 October 1, 2002 NV1F ? ? FSB 250 133
200 		2:0:4:2 500 500 1,000 125 Up to 128 system RAM 2.128
6.4 		DDR 64
128 		7.0 1.2 1.000
GeForce4 MX420 February 6, 2002 NV17 29[12] 65 AGP 4x
PCI 		166 64 2.656 SDR
DDR 		128 (SDR)
64 (DDR)
GeForce4 MX440 SE 2002 133
166[13] 		500[13]

1000

64
128 		2.128 5.312[13] DDR 64 128[13]
GeForce MX4000 December 14, 2003 NV18B 29 65 AGP 8x
PCI 		166 1000 2.656 64
GeForce PCX4300 February 19, 2004 PCIe x16 128
GeForce4 MX440 February 6, 2002 NV17 29 65 AGP 4x
PCI 		275 200 550 550 1,100 137.5 64
128 		6.4 128 1.100
GeForce4 MX440 8x September 25, 2002 NV18 29[14] 65 AGP 8x
PCI 		166
250 		2.656[15]
8.0 		64
128
GeForce4 MX460 February 6, 2002 NV17 29 65 AGP 4x
PCI 		300 275 600 600 1,200 150 8.8 128 1.200
GeForce4 Ti4200 April 16, 2002 NV25 63[16] 142 AGP 4x 250 222 (128 MB)
250 (64 MB) 		4:2:8:4 1,000 1,000 2,000 125 7.104 (128 MB)
8.0 (64 MB) 		8.0a 1.3 15.00
GeForce4 Ti4200 8x September 25, 2002 NV28 63[17] 142 AGP 8x 250 8.0
GeForce4 Ti4400 February 6, 2002 NV25 63 142 AGP 4x 275 275 1,100 1,100 2,200 137.5 128 8.8 16.50
GeForce4 Ti4400 8x
(Ti4800SE[b]) 		January 20, 2003 NV28 63 101 AGP 8x
GeForce4 Ti4600 February 6, 2002 NV25 63 142 AGP 4x 300 325 1,200 1,200 2,400 150 10.4 18.00
GeForce4 Ti4600 8x
(Ti4800[c]) 		January 20, 2003 NV28 63 101 AGP 8x
  1. ^ Pixel shaders: vertex shaders: texture mapping units: render output units
  2. ^ GeForce4 Ti4400 8x: Card manufacturers utilizing this chip labeled the card as a Ti4800SE. The surface of the chip has "Ti-8x" printed on it.
  3. ^ GeForce4 Ti4600 8x: Card manufacturers utilizing this chip labeled the card as a Ti4600, and in some cases as a Ti4800. The surface of the chip has "Ti-8x" printed on it, as well as "4800" printed at the bottom.
Model Features
nFiniteFX II Engine Video Processing Engine (VPE)
GeForce4 MX420 No Yes
GeForce4 MX440 SE No Yes
GeForce4 MX4000 No Yes
GeForce4 PCX4300 No Yes
GeForce4 MX440 No Yes
GeForce4 MX440 8X No Yes
GeForce4 MX460 No Yes
GeForce4 Ti4200 Yes No
GeForce4 Ti4200 8x Yes No
GeForce4 Ti4400 Yes No
GeForce4 Ti4400 8x Yes No
GeForce4 Ti4600 Yes No
GeForce4 Ti4600 8x Yes No

GeForce FX (5xxx) series edit

Further information: GeForce FX series and Rankine (microarchitecture)
  • All models support Direct3D 9.0a and OpenGL 1.5 (2.1 (software) with latest drivers)
  • The GeForce FX series runs vertex shaders in an array
Model Launch Code name Fab (nm)[2] Transistors (million) Die size (mm2) Bus interface Core clock (MHz) Memory clock (MHz) Core config[a] Fillrate Memory GFLOPS
FP32
MOperations/s MPixels/s MTexels/s MVertices/s Size (MB) Bandwidth (GB/s) Bus type Bus width (bit)
GeForce FX 5100 March 2003 NV34 TSMC 150 nm 45[18] 124 AGP 8x 200 166 4:2:4:4 800 800 800 100.0 64
128 		2.6 DDR 64 12.0
GeForce FX 5200 LE 250 1,000 1,000 1,000 125.0 64
128
256 		2.6
5.3 		64
128 		15.0
GeForce FX 5200 AGP 8x
PCI 		200 3.2
6.4 		64
128
GeForce FX 5200 Ultra March 6, 2003 AGP 8x 325 325 1,300 1,300 1,300 162.5 10.4 128 19.5
GeForce PCX 5300 March 17, 2004 PCIe x16 250 166 1,000 1,000 1,000 125.0 128
256 		2.6 64 15.0
GeForce FX 5500 March 2004 NV34B 45[19] 91 AGP 8x
AGP 4x
PCI 		270 166
200 		1,080 1,080 1,080 135.0 64
128
256 		5.3
6.4 		128 16.2
GeForce FX 5600 XT October 2003 NV31 TSMC 130 nm 80[20] 121 AGP 8x 235 200 940 940 940 117.5 64
128 		3.2
6.4 		64
128 		14.1
GeForce FX 5600 March 2003 AGP 8x
PCI 		325 275 1,300 1,300 1,300 162.5 64
128
256[21] 		8.8 128 19.5
GeForce FX 5600 Ultra March 6, 2003 AGP 8x 350 350 1,400 1,400 1,400 175.0 64
128 		11.2 21.0
GeForce FX 5600 Ultra Rev.2 400 400 1,600 1,600 1,600 200.0 12.8 24.0
GeForce FX 5700 VE September 2004 NV36 82[22] 133 250 200 4:3:4:4 1500 1500 1500 187.5 128
256 		3.2
6.4 		64
128 		17.5
GeForce FX 5700 LE March 2004 AGP 8x
PCI
GeForce FX 5700 2003 AGP 8x 425 250 1,700 1,700 1,700 318.7 8.0 128 29.7
GeForce PCX 5750 March 17, 2004 PCIe x16 128
GeForce FX 5700 Ultra October 23, 2003 AGP 8x 475 453 1,900 1,900 1,900 356.2 128
256 		14.4 GDDR2 33.2
GeForce FX 5700 Ultra GDDR3 March 15, 2004 475 15.2 GDDR3
GeForce FX 5800 January 27, 2003 NV30 125[23] 199 400 400 4:2:8:4 1,600 1,600 3,200 300.0 128 12.8 GDDR2 24.0
GeForce FX 5800 Ultra 500 500 2,000 2,000 4,000 375.0 16.0 30.0
GeForce FX 5900 ZT December 15, 2003 NV35 135[24] 207 325 350 4:3:8:4 1,300 1,300 2,600 243.7 22.4 DDR 256 22.7
GeForce FX 5900 XT December 15, 2003[25] 390 1,600 1,600 3,200 300.0 27.3
GeForce FX 5900 May 2003 400 425 27.2 28.0
GeForce FX 5900 Ultra May 12, 2003 450 1,800 1,800 3,600 337.5 128
256 		31.5
GeForce PCX 5900 March 17, 2004 PCIe x16 350 275 1,400 1,400 2,800 262.5 17.6 24.5
GeForce FX 5950 Ultra October 23, 2003 NV38 135[26] 207 AGP 8x 475 475 1,900 1,900 3,800 356.2 256 30.4 33.2
GeForce PCX 5950 February 17, 2004 PCIe x16 425 27.2 GDDR3
Model Launch Code name Fab (nm)[2] Transistors (million) Die size (mm2) Bus interface Core clock (MHz) Memory clock (MHz) Core config[a] Fillrate Memory GFLOPS
FP32
MOperations/s MPixels/s MTexels/s MVertices/s Size (MB) Bandwidth (GB/s) Bus type Bus width (bit)
  1. ^ a b Pixel shaders: vertex shaders: texture mapping units: render output units

GeForce 6 (6xxx) series edit

Further information: GeForce 6 series and Curie (microarchitecture)
  • All models support Direct3D 9.0c and OpenGL 2.1
  • All models support Transparency AA (starting with version 91.47 of the ForceWare drivers) and PureVideo
Model Launch Code name Fab (nm)[2] Transistors (million)
Die size (mm2) 		Bus interface Core clock (MHz) Memory clock (MHz) Core config[a] Fillrate Memory
MOperations/s MPixels/s MTexels/s MVertices/s Size (MB) Bandwidth (GB/s) Bus type Bus width (bit)
GeForce 6100 + nForce 410 October 20, 2005 MCP51 TSMC 90 nm HyperTransport 425 100–200 (DDR)
200–533 (DDR2) 		2:1:2:1 850 425 850 106.25 Up to 256 system RAM 1.6–6.4 (DDR)
3.2–17.056 (DDR2) 		DDR
DDR2 		64
128
GeForce 6150 SE + nForce 430 June 2006 MCP61 200
400[citation needed] 		3.2
16.0[citation needed] 		DDR2
GeForce 6150 LE + nForce 430 MCP61 100–200 (DDR)
200–533 (DDR2) 		1.6–6.4 (DDR)
3.2–17.056 (DDR2) 		DDR
DDR2
GeForce 6150 + nForce 430 October 20, 2005 MCP51 475 950 475 950 118.75 1.6–6.4 (DDR)
3.2–17.056 (DDR2)
GeForce 6200 LE April 4, 2005 NV44 TSMC 110 nm 75
110[27] 		AGP 8x
PCIe x16 		350 266 700 700 700 87.5 128
256 		4.256 DDR 64
GeForce 6200A April 4, 2005 NV44A 75
110[28] 		AGP 8x 350[29] 250 (DDR)
250-333 (DDR2)[29] 		4:3:4:2 1,400[29] 700[29] 1400[29] 175
225 (DDR2)[30] 		128
256[29]
512[29] 		4
4-5.34 (DDR2)[31] 		DDR
DDR2[30] 		64[30]
GeForce 6200 October 12, 2004 (PCIe)
January 17, 2005 (AGP) 		NV43 146
154[32] 		AGP 8x
PCI
PCIe x16 		300 275 4:3:4:4 1,200 1,200 1,200 225 128
256 		8.8 DDR 128
GeForce 6200 TurboCache December 15, 2004 NV44 75
110[27] 		PCIe x16 350 200
275
350 		4:3:4:2 1,400 700 1,400 262.5 128–256 System RAM incl.16/32–64/128 onboard 3.2
4.4
5.6 		DDR 64
GeForce 6500 October 1, 2005 400 333 1,600 800 1,600 300 128
256 		5.328
GeForce 6600 LE 2005 NV43 146
154[32] 		AGP 8x
PCIe x16 		300 200 4:3:4:4 1,200 1,200 1,200 225 6.4 128
GeForce 6600 August 12, 2004 275
400 		8:3:8:4 2,400 2,400 8.8
12.8 		DDR
DDR2
GeForce 6600 GT August 12, 2004 (PCIe)
November 14, 2004 (AGP) 		500 475 (AGP)
500 (PCIe) 		4,000 2,000 4,000 375 15.2 (AGP)[33]
16 (PCIe) 		GDDR3
GeForce 6800 LE July 22, 2004 (AGP)
January 16, 2005 (PCIe) 		NV40 (AGP)
NV41, NV42 (PCIe) 		IBM 130 nm 222
287 (NV40)[34]
222
225 (NV41)[35]
198
222 (NV42)[36] 		320 (AGP)
325 (PCIe) 		350 8:4:8:8 2,560 (AGP)
2,600 (PCIe) 		2,560 (AGP)
2,600 (PCIe) 		2,560 (AGP)
2,600 (PCIe) 		320 (AGP)
325 (PCIe) 		128 22.4 DDR 256
GeForce 6800 XT September 30, 2005 300 (64 Bit)
325 		266 (64 Bit)
350
500 (GDDR3) 		2,400
2,600 		2,400
2,600 		2,400
2,600 		300
325 		256 4.256
11.2
22.4
32 (GDDR3) 		DDR
DDR2
GDDR3 		64[37]
128[38]
256
GeForce 6800 April 14, 2004 (AGP)
November 8, 2004 (PCIe) 		325 350 12:5:12:12 3,900 3,900 3,900 406.25 128
256 		22.4 DDR 256
GeForce 6800 GTO April 14, 2004 NV45 222
287 (NV45)[39] 		PCIe x16 450 4,200 4,200 4,200 437.5 256 28.8 GDDR3
GeForce 6800 GS November 7, 2005 (PCIe)
December 8, 2005 (AGP) 		NV42 (PCIe)
NV40 (AGP) 		TSMC 110 nm 222
287 (NV40)[34]
198
222 (NV42)[36] 		AGP 8x
PCIe x16 		425 (PCIe)
350 (AGP) 		500 5,100 5,100 5,100 531.25 128
256 		32
GeForce 6800 GT May 4, 2004 (AGP)
June 28, 2004 (PCIe) 		NV40 (AGP)
NV45 (PCIe) 		IBM 130 nm 222
287 (NV40)[34]
222
287 (NV45)[39] 		AGP 8x
PCIe x16 		350 16:6:16:16 5,600 5,600 5,600 525
GeForce 6800 Ultra May 4, 2004 (AGP)
June 28, 2004 (PCIe)
March 14, 2005 (512 MB) 		400 525 (512 MB)
550 (256 MB) 		6,400 6,400 6,400 600 256
512 		33.6 (512 MB)
35.2 (256 MB)
GeForce 6800 Ultra Extreme Edition May 4, 2004 NV40 222
287 (NV40)[34] 		AGP 8x 450 600 7,200 7,200 7,200 675 256 35.2
Model Launch Code name Fab (nm)[2] Transistors (million)
Die size (mm2) 		Bus interface Core clock (MHz) Memory clock (MHz) Core config[a] Fillrate Memory
MOperations/s MPixels/s MTexels/s MVertices/s Size (MB) Bandwidth (GB/s) Bus type Bus width (bit)
  1. ^ a b Pixel shaders: vertex shaders: texture mapping units: render output units

Features edit

Model Features
OpenEXR HDR Scalable Link Interface (SLI) TurboCache PureVideo WMV9 Decoding
GeForce 6100 No No No Limited
GeForce 6150 SE No No Driver-Side Only Limited
GeForce 6150 No No No Yes
GeForce 6150 LE No No Driver-Side Only Yes
GeForce 6200 No No Yes (PCIe only) Yes
GeForce 6500 No Yes Yes Yes
GeForce 6600 LE Yes Yes (No SLI Connector) No Yes
GeForce 6600 Yes Yes (SLI Connector or PCIe Interface) No Yes
GeForce 6600 DDR2 Yes Yes (SLI Connector or PCIe Interface) No Yes
GeForce 6600 GT Yes Yes No Yes
GeForce 6800 LE Yes No No No
GeForce 6800 XT Yes Yes (PCIe only) No Yes (NV42 only)
GeForce 6800 Yes Yes (PCIe only) No Yes (NV41, NV42 only)
GeForce 6800 GTO Yes Yes No No
GeForce 6800 GS Yes Yes (PCIe only) No Yes (NV42 only)
GeForce 6800 GT Yes Yes (PCIe only) No No
GeForce 6800 Ultra Yes Yes (PCIe only) No No

GeForce 7 (7xxx) series edit

Further information: GeForce 7 series and Curie (microarchitecture)
  • All models support Direct3D 9.0c and OpenGL 2.1
  • All models support Transparency AA (starting with version 91.47 of the ForceWare drivers)
Model Launch Code name Fab (nm)[2] Transistors (million) Die size (mm2) Bus interface Core clock (MHz) Memory clock (MHz) Core config[a] Fillrate Memory
MOperations/s MPixels/s MTexels/s MVertices/s Size (MB) Bandwidth (GB/s) Bus type Bus width (bit)
GeForce 7025 + nForce 630a July 2007 MCP68S TSMC 110 nm HyperTransport 425 200 (DDR)
400 (DDR2)
933 (DDR3) 		2:1:2:2 850 850 850 106.25 Up to 256 system RAM 6.4
12.8
34 		DDR
DDR2
DDR3 		64
128
GeForce 7050PV + nForce 630a MCP67QV
GeForce 7050 + nForce 610i/630i MCP73 TSMC 90 nm HyperTransport/FSB 500 333 1,000 1,000 1,000 125 5.336 DDR2 64
GeForce 7100 + nForce 630i MCP76 FSB 600 400 1,200 1,200 1,200 150 6.4
GeForce 7150 + nForce 630i 630 1,260 1,260 1,260 157.5
GeForce 7100 GS August 8, 2006 NV44 TSMC 110 nm 75[27] 110 PCIe x16 350 266
333 		4:3:4:2 1,400 700 1,400 262.5 128
256 		2.4
4.8 		DDR2 32
64
GeForce 7200 GS January 18, 2006 G72 TSMC 90 nm 112[40] 81 450 400 2:2:4:2 1,800 900 1,800 337.5 3.2
6.4 		DDR2
GeForce 7300 SE March 22, 2006 350 333 4:3:4:2 128 2.656
5.328
GeForce 7300 LE
GeForce 7300 GS January 18, 2006 550 400 2,200 1,100 2,200 412.5 128
256 		6.4 64
GeForce 7300 GT May 15, 2006 G73 177[41] 125 AGP 8x
PCIe x16 		350 325 (DDR2)
700 (GDDR3) 		8:5:8:4 2,800 1,400 2,800 437.5 10.4
22.4 		DDR2
GDDR3 		128
GeForce 7500 LE 2006 G72 112[40] 81 PCIe x16 475
550 		405
324 		4:3:4:2 2,200 1,100 2,200 593.8 64
128
256 		6.480
5.2 		DDR2 64
GeForce 7600 GS March 22, 2006 (PCIe)
July 1, 2006 (AGP) 		G73 177[41] 125 AGP 8x
PCIe x16 		400 400 (DDR2)
700 (GDDR3) 		12:5:12:8 4,800 3,200 4,800 500 256 12.8
22.4 		DDR2
GDDR3 		128
GeForce 7600 GT March 9, 2006 (PCIe)
July 15, 2006 (AGP) 		560 6,720 4,480 6,720 700
GeForce 7600 GT 80 nm January 8, 2007 G73-B1 TSMC 80 nm
GeForce 7650 GS March 22, 2006 G73 PCIe x16 450 400 5,400 3,600 5,400 562.5 12.7 DDR2
GeForce 7800 GS February 2, 2006 G70 TSMC 110 nm 302[42] 333 AGP 8x 375 600 16:8:16:8 6,000 3,000 6,000 750 38.4 GDDR3 256
GeForce 7800 GT August 11, 2005 PCIe x16 400 500 20:7:20:16 8,000 6,400 8,000 700 32
GeForce 7800 GTX June 22, 2005 (256 MB)
November 14, 2005 (512 MB) 		430 (256 MB)
550 (512 MB) 		600 (256 MB)
850 (512 MB) 		24:8:24:16 10,320 (256 MB)
13,200 (512 MB) 		6,880 (256 MB)
8800 (512 MB) 		10,320 (256 MB)
13,200 (512 MB) 		860 (256 MB)
1,100 (512 MB) 		256
512 		38.4 (256 MB)
54.4 (512 MB)
GeForce 7900 GS May 2006 (PCIe)
April 2, 2007 (AGP) 		G71 TSMC 90 nm 278[43] 196 AGP 8x
PCIe x16 		450 660 20:7:20:16 9,000 7,200 9,000 787.5 256 42.24
GeForce 7900 GT March 9, 2006 PCIe x16 24:8:24:16 10,800 10,800 900
GeForce 7900 GTO October 1, 2006 650 15,600 10,400 15,600 1,300 512
GeForce 7900 GTX March 9, 2006 800 51.2
GeForce 7900 GX2 2x G71 500 600 2x 24:8:24:16 24,000 16,000 24,000 2,000 2x 512 2x 38.4
GeForce 7950 GT September 6, 2006 (PCIe)
April 2, 2007 (AGP) 		G71 AGP 8x
PCIe x16 		550 700 24:8:24:16 13,200 8,800 13,200 1,100 512 44.8
GeForce 7950 GX2 June 5, 2006 2x G71 PCIe x16 500 600 2x 24:8:24:16 24,000 16,000 24,000 2000 2x 512 2x 38.4
Model Launch Code name Fab (nm)[2] Transistors (million) Die size (mm2) Bus interface Core clock (MHz) Memory clock (MHz) Core config[a] MOperations/s MPixels/s MTexels/s MVertices/s Size (MB) Bandwidth (GB/s) Bus type Bus width (bit)
Fillrate Memory
  1. ^ a b Pixel shaders: vertex shaders: texture mapping units: render output units

Features edit

Model Features
Gamma-correct antialiasing 64-bit OpenEXR HDR Scalable Link Interface (SLI) TurboCache Dual Link DVI
GeForce 7100 GS No No Yes (PCIe only, No SLI bridge) Yes No
GeForce 7200 GS Yes Yes No Yes No
GeForce 7300 SE Yes Yes No Yes No
GeForce 7300 LE Yes Yes No Yes No
GeForce 7300 GS Yes Yes Yes (PCIe only) Yes No
GeForce 7300 GT Yes Yes Yes (PCIe only, No SLI bridge) No One port
GeForce 7600 GS Yes Yes Yes (PCIe only) No One port
GeForce 7600 GT Yes Yes Yes (PCIe only) No One port
GeForce 7600 GT (80 nm) Yes Yes Yes No One port
GeForce 7650 GS (80 nm) Yes Yes Yes (Depending on OEM Design) No One port
GeForce 7800 GS Yes Yes No No One port
GeForce 7800 GT Yes Yes Yes No One port
GeForce 7800 GTX Yes Yes Yes No One port
GeForce 7800 GTX 512 Yes Yes Yes No One port
GeForce 7900 GS Yes Yes Yes (PCIe only) No Two ports
GeForce 7900 GT Yes Yes Yes No Two ports
GeForce 7900 GTO Yes Yes Yes No Two ports
GeForce 7900 GTX Yes Yes Yes No Two ports
GeForce 7900 GX2 (GTX Duo) Yes Yes Yes No Two ports
GeForce 7950 GT Yes Yes Yes (PCIe only) No Two ports
GeForce 7950 GX2 Yes Yes Yes No Two ports

GeForce 8 (8xxx) series edit

Further information: GeForce 8 series and Tesla (microarchitecture)
  • All models support coverage sample anti-aliasing, angle-independent anisotropic filtering, and 128-bit OpenEXR HDR.
Model Launch Code name Fab (nm)[2] Transistors (million) Die size (mm2) Bus interface Core config[a] Clock rate Fillrate Memory Supported API version Processing power (GFLOPS)[b] TDP (Watts) Comments
Core (MHz) Shader (MHz) Memory (MHz) Pixel (GP/s) Texture (GT/s) Size (MB) Bandwidth (GB/s) Bus type Bus width (bit) Direct3D OpenGL Single precision
GeForce 8100 mGPU[44] 2008 MCP78 TSMC 80 nm Un­known Un­known PCIe 2.0 x16 8:8:4 500 1200 400
(system memory) 		2 4 Up to 512 from system memory 6.4
12.8 		DDR2 64
128 		10.0 3.3 28.8 Un­known The block of decoding of HD-video PureVideo HD is disconnected
GeForce 8200 mGPU[44] Un­known Un­known gt Un­known PureVideo 3 with VP3
GeForce 8300 mGPU[44] Un­known Un­known 1500 Up to 512 from system memory 36 Un­known
GeForce 8300 GS[45] July 2007 G86 210 127 PCIe 1.0 x16 450 900 400 1.8 3.6 128
512 		6.4 64 14.4 40 OEM only
GeForce 8400 GS June 15, 2007 PCIe 1.0 x16
PCI 		16:8:4 128
256
512 		28.8
GeForce 8400 GS rev.2 December 10, 2007 G98 TSMC 65 nm 86 PCIe 2.0 x16
PCIe x1
PCI 		8:8:4 567 1400 2.268 4.536 22.4 25
GeForce 8400 GS rev.3 July 12, 2010 GT218 TSMC 40 nm 260 57 PCIe 2.0 x16 8:4:4 520
589 		1230 400 (DDR2)
600 (DDR3) 		2.08
2.356 		2.08
2.356 		512
1024 		4.8
6.4
9.6 		DDR2
DDR3 		32
64 		10.1 19.7
GeForce 8500 GT April 17, 2007 G86 TSMC 80 nm 210 127 PCIe 1.0 x16
PCI 		16:8:4 450 900 400 1.8 3.6 256
512
1024 		12.8 DDR2 128 10.0 28.8 45
GeForce 8600 GS April 2007 G84 289 169 PCIe 1.0 x16 16:8:8 540 1180 4.32 4.32 256
512 		75.5 47 OEM only
GeForce 8600 GT April 17, 2007 PCIe 1.0 x16
PCI 		32:16:8 1188 400
700 		8.64 256
512
1024 		12.8
22.4 		DDR2
GDDR3 		76
GeForce 8600 GTS PCIe 1.0 x16 675 1450 1000 5.4 10.8 256
512 		32 GDDR3 92.8 71
GeForce 8800 GS January 2008 G92 TSMC 65 nm 754 324 PCIe 2.0 x16 96:48:12 550 1375 800 6.6 26.4 384
768 		38.4 192 264 105
GeForce 8800 GTS (G80) February 12, 2007 (320)
November 8, 2006 (640) 		G80 TSMC 90 nm 681 484 PCIe 1.0 x16 96:24:20 513 1188 10.3 12.3 320
640 		64 320 228 146
GeForce 8800 GTS 112 (G80) November 19, 2007 112:28:[c]20 500 1200 10 14 640 268.8 150 only XFX, EVGA and BFG models, very short-lived[48]
GeForce 8800 GT October 29, 2007 (512)
December 11, 2007 (256, 1024) 		G92 TSMC 65 nm 754 324 PCIe 2.0 x16 112:56:16 600 1500 700 (256)
900 (512, 1024) 		9.6 33.6 256
512
1024 		57.6 256 336 125
GeForce 8800 GTS (G92) December 11, 2007 128:64:16 650 1625 970 10.4 41.6 512 62.1 416 135
GeForce 8800 GTX November 8, 2006 G80 TSMC 90 nm 681 484 PCIe 1.0 x16 128:32:[c]24 575 1350 900 13.8 18.4 768 86.4 384 345.6 145
GeForce 8800 Ultra May 2, 2007 612 1500 1080 14.7 19.6 103.7 384 175
Model Launch Code name Fab (nm)[2] Transistors (million) Die size (mm2) Bus interface Core config[a] Core (MHz) Shader (MHz) Memory (MHz) Pixel (GP/s) Texture (GT/s) Size (MB) Bandwidth (GB/s) Bus type Bus width (bit) Direct3D OpenGL Single precision TDP (Watts) Comments
Clock rate Fillrate Memory Supported API version Processing power (GFLOPS)[b]
  1. ^ a b Unified shaders: texture mapping units: render output units
  2. ^ a b To calculate the processing power, see Performance.
  3. ^ a b Full G80 contains 32 texture address units and 64 texture filtering units unlike G92 which contains 64 texture address units and 64 texture filtering units[46][47]

Features edit

  • Compute Capability 1.1: has support for Atomic functions, which are used to write thread-safe programs.
  • Compute Capability 1.2: for details see CUDA
Model Features
Scalable
Link
Interface
(SLI) 		3-Way
SLI 		PureVideo HD
with VP1 		PureVideo 2 with VP2,
BSP Engine, and AES128 Engine 		PureVideo 3 with VP3,
BSP Engine, and AES128 Engine 		PureVideo 4 with VP4 Compute
ability
GeForce 8300 GS (G86) No No No Yes No No 1.1
GeForce 8400 GS Rev. 2 (G98) No No No No Yes No 1.1
GeForce 8400 GS Rev. 3 (GT218) No No No No No Yes 1.2
GeForce 8500 GT Yes No No Yes No No 1.1
GeForce 8600 GT Yes No No Yes No No 1.1
GeForce 8600 GTS Yes No No Yes No No 1.1
GeForce 8800 GS (G92) Yes No No Yes No No 1.1
GeForce 8800 GTS (G80) Yes No Yes No No No 1.0
GeForce 8800 GTS Rev. 2 (G80) Yes No Yes No No No 1.0
GeForce 8800 GT (G92) Yes No No Yes No No 1.1
GeForce 8800 GTS (G92) Yes No No Yes No No 1.1
GeForce 8800 GTX Yes Yes Yes No No No 1.0
GeForce 8800 Ultra Yes Yes Yes No No No 1.0

GeForce 9 (9xxx) series edit

Further information: GeForce 9 series and Tesla (microarchitecture)
  • All models support Coverage Sample Anti-Aliasing, Angle-Independent Anisotropic Filtering, 128-bit OpenEXR HDR
Model Launch Code name Fab (nm)[2] Transistors (million) Die size (mm2) Bus interface Core config[a] Clock rate Fillrate Memory Supported API version Processing power (GFLOPS)[b] TDP (Watts) Comments
Core (MHz) Shader (MHz) Memory (MHz) Pixel (GP/s) Texture (GT/s) Size (MB) Bandwidth (GB/s) Bus type Bus width (bit) Direct3D OpenGL Single precision
GeForce 9300 mGPU October 2008 MCP7A-S 65 nm 282 162 PCIe 2.0 x16 16:8:4 450 1200 400
666 		1.8 3.6 Up to 512 from system memory 6.4/12.8
10.664/21.328 		DDR2
DDR3 		64
128 		10.0 3.3 57.6 Un­known based on 8400 GS
GeForce 9400 mGPU MCP7A-U 580 1400 2.32 4.64 67.2 12
GeForce 9300 GE[49] June 2008 G98 TSMC 65 nm 210 86 8:8:4 540 1300 500 2.16 4.32 256 6.4[50] DDR2 64 20.8 25
GeForce 9300 GS[49] 567 1400 2.268 4.536 22.4
GeForce 9400 GT August 27, 2008 G96-200-c1
G96a
G96b 		TSMC 55 nm 314 144 PCIe 2.0 x16
PCI 		16:8:4 550 400
800 		2.2 4.4 256
512
1024 		12.8
25.6 		DDR2
GDDR3 		128 44.8 50
GeForce 9500 GS 24:12:4 500 16.0 DDR2 60 OEM
GeForce 9500 GT July 29, 2008 G96-300-C1 UMC 65 nm 32:16:8 500
800 		4.4 8.8 16.0
25.6 		DDR2
GDDR3 		89.6
GeForce 9600 GS G94a TSMC 65 nm 505 240 PCIe 2.0 x16 48:24:12 500 1250 500 6 12 768 24.0 DDR2 192 120 Un­known OEM
GeForce 9600 GSO May 2008 G92-150-A2 754 324 96:48:12 550 1375 800 6.6 26.4 384
768
1536 		38.4 GDDR3 264 84
GeForce 9600 GSO 512 October 2008 G94a
G94b 		TSMC 65 nm
TSMC 55 nm 		505 240
196?[citation needed] 		48:24:16 650 1625 900 10.4 15.6 512 57.6 256 156 90
GeForce 9600 GT Green Edition 2009 G94b TSMC 55 nm 196?[citation needed] 64:32:16 600
625 		1500
1625 		700/900
900[citation needed] 		9.6
10.0 		19.2
20.0 		512
1024 		44.8/57.6
57.6[citation needed] 		192
208 		59 Core Voltage = 1.00v
GeForce 9600 GT February 21, 2008 G94-300-A1 TSMC 65 nm 240 650 1625 900 10.4 20.8 57.6 208 95
GeForce 9800 GT Green Edition 2009 G92a2
G92b 		TSMC/UMC 65 nm
TSMC/UMC 55 nm 		754 324
260 		112:56:16 550 1375 700
800
900 		8.8 30.8 44.8
51.2
57.6 		308 75 Core Voltage = 1.00v
GeForce 9800 GT July 2008 G92a
G92b 		65 nm
UMC 55 nm 		600 1500 900 9.6 33.6 57.6 336 125
105
GeForce 9800 GTX April 1, 2008 G92-420-A2 TSMC 65 nm 324 128:64:16 675 1688 1100 10.8 43.2 512 70.4 432 140
GeForce 9800 GTX+ July 16, 2008 G92b TSMC 55 nm 260 738 1836 1100 11.808 47.232 512
1024 		470 141
GeForce 9800 GX2 March 18, 2008 2x G92 TSMC/UMC 65 nm 2x 754 2x 324 2x 128:64:16 600 1500 1000 2x 9.6 2x 38.4 2x 512 2x 64.0 2x 256 2x 384 197
Model Launch Code name Fab (nm)[2] Transistors (million) Die size (mm2) Bus interface Core config[a] Core (MHz) Shader (MHz) Memory (MHz) Pixel (GP/s) Texture (GT/s) Size (MB) Bandwidth (GB/s) Bus type Bus width (bit) Direct3D OpenGL Single precision TDP (Watts) Comments
Clock rate Fillrate Memory Supported API version Processing power (GFLOPS)[b]
  1. ^ a b Unified shaders: texture mapping units: render output units
  2. ^ a b To calculate the processing power see Tesla (microarchitecture)#Performance.

Features edit

  • Compute Capability: 1.1 has support for Atomic functions, which are used to write thread-safe programs.
Model Features
Scalable Link Interface (SLI) PureVideo 2 with VP2,
BSP Engine, and AES128 Engine 		PureVideo 3 with VP3,
BSP Engine, and AES128 Engine
GeForce 9300 GE (G98) Yes No Yes
GeForce 9300 GS (G98)
GeForce 9400 GT Yes No
GeForce 9500 GT
GeForce 9600 GSO
GeForce 9600 GT
GeForce 9800 GT
GeForce 9800 GTX Yes
3-way
GeForce 9800 GTX+
GeForce 9800 GX2 Yes

GeForce 100 series edit

Further information: GeForce 100 series and Tesla (microarchitecture)
Model Launch Code name Fab (nm) Transistors (million) Die size (mm2) Bus interface Core config[a] Clock rate Fillrate Memory configuration Supported API version Processing power (GFLOPS)[b] TDP (Watts) Comments
Core (MHz) Shader (MHz) Memory (MHz) Pixel (GP/s) Texture (GT/s) Size (MB) Bandwidth (GB/s) DRAM type Bus width (bit) Direct3D OpenGL Single precision
GeForce G 100 March 10, 2009 G98 TSMC 65 nm 210 86 PCIe 2.0 x16 8:8:4 567 1400 500 2.15 4.3 512 8.0 DDR2 64 10.0 3.3 22.4 35 OEM products
GeForce GT 120 G96b TSMC 55 nm 314 121 32:16:8 500 800 4.4 8.8 16.0 128 89.6 50
GeForce GT 130 G94b 505 196 48:24:12 1250 500 6 12 1536 24.0 192 120 75
GeForce GT 140 64:32:16 650 1625 1800 10.4 20.8 512 1024 57.6 GDDR3 256 208 105
GeForce GTS 150 G92b 754 260 128:64:16 738 1836 1000 11.808 47.232 1024 64.0 470 141
  1. ^ Unified shaders: texture mapping units: render output units
  2. ^ To calculate the processing power see Tesla (microarchitecture)#Performance.

GeForce 200 series edit

Further information: GeForce 200 series and Tesla (microarchitecture)
  • All models support Coverage Sample Anti-Aliasing, Angle-Independent Anisotropic Filtering, 240-bit OpenEXR HDR
Model Launch Code name Fab (nm) Transistors (million) Die size (mm2) Bus interface Core config[a] Clock rate Fillrate Memory configuration Supported API version Processing power (GFLOPS)[b] TDP (Watts) Comments Release Price (USD)
Core (MHz) Shader (MHz) Memory (MT/s) Pixel (GP/s) Texture (GT/s) Size (MB) Bandwidth (GB/s) DRAM type Bus width (bit) Direct3D OpenGL Single precision
GeForce 205 November 26, 2009 GT218 TSMC 40 nm 260 57 PCIe 2.0 x16 8:4:4 589 1402 1000 2.356 2.356 512 8 DDR2 64 10.1 3.3 22.4 30.5 OEM only
GeForce 210 October 12, 2009 GT218-325-B1 PCIe 2.0 x16
PCIe x1
PCI 		16:8:4 520
589 		1230
1402 		800
1000–1600 		2.356 4.712 512
1024 		4.0
8.0
12.8 		DDR2
DDR3 		32
64 		36.4
44.9 		30.5
GeForce GT 220 GT216-300-A2 TSMC 40 nm 486 100 PCIe 2.0 x16 48:16:8 615(OEM)
625 		1335(OEM)
1360 		1000
1580 		5 10 512
1024 		16.0
25.3 		DDR2
DDR3 		64
128 		128.2(OEM)
130.6 		58
GeForce GT 230 October 12, 2009[51] G94b TSMC/UMC 55 nm 505 196? 48:24:16 650 1625 1800 10.4 15.6 512
1024 		57.6 GDDR3 256 10 156 75 OEM only
April 27, 2009[52] G92b 754 260 96:48:12 500 1242 1000 6 24 1536 24 DDR2 192 238.5
GeForce GT 240 November 17, 2009 GT215-450-A2 TSMC 40 nm 727 139 96:32:8 550 1340 1800
2000
3400(GDDR5) 		4.4 17.6 512
1024 		28.8(OEM)
32
54.4(GDDR5) 		DDR3
GDDR3
GDDR5 		128 10.1 257.3 69
GeForce GTS 240 July 1, 2009[53] G92a
G92b 		TSMC 65 nm
TSMC/UMC 55 nm 		754 324
260 		112:56:16 675 1620 2200 10.8 37.8 1024 70.4 GDDR3 256 10.0 362.9 120 OEM only
GeForce GTS 250 2009 G92b TSMC/UMC 55 nm 260 128:64:16 702 1512 2000 11.2 44.9 512
1024 		64.0 387 130
March 3, 2009 G92-428-B1 TSMC 65 nm
TSMC/UMC 55 nm 		738 1836 2000
2200 		11.808 47.232 512
1024 		64.0
70.4 		470 150 Some cards are rebranded GeForce 9800 GTX+ $150
($130 512MB)
GeForce GTX 260 June 16, 2008 GT200-100-A2 65 nm 1400 576 192:64:28 576 1242 1998 16.128 36.864 896 111.9 448 477 182 Replaced by GTX 260 Core 216 $400 (dropped to $270 after 3 months[54])
September 16, 2008
November 27, 2008 (55 nm) 		GT200-103-A2 65 nm
55 nm 		576
470 		216:72:28 576 1242
1350 		1998 16.128 41.472 896 (1792) 111.9 536.5
583.2 		182
171 		$300
GeForce GTX 275 April 9, 2009 GT200-105-B3 TSMC/UMC 55 nm 470 240:80:28 633 1404 2268 17.724 50.6 896 (1792) 127.0 674 219 Effectively one-half of the GTX 295 $250
GeForce GTX 280 June 17, 2008 GT200-300-A2 65 nm 576 240:80:32 602 1296 2214 19.264 48.16 1024 141.7 512 622 236 Replaced by GTX 285 $650 (dropped to $430 after 3 months[54])
GeForce GTX 285 January 15, 2009 GT200-350-B3 TSMC/UMC 55 nm 470 648 1476 2484 20.736 51.84 1024 (2048) 159.0 512 708.48 204 EVGA GTX285 Classified supports 4-way SLI $400
GeForce GTX 295 January 8, 2009 2x GT200-400-B3 2x 1400 2x 470 2x 240:80:28 576 1242 1998 2x 16.128 2x 46.08 2x 896 2x 111.9 2x 448 1192.3 289 Dual PCB models were replaced with a single PCB model with 2 GPUs $500
Model Launch Code name Fab (nm) Transistors (million) Die size (mm2) Bus interface Core config[a] Core (MHz) Shader (MHz) Memory (MHz) Pixel (GP/s) Texture (GT/s) Size (MB) Bandwidth (GB/s) DRAM type Bus width (bit) Direct3D OpenGL Single precision TDP (Watts) Comments Release Price (USD)
Clock rate Fillrate Memory configuration Supported API version Processing power (GFLOPS)[b]
  1. ^ a b Unified shaders: texture mapping units: render output units
  2. ^ a b To calculate the processing power see Tesla (microarchitecture)#Performance.

Features edit

  • Compute Capability: 1.1 (G92 [GTS250] GPU)
  • Compute Capability: 1.2 (GT215, GT216, GT218 GPUs)
  • Compute Capability: 1.3 has double precision support for use in GPGPU applications. (GT200a/b GPUs only)
Model Features
Scalable Link Interface (SLI) PureVideo 2 with VP2
Engine: (BSP and 240 AES) 		PureVideo 4 with VP4 Engine
GeForce 210 No No Yes
GeForce GT 220
GeForce GT 240
GeForce GTS 250 Yes
3-Way (4-way for EVGA 285 Classified) 		Yes No
GeForce GTX 260
GeForce GTX 260 Core 216
GeForce GTX 260 Core 216 (55 nm)
GeForce GTX 275
GeForce GTX 280
GeForce GTX 285
GeForce GTX 295 Yes

GeForce 300 series edit

Further information: GeForce 300 series and Tesla (microarchitecture)
Model Launch Code name Fab (nm) Transistors (million) Die size (mm2) Bus interface Core config[a] Clock rate Fillrate Memory configuration Processing power (GFLOPS)[b] TDP (Watts) Comments
Core (MHz) Shader (MHz) Memory (MHz) Pixel (GP/s) Texture (GT/s) Size (MB) Bandwidth (GB/s) DRAM type Bus width (bit) Single precision
GeForce 310 November 27, 2009 GT218 TSMC 40 nm 260 57 PCIe 2.0 x16 16:8:4 589 1402 1000 2.356 4.712 512 8 DDR2 64 44.8 30.5 OEM Card, similar to Geforce 210
GeForce 315 February 2010 GT216 486 100 48:16:4 475 1100 1580 3.8 7.6 512 12.6 DDR3 105.6 33 OEM Card, similar to Geforce GT220
GeForce GT 320 GT215 727 144 72:24:8 540 1302 4.32 12.96 1024 25.3 GDDR3 128 187.5 43 OEM Card
GeForce GT 330[55] GT215-301-A3[56] 96:32:8 550 1350 4.40 17.60 512 32.00 128 257.3 75 Specifications vary depending on OEM, similar to GT230 v2.
G92[57] 500 1250 4.000 24.00 256 51.20 256 240.0
G92B[58] 96:32:16 8.000 1024 16.32 DDR2 128
GeForce GT 340 GT215 96:32:8 550 1340 3400 512
1024 		54.4 GDDR5[59] 128 257.3 69 OEM Card, similar to GT240
  1. ^ Unified shaders: texture mapping units: render output units
  2. ^ To calculate the processing power see Tesla (microarchitecture)#Performance.

GeForce 400 series edit

Further information: GeForce 400 series and Fermi (microarchitecture)
  • All cards have a PCIe 2.0 x16 Bus interface.
  • The base requirement for Vulkan 1.0 in terms of hardware features was OpenGL ES 3.1 which is a subset of OpenGL 4.3, which is supported on all Fermi and newer cards.
  • Memory bandwidths stated in the following table refer to Nvidia reference designs. Actual bandwidth can be higher or lower depending on the maker of the graphic board.
Model Launch Code name Fab (nm) Transistors (million) Die size (mm2) SM count Core config[a][b] Clock rate Fillrate Memory configuration Supported API version Processing power (GFLOPS)[c] TDP (Watts)[d] Release Price (USD)
Core (MHz) Shader (MHz) Memory (MHz) Pixel (GP/s) Texture (GT/s) Size (MB) Bandwidth (GB/s) DRAM type Bus width (bit) Vulkan Direct3D OpenGL OpenCL[e] Single precision Double precision
GeForce 405[f] September 16, 2011 GT216
GT218 		40 nm 486
260 		100
57 		1 48:16:8
16:8:4 		475
589 		1100
1402 		800
790 		3.8
2.36 		7.6
4.71 		512
1024 		12.6 DDR3 64 n/a[63] 10.1 3.3 1.1 105.6
44.86 		Un­known 30.5 OEM
GeForce GT 420 September 3, 2010 GF108 TSMC 40 nm 585 116 48:4:4 700 1400 1800 2.8 2.8 512 28.8 GDDR3 128 12 FL 11_1 4.6 134.4 Un­known 50
GeForce GT 430 October 11, 2010 GF108
GF108-300-A1 		2 96:16:4 1600
1800 		11.2 512 25.6
28.8 		1.2 268.8 Un­known 60
1800 512
1024
2048 		28.8 128 1.1 268.8 Unknown 49 $79
1300 10.4 64
GeForce GT 440 February 1, 2011 GF108 810 1620 1800
3200 		3.2 12.9 512
1024 		28.8
51.2 		GDDR3
GDDR5 		128 311.04 Un­known 65 $100
October 11, 2010 GF106 1170 238 3 144:24:24 594 1189 1600
1800 		4.86 19.44 1536
3072 		43.2 DDR3 192 342.43 Un­known 56 OEM
GeForce GTS 450 790 1580 4000 4.7 18.9 1536 96.0 GDDR5 455.04 Un­known 106
September 13, 2010
March 15, 2011 		GF106-250
GF116-200 		4 192:32:16 783 1566 1200-1600 (GDDR3)
3608 (GDDR5) 		6.2 25.0 512
1024 		57.7 128 601.34 Un­known 106 $129
GeForce GTX 460 SE November 15, 2010 GF104-225-A1 1950 332 6 288:48:32 650 1300 3400 7.8 31.2 1024 108.8 256 748.8 Un­known 150 $160
GeForce GTX 460 October 11, 2010 GF104 7 336:56:32 9.1 36.4 1024 108.8 873.6 Un­known OEM
July 12, 2010 GF104-300-KB-A1 336:56:24 675 1350 3600 9.4 37.8 768 86.4 192 907.2 Unknown $199
336:56:32 1024
2048 		115.2 256 160 $229
September 24, 2011 GF114 336:56:24 779 1557 4008 10.9 43.6 1024 96.2 192 1045.6 Un­known $199
GeForce GTX 465 May 31, 2010 GF100-030-A3 3000[64] 529 11 352:44:32 608 1215 3206 13.3 26.7 1024 102.7 256 1.2 855.36 106.92 200[d] $279
GeForce GTX 470 March 26, 2010 GF100-275-A3 14 448:56:40 3348 17.0 34.0 1280 133.9 320 1088.64 136.08 215[d] $349
GeForce GTX 480 March 26, 2010 GF100-375-A3 15 480:60:48 701 1401 3696 21.0 42.0 1536 177.4 384 1344.96 168.12 250[d] $499
Model Launch Code name Fab (nm) Transistors (million) Die size (mm2) SM count Core config[a][b] Clock rate Fillrate Memory configuration Supported API version Processing power (GFLOPS)[c] TDP (Watts)[d] Release Price (USD)
Core (MHz) Shader (MHz) Memory (MHz) Pixel (GP/s) Texture (GT/s) Size (MB) Bandwidth (GB/s) DRAM type Bus width (bit) Vulkan Direct3D OpenGL OpenCL[e] Single precision Double precision
  1. ^ a b Unified shaders: texture mapping units: render output units
  2. ^ a b Each SM in the GF100 contains 4 texture filtering units for every texture address unit. The complete GF100 die contains 64 texture address units and 256 texture filtering units.[60] Each SM in the GF104/106/108 architecture contains 8 texture filtering units for every texture address unit but has doubled both addressing and filtering units. The complete GF104 die also contains 64 texture address units and 512 texture filtering units despite the halved SM count, the complete GF106 die contains 32 texture address units and 256 texture filtering units and the complete GF108 die contains 16 texture address units and 128 texture filtering units.[61]
  3. ^ a b To calculate the processing power see Fermi (microarchitecture)#Performance.
  4. ^ a b c d e Note that while GTX 460's TDP is comparable to that of AMD's HD5000 series, GF100-based cards (GTX 480/470/465) are rated much lower but pull significantly more power, e.g. GTX 480 with 250W TDP consumes More power than an HD 5970 with 297W TDP.[62]
  5. ^ a b The 400 series is the only non-OEM family from GeForce 9 to 700 series not to include an official dual-GPU system. However, on March 18, 2011, EVGA released the first single-PCB card with dual 460s on board. The card came with 2048 MB of memory at 3600 MHz and 672 shader processors at 1400 MHz and was offered at the MSRP of $429.
  6. ^ The GeForce 405 card is a rebranded GeForce 310 which itself is a rebranded GeForce 210.

GeForce 500 series edit

Further information: GeForce 500 series and Fermi (microarchitecture)
Model Launch Code name Fab (nm) Transistors (million) Die size (mm2) Bus interface SM count Core config[a][b] Clock rate Fillrate Memory configuration Supported API version Processing power (GFLOPS)[c] TDP (watts)[d] Release Price (USD)
Core (MHz) Shader (MHz) Memory (MHz) Pixel (GP/s) Texture (GT/s) Size (MB) Bandwidth (GB/s) DRAM type Bus width (bit) Vulkan Direct3D OpenGL OpenCL8 Single precision Double precision
GeForce 510 September 29, 2011 GF119 TSMC 40 nm 292 79 PCIe 2.0 x16 1 48:8:4 523 1046 1800 2.1 4.5 1024
2048 		14.4 DDR3 64 n/a[63] 12 FL 11_1 4.6 1.1 100.4 Un­known 25 OEM
GeForce GT 520 April 12, 2011 PCIe 2.0 x16
PCIe 2.0 x1
PCI 		810 1620 3.25 6.5 14.4 155.5 Un­known 29 $59
GeForce GT 530[67] May 14, 2011 GF108-220 585 116 PCIe 2.0 x16 2 96:16:4 700 1400 2.8 11.2 28.8 128 268.8 22.40 50 OEM
GeForce GT 545 GF116 ~1170 ~238 3 144:24:16 720 1440 11.52 17.28 1536
3072 		43 192 415.07 Un­known 70 $149
870 1740 3996 13.92 20.88 1024 64 GDDR5 128 501.12 Un­known 105 OEM
GeForce GTX 550 Ti March 15, 2011 GF116-400 4 192:32:24 900 1800 4104 21.6 28.8 768+256
1536 		65.7+32.8
98.5 		128+64[e]
192 		691.2 Un­known 116 $149
GeForce GTX 555 May 14, 2011 GF114 1950 332 6 288:48:24 736 1472 3828 17.6 35.3 1024 91.9 128+64[e] 847.9 Un­known 150 OEM
GeForce GTX 560 SE February 20, 2012[68] GF114-200-KB-A1[f] Un­known
GeForce GTX 560 May 17, 2011 GF114-325-A1[f] 7 336:56:32 810 1620 4008 25.92 45.36 1024 2048 128.1 256 1088.6 Un­known $199
GeForce GTX 560 Ti January 25, 2011 GF114-400-A1[f] 8 384:64:32 822 1645 26.3 52.61 128.26 1263.4 110 170 $249
May 30, 2011 GF110[g] 3000[70] 520[70] 11 352:44:40 732 1464 3800 29.28 32.21 1280
2560 		152 320 1030.7 128.83 210[d] OEM
GeForce GTX 560 Ti 448 Cores November 29, 2011 GF110-270-A1[g] 14 448:56:40 40.99 1280 1311.7 163.97 $289
GeForce GTX 570 December 7, 2010 GF110-275-A1[g] 15 480:60:40 43.92 1280 2560 1405.4 175.68 219[d] $349
GeForce GTX 580 November 9, 2010 GF110-375-A1[g] 16 512:64:48 772 1544 4008 37.05 49.41 1536
3072[h] 		192.384 384 1581.1 197.63 244[d][72] $499
GeForce GTX 590 March 24, 2011 2x GF110-351-A1 2x 3000 2x 520 2x16 2x 512:64:48 607 1215 3414 2x29.14 2x38.85 2x 1536 2x163.87 2x384 2488.3 311.04 365 $699
Model Launch Code name Fab (nm) Transistors (million) Die size (mm2) Bus interface SM count Core config[a][b] Clock rate Fillrate Memory configuration Supported API version Processing power (GFLOPS)[c] TDP (Watts)[d] Release Price (USD)
Core (MHz) Shader (MHz) Memory (MHz) Pixel (GP/s) Texture (GT/s) Size (MB) Bandwidth (GB/s) DRAM type Bus width (bit) Vulkan Direct3D OpenGL OpenCL8 Single precision Double precision
  1. ^ a b Unified shaders: texture mapping units: render output units
  2. ^ a b Each SM in the GF110 contains 4 texture filtering units for every texture address unit. The complete GF110 die contains 64 texture address units and 256 texture filtering units.[65] Each SM in the GF114/116/118 architecture contains 8 texture filtering units for every texture address unit but has doubled both addressing and filtering units.
  3. ^ a b To calculate the processing power see Fermi (microarchitecture)#Performance.
  4. ^ a b c d e Similar to previous generation, GTX 580 and most likely future GTX 570[needs update], while reflecting its improvement over GF100, still have lower rated TDP and higher power consumption, e.g. GTX580 (243W TDP) is slightly less power hungry than GTX 480 (250W TDP). This is managed by clock throttling through drivers when a dedicated power hungry application is identified that could breach card TDP. Application name changing will disable throttling and enable full power consumption, which in some cases could be close to that of GTX480.[66]
  5. ^ a b 1024 MB RAM on 192-bit bus assemble with 4 x (128 MB) + 2 x (256 MB).
  6. ^ a b c Internally referred to as GF104B[69]
  7. ^ a b c d Internally referred to as GF100B[69]
  8. ^ Some companies have announced that they will be offering the GTX580 with 3GB RAM.[71]

GeForce 600 series edit

Further information: GeForce 600 series and Kepler (microarchitecture)
  • Add NVENC on GTX cards
  • Several 600 series cards are rebranded 400 or 500 series cards.
Model Launch Code name Fab (nm) Transistors (million) Die size (mm2) Bus interface SM count Core config[a] Clock rate Fillrate Memory configuration Supported API version Processing power (GFLOPS)[b] TDP (Watts) Release Price (USD)
Core (MHz) Average Boost (MHz) Max Boost (MHz) Shader (MHz) Memory (MHz) Pixel (GP/s) Texture (GT/s) Size (MB) Bandwidth (GB/s) DRAM type Bus width (bit) Vulkan[c] Direct3D OpenGL OpenCL Single precision Double precision
GeForce 605[d] April 3, 2012 GF119 TSMC 40 nm 292 79 PCIe 2.0 x16 1 48:8:4 523 1046 898
(1796) 		2.09 4.2 512 1024 14.4 DDR3 64 12 4.6 1.2 100.4 Un­known 25 OEM
GeForce GT 610[e] May 15, 2012 GF119-300-A1 PCIe 2.0 x16, PCIe x1, PCI 48:8:4 810 1620 1000
1800 		3.24 6.5 512
1024
2048 		8
14.4 		155.5 Un­known 29 Retail
GeForce GT 620[f] April 3, 2012 GF119 PCIe 2.0 x16 48:8:4 898
(1796) 		6.5 512
1024 		14.4 155.5 Un­known 30 OEM
May 15, 2012 GF108-100-KB-A1 585 116 2 96:16:4 700 1400 1000–1800 2.8 11.2 1024
2048 		8–14.4 268.8 Un­known 49 Retail
GeForce GT 625 February 19, 2013 GF119 292 79 1 48:8:4 810 1620 898
(1796) 		3.24 6.5 512 1024 14.4 155.5 Un­known 30 OEM
GeForce GT 630[g][h] April 24, 2012 GK107 TSMC 28 nm 1300 118 PCIe 3.0 x16 192:16:16 875 875 891
(1782) 		14 14 1024
2048 		28.5 128 1.2 336 14 50
May 15, 2012 GF108-400-A1 TSMC 40 nm 585 116 PCIe 2.0 x16 2 96:16:4 700 1620 1600–1800 2.8 11.2 1024
2048
4096 		25.6–28.8 311 Un­known 49 Retail
GF108 96:16:4 810 1620 800
(3200) 		3.2 13 1024 51.2 GDDR5 311 Un­known 65
May 29, 2013 GK208-301-A1 TSMC 28 nm 1020 79 PCIe 2.0 x8 1 384:16:8 902 902 900
(1800) 		7.22 14.44 1024
2048 		14.4 DDR3 64 1.2 692.7 Un­known 25
GeForce GT 635 February 19, 2013 GK208 PCIe 3.0 x8 384:16:8 967 967 1001
(2002) 		7.74 15.5 16 742.7 Un­known 35 OEM
GeForce GT 640[i] April 24, 2012 GF116 TSMC 40 nm 1170 238 PCIe 2.0 x16 3 144:24:24 720 1440 891
(1782) 		17.3 17.3 1536
3072 		42.8 192 414.7 Un­known 75
GK107 TSMC 28 nm 1300 118 PCIe 3.0 x16 2 384:32:16 797 797 891
(1782) 		12.8 25.5 1024
2048 		28.5 128 1.2 612.1 25.50 50
June 5, 2012 900 900 891
(1782) 		14.4 28.8 2048
4096 		28.5 691.2 28.8 65 $100
April 24, 2012 950 950 1250
(5000) 		15.2 30.4 1024
2048 		80 GDDR5 729.6 30.40 75 OEM
May 29, 2013 GK208-400-A1 TSMC 28 nm 1020 79 PCIe 2.0 x8 384:16:8 1046 1046 1252
(5008) 		8.37 16.7 1024 40.1 64 803.3 Un­known 49
GeForce GT 645[j] April 24, 2012 GF114-400-A1 TSMC 40 nm 1950 332 PCIe 2.0 x16 6 288:48:24 776 1552 1914 18.6 37.3 91.9 192 894 Un­known 140 OEM
GeForce GTX 645 April 22, 2013 GK106 TSMC 28 nm 2540 221 PCIe 3.0 x16 3 576:48:16 823.5 888.5 823 1000
(4000) 		14.16 39.5 64 128 1.2 948.1 39.53 64
GeForce GTX 650 September 13, 2012 GK107-450-A2 1300 118 2 384:32:16 1058 1058 1250
(5000) 		16.9 33.8 1024
2048 		80 812.54 33.86 $110
November 27, 2013 [73] GK-106-400-A1 2540 221 65 ?
GeForce GTX 650 Ti October 9, 2012 GK106-220-A1 4 768:64:16 928 928 1350
(5400) 		14.8 59.4 86.4 1425.41 59.39 110 $150 (130)
GeForce GTX 650 Ti Boost March 26, 2013 GK106-240-A1 768:64:24 980 1032 980 1502
(6008) 		23.5 62.7 144.2 192 1505.28 62.72 134 $170 (150)
GeForce GTX 660 September 13, 2012 GK106-400-A1 5 960:80:24 1084 1502
(6008) 		23.5 78.4 1536+512
3072 		96.1+48.1
144.2 		128+64
192 		1881.6 78.40 140 $230 (180)
August 22, 2012 GK104-200-KD-A2 3540 294 6 1152:96:24
1152:96:32 		823.5 888.5 899 823 1450
(5800) 		19.8 79 1536
2048
3072 		139
186 		192
256 		2108.6 79.06 130 OEM
GeForce GTX 660 Ti August 16, 2012 GK104-300-KD-A2 7 1344:112:24 915 980 1058 915 1502
(6008) 		22.0 102.5 2048 96.1+48.1
144.2 		128+64
192 		2459.52 102.48 150 $300
GeForce GTX 670 May 10, 2012 GK104-325-A2 1344:112:32 1084 1502
(6008) 		29.3 102.5 2048
4096 		192.256 256 2459.52 102.48 170 $400
GeForce GTX 680 March 22, 2012 GK104-400-A2 8 1536:128:32 1006[74] 1058 1110 1006 1502
(6008) 		32.2 128.8 192.256 3090.43 128.77 195 $500
GeForce GTX 690 April 29, 2012 2x GK104-355-A2 2x 3540 2x 294 2x 8 2x 1536:128:32 915 1019 1058 915 1502
(6008) 		2x 29.28 2x 117.12 2x 2048 2x 192.256 2x 256 2x 2810.88 2x 117.12 300 $1000
Model Launch Code name Fab (nm) Transistors (million) Die size (mm2) Bus interface SM count Core config[a] Clock rate Fillrate Memory configuration Supported API version Processing power (GFLOPS)[b] TDP (Watts) Release Price (USD)
Core (MHz) Average Boost (MHz) Max Boost (MHz) Shader (MHz) Memory (MHz) Pixel (GP/s) Texture (GT/s) Size (MB) Bandwidth (GB/s) DRAM type Bus width (bit) Vulkan[c] Direct3D OpenGL OpenCL Single precision Double precision
  1. ^ a b Unified shaders: texture mapping units: render output units
  2. ^ a b To calculate the processing power see Kepler (microarchitecture)#Performance, or Fermi (microarchitecture)#Performance.
  3. ^ a b Vulkan 1.2 is only supported on Kepler cards.[63]
  4. ^ The GeForce 605 (OEM) card is a rebranded GeForce 510.
  5. ^ The GeForce GT 610 card is a rebranded GeForce GT 520.
  6. ^ The GeForce GT 620 (OEM) card is a rebranded GeForce GT 520.
  7. ^ The GeForce GT 630 (DDR3, 128-bit, retail) card is a rebranded GeForce GT 430 (DDR3, 128-bit).
  8. ^ The GeForce GT 630 (GDDR5) card is a rebranded GeForce GT 440 (GDDR5).
  9. ^ The GeForce GT 640 (OEM) GF116 card is a rebranded GeForce GT 545 (DDR3).
  10. ^ The GeForce GT 645 (OEM) card is a rebranded GeForce GTX 560 SE.

GeForce 700 series edit

Further information: GeForce 700 series and Kepler (microarchitecture)

The GeForce 700 series for desktop. The GM107-chips are Maxwell-based, the GKxxx-chips Kepler.

Model Launch Code name Fab (nm) Transistors (million) Die size (mm2) Bus interface SMX count Core config[a] Clock rate Fillrate Memory configuration Supported API version Processing power (GFLOPS)[b] TDP (Watts) Release Price (USD)
Base (MHz) Average Boost (MHz) Max Boost[c] (MHz) Memory (MHz) Pixel (GP/s) Texture (GT/s) Size (MB) Bandwidth (GB/s) DRAM type Bus width (bit) Vulkan[d] Direct3D[e] OpenGL OpenCL Single precision Double precision
GeForce GT 705[77][f] March 27, 2014 GF119-300-A1 TSMC 40 nm 292 79 PCIe 2.0 x16 1 48:8:4 810 898
(1796) 		3.24 6.5 512
1024 		14.4 DDR3 64 n/a 12 4.6 1.1 155.5 19.4 29 OEM
GeForce GT 710[78] GK208-301-A1 TSMC 28 nm 1020 79 PCIe 2.0 x8 192:16:8 823 900 (1800) 6.6 13.2 512 64 1.2 1.2 316.0 13.2
January 26, 2016 GK208-203-B1 PCIe 2.0 x8, PCIe x1 192:16:8 954 900 (1800)
1253 (5010) 		7.6 15.3 1024
2048 		14.4
40.0 		DDR3
GDDR5 		366 15.3 19 $35–45
GeForce GT 720[79] March 27, 2014 GK208-201-B1 PCIe 2.0 x8 192:16:8 797 900 (1800)
1253 (5010) 		6.4 12.8 1024
2048 		14.4
40.0 		306 12.8 $49–59
GeForce GT 730
[80][g][h] 		June 18, 2014 GK208-301-A1 2 384:16:8 902 900
(1800) 		7.22 14.44 1024[81]
2048
4096 		14.4 DDR3 692.7 28.9 23 $69–79
GK208-400-A1 384:16:8 902 1250
(5000) 		7.22 14.44 1024
2048[82] 		40.0 GDDR5 25
GF108 TSMC 40 nm 585 116 PCIe 2.0 x16 96:16:4 700 900
(1800) 		2.8 11.0 1024
2048
4096 		28.8 DDR3 128 n/a 1.1 268.8 33.6 49
GeForce GT 740[i] May 29, 2014 GK107-425-A2 TSMC
28HP 		1270 118 PCIe 3.0 x16 384:32:16 993 891
(1782) 		15.9 31.8 28.5 128 1.2 1.2 762.6 31.8 64 $89–99
384:32:16 993 1252
(5008) 		15.9 31.8 80.1 GDDR5
GeForce GTX 745 February 18, 2014 GM107-220-A2 1870 148 3 384:24:16 1033 Un­known Un­known 900
(1800) 		16.5 24.8 1024
4096 		28.8 DDR3 1.3 793.3 24.8 55 OEM
GeForce GTX 750 GM107-300-A2 4 512:32:16 1020 1085 1163 1250
(5000) 		16.3 32.6 1024
2048
4096[83] 		80 GDDR5 1044.5 32.6 $119
GeForce GTX 750 Ti GM107-400-A2 5 640:40:16 1020 1085 1200 1350
(5400) 		16.3 40.8 1024
2048
4096 		86.4 1305.6 40.8 60 $149
GeForce GTX 760 192-bit October 17, 2013 GK104-200-KD-A2 3540 294 6 1152:96:24 824 888 889 1450
(5800) 		19.8 79.1 1536
3072 		139.2 192 1.2 1896.2 79.0 130 OEM
GeForce GTX 760 June 25, 2013 GK104-225-A2 1152:96:32 980 1033 1124 1502
(6008) 		31.4[j] 94 2048
4096 		192.3 256 2257.9 94.1 170 $249 ($219)
GeForce GTX 760 Ti[k] September 27, 2013[84] GK104 7 1344:112:32 915 980 1084 1502
(6008) 		29.3 102.5 2048 192.3 2459.5 102.5 OEM
GeForce GTX 770 May 30, 2013 GK104-425-A2 8 1536:128:32 1046 1085 1130 1752.5
(7010) 		33.5 134 2048 4096 224 3213.3 133.9 230 $399 ($329)
GeForce GTX 780 May 23, 2013 GK110-300-A1 7080 561 12 2304:192:48 863 900 1002 1502
(6008) 		41.4[j] 160.5 3072 6144[85] 288.4 384 3976.7 165.7 $649 ($499)
GeForce GTX 780 Ti[86][87][88] November 7, 2013 GK110-425-B1 15 2880:240:48 876 928 1019 1752.5
(7010) 		42.0[j] 210.2 3072 336.5 5045.7 210.2 $699
GeForce GTX TITAN[89][90][91] February 21, 2013 GK110-400-A1 14 2688:224:48 837 876 993 1502
(6008) 		40.2 187.5 6144 288.4 4499.7 1300[92]-1499.9 $999
GeForce GTX TITAN Black February 18, 2014 GK110-430-B1 15 2880:240:48 889 980 1058 1752.5
(7010) 		42.7 213.4 336.5 5120.6 1706.9
GeForce GTX TITAN Z May 28, 2014 2x GK110-350-B1[93] 2x 7080 2x 561 2x 15 2x 2880:240:48 705 876 Un­known 1752.5
(7010) 		2x 33.8 2x 169 2x 6144 2x 336.5 2x 384 4.5 5046x2 1682x2[94] 375 $2999
Model Launch Code name Fab (nm) Transistors (million) Die size (mm2) Bus interface SMX count Core config[a] Clock rate Fillrate Memory configuration Supported API version Processing power (GFLOPS)[b] TDP (Watts) Release Price (USD)
Base (MHz) Average Boost (MHz) Max Boost[c] (MHz) Memory (MHz) Pixel (GP/s) Texture (GT/s) Size (MB) Bandwidth (GB/s) DRAM type Bus width (bit) Vulkan[d] Direct3D[e] OpenGL OpenCL Single precision Double precision
  1. ^ a b Unified shaders: texture mapping units: render output units
  2. ^ a b To calculate the processing power see Maxwell (microarchitecture)#Performance, or Kepler (microarchitecture)#Performance.
  3. ^ a b Max Boost depends on ASIC quality. For example, some GTX TITAN with over 80% ASIC quality can hit 1019 MHz by default, lower ASIC quality will be 1006 MHz or 993 MHz.
  4. ^ a b Maxwell supports Vulkan version 1.3, while Kepler only support Vulkan version 1.2, Fermi does not support the Vulkan API at all.[63]
  5. ^ a b Kepler supports some optional 11.1 features on feature level 11_0 through the Direct3D 11.1 API, however Nvidia did not enable four non-gaming features to qualify Kepler for level 11_1.[75][76]
  6. ^ The GeForce GT 705 (OEM) is a rebranded GeForce GT 610, which itself is a rebranded GeForce GT 520.
  7. ^ The GeForce GT 730 (DDR3, 64-bit) is a rebranded GeForce GT 630 (Rev. 2).
  8. ^ The GeForce GT 730 (DDR3, 128-bit) is a rebranded GeForce GT 630 (128-bit).
  9. ^ The GeForce GT 740 (OEM) is a rebranded GeForce GTX 650.
  10. ^ a b c As a Kepler GPC is able to rasterize 8 pixels per clock, fully enabled GK110 GPUs (780 Ti/TITAN Black) can only output 40 pixels per clock (5 GPCs), despite 48 ROPs and all SMX units being physically present. For GTX 780 and GTX 760, multiple GPC configurations with differing pixel fillrate are possible, depending on which SMXs were disabled in the chip: 5/4 GPCs, or 4/3 GPCs, respectively.
  11. ^ The GeForce GTX 760 Ti (OEM) is a rebranded GeForce GTX 670.

GeForce 900 series edit

Further information: GeForce 900 series and Maxwell (microarchitecture)
Model Launch Code name Process Transistors (billion) Die size (mm2) Core config[a] Bus interface L2 Cache
(MB) 		Clock Speeds Memory Fillrate[b] Processing power (GFLOPS)[b][c] TDP (Watts) SLI support Release price (USD)
Base (MHz) Boost (MHz) Memory (MT/s) Size (GB) Bandwidth (GB/s) Bus type Bus width (bit) Pixel (GP/s)[d] Texture (GT/s)[e] Single precision Double precision MSRP
GeForce GT 945A[95][96][97] February, 2016 GM108 TSMC
28HP 		Un­known Un­known 512:24:8 (4) PCIe 3.0 x8 ? 1072 1176 1800 1 / 2 14.4 DDR3 / GDDR5 64 8.5
9.4 		25.7
28.2 		1,097.7
1,204.2 		34.3
37.6 		33 No OEM
GeForce GTX 950[98] August 20, 2015 GM206-250 2.94 227 768:48:32 (6) PCIe 3.0 x16 1 1024 1188 6600 2 105.7 GDDR5 128 32.7
38.0 		49.1
57.0 		1,572.8
1,824.7 		49.1
57.0 		90 (75[f]) 2-way SLI $159
GeForce GTX 950 (OEM)[100] Un­known GM206 1024:64:32 (8) 935 Un­known 5000 80.0 29.9
  		59.8
  		1,914.9
, 		59.8
  		Un­known OEM
GeForce GTX 960[101] January 22, 2015 GM206-300 1127 1178 7000 2
4 		112.1 36.0
37.6 		72.1
75.3 		2,308.0
2,412.5 		72.1
75.3 		120 $199
GeForce GTX 960 (OEM)[102] Un­known GM204 5.2 398 1280:80:48 (10) 924 Un­known 5000 3 120.0 192 44.3
  		73.9
  		2,365.4
, 		73.9
  		Un­known OEM
GeForce GTX 970[103] September 18, 2014 GM204-200 1664:104:56 (13) 1.75 1050 1178 7000 3.5 +
0.5[g] 		196.3 +
28.0[g] 		224 +
32[g] 		58.8
65.9 		109.2
122.5 		3,494.4
3,920.3 		109.2
122.5 		145 4-way SLI $329
GeForce GTX 980[105] September 18, 2014 GM204-400 2048:128:64 (16) 2 1126 1216 4 224.3 256 72.0
77.8 		144.1
155.6 		4,612.0
4,980.7 		144.1
155.6 		165 $549
GeForce GTX 980 Ti[106] June 1, 2015 GM200-310 8 601 2816:176:96 (22) 3 1000 1075 6 336.5 384 96.0
103.2 		176.0
189.2 		5,632.0
6,054.4 		176.0
189.2 		250 $649
GeForce GTX TITAN X[107] March 17, 2015 GM200-400 3072:192:96 (24) 12 192.0
206.4 		6,144.0
6,604.8 		192.0
206.4 		$999
  1. ^ Main shader processors : texture mapping units : render output units (streaming multiprocessors)
  2. ^ a b Base clock, Boost clock
  3. ^ To calculate the processing power see Maxwell (microarchitecture)#Performance.
  4. ^ Pixel fillrate is calculated as the number of ROPs multiplied by the respective core clock speed.
  5. ^ Texture fillrate is calculated as the number of TMUs multiplied by the respective core clock speed.
  6. ^ Some GTX950 cards were released without power connector powered only by PCIe slot. These had limited power consumption and TPD to 75W.[99]
  7. ^ a b c For accessing its memory, the GTX 970 stripes data across 7 of its 8 32-bit physical memory lanes, at 196 GB/s. The last 1/8 of its memory (0.5 GB on a 4 GB card) is accessed on a non-interleaved solitary 32-bit connection at 28 GB/s, one seventh the speed of the rest of the memory space. Because this smaller memory pool uses the same connection as the 7th lane to the larger main pool, it contends with accesses to the larger block reducing the effective memory bandwidth not adding to it as an independent connection could.[104]

GeForce 10 series edit

Further information: GeForce 10 series and Pascal (microarchitecture)
Model Launch Code name Process Transistors (billion) Die size (mm2) Core config[b] Bus interface L2 Cache
(MB) 		Clock speeds Memory Fillrate[c] Processing power (GFLOPS)[c][d] TDP (Watts) SLI support Release price (USD)
Base core (MHz) Boost core (MHz) Memory (MT/s) Size (GB) Bandwidth (GB/s) Bus type Bus width (bit) Pixel (GP/s)[e][f] Texture (GT/s)[g] Single precision Double precision Half precision MSRP Founders Edition
GeForce GT 1010 [111][112] January 13, 2021 GP108-200-A1 Samsung
14LPP 		1.8 74 256:16:16
(2) (1) 		PCIe 3.0 x4 0.25 1228 1468 5000 2 40.1 GDDR5 64 9.8
11.8 		19.7
23.5 		628.7
751.6 		26.2
31.3 		? 30 No OEM
1152 1380 2100 16.8 DDR4 9.2
11.0 		18.4
22.0 		590.0
706.6 		24.6
29.4 		? 20
GeForce GT 1030 [113][114][115][116] March 12, 2018 GP108-310-A1 384:24:16
(3) (1) 		0.5 1379 18.4
22.0 		27.6
33.0 		884.7
1,059.0 		27.6
33.0 		13.8
16.5 		$79
May 17, 2017 GP108-300-A1 1227 1468 6000 48.0 GDDR5 19.6
23.4 		29.4
35.2 		942.3
1,127.4 		29.4
35.2 		14.7
17.6 		30 $69
GeForce GTX 1050[117] October 25, 2016 GP107-300-A1 3.3 132 640:40:32
(5) (2) 		PCIe 3.0 x16 1 1354 1455 7000 112.0 128 43.3
46.6 		54.1
58.8 		1,733.1
1,862.4 		54.1
58.2 		27.0
29.1 		75 $109
May 21, 2018 GP107-301-A1 768:48:24
(6) (2) 		0.75 1392 1518 3 84.0 96 33.4
36.4 		66.8
72.9 		2,138.1
2,331.6 		66.8
72.9 		33.4
36.4
GeForce GTX 1050 Ti[117] October 25, 2016 GP107-400-A1 768:48:32
(6) (2) 		1 1290 1392 4 112.0 128 41.2
44.5 		61.9
66.8 		1,981.4
2,138.1 		61.9
66.8 		30.9
33.4 		$139
GeForce GTX 1060
[118][119][120][121] 		December 25, 2016 GP104-140-A1 TSMC
16FF 		7.2 314 1152:72:48
(9) (2) 		1.5 1506 1708 8000 3 192.0 192 72.2
81.9 		108.4
122.9 		3,469.8
3,935.2 		108.4
122.9 		54.2
61.4 		120 $199
August 18, 2016 GP106-300-A1 4.4 200
December 26, 2017 GP106-350-K3-A1 1280:80:48
(10) (2) 		1.25 5 160.0 160 60.2
68.3 		120.4
136.7 		3,855.3
4,375.0 		120.4
136.7 		60.2
68.3 		OEM
March 8, 2018 GP104-150-A1 7.2 314 1.5 6 192.0 192 72.2
82.0 		$299
October 18, 2018 GP104-150-KA-A1 GDDR5X
July 19, 2016 GP106-400-A1 4.4 200 GDDR5 $249 $299
April 20, 2017 GP106-410-A1 9000 216.0 $299
GeForce GTX 1070[122][123] Jun 10, 2016 / Dec 4, 2018 GP104-200-A1 7.2 314 1920:120:64
(15) (3) 		2 1683 8000 8 256.0 GDDR5
GDDR5X 		256 96.3
107.7 		180.7
201.9 		5,783.0
6,462.7 		180.7
201.9 		90.3
100.9 		150 4-way SLI
or
2-way SLI HB[124] 		$379 $449
GeForce GTX 1070 Ti[122] November 2, 2017 GP104-300-A1 2432:152:64
(19) (4) 		1607 GDDR5 102.8
107.7 		244
256 		7,816.4
8,186.1 		244.2
255.8 		122.1
127.9 		180 $449
GeForce GTX 1080[125][126] May 27, 2016 GP104-400-A1 2560:160:64
(20) (4) 		1733 10000 320.0 GDDR5X 102.8
110.9 		257.1
277.2 		8,227.8
8,872.9 		257.1
277.2 		128.5
138.6 		$599 $699
April 20, 2017 GP104-410-A1 11000 352.0
GeForce GTX 1080 Ti[127] March 5, 2017 GP102-350-K1-A1 12 471 3584:224:88
(28) (6) 		2.75 1480 1582 11 484.0 352 130.2
139.2 		331.5
354.3 		10,608.6
11,339.7 		331.5
354.3 		165.7
177.1 		250 $699
TITAN X Pascal[128] August 2, 2016 GP102-400-A1 3584:224:96
(28) (6) 		3 1417 1531 10000 12 480.0 384 136.0
146.9 		317.4
342.9 		10,157.0
10,974.2 		317.4
342.9 		158.7
171.4 		$1199
TITAN Xp[129] April 6, 2017 GP102-450-A1 3840:240:96
(30) (6) 		1405 1582 11400 547.7 134.8
142.0 		337.2
355.2 		10,790.4
12,149.7 		337.2
355.2 		168.6
177.6
Model Launch Code name Process Transistors (billion) Die size (mm2) Core config[b] Bus interface L2 Cache
(MB) 		Base core (MHz) Boost core (MHz) Memory (MT/s) Size (GB) Bandwidth (GB/s) Bus type Bus width (bit) Pixel (GP/s)[e][h] Texture (GT/s)[g] Single precision Double precision Half precision TDP (Watts) SLI support MSRP Founders Edition
Clock speeds Memory Fillrate[c] Processing power (GFLOPS)[c][d] Release price (USD)
  1. ^ The NVIDIA TITAN Xp and the Founders Edition GTX 1080 Ti do not have a dual-link DVI port, but a DisplayPort to single-link DVI adapter is included in the box.
  2. ^ a b Main shader processors : texture mapping units : render output units (streaming multiprocessors) (graphics processing clusters)
  3. ^ a b c d Base clock, Boost clock
  4. ^ a b To calculate the processing power see Pascal (microarchitecture)#Performance.
  5. ^ a b Pixel fillrate is calculated as the lowest of three numbers: number of ROPs multiplied by the base core clock speed, number of rasterizers multiplied by the number of fragments they can generate per rasterizer multiplied by the base core clock speed, and the number of streaming multiprocessors multiplied by the number of fragments per clock that they can output multiplied by the base clock rate.
  6. ^ As the GTX 1070 has one of the four GP104 GPCs disabled in the die, its frontend is only able to rasterize 48 pixels per clock.[109] Analogically, the GTX 1060 features only two GPCs on its GP106 die, meaning that its frontend can only rasterize 32 pixels per clock. The remaining backend ROPs can still be used for tasks such as MSAA.[110]
  7. ^ a b Texture fillrate is calculated as the number of TMUs multiplied by the base core clock speed.
  8. ^ As the GTX 1070 has one of the four GP104 GPCs disabled in the die, its frontend is only able to rasterize 48 pixels per clock.[109] Analogically, the GTX 1060 features only two GPCs on its GP106 die, meaning that its frontend can only rasterize 32 pixels per clock. The remaining backend ROPs can still be used for tasks such as MSAA.[110]

Volta series edit

Further information: Volta (microarchitecture)
Model Launch Code name Process Transistors (billion) Die size (mm2) Core config[a] Bus Interface L2 Cache
(MB) 		Clock speeds Memory Fillrate[b] Processing power (GFLOPS)[b] TDP (Watts) NVLink Support Release price (USD)
Base core clock (MHz) Boost core clock (MHz) Memory (MT/s) Size (GB) Bandwidth (GB/s) Bus type Bus width (bit) Pixel (GP/s)[c] Texture (GT/s)[d] Single precision Double precision Half precision Tensor compute + Single precision MSRP Founders Edition
Nvidia TITAN V[130] December 7, 2017 GV100-400-A1 TSMC
12FFN 		21.1 815 5120:320:96:640
(80) (6) 		PCIe 3.0 x16 4.5 1200 1455 1700 12 652.8 HBM2 3072 153.6
186.2 		384.0
465.6 		12,288.0
14,899.2 		6,144.0
7,449.6 		24,576.0
29,798.4 		110,592.0
134,092.8 		250 No $2999
Nvidia TITAN V
CEO Edition[131][132] 		June 21, 2018 GV-100-???-A1 5120:320:128:640
(80) (6) 		6 32 870.4 4096 No
  1. ^ Main shader processors : texture mapping units : render output units : tensor cores (streaming multiprocessors) (graphics processing clusters)
  2. ^ a b Base clock, Boost clock
  3. ^ Pixel fillrate is calculated as the lowest of three numbers: number of ROPs multiplied by the base core clock speed, number of rasterizers multiplied by the number of fragments they can generate per rasterizer multiplied by the base core clock speed, and the number of streaming multiprocessors multiplied by the number of fragments per clock that they can output multiplied by the base clock rate.
  4. ^ Texture fillrate is calculated as the number of TMUs multiplied by the base core clock speed.

GeForce 16 series edit

Further information: GeForce 16 series and Turing (microarchitecture)
Model Launch Code name Process Transistors (billion) Die size (mm2) Core config[a] Bus interface L2 Cache (MB) Clock speeds Memory Fillrate[b] Processing power (GFLOPS)[b] TDP (Watts) NVLink support Release price (USD)
Base core clock (MHz) Boost core clock (MHz) Memory (GT/s) Size (GB) Bandwidth (GB/s) Bus type Bus width (bit) Pixel (GP/s)[c] Texture (GT/s)[d] Single precision Double precision Half precision
GeForce GTX 1630 June 28, 2022[133] TU117-150-A1 TSMC
12FFN 		4.7 200 512:32:16:1024:0
(8) (?) 		PCIe 3.0 x16 1 1740 1785 12 4 96 GDDR6 64 27.84
28.56 		55.68
57.12 		1,781.76
1,827.84 		55.68
57.12 		3,563.52
3,655.68 		75 No ?
GeForce GTX 1650[134] April 23, 2019 TU117-300-A1 896:56:32:1792:0
(14) (2) 		1485 1665 8 128 GDDR5 128 47.52
53.28 		83.16
93.24 		2,661.00
2,984.00 		83.16
93.24 		5,322.00
5,967.00 		$149
April 3, 2020[135] 1410 1590 12 192 GDDR6 45.12
50.88 		78.96
89.04 		2,526.72
2,849.28 		78.96
89.04 		5,053.44
5,698.56
June 18, 2020[136] TU106-125-A1 10.8 445 90
GeForce GTX 1650 Super[137] November 22, 2019[138] TU116-250-KA-A1[139] 6.6 284 1280:80:32:2560:0
(20) (3) 		1.5 1530 1725 48.96
55.20 		122.40
138.0 		3,916.80
4,416.00 		122.40
138.00 		7,833.60
8,832.00 		100 $159
GeForce GTX 1660[140] March 14, 2019 TU116-300-A1 1408:88:48:2816:0
(22) (3) 		1785 8 6 GDDR5 192 73.44
85.68 		134.64
157.1 		4,308.00
5,027.00 		134.64
157.08 		8,616.00
10,053.00 		120 $219
GeForce GTX 1660 Super[141] October 29, 2019 TU116-300-A1 14 336 GDDR6 125 $229
GeForce GTX 1660 Ti[142] February 21, 2019 TU116-400-A1 1536:96:48:3072:0
(24) (3) 		1500 1770 12 288 72.0
84.96 		144.0
169.9 		4,608.00
5,437.44 		144.00
169.92 		9,216.00
10,874.88 		120 $279

RTX 20 series edit

Further information: GeForce 20 series and Turing (microarchitecture)
  • Supported APIs: Direct3D 12 Ultimate (12_2), OpenGL 4.6, OpenCL 3.0, Vulkan 1.3[63] and CUDA 7.5
  • Unlike previous generations the RTX Non-Super (RTX 2070, RTX 2080, RTX 2080 Ti) Founders Edition cards no longer have reference clocks, but are "Factory-OC". However, RTX Supers (RTX 2060 Super, RTX 2070 Super, and RTX 2080 Super) Founders Edition are reference clocks.
  • NVENC 6th generation (B-frame, etc.)
Model Launch Code name Process Transistors (billion) Die size (mm2) Core config[a] Bus interface L2 Cache
(MB) 		Clock speeds Memory Fillrate[b] Processing power (GFLOPS)[b] Ray-tracing Performance TDP (Watts) NVLink support Release price (USD)
Base core clock (MHz) Boost core clock (MHz) Memory (GT/s) Size (GB) Bandwidth (GB/s) Bus type Bus width (bit) Pixel (GP/s)[c] Texture (GT/s)[d] Single precision Double precision Half precision Tensor compute (FP16) Rays/s (Billions) RTX OPS/s (Trillions) MSRP Founders Edition
GeForce RTX 2060[143] January 15, 2019 TU106-200-KA-A1 TSMC
12FFN 		10.8 445 1920:120:48:240:30
(30) (3) 		PCIe 3.0 x16 3 1365 1680 14 6 336.0 GDDR6 192 65.52
80.64 		163.80
201.60 		5 241.60
6,451.20 		163.80
201.60 		10 483.20
12 902.40 		41 932.80
51 609.60 		5 37 160 No $349
January 10, 2020 TU104-150-KC-A1[144] 13.6 545 $299
December 7, 2021[145] TU106-300-KA-A1 10.8 445 2176:136:64:272:34
(34) (3) 		1470 1650 12
79.20 		199.92
224.40 		6 400.00
7 180.00 		199.92
224.40 		12 800.00
14 360.00 		185
GeForce RTX 2060 Super[146][147] July 9, 2019 TU106-410-A1 4 8 448.0 256 94.08
105.60 		51,200.00
57,440.00 		6 41 175 $399
GeForce RTX 2070[148][149] October 17, 2018 TU106-400-A1 2304:144:64:288:36
(36) (3) 		1410 1620 90.24
103.68 		203.04
233.28 		6,497.28
7,464.96 		203.04
233.28 		12,994.56
14,929.92 		51,978.24
59,719.68 		42 $499 $599
GeForce RTX 2070 Super[146][150] July 9, 2019 TU104-410-A1 13.6 545 2560:160:64:320:40
(40) (5) 		1605 1770 102.70
113.28 		256.80
283.20 		8,220.00
9,060.00 		256.80
283.20 		16,440.00
18,120.00 		65,760.00
72,480.00 		7 52 215 2-way NVLink $499
GeForce RTX 2080[151][152] September 20, 2018 TU104-400-A1 2944:184:64:368:46
(46) (6) 		1515 1710 96.96
109.44 		278.76
314.64 		8,920.32
10,068.48 		278.76
314.64 		17,840.64
20,136.96 		71,362.56
80,547.84 		8 57 $699 $799
GeForce RTX 2080 Super[146][153] July 23, 2019 TU104-450-A1 3072:192:64:384:48
(48) (6) 		1650 1815 15.5 496.0 105.60
116.16 		316.80
348.48 		10,140.00
11,150.00 		316.80
348.50 		20,280.00
22,300.00 		81,120.00
89,200.00 		63 250 $699
GeForce RTX 2080 Ti[154] September 27, 2018 TU102-300-K1-A1 18.6 754 4352:272:88:544:68
(68) (6) 		5.5 1350 1545 14 11 616.0 352 118.80
135.96 		367.20
420.24 		11,750.40
13,447.68 		367.20
420.24 		23,500.80
26,895.36 		94,003.20
107,581.44 		10 76 $999 $1,199
Nvidia TITAN RTX[155] December 18, 2018 TU102-400-A1 4608:288:96:576:72
(72) (6) 		6 1770[e] 24 672.0 384 129.60
169.92 		388.80
509.76 		12 441.60
16 312.32 		388.80
509.76 		24 883.20
32 624.64 		99 532.80
130 498.56 		11 84 280 $2,499
  1. ^ a b Main shader processors : texture mapping units : render output units : tensor cores (or FP16 cores in GeForce 16 series) : ray-tracing cores (streaming multiprocessors) (graphics processing clusters)
  2. ^ a b c d Base clock, Boost clock
  3. ^ a b Pixel fillrate is calculated as the lowest of three numbers: number of ROPs multiplied by the base core clock speed, number of rasterizers multiplied by the number of fragments they can generate per rasterizer multiplied by the base core clock speed, and the number of streaming multiprocessors multiplied by the number of fragments per clock that they can output multiplied by the base clock rate.
  4. ^ a b Texture fillrate is calculated as the number of TMUs multiplied by the base core clock speed.
  5. ^ Boost of the Founders Editions, as there is no reference version of this card.

RTX 30 series edit

Further information: GeForce 30 series and Ampere (microarchitecture)
Model Launch Code name Process Transistors (billion) Die size (mm2) Core config[a] Bus interface L2 Cache
(MB) 		Clock speeds Memory Fillrate Processing power (TFLOPS) Ray-tracing Performance (TFLOPS) TDP (Watts) NVLink support Release price (USD)
Base core clock (MHz) Boost core clock (MHz) Memory (MT/s) Size (GB) Bandwidth (GB/s) Bus type Bus width (bit) Pixel (GP/s) Texture (GT/s) Single precision Double precision Half precision Tensor compute (FP16) (2:1 sparse) MSRP Founders Edition
GeForce RTX 3050[156] February 2, 2024 GA107-325 Samsung
8LPP 		8.7 200 2304:72:32:72:18
(18) (2) 		PCIe 4.0
x8 		2 1042 1470 14000 6 168.0 GDDR6 96 33.34
47.04 		75.02
105.8 		4.802
6.774 		0.075
0.105 		4.802
6.774 		30.1
60.2 		70 No $169
December 16, 2022 GA107-150-A1 2560:80:32:80:20
(20) (2) 		1552 1777 8 224.0 128 49.6
59.86 		124.2
142.2 		7.95
9.01 		0.124
0.142 		7.95
9.01 		63.6
72.8 		18.2 115 $249
July 18, 2022 GA106-150 13.25 276 2304:72:32:72:18
(18) (2) 		1515 1755 48.48
56.16 		109.1
126.4 		6.981
8.087 		0.109
0.126 		6.981
8.087 		130 OEM[157]
January 27, 2022[158] GA106-150-A1 2560:80:32:80:20
(20) (2) 		1552 1777 49.6
59.86 		124.2
142.2 		7.95
9.01 		0.124
0.142 		7.95
9.01 		63.6
72.8 		18.2 $249
GeForce RTX 3060[159] October 27, 2022[160] GA106-302 3584:112:48:112:28
(28) (3) 		PCIe 4.0
x16 		3 1320 1777 15000 240.0 63.4
85.3 		147.8
199.0 		9.46
12.74 		0.148
0.199 		9.46
12.74 		75.7
101.9 		25 170 $329
May 2021 12 360.0 192
February 25, 2021 GA106-300-A1
September 1, 2021 GA104-150-A1[161] 17.4 392.5
GeForce RTX 3060 Ti[162] December 2, 2020 GA104-200-A1 4864:152:80:152:38
(38) (5) 		4 1410 1665 14000 8 448.0 256 112.8
133.2 		214.3
253.1 		13.72
16.20 		0.214
0.253 		13.70
16.20 		109.7
129.6 		32.4 200 $399
October 27, 2022[160] GA104-202 19000 608.0 GDDR6X
GeForce RTX 3070[163][164] October 29, 2020[165] GA104-300-A1 5888:184:96:184:46
(46) (6) 		1500 1725 14000 448.0 GDDR6 144.0
165.6 		276.0
317.4 		17.66
20.31 		0.276
0.318 		17.66
20.31 		141.31
162.98 		40.6 220 $499
GeForce RTX 3070 Ti[166] June 10, 2021 GA104-400-A1 6144:192:96:192:48
(48) (6) 		1575 1770 19000 608.3 GDDR6X 151.18
169.9 		302.36
339.8 		19.35
21.75 		0.302
0.340 		19.35
21.75 		154.8
174.0 		43.5 290 $599
GeForce RTX 3080[167][164] September 17, 2020 GA102-200-A1 28.3 628.4 8704:272:96:272:68
(68) (6) 		5 1440 1710 10 760.0 320 138.2
164.2 		391.68
465.12 		25.07
29.77 		0.392
0.465 		25.06
29.76 		200.54
238.14 		59.5 320 $699
January 27, 2022 GA102-220-A1 8960:280:96:280:70
(70) (6) 		6 1260 1710 12 912.0 384 131.0
177.8 		352.8
478.8 		22.6
30.6 		0.353
0.479 		22.6
30.6 		180.6
245.1 		61.3 350 $799
GeForce RTX 3080 Ti[168] June 3, 2021 GA102-225-A1 10240:320:112:320:80
(80) (7) 		1365 1665 153.5
186.5 		438.5
532.8 		28.57
34.1 		0.438
0.533 		28.06
34.10 		228.6
272.8 		68.2 $1199
GeForce RTX 3090[169][164] September 24, 2020 GA102-300-A1 10496:328:112:328:82
(82) (7) 		1395 1695 19500 24 935.8 156.2
189.8 		457.6
555.96 		29.28
35.58 		0.459
0.558 		29.38
35.68 		235.08
285.48 		71.1 2-way NVLink $1499
GeForce RTX 3090 Ti[170][171] March 29, 2022 GA102-350-A1 10752:336:112:336:84
(84) (7) 		1560 1860 21000 1008.3 174.7
208.3 		524.2
625 		33.5
40 		0.524
0.625 		33.5
40 		269.1
320.9 		79.9 450 $1999
  1. ^ Main shader processors : texture mapping unit : render output units : tensor cores : ray-tracing cores (streaming multiprocessors) (graphics processing clusters)

RTX 40 series edit

Further information: GeForce 40 series and Ada Lovelace (microarchitecture)
Model Launch Code name Process Transistors (billion) Die size (mm2) Core config[a] Bus interface L2 Cache (MB) Clock speeds Memory Fillrate Processing power (TFLOPS) Ray-tracing Performance (TFLOPS) TDP (Watts) Release price (USD)
Base core clock (MHz) Boost core clock (MHz) Memory (MT/s) Size (GB) Bandwidth (GB/s) Bus type Bus width (bit) Pixel (GP/s) Texture (GT/s) Single precision Double precision Half precision Tensor compute (FP16) (2:1 sparse) MSRP Founders Edition
GeForce RTX 4060[177] June 29, 2023 AD107-400 TSMC 4N [178] 18.9 158.7 3072:96:48:96:24
(24)(3) 		PCIe 4.0 x8 24 1830 2460 17000 8 272 GDDR6 128 118.1 236.2 11.2
15.1 		0.176
0.236 		11.2
15.1 		60 (121) 35 115 $299
GeForce RTX 4060 Ti[177] May 24, 2023 AD106-350 22.9 187.8 4352:136:48:136:34
(34)(3) 		32 2310 2540 18000 288 121.9 345.4 20.1
22.1 		0.314
0.345 		20.1
22.1 		88 (177) 51 160 $399
July 18, 2023 AD106-351 16 $499
GeForce RTX 4070[179] April 13, 2023 AD104-250 35.8 294.5 5888:184:64:184:46
(46)(4) 		PCIe 4.0 x16 36 1920 2475 21000 12 504 GDDR6X 192 158.4 455.4 22.6
29.1 		0.353
0.455 		22.6
29.1 		117 (233) 67 200 $599
GeForce RTX 4070 Super[180][181] January 17, 2024 AD104-350 7168:224:80:224:56

(56)(5)

48 1980 2475 198.0 554.4 28.39

35.48

0.444

0.554

28.39

35.48

114 (227)

142 (284)

82 220
GeForce RTX 4070 Ti[182] January 5, 2023 AD104-400 7680:240:80:240:60
(60)(5) 		2310 2610 208.8 626.4 35.5
40.1 		0.554
0.627 		35.5
40.1 		142 (284)
160 (321) 		92.7 285 $799
GeForce RTX 4070 Ti Super[181][183] January 24, 2024 AD-103-275 45.9 378.6 8448:264:112:264:66

(66)(6)

2340 2610 21000 16 672 256 292.3 689.0 39.54

44.10

0.618

0.689

39.54

44.10

158 (316)

176 (353)

102
GeForce RTX 4080[184] Unlaunched [185][186] AD104-400 35.8 294.5 7680:240:80:240:60
(60)(5) 		2310 2610 21000 12 504 192 208.8 626.4 35.5

40.1

0.554

0.627

35.5

40.1

142 (284)
160 (321) 		92.7 $899
November 16, 2022 AD103-300 45.9 378.6 9728:304:112:304:76
(76)(7) 		64 2210 2505 22400 16 717 256 280.6 761.5 43.0
48.7 		0.672
0.761 		43.0
48.8 		172 (344)
195 (390) 		112.7 320 $1199
GeForce RTX 4080 Super [187][188] January 31, 2024 AD103-400 10240:320:112:320:80

(80)(7)

2295 2550 23000 736 285.6 816.0 47.0

52.22

0.734

0.816

47.0

52.22

188 (376)

209 (418)

121 $999
GeForce RTX 4090 D[189][190] December 28, 2023 AD102-250 76.3 608.5 14592:456:176:456:114
(114)(11) 		72 2280 2520 21000 24 1008 384 443.5 1149.1 66.5
73.5 		1.040
1.149 		66.5
73.5 		266 (532)
294 (588) 		170 425 12,999
GeForce RTX 4090[191][192] October 12, 2022 AD102-300 16384:512:176:512:128
(128)(11) 		2235 1290.2 73.1
82.6 		1.142
1.291 		73.1
82.6 		292 (585)
330 (661) 		191 450 $1599
  1. ^ Main shader processors : texture mapping unit : render output units : tensor cores : ray-tracing cores (streaming multiprocessors) (graphics processing clusters)

Mobile GPUs edit

Mobile GPUs are either soldered to the mainboard or to some Mobile PCI Express Module (MXM).

GeForce2 Go series edit

Model Launch Code name Bus interface Core clock (MHz) Memory clock (MHz) Core config[a] Fillrate Memory
MOperations/s MPixels/s MTexels/s MVertices/s Size (MB) Bandwidth (GB/s) Bus type Bus width (bit)
GeForce2 Go 100 February 6, 2001 NV11M AGP 4x 125 332 2:0:4:2 250 250 500 0 8, 16 1.328 DDR 32
GeForce2 Go November 11, 2000 143 166
332 		286 286 572 16, 32 2.656 SDR
DDR 		128
64
GeForce2 Go 200 February 6, 2001 332 DDR 64
  1. ^ Pixel shaders: vertex shaders: texture mapping units: render output units

GeForce4 Go series edit

  • All models are made via 150 nm fabrication process
Model Launch Code name Bus interface Core clock (MHz) Memory clock (MHz) Core config[a] Fillrate Memory API support
MOperations/s MPixels/s MTexels/s MVertices/s Size (MB) Bandwidth (GB/s) Bus type Bus width (bit) Direct3D OpenGL
GeForce4 Go 410 February 6, 2002 NV17M AGP 8x 200 200 2:0:4:2 400 400 800 0 16 1.6 SDR 64 8.0a 1.3
GeForce4 Go 420 400 32 3.2 DDR
GeForce4 Go 440 220 440 440 440 880 64 7.04 128
GeForce4 Go 460 October 14, 2002 250 500 500 500 1000 8
GeForce4 Go 488 NV18M 300 550 600 600 1200 8.8
GeForce4 Go 4200 November 14, 2002 NV28M 200 400 4:2:8:4 800 800 1600 100 6.4
  1. ^ Pixel shaders: vertex shaders: texture mapping units: render output units

GeForce FX Go 5 (Go 5xxx) series edit

The GeForce FX Go 5 series for notebooks architecture.

Model Launch Code name Fab (nm) Bus interface Core clock (MHz) Memory clock (MHz) Core config1 Fillrate Memory Supported API version TDP (Watts)
Pixel (GP/s) Texture (GT/s) Size (MB) Bandwidth (GB/s) Bus type Bus width (bit) Direct3D OpenGL
Hardware Drivers (Software)
GeForce FX Go 5100* March 2003 NV34M 150 AGP 8x 200 400 4:2:4:4 0.8 0.8 64 3.2 DDR 64 9.0 1.5 2.1** Un­known
GeForce FX Go 5500* 300 600 1.2 1.2 32
64 		9.6 128 Un­known
GeForce FX Go 5600* NV31M 130 350 1.4 1.4 32 Un­known
GeForce FX Go 5650* 350 Un­known
GeForce FX Go 5700* February 1, 2005 NV36M 450 550 4:3:4:4 1.8 1.8 8.8 Un­known

GeForce Go 6 (Go 6xxx) series edit

Model Launch Code name Fab (nm) Bus interface Core clock (MHz) Memory clock (MHz) Core config1 Fillrate Memory
MOperations/s MPixels/s MTexels/s MVertices/s Size (MB) Bandwidth (GB/s) Bus type Bus width (bit)
GeForce Go 6100 + nForce Go 430 Un­known C51M 110 HyperTransport 425 System memory 2:1:2:1 850 425 850 106.25 Up to 128 MB system System memory DDR2 64/128
GeForce Go 6150 + nForce Go 430 February 1, 2006
GeForce Go 6200 February 1, 2006 NV44M PCIe x16 300 600 4:3:4:2 1200 600 1200 225 16 2.4 DDR 32
GeForce Go 6400 February 1, 2006 400 700 1600 800 1600 250 5.6 64
GeForce Go 6600 September 29, 2005 NV43M 300 8:3:8:4 3000 1500 3000 281.25 128 11.2 128
GeForce Go 6800 November 8, 2004 NV41M 130 700
1100 		12:5:12:12 375 22.4
35.2 		DDR, DDR2
DDR3 		256
GeForce Go 6800 Ultra February 24, 2005 450 5400 3600 5400 562.5 256

GeForce Go 7 (Go 7xxx) series edit

The GeForce Go 7 series for notebooks architecture.

Model Launch Code name Fab (nm) Bus interface Core clock (MHz) Memory clock (MHz) Core config1 Fillrate Memory Supported API version TDP (Watts) Features
Pixel (GP/s) Texture (GT/s) Size (MB) Bandwidth (GB/s) Bus type Bus width (bit) Direct3D OpenGL
GeForce 7000M February 1, 2006 MCP67MV 90 Hyper Transport 350 System memory 1:2:2:2 0.7 0.7 Up to 256 from system memory System memory DDR2 64/128 9.0c 2.1 Un­known
GeForce 7150M MCP67M 425 0.85 0.85 Un­known
GeForce Go 72002 January 2006 G72M PCIe x16 450 700 3:4:4:1 0.45 1.8 64 2.8 GDDR3 32 Un­known Transparency Anti-Aliasing
GeForce Go 73002 350 3:4:4:2 0.7 1.4 128, 256, 512 5.60 64 Un­known
GeForce Go 74002 450 900 0.9 1.8 64, 256 7.20 Un­known
GeForce Go 7600 March 2006 G73M 1000 5:8:8:8 3.6 3.6 256, 512 16 128 Un­known Scalable Link Interface (SLI), Transparency Anti-Aliasing
GeForce Go 7600 GT 2006 500 1200 5:12:12:8 4 6 256 19.2 Un­known
GeForce Go 7700 G73-N-B1 80 450 1000 3.6 5.4 512 16 Un­known
GeForce Go 7800 March 3, 2006 G70M 110 400 1100 6:16:16:8 3.2 6.4 256 35.2 256 35
GeForce Go 7800 GTX October 2005 8:24:24:16 6.4 9.6 65
GeForce Go 7900 GS April 2006 G71M 90 375 1000 7:20:20:16 6 7.5 32.0 20
GeForce Go 7900 GTX 500 1200 8:24:24:16 8 12 256 512 38.4 45
GeForce Go 7950 GTX October 2006 575 1400 9.2 13.8 512 44.8

GeForce 8M (8xxxM) series edit

The GeForce 8M series for notebooks architecture Tesla.

Model Launch Code name Fab (nm) Bus interface Core config1 Clock speed Fillrate Memory Supported API version Processing power (GFLOPS) TDP (Watts) Notes
Core (MHz) Shader (MHz) Memory (MHz) Pixel (GP/s) Texture (GT/s) Size (MB) Bandwidth (GB/s) Bus type Bus width (bit) Direct3D OpenGL
GeForce 8200M G[193] June 2008 MCP77MV, MCP79MVL 80 Integrated (PCIe 2.0 x16) 8:8:4 400 800 800
1066
(system memory) 		1.6 3.2 Up to 256 from system memory 12.8
17.056 		DDR2
DDR3 		128 10.0 3.3 19.2 Un­known PureVideo HD with VP3, Full H.264 / VC-1 / MPEG-2 HW Decode
GeForce 8400M G May 2007 NB8M(G86) PCIe x16 800 128 / 256 6.4 DDR2 / GDDR3 64 10 PureVideo HD with VP2, BSP Engine, and AES128 Engine
GeForce 8400M GS 16:8:4 38.4 11
GeForce 8400M GT 450 900 1200 1.8 3.6 256 / 512 19.2 128 43.2 14
GeForce 8600M GS NB8P(G84) 600 1200 1400 2.4 4.8 22.4 57.6 20
GeForce 8600M GT 32:16:8 475 950 800 / 1400 3.8 7.6 12.8 / 22.4 91.2
GeForce 8700M GT June 2007 625 1250 1600 5 10 25.6 GDDR3 120 29 Scalable Link Interface, PureVideo HD with VP2, BSP Engine, and AES128 Engine
GeForce 8800M GTS November 2007 NB8P(G92) 65 PCIe 2.0 x16 64:32:16 500 8 16 512 51.2 256 240 50
GeForce 8800M GTX 96:48:16 24 360 65

GeForce 9M (9xxxM) series edit

The GeForce 9M series for notebooks architecture. Tesla (microarchitecture)

Model Launch Code name Fab (nm) Bus interface Core config1 Clock speed Fillrate Memory Supported API version Processing power (GFLOPS) TDP (Watts) Notes
Core (MHz) Shader (MHz) Memory (MHz) Pixel (GP/s) Texture (GT/s) Size (MB) Bandwidth (GB/s) Bus type Bus width (bit) Direct3D OpenGL
GeForce 9100M G
mGPU 		2008 MCP77MH, MCP79MH 65 Integrated
(PCIe 2.0 x16) 		8:8:4 450 1100 1066
(system memory) 		1.8 3.6 Up to 256 from system memory 17.056 DDR3 128 10.0 3.3 26.4 12 Similar to 8400M G
GeForce 9200M GS NB9M-GE(G98) PCIe 2.0 x16 550 1300 1400 2.2 4.4 256 11.2 DDR2/GDDR3 64 31.2 13
GeForce 9300M G NB9M-GE(G86) 80 16:8:4 400 800 1200 1.6 3.2 256/512 9.6 38.4
GeForce 9300M GS NB9M-GE(G98) 65 8:8:4 550 1400 1400 2.2 4.4 11.2 33.6
GeForce 9400M G October 15, 2008 MCP79MX Integrated(PCIe 2.0 x16) 16:8:4 450 1100 800
1066
(system memory) 		1.8 3.6 Up to 256 from system memory 12.8
17.056 		DDR2
DDR3 		128 54 12 PureVideo HD with VP3. Known as the GeForce 9400M in Apple systems[194] and Nvidia ION based systems
GeForce 9500M G 2008 NB9P(G96) PCIe 2.0 x16 16:8:8 500 1250 1600 4 4 512 25.6 DDR2 / GDDR3 60 20
GeForce 9500M GS NB9P-GV(G96) 80 PCIe x16 32:16:8 475 950 1400 3.8 7.6 22.4 91.2 Rebranded 8600M GT
GeForce 9600M GS NB9P-GE2(G96) 65 PCIe 2.0 x16 430 1075 800
1600 		3.44 6.88 1024 12.8
25.6 		103.2
GeForce 9600M GT NB9P-GS(G96) 500 1250 1600 4 8 512/1024 25.6 120 23
GeForce 9650M GS NB9P-GS1(G84) 80 625 5 10 512 GDDR3 29 Rebranded 8700M GT
GeForce 9650M GT NB9P-GT(G96) 65/55 550 1325 4.4 8.8 1024 127.2 23
GeForce 9700M GT July 29, 2008 NB9E-GE(G96) 65 PCIe x16 625 1550 5 10 512 148.8 45
GeForce 9700M GTS NB9E-GS(G94) PCIe 2.0 x16 48:24:16 530 1325 8.48 12.7 51.2 256 190.8 60
GeForce 9800M GS 2008 NB9E-GT(G94) 64:32:16 8.48 16.96 254 Down Clocked 9800M GTS Via Firmware
GeForce 9800M GTS July 29, 2008 65/55 64:32:16 600 1500 9.6 19.2 512 / 1024 288 75
GeForce 9800M GT NB9E-GT2(G92) 96:48:16 500 1250 8 24 512 360 65 Rebranded 8800M GTX
GeForce 9800M GTX NB9E-GTX(G92) 65 112:56:16 28 1024 420 75
Model Launch Code name Fab (nm) Bus interface Core config1 Core (MHz) Shader (MHz) Memory (MHz) Pixel (GP/s) Texture (GT/s) Size (MB) Bandwidth (GB/s) Bus type Bus width (bit) Direct3D OpenGL Processing power (GFLOPS) TDP (Watts) Notes
Clock speed Fillrate Memory Supported API version

GeForce 100M (1xxM) series edit

The GeForce 100M series for notebooks architecture. Tesla (microarchitecture) (103M, 105M, 110M, 130M are rebranded GPU i.e. using the same GPU cores of previous generation, 9M, with promised optimisation on other features)

Model Launch Code name Fab (nm) Bus interface Core config1 Clock speed Fillrate Memory Supported API version Processing power (GFLOPS) TDP (Watts) Notes
Core (MHz) Shader (MHz) Memory (MHz) Pixel (GP/s) Texture (GT/s) Size (MB) Bandwidth (GB/s) Bus type Bus width (bit) Direct3D OpenGL
GeForce G 102M January 8, 2009 MCP79XT 65 Integrated
(PCIe 1.0 x16) 		16:8:4 450? 1000 800
(system memory) 		1.8 3.6 Up to 512 from system memory 6.4 DDR2 64 10.0 3.3 48 14 PureVideo HD, CUDA, Hybrid SLI, based on GeForce 9400M G
GeForce G 103M January 1, 2009 N10M-GE2(G98) PCIe 2.0 x16 8:8:4 640 1600 1000 2.56 5.12 512 8 38 PureVideo HD, CUDA, Hybrid SLI, comparable to the GeForce 9300M GS
GeForce G 105M January 8, 2009 N10M-GE1(G98) 1000
1400 		8
11 		GDDR2
GDDR3 		38
GeForce G 110M N10M-GE1(G96b) 55 16:8:4 400 1000 1000
1400 		1.6 3.2 1024 8
11 		DDR2
GDDR3 		48 PureVideo HD, CUDA, Hybrid SLI
GeForce GT 120M February 11, 2009 N10P-GV1(G96b) 32:16:8 500 1250 1000 4 8 16 DDR2 128 110 23 PureVideo HD, CUDA, Hybrid SLI, Comparable to the 9500M GT and 9600M GT DDR2 (500/1250/400)
GeForce GT 130M January 8, 2009 N10P-GE1(G96b) 600 1500 1000
1600 		4.8 9.6 16
25.6 		DDR2
GDDR3 		144 PureVideo HD, CUDA, Hybrid SLI, comparable to the 9650M GT
GeForce GTS 150M March 3, 2009 N10E-GE1(G94b) 64:32:16 400 1000 1600 6.4 12.8 51.2 GDDR3 256 192 Un­known PureVideo HD, CUDA, Hybrid SLI
GeForce GTS 160M N10E-GS1(G94b) 600 1500 9.6 19.2 288 60

GeForce 200M (2xxM) series edit

The GeForce 200M series is a graphics processor architecture for notebooks, Tesla (microarchitecture)

Model Launch Code name Fab (nm) Bus interface Core config1 Clock speed Fillrate Memory Supported API version Processing power (GFLOPS) TDP (Watts) Notes
Core (MHz) Shader (MHz) Memory (MHz) Pixel (GP/s) Texture (GT/s) Size (MB) Bandwidth (GB/s) Bus type Bus width (bit) Direct3D OpenGL
GeForce G210M June 15, 2009 GT218 40 PCIe 2.0 x16 16:8:4 625 1500 1600 2.5 5 512 12.8 GDDR3 64 10.1 3.3 72 14 Lower clocked versions of the GT218 core is also known as Nvidia ION 2
GeForce GT 220M 2009 G96b 55 32:16:8 500 1250 1000
1600 		4 8 1024 16
25.6 		DDR2
GDDR3 		128 120 rebranded 9600M GT @55 nm node shrink
GeForce GT 230M June 15, 2009 GT216 40 48:16:8 1100 1600 25.6 GDDR3 158 23
GeForce GT 240M 550 1210 4.4 8.8 174
GeForce GTS 250M GT215 96:32:8 500 1250 3200 4 16 51.2 GDDR5 360 28
GeForce GTS 260M GT215 550 1375 3600 4.4 17.6 57.6 396 38
GeForce GTX 260M March 3, 2009 G92b 55 112:56:16 1900 8.8 30.8 60.8 GDDR3 256 462 65
GeForce GTX 280M 128:64:16 585 1463 9.36 37.44 562 75
GeForce GTX 285M February 2010 600 1500 2000 9.6 38.4 64.0 576 Higher Clocked Version of GTX280M with new memory

GeForce 300M (3xxM) series edit

The GeForce 300M series for notebooks architecture, Tesla (microarchitecture)

Model Launch Code name Fab (nm) Bus interface Core config1 Clock speed Fillrate Memory Supported API version Processing power (GFLOPS)2 TDP (Watts)
Core (MHz) Shader (MHz) Memory (MHz) Pixel (GP/s) Texture (GT/s) Size (MB) Bandwidth (GB/s) Bus type Bus width (bit) Direct3D OpenGL
GeForce 305M January 10, 2010 GT218 40 PCIe 2.0 x16 16:8:4 525 1150 1400 2.1 4.2 512 11.2 DDR3
GDDR3 		64 10.1 3.3 55 14
GeForce 310M 625 1530 1600 2.5 5 12.8 73
GeForce 315M January 5, 2011 606 1212 2.42 4.85 58.18
GeForce 320M April 1, 2010 MCP89 48:16:8 450 950 1066 3.6 7.2 256 (shared w/ system memory)
[195] 		17.056 DDR3 128 136.8 20
GeForce GT 320M January 21, 2010 GT216 24:8:8 500 1100 1580 4 4 1024 25.3 DDR3
GDDR3 		90 14
GeForce GT 325M January 10, 2010 48:16:8 450 990 1600 3.6 7.2 25.6 142 23
GeForce GT 330M 575 1265 4.6 9.2 182
GeForce GT 335M January 7, 2010 GT215 72:24:8 450 1080 3.6 10.8 233 28?
GeForce GTS 350M 96:32:8 500 1249 3200 4 16 51.2 DDR3
GDDR3
GDDR5 		360 28
GeForce GTS 360M 1436 3600 4.4 17.6 57.6 413 38

GeForce 400M (4xxM) series edit

The GeForce 400M series for notebooks architecture, Fermi (microarchitecture)

  • 1 Unified shaders: texture mapping units: render output units
  • 2 To calculate the processing power see Fermi (microarchitecture)#Performance.
  • 3 Each SM in the GF100 also contains 4 texture address units and 16 texture filtering units. Total for the full GF100 64 texture address units and 256 texture filtering units.[60] Each SM in the GF104/106/108 architecture contains 8 texture filtering units for every texture address unit. The complete GF104 die contains 64 texture address units and 512 texture filtering units, the complete GF106 die contains 32 texture address units and 256 texture filtering units and the complete GF108 die contains 16 texture address units and 128 texture filtering units.
Model Launch Code name Fab (nm) Bus interface Core config1 Clock speed Fillrate Memory Supported API version Processing power (GFLOPS)2 TDP (Watts) Notes
Core (MHz) Shader (MHz) Memory (MHz) Pixel (GP/s) Texture (GT/s) Size (MB) Bandwidth (GB/s) Bus type Bus width (bit) Direct3D OpenGL
GeForce 410M January 5, 2011 GF119 40 PCIe 2.0 x16 48:83:4 575 1150 1600 2.3 4.6 512 and 1024 12.8 DDR3 64 12 4.5 110.4 12 Similar to Desktop GT420 OEM
GeForce GT 415M September 3, 2010 GF108 500 1000 2 4 25.6 128 96 <12(GPU only)[196]
GeForce GT 420M 96:163:4 8 192 10–23(GPU only)[196] Similar to Desktop GT430
GeForce GT 425M 560 1120 2.24 8.96 1024 215.04 20–23(GPU only)[196]
GeForce GT 435M 650 1300 2.6 10.4 2048 249.6 32–35(GPU only)[196] Similar to Desktop GT430/440
GeForce GT 445M GF106 144:243:16
144:243:24 		590 1180 1600
2500 		9.44
14.16 		14.16 1024
1536 		25.6
60 		DDR3
GDDR5 		128
192 		339.84 30–35(GPU only)[196] Similar to Desktop GTS450 OEM)
GeForce GTX 460M 192:323:24 675 1350 2500 16.2 21.6 1536 60 GDDR5 192 518.4 45–50(GPU only)[196] Similar to Desktop GTX550 Ti
GeForce GTX 470M GF104 288:483:24 550 1100 13.2 26.4 633.6 Similar to Desktop GTX 460/560SE
GeForce GTX 480M May 25, 2010 GF100 352:443:32 425 850 2400 13.6 18.7 2048 76.8 256 598.4 100(MXM module) Similar to Desktop GTX465
GeForce GTX 485M January 5, 2011 GF104 384:643:32 575 1150 3000 18.4 36.8 96.0 883.2 Similar to Desktop GTX560 Ti

GeForce 500M (5xxM) series edit

The GeForce 500M series for notebooks architecture.

Model Launch Code name Fab (nm) Bus interface Core config1 Clock speed Fillrate Memory Supported API version Processing power (GFLOPS)2 TDP (Watts) Notes
Core (MHz) Shader (MHz) Memory (MHz) Pixel (GP/s) Texture (GT/s) Size (MB) Bandwidth (GB/s) Bus type Bus width (bit) Direct3D OpenGL
GeForce GT 520M January 5, 2011 GF119 40 PCIe 2.0 x16 48:8:4 740 1480 1600 2.96 5.92 1024 12.8 DDR3 64 12 4.6 142.08 12 Similar to Desktop 510/520
GeForce GT 520M GF108 96:16:4 515 1030 2.06 8.24 197.76 20 Noticed in Lenovo laptops, similar to Desktop 530/430/440
GeForce GT 520MX May 30, 2011 GF119 48:8:4 900 1800 1800 3.6 7.2 14.4 172.8 Similar to Desktop 510 & GT520
GeForce GT 525M January 5, 2011 GF108 96:16:4 600 1200 2.4 9.6 28.8 128 230.4 20–23 Similar to Desktop GT 530/430/440
GeForce GT 540M 672 1344 2.688 10.752 2048
1024 		258.048 32–35 Similar to Desktop GT 530/440
GeForce GT 550M GF108
GF1062 		96:16:4
144:24:162 		740
475 		1480
950 		1800
1800 		2.96 11.84 1024 284.16
312.6
GeForce GT 555M GF106

GF108 		144:24:24
144:24:16
96:16:4 		590
650
753 		1180
1300
1506 		1800
1800
3138 		14.6
10.4
3 		14.6
15.6
12 		1536
2048
1024 		43.2
28.8
50.2 		DDR3
DDR3
GDDR5 		192
128
128 		339.84
374.4
289.15 		30–35 Similar to Desktop GT545
GeForce GTX 560M May 30, 2011 GF116 192:32:16
192:32:24 		775 1550 2500 18.6 24.8 2048
1536, 3072 		40.0
60.0 		GDDR5 128
192 		595.2 75 Similar to Desktop GTX 550Ti
GeForce GTX 570M[197] June 28, 2011 GF114 336:56:24 575 1150 3000 13.8 32.2 1536 72.0 192 772.8 Similar to Desktop GTX 560
GeForce GTX 580M 384:64:32 620 1240 19.8 39.7 2048 96.0 256 952.3 100 Similar to Desktop GTX 560 Ti

GeForce 600M (6xxM) series edit

Further information: GeForce 600 series

The GeForce 600M series for notebooks architecture. The processing power is obtained by multiplying shader clock speed, the number of cores, and how many instructions the cores can perform per cycle.

Model Launch Code name Fab (nm) Bus interface Core config1 Clock speed Fillrate Memory Supported API version Processing power (GFLOPS)2 TDP (Watts) Notes
Core (MHz) Shader (MHz) Memory (MT/s) Pixel (GP/s) Texture (GT/s) Size (MB) Bandwidth (GB/s) Bus type Bus width (bit) Vulkan Direct3D OpenGL
GeForce 610M[198] December 2011 GF119 (N13M-GE) 40 PCIe 2.0 x16 48:8:4 900 1800 1800 3.6 7.2 1024
2048 		14.4 DDR3 64 n/a 12 4.5 142.08 12 OEM. Rebadged GT 520MX
GeForce GT 620M[199] April 2012 GF117 (N13M-GS) 28 96:16:4 625 1250 1800 2.5 10 14.4
28.8 		64
128 		240 15 OEM. Die-Shrink GF108
GeForce GT 625M October 2012 14.4 64
GeForce GT 630M[199][200][201] April 2012 GF108 (N13P-GL)
GF117 		40
28 		660
800 		1320
1600 		1800
4000 		2.6
3.2 		10.7
12.8 		28.8
32.0 		DDR3
GDDR5 		128
64 		258.0
307.2 		33 GF108: OEM. Rebadged GT 540M
GF117: OEM Die-Shrink GF108
GeForce GT 635M[199][202][203] GF106 (N12E-GE2)
GF116 		40 144:24:24 675 1350 1800 16.2 16.2 2048
1536 		28.8
43.2 		DDR3 128
192 		289.2
388.8 		35 GF106: OEM. Rebadged GT 555M
GF116: 94% of desktop GT640[original research?]
GeForce GT 640M LE[199] March 22, 2012 GF108
GK107 (N13P-LP) 		40
28 		PCIe 2.0 x16
PCIe 3.0 x16 		96:16:4

384:32:16
(2 SMX) 		762
500 		1524
500 		3130
1800 		3
8 		12.2
16 		1024
2048 		50.2
28.8 		DDR3

GDDR5

128 1.2 292.6
384 		32
20 		GF108: 94% of desktop GT630[original research?]
GK107: 47% of desktop GTX650[original research?]
GeForce GT 640M[199][204] GK107 (N13P-GS) 28 PCIe 3.0 x16 384:32:16
(2 SMX) 		625 625 1800
4000 		10 20 28.8
64.0 		480 32 59% of desktop GTX650[original research?]
GeForce GT 645M October 2012 710 710 1800
4000 		11.36 22.72 545 67% of desktop GTX650[original research?]
GeForce GT 650M[199][205][206] March 22, 2012 GK107 (N13P-GT) 745
835
900* 		835
950
900* 		1800
4000
5000* 		11.9
13.4
14.4* 		23.8
26.7
28.8* 		512
1024
2048 		28.8
64.0
80.0* 		11.2 572.2
641.3
691.2* 		45 79% of desktop GTX650[original research?]
GeForce GTX 660M[199][206][207][208] GK107 (N13E-GE) 835 950 5000 15.2 30.4 2048 80.0 GDDR5 729.6 50 79% of desktop GTX650[original research?]
GeForce GTX 670M[199] April 2012 GF114 (N13E-GS1-LP) 40 PCIe 2.0 x16 336:56:24 620 1240 3000 14.35 33.5 1536
3072 		72.0 192 n/a 12 833 75 73% of desktop GTX 560[original research?]
GeForce GTX 670MX October 2012 GK104 (N13E-GR) 28 PCIe 3.0 x16 960:80:24
(5 SMX) 		615 615 2800 14.4 48.0 67.2 1.2 1181 61% of desktop GTX 660[original research?]
GeForce GTX 675M[199] April 2012 GF114 (N13E-GS1) 40 PCIe 2.0 x16 384:64:32 632 1265 3000 19.8 39.7 2048 96.0 256 n/a 972 100 75% of desktop GTX 560Ti[original research?]
GeForce GTX 675MX October 2012 GK104 (N13E-GSR) 28 PCIe 3.0 x16 960:80:32
(5 SMX) 		667 667 3600 19.2 48.0 4096 115.2 1.2 1281 61% of desktop GTX 660[original research?]
GeForce GTX 680M June 4, 2012 GK104 (N13E-GTX) 1344:112:32
(7 SMX) 		719 719 23 80.6 1933 78% of desktop GTX 670[original research?]
GeForce GTX 680MX October 23, 2012 GK104 1536:128:32
(8 SMX) 		5000 92.2 160 2209 122 72% of desktop GTX 680[original research?]
Model Launch Code name Fab (nm) Bus interface Core config1 Clock speed Fillrate Memory Supported API version Processing power (GFLOPS)2 TDP (Watts) Notes
Core (MHz) Shader (MHz) Memory (MT/s) Pixel (GP/s) Texture (GT/s) Size (MB) Bandwidth (GB/s) Bus type Bus width (bit) Vulkan Direct3D OpenGL

GeForce 700M (7xxM) series edit

Further information: GeForce 700 series

The GeForce 700M series for notebooks architecture. The processing power is obtained by multiplying shader clock speed, the number of cores, and how many instructions the cores can perform per cycle.

Model Launch Code name Fab (nm) Bus interface Core config1 Clock speed Fillrate Memory Supported API version Processing power (GFLOPS)2 TDP (Watts) Notes
Core (MHz) Shader (MHz) Memory (MT/s) Pixel (GP/s) Texture (GT/s) Size (MB) Bandwidth (GB/s) Bus type Bus width (bit) Vulkan Direct3D OpenGL CUDA
GeForce 710M January 2013 GF117 28 PCIe 2.0 x16 96:16:4 800 1600 1800 3.2 12.8 1024
2048 		14.4 DDR3 64 n/a 12 4.5 2.1 [209] 307.2 12 OEM. About 115% of Mobile 620 & Desktop 530[original research?]
GeForce 710M July 24, 2013 GK208 PCIe 3.0 x8 192:16:8 719 ? 5.752 11.5 1024 1.2 3.5 [210] 276.1 15 Kepler, similar to 730M with half of the cores disabled
GeForce GT 720M April 1, 2013 GF117 PCIe 2.0 x16 96:16:4 938 1876 2000 3.8 15.0 2048 16.0 n/a 2.1 [209] 360.19 ? OEM. About 130% of Mobile 625/630 & Desktop 620[original research?]
GeForce GT 720M December 25, 2013 GK208 PCIe 2.0 x8 192:16:8 719 3.032 12.13 12.8 1.2 3.5 [210] 291 22 Kepler, similar to 730M with half of the cores disabled
GeForce GT 730M January 2013 GK208 PCIe 3.0 x8 384:32:8
(2 SMX) 		719 5.8 23.0 16.0 128 552.2 33 Kepler, similar to Desktop GT640
GeForce GT 735M April 1, 2013 889 7.11 28.4 64 682.8 ? Kepler, similar to Desktop GT640
GeForce GT 740M 980 1800 7.84 31.4 14.4 752.6 Kepler, similar to Desktop GT640.
GeForce GT 740M GK107 PCIe 3.0 x16 384:32:16
(2 SMX) 		810[211] 1800
5000 		12.96 25.92 2048[211] 28.8
80 		DDR3
GDDR5[211] 		128 3.0 [209] 622.1 45 about 76% of Desktop GTX650[original research?]
GeForce GT 745M 837 2000
5000 		13.4 26.8 2048 32
80 		DDR3
GDDR5 		642.8 about 79% of Desktop GTX650[original research?]
GeForce GT 750M 967 15.5 30.9 742.7 50 about 91% of Desktop GTX650[original research?]
GeForce GT 755M[212] ? 1020 5400 15.7 31.4 86.4 GDDR5 783 about 93% of Desktop GTX650[original research?]
GeForce GTX 760M May 2013 GK106 768:64:16
(4 SMX) 		719 4000 10.5 42.1 64 1104 55 about 71% of Desktop GTX 650Ti[original research?]
GeForce GTX 765M 863 13.6 54.4 1326 65 about 92% of Desktop GTX 650Ti[original research?]
GeForce GTX 770M 960:80:24
(5 SMX) 		797 19.5 64.9 3072 96 192 1530 75 about 83% of Desktop GTX660[original research?]
GeForce GTX 780M GK104 1536:128:32
(8 SMX) 		5000 26.3 105.3 4096 160 256 2448 122 about 78% of Desktop GTX770[original research?]
Model Launch Code name Fab (nm) Bus interface Core config1 Clock speed Fillrate Memory Supported API version Processing power (GFLOPS)2 TDP (Watts) Notes
Core (MHz) Shader (MHz) Memory (MT/s) Pixel (GP/s) Texture (GT/s) Size (MB) Bandwidth (GB/s) Bus type Bus width (bit) Vulkan Direct3D OpenGL CUDA

GeForce 800M (8xxM) series edit

Further information: GeForce 800M series

The GeForce 800M series for notebooks architecture. The processing power is obtained by multiplying shader clock speed, the number of cores, and how many instructions the cores can perform per cycle.

Model Launch Code name Fab (nm) Bus interface Core config1 Clock speed Fillrate Memory Supported API version Processing power (GFLOPS)2 TDP (Watts) Notes (original research)
Core (MHz) Shader (MHz) Memory (MT/s) Pixel (GP/s) Texture (GT/s) Size (GB) Bandwidth (GB/s) Bus type Bus width (bit) Vulkan Direct3D OpenGL CUDA Compute Capability
GeForce 810M February 2014 GF117 28 PCIe 2.0 x16 48:8:4 738–888 1476–1776 1800 2.95–3.55 5.9–7.1 1 14.4 DDR3 64 n/a 12 4.5 2.1 [209] 141.7–170.5 15
GeForce 820M[213] 96:16:4 719–954 1438–1908 2000 2.9–3.8 11.5–15.3 2 16 276.1–366.3 15[214] 115% of 620 (Fermi)
GeForce 825M[215] January 27, 2014 GK208 PCIe 3.0 x8 384:16:8
(2 SMX) 		850 1800 6.8 13.6 14.4 1.2 3.5 [210] 652.8 33 94% of 630 (Kepler)
GeForce 830M[216] March 12, 2014 GM108 PCIe 3.0 x16 256:16:8
(2 SMM) 		1029 8.2 16.5 14.4 1.3 5.0[209] 526.8 ~25 50% of 750 (Maxwell)
GeForce 840M[217] 384:24:8
(3 SMM) 		2000 8.2 24.7 2–4 16 790.3 30 50–80% of 745 (Maxwell)
GeForce 845M[218][219] February 7, 2015[220] 384:32:16
(3 SMM) 		1071-1150 5000 18.8 37.6 2 40 GDDR5 903.2 33
August 16, 2015[221] GM107 512:32:16
(4 SMM) 		863 2000 13.8 27.6 16 DDR3 883.7 45
GeForce GTX 850M[222] March 12, 2014 640:40:16
(5 SMM) 		876+Boost 5000 14.0 35.0 2-4 80.2 GDDR5 128 1121.3 40 80% of 750Ti
936+Boost 2000 15.0 37.4 32 DDR3 1198.1 85% of 750Ti
GeForce GTX 860M[223] 640:40:16
(5 SMM) 		1029–1085 5000 16.5 41.2 2 80 GDDR5 1389 40–45 equal to 750Ti
GK104 1152:96:16
(6 SMX) 		797–915 12.8 76.5 4 1.2 3.0[209] 2108 75 similar to 660 OEM.
GeForce GTX 870M[224] 1344:112:24
(7 SMX) 		941–967 22.6 105.4 3, 6 120 192 2599 110 105% of 660Ti
GeForce GTX 880M[225] 1536:128:32
(8 SMX) 		954–993 30.5 122.1 4, 8 160 256 3104 130 90% of 770
Model Launch Code name Fab (nm) Bus interface Core config1 Clock speed Fillrate Memory Supported API version Processing power (GFLOPS)2 TDP (Watts) Notes (original research)
Core (MHz) Shader (MHz) Memory (MT/s) Pixel (GP/s) Texture (GT/s) Size (GB) Bandwidth (GB/s) Bus type Bus width (bit) Vulkan Direct3D OpenGL CUDA Compute Capability

GeForce 900M (9xxM) series edit

Further information: GeForce 900 series

The GeForce 900M series for notebooks architecture. The processing power is obtained by multiplying shader clock speed, the number of cores, and how many instructions the cores can perform per cycle.

Model Launch Code name Fab (nm) Bus interface Core config1 Clock speed Fillrate Memory Supported API version Processing power (GFLOPS)2 TDP (Watts) Notes
Min (MHz) Average (MHz) Memory (MT/s) Pixel (GP/s) Texture (GT/s) Size (GB) Bandwidth (GB/s) Bus type Bus width (bit) Vulkan Direct3D OpenGL OpenCL
GeForce 910M March 13,

2015

GK208B 28 PCIe 3.0 x8 384:32:8

(2 SMX)

641 5.128 20.51 2 16.02 DDR3 64 1.2 12 (11_0) 4.6 1.2 492.3 33
GeForce 920M March 12, 2015 GK208 28 PCIe 3.0 x16 384:32:8
(2 SMX) 		954 Un­known 1800 7.6 30.5 2 14.4 DDR3 64 1.2 12 (11_0) 4.6 1.2 733 33
GeForce 930M GM108 384:24:8
(3 SMM) 		928 941 7.4 22.3 1.3 713 29[226]
GeForce 940M 1072 1176 2000 8.6 25.7 16 823 36[227]
GeForce 940MX January, 2016[228] 1004 1242 9.9 29.8 954 23
June 28, 2016[229] GM107 512:32:8
(4 SMM) 		795 861 5000 6.9 27.6 40 GDDR5 882
GeForce GTX 950M March 12, 2015 640:40:16
(5 SMM) 		914 Un­known 14.6 36.6 2, 4 80 128 1170 Un­known Similar core config to GTX 750 Ti (GM107-400-A2)
2000 32 DDR3 55[230]
GeForce GTX 960M 1097 1176 5000 17.5 43.8 80 GDDR5 1403 65[231]
GeForce GTX 965M[232] January 5, 2015 GM204 1024:64:32
(8 SMM) 		944 Un­known 30.2 60.4 12 (12_1) 1933 60[233] Similar core config to GTX 960 (GM206-300)
GeForce GTX 970M[234] October 7, 2014 1280:80:48
(10 SMM) 		993 44.4 73.9 3, 6 120 192 2365 75 Similar core config to GTX 960 OEM (GM204)
GeForce GTX 980M[235] 1536:96:64
(12 SMM) 		1038 1127 66.4 99.6 4, 8 160 256 3189 100 Similar core config to GTX 970 (GM204-200) with one SMM disabled
GeForce GTX 980[236] September 22, 2015 2048:128:64
(16 SMM) 		1064 Un­known 7010 68.1 136.2 8 224 4358 165, oc to 200 Similar to Desktop GTX 980
Model Launch Code name Fab (nm) Bus interface Core config1 Clock speed Fillrate Memory Supported API version Processing power (GFLOPS)2 TDP (Watts) Notes
Min (MHz) Average (MHz) Memory (MT/s) Pixel (GP/s) Texture (GT/s) Size (GB) Bandwidth (GB/s) Bus type Bus width (bit) Vulkan Direct3D OpenGL OpenCL

GeForce 10 series edit

Further information: GeForce 10 series and Pascal (microarchitecture)
Model Launch Code name Fab (nm) Transistors (billion) Die size (mm2) Bus interface Core config Clock speeds Fillrate Memory Supported API version Processing power (GFLOPS) TDP (Watts) SLI support
Base core clock (MHz) Boost core clock (MHz) Memory (MT/s) Pixel (GP/s) Texture (GT/s) Size (GB) Bandwidth (GB/s) Bus type Bus width (bit) DirectX OpenGL Vulkan OpenCL Single precision (Boost) Double precision Half precision
GeForce GTX 1050 (Notebook)[237][238] January 3, 2017 GP107(N17P-G0-A1) 14 nm 3.3 135 PCIe 3.0 x16 640:40:16 1354 1493 7000 21.7 54.2 4 112 GDDR5 128 12 (12_1) 4.5 1.3 1.2 1733 (1911) 27 14 53 No
GeForce GTX 1050 Ti (Notebook)[237] GP107(N17P-G1-A1) 768:48:32 1493 1620 47.8 71.7 2293 (2488) 36 18 64
GeForce GTX 1060 (Notebook)[237] August 16, 2016 GP106 16 4.4 200 1280:80:48 1404 1670 8000 67.4 112 6 192 192 3594 (4275) 112 56 80
GeForce GTX 1060 Max-Q May 2017 1063 1480 71.04 118.4 3789 118.4 59.20
GP106B 1265
GeForce GTX 1070 (Notebook)[237] August 16, 2016 GP104/GP104B[239] 7.2 314 2048:128:64 1442 1645 92.3 185 8 256 256 5906 (6738) 185 92 115 Yes
GeForce GTX 1070 Max-Q May 2017 1101 1379 88.26 176.5 5648 176.5 88.26 ? No
GeForce GTX 1080 (Notebook)[237] August 16, 2016 2560:160:64 1556 1733 10000 99.6 249 320 GDDR5X 7967 (8873) 249 124 150 Yes
GeForce GTX 1080 Max-Q May 2017 1101 1468 93.95 234.9 7516 234.9 117.4 ? No

GeForce 16 series edit

Model Launch Code name Process Transistors (billion) Die size (mm2) Bus interface L2

Cache(MB)

Core config Clock speeds Memory (MT/s) Fillrate Memory Processing power (GFLOPS) TDP (Watts)
Base core clock (MHz) Boost core clock (MHz) Pixel (GP/s) Texture (GT/s) Size (GB) Bandwidth (GB/s) Bus type Bus width (bit) Single precision Double precision Half precision
Geforce GTX 1630 Jun 28, 2022 TU117 TSMC 12FFN 4.7 200 PCIe 3.0

x16

1.0 512:32:16 1740 1785 12000 28.56 57.12 4 96 GDDR6 64 1828 57.12 3.656 75
GeForce GTX 1650 (Laptop) April 23, 2019 1024:64:32 1395 1560 8000 49.92 99.84 4 128 GDDR5 128 3195 99.84[240] 6390 50
GeForce GTX 1650 Max-Q TU117(N18P-G0-MP-A1) 1020 1245 39.84 79.68 112 2550 79.68[241] 5100 30
GeForce GTX 1650 Ti Max-Q April 2, 2020 TU117 1035 1200 12000 38.4 76.8 4 192 GDDR6 2458 76.8 4915 35
GeForce GTX 1650 Ti TU117(N18P-G62-A1) 1350 1485 47.52 95.04 3041 95.04 6083 55
GeForce GTX 1660 (Laptop) ? TU116 6.6 284 1.5 1408:88:48 1455 1599 16000 76.32 127.2 6 384 192 4070 127.2[242] 8141 ?
GeForce GTX 1660 Ti Max-Q April 23, 2019 1536:96:46 1140 1335 12000 64.08 128.2 288 4101 128.2[243] 8202 60
GeForce GTX 1660 Ti (Laptop)[244] 1536:96:46 1455 1590 76.32 152.6 288 4884 152.6[245] 9769 80

GeForce 20 series edit

Further information: GeForce 20 series and Turing (microarchitecture)
Model Launch Code name Process Transistors (billion) Die size (mm2) Core config[a] Bus interface L2

Cache(MB)

Clock speeds Memory Fillrate[b] Processing power (GFLOPS)[b] Ray-tracing Performance TDP (Watts)
Base core clock (MHz) Boost core clock (MHz) Memory (MT/s) Size (GB) Bandwidth (GB/s) Bus type Bus width (bit) Pixel (GP/s)[c] Texture (GT/s)[d] Single precision Double precision Half precision Tensor compute (FP16) Rays/s (Billions) RTX OPS/s (Trillions)
GeForce RTX 2050[247][248] 2022 GA107 Samsung 8N 8.7 200 2048:64:32:64:32 (16) (3) PCIe 3.0 x8 2 1155 1477 14000 4 112.0 GDDR6 64 30-45
GeForce RTX 2060[249] January 29, 2019 TU106 TSMC
12FFN 		10.8 445 1920:120:48:240:30 (30) (3) PCIe 3.0 x16 3 960 1200 6 336.0 192 57.6 144 4608 144.0 9216 80
GeForce RTX 2060 Max-Q[250] 975 1175 11000 264.0 56.88 142.2 4550 142.2 9101 65
GeForce RTX 2070[251] 2304:144:64:288:36 (36) (3) 4 1215 1440 14000 8 448.0 256 92.16 207.4 6636 207.4 13270 115
GeForce RTX 2070 Max-Q[252] 885 1185 12000 75.84 170.6 5460 170.6 10920 80
GeForce RTX 2070 Super[253] April 2, 2020 TU104 13.6 545 2560:160:64:320:40 (40) (5) 1140 1380 14000 88.3 220.8 7066 220.8 14130 115
GeForce RTX 2070 Super Max-Q[254] 930 1155 12000 69.1 172.8 5530 172.8 11060 80
GeForce RTX 2080[255] January 29, 2019 2944:184:64:368:46 (46) (6) 1380 1590 14000 384.0 101.8 292.6 9362 292.6 18720 150
GeForce RTX 2080 Max-Q[256] 735 1095 12000 70.08 201.5 6447 201.5 12890 80
GeForce RTX 2080 Super[257] April 2, 2020 3072:192:64:384:48 (48) (6) 1365 1560 14000 448.0 99.8 299.5 9585 299.5 19170 150
GeForce RTX 2080 Super Max-Q[258] 735 1080 11000 352.0 69.1 207.4 6636 207.4 13270 80
  1. ^ Main Shader Processors : Texture Mapping Units : Render Output Units : Tensor Cores (or FP16 Cores in GeForce 16 series) : Ray-tracing Cores (Streaming Multiprocessors) (Graphics Processing Clusters)
  2. ^ a b Base clock, Boost clock
  3. ^ Pixel fillrate is calculated as the lowest of three numbers: number of ROPs multiplied by the base core clock speed, number of rasterizers multiplied by the number of fragments they can generate per rasterizer multiplied by the base core clock speed, and the number of streaming multiprocessors multiplied by the number of fragments per clock that they can output multiplied by the base clock rate.
  4. ^ Texture fillrate is calculated as the number of TMUs multiplied by the base core clock speed.

GeForce 30 series edit

Further information: GeForce 30 series and Ampere (microarchitecture)
Model Launch Code name Process
Transistors (billion)
 Die size (mm2) Core config
[a] 		Bus interface L2 Cache (MB) Clock speeds [b] Memory Fillrate[c] Processing power (TFLOPS)[c] Ray-tracing Performance TDP (Watts)
Base core (MHz) Boost core (MHz) Memory (MHz)
(Gb/s)
(MT/s) 		Size (GB) Bandwidth (GB/s) Bus type Bus width (bit) Pixel (GP/s)[d] Texture (GT/s)[e] Single precision Double precision Half precision Tensor compute (FP16)[f] Tensor TOPS 
(INT8)[f] 		Rays/s (Billions) RTX OPS/s (Trillions)

GeForce RTX 3050
Mobile/[259]
Laptop[260] 		May 11, 2021 GA107 Samsung 8N 8.7 200 2048:64:32:64:16
(16) (3)
2560:80:32:80:20
(20) (?) 		PCIe 4.0 x8 2 712-1530
622-1237 		1057-1740
990-1492 		1375-1500
11-12
11000-12000
1375-1750
11-14
11000-14000 		4
6 		176.0-192.0
132.0-224.0 		GDDR6 128
96 		22.7-48.9
33.8-55.6
 45.6-97.9
67.7-111.4 		2.92-6.27
4.33-7.13 		0.046-0.098
0.068-0.111 		2.92-6.27
4.33-7.13 		35-80
GeForce[261]
RTX 3050 
Ti Mobile/
Laptop[262] 		2560:80:48:80:20
(20) (3) 		735-1462 1035-1695 12000 4 192 128 35.3-70.2
49.7-81.4 		58.8-117.0
82.8-135.6 		3.76-7.49
5.30-8.68 		0.059-0.117
0.083-0.136 		3.76-7.49
5.30-8.68
GeForce RTX 3060 Mobile/[263]
Laptop[264] 		January 12, 2021 GA106 12.0 276 3840:120:48:120:30
(30) (3) 		PCIe 4.0 x16 3 817-1387 1282-1702 12000
14000 		6 288
336 		192 39.2-66.6
61.54-81.7 		98.0-166.4
153.8-204.2 		6.27-10.65
9.85-13.07 		0.108-0.166
0.154-0.204 		6.27-10.65
9.85-13.07 		60-115
GeForce[265]
RTX 3070 Mobile/[266]
Laptop[267] 		GA104-770-A1 17.4 392 5120:160:80:160:40
(40) (6) 		4 780-1215 1290-1620 8 384
448 		256 62.4-97.2
103.2-129.6 		124.8-194.4
206.4-259.2 		7.99-12.44
13.21-16.59 		0.125-0.194
0.206-0.259 		7.99-12.44
13.21-16.59 		80-125
GeForce RTX 3070
Ti Mobile/
Laptop[268] 		January 4, 2022 GA104 5888:184:96:184:46 (46) (6) 510-1035 1035-1485 46.9-95.2
95.2-136.6 		93.8-190.4
190.4-273.2 		6.01-12.19
12.19-17.49 		0.094-0.190
0.190-0.273 		6.01-12.19
12.19-17.49 		16.6
GeForce RTX 3080 Mobile/[269]
Laptop[270] 		January 12, 2021 GA104-775-A1 6144:192:96:192:48
(48) (6) 		780-1350 1245-1710 8-16 74.9-129.6
119.5-164.2 		149.8-259.2
239.0-328.3 		9.59-16.59
15.30-21.01 		0.150-0.259
0.239-0.328 		9.59-16.59
15.30-21.01 		80-150
GeForce RTX 3080
Ti Mobile/
Laptop[271] 		January 25, 2022 GA103 22 496 7424:232:116:232:58 (58) (6) 585-1230 1125-1590 12000
16000 		16 384
512 		67.9-142.7
 130.5-184.4  		135.7-285.4
 261.0-368.9  		8.68-18.26
  16.7-23.60   		0.136-0.285
  0.261-0.369   		8.68-18.26
  16.7-23.60   		18.71
  1. ^ Main Shader Processors : Texture Mapping Units : Render Output Units : Tensor Cores (or FP16 Cores in GeForce 16 series) : Ray-tracing Cores (Streaming Multiprocessors) (Graphics Processing Clusters)
  2. ^ Which base and boost core clockspeeds the GPU has depends on the TDP configuration set by the system builder
  3. ^ a b Base clock, Boost clock.
  4. ^ Pixel fillrate is calculated as the lowest of three numbers: number of ROPs multiplied by the base core clock speed, number of rasterizers multiplied by the number of fragments they can generate per rasterizer multiplied by the base core clock speed, and the number of streaming multiprocessors multiplied by the number of fragments per clock that they can output multiplied by the base clock rate.
  5. ^ Texture fillrate is calculated as the number of TMUs multiplied by the base core clock speed.
  6. ^ a b Cite error: The named reference Sparsity was invoked but never defined (see the help page).

GeForce 40 series edit

January 01, 1970
list, nvidia, graphics, processing, units, this, list, contains, general, information, about, graphics, processing, units, gpus, video, cards, from, nvidia, based, official, specifications, addition, some, nvidia, motherboards, come, with, integrated, onboard,. This list contains general information about graphics processing units GPUs and video cards from Nvidia based on official specifications In addition some Nvidia motherboards come with integrated onboard GPUs Limited Special Collectors Editions or AIB versions are not included Contents 1 Field explanations 2 Desktop GPUs 2 1 Pre GeForce 2 2 GeForce 256 series 2 3 GeForce2 series 2 4 GeForce3 series 2 5 GeForce4 series 2 6 GeForce FX 5xxx series 2 7 GeForce 6 6xxx series 2 7 1 Features 2 8 GeForce 7 7xxx series 2 8 1 Features 2 9 GeForce 8 8xxx series 2 9 1 Features 2 10 GeForce 9 9xxx series 2 10 1 Features 2 11 GeForce 100 series 2 12 GeForce 200 series 2 12 1 Features 2 13 GeForce 300 series 2 14 GeForce 400 series 2 15 GeForce 500 series 2 16 GeForce 600 series 2 17 GeForce 700 series 2 18 GeForce 900 series 2 19 GeForce 10 series 2 20 Volta series 2 21 GeForce 16 series 2 22 RTX 20 series 2 23 RTX 30 series 2 24 RTX 40 series 3 Mobile GPUs 3 1 GeForce2 Go series 3 2 GeForce4 Go series 3 3 GeForce FX Go 5 Go 5xxx series 3 4 GeForce Go 6 Go 6xxx series 3 5 GeForce Go 7 Go 7xxx series 3 6 GeForce 8M 8xxxM series 3 7 GeForce 9M 9xxxM series 3 8 GeForce 100M 1xxM series 3 9 GeForce 200M 2xxM series 3 10 GeForce 300M 3xxM series 3 11 GeForce 400M 4xxM series 3 12 GeForce 500M 5xxM series 3 13 GeForce 600M 6xxM series 3 14 GeForce 700M 7xxM series 3 15 GeForce 800M 8xxM series 3 16 GeForce 900M 9xxM series 3 17 GeForce 10 series 3 18 GeForce 16 series 3 19 GeForce 20 series 3 20 GeForce 30 series 3 21 GeForce 40 series 3 22 GeForce MX series 4 Workstation GPUs 4 1 Quadro 4 2 Quadro FX series 4 3 Quadro FX x300 series 4 4 Quadro FX x400 series 4 5 Quadro FX x500 series 4 6 Quadro FX x600 series 4 7 Quadro FX x700 series 4 8 Quadro FX x800 series 4 9 Quadro x000 series 4 10 Quadro Kxxx series 4 11 Quadro Mxxx series 4 12 Quadro Pxxx series 4 13 Quadro GVxxx series 4 14 Quadro Tx00 Tx000 series 4 15 Quadro RTX x000 series 4 16 RTX Ax000 series 4 17 RTX Ada Generation 4 18 Quadro NVS 5 Mobile Workstation GPUs 5 1 Quadro Go GL amp Quadro FX Go series 5 2 Quadro FX x500M series 5 3 Quadro FX x600M series 5 4 Quadro FX x700M series 5 5 Quadro FX x800M series 5 6 Quadro xxxxM series 5 7 Quadro Kx000M series 5 8 Quadro Kx100M series 5 9 Quadro Kx200M series 5 10 Quadro Mx000M series 5 11 Quadro Mx200 series 5 12 Quadro Mx500 series 5 13 Quadro Px000 series 5 14 Quadro Px200 series 5 15 Quadro RTX T x000 series 5 16 RTX Ax000 series 5 17 RTX Ada Generation 5 18 Mobility Quadro NVS series 5 19 Mobility NVS series 6 Tegra GPU 7 Data Center GPUs 7 1 GRID 7 2 Tesla 8 Console GPUs 9 See also 10 References 11 External linksField explanations editThe fields in the table listed below describe the following Model The marketing name for the processor assigned by The Nvidia Launch Date of release for the processor Code name The internal engineering codename for the processor typically designated by an NVXY name and later GXY where X is the series number and Y is the schedule of the project for that generation Fab Fabrication process Average feature size of components of the processor Bus interface Bus by which the graphics processor is attached to the system typically an expansion slot such as PCI AGP or PCI Express Memory The amount of graphics memory available to the processor SM Count Number of streaming multiprocessors 1 Core clock The factory core clock frequency while some manufacturers adjust clocks lower and higher this number will always be the reference clocks used by Nvidia Memory clock The factory effective memory clock frequency while some manufacturers adjust clocks lower and higher this number will always be the reference clocks used by Nvidia All DDR GDDR memories operate at half this frequency except for GDDR5 which operates at one quarter of this frequency Core config The layout of the graphics pipeline in terms of functional units Over time the number type and variety of functional units in the GPU core has changed significantly before each section in the list there is an explanation as to what functional units are present in each generation of processors In later models shaders are integrated into a unified shader architecture where any one shader can perform any of the functions listed Fillrate Maximum theoretical fill rate in textured pixels per second This number is generally used as a maximum throughput number for the GPU and generally a higher fill rate corresponds to a more powerful and faster GPU Memory subsection Bandwidth Maximum theoretical bandwidth for the processor at factory clock with factory bus width GHz 109 Hz Bus type Type of memory bus or buses used Bus width Maximum bit width of the memory bus or buses used This will always be a factory bus width API support section Direct3D Maximum version of Direct3D fully supported OpenGL Maximum version of OpenGL fully supported OpenCL Maximum version of OpenCL fully supported Vulkan Maximum version of Vulkan fully supported Features Added features that are not standard as a part of the two graphics libraries Desktop GPUs editPre GeForce edit Further information Fahrenheit microarchitecture Model Launch Code name Fab nm 2 Transistors million Die size mm2 Bus interface Core clock MHz Memory clock MHz Core config a Fillrate Memory MFLOPS FP32 citation needed Latest API support MOperations s MPixels s MTexels s MVertices s Size MB Bandwidth GB s Bus type Bus width bit Direct3D OpenGL STG 2000 May 22 1995 NV1 SGS500 nm 1 3 90 PCI 1275 5060 1 1 1 12 12 12 0 124 0 40 48 FPMEDOVRAM 64 24 0150 0 1 0 n a Riva 128 August 25 1997 NV3 SGS 350 nm 4 4 90 AGP 1x 5 PCI 100 100 100 100 100 4 1 6 SDR 128 200 0 5 0 1 0 Riva 128ZX February 23 1998 SGS TSMC 350 nm AGP 2x PCI 8 Riva TNT June 15 1998 NV4 TSMC 350 nm 7 6 90 90 110 2 2 2 180 180 180 816 1 76 360 0 6 0 1 2 Vanta March 22 1999 NV6 TSMC 250 nm AGP 4x PCI 100 125 200 200 200 816 1 0 64 400 0 Vanta LT March 2000 AGP 2x 80 100 160 160 160 816 0 8 320 0 Riva TNT2 M64 October 1999 AGP 4x PCI 125 150 250 250 250 8 16 32 1 2 500 0 Riva TNT2 March 15 1999 NV5 15 7 90 1632 2 4 128 Riva TNT2 Pro October 12 1999 TSMC 220 nm 143 166 286 286 286 1632 2 656 572 0 Riva TNT2 Ultra March 15 1999 TSMC 250 nm 150 183 300 300 300 1632 2 928 600 0 Model Launch Code name Fab nm 2 Transistors million Die size mm2 Bus interface Core clock MHz Memory clock MHz Core config a MOperations s MPixels s MTexels s MVertices s Size MB Bandwidth GB s Bus type Bus width bit MFLOPS FP32 Direct3D OpenGL Fillrate Memory Latest API support a b Pixel pipelines texture mapping units render output units GeForce 256 series edit Further information GeForce 256 and Celsius microarchitecture All models are made via TSMC 220 nm fabrication process All models support Direct3D 7 0 and OpenGL 1 2 All models support hardware Transform and Lighting T amp L and Cube Environment Mapping Model Launch Code name Transistors million Die size mm2 Bus interface Core clock MHz Memory clock MHz Core config a Fillrate Memory MFLOPSFP32 MOperations s MPixels s MTexels s MVertices s Size MB Bandwidth GB s Bus type Bus width bit GeForce 256 SDR 8 Oct 11 1999 NV10 17 139 AGP 4x PCI 120 166 4 4 4 480 480 480 0 3264 2 656 SDR 128 960 GeForce 256 DDR 9 Dec 13 1999 150 4 800 DDR Pixel pipelines texture mapping units render output units GeForce2 series edit Further information GeForce 2 series and Celsius microarchitecture All models support Direct3D 7 and OpenGL 1 2 All models support TwinView Dual Display Architecture Second Generation Transform and Lighting T amp L Nvidia Shading Rasterizer NSR High Definition Video Processor HDVP GeForce2 MX models support Digital Vibrance Control DVC Model Launch Code name Fab nm 2 Transistors million Die size mm2 Bus interface Core clock MHz Memory clock MHz Core config a Fillrate Memory GFLOPSFP32 MOperations s MPixels s MTexels s MVertices s Size MB Bandwidth GB s Bus type Bus width bit GeForce2 MX IGP nForce 220 420 June 4 2001 NV1A IGP NV11 MX TSMC180 nm 20 10 64 FSB 175 133 2 4 2 350 350 700 0 Up to 32 system RAM 2 1284 256 DDR 64128 0 700 GeForce2 MX200 March 3 2001 AGP 4x PCI 166 3264 1 328 SDR 64 GeForce2 MX June 28 2000 2 656 128 GeForce2 MX400 March 3 2001 200 166 200 SDR 166 DDR 400 400 800 1 328 3 200 2 656 SDRDDR 64 128 SDR 64 DDR 0 800 GeForce2 GTS April 26 2000 NV15 25 11 88 AGP 4x 166 4 8 4 800 800 1 600 5 312 DDR 128 1 600 GeForce2 Pro December 5 2000 200 6 4 GeForce2 Ti October 1 2001 TSMC150 nm 250 1 000 1 000 2 000 2 000 GeForce2 Ultra August 14 2000 TSMC180 nm 230 64 7 36 Pixel pipelines texture mapping units render output units GeForce3 series edit Further information GeForce 3 series and Kelvin microarchitecture All models are made via TSMC 150 nm fabrication process All models support Direct3D 8 0 and OpenGL 1 3 All models support 3D Textures Lightspeed Memory Architecture LMA nFiniteFX Engine Shadow Buffers Model Launch Code name Transistors million Die size mm2 Bus interface Core clock MHz Memory clock MHz Core config a Fillrate Memory GFLOPSFP32 MOperations s MPixels s MTexels s MVertices s Size MB Bandwidth GB s Bus type Bus width bit GeForce3 Ti200 October 1 2001 NV20 57 128 AGP 4x PCI 175 200 4 1 8 4 700 700 1400 43 75 64128 6 4 DDR 128 8 750 GeForce3 February 27 2001 200 230 800 800 1600 50 64 7 36 10 00 GeForce3 Ti500 October 1 2001 240 250 960 960 1920 60 64128 8 0 12 00 Pixel shaders vertex shaders texture mapping units render output units GeForce4 series edit Further information GeForce 4 series and Kelvin microarchitecture All models are manufactured via TSMC 150 nm manufacturing process All models support Accuview Antialiasing AA Lightspeed Memory Architecture II LMA II nView Model Launch Code name Transistors million Die size mm2 Bus interface Core clock MHz Memory clock MHz Core config a Fillrate Memory Supported API version GFLOPSFP32 MOperations s MPixels s MTexels s MVertices s Size MB Bandwidth GB s Bus type Bus width bit Direct3D OpenGL GeForce4 MX IGP nForce2 October 1 2002 NV1F FSB 250 133200 2 0 4 2 500 500 1 000 125 Up to 128 system RAM 2 1286 4 DDR 64128 7 0 1 2 1 000 GeForce4 MX420 February 6 2002 NV17 29 12 65 AGP 4xPCI 166 64 2 656 SDRDDR 128 SDR 64 DDR GeForce4 MX440 SE 2002 133166 13 500 13 1000 64128 2 128 5 312 13 DDR 64 128 13 GeForce MX4000 December 14 2003 NV18B 29 65 AGP 8xPCI 166 1000 2 656 64 GeForce PCX4300 February 19 2004 PCIe x16 128 GeForce4 MX440 February 6 2002 NV17 29 65 AGP 4xPCI 275 200 550 550 1 100 137 5 64128 6 4 128 1 100 GeForce4 MX440 8x September 25 2002 NV18 29 14 65 AGP 8xPCI 166250 2 656 15 8 0 64128 GeForce4 MX460 February 6 2002 NV17 29 65 AGP 4xPCI 300 275 600 600 1 200 150 8 8 128 1 200 GeForce4 Ti4200 April 16 2002 NV25 63 16 142 AGP 4x 250 222 128 MB 250 64 MB 4 2 8 4 1 000 1 000 2 000 125 7 104 128 MB 8 0 64 MB 8 0a 1 3 15 00 GeForce4 Ti4200 8x September 25 2002 NV28 63 17 142 AGP 8x 250 8 0 GeForce4 Ti4400 February 6 2002 NV25 63 142 AGP 4x 275 275 1 100 1 100 2 200 137 5 128 8 8 16 50 GeForce4 Ti4400 8x Ti4800SE b January 20 2003 NV28 63 101 AGP 8x GeForce4 Ti4600 February 6 2002 NV25 63 142 AGP 4x 300 325 1 200 1 200 2 400 150 10 4 18 00 GeForce4 Ti4600 8x Ti4800 c January 20 2003 NV28 63 101 AGP 8x Pixel shaders vertex shaders texture mapping units render output units GeForce4 Ti4400 8x Card manufacturers utilizing this chip labeled the card as a Ti4800SE The surface of the chip has Ti 8x printed on it GeForce4 Ti4600 8x Card manufacturers utilizing this chip labeled the card as a Ti4600 and in some cases as a Ti4800 The surface of the chip has Ti 8x printed on it as well as 4800 printed at the bottom Model Features nFiniteFX II Engine Video Processing Engine VPE GeForce4 MX420 No Yes GeForce4 MX440 SE No Yes GeForce4 MX4000 No Yes GeForce4 PCX4300 No Yes GeForce4 MX440 No Yes GeForce4 MX440 8X No Yes GeForce4 MX460 No Yes GeForce4 Ti4200 Yes No GeForce4 Ti4200 8x Yes No GeForce4 Ti4400 Yes No GeForce4 Ti4400 8x Yes No GeForce4 Ti4600 Yes No GeForce4 Ti4600 8x Yes No GeForce FX 5xxx series edit Further information GeForce FX series and Rankine microarchitecture All models support Direct3D 9 0a and OpenGL 1 5 2 1 software with latest drivers The GeForce FX series runs vertex shaders in an array Model Launch Code name Fab nm 2 Transistors million Die size mm2 Bus interface Core clock MHz Memory clock MHz Core config a Fillrate Memory GFLOPSFP32 MOperations s MPixels s MTexels s MVertices s Size MB Bandwidth GB s Bus type Bus width bit GeForce FX 5100 March 2003 NV34 TSMC 150 nm 45 18 124 AGP 8x 200 166 4 2 4 4 800 800 800 100 0 64 128 2 6 DDR 64 12 0 GeForce FX 5200 LE 250 1 000 1 000 1 000 125 0 64128256 2 65 3 64128 15 0 GeForce FX 5200 AGP 8xPCI 200 3 26 4 64128 GeForce FX 5200 Ultra March 6 2003 AGP 8x 325 325 1 300 1 300 1 300 162 5 10 4 128 19 5 GeForce PCX 5300 March 17 2004 PCIe x16 250 166 1 000 1 000 1 000 125 0 128256 2 6 64 15 0 GeForce FX 5500 March 2004 NV34B 45 19 91 AGP 8xAGP 4xPCI 270 166200 1 080 1 080 1 080 135 0 64128256 5 36 4 128 16 2 GeForce FX 5600 XT October 2003 NV31 TSMC 130 nm 80 20 121 AGP 8x 235 200 940 940 940 117 5 64128 3 26 4 64128 14 1 GeForce FX 5600 March 2003 AGP 8xPCI 325 275 1 300 1 300 1 300 162 5 64128256 21 8 8 128 19 5 GeForce FX 5600 Ultra March 6 2003 AGP 8x 350 350 1 400 1 400 1 400 175 0 64128 11 2 21 0 GeForce FX 5600 Ultra Rev 2 400 400 1 600 1 600 1 600 200 0 12 8 24 0 GeForce FX 5700 VE September 2004 NV36 82 22 133 250 200 4 3 4 4 1500 1500 1500 187 5 128256 3 26 4 64128 17 5 GeForce FX 5700 LE March 2004 AGP 8xPCI GeForce FX 5700 2003 AGP 8x 425 250 1 700 1 700 1 700 318 7 8 0 128 29 7 GeForce PCX 5750 March 17 2004 PCIe x16 128 GeForce FX 5700 Ultra October 23 2003 AGP 8x 475 453 1 900 1 900 1 900 356 2 128256 14 4 GDDR2 33 2 GeForce FX 5700 Ultra GDDR3 March 15 2004 475 15 2 GDDR3 GeForce FX 5800 January 27 2003 NV30 125 23 199 400 400 4 2 8 4 1 600 1 600 3 200 300 0 128 12 8 GDDR2 24 0 GeForce FX 5800 Ultra 500 500 2 000 2 000 4 000 375 0 16 0 30 0 GeForce FX 5900 ZT December 15 2003 NV35 135 24 207 325 350 4 3 8 4 1 300 1 300 2 600 243 7 22 4 DDR 256 22 7 GeForce FX 5900 XT December 15 2003 25 390 1 600 1 600 3 200 300 0 27 3 GeForce FX 5900 May 2003 400 425 27 2 28 0 GeForce FX 5900 Ultra May 12 2003 450 1 800 1 800 3 600 337 5 128256 31 5 GeForce PCX 5900 March 17 2004 PCIe x16 350 275 1 400 1 400 2 800 262 5 17 6 24 5 GeForce FX 5950 Ultra October 23 2003 NV38 135 26 207 AGP 8x 475 475 1 900 1 900 3 800 356 2 256 30 4 33 2 GeForce PCX 5950 February 17 2004 PCIe x16 425 27 2 GDDR3 Model Launch Code name Fab nm 2 Transistors million Die size mm2 Bus interface Core clock MHz Memory clock MHz Core config a Fillrate Memory GFLOPSFP32 MOperations s MPixels s MTexels s MVertices s Size MB Bandwidth GB s Bus type Bus width bit a b Pixel shaders vertex shaders texture mapping units render output units GeForce 6 6xxx series edit Further information GeForce 6 series and Curie microarchitecture All models support Direct3D 9 0c and OpenGL 2 1 All models support Transparency AA starting with version 91 47 of the ForceWare drivers and PureVideo Model Launch Code name Fab nm 2 Transistors million Die size mm2 Bus interface Core clock MHz Memory clock MHz Core config a Fillrate Memory MOperations s MPixels s MTexels s MVertices s Size MB Bandwidth GB s Bus type Bus width bit GeForce 6100 nForce 410 October 20 2005 MCP51 TSMC 90 nm HyperTransport 425 100 200 DDR 200 533 DDR2 2 1 2 1 850 425 850 106 25 Up to 256 system RAM 1 6 6 4 DDR 3 2 17 056 DDR2 DDRDDR2 64128 GeForce 6150 SE nForce 430 June 2006 MCP61 200400 citation needed 3 216 0 citation needed DDR2 GeForce 6150 LE nForce 430 MCP61 100 200 DDR 200 533 DDR2 1 6 6 4 DDR 3 2 17 056 DDR2 DDRDDR2 GeForce 6150 nForce 430 October 20 2005 MCP51 475 950 475 950 118 75 1 6 6 4 DDR 3 2 17 056 DDR2 GeForce 6200 LE April 4 2005 NV44 TSMC 110 nm 75110 27 AGP 8xPCIe x16 350 266 700 700 700 87 5 128256 4 256 DDR 64 GeForce 6200A April 4 2005 NV44A 75110 28 AGP 8x 350 29 250 DDR 250 333 DDR2 29 4 3 4 2 1 400 29 700 29 1400 29 175225 DDR2 30 128256 29 512 29 44 5 34 DDR2 31 DDRDDR2 30 64 30 GeForce 6200 October 12 2004 PCIe January 17 2005 AGP NV43 146154 32 AGP 8xPCIPCIe x16 300 275 4 3 4 4 1 200 1 200 1 200 225 128256 8 8 DDR 128 GeForce 6200 TurboCache December 15 2004 NV44 75110 27 PCIe x16 350 200275350 4 3 4 2 1 400 700 1 400 262 5 128 256 System RAM incl 16 32 64 128 onboard 3 24 45 6 DDR 64 GeForce 6500 October 1 2005 400 333 1 600 800 1 600 300 128256 5 328 GeForce 6600 LE 2005 NV43 146154 32 AGP 8xPCIe x16 300 200 4 3 4 4 1 200 1 200 1 200 225 6 4 128 GeForce 6600 August 12 2004 275400 8 3 8 4 2 400 2 400 8 812 8 DDRDDR2 GeForce 6600 GT August 12 2004 PCIe November 14 2004 AGP 500 475 AGP 500 PCIe 4 000 2 000 4 000 375 15 2 AGP 33 16 PCIe GDDR3 GeForce 6800 LE July 22 2004 AGP January 16 2005 PCIe NV40 AGP NV41 NV42 PCIe IBM 130 nm 222287 NV40 34 222225 NV41 35 198222 NV42 36 320 AGP 325 PCIe 350 8 4 8 8 2 560 AGP 2 600 PCIe 2 560 AGP 2 600 PCIe 2 560 AGP 2 600 PCIe 320 AGP 325 PCIe 128 22 4 DDR 256 GeForce 6800 XT September 30 2005 300 64 Bit 325 266 64 Bit 350500 GDDR3 2 4002 600 2 4002 600 2 4002 600 300325 256 4 25611 222 432 GDDR3 DDRDDR2GDDR3 64 37 128 38 256 GeForce 6800 April 14 2004 AGP November 8 2004 PCIe 325 350 12 5 12 12 3 900 3 900 3 900 406 25 128256 22 4 DDR 256 GeForce 6800 GTO April 14 2004 NV45 222287 NV45 39 PCIe x16 450 4 200 4 200 4 200 437 5 256 28 8 GDDR3 GeForce 6800 GS November 7 2005 PCIe December 8 2005 AGP NV42 PCIe NV40 AGP TSMC 110 nm 222287 NV40 34 198222 NV42 36 AGP 8xPCIe x16 425 PCIe 350 AGP 500 5 100 5 100 5 100 531 25 128256 32 GeForce 6800 GT May 4 2004 AGP June 28 2004 PCIe NV40 AGP NV45 PCIe IBM 130 nm 222287 NV40 34 222287 NV45 39 AGP 8xPCIe x16 350 16 6 16 16 5 600 5 600 5 600 525 GeForce 6800 Ultra May 4 2004 AGP June 28 2004 PCIe March 14 2005 512 MB 400 525 512 MB 550 256 MB 6 400 6 400 6 400 600 256512 33 6 512 MB 35 2 256 MB GeForce 6800 Ultra Extreme Edition May 4 2004 NV40 222287 NV40 34 AGP 8x 450 600 7 200 7 200 7 200 675 256 35 2 Model Launch Code name Fab nm 2 Transistors million Die size mm2 Bus interface Core clock MHz Memory clock MHz Core config a Fillrate Memory MOperations s MPixels s MTexels s MVertices s Size MB Bandwidth GB s Bus type Bus width bit a b Pixel shaders vertex shaders texture mapping units render output units Features edit Model Features OpenEXR HDR Scalable Link Interface SLI TurboCache PureVideo WMV9 Decoding GeForce 6100 No No No Limited GeForce 6150 SE No No Driver Side Only Limited GeForce 6150 No No No Yes GeForce 6150 LE No No Driver Side Only Yes GeForce 6200 No No Yes PCIe only Yes GeForce 6500 No Yes Yes Yes GeForce 6600 LE Yes Yes No SLI Connector No Yes GeForce 6600 Yes Yes SLI Connector or PCIe Interface No Yes GeForce 6600 DDR2 Yes Yes SLI Connector or PCIe Interface No Yes GeForce 6600 GT Yes Yes No Yes GeForce 6800 LE Yes No No No GeForce 6800 XT Yes Yes PCIe only No Yes NV42 only GeForce 6800 Yes Yes PCIe only No Yes NV41 NV42 only GeForce 6800 GTO Yes Yes No No GeForce 6800 GS Yes Yes PCIe only No Yes NV42 only GeForce 6800 GT Yes Yes PCIe only No No GeForce 6800 Ultra Yes Yes PCIe only No No GeForce 7 7xxx series edit Further information GeForce 7 series and Curie microarchitecture All models support Direct3D 9 0c and OpenGL 2 1 All models support Transparency AA starting with version 91 47 of the ForceWare drivers Model Launch Code name Fab nm 2 Transistors million Die size mm2 Bus interface Core clock MHz Memory clock MHz Core config a Fillrate Memory MOperations s MPixels s MTexels s MVertices s Size MB Bandwidth GB s Bus type Bus width bit GeForce 7025 nForce 630a July 2007 MCP68S TSMC 110 nm HyperTransport 425 200 DDR 400 DDR2 933 DDR3 2 1 2 2 850 850 850 106 25 Up to 256 system RAM 6 412 834 DDRDDR2DDR3 64128 GeForce 7050PV nForce 630a MCP67QV GeForce 7050 nForce 610i 630i MCP73 TSMC 90 nm HyperTransport FSB 500 333 1 000 1 000 1 000 125 5 336 DDR2 64 GeForce 7100 nForce 630i MCP76 FSB 600 400 1 200 1 200 1 200 150 6 4 GeForce 7150 nForce 630i 630 1 260 1 260 1 260 157 5 GeForce 7100 GS August 8 2006 NV44 TSMC 110 nm 75 27 110 PCIe x16 350 266333 4 3 4 2 1 400 700 1 400 262 5 128256 2 44 8 DDR2 3264 GeForce 7200 GS January 18 2006 G72 TSMC 90 nm 112 40 81 450 400 2 2 4 2 1 800 900 1 800 337 5 3 26 4 DDR2 GeForce 7300 SE March 22 2006 350 333 4 3 4 2 128 2 6565 328 GeForce 7300 LE GeForce 7300 GS January 18 2006 550 400 2 200 1 100 2 200 412 5 128256 6 4 64 GeForce 7300 GT May 15 2006 G73 177 41 125 AGP 8xPCIe x16 350 325 DDR2 700 GDDR3 8 5 8 4 2 800 1 400 2 800 437 5 10 422 4 DDR2GDDR3 128 GeForce 7500 LE 2006 G72 112 40 81 PCIe x16 475550 405324 4 3 4 2 2 200 1 100 2 200 593 8 64128256 6 4805 2 DDR2 64 GeForce 7600 GS March 22 2006 PCIe July 1 2006 AGP G73 177 41 125 AGP 8xPCIe x16 400 400 DDR2 700 GDDR3 12 5 12 8 4 800 3 200 4 800 500 256 12 822 4 DDR2GDDR3 128 GeForce 7600 GT March 9 2006 PCIe July 15 2006 AGP 560 6 720 4 480 6 720 700 GeForce 7600 GT 80 nm January 8 2007 G73 B1 TSMC 80 nm GeForce 7650 GS March 22 2006 G73 PCIe x16 450 400 5 400 3 600 5 400 562 5 12 7 DDR2 GeForce 7800 GS February 2 2006 G70 TSMC 110 nm 302 42 333 AGP 8x 375 600 16 8 16 8 6 000 3 000 6 000 750 38 4 GDDR3 256 GeForce 7800 GT August 11 2005 PCIe x16 400 500 20 7 20 16 8 000 6 400 8 000 700 32 GeForce 7800 GTX June 22 2005 256 MB November 14 2005 512 MB 430 256 MB 550 512 MB 600 256 MB 850 512 MB 24 8 24 16 10 320 256 MB 13 200 512 MB 6 880 256 MB 8800 512 MB 10 320 256 MB 13 200 512 MB 860 256 MB 1 100 512 MB 256512 38 4 256 MB 54 4 512 MB GeForce 7900 GS May 2006 PCIe April 2 2007 AGP G71 TSMC 90 nm 278 43 196 AGP 8xPCIe x16 450 660 20 7 20 16 9 000 7 200 9 000 787 5 256 42 24 GeForce 7900 GT March 9 2006 PCIe x16 24 8 24 16 10 800 10 800 900 GeForce 7900 GTO October 1 2006 650 15 600 10 400 15 600 1 300 512 GeForce 7900 GTX March 9 2006 800 51 2 GeForce 7900 GX2 2x G71 500 600 2x 24 8 24 16 24 000 16 000 24 000 2 000 2x 512 2x 38 4 GeForce 7950 GT September 6 2006 PCIe April 2 2007 AGP G71 AGP 8xPCIe x16 550 700 24 8 24 16 13 200 8 800 13 200 1 100 512 44 8 GeForce 7950 GX2 June 5 2006 2x G71 PCIe x16 500 600 2x 24 8 24 16 24 000 16 000 24 000 2000 2x 512 2x 38 4 Model Launch Code name Fab nm 2 Transistors million Die size mm2 Bus interface Core clock MHz Memory clock MHz Core config a MOperations s MPixels s MTexels s MVertices s Size MB Bandwidth GB s Bus type Bus width bit Fillrate Memory a b Pixel shaders vertex shaders texture mapping units render output units Features edit Model Features Gamma correct antialiasing 64 bit OpenEXR HDR Scalable Link Interface SLI TurboCache Dual Link DVI GeForce 7100 GS No No Yes PCIe only No SLI bridge Yes No GeForce 7200 GS Yes Yes No Yes No GeForce 7300 SE Yes Yes No Yes No GeForce 7300 LE Yes Yes No Yes No GeForce 7300 GS Yes Yes Yes PCIe only Yes No GeForce 7300 GT Yes Yes Yes PCIe only No SLI bridge No One port GeForce 7600 GS Yes Yes Yes PCIe only No One port GeForce 7600 GT Yes Yes Yes PCIe only No One port GeForce 7600 GT 80 nm Yes Yes Yes No One port GeForce 7650 GS 80 nm Yes Yes Yes Depending on OEM Design No One port GeForce 7800 GS Yes Yes No No One port GeForce 7800 GT Yes Yes Yes No One port GeForce 7800 GTX Yes Yes Yes No One port GeForce 7800 GTX 512 Yes Yes Yes No One port GeForce 7900 GS Yes Yes Yes PCIe only No Two ports GeForce 7900 GT Yes Yes Yes No Two ports GeForce 7900 GTO Yes Yes Yes No Two ports GeForce 7900 GTX Yes Yes Yes No Two ports GeForce 7900 GX2 GTX Duo Yes Yes Yes No Two ports GeForce 7950 GT Yes Yes Yes PCIe only No Two ports GeForce 7950 GX2 Yes Yes Yes No Two ports GeForce 8 8xxx series edit Further information GeForce 8 series and Tesla microarchitecture All models support coverage sample anti aliasing angle independent anisotropic filtering and 128 bit OpenEXR HDR Model Launch Code name Fab nm 2 Transistors million Die size mm2 Bus interface Core config a Clock rate Fillrate Memory Supported API version Processing power GFLOPS b TDP Watts Comments Core MHz Shader MHz Memory MHz Pixel GP s Texture GT s Size MB Bandwidth GB s Bus type Bus width bit Direct3D OpenGL Single precision GeForce 8100 mGPU 44 2008 MCP78 TSMC 80 nm Un known Un known PCIe 2 0 x16 8 8 4 500 1200 400 system memory 2 4 Up to 512 from system memory 6 412 8 DDR2 64128 10 0 3 3 28 8 Un known The block of decoding of HD video PureVideo HD is disconnected GeForce 8200 mGPU 44 Un known Un known gt Un known PureVideo 3 with VP3 GeForce 8300 mGPU 44 Un known Un known 1500 Up to 512 from system memory 36 Un known GeForce 8300 GS 45 July 2007 G86 210 127 PCIe 1 0 x16 450 900 400 1 8 3 6 128512 6 4 64 14 4 40 OEM only GeForce 8400 GS June 15 2007 PCIe 1 0 x16PCI 16 8 4 128256512 28 8 GeForce 8400 GS rev 2 December 10 2007 G98 TSMC 65 nm 86 PCIe 2 0 x16PCIe x1PCI 8 8 4 567 1400 2 268 4 536 22 4 25 GeForce 8400 GS rev 3 July 12 2010 GT218 TSMC 40 nm 260 57 PCIe 2 0 x16 8 4 4 520589 1230 400 DDR2 600 DDR3 2 082 356 2 082 356 5121024 4 86 49 6 DDR2DDR3 3264 10 1 19 7 GeForce 8500 GT April 17 2007 G86 TSMC 80 nm 210 127 PCIe 1 0 x16PCI 16 8 4 450 900 400 1 8 3 6 2565121024 12 8 DDR2 128 10 0 28 8 45 GeForce 8600 GS April 2007 G84 289 169 PCIe 1 0 x16 16 8 8 540 1180 4 32 4 32 256512 75 5 47 OEM only GeForce 8600 GT April 17 2007 PCIe 1 0 x16PCI 32 16 8 1188 400700 8 64 2565121024 12 822 4 DDR2GDDR3 76 GeForce 8600 GTS PCIe 1 0 x16 675 1450 1000 5 4 10 8 256512 32 GDDR3 92 8 71 GeForce 8800 GS January 2008 G92 TSMC 65 nm 754 324 PCIe 2 0 x16 96 48 12 550 1375 800 6 6 26 4 384768 38 4 192 264 105 GeForce 8800 GTS G80 February 12 2007 320 November 8 2006 640 G80 TSMC 90 nm 681 484 PCIe 1 0 x16 96 24 20 513 1188 10 3 12 3 320640 64 320 228 146 GeForce 8800 GTS 112 G80 November 19 2007 112 28 c 20 500 1200 10 14 640 268 8 150 only XFX EVGA and BFG models very short lived 48 GeForce 8800 GT October 29 2007 512 December 11 2007 256 1024 G92 TSMC 65 nm 754 324 PCIe 2 0 x16 112 56 16 600 1500 700 256 900 512 1024 9 6 33 6 2565121024 57 6 256 336 125 GeForce 8800 GTS G92 December 11 2007 128 64 16 650 1625 970 10 4 41 6 512 62 1 416 135 GeForce 8800 GTX November 8 2006 G80 TSMC 90 nm 681 484 PCIe 1 0 x16 128 32 c 24 575 1350 900 13 8 18 4 768 86 4 384 345 6 145 GeForce 8800 Ultra May 2 2007 612 1500 1080 14 7 19 6 103 7 384 175 Model Launch Code name Fab nm 2 Transistors million Die size mm2 Bus interface Core config a Core MHz Shader MHz Memory MHz Pixel GP s Texture GT s Size MB Bandwidth GB s Bus type Bus width bit Direct3D OpenGL Single precision TDP Watts Comments Clock rate Fillrate Memory Supported API version Processing power GFLOPS b a b Unified shaders texture mapping units render output units a b To calculate the processing power see Performance a b Full G80 contains 32 texture address units and 64 texture filtering units unlike G92 which contains 64 texture address units and 64 texture filtering units 46 47 Features edit Compute Capability 1 1 has support for Atomic functions which are used to write thread safe programs Compute Capability 1 2 for details see CUDA Model Features ScalableLinkInterface SLI 3 WaySLI PureVideo HDwith VP1 PureVideo 2 with VP2 BSP Engine and AES128 Engine PureVideo 3 with VP3 BSP Engine and AES128 Engine PureVideo 4 with VP4 Computeability GeForce 8300 GS G86 No No No Yes No No 1 1 GeForce 8400 GS Rev 2 G98 No No No No Yes No 1 1 GeForce 8400 GS Rev 3 GT218 No No No No No Yes 1 2 GeForce 8500 GT Yes No No Yes No No 1 1 GeForce 8600 GT Yes No No Yes No No 1 1 GeForce 8600 GTS Yes No No Yes No No 1 1 GeForce 8800 GS G92 Yes No No Yes No No 1 1 GeForce 8800 GTS G80 Yes No Yes No No No 1 0 GeForce 8800 GTS Rev 2 G80 Yes No Yes No No No 1 0 GeForce 8800 GT G92 Yes No No Yes No No 1 1 GeForce 8800 GTS G92 Yes No No Yes No No 1 1 GeForce 8800 GTX Yes Yes Yes No No No 1 0 GeForce 8800 Ultra Yes Yes Yes No No No 1 0 GeForce 9 9xxx series edit Further information GeForce 9 series and Tesla microarchitecture All models support Coverage Sample Anti Aliasing Angle Independent Anisotropic Filtering 128 bit OpenEXR HDR Model Launch Code name Fab nm 2 Transistors million Die size mm2 Bus interface Core config a Clock rate Fillrate Memory Supported API version Processing power GFLOPS b TDP Watts Comments Core MHz Shader MHz Memory MHz Pixel GP s Texture GT s Size MB Bandwidth GB s Bus type Bus width bit Direct3D OpenGL Single precision GeForce 9300 mGPU October 2008 MCP7A S 65 nm 282 162 PCIe 2 0 x16 16 8 4 450 1200 400666 1 8 3 6 Up to 512 from system memory 6 4 12 810 664 21 328 DDR2DDR3 64128 10 0 3 3 57 6 Un known based on 8400 GS GeForce 9400 mGPU MCP7A U 580 1400 2 32 4 64 67 2 12 GeForce 9300 GE 49 June 2008 G98 TSMC 65 nm 210 86 8 8 4 540 1300 500 2 16 4 32 256 6 4 50 DDR2 64 20 8 25 GeForce 9300 GS 49 567 1400 2 268 4 536 22 4 GeForce 9400 GT August 27 2008 G96 200 c1G96aG96b TSMC 55 nm 314 144 PCIe 2 0 x16PCI 16 8 4 550 400800 2 2 4 4 2565121024 12 825 6 DDR2GDDR3 128 44 8 50 GeForce 9500 GS 24 12 4 500 16 0 DDR2 60 OEM GeForce 9500 GT July 29 2008 G96 300 C1 UMC 65 nm 32 16 8 500800 4 4 8 8 16 025 6 DDR2GDDR3 89 6 GeForce 9600 GS G94a TSMC 65 nm 505 240 PCIe 2 0 x16 48 24 12 500 1250 500 6 12 768 24 0 DDR2 192 120 Un known OEM GeForce 9600 GSO May 2008 G92 150 A2 754 324 96 48 12 550 1375 800 6 6 26 4 3847681536 38 4 GDDR3 264 84 GeForce 9600 GSO 512 October 2008 G94aG94b TSMC 65 nmTSMC 55 nm 505 240196 citation needed 48 24 16 650 1625 900 10 4 15 6 512 57 6 256 156 90 GeForce 9600 GT Green Edition 2009 G94b TSMC 55 nm 196 citation needed 64 32 16 600625 15001625 700 900900 citation needed 9 610 0 19 220 0 5121024 44 8 57 657 6 citation needed 192208 59 Core Voltage 1 00v GeForce 9600 GT February 21 2008 G94 300 A1 TSMC 65 nm 240 650 1625 900 10 4 20 8 57 6 208 95 GeForce 9800 GT Green Edition 2009 G92a2G92b TSMC UMC 65 nmTSMC UMC 55 nm 754 324260 112 56 16 550 1375 700800900 8 8 30 8 44 851 257 6 308 75 Core Voltage 1 00v GeForce 9800 GT July 2008 G92aG92b 65 nm UMC 55 nm 600 1500 900 9 6 33 6 57 6 336 125105 GeForce 9800 GTX April 1 2008 G92 420 A2 TSMC 65 nm 324 128 64 16 675 1688 1100 10 8 43 2 512 70 4 432 140 GeForce 9800 GTX July 16 2008 G92b TSMC 55 nm 260 738 1836 1100 11 808 47 232 5121024 470 141 GeForce 9800 GX2 March 18 2008 2x G92 TSMC UMC 65 nm 2x 754 2x 324 2x 128 64 16 600 1500 1000 2x 9 6 2x 38 4 2x 512 2x 64 0 2x 256 2x 384 197 Model Launch Code name Fab nm 2 Transistors million Die size mm2 Bus interface Core config a Core MHz Shader MHz Memory MHz Pixel GP s Texture GT s Size MB Bandwidth GB s Bus type Bus width bit Direct3D OpenGL Single precision TDP Watts Comments Clock rate Fillrate Memory Supported API version Processing power GFLOPS b a b Unified shaders texture mapping units render output units a b To calculate the processing power see Tesla microarchitecture Performance Features edit Compute Capability 1 1 has support for Atomic functions which are used to write thread safe programs Model Features Scalable Link Interface SLI PureVideo 2 with VP2 BSP Engine and AES128 Engine PureVideo 3 with VP3 BSP Engine and AES128 Engine GeForce 9300 GE G98 Yes No Yes GeForce 9300 GS G98 GeForce 9400 GT Yes No GeForce 9500 GT GeForce 9600 GSO GeForce 9600 GT GeForce 9800 GT GeForce 9800 GTX Yes3 way GeForce 9800 GTX GeForce 9800 GX2 Yes GeForce 100 series edit Further information GeForce 100 series and Tesla microarchitecture Model Launch Code name Fab nm Transistors million Die size mm2 Bus interface Core config a Clock rate Fillrate Memory configuration Supported API version Processing power GFLOPS b TDP Watts Comments Core MHz Shader MHz Memory MHz Pixel GP s Texture GT s Size MB Bandwidth GB s DRAM type Bus width bit Direct3D OpenGL Single precision GeForce G 100 March 10 2009 G98 TSMC 65 nm 210 86 PCIe 2 0 x16 8 8 4 567 1400 500 2 15 4 3 512 8 0 DDR2 64 10 0 3 3 22 4 35 OEM products GeForce GT 120 G96b TSMC 55 nm 314 121 32 16 8 500 800 4 4 8 8 16 0 128 89 6 50 GeForce GT 130 G94b 505 196 48 24 12 1250 500 6 12 1536 24 0 192 120 75 GeForce GT 140 64 32 16 650 1625 1800 10 4 20 8 512 1024 57 6 GDDR3 256 208 105 GeForce GTS 150 G92b 754 260 128 64 16 738 1836 1000 11 808 47 232 1024 64 0 470 141 Unified shaders texture mapping units render output units To calculate the processing power see Tesla microarchitecture Performance GeForce 200 series edit Further information GeForce 200 series and Tesla microarchitecture All models support Coverage Sample Anti Aliasing Angle Independent Anisotropic Filtering 240 bit OpenEXR HDR Model Launch Code name Fab nm Transistors million Die size mm2 Bus interface Core config a Clock rate Fillrate Memory configuration Supported API version Processing power GFLOPS b TDP Watts Comments Release Price USD Core MHz Shader MHz Memory MT s Pixel GP s Texture GT s Size MB Bandwidth GB s DRAM type Bus width bit Direct3D OpenGL Single precision GeForce 205 November 26 2009 GT218 TSMC 40 nm 260 57 PCIe 2 0 x16 8 4 4 589 1402 1000 2 356 2 356 512 8 DDR2 64 10 1 3 3 22 4 30 5 OEM only GeForce 210 October 12 2009 GT218 325 B1 PCIe 2 0 x16PCIe x1PCI 16 8 4 520589 12301402 8001000 1600 2 356 4 712 5121024 4 08 012 8 DDR2DDR3 3264 36 444 9 30 5 GeForce GT 220 GT216 300 A2 TSMC 40 nm 486 100 PCIe 2 0 x16 48 16 8 615 OEM 625 1335 OEM 1360 10001580 5 10 5121024 16 025 3 DDR2DDR3 64128 128 2 OEM 130 6 58 GeForce GT 230 October 12 2009 51 G94b TSMC UMC 55 nm 505 196 48 24 16 650 1625 1800 10 4 15 6 5121024 57 6 GDDR3 256 10 156 75 OEM only April 27 2009 52 G92b 754 260 96 48 12 500 1242 1000 6 24 1536 24 DDR2 192 238 5 GeForce GT 240 November 17 2009 GT215 450 A2 TSMC 40 nm 727 139 96 32 8 550 1340 180020003400 GDDR5 4 4 17 6 5121024 28 8 OEM 3254 4 GDDR5 DDR3GDDR3GDDR5 128 10 1 257 3 69 GeForce GTS 240 July 1 2009 53 G92aG92b TSMC 65 nmTSMC UMC 55 nm 754 324260 112 56 16 675 1620 2200 10 8 37 8 1024 70 4 GDDR3 256 10 0 362 9 120 OEM only GeForce GTS 250 2009 G92b TSMC UMC 55 nm 260 128 64 16 702 1512 2000 11 2 44 9 5121024 64 0 387 130 March 3 2009 G92 428 B1 TSMC 65 nmTSMC UMC 55 nm 738 1836 20002200 11 808 47 232 5121024 64 070 4 470 150 Some cards are rebranded GeForce 9800 GTX 150 130 512MB GeForce GTX 260 June 16 2008 GT200 100 A2 65 nm 1400 576 192 64 28 576 1242 1998 16 128 36 864 896 111 9 448 477 182 Replaced by GTX 260 Core 216 400 dropped to 270 after 3 months 54 September 16 2008 November 27 2008 55 nm GT200 103 A2 65 nm55 nm 576470 216 72 28 576 12421350 1998 16 128 41 472 896 1792 111 9 536 5583 2 182171 300 GeForce GTX 275 April 9 2009 GT200 105 B3 TSMC UMC 55 nm 470 240 80 28 633 1404 2268 17 724 50 6 896 1792 127 0 674 219 Effectively one half of the GTX 295 250 GeForce GTX 280 June 17 2008 GT200 300 A2 65 nm 576 240 80 32 602 1296 2214 19 264 48 16 1024 141 7 512 622 236 Replaced by GTX 285 650 dropped to 430 after 3 months 54 GeForce GTX 285 January 15 2009 GT200 350 B3 TSMC UMC 55 nm 470 648 1476 2484 20 736 51 84 1024 2048 159 0 512 708 48 204 EVGA GTX285 Classified supports 4 way SLI 400 GeForce GTX 295 January 8 2009 2x GT200 400 B3 2x 1400 2x 470 2x 240 80 28 576 1242 1998 2x 16 128 2x 46 08 2x 896 2x 111 9 2x 448 1192 3 289 Dual PCB models were replaced with a single PCB model with 2 GPUs 500 Model Launch Code name Fab nm Transistors million Die size mm2 Bus interface Core config a Core MHz Shader MHz Memory MHz Pixel GP s Texture GT s Size MB Bandwidth GB s DRAM type Bus width bit Direct3D OpenGL Single precision TDP Watts Comments Release Price USD Clock rate Fillrate Memory configuration Supported API version Processing power GFLOPS b a b Unified shaders texture mapping units render output units a b To calculate the processing power see Tesla microarchitecture Performance Features edit Compute Capability 1 1 G92 GTS250 GPU Compute Capability 1 2 GT215 GT216 GT218 GPUs Compute Capability 1 3 has double precision support for use in GPGPU applications GT200a b GPUs only Model Features Scalable Link Interface SLI PureVideo 2 with VP2Engine BSP and 240 AES PureVideo 4 with VP4 Engine GeForce 210 No No Yes GeForce GT 220 GeForce GT 240 GeForce GTS 250 Yes3 Way 4 way for EVGA 285 Classified Yes No GeForce GTX 260 GeForce GTX 260 Core 216 GeForce GTX 260 Core 216 55 nm GeForce GTX 275 GeForce GTX 280 GeForce GTX 285 GeForce GTX 295 Yes GeForce 300 series edit Further information GeForce 300 series and Tesla microarchitecture All models support the following API levels Direct3D 10 1 and OpenGL 3 3 Model Launch Code name Fab nm Transistors million Die size mm2 Bus interface Core config a Clock rate Fillrate Memory configuration Processing power GFLOPS b TDP Watts Comments Core MHz Shader MHz Memory MHz Pixel GP s Texture GT s Size MB Bandwidth GB s DRAM type Bus width bit Single precision GeForce 310 November 27 2009 GT218 TSMC 40 nm 260 57 PCIe 2 0 x16 16 8 4 589 1402 1000 2 356 4 712 512 8 DDR2 64 44 8 30 5 OEM Card similar to Geforce 210 GeForce 315 February 2010 GT216 486 100 48 16 4 475 1100 1580 3 8 7 6 512 12 6 DDR3 105 6 33 OEM Card similar to Geforce GT220 GeForce GT 320 GT215 727 144 72 24 8 540 1302 4 32 12 96 1024 25 3 GDDR3 128 187 5 43 OEM Card GeForce GT 330 55 GT215 301 A3 56 96 32 8 550 1350 4 40 17 60 512 32 00 128 257 3 75 Specifications vary depending on OEM similar to GT230 v2 G92 57 500 1250 4 000 24 00 256 51 20 256 240 0 G92B 58 96 32 16 8 000 1024 16 32 DDR2 128 GeForce GT 340 GT215 96 32 8 550 1340 3400 5121024 54 4 GDDR5 59 128 257 3 69 OEM Card similar to GT240 Unified shaders texture mapping units render output units To calculate the processing power see Tesla microarchitecture Performance GeForce 400 series edit Further information GeForce 400 series and Fermi microarchitecture All cards have a PCIe 2 0 x16 Bus interface The base requirement for Vulkan 1 0 in terms of hardware features was OpenGL ES 3 1 which is a subset of OpenGL 4 3 which is supported on all Fermi and newer cards Memory bandwidths stated in the following table refer to Nvidia reference designs Actual bandwidth can be higher or lower depending on the maker of the graphic board Model Launch Code name Fab nm Transistors million Die size mm2 SM count Core config a b Clock rate Fillrate Memory configuration Supported API version Processing power GFLOPS c TDP Watts d Release Price USD Core MHz Shader MHz Memory MHz Pixel GP s Texture GT s Size MB Bandwidth GB s DRAM type Bus width bit Vulkan Direct3D OpenGL OpenCL e Single precision Double precision GeForce 405 f September 16 2011 GT216GT218 40 nm 486260 10057 1 48 16 816 8 4 475589 11001402 800790 3 82 36 7 64 71 5121024 12 6 DDR3 64 n a 63 10 1 3 3 1 1 105 644 86 Un known 30 5 OEM GeForce GT 420 September 3 2010 GF108 TSMC 40 nm 585 116 48 4 4 700 1400 1800 2 8 2 8 512 28 8 GDDR3 128 12 FL 11 1 4 6 134 4 Un known 50 GeForce GT 430 October 11 2010 GF108GF108 300 A1 2 96 16 4 16001800 11 2 512 25 628 8 1 2 268 8 Un known 60 1800 51210242048 28 8 128 1 1 268 8 Unknown 49 79 1300 10 4 64 GeForce GT 440 February 1 2011 GF108 810 1620 18003200 3 2 12 9 5121024 28 851 2 GDDR3GDDR5 128 311 04 Un known 65 100 October 11 2010 GF106 1170 238 3 144 24 24 594 1189 16001800 4 86 19 44 15363072 43 2 DDR3 192 342 43 Un known 56 OEM GeForce GTS 450 790 1580 4000 4 7 18 9 1536 96 0 GDDR5 455 04 Un known 106 September 13 2010March 15 2011 GF106 250GF116 200 4 192 32 16 783 1566 1200 1600 GDDR3 3608 GDDR5 6 2 25 0 5121024 57 7 128 601 34 Un known 106 129 GeForce GTX 460 SE November 15 2010 GF104 225 A1 1950 332 6 288 48 32 650 1300 3400 7 8 31 2 1024 108 8 256 748 8 Un known 150 160 GeForce GTX 460 October 11 2010 GF104 7 336 56 32 9 1 36 4 1024 108 8 873 6 Un known OEM July 12 2010 GF104 300 KB A1 336 56 24 675 1350 3600 9 4 37 8 768 86 4 192 907 2 Unknown 199 336 56 32 10242048 115 2 256 160 229 September 24 2011 GF114 336 56 24 779 1557 4008 10 9 43 6 1024 96 2 192 1045 6 Un known 199 GeForce GTX 465 May 31 2010 GF100 030 A3 3000 64 529 11 352 44 32 608 1215 3206 13 3 26 7 1024 102 7 256 1 2 855 36 106 92 200 d 279 GeForce GTX 470 March 26 2010 GF100 275 A3 14 448 56 40 3348 17 0 34 0 1280 133 9 320 1088 64 136 08 215 d 349 GeForce GTX 480 March 26 2010 GF100 375 A3 15 480 60 48 701 1401 3696 21 0 42 0 1536 177 4 384 1344 96 168 12 250 d 499 Model Launch Code name Fab nm Transistors million Die size mm2 SM count Core config a b Clock rate Fillrate Memory configuration Supported API version Processing power GFLOPS c TDP Watts d Release Price USD Core MHz Shader MHz Memory MHz Pixel GP s Texture GT s Size MB Bandwidth GB s DRAM type Bus width bit Vulkan Direct3D OpenGL OpenCL e Single precision Double precision a b Unified shaders texture mapping units render output units a b Each SM in the GF100 contains 4 texture filtering units for every texture address unit The complete GF100 die contains 64 texture address units and 256 texture filtering units 60 Each SM in the GF104 106 108 architecture contains 8 texture filtering units for every texture address unit but has doubled both addressing and filtering units The complete GF104 die also contains 64 texture address units and 512 texture filtering units despite the halved SM count the complete GF106 die contains 32 texture address units and 256 texture filtering units and the complete GF108 die contains 16 texture address units and 128 texture filtering units 61 a b To calculate the processing power see Fermi microarchitecture Performance a b c d e Note that while GTX 460 s TDP is comparable to that of AMD s HD5000 series GF100 based cards GTX 480 470 465 are rated much lower but pull significantly more power e g GTX 480 with 250W TDP consumes More power than an HD 5970 with 297W TDP 62 a b The 400 series is the only non OEM family from GeForce 9 to 700 series not to include an official dual GPU system However on March 18 2011 EVGA released the first single PCB card with dual 460s on board The card came with 2048 MB of memory at 3600 MHz and 672 shader processors at 1400 MHz and was offered at the MSRP of 429 The GeForce 405 card is a rebranded GeForce 310 which itself is a rebranded GeForce 210 GeForce 500 series edit Further information GeForce 500 series and Fermi microarchitecture Model Launch Code name Fab nm Transistors million Die size mm2 Bus interface SM count Core config a b Clock rate Fillrate Memory configuration Supported API version Processing power GFLOPS c TDP watts d Release Price USD Core MHz Shader MHz Memory MHz Pixel GP s Texture GT s Size MB Bandwidth GB s DRAM type Bus width bit Vulkan Direct3D OpenGL OpenCL8 Single precision Double precision GeForce 510 September 29 2011 GF119 TSMC 40 nm 292 79 PCIe 2 0 x16 1 48 8 4 523 1046 1800 2 1 4 5 10242048 14 4 DDR3 64 n a 63 12 FL 11 1 4 6 1 1 100 4 Un known 25 OEM GeForce GT 520 April 12 2011 PCIe 2 0 x16PCIe 2 0 x1PCI 810 1620 3 25 6 5 14 4 155 5 Un known 29 59 GeForce GT 530 67 May 14 2011 GF108 220 585 116 PCIe 2 0 x16 2 96 16 4 700 1400 2 8 11 2 28 8 128 268 8 22 40 50 OEM GeForce GT 545 GF116 1170 238 3 144 24 16 720 1440 11 52 17 28 15363072 43 192 415 07 Un known 70 149 870 1740 3996 13 92 20 88 1024 64 GDDR5 128 501 12 Un known 105 OEM GeForce GTX 550 Ti March 15 2011 GF116 400 4 192 32 24 900 1800 4104 21 6 28 8 768 2561536 65 7 32 898 5 128 64 e 192 691 2 Un known 116 149 GeForce GTX 555 May 14 2011 GF114 1950 332 6 288 48 24 736 1472 3828 17 6 35 3 1024 91 9 128 64 e 847 9 Un known 150 OEM GeForce GTX 560 SE February 20 2012 68 GF114 200 KB A1 f Un known GeForce GTX 560 May 17 2011 GF114 325 A1 f 7 336 56 32 810 1620 4008 25 92 45 36 1024 2048 128 1 256 1088 6 Un known 199 GeForce GTX 560 Ti January 25 2011 GF114 400 A1 f 8 384 64 32 822 1645 26 3 52 61 128 26 1263 4 110 170 249 May 30 2011 GF110 g 3000 70 520 70 11 352 44 40 732 1464 3800 29 28 32 21 12802560 152 320 1030 7 128 83 210 d OEM GeForce GTX 560 Ti 448 Cores November 29 2011 GF110 270 A1 g 14 448 56 40 40 99 1280 1311 7 163 97 289 GeForce GTX 570 December 7 2010 GF110 275 A1 g 15 480 60 40 43 92 1280 2560 1405 4 175 68 219 d 349 GeForce GTX 580 November 9 2010 GF110 375 A1 g 16 512 64 48 772 1544 4008 37 05 49 41 15363072 h 192 384 384 1581 1 197 63 244 d 72 499 GeForce GTX 590 March 24 2011 2x GF110 351 A1 2x 3000 2x 520 2x16 2x 512 64 48 607 1215 3414 2x29 14 2x38 85 2x 1536 2x163 87 2x384 2488 3 311 04 365 699 Model Launch Code name Fab nm Transistors million Die size mm2 Bus interface SM count Core config a b Clock rate Fillrate Memory configuration Supported API version Processing power GFLOPS c TDP Watts d Release Price USD Core MHz Shader MHz Memory MHz Pixel GP s Texture GT s Size MB Bandwidth GB s DRAM type Bus width bit Vulkan Direct3D OpenGL OpenCL8 Single precision Double precision a b Unified shaders texture mapping units render output units a b Each SM in the GF110 contains 4 texture filtering units for every texture address unit The complete GF110 die contains 64 texture address units and 256 texture filtering units 65 Each SM in the GF114 116 118 architecture contains 8 texture filtering units for every texture address unit but has doubled both addressing and filtering units a b To calculate the processing power see Fermi microarchitecture Performance a b c d e Similar to previous generation GTX 580 and most likely future GTX 570 needs update while reflecting its improvement over GF100 still have lower rated TDP and higher power consumption e g GTX580 243W TDP is slightly less power hungry than GTX 480 250W TDP This is managed by clock throttling through drivers when a dedicated power hungry application is identified that could breach card TDP Application name changing will disable throttling and enable full power consumption which in some cases could be close to that of GTX480 66 a b 1024 MB RAM on 192 bit bus assemble with 4 x 128 MB 2 x 256 MB a b c Internally referred to as GF104B 69 a b c d Internally referred to as GF100B 69 Some companies have announced that they will be offering the GTX580 with 3GB RAM 71 GeForce 600 series edit Further information GeForce 600 series and Kepler microarchitecture Add NVENC on GTX cards Several 600 series cards are rebranded 400 or 500 series cards Model Launch Code name Fab nm Transistors million Die size mm2 Bus interface SM count Core config a Clock rate Fillrate Memory configuration Supported API version Processing power GFLOPS b TDP Watts Release Price USD Core MHz Average Boost MHz Max Boost MHz Shader MHz Memory MHz Pixel GP s Texture GT s Size MB Bandwidth GB s DRAM type Bus width bit Vulkan c Direct3D OpenGL OpenCL Single precision Double precision GeForce 605 d April 3 2012 GF119 TSMC 40 nm 292 79 PCIe 2 0 x16 1 48 8 4 523 1046 898 1796 2 09 4 2 512 1024 14 4 DDR3 64 12 4 6 1 2 100 4 Un known 25 OEM GeForce GT 610 e May 15 2012 GF119 300 A1 PCIe 2 0 x16 PCIe x1 PCI 48 8 4 810 1620 10001800 3 24 6 5 51210242048 814 4 155 5 Un known 29 Retail GeForce GT 620 f April 3 2012 GF119 PCIe 2 0 x16 48 8 4 898 1796 6 5 5121024 14 4 155 5 Un known 30 OEM May 15 2012 GF108 100 KB A1 585 116 2 96 16 4 700 1400 1000 1800 2 8 11 2 10242048 8 14 4 268 8 Un known 49 Retail GeForce GT 625 February 19 2013 GF119 292 79 1 48 8 4 810 1620 898 1796 3 24 6 5 512 1024 14 4 155 5 Un known 30 OEM GeForce GT 630 g h April 24 2012 GK107 TSMC 28 nm 1300 118 PCIe 3 0 x16 192 16 16 875 875 891 1782 14 14 10242048 28 5 128 1 2 336 14 50 May 15 2012 GF108 400 A1 TSMC 40 nm 585 116 PCIe 2 0 x16 2 96 16 4 700 1620 1600 1800 2 8 11 2 102420484096 25 6 28 8 311 Un known 49 Retail GF108 96 16 4 810 1620 800 3200 3 2 13 1024 51 2 GDDR5 311 Un known 65 May 29 2013 GK208 301 A1 TSMC 28 nm 1020 79 PCIe 2 0 x8 1 384 16 8 902 902 900 1800 7 22 14 44 10242048 14 4 DDR3 64 1 2 692 7 Un known 25 GeForce GT 635 February 19 2013 GK208 PCIe 3 0 x8 384 16 8 967 967 1001 2002 7 74 15 5 16 742 7 Un known 35 OEM GeForce GT 640 i April 24 2012 GF116 TSMC 40 nm 1170 238 PCIe 2 0 x16 3 144 24 24 720 1440 891 1782 17 3 17 3 15363072 42 8 192 414 7 Un known 75 GK107 TSMC 28 nm 1300 118 PCIe 3 0 x16 2 384 32 16 797 797 891 1782 12 8 25 5 10242048 28 5 128 1 2 612 1 25 50 50 June 5 2012 900 900 891 1782 14 4 28 8 20484096 28 5 691 2 28 8 65 100 April 24 2012 950 950 1250 5000 15 2 30 4 10242048 80 GDDR5 729 6 30 40 75 OEM May 29 2013 GK208 400 A1 TSMC 28 nm 1020 79 PCIe 2 0 x8 384 16 8 1046 1046 1252 5008 8 37 16 7 1024 40 1 64 803 3 Un known 49 GeForce GT 645 j April 24 2012 GF114 400 A1 TSMC 40 nm 1950 332 PCIe 2 0 x16 6 288 48 24 776 1552 1914 18 6 37 3 91 9 192 894 Un known 140 OEM GeForce GTX 645 April 22 2013 GK106 TSMC 28 nm 2540 221 PCIe 3 0 x16 3 576 48 16 823 5 888 5 823 1000 4000 14 16 39 5 64 128 1 2 948 1 39 53 64 GeForce GTX 650 September 13 2012 GK107 450 A2 1300 118 2 384 32 16 1058 1058 1250 5000 16 9 33 8 10242048 80 812 54 33 86 110 November 27 2013 73 GK 106 400 A1 2540 221 65 GeForce GTX 650 Ti October 9 2012 GK106 220 A1 4 768 64 16 928 928 1350 5400 14 8 59 4 86 4 1425 41 59 39 110 150 130 GeForce GTX 650 Ti Boost March 26 2013 GK106 240 A1 768 64 24 980 1032 980 1502 6008 23 5 62 7 144 2 192 1505 28 62 72 134 170 150 GeForce GTX 660 September 13 2012 GK106 400 A1 5 960 80 24 1084 1502 6008 23 5 78 4 1536 5123072 96 1 48 1144 2 128 64192 1881 6 78 40 140 230 180 August 22 2012 GK104 200 KD A2 3540 294 6 1152 96 241152 96 32 823 5 888 5 899 823 1450 5800 19 8 79 153620483072 139 186 192256 2108 6 79 06 130 OEM GeForce GTX 660 Ti August 16 2012 GK104 300 KD A2 7 1344 112 24 915 980 1058 915 1502 6008 22 0 102 5 2048 96 1 48 1144 2 128 64192 2459 52 102 48 150 300 GeForce GTX 670 May 10 2012 GK104 325 A2 1344 112 32 1084 1502 6008 29 3 102 5 20484096 192 256 256 2459 52 102 48 170 400 GeForce GTX 680 March 22 2012 GK104 400 A2 8 1536 128 32 1006 74 1058 1110 1006 1502 6008 32 2 128 8 192 256 3090 43 128 77 195 500 GeForce GTX 690 April 29 2012 2x GK104 355 A2 2x 3540 2x 294 2x 8 2x 1536 128 32 915 1019 1058 915 1502 6008 2x 29 28 2x 117 12 2x 2048 2x 192 256 2x 256 2x 2810 88 2x 117 12 300 1000 Model Launch Code name Fab nm Transistors million Die size mm2 Bus interface SM count Core config a Clock rate Fillrate Memory configuration Supported API version Processing power GFLOPS b TDP Watts Release Price USD Core MHz Average Boost MHz Max Boost MHz Shader MHz Memory MHz Pixel GP s Texture GT s Size MB Bandwidth GB s DRAM type Bus width bit Vulkan c Direct3D OpenGL OpenCL Single precision Double precision a b Unified shaders texture mapping units render output units a b To calculate the processing power see Kepler microarchitecture Performance or Fermi microarchitecture Performance a b Vulkan 1 2 is only supported on Kepler cards 63 The GeForce 605 OEM card is a rebranded GeForce 510 The GeForce GT 610 card is a rebranded GeForce GT 520 The GeForce GT 620 OEM card is a rebranded GeForce GT 520 The GeForce GT 630 DDR3 128 bit retail card is a rebranded GeForce GT 430 DDR3 128 bit The GeForce GT 630 GDDR5 card is a rebranded GeForce GT 440 GDDR5 The GeForce GT 640 OEM GF116 card is a rebranded GeForce GT 545 DDR3 The GeForce GT 645 OEM card is a rebranded GeForce GTX 560 SE GeForce 700 series edit Further information GeForce 700 series and Kepler microarchitecture The GeForce 700 series for desktop The GM107 chips are Maxwell based the GKxxx chips Kepler Improve NVENC Model Launch Code name Fab nm Transistors million Die size mm2 Bus interface SMX count Core config a Clock rate Fillrate Memory configuration Supported API version Processing power GFLOPS b TDP Watts Release Price USD Base MHz Average Boost MHz Max Boost c MHz Memory MHz Pixel GP s Texture GT s Size MB Bandwidth GB s DRAM type Bus width bit Vulkan d Direct3D e OpenGL OpenCL Single precision Double precision GeForce GT 705 77 f March 27 2014 GF119 300 A1 TSMC 40 nm 292 79 PCIe 2 0 x16 1 48 8 4 810 898 1796 3 24 6 5 5121024 14 4 DDR3 64 n a 12 4 6 1 1 155 5 19 4 29 OEM GeForce GT 710 78 GK208 301 A1 TSMC 28 nm 1020 79 PCIe 2 0 x8 192 16 8 823 900 1800 6 6 13 2 512 64 1 2 1 2 316 0 13 2 January 26 2016 GK208 203 B1 PCIe 2 0 x8 PCIe x1 192 16 8 954 900 1800 1253 5010 7 6 15 3 10242048 14 440 0 DDR3GDDR5 366 15 3 19 35 45 GeForce GT 720 79 March 27 2014 GK208 201 B1 PCIe 2 0 x8 192 16 8 797 900 1800 1253 5010 6 4 12 8 10242048 14 440 0 306 12 8 49 59 GeForce GT 730 80 g h June 18 2014 GK208 301 A1 2 384 16 8 902 900 1800 7 22 14 44 1024 81 20484096 14 4 DDR3 692 7 28 9 23 69 79 GK208 400 A1 384 16 8 902 1250 5000 7 22 14 44 10242048 82 40 0 GDDR5 25 GF108 TSMC 40 nm 585 116 PCIe 2 0 x16 96 16 4 700 900 1800 2 8 11 0 102420484096 28 8 DDR3 128 n a 1 1 268 8 33 6 49 GeForce GT 740 i May 29 2014 GK107 425 A2 TSMC28HP 1270 118 PCIe 3 0 x16 384 32 16 993 891 1782 15 9 31 8 28 5 128 1 2 1 2 762 6 31 8 64 89 99 384 32 16 993 1252 5008 15 9 31 8 80 1 GDDR5 GeForce GTX 745 February 18 2014 GM107 220 A2 1870 148 3 384 24 16 1033 Un known Un known 900 1800 16 5 24 8 10244096 28 8 DDR3 1 3 793 3 24 8 55 OEM GeForce GTX 750 GM107 300 A2 4 512 32 16 1020 1085 1163 1250 5000 16 3 32 6 102420484096 83 80 GDDR5 1044 5 32 6 119 GeForce GTX 750 Ti GM107 400 A2 5 640 40 16 1020 1085 1200 1350 5400 16 3 40 8 102420484096 86 4 1305 6 40 8 60 149 GeForce GTX 760 192 bit October 17 2013 GK104 200 KD A2 3540 294 6 1152 96 24 824 888 889 1450 5800 19 8 79 1 15363072 139 2 192 1 2 1896 2 79 0 130 OEM GeForce GTX 760 June 25 2013 GK104 225 A2 1152 96 32 980 1033 1124 1502 6008 31 4 j 94 20484096 192 3 256 2257 9 94 1 170 249 219 GeForce GTX 760 Ti k September 27 2013 84 GK104 7 1344 112 32 915 980 1084 1502 6008 29 3 102 5 2048 192 3 2459 5 102 5 OEM GeForce GTX 770 May 30 2013 GK104 425 A2 8 1536 128 32 1046 1085 1130 1752 5 7010 33 5 134 2048 4096 224 3213 3 133 9 230 399 329 GeForce GTX 780 May 23 2013 GK110 300 A1 7080 561 12 2304 192 48 863 900 1002 1502 6008 41 4 j 160 5 3072 6144 85 288 4 384 3976 7 165 7 649 499 GeForce GTX 780 Ti 86 87 88 November 7 2013 GK110 425 B1 15 2880 240 48 876 928 1019 1752 5 7010 42 0 j 210 2 3072 336 5 5045 7 210 2 699 GeForce GTX TITAN 89 90 91 February 21 2013 GK110 400 A1 14 2688 224 48 837 876 993 1502 6008 40 2 187 5 6144 288 4 4499 7 1300 92 1499 9 999 GeForce GTX TITAN Black February 18 2014 GK110 430 B1 15 2880 240 48 889 980 1058 1752 5 7010 42 7 213 4 336 5 5120 6 1706 9 GeForce GTX TITAN Z May 28 2014 2x GK110 350 B1 93 2x 7080 2x 561 2x 15 2x 2880 240 48 705 876 Un known 1752 5 7010 2x 33 8 2x 169 2x 6144 2x 336 5 2x 384 4 5 5046x2 1682x2 94 375 2999 Model Launch Code name Fab nm Transistors million Die size mm2 Bus interface SMX count Core config a Clock rate Fillrate Memory configuration Supported API version Processing power GFLOPS b TDP Watts Release Price USD Base MHz Average Boost MHz Max Boost c MHz Memory MHz Pixel GP s Texture GT s Size MB Bandwidth GB s DRAM type Bus width bit Vulkan d Direct3D e OpenGL OpenCL Single precision Double precision a b Unified shaders texture mapping units render output units a b To calculate the processing power see Maxwell microarchitecture Performance or Kepler microarchitecture Performance a b Max Boost depends on ASIC quality For example some GTX TITAN with over 80 ASIC quality can hit 1019 MHz by default lower ASIC quality will be 1006 MHz or 993 MHz a b Maxwell supports Vulkan version 1 3 while Kepler only support Vulkan version 1 2 Fermi does not support the Vulkan API at all 63 a b Kepler supports some optional 11 1 features on feature level 11 0 through the Direct3D 11 1 API however Nvidia did not enable four non gaming features to qualify Kepler for level 11 1 75 76 The GeForce GT 705 OEM is a rebranded GeForce GT 610 which itself is a rebranded GeForce GT 520 The GeForce GT 730 DDR3 64 bit is a rebranded GeForce GT 630 Rev 2 The GeForce GT 730 DDR3 128 bit is a rebranded GeForce GT 630 128 bit The GeForce GT 740 OEM is a rebranded GeForce GTX 650 a b c As a Kepler GPC is able to rasterize 8 pixels per clock fully enabled GK110 GPUs 780 Ti TITAN Black can only output 40 pixels per clock 5 GPCs despite 48 ROPs and all SMX units being physically present For GTX 780 and GTX 760 multiple GPC configurations with differing pixel fillrate are possible depending on which SMXs were disabled in the chip 5 4 GPCs or 4 3 GPCs respectively The GeForce GTX 760 Ti OEM is a rebranded GeForce GTX 670 GeForce 900 series edit Further information GeForce 900 series and Maxwell microarchitecture All models support the following APIs Direct3D 12 1 OpenGL 4 6 OpenCL 3 0 and Vulkan 1 3 63 and CUDA 5 2 Improve NVENC YUV4 4 4 predictive lossless encoding Add H265 hardware support on GM20x GM108 does not have NVENC hardware encoder support Model Launch Code name Process Transistors billion Die size mm2 Core config a Bus interface L2 Cache MB Clock Speeds Memory Fillrate b Processing power GFLOPS b c TDP Watts SLI support Release price USD Base MHz Boost MHz Memory MT s Size GB Bandwidth GB s Bus type Bus width bit Pixel GP s d Texture GT s e Single precision Double precision MSRP GeForce GT 945A 95 96 97 February 2016 GM108 TSMC28HP Un known Un known 512 24 8 4 PCIe 3 0 x8 1072 1176 1800 1 2 14 4 DDR3 GDDR5 64 8 59 4 25 728 2 1 097 71 204 2 34 337 6 33 No OEM GeForce GTX 950 98 August 20 2015 GM206 250 2 94 227 768 48 32 6 PCIe 3 0 x16 1 1024 1188 6600 2 105 7 GDDR5 128 32 738 0 49 157 0 1 572 81 824 7 49 157 0 90 75 f 2 way SLI 159 GeForce GTX 950 OEM 100 Un known GM206 1024 64 32 8 935 Un known 5000 80 0 29 9 59 8 1 914 9 59 8 Un known OEM GeForce GTX 960 101 January 22 2015 GM206 300 1127 1178 7000 24 112 1 36 037 6 72 175 3 2 308 02 412 5 72 175 3 120 199 GeForce GTX 960 OEM 102 Un known GM204 5 2 398 1280 80 48 10 924 Un known 5000 3 120 0 192 44 3 73 9 2 365 4 73 9 Un known OEM GeForce GTX 970 103 September 18 2014 GM204 200 1664 104 56 13 1 75 1050 1178 7000 3 5 0 5 g 196 3 28 0 g 224 32 g 58 865 9 109 2122 5 3 494 43 920 3 109 2122 5 145 4 way SLI 329 GeForce GTX 980 105 September 18 2014 GM204 400 2048 128 64 16 2 1126 1216 4 224 3 256 72 077 8 144 1155 6 4 612 04 980 7 144 1155 6 165 549 GeForce GTX 980 Ti 106 June 1 2015 GM200 310 8 601 2816 176 96 22 3 1000 1075 6 336 5 384 96 0103 2 176 0189 2 5 632 06 054 4 176 0189 2 250 649 GeForce GTX TITAN X 107 March 17 2015 GM200 400 3072 192 96 24 12 192 0206 4 6 144 06 604 8 192 0206 4 999 Main shader processors texture mapping units render output units streaming multiprocessors a b Base clock Boost clock To calculate the processing power see Maxwell microarchitecture Performance Pixel fillrate is calculated as the number of ROPs multiplied by the respective core clock speed Texture fillrate is calculated as the number of TMUs multiplied by the respective core clock speed Some GTX950 cards were released without power connector powered only by PCIe slot These had limited power consumption and TPD to 75W 99 a b c For accessing its memory the GTX 970 stripes data across 7 of its 8 32 bit physical memory lanes at 196 GB s The last 1 8 of its memory 0 5 GB on a 4 GB card is accessed on a non interleaved solitary 32 bit connection at 28 GB s one seventh the speed of the rest of the memory space Because this smaller memory pool uses the same connection as the 7th lane to the larger main pool it contends with accesses to the larger block reducing the effective memory bandwidth not adding to it as an independent connection could 104 GeForce 10 series edit Further information GeForce 10 series and Pascal microarchitecture Supported display standards DP 1 4 no DSC HDMI 2 0b Dual link DVI a 108 Supported APIs Direct3D 12 12 1 OpenGL 4 6 OpenCL 3 0 Vulkan 1 3 63 and CUDA 6 1 Improved NVENC HEVC Main10 decode 8K30 etc Model Launch Code name Process Transistors billion Die size mm2 Core config b Bus interface L2 Cache MB Clock speeds Memory Fillrate c Processing power GFLOPS c d TDP Watts SLI support Release price USD Base core MHz Boost core MHz Memory MT s Size GB Bandwidth GB s Bus type Bus width bit Pixel GP s e f Texture GT s g Single precision Double precision Half precision MSRP Founders Edition GeForce GT 1010 111 112 January 13 2021 GP108 200 A1 Samsung14LPP 1 8 74 256 16 16 2 1 PCIe 3 0 x4 0 25 1228 1468 5000 2 40 1 GDDR5 64 9 811 8 19 723 5 628 7751 6 26 231 3 30 No OEM 1152 1380 2100 16 8 DDR4 9 211 0 18 422 0 590 0706 6 24 629 4 20 GeForce GT 1030 113 114 115 116 March 12 2018 GP108 310 A1 384 24 16 3 1 0 5 1379 18 422 0 27 633 0 884 71 059 0 27 633 0 13 816 5 79 May 17 2017 GP108 300 A1 1227 1468 6000 48 0 GDDR5 19 623 4 29 435 2 942 31 127 4 29 435 2 14 717 6 30 69 GeForce GTX 1050 117 October 25 2016 GP107 300 A1 3 3 132 640 40 32 5 2 PCIe 3 0 x16 1 1354 1455 7000 112 0 128 43 346 6 54 158 8 1 733 11 862 4 54 158 2 27 029 1 75 109 May 21 2018 GP107 301 A1 768 48 24 6 2 0 75 1392 1518 3 84 0 96 33 436 4 66 872 9 2 138 12 331 6 66 872 9 33 436 4 GeForce GTX 1050 Ti 117 October 25 2016 GP107 400 A1 768 48 32 6 2 1 1290 1392 4 112 0 128 41 244 5 61 966 8 1 981 42 138 1 61 966 8 30 933 4 139 GeForce GTX 1060 118 119 120 121 December 25 2016 GP104 140 A1 TSMC16FF 7 2 314 1152 72 48 9 2 1 5 1506 1708 8000 3 192 0 192 72 281 9 108 4122 9 3 469 83 935 2 108 4122 9 54 261 4 120 199 August 18 2016 GP106 300 A1 4 4 200 December 26 2017 GP106 350 K3 A1 1280 80 48 10 2 1 25 5 160 0 160 60 268 3 120 4136 7 3 855 34 375 0 120 4136 7 60 268 3 OEM March 8 2018 GP104 150 A1 7 2 314 1 5 6 192 0 192 72 282 0 299 October 18 2018 GP104 150 KA A1 GDDR5X July 19 2016 GP106 400 A1 4 4 200 GDDR5 249 299 April 20 2017 GP106 410 A1 9000 216 0 299 GeForce GTX 1070 122 123 Jun 10 2016 Dec 4 2018 GP104 200 A1 7 2 314 1920 120 64 15 3 2 1683 8000 8 256 0 GDDR5GDDR5X 256 96 3107 7 180 7201 9 5 783 06 462 7 180 7201 9 90 3100 9 150 4 way SLIor2 way SLI HB 124 379 449 GeForce GTX 1070 Ti 122 November 2 2017 GP104 300 A1 2432 152 64 19 4 1607 GDDR5 102 8107 7 244256 7 816 48 186 1 244 2255 8 122 1127 9 180 449 GeForce GTX 1080 125 126 May 27 2016 GP104 400 A1 2560 160 64 20 4 1733 10000 320 0 GDDR5X 102 8110 9 257 1277 2 8 227 88 872 9 257 1277 2 128 5138 6 599 699 April 20 2017 GP104 410 A1 11000 352 0 GeForce GTX 1080 Ti 127 March 5 2017 GP102 350 K1 A1 12 471 3584 224 88 28 6 2 75 1480 1582 11 484 0 352 130 2139 2 331 5354 3 10 608 611 339 7 331 5354 3 165 7177 1 250 699 TITAN X Pascal 128 August 2 2016 GP102 400 A1 3584 224 96 28 6 3 1417 1531 10000 12 480 0 384 136 0146 9 317 4342 9 10 157 010 974 2 317 4342 9 158 7171 4 1199 TITAN Xp 129 April 6 2017 GP102 450 A1 3840 240 96 30 6 1405 1582 11400 547 7 134 8142 0 337 2355 2 10 790 412 149 7 337 2355 2 168 6177 6 Model Launch Code name Process Transistors billion Die size mm2 Core config b Bus interface L2 Cache MB Base core MHz Boost core MHz Memory MT s Size GB Bandwidth GB s Bus type Bus width bit Pixel GP s e h Texture GT s g Single precision Double precision Half precision TDP Watts SLI support MSRP Founders Edition Clock speeds Memory Fillrate c Processing power GFLOPS c d Release price USD The NVIDIA TITAN Xp and the Founders Edition GTX 1080 Ti do not have a dual link DVI port but a DisplayPort to single link DVI adapter is included in the box a b Main shader processors texture mapping units render output units streaming multiprocessors graphics processing clusters a b c d Base clock Boost clock a b To calculate the processing power see Pascal microarchitecture Performance a b Pixel fillrate is calculated as the lowest of three numbers number of ROPs multiplied by the base core clock speed number of rasterizers multiplied by the number of fragments they can generate per rasterizer multiplied by the base core clock speed and the number of streaming multiprocessors multiplied by the number of fragments per clock that they can output multiplied by the base clock rate As the GTX 1070 has one of the four GP104 GPCs disabled in the die its frontend is only able to rasterize 48 pixels per clock 109 Analogically the GTX 1060 features only two GPCs on its GP106 die meaning that its frontend can only rasterize 32 pixels per clock The remaining backend ROPs can still be used for tasks such as MSAA 110 a b Texture fillrate is calculated as the number of TMUs multiplied by the base core clock speed As the GTX 1070 has one of the four GP104 GPCs disabled in the die its frontend is only able to rasterize 48 pixels per clock 109 Analogically the GTX 1060 features only two GPCs on its GP106 die meaning that its frontend can only rasterize 32 pixels per clock The remaining backend ROPs can still be used for tasks such as MSAA 110 Volta series edit Further information Volta microarchitecture Supported APIs Direct3D 12 12 1 OpenGL 4 6 OpenCL 3 0 Vulkan 1 3 63 and CUDA 7 0 Model Launch Code name Process Transistors billion Die size mm2 Core config a Bus Interface L2 Cache MB Clock speeds Memory Fillrate b Processing power GFLOPS b TDP Watts NVLink Support Release price USD Base core clock MHz Boost core clock MHz Memory MT s Size GB Bandwidth GB s Bus type Bus width bit Pixel GP s c Texture GT s d Single precision Double precision Half precision Tensor compute Single precision MSRP Founders Edition Nvidia TITAN V 130 December 7 2017 GV100 400 A1 TSMC12FFN 21 1 815 5120 320 96 640 80 6 PCIe 3 0 x16 4 5 1200 1455 1700 12 652 8 HBM2 3072 153 6186 2 384 0465 6 12 288 014 899 2 6 144 07 449 6 24 576 029 798 4 110 592 0134 092 8 250 No 2999 Nvidia TITAN VCEO Edition 131 132 June 21 2018 GV 100 A1 5120 320 128 640 80 6 6 32 870 4 4096 No Main shader processors texture mapping units render output units tensor cores streaming multiprocessors graphics processing clusters a b Base clock Boost clock Pixel fillrate is calculated as the lowest of three numbers number of ROPs multiplied by the base core clock speed number of rasterizers multiplied by the number of fragments they can generate per rasterizer multiplied by the base core clock speed and the number of streaming multiprocessors multiplied by the number of fragments per clock that they can output multiplied by the base clock rate Texture fillrate is calculated as the number of TMUs multiplied by the base core clock speed GeForce 16 series edit Further information GeForce 16 series and Turing microarchitecture Supported APIs Direct3D 12 feature level 12 1 OpenGL 4 6 OpenCL 3 0 Vulkan 1 3 63 and CUDA 7 5 NVENC 6th generation B frame etc TU117 only supports Volta NVENC 5th generation Model Launch Code name Process Transistors billion Die size mm2 Core config a Bus interface L2 Cache MB Clock speeds Memory Fillrate b Processing power GFLOPS b TDP Watts NVLink support Release price USD Base core clock MHz Boost core clock MHz Memory GT s Size GB Bandwidth GB s Bus type Bus width bit Pixel GP s c Texture GT s d Single precision Double precision Half precision GeForce GTX 1630 June 28 2022 133 TU117 150 A1 TSMC12FFN 4 7 200 512 32 16 1024 0 8 PCIe 3 0 x16 1 1740 1785 12 4 96 GDDR6 64 27 84 28 56 55 6857 12 1 781 761 827 84 55 6857 12 3 563 523 655 68 75 No GeForce GTX 1650 134 April 23 2019 TU117 300 A1 896 56 32 1792 0 14 2 1485 1665 8 128 GDDR5 128 47 5253 28 83 16 93 24 2 661 002 984 00 83 1693 24 5 322 005 967 00 149 April 3 2020 135 1410 1590 12 192 GDDR6 45 1250 88 78 9689 04 2 526 722 849 28 78 9689 04 5 053 445 698 56 June 18 2020 136 TU106 125 A1 10 8 445 90 GeForce GTX 1650 Super 137 November 22 2019 138 TU116 250 KA A1 139 6 6 284 1280 80 32 2560 0 20 3 1 5 1530 1725 48 9655 20 122 40138 0 3 916 804 416 00 122 40138 00 7 833 60 8 832 00 100 159 GeForce GTX 1660 140 March 14 2019 TU116 300 A1 1408 88 48 2816 0 22 3 1785 8 6 GDDR5 192 73 4485 68 134 64157 1 4 308 005 027 00 134 64157 08 8 616 0010 053 00 120 219 GeForce GTX 1660 Super 141 October 29 2019 TU116 300 A1 14 336 GDDR6 125 229 GeForce GTX 1660 Ti 142 February 21 2019 TU116 400 A1 1536 96 48 3072 0 24 3 1500 1770 12 288 72 084 96 144 0169 9 4 608 005 437 44 144 00169 92 9 216 0010 874 88 120 279 RTX 20 series edit Further information GeForce 20 series and Turing microarchitecture Supported APIs Direct3D 12 Ultimate 12 2 OpenGL 4 6 OpenCL 3 0 Vulkan 1 3 63 and CUDA 7 5 Unlike previous generations the RTX Non Super RTX 2070 RTX 2080 RTX 2080 Ti Founders Edition cards no longer have reference clocks but are Factory OC However RTX Supers RTX 2060 Super RTX 2070 Super and RTX 2080 Super Founders Edition are reference clocks NVENC 6th generation B frame etc Model Launch Code name Process Transistors billion Die size mm2 Core config a Bus interface L2 Cache MB Clock speeds Memory Fillrate b Processing power GFLOPS b Ray tracing Performance TDP Watts NVLink support Release price USD Base core clock MHz Boost core clock MHz Memory GT s Size GB Bandwidth GB s Bus type Bus width bit Pixel GP s c Texture GT s d Single precision Double precision Half precision Tensor compute FP16 Rays s Billions RTX OPS s Trillions MSRP Founders Edition GeForce RTX 2060 143 January 15 2019 TU106 200 KA A1 TSMC12FFN 10 8 445 1920 120 48 240 30 30 3 PCIe 3 0 x16 3 1365 1680 14 6 336 0 GDDR6 192 65 5280 64 163 80201 60 5 241 606 451 20 163 80201 60 10 483 2012 902 40 41 932 8051 609 60 5 37 160 No 349 January 10 2020 TU104 150 KC A1 144 13 6 545 299 December 7 2021 145 TU106 300 KA A1 10 8 445 2176 136 64 272 34 34 3 1470 1650 12 79 20 199 92224 40 6 400 007 180 00 199 92224 40 12 800 0014 360 00 185 GeForce RTX 2060 Super 146 147 July 9 2019 TU106 410 A1 4 8 448 0 256 94 08105 60 51 200 0057 440 00 6 41 175 399 GeForce RTX 2070 148 149 October 17 2018 TU106 400 A1 2304 144 64 288 36 36 3 1410 1620 90 24103 68 203 04233 28 6 497 287 464 96 203 04233 28 12 994 5614 929 92 51 978 2459 719 68 42 499 599 GeForce RTX 2070 Super 146 150 July 9 2019 TU104 410 A1 13 6 545 2560 160 64 320 40 40 5 1605 1770 102 70113 28 256 80283 20 8 220 009 060 00 256 80283 20 16 440 0018 120 00 65 760 0072 480 00 7 52 215 2 way NVLink 499 GeForce RTX 2080 151 152 September 20 2018 TU104 400 A1 2944 184 64 368 46 46 6 1515 1710 96 96109 44 278 76314 64 8 920 3210 068 48 278 76314 64 17 840 6420 136 96 71 362 5680 547 84 8 57 699 799 GeForce RTX 2080 Super 146 153 July 23 2019 TU104 450 A1 3072 192 64 384 48 48 6 1650 1815 15 5 496 0 105 60116 16 316 80348 48 10 140 0011 150 00 316 80348 50 20 280 0022 300 00 81 120 0089 200 00 63 250 699 GeForce RTX 2080 Ti 154 September 27 2018 TU102 300 K1 A1 18 6 754 4352 272 88 544 68 68 6 5 5 1350 1545 14 11 616 0 352 118 80135 96 367 20420 24 11 750 4013 447 68 367 20420 24 23 500 8026 895 36 94 003 20107 581 44 10 76 999 1 199 Nvidia TITAN RTX 155 December 18 2018 TU102 400 A1 4608 288 96 576 72 72 6 6 1770 e 24 672 0 384 129 60169 92 388 80509 76 12 441 6016 312 32 388 80509 76 24 883 2032 624 64 99 532 80130 498 56 11 84 280 2 499 a b Main shader processors texture mapping units render output units tensor cores or FP16 cores in GeForce 16 series ray tracing cores streaming multiprocessors graphics processing clusters a b c d Base clock Boost clock a b Pixel fillrate is calculated as the lowest of three numbers number of ROPs multiplied by the base core clock speed number of rasterizers multiplied by the number of fragments they can generate per rasterizer multiplied by the base core clock speed and the number of streaming multiprocessors multiplied by the number of fragments per clock that they can output multiplied by the base clock rate a b Texture fillrate is calculated as the number of TMUs multiplied by the base core clock speed Boost of the Founders Editions as there is no reference version of this card RTX 30 series edit Further information GeForce 30 series and Ampere microarchitecture Supported APIs Direct3D 12 Ultimate 12 2 OpenGL 4 6 OpenCL 3 0 Vulkan 1 3 63 and CUDA 8 6 Supported display connections HDMI 2 1 DisplayPort 1 4a NVENC 7th generation Tensor core 3rd gen RT Core 2nd gen RTX IO Improved NVDEC with AV1 decode NVIDIA DLSS 2 0 Model Launch Code name Process Transistors billion Die size mm2 Core config a Bus interface L2 Cache MB Clock speeds Memory Fillrate Processing power TFLOPS Ray tracing Performance TFLOPS TDP Watts NVLink support Release price USD Base core clock MHz Boost core clock MHz Memory MT s Size GB Bandwidth GB s Bus type Bus width bit Pixel GP s Texture GT s Single precision Double precision Half precision Tensor compute FP16 2 1 sparse MSRP Founders Edition GeForce RTX 3050 156 February 2 2024 GA107 325 Samsung8LPP 8 7 200 2304 72 32 72 18 18 2 PCIe 4 0x8 2 1042 1470 14000 6 168 0 GDDR6 96 33 3447 04 75 02105 8 4 8026 774 0 0750 105 4 8026 774 30 160 2 70 No 169 December 16 2022 GA107 150 A1 2560 80 32 80 20 20 2 1552 1777 8 224 0 128 49 659 86 124 2142 2 7 959 01 0 1240 142 7 959 01 63 672 8 18 2 115 249 July 18 2022 GA106 150 13 25 276 2304 72 32 72 18 18 2 1515 1755 48 4856 16 109 1126 4 6 9818 087 0 1090 126 6 9818 087 130 OEM 157 January 27 2022 158 GA106 150 A1 2560 80 32 80 20 20 2 1552 1777 49 659 86 124 2142 2 7 959 01 0 1240 142 7 959 01 63 672 8 18 2 249 GeForce RTX 3060 159 October 27 2022 160 GA106 302 3584 112 48 112 28 28 3 PCIe 4 0x16 3 1320 1777 15000 240 0 63 485 3 147 8199 0 9 4612 74 0 1480 199 9 4612 74 75 7101 9 25 170 329 May 2021 12 360 0 192 February 25 2021 GA106 300 A1 September 1 2021 GA104 150 A1 161 17 4 392 5 GeForce RTX 3060 Ti 162 December 2 2020 GA104 200 A1 4864 152 80 152 38 38 5 4 1410 1665 14000 8 448 0 256 112 8133 2 214 3253 1 13 7216 20 0 2140 253 13 7016 20 109 7129 6 32 4 200 399 October 27 2022 160 GA104 202 19000 608 0 GDDR6X GeForce RTX 3070 163 164 October 29 2020 165 GA104 300 A1 5888 184 96 184 46 46 6 1500 1725 14000 448 0 GDDR6 144 0165 6 276 0317 4 17 6620 31 0 2760 318 17 6620 31 141 31162 98 40 6 220 499 GeForce RTX 3070 Ti 166 June 10 2021 GA104 400 A1 6144 192 96 192 48 48 6 1575 1770 19000 608 3 GDDR6X 151 18169 9 302 36339 8 19 3521 75 0 3020 340 19 3521 75 154 8174 0 43 5 290 599 GeForce RTX 3080 167 164 September 17 2020 GA102 200 A1 28 3 628 4 8704 272 96 272 68 68 6 5 1440 1710 10 760 0 320 138 2164 2 391 68465 12 25 0729 77 0 3920 465 25 0629 76 200 54238 14 59 5 320 699 January 27 2022 GA102 220 A1 8960 280 96 280 70 70 6 6 1260 1710 12 912 0 384 131 0177 8 352 8478 8 22 630 6 0 3530 479 22 630 6 180 6245 1 61 3 350 799 GeForce RTX 3080 Ti 168 June 3 2021 GA102 225 A1 10240 320 112 320 80 80 7 1365 1665 153 5186 5 438 5532 8 28 5734 1 0 4380 533 28 0634 10 228 6272 8 68 2 1199 GeForce RTX 3090 169 164 September 24 2020 GA102 300 A1 10496 328 112 328 82 82 7 1395 1695 19500 24 935 8 156 2189 8 457 6555 96 29 2835 58 0 4590 558 29 3835 68 235 08285 48 71 1 2 way NVLink 1499 GeForce RTX 3090 Ti 170 171 March 29 2022 GA102 350 A1 10752 336 112 336 84 84 7 1560 1860 21000 1008 3 174 7208 3 524 2625 33 540 0 5240 625 33 540 269 1320 9 79 9 450 1999 Main shader processors texture mapping unit render output units tensor cores ray tracing cores streaming multiprocessors graphics processing clusters RTX 40 series edit Further information GeForce 40 series and Ada Lovelace microarchitecture Supported APIs Direct3D 12 Ultimate 12 2 OpenGL 4 6 OpenCL 3 0 Vulkan 1 3 and CUDA 8 9 172 Supported display connections HDMI 2 1 DisplayPort 1 4a Tensor core 4th gen RT core 3rd gen NVIDIA DLSS 3 NVIDIA DLSS 3 5 Shader Execution Reordering Dual NVENC with 8K 10 bit 60FPS AV1 fixed function hardware encoding 173 174 Opacity Micro Maps OMM Displacement Micro Meshes DMM No NVLink support Multi GPU over PCIe 5 0 175 176 Model Launch Code name Process Transistors billion Die size mm2 Core config a Bus interface L2 Cache MB Clock speeds Memory Fillrate Processing power TFLOPS Ray tracing Performance TFLOPS TDP Watts Release price USD Base core clock MHz Boost core clock MHz Memory MT s Size GB Bandwidth GB s Bus type Bus width bit Pixel GP s Texture GT s Single precision Double precision Half precision Tensor compute FP16 2 1 sparse MSRP Founders Edition GeForce RTX 4060 177 June 29 2023 AD107 400 TSMC 4N 178 18 9 158 7 3072 96 48 96 24 24 3 PCIe 4 0 x8 24 1830 2460 17000 8 272 GDDR6 128 118 1 236 2 11 215 1 0 1760 236 11 215 1 60 121 35 115 299 GeForce RTX 4060 Ti 177 May 24 2023 AD106 350 22 9 187 8 4352 136 48 136 34 34 3 32 2310 2540 18000 288 121 9 345 4 20 122 1 0 3140 345 20 122 1 88 177 51 160 399 July 18 2023 AD106 351 16 499 GeForce RTX 4070 179 April 13 2023 AD104 250 35 8 294 5 5888 184 64 184 46 46 4 PCIe 4 0 x16 36 1920 2475 21000 12 504 GDDR6X 192 158 4 455 4 22 629 1 0 3530 455 22 629 1 117 233 67 200 599 GeForce RTX 4070 Super 180 181 January 17 2024 AD104 350 7168 224 80 224 56 56 5 48 1980 2475 198 0 554 4 28 39 35 48 0 444 0 554 28 39 35 48 114 227 142 284 82 220 GeForce RTX 4070 Ti 182 January 5 2023 AD104 400 7680 240 80 240 60 60 5 2310 2610 208 8 626 4 35 540 1 0 5540 627 35 540 1 142 284 160 321 92 7 285 799 GeForce RTX 4070 Ti Super 181 183 January 24 2024 AD 103 275 45 9 378 6 8448 264 112 264 66 66 6 2340 2610 21000 16 672 256 292 3 689 0 39 54 44 10 0 618 0 689 39 54 44 10 158 316 176 353 102 GeForce RTX 4080 184 Unlaunched 185 186 AD104 400 35 8 294 5 7680 240 80 240 60 60 5 2310 2610 21000 12 504 192 208 8 626 4 35 5 40 1 0 554 0 627 35 5 40 1 142 284 160 321 92 7 899 November 16 2022 AD103 300 45 9 378 6 9728 304 112 304 76 76 7 64 2210 2505 22400 16 717 256 280 6 761 5 43 048 7 0 6720 761 43 048 8 172 344 195 390 112 7 320 1199 GeForce RTX 4080 Super 187 188 January 31 2024 AD103 400 10240 320 112 320 80 80 7 2295 2550 23000 736 285 6 816 0 47 0 52 22 0 734 0 816 47 0 52 22 188 376 209 418 121 999 GeForce RTX 4090 D 189 190 December 28 2023 AD102 250 76 3 608 5 14592 456 176 456 114 114 11 72 2280 2520 21000 24 1008 384 443 5 1149 1 66 573 5 1 0401 149 66 573 5 266 532 294 588 170 425 12 999 GeForce RTX 4090 191 192 October 12 2022 AD102 300 16384 512 176 512 128 128 11 2235 1290 2 73 182 6 1 1421 291 73 182 6 292 585 330 661 191 450 1599 Main shader processors texture mapping unit render output units tensor cores ray tracing cores streaming multiprocessors graphics processing clusters Mobile GPUs editMobile GPUs are either soldered to the mainboard or to some Mobile PCI Express Module MXM GeForce2 Go series edit All models are manufactured with a 180 nm manufacturing process All models support Direct3D 7 0 and OpenGL 1 2 Celsius microarchitecture Model Launch Code name Bus interface Core clock MHz Memory clock MHz Core config a Fillrate Memory MOperations s MPixels s MTexels s MVertices s Size MB Bandwidth GB s Bus type Bus width bit GeForce2 Go 100 February 6 2001 NV11M AGP 4x 125 332 2 0 4 2 250 250 500 0 8 16 1 328 DDR 32 GeForce2 Go November 11 2000 143 166332 286 286 572 16 32 2 656 SDRDDR 12864 GeForce2 Go 200 February 6 2001 332 DDR 64 Pixel shaders vertex shaders texture mapping units render output units GeForce4 Go series edit All models are made via 150 nm fabrication process Model Launch Code name Bus interface Core clock MHz Memory clock MHz Core config a Fillrate Memory API support MOperations s MPixels s MTexels s MVertices s Size MB Bandwidth GB s Bus type Bus width bit Direct3D OpenGL GeForce4 Go 410 February 6 2002 NV17M AGP 8x 200 200 2 0 4 2 400 400 800 0 16 1 6 SDR 64 8 0a 1 3 GeForce4 Go 420 400 32 3 2 DDR GeForce4 Go 440 220 440 440 440 880 64 7 04 128 GeForce4 Go 460 October 14 2002 250 500 500 500 1000 8 GeForce4 Go 488 NV18M 300 550 600 600 1200 8 8 GeForce4 Go 4200 November 14 2002 NV28M 200 400 4 2 8 4 800 800 1600 100 6 4 Pixel shaders vertex shaders texture mapping units render output units GeForce FX Go 5 Go 5xxx series edit The GeForce FX Go 5 series for notebooks architecture 1 Vertex shaders pixel shaders texture mapping units render output units The GeForce FX series runs vertex shaders in an array GeForce FX series has limited OpenGL 2 1 support with the last Windows XP driver released for it 175 19 Rankine microarchitecture Model Launch Code name Fab nm Bus interface Core clock MHz Memory clock MHz Core config1 Fillrate Memory Supported API version TDP Watts Pixel GP s Texture GT s Size MB Bandwidth GB s Bus type Bus width bit Direct3D OpenGL Hardware Drivers Software GeForce FX Go 5100 March 2003 NV34M 150 AGP 8x 200 400 4 2 4 4 0 8 0 8 64 3 2 DDR 64 9 0 1 5 2 1 Un known GeForce FX Go 5500 300 600 1 2 1 2 3264 9 6 128 Un known GeForce FX Go 5600 NV31M 130 350 1 4 1 4 32 Un known GeForce FX Go 5650 350 Un known GeForce FX Go 5700 February 1 2005 NV36M 450 550 4 3 4 4 1 8 1 8 8 8 Un known GeForce Go 6 Go 6xxx series edit All models support Direct3D 9 0c and OpenGL 2 1 Curie microarchitecture Model Launch Code name Fab nm Bus interface Core clock MHz Memory clock MHz Core config1 Fillrate Memory MOperations s MPixels s MTexels s MVertices s Size MB Bandwidth GB s Bus type Bus width bit GeForce Go 6100 nForce Go 430 Un known C51M 110 HyperTransport 425 System memory 2 1 2 1 850 425 850 106 25 Up to 128 MB system System memory DDR2 64 128 GeForce Go 6150 nForce Go 430 February 1 2006 GeForce Go 6200 February 1 2006 NV44M PCIe x16 300 600 4 3 4 2 1200 600 1200 225 16 2 4 DDR 32 GeForce Go 6400 February 1 2006 400 700 1600 800 1600 250 5 6 64 GeForce Go 6600 September 29 2005 NV43M 300 8 3 8 4 3000 1500 3000 281 25 128 11 2 128 GeForce Go 6800 November 8 2004 NV41M 130 7001100 12 5 12 12 375 22 435 2 DDR DDR2DDR3 256 GeForce Go 6800 Ultra February 24 2005 450 5400 3600 5400 562 5 256 1 Pixel shaders vertex shaders texture mapping units render output units GeForce Go 7 Go 7xxx series edit The GeForce Go 7 series for notebooks architecture 1 Vertex shaders pixel shaders texture mapping units render output units 2 Graphics card supports TurboCache memory size entries in bold indicate total memory graphics system RAM otherwise entries are graphics RAM only Curie microarchitecture Model Launch Code name Fab nm Bus interface Core clock MHz Memory clock MHz Core config1 Fillrate Memory Supported API version TDP Watts Features Pixel GP s Texture GT s Size MB Bandwidth GB s Bus type Bus width bit Direct3D OpenGL GeForce 7000M February 1 2006 MCP67MV 90 Hyper Transport 350 System memory 1 2 2 2 0 7 0 7 Up to 256 from system memory System memory DDR2 64 128 9 0c 2 1 Un known GeForce 7150M MCP67M 425 0 85 0 85 Un known GeForce Go 72002 January 2006 G72M PCIe x16 450 700 3 4 4 1 0 45 1 8 64 2 8 GDDR3 32 Un known Transparency Anti Aliasing GeForce Go 73002 350 3 4 4 2 0 7 1 4 128 256 512 5 60 64 Un known GeForce Go 74002 450 900 0 9 1 8 64 256 7 20 Un known GeForce Go 7600 March 2006 G73M 1000 5 8 8 8 3 6 3 6 256 512 16 128 Un known Scalable Link Interface SLI Transparency Anti Aliasing GeForce Go 7600 GT 2006 500 1200 5 12 12 8 4 6 256 19 2 Un known GeForce Go 7700 G73 N B1 80 450 1000 3 6 5 4 512 16 Un known GeForce Go 7800 March 3 2006 G70M 110 400 1100 6 16 16 8 3 2 6 4 256 35 2 256 35 GeForce Go 7800 GTX October 2005 8 24 24 16 6 4 9 6 65 GeForce Go 7900 GS April 2006 G71M 90 375 1000 7 20 20 16 6 7 5 32 0 20 GeForce Go 7900 GTX 500 1200 8 24 24 16 8 12 256 512 38 4 45 GeForce Go 7950 GTX October 2006 575 1400 9 2 13 8 512 44 8 GeForce 8M 8xxxM series edit The GeForce 8M series for notebooks architecture Tesla 1 Unified shaders texture mapping units render output units Model Launch Code name Fab nm Bus interface Core config1 Clock speed Fillrate Memory Supported API version Processing power GFLOPS TDP Watts Notes Core MHz Shader MHz Memory MHz Pixel GP s Texture GT s Size MB Bandwidth GB s Bus type Bus width bit Direct3D OpenGL GeForce 8200M G 193 June 2008 MCP77MV MCP79MVL 80 Integrated PCIe 2 0 x16 8 8 4 400 800 8001066 system memory 1 6 3 2 Up to 256 from system memory 12 817 056 DDR2DDR3 128 10 0 3 3 19 2 Un known PureVideo HD with VP3 Full H 264 VC 1 MPEG 2 HW Decode GeForce 8400M G May 2007 NB8M G86 PCIe x16 800 128 256 6 4 DDR2 GDDR3 64 10 PureVideo HD with VP2 BSP Engine and AES128 Engine GeForce 8400M GS 16 8 4 38 4 11 GeForce 8400M GT 450 900 1200 1 8 3 6 256 512 19 2 128 43 2 14 GeForce 8600M GS NB8P G84 600 1200 1400 2 4 4 8 22 4 57 6 20 GeForce 8600M GT 32 16 8 475 950 800 1400 3 8 7 6 12 8 22 4 91 2 GeForce 8700M GT June 2007 625 1250 1600 5 10 25 6 GDDR3 120 29 Scalable Link Interface PureVideo HD with VP2 BSP Engine and AES128 Engine GeForce 8800M GTS November 2007 NB8P G92 65 PCIe 2 0 x16 64 32 16 500 8 16 512 51 2 256 240 50 GeForce 8800M GTX 96 48 16 24 360 65 GeForce 9M 9xxxM series edit The GeForce 9M series for notebooks architecture Tesla microarchitecture 1 Unified shaders texture mapping units render output units Model Launch Code name Fab nm Bus interface Core config1 Clock speed Fillrate Memory Supported API version Processing power GFLOPS TDP Watts Notes Core MHz Shader MHz Memory MHz Pixel GP s Texture GT s Size MB Bandwidth GB s Bus type Bus width bit Direct3D OpenGL GeForce 9100M G mGPU 2008 MCP77MH MCP79MH 65 Integrated PCIe 2 0 x16 8 8 4 450 1100 1066 system memory 1 8 3 6 Up to 256 from system memory 17 056 DDR3 128 10 0 3 3 26 4 12 Similar to 8400M G GeForce 9200M GS NB9M GE G98 PCIe 2 0 x16 550 1300 1400 2 2 4 4 256 11 2 DDR2 GDDR3 64 31 2 13 GeForce 9300M G NB9M GE G86 80 16 8 4 400 800 1200 1 6 3 2 256 512 9 6 38 4 GeForce 9300M GS NB9M GE G98 65 8 8 4 550 1400 1400 2 2 4 4 11 2 33 6 GeForce 9400M G October 15 2008 MCP79MX Integrated PCIe 2 0 x16 16 8 4 450 1100 8001066 system memory 1 8 3 6 Up to 256 from system memory 12 817 056 DDR2DDR3 128 54 12 PureVideo HD with VP3 Known as the GeForce 9400M in Apple systems 194 and Nvidia ION based systems GeForce 9500M G 2008 NB9P G96 PCIe 2 0 x16 16 8 8 500 1250 1600 4 4 512 25 6 DDR2 GDDR3 60 20 GeForce 9500M GS NB9P GV G96 80 PCIe x16 32 16 8 475 950 1400 3 8 7 6 22 4 91 2 Rebranded 8600M GT GeForce 9600M GS NB9P GE2 G96 65 PCIe 2 0 x16 430 1075 8001600 3 44 6 88 1024 12 825 6 103 2 GeForce 9600M GT NB9P GS G96 500 1250 1600 4 8 512 1024 25 6 120 23 GeForce 9650M GS NB9P GS1 G84 80 625 5 10 512 GDDR3 29 Rebranded 8700M GT GeForce 9650M GT NB9P GT G96 65 55 550 1325 4 4 8 8 1024 127 2 23 GeForce 9700M GT July 29 2008 NB9E GE G96 65 PCIe x16 625 1550 5 10 512 148 8 45 GeForce 9700M GTS NB9E GS G94 PCIe 2 0 x16 48 24 16 530 1325 8 48 12 7 51 2 256 190 8 60 GeForce 9800M GS 2008 NB9E GT G94 64 32 16 8 48 16 96 254 Down Clocked 9800M GTS Via Firmware GeForce 9800M GTS July 29 2008 65 55 64 32 16 600 1500 9 6 19 2 512 1024 288 75 GeForce 9800M GT NB9E GT2 G92 96 48 16 500 1250 8 24 512 360 65 Rebranded 8800M GTX GeForce 9800M GTX NB9E GTX G92 65 112 56 16 28 1024 420 75 Model Launch Code name Fab nm Bus interface Core config1 Core MHz Shader MHz Memory MHz Pixel GP s Texture GT s Size MB Bandwidth GB s Bus type Bus width bit Direct3D OpenGL Processing power GFLOPS TDP Watts Notes Clock speed Fillrate Memory Supported API version GeForce 100M 1xxM series edit The GeForce 100M series for notebooks architecture Tesla microarchitecture 103M 105M 110M 130M are rebranded GPU i e using the same GPU cores of previous generation 9M with promised optimisation on other features 1 Unified shaders texture mapping units render output units Model Launch Code name Fab nm Bus interface Core config1 Clock speed Fillrate Memory Supported API version Processing power GFLOPS TDP Watts Notes Core MHz Shader MHz Memory MHz Pixel GP s Texture GT s Size MB Bandwidth GB s Bus type Bus width bit Direct3D OpenGL GeForce G 102M January 8 2009 MCP79XT 65 Integrated PCIe 1 0 x16 16 8 4 450 1000 800 system memory 1 8 3 6 Up to 512 from system memory 6 4 DDR2 64 10 0 3 3 48 14 PureVideo HD CUDA Hybrid SLI based on GeForce 9400M G GeForce G 103M January 1 2009 N10M GE2 G98 PCIe 2 0 x16 8 8 4 640 1600 1000 2 56 5 12 512 8 38 PureVideo HD CUDA Hybrid SLI comparable to the GeForce 9300M GS GeForce G 105M January 8 2009 N10M GE1 G98 10001400 811 GDDR2GDDR3 38 GeForce G 110M N10M GE1 G96b 55 16 8 4 400 1000 10001400 1 6 3 2 1024 811 DDR2GDDR3 48 PureVideo HD CUDA Hybrid SLI GeForce GT 120M February 11 2009 N10P GV1 G96b 32 16 8 500 1250 1000 4 8 16 DDR2 128 110 23 PureVideo HD CUDA Hybrid SLI Comparable to the 9500M GT and 9600M GT DDR2 500 1250 400 GeForce GT 130M January 8 2009 N10P GE1 G96b 600 1500 10001600 4 8 9 6 1625 6 DDR2GDDR3 144 PureVideo HD CUDA Hybrid SLI comparable to the 9650M GT GeForce GTS 150M March 3 2009 N10E GE1 G94b 64 32 16 400 1000 1600 6 4 12 8 51 2 GDDR3 256 192 Un known PureVideo HD CUDA Hybrid SLI GeForce GTS 160M N10E GS1 G94b 600 1500 9 6 19 2 288 60 GeForce 200M 2xxM series edit The GeForce 200M series is a graphics processor architecture for notebooks Tesla microarchitecture 1 Unified shaders texture mapping units render output units Model Launch Code name Fab nm Bus interface Core config1 Clock speed Fillrate Memory Supported API version Processing power GFLOPS TDP Watts Notes Core MHz Shader MHz Memory MHz Pixel GP s Texture GT s Size MB Bandwidth GB s Bus type Bus width bit Direct3D OpenGL GeForce G210M June 15 2009 GT218 40 PCIe 2 0 x16 16 8 4 625 1500 1600 2 5 5 512 12 8 GDDR3 64 10 1 3 3 72 14 Lower clocked versions of the GT218 core is also known as Nvidia ION 2 GeForce GT 220M 2009 G96b 55 32 16 8 500 1250 10001600 4 8 1024 1625 6 DDR2GDDR3 128 120 rebranded 9600M GT 55 nm node shrink GeForce GT 230M June 15 2009 GT216 40 48 16 8 1100 1600 25 6 GDDR3 158 23 GeForce GT 240M 550 1210 4 4 8 8 174 GeForce GTS 250M GT215 96 32 8 500 1250 3200 4 16 51 2 GDDR5 360 28 GeForce GTS 260M GT215 550 1375 3600 4 4 17 6 57 6 396 38 GeForce GTX 260M March 3 2009 G92b 55 112 56 16 1900 8 8 30 8 60 8 GDDR3 256 462 65 GeForce GTX 280M 128 64 16 585 1463 9 36 37 44 562 75 GeForce GTX 285M February 2010 600 1500 2000 9 6 38 4 64 0 576 Higher Clocked Version of GTX280M with new memory GeForce 300M 3xxM series edit The GeForce 300M series for notebooks architecture Tesla microarchitecture 1 Unified shaders texture mapping units render output units 2 To calculate the processing power see Tesla microarchitecture Performance Model Launch Code name Fab nm Bus interface Core config1 Clock speed Fillrate Memory Supported API version Processing power GFLOPS 2 TDP Watts Core MHz Shader MHz Memory MHz Pixel GP s Texture GT s Size MB Bandwidth GB s Bus type Bus width bit Direct3D OpenGL GeForce 305M January 10 2010 GT218 40 PCIe 2 0 x16 16 8 4 525 1150 1400 2 1 4 2 512 11 2 DDR3GDDR3 64 10 1 3 3 55 14 GeForce 310M 625 1530 1600 2 5 5 12 8 73 GeForce 315M January 5 2011 606 1212 2 42 4 85 58 18 GeForce 320M April 1 2010 MCP89 48 16 8 450 950 1066 3 6 7 2 256 shared w system memory 195 17 056 DDR3 128 136 8 20 GeForce GT 320M January 21 2010 GT216 24 8 8 500 1100 1580 4 4 1024 25 3 DDR3GDDR3 90 14 GeForce GT 325M January 10 2010 48 16 8 450 990 1600 3 6 7 2 25 6 142 23 GeForce GT 330M 575 1265 4 6 9 2 182 GeForce GT 335M January 7 2010 GT215 72 24 8 450 1080 3 6 10 8 233 28 GeForce GTS 350M 96 32 8 500 1249 3200 4 16 51 2 DDR3GDDR3GDDR5 360 28 GeForce GTS 360M 1436 3600 4 4 17 6 57 6 413 38 GeForce 400M 4xxM series edit The GeForce 400M series for notebooks architecture Fermi microarchitecture 1 Unified shaders texture mapping units render output units 2 To calculate the processing power see Fermi microarchitecture Performance 3 Each SM in the GF100 also contains 4 texture address units and 16 texture filtering units Total for the full GF100 64 texture address units and 256 texture filtering units 60 Each SM in the GF104 106 108 architecture contains 8 texture filtering units for every texture address unit The complete GF104 die contains 64 texture address units and 512 texture filtering units the complete GF106 die contains 32 texture address units and 256 texture filtering units and the complete GF108 die contains 16 texture address units and 128 texture filtering units Model Launch Code name Fab nm Bus interface Core config1 Clock speed Fillrate Memory Supported API version Processing power GFLOPS 2 TDP Watts Notes Core MHz Shader MHz Memory MHz Pixel GP s Texture GT s Size MB Bandwidth GB s Bus type Bus width bit Direct3D OpenGL GeForce 410M January 5 2011 GF119 40 PCIe 2 0 x16 48 83 4 575 1150 1600 2 3 4 6 512 and 1024 12 8 DDR3 64 12 4 5 110 4 12 Similar to Desktop GT420 OEM GeForce GT 415M September 3 2010 GF108 500 1000 2 4 25 6 128 96 lt 12 GPU only 196 GeForce GT 420M 96 163 4 8 192 10 23 GPU only 196 Similar to Desktop GT430 GeForce GT 425M 560 1120 2 24 8 96 1024 215 04 20 23 GPU only 196 GeForce GT 435M 650 1300 2 6 10 4 2048 249 6 32 35 GPU only 196 Similar to Desktop GT430 440 GeForce GT 445M GF106 144 243 16144 243 24 590 1180 16002500 9 4414 16 14 16 10241536 25 660 DDR3GDDR5 128192 339 84 30 35 GPU only 196 Similar to Desktop GTS450 OEM GeForce GTX 460M 192 323 24 675 1350 2500 16 2 21 6 1536 60 GDDR5 192 518 4 45 50 GPU only 196 Similar to Desktop GTX550 Ti GeForce GTX 470M GF104 288 483 24 550 1100 13 2 26 4 633 6 Similar to Desktop GTX 460 560SE GeForce GTX 480M May 25 2010 GF100 352 443 32 425 850 2400 13 6 18 7 2048 76 8 256 598 4 100 MXM module Similar to Desktop GTX465 GeForce GTX 485M January 5 2011 GF104 384 643 32 575 1150 3000 18 4 36 8 96 0 883 2 Similar to Desktop GTX560 Ti GeForce 500M 5xxM series edit The GeForce 500M series for notebooks architecture 1 Unified shaders texture mapping units render output units 2 On Some Dell XPS17 Model Launch Code name Fab nm Bus interface Core config1 Clock speed Fillrate Memory Supported API version Processing power GFLOPS 2 TDP Watts Notes Core MHz Shader MHz Memory MHz Pixel GP s Texture GT s Size MB Bandwidth GB s Bus type Bus width bit Direct3D OpenGL GeForce GT 520M January 5 2011 GF119 40 PCIe 2 0 x16 48 8 4 740 1480 1600 2 96 5 92 1024 12 8 DDR3 64 12 4 6 142 08 12 Similar to Desktop 510 520 GeForce GT 520M GF108 96 16 4 515 1030 2 06 8 24 197 76 20 Noticed in Lenovo laptops similar to Desktop 530 430 440 GeForce GT 520MX May 30 2011 GF119 48 8 4 900 1800 1800 3 6 7 2 14 4 172 8 Similar to Desktop 510 amp GT520 GeForce GT 525M January 5 2011 GF108 96 16 4 600 1200 2 4 9 6 28 8 128 230 4 20 23 Similar to Desktop GT 530 430 440 GeForce GT 540M 672 1344 2 688 10 752 20481024 258 048 32 35 Similar to Desktop GT 530 440 GeForce GT 550M GF108GF1062 96 16 4144 24 162 740475 1480950 18001800 2 96 11 84 1024 284 16312 6 GeForce GT 555M GF106GF108 144 24 24144 24 1696 16 4 590650753 118013001506 180018003138 14 610 43 14 615 612 153620481024 43 228 850 2 DDR3DDR3GDDR5 192128128 339 84374 4289 15 30 35 Similar to Desktop GT545 GeForce GTX 560M May 30 2011 GF116 192 32 16192 32 24 775 1550 2500 18 6 24 8 20481536 3072 40 060 0 GDDR5 128192 595 2 75 Similar to Desktop GTX 550Ti GeForce GTX 570M 197 June 28 2011 GF114 336 56 24 575 1150 3000 13 8 32 2 1536 72 0 192 772 8 Similar to Desktop GTX 560 GeForce GTX 580M 384 64 32 620 1240 19 8 39 7 2048 96 0 256 952 3 100 Similar to Desktop GTX 560 Ti GeForce 600M 6xxM series edit Further information GeForce 600 series The GeForce 600M series for notebooks architecture The processing power is obtained by multiplying shader clock speed the number of cores and how many instructions the cores can perform per cycle 1 Unified shaders texture mapping units render output units Non GTX Graphics lack support NVENC Model Launch Code name Fab nm Bus interface Core config1 Clock speed Fillrate Memory Supported API version Processing power GFLOPS 2 TDP Watts Notes Core MHz Shader MHz Memory MT s Pixel GP s Texture GT s Size MB Bandwidth GB s Bus type Bus width bit Vulkan Direct3D OpenGL GeForce 610M 198 December 2011 GF119 N13M GE 40 PCIe 2 0 x16 48 8 4 900 1800 1800 3 6 7 2 10242048 14 4 DDR3 64 n a 12 4 5 142 08 12 OEM Rebadged GT 520MX GeForce GT 620M 199 April 2012 GF117 N13M GS 28 96 16 4 625 1250 1800 2 5 10 14 428 8 64128 240 15 OEM Die Shrink GF108 GeForce GT 625M October 2012 14 4 64 GeForce GT 630M 199 200 201 April 2012 GF108 N13P GL GF117 4028 660800 13201600 18004000 2 63 2 10 712 8 28 832 0 DDR3GDDR5 12864 258 0307 2 33 GF108 OEM Rebadged GT 540MGF117 OEM Die Shrink GF108 GeForce GT 635M 199 202 203 GF106 N12E GE2 GF116 40 144 24 24 675 1350 1800 16 2 16 2 20481536 28 843 2 DDR3 128192 289 2388 8 35 GF106 OEM Rebadged GT 555MGF116 94 of desktop GT640 original research GeForce GT 640M LE 199 March 22 2012 GF108GK107 N13P LP 4028 PCIe 2 0 x16PCIe 3 0 x16 96 16 4384 32 16 2 SMX 762500 1524500 31301800 38 12 216 10242048 50 228 8 DDR3 GDDR5 128 1 2 292 6384 3220 GF108 94 of desktop GT630 original research GK107 47 of desktop GTX650 original research GeForce GT 640M 199 204 GK107 N13P GS 28 PCIe 3 0 x16 384 32 16 2 SMX 625 625 18004000 10 20 28 864 0 480 32 59 of desktop GTX650 original research GeForce GT 645M October 2012 710 710 18004000 11 36 22 72 545 67 of desktop GTX650 original research GeForce GT 650M 199 205 206 March 22 2012 GK107 N13P GT 745835900 835950900 180040005000 11 913 414 4 23 826 728 8 51210242048 28 864 080 0 11 2 572 2641 3691 2 45 79 of desktop GTX650 original research GeForce GTX 660M 199 206 207 208 GK107 N13E GE 835 950 5000 15 2 30 4 2048 80 0 GDDR5 729 6 50 79 of desktop GTX650 original research GeForce GTX 670M 199 April 2012 GF114 N13E GS1 LP 40 PCIe 2 0 x16 336 56 24 620 1240 3000 14 35 33 5 15363072 72 0 192 n a 12 833 75 73 of desktop GTX 560 original research GeForce GTX 670MX October 2012 GK104 N13E GR 28 PCIe 3 0 x16 960 80 24 5 SMX 615 615 2800 14 4 48 0 67 2 1 2 1181 61 of desktop GTX 660 original research GeForce GTX 675M 199 April 2012 GF114 N13E GS1 40 PCIe 2 0 x16 384 64 32 632 1265 3000 19 8 39 7 2048 96 0 256 n a 972 100 75 of desktop GTX 560Ti original research GeForce GTX 675MX October 2012 GK104 N13E GSR 28 PCIe 3 0 x16 960 80 32 5 SMX 667 667 3600 19 2 48 0 4096 115 2 1 2 1281 61 of desktop GTX 660 original research GeForce GTX 680M June 4 2012 GK104 N13E GTX 1344 112 32 7 SMX 719 719 23 80 6 1933 78 of desktop GTX 670 original research GeForce GTX 680MX October 23 2012 GK104 1536 128 32 8 SMX 5000 92 2 160 2209 122 72 of desktop GTX 680 original research Model Launch Code name Fab nm Bus interface Core config1 Clock speed Fillrate Memory Supported API version Processing power GFLOPS 2 TDP Watts Notes Core MHz Shader MHz Memory MT s Pixel GP s Texture GT s Size MB Bandwidth GB s Bus type Bus width bit Vulkan Direct3D OpenGL GeForce 700M 7xxM series edit Further information GeForce 700 series The GeForce 700M series for notebooks architecture The processing power is obtained by multiplying shader clock speed the number of cores and how many instructions the cores can perform per cycle 1 Unified shaders texture mapping units render output units Non GTX Graphics lack support NVENC Model Launch Code name Fab nm Bus interface Core config1 Clock speed Fillrate Memory Supported API version Processing power GFLOPS 2 TDP Watts Notes Core MHz Shader MHz Memory MT s Pixel GP s Texture GT s Size MB Bandwidth GB s Bus type Bus width bit Vulkan Direct3D OpenGL CUDA GeForce 710M January 2013 GF117 28 PCIe 2 0 x16 96 16 4 800 1600 1800 3 2 12 8 10242048 14 4 DDR3 64 n a 12 4 5 2 1 209 307 2 12 OEM About 115 of Mobile 620 amp Desktop 530 original research GeForce 710M July 24 2013 GK208 PCIe 3 0 x8 192 16 8 719 5 752 11 5 1024 1 2 3 5 210 276 1 15 Kepler similar to 730M with half of the cores disabled GeForce GT 720M April 1 2013 GF117 PCIe 2 0 x16 96 16 4 938 1876 2000 3 8 15 0 2048 16 0 n a 2 1 209 360 19 OEM About 130 of Mobile 625 630 amp Desktop 620 original research GeForce GT 720M December 25 2013 GK208 PCIe 2 0 x8 192 16 8 719 3 032 12 13 12 8 1 2 3 5 210 291 22 Kepler similar to 730M with half of the cores disabled GeForce GT 730M January 2013 GK208 PCIe 3 0 x8 384 32 8 2 SMX 719 5 8 23 0 16 0 128 552 2 33 Kepler similar to Desktop GT640 GeForce GT 735M April 1 2013 889 7 11 28 4 64 682 8 Kepler similar to Desktop GT640 GeForce GT 740M 980 1800 7 84 31 4 14 4 752 6 Kepler similar to Desktop GT640 GeForce GT 740M GK107 PCIe 3 0 x16 384 32 16 2 SMX 810 211 18005000 12 96 25 92 2048 211 28 880 DDR3GDDR5 211 128 3 0 209 622 1 45 about 76 of Desktop GTX650 original research GeForce GT 745M 837 20005000 13 4 26 8 2048 3280 DDR3GDDR5 642 8 about 79 of Desktop GTX650 original research GeForce GT 750M 967 15 5 30 9 742 7 50 about 91 of Desktop GTX650 original research GeForce GT 755M 212 1020 5400 15 7 31 4 86 4 GDDR5 783 about 93 of Desktop GTX650 original research GeForce GTX 760M May 2013 GK106 768 64 16 4 SMX 719 4000 10 5 42 1 64 1104 55 about 71 of Desktop GTX 650Ti original research GeForce GTX 765M 863 13 6 54 4 1326 65 about 92 of Desktop GTX 650Ti original research GeForce GTX 770M 960 80 24 5 SMX 797 19 5 64 9 3072 96 192 1530 75 about 83 of Desktop GTX660 original research GeForce GTX 780M GK104 1536 128 32 8 SMX 5000 26 3 105 3 4096 160 256 2448 122 about 78 of Desktop GTX770 original research Model Launch Code name Fab nm Bus interface Core config1 Clock speed Fillrate Memory Supported API version Processing power GFLOPS 2 TDP Watts Notes Core MHz Shader MHz Memory MT s Pixel GP s Texture GT s Size MB Bandwidth GB s Bus type Bus width bit Vulkan Direct3D OpenGL CUDA GeForce 800M 8xxM series edit Further information GeForce 800M series The GeForce 800M series for notebooks architecture The processing power is obtained by multiplying shader clock speed the number of cores and how many instructions the cores can perform per cycle 1 Unified shaders texture mapping units render output units 810M to 845M Graphics lack support NVENC Model Launch Code name Fab nm Bus interface Core config1 Clock speed Fillrate Memory Supported API version Processing power GFLOPS 2 TDP Watts Notes original research Core MHz Shader MHz Memory MT s Pixel GP s Texture GT s Size GB Bandwidth GB s Bus type Bus width bit Vulkan Direct3D OpenGL CUDA Compute Capability GeForce 810M February 2014 GF117 28 PCIe 2 0 x16 48 8 4 738 888 1476 1776 1800 2 95 3 55 5 9 7 1 1 14 4 DDR3 64 n a 12 4 5 2 1 209 141 7 170 5 15 GeForce 820M 213 96 16 4 719 954 1438 1908 2000 2 9 3 8 11 5 15 3 2 16 276 1 366 3 15 214 115 of 620 Fermi GeForce 825M 215 January 27 2014 GK208 PCIe 3 0 x8 384 16 8 2 SMX 850 1800 6 8 13 6 14 4 1 2 3 5 210 652 8 33 94 of 630 Kepler GeForce 830M 216 March 12 2014 GM108 PCIe 3 0 x16 256 16 8 2 SMM 1029 8 2 16 5 14 4 1 3 5 0 209 526 8 25 50 of 750 Maxwell GeForce 840M 217 384 24 8 3 SMM 2000 8 2 24 7 2 4 16 790 3 30 50 80 of 745 Maxwell GeForce 845M 218 219 February 7 2015 220 384 32 16 3 SMM 1071 1150 5000 18 8 37 6 2 40 GDDR5 903 2 33 August 16 2015 221 GM107 512 32 16 4 SMM 863 2000 13 8 27 6 16 DDR3 883 7 45 GeForce GTX 850M 222 March 12 2014 640 40 16 5 SMM 876 Boost 5000 14 0 35 0 2 4 80 2 GDDR5 128 1121 3 40 80 of 750Ti 936 Boost 2000 15 0 37 4 32 DDR3 1198 1 85 of 750Ti GeForce GTX 860M 223 640 40 16 5 SMM 1029 1085 5000 16 5 41 2 2 80 GDDR5 1389 40 45 equal to 750Ti GK104 1152 96 16 6 SMX 797 915 12 8 76 5 4 1 2 3 0 209 2108 75 similar to 660 OEM GeForce GTX 870M 224 1344 112 24 7 SMX 941 967 22 6 105 4 3 6 120 192 2599 110 105 of 660Ti GeForce GTX 880M 225 1536 128 32 8 SMX 954 993 30 5 122 1 4 8 160 256 3104 130 90 of 770 Model Launch Code name Fab nm Bus interface Core config1 Clock speed Fillrate Memory Supported API version Processing power GFLOPS 2 TDP Watts Notes original research Core MHz Shader MHz Memory MT s Pixel GP s Texture GT s Size GB Bandwidth GB s Bus type Bus width bit Vulkan Direct3D OpenGL CUDA Compute Capability GeForce 900M 9xxM series edit Further information GeForce 900 series The GeForce 900M series for notebooks architecture The processing power is obtained by multiplying shader clock speed the number of cores and how many instructions the cores can perform per cycle 1 Unified shaders texture mapping units render output units 920M to 940M Graphics lack support NVENC Model Launch Code name Fab nm Bus interface Core config1 Clock speed Fillrate Memory Supported API version Processing power GFLOPS 2 TDP Watts Notes Min MHz Average MHz Memory MT s Pixel GP s Texture GT s Size GB Bandwidth GB s Bus type Bus width bit Vulkan Direct3D OpenGL OpenCL GeForce 910M March 13 2015 GK208B 28 PCIe 3 0 x8 384 32 8 2 SMX 641 5 128 20 51 2 16 02 DDR3 64 1 2 12 11 0 4 6 1 2 492 3 33 GeForce 920M March 12 2015 GK208 28 PCIe 3 0 x16 384 32 8 2 SMX 954 Un known 1800 7 6 30 5 2 14 4 DDR3 64 1 2 12 11 0 4 6 1 2 733 33 GeForce 930M GM108 384 24 8 3 SMM 928 941 7 4 22 3 1 3 713 29 226 GeForce 940M 1072 1176 2000 8 6 25 7 16 823 36 227 GeForce 940MX January 2016 228 1004 1242 9 9 29 8 954 23 June 28 2016 229 GM107 512 32 8 4 SMM 795 861 5000 6 9 27 6 40 GDDR5 882 GeForce GTX 950M March 12 2015 640 40 16 5 SMM 914 Un known 14 6 36 6 2 4 80 128 1170 Un known Similar core config to GTX 750 Ti GM107 400 A2 2000 32 DDR3 55 230 GeForce GTX 960M 1097 1176 5000 17 5 43 8 80 GDDR5 1403 65 231 GeForce GTX 965M 232 January 5 2015 GM204 1024 64 32 8 SMM 944 Un known 30 2 60 4 12 12 1 1933 60 233 Similar core config to GTX 960 GM206 300 GeForce GTX 970M 234 October 7 2014 1280 80 48 10 SMM 993 44 4 73 9 3 6 120 192 2365 75 Similar core config to GTX 960 OEM GM204 GeForce GTX 980M 235 1536 96 64 12 SMM 1038 1127 66 4 99 6 4 8 160 256 3189 100 Similar core config to GTX 970 GM204 200 with one SMM disabled GeForce GTX 980 236 September 22 2015 2048 128 64 16 SMM 1064 Un known 7010 68 1 136 2 8 224 4358 165 oc to 200 Similar to Desktop GTX 980 Model Launch Code name Fab nm Bus interface Core config1 Clock speed Fillrate Memory Supported API version Processing power GFLOPS 2 TDP Watts Notes Min MHz Average MHz Memory MT s Pixel GP s Texture GT s Size GB Bandwidth GB s Bus type Bus width bit Vulkan Direct3D OpenGL OpenCL GeForce 10 series edit Further information GeForce 10 series and Pascal microarchitecture Unified shaders texture mapping units render output units Improve NVENC Better support H265 VP9 Supported APIs Direct3D 12 12 1 OpenGL 4 6 OpenCL 3 0 Vulkan 1 3 and CUDA 6 1 209 Model Launch Code name Fab nm Transistors billion Die size mm2 Bus interface Core config Clock speeds Fillrate Memory Supported API version Processing power GFLOPS TDP Watts SLI support Base core clock MHz Boost core clock MHz Memory MT s Pixel GP s Texture GT s Size GB Bandwidth GB s Bus type Bus width bit DirectX OpenGL Vulkan OpenCL Single precision Boost Double precision Half precision GeForce GTX 1050 Notebook 237 238 January 3 2017 GP107 N17P G0 A1 14 nm 3 3 135 PCIe 3 0 x16 640 40 16 1354 1493 7000 21 7 54 2 4 112 GDDR5 128 12 12 1 4 5 1 3 1 2 1733 1911 27 14 53 No GeForce GTX 1050 Ti Notebook 237 GP107 N17P G1 A1 768 48 32 1493 1620 47 8 71 7 2293 2488 36 18 64 GeForce GTX 1060 Notebook 237 August 16 2016 GP106 16 4 4 200 1280 80 48 1404 1670 8000 67 4 112 6 192 192 3594 4275 112 56 80 GeForce GTX 1060 Max Q May 2017 1063 1480 71 04 118 4 3789 118 4 59 20 GP106B 1265 GeForce GTX 1070 Notebook 237 August 16 2016 GP104 GP104B 239 7 2 314 2048 128 64 1442 1645 92 3 185 8 256 256 5906 6738 185 92 115 Yes GeForce GTX 1070 Max Q May 2017 1101 1379 88 26 176 5 5648 176 5 88 26 No GeForce GTX 1080 Notebook 237 August 16 2016 2560 160 64 1556 1733 10000 99 6 249 320 GDDR5X 7967 8873 249 124 150 Yes GeForce GTX 1080 Max Q May 2017 1101 1468 93 95 234 9 7516 234 9 117 4 No GeForce 16 series edit Supported APIs Direct3D 12 12 1 OpenGL 4 6 OpenCL 3 0 Vulkan 1 3 and CUDA 7 5 improve NVENC No SLI no TensorCore and no Raytracing hardware acceleration Model Launch Code name Process Transistors billion Die size mm2 Bus interface L2 Cache MB Core config Clock speeds Memory MT s Fillrate Memory Processing power GFLOPS TDP Watts Base core clock MHz Boost core clock MHz Pixel GP s Texture GT s Size GB Bandwidth GB s Bus type Bus width bit Single precision Double precision Half precision Geforce GTX 1630 Jun 28 2022 TU117 TSMC 12FFN 4 7 200 PCIe 3 0 x16 1 0 512 32 16 1740 1785 12000 28 56 57 12 4 96 GDDR6 64 1828 57 12 3 656 75 GeForce GTX 1650 Laptop April 23 2019 1024 64 32 1395 1560 8000 49 92 99 84 4 128 GDDR5 128 3195 99 84 240 6390 50 GeForce GTX 1650 Max Q TU117 N18P G0 MP A1 1020 1245 39 84 79 68 112 2550 79 68 241 5100 30 GeForce GTX 1650 Ti Max Q April 2 2020 TU117 1035 1200 12000 38 4 76 8 4 192 GDDR6 2458 76 8 4915 35 GeForce GTX 1650 Ti TU117 N18P G62 A1 1350 1485 47 52 95 04 3041 95 04 6083 55 GeForce GTX 1660 Laptop TU116 6 6 284 1 5 1408 88 48 1455 1599 16000 76 32 127 2 6 384 192 4070 127 2 242 8141 GeForce GTX 1660 Ti Max Q April 23 2019 1536 96 46 1140 1335 12000 64 08 128 2 288 4101 128 2 243 8202 60 GeForce GTX 1660 Ti Laptop 244 1536 96 46 1455 1590 76 32 152 6 288 4884 152 6 245 9769 80 GeForce 20 series edit Further information GeForce 20 series and Turing microarchitecture Supported APIs Direct3D 12 12 2 OpenGL 4 6 OpenCL 3 0 Vulkan 1 3 and CUDA 7 5 improve NVENC Support B Frame on H265 MX Graphics lack NVENC and they are based on Pascal architecture 246 Add TensorCore and Ray tracing hardware acceleration RTX IO Only on RTX cards Nvidia DLSS Model Launch Code name Process Transistors billion Die size mm2 Core config a Bus interface L2 Cache MB Clock speeds Memory Fillrate b Processing power GFLOPS b Ray tracing Performance TDP Watts Base core clock MHz Boost core clock MHz Memory MT s Size GB Bandwidth GB s Bus type Bus width bit Pixel GP s c Texture GT s d Single precision Double precision Half precision Tensor compute FP16 Rays s Billions RTX OPS s Trillions GeForce RTX 2050 247 248 2022 GA107 Samsung 8N 8 7 200 2048 64 32 64 32 16 3 PCIe 3 0 x8 2 1155 1477 14000 4 112 0 GDDR6 64 30 45 GeForce RTX 2060 249 January 29 2019 TU106 TSMC12FFN 10 8 445 1920 120 48 240 30 30 3 PCIe 3 0 x16 3 960 1200 6 336 0 192 57 6 144 4608 144 0 9216 80 GeForce RTX 2060 Max Q 250 975 1175 11000 264 0 56 88 142 2 4550 142 2 9101 65 GeForce RTX 2070 251 2304 144 64 288 36 36 3 4 1215 1440 14000 8 448 0 256 92 16 207 4 6636 207 4 13270 115 GeForce RTX 2070 Max Q 252 885 1185 12000 75 84 170 6 5460 170 6 10920 80 GeForce RTX 2070 Super 253 April 2 2020 TU104 13 6 545 2560 160 64 320 40 40 5 1140 1380 14000 88 3 220 8 7066 220 8 14130 115 GeForce RTX 2070 Super Max Q 254 930 1155 12000 69 1 172 8 5530 172 8 11060 80 GeForce RTX 2080 255 January 29 2019 2944 184 64 368 46 46 6 1380 1590 14000 384 0 101 8 292 6 9362 292 6 18720 150 GeForce RTX 2080 Max Q 256 735 1095 12000 70 08 201 5 6447 201 5 12890 80 GeForce RTX 2080 Super 257 April 2 2020 3072 192 64 384 48 48 6 1365 1560 14000 448 0 99 8 299 5 9585 299 5 19170 150 GeForce RTX 2080 Super Max Q 258 735 1080 11000 352 0 69 1 207 4 6636 207 4 13270 80 Main Shader Processors Texture Mapping Units Render Output Units Tensor Cores or FP16 Cores in GeForce 16 series Ray tracing Cores Streaming Multiprocessors Graphics Processing Clusters a b Base clock Boost clock Pixel fillrate is calculated as the lowest of three numbers number of ROPs multiplied by the base core clock speed number of rasterizers multiplied by the number of fragments they can generate per rasterizer multiplied by the base core clock speed and the number of streaming multiprocessors multiplied by the number of fragments per clock that they can output multiplied by the base clock rate Texture fillrate is calculated as the number of TMUs multiplied by the base core clock speed GeForce 30 series edit Further information GeForce 30 series and Ampere microarchitecture Supported APIs Direct3D 12 Ultimate 12 2 OpenGL 4 6 OpenCL 3 0 Vulkan 1 3 63 and CUDA 8 6 Tensor core 3rd gen RT core 2nd gen RTX IO Improve NVDEC Add AV1 Model Launch Code name Process Transistors billion Die size mm2 Core config a Bus interface L2 Cache MB Clock speeds b Memory Fillrate c Processing power TFLOPS c Ray tracing Performance TDP Watts Base core MHz Boost core MHz Memory MHz Gb s MT s Size GB Bandwidth GB s Bus type Bus width bit Pixel GP s d Texture GT s e Single precision Double precision Half precision Tensor compute FP16 f Tensor TOPS INT8 f Rays s Billions RTX OPS s Trillions GeForce RTX 3050Mobile 259 Laptop 260 May 11 2021 GA107 Samsung 8N 8 7 200 2048 64 32 64 16 16 3 2560 80 32 80 20 20 PCIe 4 0 x8 2 712 1530622 1237 1057 1740990 1492 1375 150011 1211000 120001375 175011 1411000 14000 46 176 0 192 0132 0 224 0 GDDR6 12896 22 7 48 933 8 55 6 45 6 97 967 7 111 4 2 92 6 274 33 7 13 0 046 0 0980 068 0 111 2 92 6 274 33 7 13 35 80 GeForce 261 RTX 3050 Ti Mobile Laptop 262 2560 80 48 80 20 20 3 735 1462 1035 1695 12000 4 192 128 35 3 70 249 7 81 4 58 8 117 082 8 135 6 3 76 7 495 30 8 68 0 059 0 1170 083 0 136 3 76 7 495 30 8 68 GeForce RTX 3060 Mobile 263 Laptop 264 January 12 2021 GA106 12 0 276 3840 120 48 120 30 30 3 PCIe 4 0 x16 3 817 1387 1282 1702 1200014000 6 288336 192 39 2 66 661 54 81 7 98 0 166 4153 8 204 2 6 27 10 659 85 13 07 0 108 0 1660 154 0 204 6 27 10 659 85 13 07 60 115 GeForce 265 RTX 3070 Mobile 266 Laptop 267 GA104 770 A1 17 4 392 5120 160 80 160 40 40 6 4 780 1215 1290 1620 8 384448 256 62 4 97 2103 2 129 6 124 8 194 4206 4 259 2 7 99 12 4413 21 16 59 0 125 0 1940 206 0 259 7 99 12 4413 21 16 59 80 125 GeForce RTX 3070Ti Mobile Laptop 268 January 4 2022 GA104 5888 184 96 184 46 46 6 510 1035 1035 1485 46 9 95 295 2 136 6 93 8 190 4190 4 273 2 6 01 12 1912 19 17 49 0 094 0 1900 190 0 273 6 01 12 1912 19 17 49 16 6 GeForce RTX 3080 Mobile 269 Laptop 270 January 12 2021 GA104 775 A1 6144 192 96 192 48 48 6 780 1350 1245 1710 8 16 74 9 129 6119 5 164 2 149 8 259 2239 0 328 3 9 59 16 5915 30 21 01 0 150 0 2590 239 0 328 9 59 16 5915 30 21 01 80 150 GeForce RTX 3080Ti Mobile Laptop 271 January 25 2022 GA103 22 496 7424 232 116 232 58 58 6 585 1230 1125 1590 1200016000 16 384512 67 9 142 7 130 5 184 4 135 7 285 4 261 0 368 9 8 68 18 26 16 7 23 60 0 136 0 285 0 261 0 369 8 68 18 26 16 7 23 60 18 71 Main Shader Processors Texture Mapping Units Render Output Units Tensor Cores or FP16 Cores in GeForce 16 series Ray tracing Cores Streaming Multiprocessors Graphics Processing Clusters Which base and boost core clockspeeds the GPU has depends on the TDP configuration set by the system builder a b Base clock Boost clock Pixel fillrate is calculated as the lowest of three numbers number of ROPs multiplied by the base core clock speed number of rasterizers multiplied by the number of fragments they can generate per rasterizer multiplied by the base core clock speed and the number of streaming multiprocessors multiplied by the number of fragments per clock that they can output multiplied by the base clock rate Texture fillrate is calculated as the number of TMUs multiplied by the base core clock speed a b Cite error The named reference Sparsity was invoked but never defined see the help page GeForce 40 series edit div, wikipedia, wiki, book, books, library,

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