List_of_Nvidia_graphics_processing_units

List of Nvidia graphics processing units

Add article description

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

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

Pre-GeForce

Further information: Fahrenheit (microarchitecture)

More information Model, Launch ...

Model	Launch	Code name	Fab (nm)^[2]	Transistors (million)	Die size (mm²)	Bus interface	Core clock (MHz)	Memory clock (MHz)	Core config^{[lower-alpha 1]}	Fillrate				Memory				MFLOPS FP32 ^{[citation needed]}	Latest API support
Model	Launch	Code name	Fab (nm)^[2]	Transistors (million)	Die size (mm²)	Bus interface	Core clock (MHz)	Memory clock (MHz)	Core config^{[lower-alpha 1]}	MOperations/s	MPixels/s	MTexels/s	MVertices/s	Size (MB)	Bandwidth (GB/s)	Bus type	Bus width (bit)	MFLOPS FP32 ^{[citation needed]}	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	NV3	SGS/TSMC 350 nm	4^[4]	90	AGP 2x, PCI	100	100		100	100	100		8	1.6			200.0	5.0	1.0
Riva TNT	June 15, 1998	NV4	TSMC 350 nm	7^[6]	90	AGP 2x, PCI	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		125	150		250	250	250		16 32	2.4		128	500.0
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^{[lower-alpha 1]}	MOperations/s	MPixels/s	MTexels/s	MVertices/s	Size (MB)	Bandwidth (GB/s)	Bus type	Bus width (bit)	MFLOPS FP32	Direct3D	OpenGL
Model	Launch	Code name	Fab (nm)^[2]	Transistors (million)	Die size (mm²)	Bus interface	Core clock (MHz)	Memory clock (MHz)	Core config^{[lower-alpha 1]}	Fillrate				Memory				MFLOPS FP32	Latest API support

Pixel pipelines: texture mapping units: render output units

GeForce 256 series

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

More information Model, Launch ...

Model	Launch	Code name	Transistors (million)	Die size (mm²)	Bus interface	Core clock (MHz)	Memory clock (MHz)	Core config^{[lower-alpha 1]}	Fillrate				Memory				MFLOPS FP32
Model	Launch	Code name	Transistors (million)	Die size (mm²)	Bus interface	Core clock (MHz)	Memory clock (MHz)	Core config^{[lower-alpha 1]}	MOperations/s	MPixels/s	MTexels/s	MVertices/s	Size (MB)	Bandwidth (GB/s)	Bus type	Bus width (bit)	MFLOPS FP32
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	NV10	17	139	AGP 4x, PCI	120	150	4:4:4	480	480	480	0	32 64	4.800	DDR	128	960

Pixel pipelines: texture mapping units: render output units

GeForce2 series

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)

More information Model, Launch ...

Model	Launch	Code name	Fab (nm)^[2]	Transistors (million)	Die size (mm²)	Bus interface	Core clock (MHz)	Memory clock (MHz)	Core config^{[lower-alpha 1]}	Fillrate				Memory				GFLOPS FP32
Model	Launch	Code name	Fab (nm)^[2]	Transistors (million)	Die size (mm²)	Bus interface	Core clock (MHz)	Memory clock (MHz)	Core config^{[lower-alpha 1]}	MOperations/s	MPixels/s	MTexels/s	MVertices/s	Size (MB)	Bandwidth (GB/s)	Bus type	Bus width (bit)	GFLOPS FP32
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							166							2.656	SDR	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		800	800	1,600			6.4			1.600
GeForce2 Ti	October 1, 2001		TSMC 150 nm				250	200		1,000	1,000	2,000			6.4			2.000
GeForce2 Ultra	August 14, 2000		TSMC 180 nm				250	230		1,000	1,000	2,000		64	7.36			2.000

Pixel pipelines: texture mapping units: render output units

GeForce3 series

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

More information Model, Launch ...

Model	Launch	Code name	Transistors (million)	Die size (mm²)	Bus interface	Core clock (MHz)	Memory clock (MHz)	Core config^{[lower-alpha 1]}	Fillrate				Memory				GFLOPS FP32
Model	Launch	Code name	Transistors (million)	Die size (mm²)	Bus interface	Core clock (MHz)	Memory clock (MHz)	Core config^{[lower-alpha 1]}	MOperations/s	MPixels/s	MTexels/s	MVertices/s	Size (MB)	Bandwidth (GB/s)	Bus type	Bus width (bit)	GFLOPS FP32
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

Pixel shaders: vertex shaders: texture mapping units: render output units

GeForce4 series

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

More information Model, Launch ...

Model	Launch	Code name	Transistors (million)	Die size (mm²)	Bus interface	Core clock (MHz)	Memory clock (MHz)	Core config^{[lower-alpha 1]}	Fillrate				Memory				Supported API version		GFLOPS FP32
Model	Launch	Code name	Transistors (million)	Die size (mm²)	Bus interface	Core clock (MHz)	Memory clock (MHz)	Core config^{[lower-alpha 1]}	MOperations/s	MPixels/s	MTexels/s	MVertices/s	Size (MB)	Bandwidth (GB/s)	Bus type	Bus width (bit)	Direct3D	OpenGL	GFLOPS FP32
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				1,000		64	2.656	SDR DDR	128 (SDR) 64 (DDR)
GeForce4 MX440 SE	2002	NV17	29^[12]	65	AGP 4x PCI		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		64 128	2.656		64
GeForce PCX4300	February 19, 2004	NV18B	29	65	PCIe x16		166				1000		128	2.656		64
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	275	166 250		550	550	1,100	137.5		2.656^[15] 8.0		64 128			1.100
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	250		1,000	1,000	2,000	125		8.0					15.00
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^{[lower-alpha 2]})	January 20, 2003	NV28	63	101	AGP 8x	275	275		1,100	1,100	2,200	137.5		8.8					16.50
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^{[lower-alpha 3]})	January 20, 2003	NV28	63	101	AGP 8x	300	325		1,200	1,200	2,400	150		10.4					18.00

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.

More information Model, Features ...

Model	Features
Model	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

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

More information Model, Launch ...

Model	Launch	Code name	Fab (nm)^[2]	Transistors (million)	Die size (mm²)	Bus interface	Core clock (MHz)	Memory clock (MHz)	Core config^{[lower-alpha 1]}	Fillrate				Memory				GFLOPS FP32
Model	Launch	Code name	Fab (nm)^[2]	Transistors (million)	Die size (mm²)	Bus interface	Core clock (MHz)	Memory clock (MHz)	Core config^{[lower-alpha 1]}	MOperations/s	MPixels/s	MTexels/s	MVertices/s	Size (MB)	Bandwidth (GB/s)	Bus type	Bus width (bit)	GFLOPS FP32
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						AGP 8x	250	166		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	250	200		1,000	1,000	1,000	125.0		3.2 6.4		64 128	15.0
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	March 6, 2003						400	400		1,600	1,600	1,600	200.0	64 128	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	250	200		1500	1500	1500	187.5		3.2 6.4		64 128	17.5
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	425	250		1,700	1,700	1,700	318.7	128	8.0			29.7
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	475		1,900	1,900	1,900	356.2	128 256	15.2	GDDR3		33.2
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	January 27, 2003	NV30		125^[23]	199		500	500	4:2:8:4	2,000	2,000	4,000	375.0		16.0	GDDR2		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	350		1,600	1,600	3,200	300.0		22.4			27.3
GeForce FX 5900	May 2003						400	425		1,600	1,600	3,200	300.0		27.2			28.0
GeForce FX 5900 Ultra	May 12, 2003						450	425		1,800	1,800	3,600	337.5	128 256	27.2			31.5
GeForce PCX 5900	March 17, 2004					PCIe x16	350	275		1,400	1,400	2,800	262.5	128 256	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	NV38		135^[26]	207	PCIe x16	475	425		1,900	1,900	3,800	356.2	256	27.2	GDDR3		33.2
Model	Launch	Code name	Fab (nm)^[2]	Transistors (million)	Die size (mm²)	Bus interface	Core clock (MHz)	Memory clock (MHz)	Core config^{[lower-alpha 1]}	Fillrate				Memory				GFLOPS FP32
Model	Launch	Code name	Fab (nm)^[2]	Transistors (million)	Die size (mm²)	Bus interface	Core clock (MHz)	Memory clock (MHz)	Core config^{[lower-alpha 1]}	MOperations/s	MPixels/s	MTexels/s	MVertices/s	Size (MB)	Bandwidth (GB/s)	Bus type	Bus width (bit)	GFLOPS FP32

Pixel shaders: vertex shaders: texture mapping units: render output units

GeForce 6 (6xxx) series

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

More information Model, Launch ...

Model	Launch	Code name	Fab (nm)^[2]	Transistors (million) Die size (mm²)	Bus interface	Core clock (MHz)	Memory clock (MHz)	Core config^{[lower-alpha 1]}	Fillrate				Memory
Model	Launch	Code name	Fab (nm)^[2]	Transistors (million) Die size (mm²)	Bus interface	Core clock (MHz)	Memory clock (MHz)	Core config^{[lower-alpha 1]}	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	June 2006	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	100–200 (DDR) 200–533 (DDR2)		950	475	950	118.75		1.6–6.4 (DDR) 3.2–17.056 (DDR2)	DDR 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	NV44		75 110^[27]	PCIe x16	400	333	4:3:4:2	1,600	800	1,600	300	128 256	5.328		64
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					300	275 400	8:3:8:4	2,400	1,200	2,400	225		8.8 12.8	DDR DDR2
GeForce 6600 GT	August 12, 2004 (PCIe) November 14, 2004 (AGP)					500	475 (AGP) 500 (PCIe)	8:3:8:4	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)	8:4:8:8	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	500	16:6:16:16	5,600	5,600	5,600	525	128 256	32
GeForce 6800 Ultra	May 4, 2004 (AGP) June 28, 2004 (PCIe) March 14, 2005 (512 MB)	NV40 (AGP) NV45 (PCIe)		222 287 (NV40)^[34] 222 287 (NV45)^[39]	AGP 8x PCIe x16	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^{[lower-alpha 1]}	Fillrate				Memory
Model	Launch	Code name	Fab (nm)^[2]	Transistors (million) Die size (mm²)	Bus interface	Core clock (MHz)	Memory clock (MHz)	Core config^{[lower-alpha 1]}	MOperations/s	MPixels/s	MTexels/s	MVertices/s	Size (MB)	Bandwidth (GB/s)	Bus type	Bus width (bit)

Pixel shaders: vertex shaders: texture mapping units: render output units

Features

More information Model, Features ...

Model	Features
Model	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

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)

More information Model, Launch ...

Model	Launch	Code name	Fab (nm)^[2]	Transistors (million)	Die size (mm²)	Bus interface	Core clock (MHz)	Memory clock (MHz)	Core config^{[lower-alpha 1]}	Fillrate				Memory
Model	Launch	Code name	Fab (nm)^[2]	Transistors (million)	Die size (mm²)	Bus interface	Core clock (MHz)	Memory clock (MHz)	Core config^{[lower-alpha 1]}	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	TSMC 110 nm			HyperTransport	425	200 (DDR) 400 (DDR2) 933 (DDR3)		850	850	850	106.25		6.4 12.8 34	DDR DDR2 DDR3	64 128
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		MCP76				FSB	630	400		1,260	1,260	1,260	157.5		6.4
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	128 256	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	March 22, 2006						350	333						128	2.656 5.328
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	128 256	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)	G73					560			6,720	4,480	6,720	700
GeForce 7600 GT 80 nm	January 8, 2007	G73-B1	TSMC 80 nm				560			6,720	4,480	6,720	700
GeForce 7650 GS	March 22, 2006	G73	TSMC 80 nm			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)					PCIe x16	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	450		24:8:24:16	10,800	7,200	10,800	900	256
GeForce 7900 GTO	October 1, 2006						650			15,600	10,400	15,600	1,300	512
GeForce 7900 GTX	March 9, 2006						650	800		15,600	10,400	15,600	1,300	512	51.2
GeForce 7900 GX2	March 9, 2006	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^{[lower-alpha 1]}	MOperations/s	MPixels/s	MTexels/s	MVertices/s	Size (MB)	Bandwidth (GB/s)	Bus type	Bus width (bit)
Model	Launch	Code name	Fab (nm)^[2]	Transistors (million)	Die size (mm²)	Bus interface	Core clock (MHz)	Memory clock (MHz)	Core config^{[lower-alpha 1]}	Fillrate				Memory

Pixel shaders: vertex shaders: texture mapping units: render output units

Features

More information Model, Features ...

Model	Features
Model	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

Further information: GeForce 8 series and Tesla (microarchitecture)

All models support coverage sample anti-aliasing, angle-independent anisotropic filtering, and 128-bit OpenEXR HDR.

More information Model, Launch ...

Model	Launch	Code name	Fab (nm)^[2]	Transistors (million)	Die size (mm²)	Bus interface	Core config^{[lower-alpha 1]}	Clock rate			Fillrate		Memory				Supported API version		Processing power (GFLOPS)^{[lower-alpha 2]}	TDP (Watts)	Comments
Model	Launch	Code name	Fab (nm)^[2]	Transistors (million)	Die size (mm²)	Bus interface	Core config^{[lower-alpha 1]}	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
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				1200				gt						28.8	Unknown	PureVideo 3 with VP3
GeForce 8300 mGPU^[44]				Unknown	Unknown				1500				Up to 512 from system memory						36	Unknown	PureVideo 3 with VP3
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	G86			127	PCIe 1.0 x16 PCI	16:8:4	450	900		1.8	3.6	128 256 512						28.8	40
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	128 256 512						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	25
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	400	4.32	4.32	256 512	12.8	DDR2				75.5	47	OEM only
GeForce 8600 GT	April 17, 2007					PCIe 1.0 x16 PCI	32:16:8	540	1188	400 700	4.32	8.64	256 512 1024	12.8 22.4	DDR2 GDDR3				76	47
GeForce 8600 GTS	April 17, 2007					PCIe 1.0 x16	32:16:8	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	G80	TSMC 90 nm	681	484	PCIe 1.0 x16	112:28:^{[lower-alpha 3]}20	500	1200		10	14	640	64		320			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	G92	TSMC 65 nm	754	324	PCIe 2.0 x16	128:64:16	650	1625	970	10.4	41.6	512	62.1		256			416	135
GeForce 8800 GTX	November 8, 2006	G80	TSMC 90 nm	681	484	PCIe 1.0 x16	128:32:^{[lower-alpha 3]}24	575	1350	900	13.8	18.4	768	86.4		384			345.6	145
GeForce 8800 Ultra	May 2, 2007	G80	TSMC 90 nm	681	484	PCIe 1.0 x16	128:32:^{[lower-alpha 3]}24	612	1500	1080	14.7	19.6	768	103.7		384			384	175
Model	Launch	Code name	Fab (nm)^[2]	Transistors (million)	Die size (mm²)	Bus interface	Core config^{[lower-alpha 1]}	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
Model	Launch	Code name	Fab (nm)^[2]	Transistors (million)	Die size (mm²)	Bus interface	Core config^{[lower-alpha 1]}	Clock rate			Fillrate		Memory				Supported API version		Processing power (GFLOPS)^{[lower-alpha 2]}	TDP (Watts)	Comments

Unified shaders: texture mapping units: render output units
To calculate the processing power, see Performance.
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

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

More information Model, Features ...

Model	Features
Model	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

Further information: GeForce 9 series and Tesla (microarchitecture)

All models support Coverage Sample Anti-Aliasing, Angle-Independent Anisotropic Filtering, 128-bit OpenEXR HDR

More information Model, Launch ...

Model	Launch	Code name	Fab (nm)^[2]	Transistors (million)	Die size (mm²)	Bus interface	Core config^{[lower-alpha 1]}	Clock rate			Fillrate		Memory				Supported API version		Processing power (GFLOPS)^{[lower-alpha 2]}	TDP (Watts)	Comments
Model	Launch	Code name	Fab (nm)^[2]	Transistors (million)	Die size (mm²)	Bus interface	Core config^{[lower-alpha 1]}	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
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	October 2008	MCP7A-U	65 nm	282	162		16:8:4	580	1400	400 666	2.32	4.64	Up to 512 from system memory	6.4/12.8 10.664/21.328	DDR2 DDR3	64 128			67.2	12	based on 8400 GS
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]	June 2008	G98	TSMC 65 nm	210	86		8:8:4	567	1400	500	2.268	4.536	256	6.4^[50]	DDR2	64			22.4	25
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	July 29, 2008	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	TSMC 65 nm	754	324		96:48:12	550	1375	800	6.6	26.4	384 768 1536	38.4	GDDR3	192			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		64:32:16	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		324 260		112:56:16	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		128:64:16	738	1836	1100	11.808	47.232	512 1024	70.4					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^{[lower-alpha 1]}	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
Model	Launch	Code name	Fab (nm)^[2]	Transistors (million)	Die size (mm²)	Bus interface	Core config^{[lower-alpha 1]}	Clock rate			Fillrate		Memory				Supported API version		Processing power (GFLOPS)^{[lower-alpha 2]}	TDP (Watts)	Comments

Unified shaders: texture mapping units: render output units
To calculate the processing power see Tesla (microarchitecture)#Performance.

Features

Compute Capability: 1.1 has support for Atomic functions, which are used to write thread-safe programs.

More information Model, Features ...

Model	Features
Model	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)		No	Yes
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+	Yes 3-way
GeForce 9800 GX2	Yes

GeForce 100 series

Further information: GeForce 100 series and Tesla (microarchitecture)

More information Model, Launch ...

Model	Launch	Code name	Fab (nm)	Transistors (million)	Die size (mm²)	Bus interface	Core config^{[lower-alpha 1]}	Clock rate			Fillrate		Memory configuration				Supported API version		Processing power (GFLOPS)^{[lower-alpha 2]}	TDP (Watts)	Comments
Model	Launch	Code name	Fab (nm)	Transistors (million)	Die size (mm²)	Bus interface	Core config^{[lower-alpha 1]}	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
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	1400	800	4.4	8.8	512	16.0		128			89.6	50
GeForce GT 130		G94b		505	196		48:24:12	500	1250	500	6	12	1536	24.0		192			120	75
GeForce GT 140		G94b		505	196		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	GDDR3	256			470	141

Unified shaders: texture mapping units: render output units
To calculate the processing power see Tesla (microarchitecture)#Performance.

GeForce 200 series

Further information: GeForce 200 series and Tesla (microarchitecture)

All models support Coverage Sample Anti-Aliasing, Angle-Independent Anisotropic Filtering, 240-bit OpenEXR HDR

More information Model, Launch ...

Model	Launch	Code name	Fab (nm)	Transistors (million)	Die size (mm²)	Bus interface	Core config^{[lower-alpha 1]}	Clock rate			Fillrate		Memory configuration				Supported API version		Processing power (GFLOPS)^{[lower-alpha 2]}	TDP (Watts)	Comments	Release Price (USD)
Model	Launch	Code name	Fab (nm)	Transistors (million)	Die size (mm²)	Bus interface	Core config^{[lower-alpha 1]}	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	TDP (Watts)	Comments	Release Price (USD)
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	TSMC 40 nm	260	57	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	October 12, 2009	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
GeForce GT 230	April 27, 2009^[52]	G92b	TSMC/UMC 55 nm	754	260		96:48:12	500	1242	1000	6	24	1536	24	DDR2	192	10		238.5	75	OEM only
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
GeForce GTS 250	March 3, 2009	G92-428-B1	TSMC 65 nm TSMC/UMC 55 nm		260		128:64:16	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])
GeForce GTX 260	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		240:80:32	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	TSMC/UMC 55 nm	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^{[lower-alpha 1]}	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)
Model	Launch	Code name	Fab (nm)	Transistors (million)	Die size (mm²)	Bus interface	Core config^{[lower-alpha 1]}	Clock rate			Fillrate		Memory configuration				Supported API version		Processing power (GFLOPS)^{[lower-alpha 2]}	TDP (Watts)	Comments	Release Price (USD)

Unified shaders: texture mapping units: render output units
To calculate the processing power see Tesla (microarchitecture)#Performance.

Features

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)

More information Model, Features ...

Model	Features
Model	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

Further information: GeForce 300 series and Tesla (microarchitecture)

All models support the following API levels: Direct3D 10.1 and OpenGL 3.3

More information Model, Launch ...

Model	Launch	Code name	Fab (nm)	Transistors (million)	Die size (mm²)	Bus interface	Core config^{[lower-alpha 1]}	Clock rate			Fillrate		Memory configuration				Processing power (GFLOPS)^{[lower-alpha 2]}	TDP (Watts)	Comments
Model	Launch	Code name	Fab (nm)	Transistors (million)	Die size (mm²)	Bus interface	Core config^{[lower-alpha 1]}	Core (MHz)	Shader (MHz)	Memory (MHz)	Pixel (GP/s)	Texture (GT/s)	Size (MB)	Bandwidth (GB/s)	DRAM type	Bus width (bit)	Single precision	TDP (Watts)	Comments
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	64	105.6	33	OEM Card, similar to Geforce GT220
GeForce GT 320		GT215		727	144		72:24:8	540	1302	1580	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]					96:32:8	500	1250		4.000	24.00	256	51.20		256	240.0
		G92B^[58]					96:32:16	500	1250		8.000	24.00	1024	16.32	DDR2	128	240.0
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

Unified shaders: texture mapping units: render output units
To calculate the processing power see Tesla (microarchitecture)#Performance.

GeForce 400 series

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.

More information Model, Launch ...

Model	Launch	Code name	Fab (nm)	Transistors (million)	Die size (mm²)	SM count	Core config^{[lower-alpha 1]}^{[lower-alpha 2]}	Clock rate			Fillrate		Memory configuration				Supported API version				Processing power (GFLOPS)^{[lower-alpha 3]}		TDP (Watts)^{[lower-alpha 4]}	Release Price (USD)
Model	Launch	Code name	Fab (nm)	Transistors (million)	Die size (mm²)	SM count	Core config^{[lower-alpha 1]}^{[lower-alpha 2]}	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^{[lower-alpha 5]}	Single precision	Double precision	TDP (Watts)^{[lower-alpha 4]}	Release Price (USD)
GeForce 405^{[lower-alpha 6]}	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	1	48:4:4	700	1400	1800	2.8	2.8	512	28.8	GDDR3	128		12 FL 11_1	4.6	1.1	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		128				1.2	268.8	Unknown	60
										1800			512 1024 2048	28.8		128				1.1	268.8	Unknown	49	$79
										1300			512 1024 2048	10.4		64					268.8	Unknown	49	$79
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
GeForce GT 440	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	October 11, 2010	GF106				3	144:24:24	790	1580	4000	4.7	18.9	1536	96.0	GDDR5	192					455.04	Unknown	106	OEM
GeForce GTS 450	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	650	1300	3400	9.1	36.4	1024	108.8		256					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
	July 12, 2010	GF104-300-KB-A1					336:56:32	675	1350	3600	9.4	37.8	1024 2048	115.2		256					907.2	Unknown	160	$229
	September 24, 2011	GF114					336:56:24	779	1557	4008	10.9	43.6	1024	96.2		192					1045.6	Unknown	160	$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^{[lower-alpha 4]}	$279
GeForce GTX 470	March 26, 2010	GF100-275-A3				14	448:56:40	608	1215	3348	17.0	34.0	1280	133.9		320					1088.64	136.08	215^{[lower-alpha 4]}	$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^{[lower-alpha 4]}	$499
Model	Launch	Code name	Fab (nm)	Transistors (million)	Die size (mm²)	SM count	Core config^{[lower-alpha 1]}^{[lower-alpha 2]}	Clock rate			Fillrate		Memory configuration				Supported API version				Processing power (GFLOPS)^{[lower-alpha 3]}		TDP (Watts)^{[lower-alpha 4]}	Release Price (USD)
Model	Launch	Code name	Fab (nm)	Transistors (million)	Die size (mm²)	SM count	Core config^{[lower-alpha 1]}^{[lower-alpha 2]}	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^{[lower-alpha 5]}	Single precision	Double precision	TDP (Watts)^{[lower-alpha 4]}	Release Price (USD)

Unified shaders: texture mapping units: render output units
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]
To calculate the processing power see Fermi (microarchitecture)#Performance.
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]
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

Further information: GeForce 500 series and Fermi (microarchitecture)

More information Model, Launch ...

Model	Launch	Code name	Fab (nm)	Transistors (million)	Die size (mm²)	Bus interface	SM count	Core config^{[lower-alpha 1]}^{[lower-alpha 2]}	Clock rate			Fillrate		Memory configuration				Supported API version				Processing power (GFLOPS)^{[lower-alpha 3]}		TDP (watts)^{[lower-alpha 4]}	Release Price (USD)
Model	Launch	Code name	Fab (nm)	Transistors (million)	Die size (mm²)	Bus interface	SM count	Core config^{[lower-alpha 1]}^{[lower-alpha 2]}	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	TDP (watts)^{[lower-alpha 4]}	Release Price (USD)
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	GF119		292	79	PCIe 2.0 x16 PCIe 2.0 x1 PCI	1	48:8:4	810	1620		3.25	6.5		14.4		64					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
GeForce GT 545		GF116					3	144:24:16	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^{[lower-alpha 5]} 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^{[lower-alpha 5]}					847.9	Unknown	150	OEM
GeForce GTX 560 SE	February 20, 2012^[68]	GF114-200-KB-A1^{[lower-alpha 6]}					6	288:48:24	736	1472	3828	17.6	35.3	1024	91.9		128+64^{[lower-alpha 5]}					847.9	Unknown		OEM
GeForce GTX 560	May 17, 2011	GF114-325-A1^{[lower-alpha 6]}					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^{[lower-alpha 6]}					8	384:64:32	822	1645	4008	26.3	52.61	1024 2048	128.26		256					1263.4	110	170	$249
GeForce GTX 560 Ti	May 30, 2011	GF110^{[lower-alpha 7]}		3000^[70]	520^[70]		11	352:44:40	732	1464	3800	29.28	32.21	1280 2560	152		320					1030.7	128.83	210^{[lower-alpha 4]}	OEM
GeForce GTX 560 Ti 448 Cores	November 29, 2011	GF110-270-A1^{[lower-alpha 7]}					14	448:56:40					40.99	1280								1311.7	163.97	210^{[lower-alpha 4]}	$289
GeForce GTX 570	December 7, 2010	GF110-275-A1^{[lower-alpha 7]}					15	480:60:40					43.92	1280 2560								1405.4	175.68	219^{[lower-alpha 4]}	$349
GeForce GTX 580	November 9, 2010	GF110-375-A1^{[lower-alpha 7]}					16	512:64:48	772	1544	4008	37.05	49.41	1536 3072^{[lower-alpha 8]}	192.384		384					1581.1	197.63	244^{[lower-alpha 4]}^[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^{[lower-alpha 1]}^{[lower-alpha 2]}	Clock rate			Fillrate		Memory configuration				Supported API version				Processing power (GFLOPS)^{[lower-alpha 3]}		TDP (Watts)^{[lower-alpha 4]}	Release Price (USD)
Model	Launch	Code name	Fab (nm)	Transistors (million)	Die size (mm²)	Bus interface	SM count	Core config^{[lower-alpha 1]}^{[lower-alpha 2]}	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	TDP (Watts)^{[lower-alpha 4]}	Release Price (USD)

Unified shaders: texture mapping units: render output units
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.
To calculate the processing power see Fermi (microarchitecture)#Performance.
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]
1024 MB RAM on 192-bit bus assemble with 4 x (128 MB) + 2 x (256 MB).
Internally referred to as GF104B^[69]
Internally referred to as GF100B^[69]
Some companies have announced that they will be offering the GTX580 with 3GB RAM.^[71]

GeForce 600 series

Further information: GeForce 600 series and Kepler (microarchitecture)

Add NVENC on GTX cards
Several 600 series cards are rebranded 400 or 500 series cards.

More information Model, Launch ...

Model	Launch	Code name	Fab (nm)	Transistors (million)	Die size (mm²)	Bus interface	SM count	Core config^{[lower-alpha 1]}	Clock rate					Fillrate		Memory configuration				Supported API version				Processing power (GFLOPS)^{[lower-alpha 2]}		TDP (Watts)	Release Price (USD)
Model	Launch	Code name	Fab (nm)	Transistors (million)	Die size (mm²)	Bus interface	SM count	Core config^{[lower-alpha 1]}	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^{[lower-alpha 3]}	Direct3D	OpenGL	OpenCL	Single precision	Double precision	TDP (Watts)	Release Price (USD)
GeForce 605^{[lower-alpha 4]}	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^{[lower-alpha 5]}	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^{[lower-alpha 6]}	April 3, 2012	GF119				PCIe 2.0 x16		48:8:4	810	—	—	1620	898 (1796)	3.24	6.5	512 1024	14.4							155.5	Unknown	30	OEM
GeForce GT 620^{[lower-alpha 6]}	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^{[lower-alpha 7]}^{[lower-alpha 8]}	April 24, 2012	GK107	TSMC 28 nm	1300	118	PCIe 3.0 x16	1	192:16:16	875	—	—	875	891 (1782)	14	14	1024 2048	28.5		128	1.2				336	14	50	OEM
	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
	May 15, 2012	GF108	TSMC 40 nm	585	116	PCIe 2.0 x16	2	96:16:4	810	—	—	1620	800 (3200)	3.2	13	1024	51.2	GDDR5		—				311	Unknown	65	Retail
	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	TSMC 28 nm	1020	79	PCIe 3.0 x8	1	384:16:8	967	—	—	967	1001 (2002)	7.74	15.5	1024 2048	16		64	1.2				742.7	Unknown	35	OEM
GeForce GT 640^{[lower-alpha 9]}	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
	April 24, 2012	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^{[lower-alpha 10]}	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	OEM
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	64	$110
GeForce GTX 650	November 27, 2013 ^[73]	GK-106-400-A1		2540	221		2	384:32:16	1058	—	65	1058	1250 (5000)	16.9	33.8		80							812.54	33.86	?
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					4	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	980	1032	1084	980	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)
GeForce GTX 660	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					7	1344:112:32	915	980	1084	915	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	2048 4096	192.256		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^{[lower-alpha 1]}	Clock rate					Fillrate		Memory configuration				Supported API version				Processing power (GFLOPS)^{[lower-alpha 2]}		TDP (Watts)	Release Price (USD)
Model	Launch	Code name	Fab (nm)	Transistors (million)	Die size (mm²)	Bus interface	SM count	Core config^{[lower-alpha 1]}	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^{[lower-alpha 3]}	Direct3D	OpenGL	OpenCL	Single precision	Double precision	TDP (Watts)	Release Price (USD)

Unified shaders: texture mapping units: render output units
To calculate the processing power see Kepler (microarchitecture)#Performance, or Fermi (microarchitecture)#Performance.
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

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

More information Model, Launch ...

Model	Launch	Code name	Fab (nm)	Transistors (million)	Die size (mm²)	Bus interface	SMX count	Core config^{[lower-alpha 1]}	Clock rate				Fillrate		Memory configuration				Supported API version				Processing power (GFLOPS)^{[lower-alpha 2]}		TDP (Watts)	Release Price (USD)
Model	Launch	Code name	Fab (nm)	Transistors (million)	Die size (mm²)	Bus interface	SMX count	Core config^{[lower-alpha 1]}	Base (MHz)	Average Boost (MHz)	Max Boost^{[lower-alpha 3]} (MHz)	Memory (MHz)	Pixel (GP/s)	Texture (GT/s)	Size (MB)	Bandwidth (GB/s)	DRAM type	Bus width (bit)	Vulkan^{[lower-alpha 4]}	Direct3D^{[lower-alpha 5]}	OpenGL	OpenCL	Single precision	Double precision	TDP (Watts)	Release Price (USD)
GeForce GT 705^[77]^{[lower-alpha 6]}	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]	March 27, 2014	GK208-301-A1	TSMC 28 nm	1020	79	PCIe 2.0 x8		192:16:8	823	—	—	900 (1800)	6.6	13.2	512	14.4	DDR3	64	1.2			1.2	316.0	13.2		OEM
GeForce GT 710^[78]	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	DDR3 GDDR5						306	12.8	19	$49–59
GeForce GT 730 ^[80]^{[lower-alpha 7]}^{[lower-alpha 8]}	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						692.7	28.9	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^{[lower-alpha 9]}	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	DDR3	128	1.2			1.2	762.6	31.8	64	$89–99
GeForce GT 740^{[lower-alpha 9]}	May 29, 2014	GK107-425-A2		1270	118			384:32:16	993	—	—	1252 (5008)	15.9	31.8		80.1	GDDR5		1.2				762.6	31.8	64	$89–99
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	55	$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					6	1152:96:32	980	1033	1124	1502 (6008)	31.4^{[lower-alpha 10]}	94	2048 4096	192.3		256					2257.9	94.1	170	$249 ($219)
GeForce GTX 760 Ti^{[lower-alpha 11]}	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	170	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^{[lower-alpha 10]}	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^{[lower-alpha 10]}	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	6144	336.5							5120.6	1706.9		$999
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^{[lower-alpha 1]}	Clock rate				Fillrate		Memory configuration				Supported API version				Processing power (GFLOPS)^{[lower-alpha 2]}		TDP (Watts)	Release Price (USD)
Model	Launch	Code name	Fab (nm)	Transistors (million)	Die size (mm²)	Bus interface	SMX count	Core config^{[lower-alpha 1]}	Base (MHz)	Average Boost (MHz)	Max Boost^{[lower-alpha 3]} (MHz)	Memory (MHz)	Pixel (GP/s)	Texture (GT/s)	Size (MB)	Bandwidth (GB/s)	DRAM type	Bus width (bit)	Vulkan^{[lower-alpha 4]}	Direct3D^{[lower-alpha 5]}	OpenGL	OpenCL	Single precision	Double precision	TDP (Watts)	Release Price (USD)

Unified shaders: texture mapping units: render output units
To calculate the processing power see Maxwell (microarchitecture)#Performance, or Kepler (microarchitecture)#Performance.
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.
Maxwell supports Vulkan version 1.3, while Kepler only support Vulkan version 1.2, Fermi does not support the Vulkan API at all.^[63]
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.
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

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.

More information Model, Launch ...

Model	Launch	Code name	Process	Transistors (billion)	Die size (mm²)	Core config^{[lower-alpha 1]}	Bus interface	L2 Cache (MB)	Clock Speeds			Memory				Fillrate^{[lower-alpha 2]}		Processing power (GFLOPS)^{[lower-alpha 2]}^{[lower-alpha 3]}		TDP (Watts)	SLI support	Release price (USD)
Model	Launch	Code name	Process	Transistors (billion)	Die size (mm²)	Core config^{[lower-alpha 1]}	Bus interface	L2 Cache (MB)	Base (MHz)	Boost (MHz)	Memory (MT/s)	Size (GB)	Bandwidth (GB/s)	Bus type	Bus width (bit)	Pixel (GP/s)^{[lower-alpha 4]}	Texture (GT/s)^{[lower-alpha 5]}	Single precision	Double precision	TDP (Watts)	SLI support	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^{[lower-alpha 6]})	2-way SLI	$159
GeForce GTX 950 (OEM)^[100]	Unknown	GM206				1024:64:32 (8)			935	Unknown	5000	2	80.0			29.9	59.8	1,914.9 ,	59.8	Unknown		OEM
GeForce GTX 960^[101]	January 22, 2015	GM206-300				1024:64:32 (8)			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^{[lower-alpha 7]}	196.3 + 28.0^{[lower-alpha 7]}		224 + 32^{[lower-alpha 7]}	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		8	601	3072:192:96 (24)		3	1000	1075		12	336.5		384	96.0 103.2	192.0 206.4	6,144.0 6,604.8	192.0 206.4	250		$999

Main shader processors : texture mapping units : render output units (streaming multiprocessors)
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]
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

Further information: GeForce 10 series and Pascal (microarchitecture)

Supported display standards: DP 1.4 (no DSC), HDMI 2.0b, Dual-link DVI^{[lower-alpha 1]}^[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.)

More information Model, Launch ...

Model	Launch	Code name	Process	Transistors (billion)	Die size (mm²)	Core config^{[lower-alpha 2]}	Bus interface	L2 Cache (MB)	Clock speeds			Memory				Fillrate^{[lower-alpha 3]}		Processing power (GFLOPS)^{[lower-alpha 3]}^{[lower-alpha 4]}			TDP (Watts)	SLI support	Release price (USD)
Model	Launch	Code name	Process	Transistors (billion)	Die size (mm²)	Core config^{[lower-alpha 2]}	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)^{[lower-alpha 5]}^{[lower-alpha 6]}	Texture (GT/s)^{[lower-alpha 7]}	Single precision	Double precision	Half precision	TDP (Watts)	SLI support	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	—
GeForce GT 1010 ^[111]^[112]	January 13, 2021	GP108-200-A1				256:16:16 (2) (1)		0.25	1152	1380	2100		16.8	DDR4		9.2 11.0	18.4 22.0	590.0 706.6	24.6 29.4	?	20		OEM
GeForce GT 1030 ^[113]^[114]^[115]^[116]	March 12, 2018	GP108-310-A1				384:24:16 (3) (1)		0.5	1152	1379	2100		16.8	DDR4		18.4 22.0	27.6 33.0	884.7 1,059.0	27.6 33.0	13.8 16.5	20		$79
GeForce GT 1030 ^[113]^[114]^[115]^[116]	May 17, 2017	GP108-300-A1				384:24:16 (3) (1)		0.5	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
GeForce GTX 1050^[117]	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			$109
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	1152:72:48 (9) (2)		1.5				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			$199
	December 26, 2017	GP106-350-K3-A1		4.4	200	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		7.2	314									GDDR5X									$299
	July 19, 2016	GP106-400-A1		4.4	200									GDDR5									$249	$299
	April 20, 2017	GP106-410-A1		4.4	200						9000		216.0	GDDR5									$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	1683	8000		256.0	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
GeForce GTX 1080^[125]^[126]	April 20, 2017	GP104-410-A1				2560:160:64 (20) (4)				1733	11000		352.0			102.8 110.9	257.1 277.2	8,227.8 8,872.9	257.1 277.2	128.5 138.6			$599	$699
GeForce GTX 1080 Ti^[127]	March 5, 2017	GP102-350-K1-A1		12	471	3584:224:88 (28) (6)		2.75	1480	1582	11000	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)		3	1405	1582	11400	12	547.7		384	134.8 142.0	337.2 355.2	10,790.4 12,149.7	337.2 355.2	168.6 177.6			$1199	—
Model	Launch	Code name	Process	Transistors (billion)	Die size (mm²)	Core config^{[lower-alpha 2]}	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)^{[lower-alpha 5]}^{[lower-alpha 8]}	Texture (GT/s)^{[lower-alpha 7]}	Single precision	Double precision	Half precision	TDP (Watts)	SLI support	MSRP	Founders Edition
Model	Launch	Code name	Process	Transistors (billion)	Die size (mm²)	Core config^{[lower-alpha 2]}	Bus interface	L2 Cache (MB)	Clock speeds			Memory				Fillrate^{[lower-alpha 3]}		Processing power (GFLOPS)^{[lower-alpha 3]}^{[lower-alpha 4]}			TDP (Watts)	SLI support	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.
Main shader processors : texture mapping units : render output units (streaming multiprocessors) (graphics processing clusters)
Base clock, Boost clock
To calculate the processing power see Pascal (microarchitecture)#Performance.
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]
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

Further information: Volta (microarchitecture)

Supported APIs: Direct3D 12 (12_1), OpenGL 4.6, OpenCL 3.0, Vulkan 1.3^[63] and CUDA 7.0

More information Model, Launch ...

Model	Launch	Code name	Process	Transistors (billion)	Die size (mm²)	Core config^{[lower-alpha 1]}	Bus Interface	L2 Cache (MB)	Clock speeds			Memory				Fillrate^{[lower-alpha 2]}		Processing power (GFLOPS)^{[lower-alpha 2]}				TDP (Watts)	NVLink Support	Release price (USD)
Model	Launch	Code name	Process	Transistors (billion)	Die size (mm²)	Core config^{[lower-alpha 1]}	Bus Interface	L2 Cache (MB)	Base core clock (MHz)	Boost core clock (MHz)	Memory (MT/s)	Size (GB)	Bandwidth (GB/s)	Bus type	Bus width (bit)	Pixel (GP/s)^{[lower-alpha 3]}	Texture (GT/s)^{[lower-alpha 4]}	Single precision	Double precision	Half precision	Tensor compute + Single precision	TDP (Watts)	NVLink Support	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	TSMC 12FFN	21.1	815	5120:320:128:640 (80) (6)	PCIe 3.0 x16	6	1200	1455	1700	32	870.4	HBM2	4096	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	—

Main shader processors : texture mapping units : render output units : tensor cores (streaming multiprocessors) (graphics processing clusters)
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

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)

More information Model, Launch ...

Model	Launch	Code name	Process	Transistors (billion)	Die size (mm²)	Core config^{[lower-alpha 1]}	Bus interface	L2 Cache (MB)	Clock speeds			Memory				Fillrate^{[lower-alpha 2]}		Processing power (GFLOPS)^{[lower-alpha 2]}			TDP (Watts)	NVLink support	Release price (USD)
Model	Launch	Code name	Process	Transistors (billion)	Die size (mm²)	Core config^{[lower-alpha 1]}	Bus interface	L2 Cache (MB)	Base core clock (MHz)	Boost core clock (MHz)	Memory (GT/s)	Size (GB)	Bandwidth (GB/s)	Bus type	Bus width (bit)	Pixel (GP/s)^{[lower-alpha 3]}	Texture (GT/s)^{[lower-alpha 4]}	Single precision	Double precision	Half precision	TDP (Watts)	NVLink support	Release price (USD)
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]	TU117-300-A1							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				1410	1590						45.12 50.88	78.96 89.04	2,526.72 2,849.28	78.96 89.04	5,053.44 5,698.56	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				1408:88:48:2816:0 (22) (3)				1785	14		336	GDDR6		73.44 85.68	134.64 157.1	4,308.00 5,027.00	134.64 157.08	8,616.00 10,053.00	125		$229
GeForce GTX 1660 Ti^[142]	February 21, 2019	TU116-400-A1				1536:96:48:3072:0 (24) (3)			1500	1770	12		288	GDDR6		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

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.)

More information Model, Launch ...

Model	Launch	Code name	Process	Transistors (billion)	Die size (mm²)	Core config^{[lower-alpha 1]}	Bus interface	L2 Cache (MB)	Clock speeds			Memory				Fillrate^{[lower-alpha 2]}		Processing power (GFLOPS)^{[lower-alpha 2]}				Ray-tracing Performance		TDP (Watts)	NVLink support	Release price (USD)
Model	Launch	Code name	Process	Transistors (billion)	Die size (mm²)	Core config^{[lower-alpha 1]}	Bus interface	L2 Cache (MB)	Base core clock (MHz)	Boost core clock (MHz)	Memory (GT/s)	Size (GB)	Bandwidth (GB/s)	Bus type	Bus width (bit)	Pixel (GP/s)^{[lower-alpha 3]}	Texture (GT/s)^{[lower-alpha 4]}	Single precision	Double precision	Half precision	Tensor compute (FP16)	Rays/s (Billions)	RTX OPS/s (Trillions)	TDP (Watts)	NVLink support	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	1920:120:48:240:30 (30) (3)			1365	1680		6				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		$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		$299
GeForce RTX 2060 Super^[146]^[147]	July 9, 2019	TU106-410-A1				2176:136:64:272:34 (34) (3)		4	1470	1650		8	448.0		256	94.08 105.60	199.92 224.40	6 400.00 7 180.00	199.92 224.40	12 800.00 14 360.00	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	6	42	175		$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	$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	215		$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	8	63	250		$699	$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	250		$999	$1,199
Nvidia TITAN RTX^[155]	December 18, 2018	TU102-400-A1		18.6	754	4608:288:96:576:72 (72) (6)		6	1350	1770^{[lower-alpha 5]}	14	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

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)
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.
Boost of the Founders Editions, as there is no reference version of this card.

RTX 30 series

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

More information Model, Launch ...

Model	Launch	Code name	Process	Transistors (billion)	Die size (mm²)	Core config^{[lower-alpha 1]}	Bus interface	L2 Cache (MB)	Clock speeds			Memory				Fillrate		Processing power (TFLOPS)				Ray-tracing Performance (TFLOPS)	TDP (Watts)	NVLink support	Release price (USD)
Model	Launch	Code name	Process	Transistors (billion)	Die size (mm²)	Core config^{[lower-alpha 1]}	Bus interface	L2 Cache (MB)	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)	Ray-tracing Performance (TFLOPS)	TDP (Watts)	NVLink support	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		8.7	200	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	130		$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	GA106-302										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
GeForce RTX 3060 Ti^[162]	October 27, 2022^[160]	GA104-202				4864:152:80:152:38 (38) (5)			1410	1665	19000		608.0	GDDR6X		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
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
GeForce RTX 3080^[167]^[164]	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		12	912.0			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	24	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	2-way NVLink	$1999

Main shader processors : texture mapping unit : render output units : tensor cores : ray-tracing cores (streaming multiprocessors) (graphics processing clusters)

RTX 40 series

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]

More information Model, Launch ...

Model	Launch	Code name	Process	Transistors (billion)	Die size (mm²)	Core config^{[lower-alpha 1]}	Bus interface	L2 Cache (MB)	Clock speeds			Memory				Fillrate		Processing power (TFLOPS)				Ray-tracing Performance (TFLOPS)	TDP (Watts)	Release price (USD)
Model	Launch	Code name	Process	Transistors (billion)	Die size (mm²)	Core config^{[lower-alpha 1]}	Bus interface	L2 Cache (MB)	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)	Ray-tracing Performance (TFLOPS)	TDP (Watts)	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	8	288			121.9	345.4	20.1 22.1	0.314 0.345	20.1 22.1	88 (177)	51	160	$399
GeForce RTX 4060 Ti^[177]	July 18, 2023	AD106-351		22.9	187.8	4352:136:48:136:34 (34)(3)		32	2310	2540	18000	16	288			121.9	345.4	20.1 22.1	0.314 0.345	20.1 22.1	88 (177)	51	160	$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	$599
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		$799	—
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
GeForce RTX 4080^[184]	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		45.9	378.6	10240:320:112:320:80 (80)(7)		64	2295	2550	23000	16	736		256	285.6	816.0	47.0 52.22	0.734 0.816	47.0 52.22	188 (376) 209 (418)	121	320	$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		76.3	608.5	16384:512:176:512:128 (128)(11)		72	2235	2520	21000	24	1008		384	443.5	1290.2	73.1 82.6	1.142 1.291	73.1 82.6	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

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

GeForce2 Go series

All models are manufactured with a 180 nm manufacturing process
All models support Direct3D 7.0 and OpenGL 1.2
Celsius (microarchitecture)

More information Model, Launch ...

Model	Launch	Code name	Bus interface	Core clock (MHz)	Memory clock (MHz)	Core config^{[lower-alpha 1]}	Fillrate				Memory
Model	Launch	Code name	Bus interface	Core clock (MHz)	Memory clock (MHz)	Core config^{[lower-alpha 1]}	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			143	332		286	286	572		16, 32	2.656	DDR	64

Pixel shaders: vertex shaders: texture mapping units: render output units

GeForce4 Go series

All models are made via 150 nm fabrication process

More information Model, Launch ...

Model	Launch	Code name	Bus interface	Core clock (MHz)	Memory clock (MHz)	Core config^{[lower-alpha 1]}	Fillrate				Memory				API support
Model	Launch	Code name	Bus interface	Core clock (MHz)	Memory clock (MHz)	Core config^{[lower-alpha 1]}	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				200	400		400	400	800		32	3.2	DDR	64
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

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)

More information Model, Launch ...

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
								Pixel (GP/s)	Texture (GT/s)	Size (MB)	Bandwidth (GB/s)	Bus type	Bus width (bit)	Direct3D	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^*		NV34M	150		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^*		NV31M			350			1.4	1.4								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

All models support Direct3D 9.0c and OpenGL 2.1
Curie (microarchitecture)

More information Model, Launch ...

Model	Launch	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Memory clock (MHz)	Core config¹	Fillrate				Memory
Model	Launch	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Memory clock (MHz)	Core config¹	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	C51M		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 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	NV44M			400	700	4:3:4:2	1600	800	1600	250	16	5.6		64
GeForce Go 6600	September 29, 2005	NV43M			300	700	8:3:8:4	3000	1500	3000	281.25	128	11.2		128
GeForce Go 6800	November 8, 2004	NV41M	130		300	700 1100	12:5:12:12	3000	1500	3000	375	128	22.4 35.2	DDR, DDR2 DDR3	256
GeForce Go 6800 Ultra	February 24, 2005	NV41M	130		450	700 1100	12:5:12:12	5400	3600	5400	562.5	256	22.4 35.2	DDR, DDR2 DDR3	256

¹ Pixel shaders: vertex shaders: texture mapping units: render output units

GeForce Go 7 (Go 7xxx) series

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)

More information Model, Launch ...

Model	Launch	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Memory clock (MHz)	Core config¹	Fillrate		Memory				Supported API version		TDP (Watts)	Features
Model	Launch	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Memory clock (MHz)	Core config¹	Pixel (GP/s)	Texture (GT/s)	Size (MB)	Bandwidth (GB/s)	Bus type	Bus width (bit)	Direct3D	OpenGL	TDP (Watts)	Features
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	February 1, 2006	MCP67M		Hyper Transport	425	System memory	1:2:2:2	0.85	0.85	Up to 256 from system memory	System memory	DDR2	64/128			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	700	3:4:4:2	0.7	1.4	128, 256, 512	5.60		64			Unknown
GeForce Go 7400²					450	900	3:4:4:2	0.9	1.8	64, 256	7.20		64			Unknown
GeForce Go 7600	March 2006	G73M			450	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	G73M			500	1200	5:12:12:8	4	6	256	19.2					Unknown
GeForce Go 7700	2006	G73-N-B1	80		450	1000	5:12:12:8	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	G70M	110		400	1100	8:24:24:16	6.4	9.6		35.2					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	April 2006				500	1200	8:24:24:16	8	12	256 512	38.4					45
GeForce Go 7950 GTX	October 2006				575	1400	8:24:24:16	9.2	13.8	512	44.8					45

GeForce 8M (8xxxM) series

The GeForce 8M series for notebooks architecture Tesla.

¹ Unified shaders: texture mapping units: render output units

More information Model, Launch ...

Model	Launch	Code name	Fab (nm)	Bus interface	Core config¹	Clock speed			Fillrate		Memory				Supported API version		Processing power (GFLOPS)	TDP (Watts)	Notes
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
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	8:8:4			800			128 / 256	6.4	DDR2 / GDDR3	64			19.2	10	PureVideo HD with VP2, BSP Engine, and AES128 Engine
GeForce 8400M GS					16:8:4			800			128 / 256	6.4		64			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	20
GeForce 8700M GT	June 2007				32:16:8	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	November 2007	NB8P(G92)	65	PCIe 2.0 x16	96:48:16	500			8	24	512	51.2		256			360	65

GeForce 9M (9xxxM) series

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

¹ Unified shaders: texture mapping units: render output units

More information Model, Launch ...

Model	Launch	Code name	Fab (nm)	Bus interface	Core config¹	Clock speed			Fillrate		Memory				Supported API version		Processing power (GFLOPS)	TDP (Watts)	Notes
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
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)	65	PCIe 2.0 x16	8:8:4	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	256/512	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	512	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)	65			500	1250	1600	4	8	512/1024	25.6					120	23
GeForce 9650M GS		NB9P-GS1(G84)	80			625	1250		5	10	512		GDDR3				120	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	July 29, 2008	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	530	1325		8.48	16.96							254	60	Down Clocked 9800M GTS Via Firmware
GeForce 9800M GTS	July 29, 2008	NB9E-GT(G94)	65/55		64:32:16	600	1500		9.6	19.2	512 / 1024						288	75
GeForce 9800M GT		NB9E-GT2(G92)	65/55		96:48:16	500	1250		8	24	512						360	65	Rebranded 8800M GTX
GeForce 9800M GTX		NB9E-GTX(G92)	65		112:56:16	500	1250		8	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
Model	Launch	Code name	Fab (nm)	Bus interface	Core config¹	Clock speed			Fillrate		Memory				Supported API version		Processing power (GFLOPS)	TDP (Watts)	Notes

GeForce 100M (1xxM) series

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

More information Model, Launch ...

Model	Launch	Code name	Fab (nm)	Bus interface	Core config¹	Clock speed			Fillrate		Memory				Supported API version		Processing power (GFLOPS)	TDP (Watts)	Notes
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
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	DDR2				38		PureVideo HD, CUDA, Hybrid SLI, comparable to the GeForce 9300M GS
GeForce G 105M	January 8, 2009	N10M-GE1(G98)			8:8:4	640	1600	1000 1400	2.56	5.12		8 11	GDDR2 GDDR3				38
GeForce G 110M	January 8, 2009	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)			32:16:8	600	1500	1000 1600	4.8	9.6		16 25.6	DDR2 GDDR3	128			144	23	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	March 3, 2009	N10E-GS1(G94b)			64:32:16	600	1500	1600	9.6	19.2		51.2	GDDR3	256			288	60	PureVideo HD, CUDA, Hybrid SLI

GeForce 200M (2xxM) series

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

¹ Unified shaders: texture mapping units: render output units

More information Model, Launch ...

Model	Launch	Code name	Fab (nm)	Bus interface	Core config¹	Clock speed			Fillrate		Memory				Supported API version		Processing power (GFLOPS)	TDP (Watts)	Notes
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
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	14	rebranded 9600M GT @55 nm node shrink
GeForce GT 230M	June 15, 2009	GT216	40		48:16:8	500	1100	1600	4	8		25.6	GDDR3				158	23
GeForce GT 240M		GT216			48:16:8	550	1210	1600	4.4	8.8		25.6	GDDR3				174	23
GeForce GTS 250M		GT215			96:32:8	500	1250	3200	4	16		51.2	GDDR5				360	28
GeForce GTS 260M		GT215			96:32:8	550	1375	3600	4.4	17.6		57.6	GDDR5				396	38
GeForce GTX 260M	March 3, 2009	G92b	55		112:56:16	550	1375	1900	8.8	30.8		60.8	GDDR3	256			462	65
GeForce GTX 280M	March 3, 2009				128:64:16	585	1463	1900	9.36	37.44		60.8					562	75
GeForce GTX 285M	February 2010				128:64:16	600	1500	2000	9.6	38.4		64.0					576	75	Higher Clocked Version of GTX280M with new memory

GeForce 300M (3xxM) series

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.

More information Model, Launch ...

Model	Launch	Code name	Fab (nm)	Bus interface	Core config¹	Clock speed			Fillrate		Memory				Supported API version		Processing power (GFLOPS)²	TDP (Watts)
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)²	TDP (Watts)
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	January 10, 2010					625	1530	1600	2.5	5		12.8					73
GeForce 315M	January 5, 2011					606	1212	1600	2.42	4.85		12.8					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	January 10, 2010				48:16:8	575	1265		4.6	9.2							182	23
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					96:32:8	500	1436	3600	4.4	17.6		57.6	DDR3 GDDR3 GDDR5				413	38

GeForce 400M (4xxM) series

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.

More information Model, Launch ...

Model	Launch	Code name	Fab (nm)	Bus interface	Core config¹	Clock speed			Fillrate		Memory				Supported API version		Processing power (GFLOPS)²	TDP (Watts)	Notes
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)²	TDP (Watts)	Notes
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			48:8³:4	500	1000		2	4		25.6		128			96	<12(GPU only)^[196]	Similar to Desktop GT420 OEM
GeForce GT 420M					96:16³:4	500	1000		2	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]	Similar to Desktop GT430
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		GF106			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	2500	13.2	26.4	1536	60		192			633.6	45–50(GPU only)^[196]	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	2048	96.0		256			883.2	100(MXM module)	Similar to Desktop GTX560 Ti

GeForce 500M (5xxM) series

The GeForce 500M series for notebooks architecture.

¹ Unified shaders: texture mapping units: render output units
² On Some Dell XPS17

More information Model, Launch ...

Model	Launch	Code name	Fab (nm)	Bus interface	Core config¹	Clock speed			Fillrate		Memory				Supported API version		Processing power (GFLOPS)²	TDP (Watts)	Notes
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)²	TDP (Watts)	Notes
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	1600	2.06	8.24		12.8					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	20	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		GF108			96:16:4	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	32–35	Similar to Desktop GT 530/440
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	75	Similar to Desktop GTX 560
GeForce GTX 580M	June 28, 2011	GF114			384:64:32	620	1240	3000	19.8	39.7	2048	96.0		256			952.3	100	Similar to Desktop GTX 560 Ti

GeForce 600M (6xxM) series

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

More information Model, Launch ...

Model	Launch	Code name	Fab (nm)	Bus interface	Core config¹	Clock speed			Fillrate		Memory				Supported API version			Processing power (GFLOPS)²	TDP (Watts)	Notes
Model	Launch	Code name	Fab (nm)	Bus interface	Core config¹	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	Processing power (GFLOPS)²	TDP (Watts)	Notes
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	GF117 (N13M-GS)	28			625	1250	1800	2.5	10		14.4		64				240	15	OEM. Die-Shrink GF108
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]	April 2012	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]	March 22, 2012	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	GK107 (N13P-GS)				710	710	1800 4000	11.36	22.72		28.8 64.0						545	32	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]	March 22, 2012	GK107 (N13E-GE)				835	950	5000	15.2	30.4	2048	80.0	GDDR5			11.2		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	1536 3072	67.2		192	1.2			1181	75	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	3600	23	80.6		115.2						1933		78% of desktop GTX 670^{[original research?]}
GeForce GTX 680MX	October 23, 2012	GK104			1536:128:32 (8 SMX)	719	719	5000	23	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
Model	Launch	Code name	Fab (nm)	Bus interface	Core config¹	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	Processing power (GFLOPS)²	TDP (Watts)	Notes

GeForce 700M (7xxM) series

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

More information Model, Launch ...

Model	Launch	Code name	Fab (nm)	Bus interface	Core config¹	Clock speed			Fillrate		Memory				Supported API version				Processing power (GFLOPS)²	TDP (Watts)	Notes
Model	Launch	Code name	Fab (nm)	Bus interface	Core config¹	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	Processing power (GFLOPS)²	TDP (Watts)	Notes
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	?	1800	5.752	11.5	1024	14.4			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		16.0		64					682.8	?	Kepler, similar to Desktop GT640
GeForce GT 740M						980		1800	7.84	31.4		14.4		64					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	45	about 79% of Desktop GTX650^{[original research?]}
GeForce GT 750M						967		2000 5000	15.5	30.9		32 80	DDR3 GDDR5						742.7	50	about 91% of Desktop GTX650^{[original research?]}
GeForce GT 755M^[212]	?					1020		5400	15.7	31.4		86.4	GDDR5						783	50	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					768:64:16 (4 SMX)	863			13.6	54.4		64							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)	797		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
Model	Launch	Code name	Fab (nm)	Bus interface	Core config¹	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	Processing power (GFLOPS)²	TDP (Watts)	Notes

GeForce 800M (8xxM) series

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

More information Model, Launch ...

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)
Model	Launch	Code name	Fab (nm)	Bus interface	Core config¹	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	Processing power (GFLOPS)²	TDP (Watts)	Notes (original research)
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]	February 2014	GF117		PCIe 2.0 x16	96:16:4	719–954	1438–1908	2000	2.9–3.8	11.5–15.3	2	16			n/a			2.1 ^[209]	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		1800	8.2	16.5		14.4			1.3			5.0^[209]	526.8	~25	50% of 750 (Maxwell)
GeForce 840M^[217]	March 12, 2014				384:24:8 (3 SMM)	1029		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
GeForce 845M^[218]^[219]	August 16, 2015^[221]	GM107			512:32:16 (4 SMM)	863		2000	13.8	27.6	2	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
GeForce GTX 850M^[222]					640:40:16 (5 SMM)	936+Boost		2000	15.0	37.4	2-4	32	DDR3						1198.1	40	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
GeForce GTX 860M^[223]		GK104			1152:96:16 (6 SMX)	797–915			12.8	76.5	4	80			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)
Model	Launch	Code name	Fab (nm)	Bus interface	Core config¹	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	Processing power (GFLOPS)²	TDP (Watts)	Notes (original research)

GeForce 900M (9xxM) series

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

More information Model, Launch ...

Model	Launch	Code name	Fab (nm)	Bus interface	Core config¹	Clock speed			Fillrate		Memory				Supported API version				Processing power (GFLOPS)²	TDP (Watts)	Notes
Model	Launch	Code name	Fab (nm)	Bus interface	Core config¹	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	Processing power (GFLOPS)²	TDP (Watts)	Notes
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	1800	7.4	22.3		14.4			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	2000	9.9	29.8		16							954	23
GeForce 940MX	June 28, 2016^[229]	GM107			512:32:8 (4 SMM)	795	861	5000	6.9	27.6		40	GDDR5						882	23
GeForce GTX 950M	March 12, 2015				640:40:16 (5 SMM)	914	Unknown	5000	14.6	36.6	2, 4	80	GDDR5	128					1170	Unknown	Similar core config to GTX 750 Ti (GM107-400-A2)
GeForce GTX 950M						914	Unknown	2000	14.6	36.6		32	DDR3						1170	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		80				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)	944	993		44.4	73.9	3, 6	120		192					2365	75	Similar core config to GTX 960 OEM (GM204)
GeForce GTX 980M^[235]	October 7, 2014				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		256					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
Model	Launch	Code name	Fab (nm)	Bus interface	Core config¹	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	Processing power (GFLOPS)²	TDP (Watts)	Notes

GeForce 10 series

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]

More information Model, Launch ...

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
Model	Launch	Code name	Fab (nm)	Transistors (billion)	Die size (mm²)	Bus interface	Core config	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	TDP (Watts)	SLI support
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]	January 3, 2017	GP107(N17P-G1-A1)	14 nm	3.3	135		768:48:32	1493	1620	7000	47.8	71.7	4	112		128					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	GP106						1063	1480		71.04	118.4									3789	118.4	59.20
GeForce GTX 1060 Max-Q	May 2017	GP106B						1265	1480		71.04	118.4									3789	118.4	59.20
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						2048:128:64	1101	1379		88.26	176.5		256							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						2560:160:64	1101	1468	10000	93.95	234.9		320	GDDR5X						7516	234.9	117.4	?	No

GeForce 16 series

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.

More information Model, Launch ...


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)
Model	Launch	Code name	Process	Transistors (billion)	Die size (mm²)	Bus interface	L2 Cache(MB)	Core config	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)	Single precision	Double precision	Half precision	TDP (Watts)
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	TU117						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	April 23, 2019	TU117(N18P-G0-MP-A1)							1020	1245	8000	39.84	79.68	4	112	GDDR5		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	April 2, 2020	TU117(N18P-G62-A1)							1350	1485	12000	47.52	95.04	4	192			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]	April 23, 2019							1536:96:46	1455	1590	12000	76.32	152.6		288			4884	152.6^[245]	9769	80

GeForce 20 series

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

More information Model, Launch ...

Model	Launch	Code name	Process	Transistors (billion)	Die size (mm²)	Core config^{[lower-alpha 1]}	Bus interface	L2 Cache(MB)	Clock speeds			Memory				Fillrate^{[lower-alpha 2]}		Processing power (GFLOPS)^{[lower-alpha 2]}				Ray-tracing Performance		TDP (Watts)
Model	Launch	Code name	Process	Transistors (billion)	Die size (mm²)	Core config^{[lower-alpha 1]}	Bus interface	L2 Cache(MB)	Base core clock (MHz)	Boost core clock (MHz)	Memory (MT/s)	Size (GB)	Bandwidth (GB/s)	Bus type	Bus width (bit)	Pixel (GP/s)^{[lower-alpha 3]}	Texture (GT/s)^{[lower-alpha 4]}	Single precision	Double precision	Half precision	Tensor compute (FP16)	Rays/s (Billions)	RTX OPS/s (Trillions)	TDP (Watts)
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	14000	6	336.0		192	57.6	144	4608	144.0	9216				80
GeForce RTX 2060 Max-Q^[250]						1920:120:48:240:30 (30) (3)		3	975	1175	11000	6	264.0		192	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]						2304:144:64:288:36 (36) (3)			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]	April 2, 2020					2560:160:64:320:40 (40) (5)			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]	January 29, 2019					2944:184:64:368:46 (46) (6)			735	1095	12000		384.0			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]	April 2, 2020					3072:192:64:384:48 (48) (6)			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)
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

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)

More information Model, Launch ...

Model	Launch	Code name	Process	Transistors (billion)	Die size (mm²)	Core config^{[lower-alpha 1]}	Bus interface	L2 Cache(MB)	Clock speeds ^{[lower-alpha 2]}			Memory				Fillrate^{[lower-alpha 3]}		Processing power (TFLOPS)^{[lower-alpha 3]}				Ray-tracing Performance		TDP (Watts)
Model	Launch	Code name	Process	Transistors (billion)	Die size (mm²)	Core config^{[lower-alpha 1]}	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)^{[lower-alpha 4]}	Texture (GT/s)^{[lower-alpha 5]}	Single precision	Double precision	Half precision	Tensor compute (FP16)	Rays/s (Billions)	RTX OPS/s (Trillions)	TDP (Watts)
GeForce RTX 3050^[259]^[260]	May 11, 2021	GA107	Samsung 8N	8.7	200	2048:64:32:64:16 (16) (3)	PCIe 4.0 x8	2	712-1530	1057-1740	11000 12000	4	176 192	GDDR6	128	22.8-49.0 33.8-55.7	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 RTX 3050 Ti^[261]^[262]	May 11, 2021	GA107		8.7	200	2560:80:48:80:20 (20) (3)	PCIe 4.0 x8	2	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				35-80
GeForce RTX 3060^[263]^[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 RTX 3070^[265]^[266]^[267]	January 12, 2021	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^[268]	January 4, 2022	GA104				5888:184:96:184:46 (46) (6)			510-1035	1035-1485		8				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			80-125
GeForce RTX 3080^[269]^[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^[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			80-150

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
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 40 series

Further information: GeForce 40 series

Supported APIs: Direct3D 12 Ultimate (12_2), OpenGL 4.6, OpenCL 3.0, Vulkan 1.3^[63] and CUDA 8.9
Tensor core 4th gen
RT core 3rd gen
DLSS 3 (Super Resolution + Frame Generation) ^[272]
SER ^[273]

More information Model, Launch ...

Model	Launch	Code name	Process	Transistors (billion)	Die size (mm²)	Core config^{[lower-alpha 1]}	Bus interface	L2 Cache (MB)	Clock speeds ^{[lower-alpha 2]}			Memory				Fillrate^{[lower-alpha 3]}		Processing power (TFLOPS)^{[lower-alpha 3]}				Ray-tracing Performance		TDP (Watts)
Model	Launch	Code name	Process	Transistors (billion)	Die size (mm²)	Core config^{[lower-alpha 1]}	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)^{[lower-alpha 4]}	Texture (GT/s)^{[lower-alpha 5]}	Single precision	Double precision	Half precision	Tensor compute (FP16)	Rays/s (Billions)	RTX OPS/s (Trillions)	TDP (Watts)
GeForce RTX 4050^[274]	February 22, 2023	AD107	TSMC 4N	18.9	146	2560:80:32:80:20 (20) (2)	PCIe 4.0 x8	12		1605-2370	14000 (Max-Q) 16000	6	168 192	GDDR6 ^[275]	96									35-115
GeForce RTX 4060^[274]		AD107		18.9	146	3072:96:32:96:24 (24) (2)		32	1140-2295	1470-2370		8	224 256		128	36-73 47-75
GeForce RTX 4070^[274]		AD106		22.9	190	4608:144:48:144:36 (36) (3)		32	735-2070	1230-2175		8	224 256		128	35-99 59-104	105-298 177-313	6.77-19.0 11.3-20.0	0.10-0.29 0.17-0.31	6.77-19.0 11.3-20.0	54.1-152.6 90.6-160.3
GeForce RTX 4080^[274]	February 8, 2023	AD104		35.8	295	7424:232:80:232:58 (58) (5)	PCIe 4.0 x16	48	795-1860	1350-2280	14000 (Max-Q) 18000	12	336 432		192	63-148 108-182	184-431 313-528	11.8-27.6 20.0-33.8	0.18-0.43 0.31-0.52	11.8-27.6 20.0-33.8	94.4-220.9 160.3-270.8			60-150
GeForce RTX 4090^[274]	February 8, 2023	AD103		45.9	379	9728:304:112:304:76 (76) (7)	PCIe 4.0 x16	64	930-1620	1455-2550	14000 (Max-Q) 18000	16	448 576		256	104-181 162-285	282-492 442-775	18.0-31.5 28.3-49.6	0.28-0.49 0.44-0.77	18.0-31.5 28.3-49.6	144.7-252.1 226.4-396.9			80-150

Main Shader Processors : Texture Mapping Units : Render Output Units : Tensor Cores : 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
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 MX series

More information Model (Architecture), Launch ...

Model (Architecture)	Launch	Code name(s)	Process	Transistors (billion)	Die size (mm²)	Core config^{[lower-alpha 1]}	Bus interface	L2 Cache (MB)	Clock speeds			Memory				Fillrate^{[lower-alpha 2]}		Processing power (GFLOPS)^{[lower-alpha 2]}				Ray tracing Performance		TDP (Watts)
Model (Architecture)	Launch	Code name(s)	Process	Transistors (billion)	Die size (mm²)	Core config^{[lower-alpha 1]}	Bus interface	L2 Cache (MB)	Base core clock (MHz)	Boost core clock (MHz)	Memory (MT/s)	Size (GB)	Bandwidth (GB/s)	Type	Bus width (bit)	Pixel (GP/s)^{[lower-alpha 3]}	Texture (GT/s)^{[lower-alpha 4]}	Single precision	Double precision	Half precision	Tensor compute (FP16)	Rays/s (Billions)	RTX OPS (Trillions)	TDP (Watts)
GeForce MX110 (Maxwell)^[276]^[277]	Nov 17, 2017	GM108 (N16V-GMR1-A1)	TSMC 28 nm	?	?	256:16:8:3	PCIe 3.0 ×4	1	965	993	1800 (DDR3) 5000 (GDDR5)	2	14.4 (DDR3) 40.1 (GDDR5)	DDR3 GDDR5	64	(7.944)	(15.89)	(508.4)	(15.89)	—	—	—	—	30
GeForce MX130 (Maxwell)^[276]^[278]^[279]	Nov 17, 2017	GM108 (N16S-GTR-A1)	TSMC 28 nm	?	?	384:24:8:3		1	1122	1242	1800 (DDR3) 5000 (GDDR5)	2	14.4 (DDR3) 40.1 (GDDR5)	DDR3 GDDR5		(9.936)	(29.81)	861.7 (953.9)	26.93 (29.81)	—				30
GeForce MX150 (Pascal)^[280]^[281]^[282]	May 17, 2017	GP108 (N17S-LG-A1)	Samsung 14 nm	1.8	74	384:24:16:3		0.5	937	1038	5000	2 4	40	GDDR5		(14.99)	(22.49)	719.6 (797.2)	22.49 (24.91)	11.24 (12.45)				10
GeForce MX150 (Pascal)^[280]^[281]^[282]	May 17, 2017	GP108-650-A1 (N17S-G1-A1)				384:24:16:3		0.5	1468	1532	6000	2 4	48			(23.49)	(35.23)	1127 (1177)	35.23 (36.77)	17.62 (18.38)				25
GeForce MX230 (Pascal)^[283]	Feb 20, 2019	GP108 (N17S-G0-A1)				256:16:16:2		0.5	1519	1531	7000	2 4	56			(25.31)	(25.31)	(810.0)	(25.31)	(12.66)				10
GeForce MX250 (Pascal)^[284]^[285]		GP108 (N17S-LG-A1)				384:24:16:3			937	1038			48			(16.61)	(24.91)	(797.2)	(24.91)	(12.46)				10
GeForce MX250 (Pascal)^[284]^[285]		GP108 (N17S-G2-A1)							1518	1582			56			(24.3)	(36.4)	(1166)	(37.97)	(18.98)				25
GeForce MX330 (Pascal)^[286]	Feb 12, 2020	GP108-655-A1 (N17S-LP-A1) (N17S-G3-A1)							746(LP) 1531	936(LP) 1594						(25.50)	(38.26)	(1224)	(38.26)	(19.13)				10-30
GeForce MX350 (Pascal)^[287]	Feb 12, 2020	GP107-670-A1 (N17S-LP-A1) (N17S-G5-A1)		3.3	132	640:32:16:5			747(LP) 1354	937(LP) 1468						(23.49)	(46.98)	(1879)	(58.72)	(29.36)				15-25
GeForce MX450 (Turing)^[288]^[289]	Aug 1, 2020	TU117 (N18S-LP-A1) (N18S-G5-A1)	TSMC 12FFN	4.7	200	896:56:32:14	PCIe 4.0 ×4	1	720(LP) 1395	930(LP) 1575	7000	2				23.04 (50.40)	40.32 (88.20)	1290 (2822)	40.32 (88.20)	2581 (5645)				10-30
GeForce MX450 (Turing)^[288]^[289]	Aug 1, 2020	TU117 (N18S-LP-A1) (N18S-G5-A1)				896:56:32:14		1	720(LP) 1395	930(LP) 1575	10000	2	80	GDDR6		23.04 (50.40)	40.32 (88.20)	1290 (2822)	40.32 (88.20)	2581 (5645)				10-30
GeForce MX550 (Turing)^[290]^[291]^[292]^[293]	Mar 2022	TU117-670-A1 (GN18-S5-A1)				1024:32:16:8		2	1065	1320	12000	2 4	96			(21.12)	(42.24)	(2703)	(42.24)	(2703)				15-30
GeForce MX570 (Ampere)^[290]^[294]^[292]^[295]	Mar 2022	GA107 (GN20-S5-A1)	Samsung 8N	8.7	200	2048 64:40:16:16:64		2	1087	1155	12000	2 4	96			(46.20)	(73.92)	(4731)	(73.92)	(4731)				15-45

Shader Processors : Texture mapping units : Render output units : Streaming Multiprocessors : Ray tracing cores : Tensor Cores
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.

Workstation GPUs

Quadro

Further information: Quadro

¹ Vertex shaders: pixel shaders: texture mapping units: render output units

More information Model, Code name ...

Model	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Memory clock (MHz)	Core config¹	Fillrate		Memory				Supported API version		TDP (Watts)	Notes
Model	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Memory clock (MHz)	Core config¹	Pixel (GP/s)	Texture (GT/s)	Size (MB)	Bandwidth (GB/s)	Bus type	Bus width (bit)	Direct3D	OpenGL	TDP (Watts)	Notes
Quadro	NV10GL	220	AGP 4x	135	166	0:4:4:4	0.54	0.54	64	2.66	SDR	128	7	1.2
Quadro DDR	NV10GL	220		135	333	0:4:4:4	0.54	0.54		5.312	DDR
Quadro2 MXR	NV11GL	180		200	183	0:2:4:2	0.4	0.4		2.93	SDR
Quadro2 EX	NV11GL	180		175	166	0:2:4:2	0.35	0.35		2.7	SDR
Quadro2 PRO	NV15GL	150		250	400	0:4:8:4	1	2		6.4	DDR
Quadro DCC	NV20GL	180		200	460	1:4:8:4	0.8	1.6	128	7.4			8	1.4
Quadro4 380XGL	NV18GL	150	AGP 8x	275	513	0:2:4:2	0.55	1.1		8.2			7
Quadro4 500XGL	NV17GL		AGP 4x	250	166		0.5	1		2.7	SDR
Quadro4 550XGL	NV17GL		AGP 4x	270	400		0.59	1.08	64	6.4	DDR
Quadro4 580XGL	NV18GL		AGP 8x	300	400		0.6	1.2		6.4
Quadro4 700XGL	NV25		AGP 4x	275	550	2:4:8:4	1.1	2.2		8.8			8
Quadro4 750XGL				275	550		1.1	2.2	128	8.8				1.5		Stereo display
Quadro4 900XGL				300	650		1.2	2.4		10.4				1.4
Quadro4 980XGL	NV28GL		AGP 8x	300	650		1.2	2.4		10.4				1.4
Model	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Memory clock (MHz)	Core config¹	Pixel (GP/s)	Texture (GT/s)	Size (MB)	Bandwidth (GB/s)	Bus type	Bus width (bit)	Direct3D	OpenGL	TDP (Watts)	Features
Model	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Memory clock (MHz)	Core config¹	Fillrate		Memory				Supported API version		TDP (Watts)	Features

Quadro FX series

Further information: Quadro

¹ Vertex shaders: pixel shaders: texture mapping units: render output units

More information Model, Code name ...

Model	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Memory clock (MHz)	Core config^1*	Fillrate		Memory				Supported API version		TDP (Watts)	Notes
Model	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Memory clock (MHz)	Core config^1*	Pixel (GP/s)	Texture (GT/s)	Size (MB)	Bandwidth (GB/s)	Bus type	Bus width (bit)	Direct3D	OpenGL	TDP (Watts)	Notes
Quadro FX 500	NV34GL	150	AGP 8x	270	480	2:4:4:4	1.08	1.08	128	7.687	DDR	128	9.0	2.0		Stereo display
Quadro FX 600	NV34GL		PCI	350	800	2:4:4:4	1	1	256	7.8
Quadro FX 700	NV35GL		AGP 8x	275	550	3:4:8:4	1.1	2.2	128	8.8
Quadro FX 1000	NV30GL	130		300	600	2:4:8:4	1.2	2.4		9.6	GDDR2
Quadro FX 1100	NV36GL			425	648	3:4:4:4	1.7	1.7		10.1	DDR
Quadro FX 2000	NV30GL			400	800	2:4:8:4	1.6	3.2		12.8	GDDR2
Quadro FX 3000	NV35GL				850	3:4:8:4			256	27.2	DDR	256
Quadro FX 3000G	NV35GL				850	3:4:8:4				27.2	DDR					Stereo display, Genlock
Quadro FX 4000	NV40GL			375	1000	6:12:12:12	4.5	4.5		32.0	GDDR3		9.0c	2.1	142	Stereo display
Quadro FX 4000 SDI	NV40GL			375	1000	6:12:12:12	4.5	4.5		32.0	GDDR3		9.0c	2.1		Stereo display, Genlock

Quadro FX (x300) series

Further information: Quadro

¹ Vertex shaders: pixel shaders: texture mapping units: render output units

More information Model, Code name ...

Model	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Memory clock (MHz)	Core config¹	Fillrate		Memory				Supported API version		TDP (Watts)
Model	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Memory clock (MHz)	Core config¹	Pixel (GP/s)	Texture (GT/s)	Size (MB)	Bandwidth (GB/s)	Bus type	Bus width (bit)	Direct3D	OpenGL	TDP (Watts)
Quadro FX 330	NV37GL	150	PCIe x16	250	400	2:4:4:4	1	1	64	3.2	DDR	128	9.0	2.0	21
Quadro FX 1300	NV38	130	PCIe x16	350	550	3:4:8:4	1.4	2.8	128	17.6	DDR	256	9.0	2.1	55

Quadro FX (x400) series

Further information: Quadro

¹ Vertex shaders: pixel shaders: texture mapping units: render output units

More information Model, Code name ...

Model	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Memory clock (MHz)	Core config¹	Fillrate		Memory				Supported API version		TDP (Watts)	Notes
Model	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Memory clock (MHz)	Core config¹	Pixel (GP/s)	Texture (GT/s)	Size (MB)	Bandwidth (GB/s)	Bus type	Bus width (bit)	Direct3D	OpenGL	TDP (Watts)	Notes
Quadro FX 540	NV43GL	90	PCIe x16	300	550	4:8:8:8	2.4	2.4	128	8.8	GDDR3	128	9.0c	2.1	35
Quadro FX 1400	NV41	130		350	600	5:8:8:8	2.8	2.8	128	19.2	DDR	256			75	Stereo display, SLI
Quadro FX 3400	NV45GL/ NV40	130		350	900	5:12:12:12	4.2	4.2	256	28.8	GDDR3				101
Quadro FX 3450	NV41	110		425	1000	5:12:12:12	5.1	5.1	256	32.0					83
Quadro FX 4400	NV45GL A3/ NV40	130		400	1050	6:16:16:16	6.4	6.4	512	33.7					110

Quadro FX (x500) series

Further information: Quadro

¹ Vertex shaders: pixel shaders: texture mapping units: render output units

More information Model, Code name ...

Model	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Memory clock (MHz)	Core config¹	Fillrate		Memory				Supported API version		TDP (Watts)	Notes
Model	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Memory clock (MHz)	Core config¹	Pixel (GP/s)	Texture (GT/s)	Size (MB)	Bandwidth (GB/s)	Bus type	Bus width (bit)	Direct3D	OpenGL	TDP (Watts)	Notes
Quadro FX 350	G72	90	PCIe x16	550	400	3:4:4:2	1.1	2.2	128	6.4	DDR2	64	9.0c	2.1	21
Quadro FX 550	NV43	110		360	400	4:8:8:8	2.88	2.88	128	12.8	GDDR3	128			30
Quadro FX 1500	G71	90		325	625	6:16:16:16	5.2	5.2	256	40.0		256			65
Quadro FX 3500	G71	90		450	660	7:20:20:16	7.2	9	256	42.2					80	Stereo display, SLI
Quadro FX 4500	G70	110		430	525	8:24:24:16	6.88	10.3	512	33.6					109	Stereo display, SLI
Quadro FX 4500 SDI	G70	110		430	525	8:24:24:16	6.88	10.3	512	33.6					116	Stereo display, Genlock
Quadro FX 4500X2	G71	90		500	605	2x 8:24:24:16	2x 8	2x 12	2x 512	2x 38.7		2x 256			145	Stereo display, SLI, Genlock
Quadro FX 4500 rev. A2				650	800	8:24:24:16	10.4	15.6	512	51.2		256			105
Quadro FX 5500					505				1024	32.3	DDR2				96
Quadro FX 5500 SDI					505				1024	32.3	DDR2				104

Quadro FX (x600) series

Further information: Quadro

¹ Vertex shaders: pixel shaders: texture mapping units: render output units
² Unified shaders: texture mapping units: render output units

More information Model, Launch ...

Model	Launch	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Shader clock (MHz)	Memory clock (MHz)	Core config¹²	Fillrate		Memory				Processing power (GFLOPS)^[296]^[297]		Supported API version		TDP (Watts)	Notes
Model	Launch	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Shader clock (MHz)	Memory clock (MHz)	Core config¹²	Pixel (GP/s)	Texture (GT/s)	Size (MB)	Bandwidth (GB/s)	Bus type	Bus width (bit)	Single precision	Double precision	Direct3D	OpenGL	TDP (Watts)	Notes
Quadro FX 560	Apr 20, 2006	G73GL	90	PCIe x16	350	350	1200	5:12:12:8	2.8	4.2	128	19.2	GDDR3	128			9.0c	2.1	30
Quadro FX 4600²	Mar 5, 2007	G80-850-A2 + NVIO-1-A3			500	1200	1400	96:24:24	12	24	768	67.2		384	345	-	10.0	3.3	134	Stereo display, SLI, Genlock
Quadro FX 4600 SDI²	Mar 5, 2007	G80-850-A2 + NVIO-1-A3			500	1200	1400	96:24:24	12	24	768	67.2			345				154
Quadro FX 5600²	Mar 5, 2007	G80-875-A2 + NVIO-1-A3		PCIe 2.0 x16	600	1350	1600	128:32:24	14.4	38.4	1536	76.8			518.4				171

Quadro FX (x700) series

Further information: Quadro

¹Unified shaders: texture mapping units: render output units

More information Model, Launch ...

Model	Launch	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Shader clock (MHz)	Memory clock (MHz)	Core config¹	Fillrate		Memory				Processing power (GFLOPS)^[296]^[297]		Supported API version		TDP (Watts)	Notes
Model	Launch	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Shader clock (MHz)	Memory clock (MHz)	Core config¹	Pixel (GP/s)	Texture (GT/s)	Size (MB)	Bandwidth (GB/s)	Bus type	Bus width (bit)	Single precision	Double precision	Direct3D	OpenGL	TDP (Watts)	Notes
Quadro FX 370	Sep 12, 2007	G84-825-A2	80	PCIe x16	360	720	800	16:8:4	1.44	2.88	256	6.4	DDR2	64	34.56	-	10.0	3.3	35
Quadro FX 370 LP	Nov 6, 2008	G98	80	PCIe x16	540	1300	1000	8:8:4	2.16	4.32	256	8		64	25.92				25	DMS-59 for two Single Link DVI
Quadro FX 470	Sep 12, 2007	MCP7A-U	65	PCIe 2.0 x16 (Integrated)	580	1400	800 (system memory)	16:8:4	2.32	4.64	Up to 256MB from system memory.	12.8		128	67.2				30	based on GeForce 9400 mGPU
Quadro FX 570	Sep 12, 2007	G84-850-A2	80	PCIe x16	460	920	800	16:8:8	3.68	3.68	256				44.1				38
Quadro FX 1700	Sep 12, 2007	G84-875-A2	80	PCIe x16	460	920	800	32:16:8	3.68	7.36	512				88.32				42
Quadro FX 3700	Jan 8, 2008	G92-875-A2	65	PCIe 2.0 x16	500	1250	1600	112:56:16	8	28	512	51.2	GDDR3	256	420				78	Stereo display, SLI
Quadro FX 4700X2	Apr 18, 2008	2x G92-880-A2			600	1500		2x 128:64:16	2x 9.6	2x 38.4	2x 1024	2x 51.2		2x 256	2x 576				226	SLI
Quadro VX 200	Jan 8, 2008	G92-851-A2			450	1125		96:48:16	7.2	21.6	512	51.2		256	324				75	2x Dual-link DVI, S-Video, optimised for Autodesk AutoCAD

Quadro FX (x800) series

Further information: Quadro

¹Unified shaders: texture mapping units: render output units

More information Model, Launch ...

Model	Launch	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Shader clock (MHz)	Memory clock (MHz)	Core config¹	Fillrate		Memory				Processing power (GFLOPS)^[296]^[297]		Supported API version		TDP (Watts)	Notes
Model	Launch	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Shader clock (MHz)	Memory clock (MHz)	Core config¹	Pixel (GP/s)	Texture (GT/s)	Size (MB)	Bandwidth (GB/s)	Bus type	Bus width (bit)	Single precision	Double precision	Direct3D	OpenGL	TDP (Watts)	Notes
Quadro FX 380	Mar 30, 2009	G96-850-C1	65	PCIe 2.0 x16	450	1100	1400	16:8:8	3.6	3.6	256	22.4	GDDR3	128	52.8	-	10.0	3.3	34	Two Dual Link DVI, no DisplayPort
Quadro FX 380 LP	Dec 1, 2009	GT218GL	40		589	1402	1600	16:8:4	2.356	4.712	512	12.8		64	67.296				28	DisplayPort, Dual Link DVI
Quadro FX 580	Apr 9, 2009	G96-875-C1	65		450	1125		32:16:8	3.6	7.2	512	25.6		128	108				40	Dual DisplayPort, Dual Link DVI
Quadro FX 1800	Mar 30, 2009	G94-876-B1	65		550	1375		64:32:12	6.6	17.6	768	38.4		192	264				59	Stereo DP Dual Link DVI, Dual DisplayPort, SLI
Quadro FX 3800	Mar 30, 2009	G200-835-B3 + NVIO2-A2	55		600	1204		192:64:16	9.632	38.528	1024	51.2		256	691.2	86.4			108
Quadro FX 4800	Nov 11, 2008	G200-850-B3 + NVIO2-A2			602	1204		192:64:24	14.448	38.528	1536	76.8		384	693.504	86.688			150
Quadro FX 5800	Nov 11, 2008	G200-875-B2 + NVIO2-A2			610	1296		240:80:32	20.736	51.840	4096	102.4		512	878.4	109.8			189
Quadro CX^[298]	Nov 11, 2008	GT200GL + NVIO2			602	1204		192:64:24	14.448	38.528	1536	76.8		384	693.504	86.688			150	Display Port and dual-link DVI Output, optimised for Adobe Creative Suite 4

Quadro x000 series

Further information: Quadro

¹ Unified shaders: texture mapping units: render output units
⁴ Each SM in the Fermi architecture contains 4 texture filtering units for every texture address unit. Total for the full GF100 64 texture address units and 256 texture filtering units^[60]

More information Model, Launch ...

Model	Launch	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Shader clock (MHz)	Memory clock (MHz)	Core config¹	Fillrate		Memory				Processing power (GFLOPS)^[296]^[297]		Supported API version		TDP (Watts)	Notes
Model	Launch	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Shader clock (MHz)	Memory clock (MHz)	Core config¹	Pixel (GP/s)	Texture (GT/s)	Size (MB)	Bandwidth (GB/s)	Bus type	Bus width (bit)	Single precision	Double precision	Direct3D	OpenGL	TDP (Watts)	Notes
Quadro 400	Apr 5, 2011	GT216GL	40	PCIe 2.0 x16	450	1125	1540	48:16:4	1.8	7.2	512	12.3	DDR3	64	108	-	10.1	4.5	32	DisplayPort, Dual Link DVI
Quadro 600	Dec 13, 2010	GF108GL			640	1280	1600	96:16⁴:4	2.56	10.24	1024	25.6	DDR3	128	245.76	15	11.0	4.6	40	DisplayPort, Dual Link DVI
Quadro 2000	Dec 24, 2010	GF106GL (GF106-875)			625	1250	2600	192:32⁴:16	10	20	1024	41.6	GDDR5	128	480	30			62	Stereo DP Dual Link DVI, Dual DisplayPort
Quadro 4000	Nov 2, 2010	GF100			475	950	2800	256:32⁴:32	15.2	15.2	2048	89.6		256	486.4	243			142
Quadro 5000	Feb 23, 2011				513	1026	3000	352:44⁴:40	20.53	22.572	2560	120		320	722.304	359			152
Quadro 6000	Dec 10, 2010				574	1148	3000	448:56⁴:48	27.552	32.144	6144	144		384	1028.608	515			204
Quadro 7000	May 2, 2012	GF110			651	1301	3696	512:64⁴:48	31.248	41.7	6144	177		384	1332	667			204
Quadro Plex 7000^[299]	July 25, 2011	2x GF100			574	1148	3000	2x 512:64⁴:48	2x 18.37	2x 36.74	2x 6144	2x 144		2x 384	2x 1176	2x 588			600

Quadro Kxxx series

Further information: Quadro

¹Unified shaders: texture mapping units: render output units

More information Model, Launch ...

Model	Launch	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Shader clock (MHz)	Memory clock (MHz)	Core config¹	Fillrate		Memory				Processing power (GFLOPS)^[296]^[297]		Supported API version				TDP (Watts)	Notes
Model	Launch	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Shader clock (MHz)	Memory clock (MHz)	Core config¹	Pixel (GP/s)	Texture (GT/s)	Size (MB)	Bandwidth (GB/s)	Bus type	Bus width (bit)	Single precision	Double precision	Direct3D	OpenGL	Vulkan	CUDA	TDP (Watts)	Notes
Quadro 410	Aug 7, 2012	GK107	28	PCIe 2.0 x16	706	706	1800	192:16:8 (1 SMX)	5.65	11.3	512	14.4	DDR3^[300]	64	271.10		11.0	4.6	1.2	3.0	38
Quadro K600	Mar 1, 2013				876	876	891 (1782)	192:16:16 (1 SMX)	14.0	14.0	1024	28.5	DDR3	128	336.38						41	6.3" Card
Quadro K2000	Mar 1, 2013				954	954	1000 (4000)	384:32:16 (2 SMX)	15.2	30.5	2048	64	GDDR5		732.67						51	7.97" Card
Quadro K2000D	Mar 1, 2013				954	954	1000 (4000)	384:32:16 (2 SMX)	15.2	30.5	2048	64			732.67						51	7.97" Card
Quadro K4000	Mar 1, 2013	GK106			810.5	810.5	1404 (5616)	768:64:24 (4 SMX)	19.4	51.9	3072	134.8		192	1244.93						80	9.5" Card
Quadro K5000	Aug 17, 2012	GK104			706	706	1350 (5400)	1536:128:32 (8 SMX)	22.6	90.4	4096	172.8		256	2168.83	90.4					122	10.5" Card
Quadro K6000	Jul 23, 2013	GK110		PCIe 3.0 x16	901.5	901.5	1502 (6008)	2880:240:48 (15 SMX)	54.1	216	12288	288		384	5196	1732				3.5	225	10.5" Card

More information Model, Launch ...

Model	Launch	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Shader clock (MHz)	Memory clock (MHz)	Core config¹	Fillrate		Memory				Processing power (GFLOPS)^[296]^[297]		Supported API version				TDP (Watts)	Notes
Model	Launch	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Shader clock (MHz)	Memory clock (MHz)	Core config¹	Pixel (GP/s)	Texture (GT/s)	Size (MB)	Bandwidth (GB/s)	Bus type	Bus width (bit)	Single precision	Double precision	Direct3D	OpenGL	Vulkan	CUDA	TDP (Watts)	Notes
Quadro K420	Jul 22, 2014	GK107	28	PCIe 2.0 x16	780	780	1800	192:16:16 (1 SMX)	12.48	12.48	1024 2048^[301]	29	DDR3	128	299.52	12.48	11.0	4.6	1.2	3.0	41
Quadro K620	Jul 22, 2014	GM107-850			1000	1000	900 (1800)	384:24:16 (3 SMM)	16.0	24.0	2048	28.8	DDR3		768.0	24.0	12.0		1.3	5.0	45	6.3" Card
Quadro K1200	Jan 28, 2015	GM107-860			954		1253	512:32:16 (4 SMM)	15.3	30.5	4096	80.2	GDDR5		1083						45	7.97" Card
Quadro K2200	Jul 22, 2014	GM107-875-A2^[302]			1046	1046	1253 (5012)	640:40:16 (5 SMM)	16.7	41.8		80.2			1338.9	41.8					68	7.97" Card
Quadro K4200	Jul 22, 2014	GK104			780	780	1350 (5400)	1344:112:32 (7 SMX)	24.96	87.36		172.8		256	2096.64	87.36	11.0		1.2	3.0	105	9.5" Card
Quadro K5200	Jul 22, 2014	GK110B		PCIe 3.0 x16	650	650	1500 (6000)	2304:192:32 (12 SMX)	20.8	124.8	8192	192		256	2995.2	124.8	11.0		1.2	3.5	150	10.5" Card

Quadro Mxxx series

Further information: Quadro

¹Unified shaders: texture mapping units: render output units: streaming multiprocessors

More information Model, Launch ...

Model	Launch	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Shader clock (MHz)	Memory clock (MHz)	Core config¹	Fillrate		Memory				Processing power (GFLOPS)^[296]^[297]		Supported API version					TDP (Watts)	Notes
Model	Launch	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Shader clock (MHz)	Memory clock (MHz)	Core config¹	Pixel (GP/s)	Texture (GT/s)	Size (GB)	Bandwidth (GB/s)	Bus type	Bus width (bit)	Single precision	Double precision	Direct3D	OpenGL	Vulkan	OpenCL	CUDA	TDP (Watts)	Notes
Quadro M2000	Apr 8, 2016	GM206-875-A1^[303]	28	PCIe 3.0 x16	796	1163	1653 (6612)	768:48:32:6	37.8	56.6	4	105.8	GDDR5	128	1812.5	56.6	12.1	4.6	1.3	1.2	5.2	75	Four DisplayPort 1.2a
Quadro M4000	Jun 29, 2015	GM204-850-A1^[304]			773	773	1503 (6012)	1664:104:64:13	51.2	83.2	8	192.4		256	2662.4	83.2						120	Four DisplayPort 1.2a
Quadro M5000	Jun 29, 2015	GM204-875-A1^[304]			861	1038	1653 (6612)	2048:128:64:16	67.2	134.4	8	211.6		256	4300.8	134.4						150	Four DisplayPort 1.2a, One DVI-I
Quadro M6000	Mar 21, 2015	GM200GL GM200-880-A1^[303]			988	1114	1653 (6612)	3072:192:96:24	94.8	189.7	12 24	317		384	6070	190						250^[305]	Four DisplayPort 1.2a, One DVI-I

Quadro Pxxx series

Further information: Quadro

¹Unified shaders: texture mapping units: render output units: streaming multiprocessors

More information Model, Launch ...

Model	Launch	Code name^[239]	Fab (nm)	Bus interface	Core clock (MHz)	Boost clock (MHz)	Memory clock (MHz)	Core config¹	Fillrate^[306]		Memory				Processing power (GFLOPS)^[296]^[297]		Supported API version					TDP (Watts)	Notes
Model	Launch	Code name^[239]	Fab (nm)	Bus interface	Core clock (MHz)	Boost clock (MHz)	Memory clock (MHz)	Core config¹	Pixel (GP/s)	Texture (GT/s)	Size (GB)	Bandwidth (GB/s)	Bus type	Bus width (bit)	Single precision	Double precision	Direct3D	OpenGL	Vulkan	OpenCL	CUDA	TDP (Watts)	Notes
Quadro P400	Feb 7, 2017	GP107-825	14	PCIe 3.0 x16	1228	1252	1003 (4012)	256:16:16:2	17.1	17.1	2	32	GDDR5	64	641	20.0	12.1	4.6	1.3	1.2	6.1	30	Three Mini-DisplayPort 1.4
Quadro P600	Feb 7, 2017	GP107-850			1329	1557	1003 (4012)	384:24:16:3	21.7	32.5		64		128	1195	37.3						40	Four Mini-DisplayPort 1.4
Quadro P620	Feb 1, 2018	GP107-855			1266	1354	1003 (4012)	512:32:16:4	23.3	46.6		64			1490	46.6						40
Quadro P1000	Feb 7, 2017	GP107-860			1266	1481	1752 (7008)	640:40:32:5	43.3	54.2	4	82			1894	59.2						47
Quadro P2000	Feb 6, 2017	GP106-875	16		1076	1480	2002 (8008)	1024:64:40:8	54.8	87.7	5	140		160	3010	93.8						75	Four DisplayPort 1.4
Quadro P2200	Jun 10, 2019	GP106-880-K1-A1^[307]			1000	1493	1251 (10008)	1280:80:40:9	59.7	119.4	5	200	GDDR5X	160	3822	121.3						75
Quadro P4000	Feb 6, 2017	GP104-850-A1			1202	1480	1901 (7604)	1792:112:64:14	78.5	137.4	8	243	GDDR5	256	5300	165.6						105
Quadro P5000	Oct 1, 2016	GP104-875-A1			1607	1733	1126 (9008)	2560:160:64:20	102.8	257.1	16	288	GDDR5X	256	8873	277.3						180	Four DisplayPort 1.4, One DVI-D
Quadro P6000	Oct 1, 2016	GP102-875-A1			1506	1645	1126 (9008)	3840:240:96:30	136.0	340.0	24	432	GDDR5X	384	10882 (11758)	~340						250	Four DisplayPort 1.4, One DVI-D
Quadro GP100	Oct 1, 2016	GP100-876-A1			1304	1442	703 (1406)	3584:224:128:56	184.7	323	16	720	HBM2	4096	10336	5168					6	235	NVLINK support

Quadro GVxxx series

Further information: Quadro

¹ Unified shaders: texture mapping units: render output units: streaming multiprocessors: tensor cores

More information Model, Launch ...

Model	Launch	Code name^[239]	Fab (nm)	Bus interface	Core clock (MHz)	Boost clock (MHz)	Memory clock (MHz)	Core config¹	Fillrate^[306]		Memory				Processing power (GFLOPS)		Supported API version					TDP (Watts)	Notes
Model	Launch	Code name^[239]	Fab (nm)	Bus interface	Core clock (MHz)	Boost clock (MHz)	Memory clock (MHz)	Core config¹	Pixel (GP/s)	Texture (GT/s)	Size (GB)	Bandwidth (GB/s)	Bus type	Bus width (bit)	Single precision	Double precision	Direct3D	OpenGL	Vulkan	OpenCL	CUDA	TDP (Watts)	Notes
Quadro GV100^[308]	Mar 27, 2018	GV100-875-A1	12	PCIe 3.0 x16	1132	1627	848 (1696)	5120:320:128:80:640	208.4	521	32	870	HBM2	4096	14800	7400	12.1	4.6	1.3	3.0	7.0	250	4x DisplayPort, NVLINK support

Quadro Tx00/Tx000 series

¹ Unified shaders: texture mapping units: render output units: streaming multiprocessors

More information Model, Launch ...

Model	Launch	Code name^[239]	Fab (nm)	Bus interface	Core clock (MHz)	Boost clock (MHz)	Memory clock (MT)	Core config¹	Fillrate^[306]		Memory				Processing power (GFLOPS)^[306]		Supported API version					TDP (Watts)	Notes
Model	Launch	Code name^[239]	Fab (nm)	Bus interface	Core clock (MHz)	Boost clock (MHz)	Memory clock (MT)	Core config¹	Pixel (GP/s)	Texture (GT/s)	Size (GB)	Bandwidth (GB/s)	Bus type	Bus width (bit)	Single precision	Double precision	Direct3D	OpenGL	Vulkan	OpenCL	CUDA	TDP (Watts)	Notes
NVIDIA T400 ^[309]^[310]^[311]	May 6, 2021	TU117	TSMC 12FFN	PCIe 3.0 x16	420	1425	10000	384:24:16:6	22.8	34.2	2 4	80	GDDR6	64	1090	34.1	12.1	4.6	1.3	3.0	7.5	30	3x Mini-DisplayPort
NVIDIA T600 ^[309]^[312]^[313]	Apr 12, 2021	TU117-850-A1			735	1335		640:40:32:10	42.7	53.4	4	160		128	1700	53.1						40	4x Mini-DisplayPort
NVIDIA T1000 ^[309]^[314]^[315]	May 6, 2021	TU117			1065	1395		896:56:32:14	44.6	78.1	4 8	160		128	2500	78.1						50	4x Mini-DisplayPort

Quadro RTX x000 series

¹ Unified shaders: texture mapping units: render output units: streaming multiprocessors: tensor cores

More information Model, Launch ...

Model	Launch	Code name^[239]	Fab (nm)	Bus interface	Core clock (MHz)	Boost clock (MHz)	Memory clock (MHz)	Core config¹	Fillrate^[306]		Memory				Processing power (GFLOPS)^[306]		Supported API version					TDP (Watts)	Notes
Model	Launch	Code name^[239]	Fab (nm)	Bus interface	Core clock (MHz)	Boost clock (MHz)	Memory clock (MHz)	Core config¹	Pixel (GP/s)	Texture (GT/s)	Size (GB)	Bandwidth (GB/s)	Bus type	Bus width (bit)	Single precision	Double precision	Direct3D	OpenGL	Vulkan	OpenCL	CUDA	TDP (Watts)	Notes
Quadro RTX 4000	Nov 13, 2018	TU104-850-A1	12	PCIe 3.0 x16	1005	1545	1625 (13000)	2304:144:64:36:288	98.9	222.5	8	416	GDDR6	256	7119	222.5	12.2	4.6	1.3	3.0	7.5	100-125	3x DisplayPort 1x USB Type-C
Quadro RTX 5000	Aug 13, 2018	TU104-875-A1			1620	1815	1750 (14000)	3072:192:64:48:384	116.2	348.5	16	448		256	11151	348.5						125-230
Quadro RTX 6000	Aug 13, 2018	TU102-875-A1			1440	1770		4608:288:96:72:576	169.9	509.8	24	672		384	16312	509.8						100-260
Quadro RTX 8000	Aug 13, 2018	TU102-875-A1			1395	1770		4608:288:96:72:576	169.9	509.8	48	672		384	16312	509.8						100-260

RTX Ax000 series

¹ Unified shaders: texture mapping units: render output units: streaming multiprocessors: tensor cores

More information Model, Launch ...

Model	Launch	Code name^[239]	Fab (nm)	Bus interface	Core clock (MHz)	Boost clock (MHz)	Memory clock (MHz)	Core config¹	Fillrate^[306]		Memory				Processing power (GFLOPS)^[306]				Supported API version					TDP (Watts)	Notes
Model	Launch	Code name^[239]	Fab (nm)	Bus interface	Core clock (MHz)	Boost clock (MHz)	Memory clock (MHz)	Core config¹	Pixel (GP/s)	Texture (GT/s)	Size (GB)	Bandwidth (GB/s)	Bus type	Bus width (bit)	Half precision	Single precision	Double precision	Tensor compute (FP16) (sparse)	Direct3D	OpenGL	Vulkan	OpenCL	CUDA	TDP (Watts)	Notes
RTX A2000 ^[316]^[317]^[318]^[319]	Aug 10, 2021	GA106-850-A1	8	PCIe 4.0 x16	562	1200	1500 (12000)	3328:104:48:26:104	57.6	124.8	6	288	GDDR6	192	7987	7987	124.8	63900	12.2	4.6	1.3	3.0	8.6	70	4x mini DisplayPort
RTX A2000 ^[316]^[317]^[318]^[319]	Aug 10, 2021	GA106-850-A1		PCIe 4.0 x16	562	1200	1500 (12000)	3328:104:48:26:104	57.6	124.8	12	288	GDDR6	192	7987	7987	124.8	63900						70	4x mini DisplayPort
RTX A4000 ^[320]^[321]^[322]	Apr 12, 2021	GA104-875-A1		PCIe 4.0 x16	735	1560	1750 (14000)	6144:192:96:48:192	149.769	299.5	16	448	GDDR6	256	19170	19170	599	153400						140	4x DisplayPort
RTX A4500 ^[323]	Nov 23, 2021	GA102-825-KD-A1		PCIe 4.0 x16	1050	1650	2000 (16000)	7168:224:80:56:224	132.008	369.623	20	640	GDDR6	320	23655.91	23655.91	739.24	189247.31						200	4x DisplayPort
RTX A5000 ^[324]^[325]^[326]	Apr 12, 2021	GA102-850-A1		PCIe 4.0 x16	1170	1695	2000 (16000)	8192:256:96:64:256	162.730	433.947	24	768	GDDR6	384	27772.65	27772.65	867.89	222181.25						230	4x DisplayPort
RTX A5500 ^[319]	Mar 22, 2022	GA102-860-A1		PCIe 4.0 x16	1080	1665	2000 (16000)	10240:320:112:80:320	186.491	532.834	24	768	GDDR6	384	34101.38	34101.38	1065.66	272811.05						230	4x DisplayPort
RTX A6000 ^[327]^[328]^[329]	Oct 5, 2020	GA102-875-A1		PCIe 4.0 x16	1410	1800	2000 (16000)	10752:336:112:84:336	201.612	604.838	48	768	GDDR6	384	38709.67	38709.67	1209.67	309677.41						300	4x DisplayPort

RTX Ada Generation

More information Model, Launch ...

Model	Launch	Code name^[239]	Fab (nm)	Bus interface	Core clock (MHz)	Boost clock (MHz)	Memory clock (MHz)	Core config¹	Fillrate^[306]		Memory				Processing power (GFLOPS)^[306]				Supported API version					TDP (Watts)	Notes	Size
Model	Launch	Code name^[239]	Fab (nm)	Bus interface	Core clock (MHz)	Boost clock (MHz)	Memory clock (MHz)	Core config¹	Pixel (GP/s)	Texture (GT/s)	Size (GB)	Bandwidth (GB/s)	Bus type	Bus width (bit)	Half precision	Single precision	Double precision	Tensor compute (FP16) (sparse)	Direct3D	OpenGL	Vulkan	OpenCL	CUDA	TDP (Watts)	Notes	Profile	Slots
RTX 4000 SFF Ada Generation^[330]	Mar 21, 2023	AD104	TSMC 4N	PCIe 4.0 x16	720	1560	1750 (14000)	6144:192:80:48:192	125.2	300.5	20	280	GDDR6	160	19,230	19,230	300		12.2	4.6	1.3	3.0	8.9	70	4x mini DisplayPort	HHHL	Double
RTX 4000 Ada Generation^[331]	Aug 9, 2023	AD104		PCIe 4.0 x16	1500	2175	1750 (14000)	6144:192:80:48:192	174	417.6	20	360	GDDR6	160	26,730	26,730	417							130	4x DisplayPort	FHFL	Single
RTX 4500 Ada Generation^[332]	Aug 9, 2023	AD104-875-A1		PCIe 4.0 x16	2070	2580	2250 (18000)	7680:240:80:60:240	206	620	24	432	GDDR6	192	39,630	39,630	619							210	4x DisplayPort	FHFL	Double
RTX 5000 Ada Generation^[333]	Aug 9, 2023	AD102-850-KAB-A1		PCIe 4.0 x16	1155	2550	2250 (18000)	12800:400:160:100:400	408.0	1,020	32	576	GDDR6	256	65,280	65,280	1,020							250	4x DisplayPort	FHFL	Double
RTX 5880 Ada Generation^[334]	Jan 5, 2024	AD102		PCIe 4.0 x16		2460	2500 (20000)	14080:440:176:110:440	433.0	1,082	48	960	GDDR6	384	69,272	69,272	1,082							285	4x DisplayPort	FHFL	Double
RTX 6000 Ada Generation^[335]	Dec 3, 2022	AD102-870-A1		PCIe 4.0 x16	915	2505	2500 (20000)	18176:568:192:142:568	481.0	1,423	48	960	GDDR6	384	91,060	91,060	1,423							300	4x DisplayPort	FHFL	Double

Quadro NVS

Further information: Quadro

¹ Vertex shaders: pixel shaders: texture mapping units: render output units
² Unified shaders: texture mapping units: render output units
^* NV31, NV34 and NV36 are 2x2 pipeline designs if running vertex shader, otherwise they are 4x1 pipeline designs.

More information Model, Launch ...

Model	Launch	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Shader clock (MHz)	Memory clock (MHz)	Core config^12*	Fillrate		Memory				Processing power (GFLOPS)	Supported API version			TDP (Watts)	Notes
Model	Launch	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Shader clock (MHz)	Memory clock (MHz)	Core config^12*	Pixel (GP/s)	Texture (GT/s)	Size (MB)	Bandwidth (GB/s)	Bus type	Bus width (bit)	Single precision	Direct3D	OpenGL	Vulkan	TDP (Watts)	Notes
NVS 50	May 31, 2005	NV18	150	AGP 4x/PCI	250	250	200	0:2:4:2	0.5	1.0	64	1.6	DDR	32		7	1.2	n/a		DVI-I, S-Video
NVS 100	Dec 22, 2003	NV17			200		333	0:2:4:2			64	2.664		64						2x DVI-I, VGA, S-Video
NVS 200	Dec 22, 2003	NV17			250	250	250	0:2:4:2	0.5	1.0	64	8.0		128						LFH-60
NVS 210S	Dec 22, 2003	MCP51	90	Integrated	425			1:2:2:1	0.425	0.850	Up to 256 from system memory					9.0c				DVI + VGA
NVS 280	Oct 28, 2003	NV34GL	150	PCIe x16/AGP 8x / PCI	275	275	250	0:2:4:2/ 1:2:2:2 *:4:4:4	0.55	1.1	64	8.0				9.0	1.5		13	DMS-59
NVS 285	Jun 6, 2006	NV44	110	PCIe x1/x16	275	275	275	3:4:4:2	0.55	1.1	128	8.8				9.0	2.1		18	DMS-59
NVS 290	Oct 4, 2007	G86-827-A2	80		460	920	800	16:8:4	1.84	3.68	256	6.4	DDR2	64	44.16	10	3.3		21	DMS-59
NVS 295	May 7, 2009	G98	65		550	1300	1400	8:8:4	2.2	4.4	256	11.2	GDDR3		31.2	10			23	2x DisplayPort or 2x DVI-D
NVS 300	Jan 8, 2011	GT218	40		589	1402	1580	16:8:4	2.356	4.712	512	12.64	DDR3		67.3	10.1			17.5	DMS-59
NVS 310	Jun 26, 2012	GF119		PCIe x16	523	1046	1750	48:8:4	2.092	4.184	512	14			100.4	11.0	4.1		19.5	2x DisplayPort
NVS 315	Mar 10, 2013	GF119		PCIe x16	523	1046	1750	48:8:4	2.092	4.184	1024	14			100.4	11.0	4.1		19.5	DMS-59 Idle Power Consumption 7W
NVS 400	Jul 16, 2004	2x NV17	150	PCI	220	220	332	2x 0:2:4:2	2x 0.44	2x 0.88	2x 64	2x 11.0	DDR	2x 128	2x 5.328	7	1.2		18	2x LFH-60
NVS 420	Jan 20, 2009	2xG98-850-U2	65	PCIe x1/x16	550	1300	1400	2x 8:8:4	2x 2.2	2x 4.4	2x 256	2x 11.2	GDDR3	2x 64	2x 31.2	10	3.3		40	through VHDCI to (4x DisplayPort or 4x DVI-D)
NVS 440	Feb 14, 2006	2xNV43	110		250		500	2x 4:8:8:8	2x 2.000	2x 2.000	2x 128	2x 8.000	DDR	2x 128		9.0	2.1		31	2x DMS-59^[336]
NVS 450	Nov 11, 2008	2xG98	65		550	1300	1400	2x 8:8:4	2x 2.2	2x 4.4	2x 256	2x 11.2	GDDR3	2x 64	2x 31.2	10	3.3		35	4x DisplayPort
NVS 510	Oct 23, 2012	GK107	28	PCIe 2.0 x16	797		1782	192:16:8 (1 SMX)	3.188	12.75	2048	28.5	DDR3	128	306.0	11.0	4.6	1.2	35	4x miniDisplayPort
NVS 810	Nov 4, 2015	2x GM107	28	PCIe 3.0 x16	1033		1800	2x 512:32:16	16.53	33.06	2x 2048	2x 14.4	DDR3	2x 64	1058	11.0	4.6	1.3	68	8x miniDisplayPort

Mobile Workstation GPUs

Quadro Go (GL) & Quadro FX Go series

Further information: Quadro

Early mobile Quadro chips based on the GeForce2 Go up to GeForce Go 6800. Precise specifications on these old mobile workstation chips are very hard to find, and conflicting between Nvidia press releases and product lineups in GPU databases like TechPowerUp's GPUDB.

¹ Vertex shaders: pixel shaders: texture mapping units: render output units
² Unified shaders: texture mapping units: render output units

More information Model, Launch ...

Model	Launch	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Memory clock (MHz)	Core config¹²	Fillrate		Memory				Supported API version		TDP (Watts)	Notes
Model	Launch	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Memory clock (MHz)	Core config¹²	Pixel (GP/s)	Texture (GT/s)	Size (MB)	Bandwidth (GB/s)	Bus type	Bus width (bit)	Direct3D	OpenGL	TDP (Watts)	Notes
Quadro2 Go^[337]	August 14, 2001^[338]^[339]	NV11 GLM	180	AGP 4x	143	130 360	2:0:4:2	0.286	0.592	32 64	2.9 5.8	SDR DDR	128	7.0	1.2		First mobile Quadro based on the GeForce2 Go, Dynamic core clock 100–143 MHz, dynamic voltage 1.575V, graphics core listed as 64-bit and 128-bit for DDR and SDR SDRAM types respectively according to Nvidia^[340]^[341]
Quadro4 500 Go GL^[342]^[343]	April 23, 2002^[344]	NV17 GLM	150	AGP 4x,8x	220	220	2:0:4:2	0.44	0.88	64	7.0	DDR	128	7.0	1.3		Based on the GeForce4 Go, dynamic core clock 66–220 MHz, core voltage 1.35 V, uses DDR SDRAM according to Nvidia brochures^[341]
Quadro4 700 Go GL^[342]^[345]^[346]	February 5, 2003^[347]^[348]	NV28 GLM	150	AGP 4x,8x	176	200	4:2:4:4	0.704	0.704	64	7.4?		128?	8.1	1.3		Based on GeForce4 Go 4200, uses DDR according to Nvidia brochures
Quadro FX Go 700^[349]	June 2003?^[350]	NV31 GLM	130	AGP 8x	295	590	4:2:4:4	1.18	1.18	128	9.44?		128	9.0	2.1?		Slightly underclocked Geforce FX 5600 Go
Quadro FX Go 1000^[351]	February 2004?	NV36 GLM	130?	AGP 8x	295	570	4:3:4:4	1.18	1.18	128	9.12?		128				Based on TSMC 130 nm process with one extra pixel shader?
Quadro FX Go 1400^[351]	February 25, 2005^[352]	NV41 GLM	130	PCIe	275	590	12:5:12:12?	2.20	2.2	256	18.9?		256				Last chip designated as a Quadro FX Go, uses PCIe instead of AGP 8x. Core config has been mentioned as either 8:5:8:8 or 12:5:12:12 - the latter is likely since chip is derived from GeForce Go 6800.

Quadro FX (x500M) series

Further information: Quadro

GeForce 7-Series based.

¹ Vertex shaders: pixel shaders: texture mapping units: render output units

More information Model, Launch ...

Model	Launch	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Memory clock (MHz)	Core config¹	Fillrate		Memory				Supported API version		TDP (Watts)
Model	Launch	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Memory clock (MHz)	Core config¹	Pixel (GP/s)	Texture (GT/s)	Size (MB)	Bandwidth (GB/s)	Bus type	Bus width (bit)	Direct3D	OpenGL	TDP (Watts)
Quadro FX 350M	Mar 13, 2006	G72GLM	90	PCIe 1.0 x16	450	900	3:4:4:2	0.9	1.8	256	14.4	GDDR3	128	9.0c	2.1	15
Quadro FX 1500M	Apr 18, 2006	G71GLM			375	1000	8:24:24:16	6	9	512	32		256
Quadro FX 2500M	Sep 29, 2005				500	1200		8	12		38.4
Quadro FX 3500M	Mar 1, 2007				575	1200		9.2	13.8		38.4

Quadro FX (x600M) series

Further information: Quadro

GeForce 8-Series (except FX 560M and FX 3600M) based. First Quadro Mobile line to support DirectX 10.

¹Unified shaders: texture mapping units: render output units

More information Model, Launch ...

Model	Launch	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Shader clock (MHz)	Memory clock (MHz)	Core config¹	Fillrate		Memory				Processing power (GFLOPS)	Supported API version		TDP (Watts)	Notes
Model	Launch	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Shader clock (MHz)	Memory clock (MHz)	Core config¹	Pixel (GP/s)	Texture (GT/s)	Size (MB)	Bandwidth (GB/s)	Bus type	Bus width (bit)	Single precision	Direct3D	OpenGL	TDP (Watts)	Notes
Quadro FX 360M	May 9, 2007	G86M	80	PCIe 1.0 x16	400	800	1200	16:8:4	1.6	3.2	256	9.6	DDR2	64	38.4	10.0	3.3	17	Based on the GeForce 8400M GS
Quadro FX 560M	Apr 20, 2006	G73GLM	90		500	500	1200	5:12:12:8	4	6	512	19.2	GDDR3	128		9.0c	2.1	35?	7600GS based?
Quadro FX 1600M	Jun 1, 2007	G84M	80		625	1250	1600	32:16:8	5	10		25.6		128	120	10.0	3.3	50?
Quadro FX 3600M	Feb 23, 2008	G92M	65		500	1250	1600	64:32:16 96:48:16	8 8	16 24		51.2		256	240 360	10.0	3.3	70	Based on the GeForce 8800M GTX. Dell Precision M6300 uses 64 shader version of the FX 3600M

Quadro FX (x700M) series

Further information: Quadro

¹Unified shaders: texture mapping units: render output units

More information Model, Launch ...

Model	Launch	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Shader clock (MHz)	Memory clock (MHz)	Core config¹	Fillrate		Memory				Processing power (GFLOPS)	Supported API version		TDP (Watts)
Model	Launch	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Shader clock (MHz)	Memory clock (MHz)	Core config¹	Pixel (GP/s)	Texture (GT/s)	Size (MB)	Bandwidth (GB/s)	Bus type	Bus width (bit)	Single precision	Direct3D	OpenGL	TDP (Watts)
Quadro FX 370M	Aug 15, 2008	G98M	65	PCIe 1.0 x16	550	1400	1200	8:4:4	2.2	2.2	256	9.6	GDDR3	64	33.6	10.0	3.3	20
Quadro FX 570M	Jun 1, 2007	G84M	80		475	950	1400	32:16:8	3.8	7.6	512	22.4		128	91.2			45
Quadro FX 770M	Aug 14, 2008	G96M	65		500	1250	1600		4	8		25.6			119.0			35
Quadro FX 1700M	Oct 1, 2008	G96M			625	1550			5	10		25.6			148.8			50
Quadro FX 2700M	Aug 14, 2008	G94M			530	1325		48:24:16	8.48	12.72		51.2		256	190.8			65
Quadro FX 3700M	Aug 14, 2008	G92M			530	1375		128:64:16	8.8	35.2	1024	51.2		256	528			75

Quadro FX (x800M) series

Further information: Quadro

The last DirectX 10 based Quadro mobile cards.

¹Unified shaders: texture mapping units: render output units

More information Model, Launch ...

Model	Launch	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Shader clock (MHz)	Memory clock (MHz)	Core config¹	Fillrate		Memory				Processing power (GFLOPS)	Supported API version		TDP (Watts)
Model	Launch	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Shader clock (MHz)	Memory clock (MHz)	Core config¹	Pixel (GP/s)	Texture (GT/s)	Size (MB)	Bandwidth (GB/s)	Bus type	Bus width (bit)	Single precision	Direct3D	OpenGL	TDP (Watts)
Quadro FX 380M	Jan 7, 2010	GT218M	40	PCIe 2.0 x16	625	1530	1600	16:8:4	2.5	5	512	12.8	GDDR3	64	73.44	10.1	3.3	25
Quadro FX 880M	Jan 7, 2010	GT216M			550	1210	1600	48:16:8	4.4	8.8	1024	25.6	GDDR3	128	174.24			35
Quadro FX 1800M	Jun 15, 2009	GT215M			450	1080	1600 2200	72:24:8	3.6	10.8		25.6 35.2	GDDR3 GDDR5	128	233.28			45
Quadro FX 2800M	Dec 1, 2009	G92M	55		500	1250	2000	96:48:16	8	16		64	GDDR3	256	360	10.0		75
Quadro FX 3800M	Aug 14, 2008	G92M	55		675	1688	2000	128:64:16	10.8	43.2		64	GDDR3	256	648.192	10.0		100

Quadro (xxxxM) series

Further information: Quadro

¹ Unified shaders: texture mapping units: render output units
² Each SM in the Fermi architecture contains 4 texture filtering units for every texture address unit

More information Model, Launch ...

Model	Launch	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Shader clock (MHz)	Memory clock (MHz)	Core config¹²	Fillrate		Memory				Processing power (GFLOPS)	Supported API version		TDP (Watts)	Notes
Model	Launch	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Shader clock (MHz)	Memory clock (MHz)	Core config¹²	Pixel (GP/s)	Texture (GT/s)	Size (MB)	Bandwidth (GB/s)	Bus type	Bus width (bit)	Single precision	Direct3D	OpenGL	TDP (Watts)	Notes
Quadro 500M	Feb 22, 2011	GF108	40	PCIe 2.0 x16	700	1400	1800	96:16:4	2.8	11.2	1024	28.8	DDR3	128	268.8	11.0	4.5	35
Quadro 1000M	Jan 13, 2011	GF108			700	1400		96:16:4	2.8	11.2	2048				268.8			45	Dell Precision M4600
Quadro 2000M	Jan 13, 2011	GF106			550	1100		192:32:16	8.8	17.6					422.4			55	Dell Precision M4600
Quadro 3000M	Feb 22, 2011	GF104			450	900	2500	240:40:32	14.4	18		80	GDDR5	256	432			75	Dell Precision M6600
Quadro 4000M	Feb 22, 2011	GF104			475	950	2500	336:56:32	15.2	26.6		80			638.4			100	Dell Precision M6600
Quadro 5000M	Jul 27, 2010	GF100			405	810	2400	320:40:32	12.96	16.2		76.8			518.4				Dell Precision M6500
Quadro 5010M	Feb 22, 2011	GF110			450	900	2600	384:48:32	14.4	21.6	4096	83.2			691.2				Dell Precision M6600

Quadro (Kx000M) series

Further information: Quadro

¹Unified shaders: texture mapping units: render output units

More information Model, Launch ...

Model	Launch	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Shader clock (MHz)	Memory clock (MHz)	Core config¹	Fillrate		Memory				Processing power (GFLOPS)	Supported API version		Nvidia Optimus technology	TDP (Watts)	Notes
Model	Launch	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Shader clock (MHz)	Memory clock (MHz)	Core config¹	Pixel (GP/s)	Texture (GT/s)	Size (MB)	Bandwidth (GB/s)	Bus type	Bus width (bit)	Single precision	Direct3D	OpenGL	Nvidia Optimus technology	TDP (Watts)	Notes
Quadro K500M	Jun 1, 2012	GK107	28	PCIe 3.0 x16	850	850	1600	192:16:8	6.8	13.6	1024	12.8	DDR3	64	326.4	11.0	4.5	Yes	35
Quadro K1000M	Jun 1, 2012				850	850	1800	192:16:16	13.6	13.6	2048	28.8		128	326.4				45	Dell Precision M4700
Quadro K2000M	Jun 1, 2012				745	745	1800	384:32:16	11.92	23.84		28.8		128	572.16				55	Dell Precision M4700
Quadro K3000M	Jun 1, 2012	GK104			654	654	2800	576:48:32	20.93	31.39		89.6	GDDR5	256	753.41				75	Dell Precision M6700
Quadro K4000M	Jun 1, 2012				600	600	2800	960:80:32	19.2	48	4096	89.6			1152				100	Dell Precision M6700
Quadro K5000M	Aug 7, 2012				706	706	3000	1344:112:32	22.59	79.07	4096	96			1897.73				100	Dell Precision M6700

Quadro (Kx100M) series

Further information: Quadro

¹Unified shaders: texture mapping units: render output units

More information Model, Launch ...

Model	Launch	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Shader clock (MHz)	Memory clock (MHz)	Core config¹	Fillrate		Memory				Processing power (GFLOPS)	Supported API version		Nvidia Optimus technology	TDP (Watts)	Notes
Model	Launch	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Shader clock (MHz)	Memory clock (MHz)	Core config¹	Pixel (GP/s)	Texture (GT/s)	Size (MB)	Bandwidth (GB/s)	Bus type	Bus width (bit)	Single precision	Direct3D	OpenGL	Nvidia Optimus technology	TDP (Watts)	Notes
Quadro K510M	Jul 23, 2013	GK208	28	PCIe 3.0 x8	850	850	1200 (2400)	192:16:8 (1 SMX)	6.8	13.6	1024	19.2	GDDR5	64	326.4	11.0	4.5	Yes	30
Quadro K610M	Jul 23, 2013	GK208		PCIe 3.0 x16	980	980	1300 (2600)	192:16:8 (1 SMX)	7.84	15.68	1024	20.8		64	376.32				30
Quadro K1100M	Jul 23, 2013	GK107			716	716	1400 (2800)	384:32:16 (2 SMX)	11.45	22.91	2048	44.8		128	549.89				45	Dell Precision M3800 and M4800
Quadro K2100M	Jul 23, 2013	GK106			654	654	1500 (3000)	576:48:16 (3 SMX)	10.46	31.39	2048	48.0		128	753.41				55	Dell Precision M4800
Quadro K3100M	Jul 23, 2013	GK104			680	680	800 (3200)	768:64:32 (4 SMX)	21.76	43.52	4096	102.4		256	1044.48				75	Dell Precision M6800
Quadro K4100M	Jul 23, 2013				706	706	800 (3200)	1152:96:32 (6 SMX)	22.59	67.77	4096	102.4			1626.624				100	Dell Precision M6800
Quadro K5100M	Jul 23, 2013				771	771	900 (3600)	1536:128:32 (8 SMX)	24.67	98.68	8192	115.2			2368.51				100	Dell Precision M6800

Quadro (Kx200M) series

Further information: Quadro

¹Unified shaders: texture mapping units: render output units

More information Model, Launch ...

Model	Launch	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Boost clock (MHz)	Memory clock (MHz)	Core config¹	Fillrate		Memory				Processing power (GFLOPS)		Supported API version		Nvidia Optimus technology	TDP (Watts)
Model	Launch	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Boost clock (MHz)	Memory clock (MHz)	Core config¹	Pixel (GP/s)	Texture (GT/s)	Size (MB)	Bandwidth (GB/s)	Bus type	Bus width (bit)	Single precision	Double precision	Direct3D	OpenGL	Nvidia Optimus technology	TDP (Watts)
Quadro K2200M	Jul 19, 2014	GM107	28	PCIe 3.0 x16	1150	1150	1253 (5012)	640:40:16 (5 SMM)	18.4	46	2048	80.2	GDDR5	128	1472	46	12.1	4.5	Yes	65

Quadro (Mx000M) series

Further information: Quadro

¹Unified shaders: texture mapping units: render output units

More information Model, Launch ...

Model	Launch	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Boost clock (MHz)	Memory clock (MHz)	Core config¹	Fillrate		Memory				Processing power (GFLOPS)		Supported API version			Nvidia Optimus technology	TDP (Watts)
Model	Launch	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Boost clock (MHz)	Memory clock (MHz)	Core config¹	Pixel (GP/s)	Texture (GT/s)	Size (MB)	Bandwidth (GB/s)	Bus type	Bus width (bit)	Single precision	Double precision	Direct3D	OpenGL	Vulkan	Nvidia Optimus technology	TDP (Watts)
Quadro M500M	Apr 27, 2016	GM108	28	PCIe 3.0 x16	1029	1124	900 (1800)	384:24:8 (3 SMM)	8.992	17.98	2048	14.40	DDR3	64	863.2	26.98	12.1	4.5	1.0	Yes	25
Quadro M600M	Aug 18, 2015	GM107			837	876	1253 (5012)	384:24:16 (3 SMM)	7.008	14.02		80.2	GDDR5	128	672.8	21.02					30
Quadro M1000M	Aug 18, 2015				993			512:32:16 (4 SMM)	15.89	31.78					1017	31.78					40
Quadro M2000M	Dec 3, 2015				1029	1098		640:40:16 (5 SMM)	17.57	43.92	4096				1405	43.92					55
Quadro M3000M	Aug 18, 2015	GM204			1050			1024:64:32 (8 SMM)	33.60	67.20		160.4		256	2150	67.20					75
Quadro M4000M	Aug 18, 2015				975			1280:80:48 (10 SMM)	62.40	78.00					2496	78.00					100
Quadro M5000M	Aug 18, 2015				962			1536:96:64 (12 SMM)	62.40	93.60	8192				2955.3	93.60					100

Quadro (Mx200) series

Further information: Quadro

¹Unified shaders: texture mapping units: render output units

More information Model, Launch ...

Model	Launch	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Boost clock (MHz)	Memory clock (MHz)	Core config¹	Fillrate		Memory				Processing power (GFLOPS)	Supported API version		Nvidia Optimus technology	TDP (Watts)
Model	Launch	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Boost clock (MHz)	Memory clock (MHz)	Core config¹	Pixel (GP/s)	Texture (GT/s)	Size (MB)	Bandwidth (GB/s)	Bus type	Bus width (bit)	Single precision	Direct3D	OpenGL	Nvidia Optimus technology	TDP (Watts)
Quadro M520	Jan 11, 2017	GM108	28	PCIe 3.0 x16	965	1176	5000	384:24:8 (3 SMM)	9.4	18.8	1024	40	GDDR5	64	840	12.1	4.5	Yes	25
Quadro M620	Jan 11, 2017	GM107			756	1018	5012	512:32:16 (4 SMM)	16.3	32.6	2048	80.2		128	1000				30
Quadro M1200	Jan 11, 2017	GM107			991	1148	5012	640:40:16 (5 SMM)	18.4	45.9	4096	80.2			1400				45
Quadro M2200	Jan 11, 2017	GM206			695	1037	5508	1024:64:32 (8 SMM)	33.2	66.3	4096	88.1			2100				55

Quadro (Mx500) series

Further information: Quadro

¹Unified shaders: texture mapping units: render output units

More information Model, Launch ...

Model	Launch	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Boost clock (MHz)	Memory clock (MHz)	Core config¹	Fillrate		Memory				Processing power (GFLOPS)	Supported API version		Nvidia Optimus technology	TDP (Watts)
Model	Launch	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Boost clock (MHz)	Memory clock (MHz)	Core config¹	Pixel (GP/s)	Texture (GT/s)	Size (MB)	Bandwidth (GB/s)	Bus type	Bus width (bit)	Single precision	Direct3D	OpenGL	Nvidia Optimus technology	TDP (Watts)
Quadro M5500	Apr 8, 2016	GM204	28	PCIe 3.0 x16	861	1140	6606	2048:128:64 (16 SMM)	73	145.9	8192	211.4	GDDR5	256	4669	12.1	4.5	Yes	150

Quadro (Px000) series

Further information: Quadro

¹Unified shaders: texture mapping units: render output units: streaming multiprocessors

More information Model, Launch ...

Model	Launch	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Boost clock (MHz)	Memory clock (MHz)	Core config¹	Fillrate		Memory				Processing power (GFLOPS)	Supported API version		Nvidia Optimus technology	TDP (Watts)
Model	Launch	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Boost clock (MHz)	Memory clock (MHz)	Core config¹	Pixel (GP/s)	Texture (GT/s)	Size (MB)	Bandwidth (GB/s)	Bus type	Bus width (bit)	Single precision	Direct3D	OpenGL	Nvidia Optimus technology	TDP (Watts)
Quadro P500	Jan 5, 2018	GP108	14	PCIe 3.0 x16				256:16:16:2			2048	40	GDDR5	64	750	12.1	4.5	Yes	18
Quadro P600	Feb 7, 2017	GP107						384:24:16:3			2048	80		128	1200				25
Quadro P1000	Feb 7, 2017	GP107(N18P-Q1-A1)						512:32:16:4			4096	96			1600				40
Quadro P2000	Feb 6, 2017	GP107(N18P-Q3-A1)						768:64:32:6			4096	96			2400				50
Quadro P3000	Jan 11, 2017	GP106	16					1280:80:48:10			6144	168		192	3098				75
Quadro P4000	Jan 11, 2017	GP104						1792:112:64:14			8192	192		256	4398				100
Quadro P4000 Max-Q	Jan 11, 2017							1792:112:64:14			8192								80
Quadro P5000	Jan 11, 2017							2048:128:64:16			16,384				6197				100

Quadro (Px200) series

Further information: Quadro

¹Unified shaders: texture mapping units: render output units: streaming multiprocessors

More information Model, Launch ...

Model	Launch	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Boost clock (MHz)	Memory clock (MHz)	Core config¹	Fillrate		Memory				Processing power (GFLOPS)	Supported API version		Nvidia Optimus technology	TDP (Watts)
Model	Launch	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Boost clock (MHz)	Memory clock (MHz)	Core config¹	Pixel (GP/s)	Texture (GT/s)	Size (MB)	Bandwidth (GB/s)	Bus type	Bus width (bit)	Single precision	Direct3D	OpenGL	Nvidia Optimus technology	TDP (Watts)
Quadro P3200	Feb 21, 2018	GP104	16	PCIe 3.0 x16				1792:112:64:14			6144	168	GDDR5	192	5300	12.1	4.5	Yes	78
Quadro P4200	Feb 21, 2018							2304:144:64:18			8192	168		256	7600				115
Quadro P5200	Feb 21, 2018							2560:160:64:20			16,384	230		256	8900				150

Quadro RTX / T x000 series

¹ Unified shaders: texture mapping units: render output units: streaming multiprocessors: tensor cores (or FP16 Cores in T x000 Series)

More information Model, Launch ...

Model	Launch	Code name^[239]	Fab (nm)	Bus interface	Core clock (MHz)	Boost clock (MHz)	L2 Cache (MB)	Core config¹	Fillrate		Memory					Processing power (GFLOPS)			Supported API version					TDP (Watts)	Notes
Model	Launch	Code name^[239]	Fab (nm)	Bus interface	Core clock (MHz)	Boost clock (MHz)	L2 Cache (MB)	Core config¹	Pixel (GP/s)	Texture (GT/s)	Size (GB)	Bandwidth (GB/s)	Memory clock (MHz)	Bus type	Bus width (bit)	Single precision	Half Precision	Double precision	Direct3D	OpenGL	Vulkan	OpenCL	CUDA	TDP (Watts)	Notes
Quadro T500^[319]	Dec 2, 2020	TU117(N19P-Q1-A1)	12	PCIe 3.0			1	896:?:?:?:?			2	80		GDDR5		3000			12.1	4.6	1.2	3.0	7.5
Quadro T500^[319]	Dec 2, 2020	TU117(N19P-Q1-A1)						896:?:?:?:?			4	80				3000
Quadro T550^[319]	May 2022							1024:?:?:?:?				112				3700
Quadro T600^[319]	Apr 12, 2021							896:?:?:?:?				192				3000
Quadro T1000^[353]	May 27, 2019	TU117(N19P-Q1-A1)			1395	1455		768:48:32:12:1536	46.56	69.84		128	2000		128	2235		69.84						40-50
Quadro T1200^[319]	Apr 12, 2021							1024:?:?:?:?				224				3700
Quadro T2000^[353]	May 27, 2019	TU117(N19P-Q3-A1)			1575	1785		1024:64:32:16:2048	57.1	114.2		128			128	3500								60
Quadro T2000 Max-Q	May 27, 2019	TU117						1024:64:32:16:2048				128			128									40
Quadro RTX 3000^[353]	May 27, 2019	TU106(N19E-Q1-KA-K1)			945	1380	4	2304:144:48:36:288	88.32	198.7	6	448	1750	GDDR6	256	6359	12,720	198.7						60-80
Quadro RTX 3000 Max-Q^[354]	May 27, 2019	TU106			600	1215		2304:144:48:36:288	77.76	175.0	6	416	1625			5599	11,200	175.0						60
Quadro RTX 4000^[353]	May 27, 2019	TU104(N19E-Q3-A1)			1110	1560		2560:160:64:40:320	99.84	249.6	8	448	1750			7987	15,970	249.6						110
Quadro RTX 4000 Max-Q^[355]	May 27, 2019	TU104			780	1380		2560:160:64:40:320	88.32	220.8	8	416	1625			7066	14,130	220.8						80
Quadro RTX 5000^[353]	May 27, 2019	TU104(N19E-Q5-A1)						3072:192:64:48:384	98.88	296.6	16	448	1750			9492	18,980	296.6						110
Quadro RTX 5000 Max-Q^[356]	May 27, 2019	TU104			600	1350		3072:192:64:48:384	86.40	259.2	16	448	1750			8294	15,970	259.2						80

RTX Ax000 series

¹ Unified shaders: texture mapping units: render output units: streaming multiprocessors: tensor cores

More information Model, Launch ...

Model	Launch	Code name^[239]	Fab (nm)	Bus interface	Core clock (MHz)	Boost clock (MHz)	L2 Cache (MB)	Core config¹	Fillrate		Memory					Processing power (GFLOPS)			Supported API version					TDP (Watts)	Notes
Model	Launch	Code name^[239]	Fab (nm)	Bus interface	Core clock (MHz)	Boost clock (MHz)	L2 Cache (MB)	Core config¹	Pixel (GP/s)	Texture (GT/s)	Size (GB)	Bandwidth (GB/s)	Memory clock (MHz)	Bus type	Bus width (bit)	Single precision	Half Precision	Double precision	Direct3D	OpenGL	Vulkan	OpenCL	CUDA	TDP (Watts)	Notes
RTX A500^[319]	Mar 22, 2022		Samsung 8N	PCIe 4.0		1710		2048:64:32:16:64			4	112	1750	GDDR6	64	7300			12.2	4.6	1.3	3.0		60
RTX A1000^[319]	Unknown					1845		2048:64:32:16:64			4	224	1750	GDDR6	128	7500								95
RTX A1000 6GB	Unknown					1830		2560:80:48:20:80			6	168	1750	GDDR6	96	9300
RTX A2000	Apr 12, 2021					1830					4	192	1500	GDDR6	128	9300
RTX A2000 8GB^[319]	Mar 22, 2022					1830					8	224	1750	GDDR6	128	9300
RTX A3000	Apr 12, 2021	GA104-A1				1560	4	4096:128:64:32:128		199.69	6	336	1750	GDDR6	192	12,800		399.38						130
RTX A3000 12GB^[319]	Mar 22, 2022	GA104-A1				1725	4	4096:128:64:32:128		220.81	12	336	1750	GDDR6	192	14,100		441.62						130
RTX A4000	Apr 12, 2021	GA104-A1				1740	4	5120:160:80:40:160		278.41	16	448	1750	GDDR6	256	17,800		556.83						140
RTX A4500^[319]	Mar 22, 2022	GA104-A1				1575	4	5888:184:96:46:184		289.81		512	2000	GDDR6	256	18,500		579.63						140
RTX A5000^[319]	Apr 12, 2021	GA104-A1				1770	4	6144:192:96:48:192		339.86		448	1750	GDDR6	256	21,700		679.72						165
RTX A5500^[357]^[319]	Mar 22, 2022	GA103-A1				1665	4	7424:232:96:58:232	159.85	386.30		512	2000	GDDR6	256	24,700		772.60						165

RTX Ada Generation

¹ CUDA cores: RT cores: Tensor cores

More information Model, Launch ...

Model	Launch	Code name^[239]	Fab (nm)	Bus interface	Core clock (MHz)	Boost clock (MHz)	L2 Cache (MB)	Core config¹	Fillrate		Memory					Processing power (GFLOPS)				Supported API version					TDP (Watts)	Notes
Model	Launch	Code name^[239]	Fab (nm)	Bus interface	Core clock (MHz)	Boost clock (MHz)	L2 Cache (MB)	Core config¹	Pixel (GP/s)	Texture (GT/s)	Size (GB)	Bandwidth (GB/s)	Memory clock (MHz)	Bus type	Bus width (bit)	Single precision	Tensor	HalfPrecision	Double precision	Direct3D	OpenGL	Vulkan	OpenCL	CUDA	TDP (Watts)	Notes
RTX 2000 Ada Generation^[358]	Mar, 2023	AD107	TSMC 4N	PCIe 4.0		2360	24	3072:24:96			8	256	1600	GDDR6	128	14,500	231,600								35 - 140
RTX 3000 Ada Generation^[358]		AD106				2160	32	4608:36:144			8 (ECC)	256	1600	GDDR6	128	19,900	318,600								35 - 140
RTX 3500 Ada Generation^[358]		AD104				2250	48	5120:40:160			12 (ECC)	432	1800	GDDR6	192	23,300	368,600								60 - 140
RTX 4000 Ada Generation^[358]		AD104				2260	48	7424:58:232			12 (ECC)	432		GDDR6	192	33,600	538,000								60 - 175
RTX 5000 Ada Generation^[358]		AD103				2190	64	9728:76:304			16 (ECC)	576		GDDR6	256	42,600	681,800								60 - 175

Mobility Quadro NVS series

Further information: Quadro

¹ Vertex shaders: pixel shaders: texture mapping units: render output units
² Unified shaders: texture mapping units: render output units

More information Model, Launch ...

Model	Launch	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Shader clock (MHz)	Memory clock (MHz)	Core config¹²	Fillrate		Memory				Processing power (GFLOPS)	Supported API version		TDP (Watts)	Notes
Model	Launch	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Shader clock (MHz)	Memory clock (MHz)	Core config¹²	Pixel (GP/s)	Texture (GT/s)	Size (MB)	Bandwidth (GB/s)	Bus type	Bus width (bit)	Single precision	Direct3D	OpenGL	TDP (Watts)	Notes
Quadro NVS 110M	Jun 1, 2006	G72M	90	PCIe 1.0 x16	300	300	600	3:4:4:2	0.6	1.2	Up to 512	4.8	DDR	64		9.0c	2.1	10
Quadro NVS 120M	Jun 1, 2006	G72GLM	90	PCIe 1.0 x16	450	450	700	3:4:4:2	0.9	1.8	Up to 512	5.6	DDR2			9.0c	2.1
Quadro NVS 130M	May 9, 2007	G86M	80	PCIe 2.0 x16	400?	800?	700	8:4:4	1.6?	1.6?	Up to 256	6.4?	DDR2		19.2	10.0	3.3
Quadro NVS 135M	May 9, 2007				400	800	1188	16:8:4	1.6	3.2	Up to 256	9.504	GDDR3		38.4
Quadro NVS 140M	May 9, 2007				400	800	1200	16:8:4	1.6	3.2	Up to 512	9.6			38.4
Quadro NVS 150M	Aug 15, 2008	G98M	65		530	1300	1400	8:4:4	2.12	2.12	Up to 256	11.2			31.2
Quadro NVS 160M	Aug 15, 2008	G98M	65		580	1450	1400	8:8:4	2.12	4.24	256	11.2			34.8			12
Quadro NVS 300M	May 24, 2006	G72GLM	90	PCIe 1.0 x16	450	450	1000	3:4:4:2	0.9	1.8	Up to 512	8	DDR2			9.0c	2.1	16
Quadro NVS 320M	Jun 9, 2007	G84M	65	PCIe 2.0 x16	575	1150	1400	32:16:8	4.6	9.2	Up to 512	22.4	GDDR3	128	110.4	10.0	3.3	20
Quadro NVS 510M	Aug 21, 2006	G72GLM	90	PCIe 1.0 x16	500	500	1200	8:24:24:16	8	12	Up to 1024	38.4	GDDR3	256		9.0c	2.1	45?	based on Go 7900 GTX

Mobility NVS series

Further information: Quadro

¹Unified shaders: texture mapping units: render output units

More information Model, Launch ...

Model	Launch	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Shader clock (MHz)	Memory clock (MHz)	Core config¹	Fillrate		Memory				Processing power (GFLOPS)	Supported API version		TDP (Watts)	Notes
Model	Launch	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Shader clock (MHz)	Memory clock (MHz)	Core config¹	Pixel (GP/s)	Texture (GT/s)	Size (MB)	Bandwidth (GB/s)	Bus type	Bus width (bit)	Single precision	Direct3D	OpenGL	TDP (Watts)	Notes
NVS 2100M	Jan 7, 2010	GT218M	40	PCIe 2.0 x16	535	1230	1600	16:8:4	2.14	4.28	Up to 512	12.8	GDDR3	64	59.04	10.1	3.3	14
NVS 3100M	Jan 7, 2010	GT218M			600	1470		16:8:4	2.4	4.8	Up to 512				70.56	10.1	3.3	14	based on G210M/310M
NVS 4200M	Jan 7, 2010	GF119			810	1620		48:8:4	3.24	6.48	Up to 1024				155.52	11	4.5		based on GT 520M
NVS 5100M	Feb 22, 2011	GT216M			550	1210		48:16:8	4.4	8.8		25.6		128	174.24	10.1	3.3	35
NVS 5200M	Jun 1, 2012	GF108 GF117^[359]	40/28		625	1250	1800	96:16:4	2.5	10		14.4		64	240	11	4.5
NVS 5400M	Jun 1, 2012	GF108 GF117^[359]	40/28		660	1320	1800	96:16:4	2.64	10.56		28.8		128	253.44	11	4.5

Tegra GPU

Main article: Tegra

Data Center GPUs

GRID

More information Model, Archi- tecture ...

Model	Archi- tecture	Chips	Thread processors (total)	Bus interface	Memory		TDP (Watts)
Model	Archi- tecture	Chips	Thread processors (total)	Bus interface	Bus type	Size (GB)	TDP (Watts)
GRID K1^[360]	Kepler	4x GK107	4x 192	PCIe 3.0 x16	DDR3	4x 4 GB	130
GRID K2^[361]		2x GK104-895	2x 1536		GDDR5	2x 4 GB	225
GRID K340		4x GK107	4x 384			4x 1 GB
GRID K520		2x GK104	2x 1536			2x 4 GB

Data from GRID GPUS^[362]

Tesla

Further information: Nvidia Tesla

More information Model, Micro-architecture ...

Model	Micro- architecture	Launch	Chips	Core clock (MHz)	Shaders			Memory					Processing power (GFLOPS)^{[lower-alpha 1]}			CUDA compute capability^{[lower-alpha 2]}	TDP (W)	Notes, form factor
Model	Micro- architecture	Launch	Chips	Core clock (MHz)	CUDA cores (total)	Base clock (MHz)	Max boost clock (MHz)^{[lower-alpha 3]}	Bus type	Bus width (bit)	Size (GB)	Clock (MT/s)	Bandwidth (GB/s)	Half precision Tensor Core FP32 Accumulate	Single precision (MAD or FMA)	Double precision (FMA)	CUDA compute capability^{[lower-alpha 2]}	TDP (W)	Notes, form factor
C870 GPU Computing Module^{[lower-alpha 4]}	Tesla	May 2, 2007	1× G80	600	128	1,350	—	GDDR3	384	1.5	1,600	76.8	No	345.6	No	1.0	170.9	Internal PCIe GPU (full-height, dual-slot)
D870 Deskside Computer^{[lower-alpha 4]}		May 2, 2007	2× G80	600	256	1,350	—	GDDR3	2× 384	2× 1.5	1,600	2× 76.8	No	691.2	No	1.0	520	Deskside or 3U rack-mount external GPUs
S870 GPU Computing Server^{[lower-alpha 4]}		May 2, 2007	4× G80	600	512	1,350	—	GDDR3	4× 384	4× 1.5	1,600	4× 76.8	No	1382.4	No	1.0		1U rack-mount external GPUs, connect via 2× PCIe (×16)
C1060 GPU Computing Module^{[lower-alpha 5]}		April 9, 2009	1× GT200	602	240	1,296^[364]	—	GDDR3	512	4	1,600	102.4	No	622.08	77.76	1.3	187.8	Internal PCIe GPU (full-height, dual-slot)
S1070 GPU Computing Server "400 configuration"^{[lower-alpha 5]}		June 1, 2008	4× GT200	602	960	1296	—	GDDR3	4× 512	4× 4	1,538.4	4× 98.5	No	2,488.3	311.0	1.3	800	1U rack-mount external GPUs, connect via 2× PCIe (×8 or ×16)
S1070 GPU Computing Server "500 configuration"^{[lower-alpha 5]}			4× GT200	602	960	1,440	—	GDDR3	4× 512	4× 4	1,538.4	4× 98.5	No	2,764.8	345.6	1.3	800
S1075 GPU Computing Server^{[lower-alpha 5]}^[365]		June 1, 2008	4× GT200	602	960	1,440	—	GDDR3	4× 512	4× 4	1,538.4	4× 98.5	No	2,764.8	345.6	1.3		1U rack-mount external GPUs, connect via 1× PCIe (×8 or ×16)
Quadro Plex 2200 D2 Visual Computing System^{[lower-alpha 6]}		July 25, 2008	2× GT200GL	648	480	1,296	—	GDDR3	2× 512	2× 4	1,600	2× 102.4	No	1,244.2	155.5	1.3		Deskside or 3U rack-mount external GPUs with 4 dual-link DVI outputs
Quadro Plex 2200 S4 Visual Computing System^{[lower-alpha 6]}		July 25, 2008	4× GT200GL	648	960	1,296	—	GDDR3	4× 512	4× 4	1,600	4× 102.4	No	2,488.3	311.0	1.3	1,200	1U rack-mount external GPUs, connect via 2× PCIe (×8 or ×16)
C2050 GPU Computing Module^[366]	Fermi	July 25, 2011	1× GF100	575	448	1,150	—	GDDR5	384	3^{[lower-alpha 7]}	3000	144	No	1,030.4	515.2	2.0	247	Internal PCIe GPU (full-height, dual-slot)
M2050 GPU Computing Module^[367]		July 25, 2011	1× GF100	575	448	1,150	—	GDDR5	384	3^{[lower-alpha 7]}	3,092	148.4	No	1,030.4	515.2	2.0	225	Internal PCIe GPU (full-height, dual-slot)
C2070 GPU Computing Module^[366]		July 25, 2011	1× GF100	575	448	1,150	—	GDDR5	384	6^{[lower-alpha 7]}	3,000	144	No	1,030.4	515.2	2.0	247	Internal PCIe GPU (full-height, dual-slot)
C2075 GPU Computing Module^[368]		July 25, 2011					—				3,000	144	No				225
M2070/M2070Q GPU Computing Module^[369]		July 25, 2011					—				3,132	150.336	No				225
M2090 GPU Computing Module^[370]		July 25, 2011	1× GF110	650	512	1,300	—	GDDR5	384	6^{[lower-alpha 7]}	3700	177.6	No	1,331.2	665.6	2.0	225	Internal PCIe GPU (full-height, dual-slot)
S2050 GPU Computing Server		July 25, 2011	4× GF100	575	1792	1150	—	GDDR5	4× 384	4× 3^{[lower-alpha 7]}	3	4× 148.4	No	4,121.6	2,060.8	2.0	900	1U rack-mount external GPUs, connect via 2× PCIe (×8 or ×16)
S2070 GPU Computing Server			4× GF100	575	1792	1150	—	GDDR5	4× 384	4× 6^{[lower-alpha 7]}	3	4× 148.4	No	4,121.6	2,060.8	2.0	900
K10 GPU accelerator^[371]	Kepler	May 1, 2012	2× GK104	—	3,072	745	?	GDDR5	2× 256	2× 4	5,000	2× 160	No	4,577	190.7	3.0	225	Internal PCIe GPU (full-height, dual-slot)
K20 GPU accelerator^[372]^[373]		November 12, 2012	1× GK110	—	2,496	706	758	GDDR5	320	5	5,200	208	No	3,524	1,175	3.5	225	Internal PCIe GPU (full-height, dual-slot)
K20X GPU accelerator^[374]		November 12, 2012	1× GK110	—	2,688	732	?	GDDR5	384	6	5,200	250	No	3,935	1,312	3.5	235	Internal PCIe GPU (full-height, dual-slot)
K40 GPU accelerator^[375]		October 8, 2013	1× GK110B	—	2,880	745	875	GDDR5	384	12^{[lower-alpha 7]}	6,000	288	No	4,291–5,040	1,430–1,680	3.5	235	Internal PCIe GPU (full-height, dual-slot)
K80 GPU accelerator^[376]		November 17, 2014	2× GK210	—	4,992	560	875	GDDR5	2× 384	2× 12	5,000	2× 240	No	5,591–8,736	1,864–2,912	3.7	300	Internal PCIe GPU (full-height, dual-slot)
M4 GPU accelerator^[377]^[378]	Maxwell	November 10, 2015	1× GM206	—	1,024	872	1,072	GDDR5	128	4	5,500	88	No	1,786–2,195	55.81–68.61	5.2	50–75	Internal PCIe GPU (half-height, single-slot)
M6 GPU accelerator^[379]		August 30, 2015	1× GM204-995-A1	—	1536	722	1,051	GDDR5	256	8	4,600	147.2	No	2,218–3,229	69.3–100.9	5.2	75–100	Internal MXM GPU
M10 GPU accelerator^[380]			4× GM107	—	2,560	1,033	?	GDDR5	4× 128	4× 8	5,188	4× 83	No	5,289	165.3	5.2	225	Internal PCIe GPU (full-height, dual-slot)
M40 GPU accelerator^[378]^[381]		November 10, 2015	1× GM200	—	3,072	948	1,114	GDDR5	384	12 or 24	6,000	288	No	5,825–6,844	182.0–213.9	5.2	250	Internal PCIe GPU (full-height, dual-slot)
M60 GPU accelerator^[382]		August 30, 2015	2× GM204-895-A1	—	4,096	899	1,178	GDDR5	2× 256	2× 8	5,000	2× 160	No	7,365–9,650	230.1–301.6	5.2	225–300	Internal PCIe GPU (full-height, dual-slot)
P4 GPU accelerator^[383]	Pascal	September 13, 2016	1× GP104	—	2,560	810	1,063	GDDR5	256	8	6,000	192.0	No	4,147–5,443	129.6–170.1	6.1	50-75	PCIe card
P6 GPU accelerator^[384]^[385]		March 24, 2017	1× GP104-995-A1	—	2,048	1,012	1,506	GDDR5	256	16	3,003	192.2	No	6,169	192.8	6.1	90	MXM card
P40 GPU accelerator^[383]		September 13, 2016	1× GP102	—	3,840	1,303	1,531	GDDR5	384	24	7,200	345.6	No	10,007–11,758	312.7–367.4	6.1	250	PCIe card
P100 GPU accelerator (mezzanine)^[386]^[387]		April 5, 2016	1× GP100-890-A1	—	3,584	1,328	1,480	HBM2	4,096	16	1,430	732	No	9,519–10,609	4,760–5,304	6.0	300	SXM card
P100 GPU accelerator (16 GB card)^[388]		June 20, 2016	1× GP100	—		1126	1303		4,096	16		732	No	8,071‒9,340	4,036‒4,670		250	PCIe card
P100 GPU accelerator (12 GB card)^[388]		June 20, 2016	1× GP100	—		1126	1303		3,072	12		549	No	8,071‒9,340	4,036‒4,670		250	PCIe card
V100 GPU accelerator (mezzanine)^[389]^[390]^[391]	Volta	May 10, 2017	1× GV100-895-A1	—	5120	Unknown	1,455	HBM2	4,096	16 or 32	1,750	900	119,192	14,899	7,450	7.0	300	SXM card
V100 GPU accelerator (PCIe card)^[389]^[390]^[391]		June 21, 2017	1× GV100	—		Unknown	1,370			16 or 32	1,750	900	112,224	14,028	7,014		250	PCIe card
V100 GPU accelerator (PCIe FHHL card)		March 27, 2018	1× GV100	—		937	1,290			16	1,620	829.44	105,680	13,210	6,605		250	PCIe FHHL card
T4 GPU accelerator (PCIe card)^[392]^[393]	Turing	September 12, 2018	1× TU104-895-A1	—	2,560	585	1,590	GDDR6	256	16	5,000	320	64,800	8,100	Unknown	7.5	70	PCIe card
A2 GPU accelerator (PCIe card)^[394]	Ampere	November 10, 2021	1× GA107	—	1,280	1,440	1,770	GDDR6	128	16	6,252	200	18,124	4,531	140	8.6	40-60	PCIe card (half height, single-slot)
A10 GPU accelerator (PCIe card)^[395]		April 12, 2021	1× GA102-890-A1	—	9,216	885	1,695	GDDR6	384	24	6,252	600	124,960	31,240	976	8.6	150	PCIe card (single-slot)
A16 GPU accelerator (PCIe card)^[396]		April 12, 2021	4× GA107	—	4× 1,280	885	1,695	GDDR6	4× 128	4× 16	7,242	4× 200	4x 18,432	4× 4,608	1,084.8	8.6	250	PCIe card (dual-slot)
A30 GPU accelerator (PCIe card)^[397]		April 12, 2021	1× GA100	—	3,584	930	1,440	HBM2	3,072	24	1,215	933.1	165,120	10,320	5,161	8.0	165	PCIe card (dual-slot)
A40 GPU accelerator (PCIe card)^[398]		October 5, 2020	1× GA102	—	10,752	1,305	1,740	GDDR6	384	48	7,248	695.8	149,680	37,420	1,168	8.6	300	PCIe card (dual-slot)
A100 GPU accelerator (PCIe card)^[399]^[400]		May 14, 2020^[401]	1× GA100-883AA-A1	—	6,912	765	1410	HBM2	5,120	40 or 80	1,215	1,555	312,000	19,500	9,700	8.0	250	PCIe card (dual-slot)
H100 GPU accelerator (PCIe card)^[402]	Hopper	March 22, 2022^[403]	1× GH100^[404]	—	14,592	1,065	1,755 CUDA 1620 TC	HBM2E	5120	80	1,000	2,039	756,449	51,200	25,600	9.0	350	PCIe card (dual-slot)
H100 GPU accelerator (SXM card)	Hopper	March 22, 2022^[403]	1× GH100^[404]	—	16,896	1,065	1,980 CUDA 1,830 TC	HBM3	5,120	80	1,500	3,352	989,430	66,900	33,500	9.0	700	SXM card
L40 GPU accelerator^[405]	Ada Lovelace	October 13, 2022	1× AD102^[406]	—	18,176	735	2,490	GDDR6	384	48	2,250	864	362,066	90,516	1,414	8.9	300	PCIe card (dual-slot)
L4 GPU accelerator^[407]^[408]	Ada Lovelace	March 21, 2023^[409]	1x AD104^[410]	—	7,424	795	2,040	GDDR6	192	24	1,563	300	121,000	30,300	490	8.9	72	HHHL single slot PCIe card

Notes

To calculate the processing power see Tesla (microarchitecture)#Performance, Fermi (microarchitecture)#Performance, Kepler (microarchitecture)#Performance, Maxwell (microarchitecture)#Performance, or Pascal (microarchitecture)#Performance. A number range specifies the minimum and maximum processing power at, respectively, the base clock and maximum boost clock.
Core architecture version according to the CUDA programming guide.
GPU Boost is a default feature that increases the core clock rate while remaining under the card's predetermined power budget. Multiple boost clocks are available, but this table lists the highest clock supported by each card.^[363]
Specifications not specified by Nvidia assumed to be based on the GeForce 8800 GTX
Specifications not specified by Nvidia assumed to be based on the GeForce GTX 280
Specifications not specified by Nvidia assumed to be based on the Quadro FX 5800
With ECC on, a portion of the dedicated memory is used for ECC bits, so the available user memory is reduced by 12.5%. (e.g. 4 GB total memory yields 3.5 GB of user available memory.)

Console GPUs

More information Model, Launch ...

Model	Launch	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Memory clock (MHz)	Core config^1,2,3	Fillrate				Memory				Processing power (GFLOPS)³			Deep Learning	Latest supported API version
Model	Launch	Code name	Fab (nm)	Bus interface	Core clock (MHz)	Memory clock (MHz)	Core config^1,2,3	MOperations/s	MTexels/s	MPixels/s	MTri/s	Size (MB)	Bandwidth (GB/s)	Bus type	Bus width (bit)	Single precision	Half precision	Ray Tracing Performance	TOPS (INT8)	Direct3D	OpenGL	Vulkan	Other
XGPU (Xbox) ^[411]^[412]	November 15, 2001	NV2A	TSMC 150 nm	Integrated	233	200	4:2:8:4¹	5,800	1,864	932	116.5	64	6.4	DDR	128	13.9	-	N/A	N/A	8.1	1.4	N/A	N/A
RSX (PS3) ^[413]^[414] ^[415]	November 11, 2006	G70	Toshiba 90/65/40 nm/28 nm	FlexIO	550 (Pixel Shaders), 500 (Vertex Shaders)	650	24:8:24:8¹	13,200	12,000	4,400	275	256 256	15 (write) 20 (read) 20.8	XDR GDDR3	128	325.6 (w/Cell SPUs)	-	N/A	N/A	N/A	ES 1.1 w/Cg	N/A	N/A
NX-SoC (Nintendo Switch) ^[416]^[417]	March 3, 2017	GM20B	TSMC 20 nm	Integrated	76.8 307.2 384.0 460.8 (Undocked) 768.0 921.6 1267.2 (Docked)	1333 (Undocked) 1600 (Docked)	256:16:16²	39,321 157,286 196,608 235,929 393,216 471,859 648,806	1,228 4,915 6,144 7,372 12,288 14,745 20,275	1,228 4,915 6,144 7,372 12,288 14,745 20,275	probably ~500/1000	4096	21.3 (Undocked) 25.6 (Docked)	LPDDR4	64	39.3 157.2 196.6 235.9 393.2 471.8 648.8	78.6 314.5 393.2 471.8 786.4 943.7 1297.6	N/A	N/A		4.6^[418] ES 3.2^[419]	1.2^[420]	Nvidia NVN ^[421]
NX-SoC (Nintendo Switch) ^[416]^[417]	August 30, 2019	GM20B	TSMC 16 nm	Integrated		1333 (Undocked) 1600 (Docked)	256:16:16²	39,321 157,286 196,608 235,929 393,216 471,859 648,806	1,228 4,915 6,144 7,372 12,288 14,745 20,275	1,228 4,915 6,144 7,372 12,288 14,745 20,275	probably ~500/1000	4096	21.3 (Undocked) 25.6 (Docked)	LPDDR4X	64	39.3 157.2 196.6 235.9 393.2 471.8 648.8	78.6 314.5 393.2 471.8 786.4 943.7 1297.6	N/A	N/A		4.6^[418] ES 3.2^[419]	1.2^[420]	Nvidia NVN ^[421]

¹ Pixel shaders: vertex shaders: texture mapping units: render output units
² Unified shaders: Texture mapping units : Render output units
³ Unified shaders: Texture mapping units : Render output units : Ray tracing cores : Tensor Core

References

[1]
Benjamin Sun (26 March 2010). "Nvidia GeForce GTX 480 Video Card Review :: Streaming Multiprocessor". Motherboards.org. Archived from the original on 20 December 2011. Retrieved 14 March 2012.
[2]
"3D accelerator database". Vintage 3D. Archived from the original on 23 October 2018. Retrieved 21 July 2019.
[3]
"NVIDIA NV1 GPU Specs | TechPowerUp GPU Database". 25 August 2023.
[4]
"NVIDIA NV3 GPU Specs | TechPowerUp GPU Database". 25 August 2023.
[5]
"RIVA 128/ZX/TNT FAQ". Archived from the original on 16 June 2018. Retrieved 15 June 2018.
[6]
"NVIDIA NV4 GPU Specs | TechPowerUp GPU Database". 25 August 2023.
[7]
"NVIDIA NV5 GPU Specs | TechPowerUp GPU Database". 21 September 2023.
[8]
"4x AGP GeForce 256 Graphics Accelerator" (PDF). vgamuseum.info. Retrieved 26 September 2022.
[9]
"NVIDIA GeForce 256 DDR Specs". TechPowerUp. Retrieved 16 February 2021.
[10]
"NVIDIA GeForce2 MX PCI Specs". TechPowerUp. Retrieved 16 February 2021.
[11]
"NVIDIA NV15 GPU Specs | TechPowerUp GPU Database". Retrieved 15 April 2024.
[12]
"NVIDIA GeForce4 MX 420 PCI Specs". TechPowerUp. Retrieved 16 February 2021.
[13]
Archived copy Archived 2023-07-11 at the Wayback Machine
[14]
"NVIDIA GeForce4 MX 440-8x Specs". TechPowerUp. Retrieved 16 February 2021.
[15]
"mx4408x-64bit166-Mhz". ImgBB. Retrieved 25 December 2022.
[16]
"NVIDIA GeForce4 Ti 4200 Specs". TechPowerUp. Retrieved 16 February 2021.
[17]
"NVIDIA GeForce4 Ti 4200-8X Specs". TechPowerUp. Retrieved 20 November 2022.
[18]
"NVIDIA NV34 GPU Specs". TechPowerUp. Retrieved 16 February 2021.
[19]
"NVIDIA GeForce FX 5500 PCI Specs". TechPowerUp. Retrieved 16 February 2021.
[20]
"NVIDIA GeForce FX 5600 XT PCI Specs". TechPowerUp. Retrieved 16 February 2021.
[21]
"GeForce FX 5600". Nvidia.com. Archived from the original on 25 September 2015. Retrieved 11 December 2015.
[22]
"NVIDIA GeForce FX 5700 LE Specs". TechPowerUp. Retrieved 16 February 2021.
[23]
"NVIDIA GeForce FX 5800 Specs". TechPowerUp. Retrieved 16 February 2021.
[24]
"NVIDIA GeForce FX 5900 Specs". TechPowerUp. Retrieved 16 February 2021.
[25]
"NVIDIA and Activision Launch "Call of Duty" Bundle with GeForce FX 5900 Graphics Cards". Archived from the original on 1 April 2017. Retrieved 31 March 2017.
[26]
"NVIDIA GeForce FX 5950 Ultra Specs". TechPowerUp. Retrieved 16 February 2021.
[27]
"NVIDIA NV44 GPU Specs". TechPowerUp. Retrieved 16 February 2021.
[28]
"NVIDIA NV44B GPU Specs". TechPowerUp. Retrieved 16 February 2021.
[29]
"GeForce 6 Series-6200 - XFXforce.com". Archived from the original on 16 September 2008.
[30]
"GeForce 6200:Model PV-T44A-WANG - XFXforce.com". Archived from the original on 12 April 2008.
[31]
"Products GeForce 6200:Features - XFXforce.com". Archived from the original on 12 October 2007.
[32]
"NVIDIA NV43 GPU Specs". TechPowerUp. Retrieved 16 February 2021.
[33]
"Nvidia GeForce 6600 GT AGP". Techpowerup.com. Archived from the original on 16 April 2015. Retrieved 16 April 2015.
[34]
"NVIDIA NV40 GPU Specs". TechPowerUp. Retrieved 16 February 2021.
[35]
"NVIDIA NV41 GPU Specs". TechPowerUp. Retrieved 16 February 2021.
[36]
"NVIDIA NV42 GPU Specs". TechPowerUp. Retrieved 16 February 2021.
[37]
"映泰集团 :: V6802XA16 :: 产品规格". www.biostar.com.tw. Retrieved 12 December 2019.
[38]
"VGA/GPU Manufacturer - BIOSTAR Group". www.biostar.com.tw. Retrieved 12 December 2019.
[39]
"NVIDIA NV45 GPU Specs". TechPowerUp. Retrieved 16 February 2021.
[40]
"NVIDIA G72 GPU Specs". TechPowerUp. Retrieved 16 February 2021.
[41]
"NVIDIA G73 GPU Specs". TechPowerUp. Retrieved 16 February 2021.
[42]
"NVIDIA G70 GPU Specs". TechPowerUp. Retrieved 16 February 2021.
[43]
"NVIDIA G71 GPU Specs". TechPowerUp. Retrieved 16 February 2021.
[44]
"AMD and Nvidia Platforms Do Battle". Tomshardware.com. 18 July 2008. Retrieved 11 December 2015.
[45]
"Nvidia GF8600/8500/8300 details revealed". 12 April 2007. Archived from the original on 25 September 2007.
[46]
"Lots More Compute, a Leetle More Texturing - Nvidia's 1.4 Billion Transistor GPU: GT200 Arrives as the GeForce GTX 280 & 260". Anandtech.com. Archived from the original on 22 December 2015. Retrieved 11 December 2015.
[47]
"Digging deeper into the shader core - Nvidia's GeForce 8800 (G80): GPUs Re-architected for Direct3D 10". Anandtech.com. Archived from the original on 22 December 2015. Retrieved 11 December 2015.
[48]
Volker Rißka (3 November 2007). "Zwei neue GeForce 8800 GTS bis Dezember". Computerbase.de. Archived from the original on 18 July 2011. Retrieved 11 December 2015.
[49]
Nvidia Corporation (2008). "Nvidia GeForce 9300 GE". Archived from the original on 16 April 2009. Retrieved 22 February 2010.
[50]
"NVIDIA GeForce 9300 GE Specs | TechPowerUp GPU Database". Techpowerup.com. 22 August 2022. Retrieved 22 August 2022.
[51]
"NVIDIA GeForce GT 230 Specs". Retrieved 6 August 2018.
[52]
"Pegatron GT 230 Specs". TechPowerUp. 18 August 2023. Retrieved 18 August 2023.
[53]
"NVIDIA GeForce GTS 240 OEM | techPowerUp GPU Database". Archived from the original on 12 December 2016. Retrieved 6 August 2018.
[54]
"Zotac GeForce GTX 260 Amp² Edition 216 Shaders Review". 16 September 2008. Retrieved 6 August 2018.
[55]
"Nvidia GeForce GT 330 OEM | techPowerUp GPU Database". Techpowerup.com. Archived from the original on 18 October 2014. Retrieved 11 December 2015.
[56]
"NVIDIA GeForce GT 330 OEM Specs". TechPowerUp. Retrieved 23 March 2020.
[57]
"NVIDIA GeForce GT 330 OEM Specs". TechPowerUp. Retrieved 23 March 2020.
[58]
"NVIDIA GeForce GT 330 OEM Specs". TechPowerUp. Retrieved 23 March 2020.
[59]
"GeForce GT 340 OEM | GeForce". Nvidia.com. Archived from the original on 28 February 2012. Retrieved 11 December 2015.
[60]
"The GF100 Recap - Nvidia's GeForce GTX 480 and GTX 470: 6 Months Late, Was It Worth the Wait?". Anandtech.com. Archived from the original on 5 August 2011. Retrieved 11 December 2015.
[61]
"GF104: Nvidia Goes Superscalar - Nvidia's GeForce GTX 460: The $200 King". Anandtech.com. Archived from the original on 22 December 2015. Retrieved 11 December 2015.
[62]
"GeForce GTX 480 And 470: From Fermi And GF100 To Actual Cards!". Tomshardware.com. 27 March 2010. Retrieved 11 December 2015.
[63]
"The Khronos Group". 31 May 2022.
[64]
"Nvidia Fermi Compute Architecture Whitepaper" (PDF). Archived (PDF) from the original on 22 November 2009. Retrieved 17 April 2010. ( 855KB), page 11 of 22
[65]
"GF110: Fermi Learns Some New Tricks - Nvidia's GeForce GTX 580: Fermi Refined". Anandtech.com. Archived from the original on 13 January 2016. Retrieved 11 December 2015.
[66]
"Power, Temperature, and Noise - Nvidia's GeForce GTX 580: Fermi Refined". Anandtech.com. Archived from the original on 13 January 2016. Retrieved 11 December 2015.
[67]
"NVIDIA GeForce GT 530 OEM Specs". TechPowerUp. Retrieved 25 September 2022.
[68]
"NVIDIA GeForce GTX 560 SE Specs". TechPowerUp. 18 August 2023. Retrieved 18 August 2023.
[69]
"...and GF110s real name is: GF100B". GPU-Tech.org. Archived from the original on 13 January 2016. Retrieved 11 December 2015.
[70]
Ryan Smith (9 November 2010). "Nvidia's GeForce GTX 580: Fermi Refined". AnandTech. Archived from the original on 10 November 2010. Retrieved 9 November 2010.
[71]
"Products - Featured Products". EVGA. Archived from the original on 24 March 2012. Retrieved 11 December 2015.
[72]
"Nvidia GeForce GTX 580 1536 MB Review". TechPowerUp. 9 November 2010. Archived from the original on 22 December 2015. Retrieved 11 December 2015.
[73]
"NVIDIA GeForce GTX 650 Specs". TechPowerUp. Retrieved 9 December 2021.
[74]
"Nvidia GeForce GTX 680 Whitepaper.pdf" (PDF). Archived from the original (PDF) on April 17, 2012. ( 1405KB), page 6 of 29
[75]
"Nvidia Kepler not fully compliant with Direct3D 11.1". Guru3d.com. Archived from the original on 22 December 2015. Retrieved 11 December 2015.
[76]
"Nvidia Doesn't Fully Support DirectX 11.1 with Kepler GPUs, But…". 21 November 2012. Archived from the original on 3 September 2013.
[77]
"Nvidia GeForce GT 705 | techPowerUp GPU Database". Techpowerup.com. Archived from the original on 15 June 2014. Retrieved 11 December 2015.
[78]
"Nvidia GeForce GT 710 | techPowerUp GPU Database". Techpowerup.com. Archived from the original on 15 June 2014. Retrieved 11 December 2015.
[79]
"Nvidia GeForce GT 720 | techPowerUp GPU Database". Techpowerup.com. Archived from the original on 15 June 2014. Retrieved 11 December 2015.
[80]
"GT 730 | Specifications". GeForce.com. Archived from the original on 12 December 2015. Retrieved 11 December 2015.
[81]
"GeForce GT 730 1GB-ZOTAC". ZOTAC. Archived from the original on 19 July 2016. Retrieved 12 July 2017.
[82]
"EVGA - Products - EVGA GeForce GT 730 2GB (Low Profile) - 02G-P3-3733-KR". Archived from the original on 15 February 2017. Retrieved 29 April 2017.
[83]
"AFOX GTX 750 4 GB Specs". TechPowerUp. Retrieved 11 August 2021.
[84]
"NVIDIA GeForce GTX 760 Ti OEM Specs". Archived from the original on 30 May 2016. Retrieved 6 August 2018.
[85]
"Articles - EVGA GeForce GTX 780 6GB Step-Up Available Now!". EVGA. 21 March 2014. Archived from the original on 13 January 2016. Retrieved 11 December 2015.
[86]
"GeForce GTX780 Ti. Specifications". Geforce.com. Archived from the original on 12 December 2015. Retrieved 11 December 2015.
[87]
"Nvidia GeForce GTX 780 Ti has 2880 CUDA cores". Videocardz.com. 31 October 2013. Archived from the original on 22 December 2015. Retrieved 11 December 2015.
[88]
"PNY dévoile son nouveau foudre de guerre: la GeForce GTX 780 TI". Web-engage.augure.com. Archived from the original on 9 November 2013. Retrieved 11 December 2015.
[89]
"GeForce GTX TITAN". Geforce.com. Archived from the original on 5 December 2015. Retrieved 11 December 2015.
[90]
"TITAN Graphics Card". Nvidia.com. Archived from the original on 24 February 2013. Retrieved 11 December 2015.
[91]
"Nvidia's GeForce GTX Titan, Part 1: Titan For Gaming, Titan For Compute". Anandtech.com. Archived from the original on 4 December 2015. Retrieved 11 December 2015.
[92]
"Titan's Compute Performance (aka Ph.D Lust) - Nvidia's GeForce GTX Titan Review, Part 2: Titan's Performance Unveiled". Anandtech.com. Archived from the original on 22 December 2015. Retrieved 11 December 2015. the calculated fp64 peak of Titan is 1.5 TFlops. However, under heavy load in fp64 mode, the card may underclock below the listed 837MHz to remain within the power and thermal specifications
[93]
"售价21999元！NV旗舰GTX TITAN Z评测-太平洋电脑网". 5 June 2014. Retrieved 16 August 2020.
[94]
"NVIDIA GeForce GTX TITAN Z Specs". TechPowerUp. Retrieved 26 February 2020.
[95]
"Sprout Pro by HP". HP. Archived from the original on 9 January 2019. Retrieved 9 January 2019.
[96]
"Linux, Solaris, and FreeBSD driver 361.28 (long-lived branch release)". Nvidia. 9 February 2016. Archived from the original on 16 February 2016. Retrieved 10 February 2016.
[97]
"NVIDIA GeForce 945A Specs". Retrieved 6 August 2018.^{[dead link]}
[98]
"GTX 950 | Specifications". GeForce. Archived from the original on 12 December 2015. Retrieved 11 December 2015.
[99]
Shilov, Anton. "GIGABYTE Adds 75W GeForce GTX 950 to Lineup". www.anandtech.com.
[100]
"GeForce GTX 950 (OEM) | Specifications | GeForce". geforce.com. Archived from the original on 23 September 2018. Retrieved 9 January 2019.
[101]
"GTX 960 | Specifications". GeForce. Archived from the original on 12 December 2015. Retrieved 11 December 2015.
[102]
"GeForce GTX 960 (OEM) | Specifications | GeForce". geforce.com. Archived from the original on 23 September 2018. Retrieved 9 January 2019.
[103]
"GTX 970 | Specifications". GeForce. Archived from the original on 7 December 2015. Retrieved 11 December 2015.
[104]
Wasson, Scott (26 January 2015). "Nvidia: the GeForce GTX 970 works exactly as intended, A look inside the card's unusual memory config". The Tech Report. p. 1. Archived from the original on 28 January 2015. Retrieved 26 January 2015.
[105]
"GTX 980 | Specifications". GeForce. Archived from the original on 8 December 2015. Retrieved 11 December 2015.
[106]
"GTX 980 Ti | Specifications". GeForce. Archived from the original on 11 December 2015. Retrieved 11 December 2015.
[107]
"GTX TITAN X | Specifications". GeForce. Archived from the original on 5 December 2015. Retrieved 11 December 2015.
[108]
Nvidia. "GTX 1080 Graphics Card". Archived from the original on 7 May 2016. Retrieved 7 May 2016.
[109]
Smith, Ryan. "The Nvidia GeForce GTX 1080 & GTX 1070 Founders Editions Review: Kicking Off the FinFET Generation". Archived from the original on 23 July 2016. Retrieved 21 July 2016.
[110]
"The GeForce GTX 1060 Founders Edition & ASUS Strix GTX 1060 Review". Archived from the original on 18 February 2017. Retrieved 17 February 2017.
[111]
"NVIDIA GeForce GT 1010 Specs". TechPowerUp. Retrieved 14 February 2021.
[112]
"NVIDIA GeForce GT 1010 DDR4 Specs". TechPowerUp. Retrieved 14 February 2021.
[113]
"GeForce GT 1030 | Specifications | GeForce". Archived from the original on 20 May 2017. Retrieved 17 May 2017.
[114]
"GeForce GT 1030: The DDR4 Abomination Benchmarked". 9 July 2018. Archived from the original on 22 August 2018. Retrieved 22 August 2018.
[115]
"Overview GeForce GT 1030 AERO ITX 2G OC". Archived from the original on 30 June 2017. Retrieved 26 May 2017.
[116]
"::Palit Products - GeForce GT 1030 ::". Archived from the original on 14 June 2017. Retrieved 26 May 2017.
[117]
"GeForce GTX 1050 Graphics Card". nvidia.com. Archived from the original on 22 December 2016. Retrieved 27 December 2018.
[118]
"GTX 1060 Graphics Card". nvidia.com. Archived from the original on 16 August 2016. Retrieved 18 August 2016.
[119]
"NVIDIA Preps Cut Down, 5 GB GTX 1060 Graphics Card For Cafes". wccftech.com. 26 December 2017. Archived from the original on 20 December 2018. Retrieved 29 December 2018.
[120]
"NVIDIA launches GeForce GTX 1080 11 Gbps and GTX 1060 9 Gbps". videocardz.com. 20 April 2017. Archived from the original on 2 September 2018. Retrieved 29 December 2018.
[121]
"Gigabyte may be readying a GeForce GTX 1060 with GDDR5X". hexus.net. 19 October 2018. Archived from the original on 30 December 2018. Retrieved 29 December 2018.
[122]
"GEFORCE GTX 1070 FAMILY". nvidia.com. Archived from the original on 27 October 2017. Retrieved 29 December 2018.
[123]
"NVIDIA Unveils GeForce GTX 1070 with GDDR5X Memory". techpowerup.com. 5 December 2018. Archived from the original on 30 December 2018. Retrieved 29 December 2018.
[124]
W1zzard (21 June 2016). "Nvidia GeForce GTX 1080 SLI". TechPowerUp. Archived from the original on 24 June 2016. Retrieved 21 June 2016.
[125]
Nvidia. "GTX 1080 Graphics Card". Archived from the original on 22 December 2016. Retrieved 7 May 2016.
[126]
W1zzard (17 May 2016). "Nvidia GeForce GTX 1080 8 GB". TechPowerUp. Archived from the original on 21 May 2016. Retrieved 17 May 2016.
[127]
Nvidia. "GeForce GTX 1080 Ti Graphics Card". Archived from the original on 1 March 2017. Retrieved 1 March 2017.
[128]
Nvidia. "Nvidia TITAN X Graphics Card". Archived from the original on 22 July 2016. Retrieved 21 July 2016.
[129]
Nvidia. "TITAN Xp Graphics Card with Pascal Architecture". Archived from the original on 6 April 2017. Retrieved 6 April 2017.
[130]
Nvidia. "Nvidia TITAN V Graphics Card". Archived from the original on 8 December 2017. Retrieved 8 December 2017.
[131]
Smith, Ryan. "NVIDIA Unveils & Gives Away New Limited Edition 32GB Titan V "CEO Edition"". Archived from the original on 30 July 2018. Retrieved 8 August 2018.
[132]
"NVIDIA TITAN V - CEO Edition". TechPowerUp. Retrieved 8 August 2018.^{[dead link]}
[133]
"NVIDIA officially launches GeForce GTX 1630 graphics card". VideoCardz.com. Retrieved 28 June 2022.
[134]
"NVIDIA GeForce GTX 1650 Graphics Card". NVIDIA. Archived from the original on 23 April 2019. Retrieved 23 April 2019.
[135]
"NVIDIA's GeForce GTX 1650 GDDR6 Released: GDDR6 Reaching Price Parity With GDDR5". Anandtech. Retrieved 6 April 2020.
[136]
"NVIDIA GeForce GTX 1650 TU106 Specs". TechPowerUp. Retrieved 14 December 2021.
[137]
"NVIDIA GeForce GTX 1650 SUPER Graphics Card". NVIDIA. Retrieved 29 October 2019.
[138]
"NVIDIA Announces GeForce GTX 1650 Super: Launching November 22nd". Retrieved 29 October 2019.
[139]
"GTX 1660, 1650 Super boost speeds for Nvidia's cheapest gaming cards". Retrieved 29 October 2019.
[140]
"The GeForce 16 Series Graphics Cards are Here". NVIDIA. Archived from the original on 25 March 2019. Retrieved 23 March 2019.
[141]
"NVIDIA GeForce GTX 1660 SUPER Graphics Card". NVIDIA. Retrieved 29 October 2019.
[142]
"NVIDIA GeForce RTX 1660 Graphics Card". NVIDIA. Archived from the original on 22 February 2019. Retrieved 22 February 2019.
[143]
"NVIDIA GeForce RTX 2060 Graphics Card". NVIDIA. Archived from the original on 7 January 2019. Retrieved 8 January 2019.
[144]
"NVIDIA GeForce RTX 2060 TU104 Specs". TechPowerUp. Retrieved 18 February 2020.
[145]
"NVIDIA launches GeForce RTX 2060 with 12GB and TU106-300 GPU, overpriced gaming GPU for miners". videocardz. Retrieved 9 July 2021.
[146]
"The GeForce RTX 2070 Super & RTX 2060 Super Review". Anandtech. 2 July 2019. Archived from the original on 2 July 2019. Retrieved 2 July 2019.
[147]
"Your Graphics, Now with SUPER Powers". Archived from the original on 2 July 2019. Retrieved 2 July 2019.
[148]
"Introducing NVIDIA GeForce RTX 2070 Graphics Card". NVIDIA. Archived from the original on 20 August 2018. Retrieved 20 August 2018.
[149]
"Nvidia Turing architecture deep dive". pcgamer.com. Archived from the original on 18 September 2018. Retrieved 27 September 2018.
[150]
"Your Graphics, Now with SUPER Powers". Archived from the original on 2 July 2019. Retrieved 2 July 2019.
[151]
"NVIDIA GeForce RTX 2080 Founders Edition Graphics Card". NVIDIA. Archived from the original on 20 August 2018. Retrieved 20 August 2018.
[152]
"Nvidia Can Automatically Overclock Your GeForce RTX in 20 Minutes". Pcmag. Archived from the original on 20 September 2018. Retrieved 20 September 2018.
[153]
"Your Graphics, Now with SUPER Powers". Archived from the original on 2 July 2019. Retrieved 2 July 2019.
[154]
"Graphics Reinvented: NVIDIA GeForce RTX 2080 Ti Graphics Card". NVIDIA. Archived from the original on 20 August 2018. Retrieved 20 August 2018.
[155]
"TITAN RTX Ultimate PC Graphics Card with Turing: NVIDIA". nvidia.com. Archived from the original on 26 December 2018. Retrieved 27 December 2018.
[156]
"NVIDIA GeForce RTX 3050 Graphics Card Announcement". NVIDIA (in Finnish). Retrieved 4 January 2022.
[157]
Klotz, Aaron (18 July 2022). "OEM Exclusive RTX 3050 Confirmed With Cutdown Specs". Tom's Hardware. Retrieved 19 September 2022.
[158]
"NVIDIA Announces the GeForce RTX 30 Series". Mugens-Reviews (in German). Retrieved 6 January 2022.
[159]
"NVIDIA GeForce RTX 3060 Graphics Card Announcement". NVIDIA. Retrieved 12 January 2021.
[160]
"NVIDIA officially introduces GeForce RTX 3060 8GB and RTX 3060 Ti GDDR6X". VideoCardz.com. Retrieved 29 October 2022.
[161]
Mujtaba, Hassan (25 September 2021). "Custom GALAX & Gainward GeForce RTX 3060 Cards With NVIDIA Ampere GA104 GPUs Listed". Wccftech. Retrieved 25 September 2021.
[162]
"NVIDIA GeForce RTX 3060 Ti Graphics Card". Retrieved 1 December 2020.
[163]
"NVIDIA GeForce RTX 3070 Graphics Card". NVIDIA. Retrieved 6 September 2020.
[164]
Smith, Ryan (1 September 2020). "NVIDIA Announces the GeForce RTX 30 Series: Ampere For Gaming, Starting With RTX 3080 & RTX 3090". AnandTech. Retrieved 2 September 2020.
[165]
"GeForce RTX 3070 Availability Update". NVIDIA.
[166]
"NVIDIA GeForce RTX 3070 Family". NVIDIA. Retrieved 2 June 2021.
[167]
"NVIDIA GeForce RTX 3080 Graphics Card". NVIDIA. Retrieved 6 September 2020.
[168]
"NVIDIA GeForce RTX 3080 Family of Graphics Card". NVIDIA. Retrieved 2 June 2021.
[169]
"NVIDIA GeForce RTX 3090 Graphics Card". NVIDIA. Retrieved 6 September 2020.
[170]
"GeForce RTX 3090 Ti Is Here: The Fastest GeForce GPU For The Most Demanding Creators & Gamers". NVIDIA. Retrieved 2 April 2022.
[171]
"NVIDIA GeForce RTX 3090 Ti Specs". TechPowerUp. Retrieved 2 April 2022.
[172]
"CUDA C++ Programming Guide". docs.nvidia.com. Retrieved 20 September 2022.
[173]
"Creativity At The Speed of Light: GeForce RTX 40 Series Graphics Cards Unleash Up To 2X Performance in 3D Rendering, AI, and Video Exports For Gamers and Creators". NVIDIA.
[174]
"Nvidia Video Codec SDK". 23 August 2013.
[175]
Chuong Nguyen (21 September 2022). "Nvidia kills off NVLink on RTX 4090". Windows Central. Retrieved 1 January 2023.
[176]
"Jensen Confirms: NVLink Support in Ada Lovelace is Gone". TechPowerUp. 21 September 2022. Retrieved 21 November 2022.
[177]
"NVIDIA GeForce RTX 4060 Ti & 4060 Graphics Cards". NVIDIA. Retrieved 18 May 2023.
[178]
"Nvidia's Ada Lovelace GPU generation: $1,599 for RTX 4090, $899 and up for 4080". Ars Technica. 20 September 2022. Retrieved 27 July 2023.
[179]
"NVIDIA GeForce RTX 4070 Family". NVIDIA. Retrieved 13 April 2023.
[180]
"NVIDIA GeForce RTX 4070 SUPER Specs". TechPowerUp. 9 January 2024. Retrieved 9 January 2024.
[181]
"NVIDIA GeForce RTX 4070 Family Graphics Cards". NVIDIA. Retrieved 9 January 2024.
[182]
"NVIDIA "accidentally" confirms GeForce RTX 4070 Ti GPU specifications". VideoCardz. 30 December 2022. Retrieved 31 December 2022.
[183]
"NVIDIA GeForce RTX 4070 Ti SUPER Specs". TechPowerUp. 9 January 2024. Retrieved 9 January 2024.
[184]
"NVIDIA GeForce RTX 4080 Graphics Cards". NVIDIA. Retrieved 20 September 2022.
[185]
Warren, Tom (14 October 2022). "Nvidia says it's "unlaunching" the 12GB RTX 4080 after backlash". The Verge. Retrieved 14 October 2022.
[186]
"Unlaunching The 12GB 4080". NVIDIA. Retrieved 14 October 2022.
[187]
"NVIDIA GeForce RTX 4080 SUPER Specs". TechPowerUp. 9 January 2024. Retrieved 9 January 2024.
[188]
"NVIDIA GeForce RTX 4080 Family Graphics Cards". NVIDIA. Retrieved 9 January 2024.
[189]
"GeForce RTX 4090 D 显卡". NVIDIA (in Chinese (China)). Retrieved 29 December 2023.
[190]
"NVIDIA GeForce RTX 4090D Specs". TechPowerUp. 29 December 2023. Retrieved 29 December 2023.
[191]
"NVIDIA GeForce RTX 4090 Graphics Cards". NVIDIA. Retrieved 20 September 2022.
[192]
"NVIDIA Ada GPU Architecture" (PDF). Retrieved 8 October 2022.
[193]
"GeForce 8200M G mGPU. Specifications". Geforce.com. Archived from the original on 22 December 2015. Retrieved 11 December 2015.
[194]
"Hardware | GeForce". Nvidia.com. Archived from the original on 12 February 2012. Retrieved 11 December 2015.
[195]
"Not Arrandale, but Better Graphics - Apple's 13-inch MacBook Pro (Early 2010) Reviewed: Shaking the CPU/GPU Balance". Anandtech.com. Archived from the original on 13 January 2016. Retrieved 11 December 2015.
[196]
"Nvidia's GeForce 400M Mobile GPUs: 7 New Fermis Introduced - Page 3". Hardwarecanucks.com. 2 September 2010. Archived from the original on 22 December 2015. Retrieved 11 December 2015.
[197]
"Graphics Cards, Gaming, Laptops, and Virtual Reality from NVIDIA GeForce". Archived from the original on 29 June 2011. Retrieved 1 July 2011.
[198]
"GeForce 610M Graphics Card with Optimus technology | Nvidia". Nvidia.in. Archived from the original on 8 December 2015. Retrieved 11 December 2015.
[199]
"Nvidia's GeForce 600M series: Mobile Kepler and Fermi Die Shrinks". Anandtech.com. Archived from the original on 19 September 2015. Retrieved 11 December 2015.
[200]
"GeForce GT 630M Graphics Card with Optimus technology | Nvidia". Nvidia.in. Archived from the original on 4 December 2015. Retrieved 11 December 2015.
[201]
"GT 630M | Specifications". GeForce. Archived from the original on 9 December 2015. Retrieved 11 December 2015.
[202]
"GeForce GT 635M GPU with Nvidia Optimus technology | Nvidia". Nvidia.in. Archived from the original on 22 December 2015. Retrieved 11 December 2015.
[203]
"GT 635M | Specifications". GeForce. Archived from the original on 19 December 2015. Retrieved 11 December 2015.
[204]
"Acer Aspire TimelineU M3: Life on the Kepler Verge". Anandtech.com. Archived from the original on 22 December 2015. Retrieved 11 December 2015.
[205]
RPL (18 March 2012). "HP Lists New Ivy Bridge 2012 Mosaic Design Laptops, Available April 8th". Laptop Reviews. Archived from the original on 23 May 2013. Retrieved 11 December 2015.
[206]
"Help Me Choose: Video Cards | Dell". Content.dell.com. Archived from the original on 2 November 2012. Retrieved 11 December 2015.
[207]
"Lenovo unveils six mainstream consumer laptops (and one desktop replacement)". Engadget.com. 8 January 2012. Archived from the original on 22 December 2015. Retrieved 11 December 2015.
[208]
"Asus G75VW Ivy Bridge 660M Review! and owners lounge | Page 4 | NotebookReview". Forum.notebookreview.com. Archived from the original on 7 January 2015. Retrieved 11 December 2015.
[209]
"CUDA GPUs - Compute Capacity | NVIDIA Developer". Nvidia. 4 June 2012. Retrieved 11 April 2023.
[210]
"NVIDIA GK208 GPU Specs". TechPowerUP. Retrieved 11 April 2023.
[211]
"Nvidia GeForce GT 740M - NotebookCheck.net Tech". Notebookcheck.net. 17 March 2013. Archived from the original on 17 December 2015. Retrieved 11 December 2015.
[212]
"GT 755M | Specifications". GeForce. Archived from the original on 8 December 2015. Retrieved 11 December 2015.
[213]
"820M | Specifications". GeForce. Archived from the original on 19 December 2015. Retrieved 11 December 2015.
[214]
"Nvidia GeForce 820M | techPowerUp GPU Database". Techpowerup.com. Archived from the original on 30 December 2014. Retrieved 11 December 2015.
[215]
"Nvidia GeForce 825M - NotebookCheck.net Tech". Notebookcheck.net. 13 March 2014. Archived from the original on 26 November 2015. Retrieved 11 December 2015.
[216]
"830M | Specifications". GeForce. Archived from the original on 10 December 2015. Retrieved 11 December 2015.
[217]
"840M | Specifications". GeForce. Archived from the original on 17 December 2015. Retrieved 11 December 2015.
[218]
"N551JQ | Notebooks | ASUS Global". Asus.com. 29 May 2012. Archived from the original on 19 March 2015. Retrieved 11 December 2015.
[219]
Jentsch, Sebastian (9 June 2015). "Dell Inspiron 17 7746 (2015) Notebook Review". Notebookcheck. Archived from the original on 16 August 2017. Retrieved 19 March 2019.
[220]
"NVIDIA GeForce 845M Specs". TechPowerUp. Retrieved 19 March 2019.
[221]
"NVIDIA GeForce 845M Specs". TechPowerUp. Retrieved 19 March 2019.
[222]
"GTX 850M | Specifications". GeForce. Archived from the original on 6 December 2015. Retrieved 11 December 2015.
[223]
"GTX 860M | Specifications". GeForce. Archived from the original on 4 December 2015. Retrieved 11 December 2015.
[224]
"GTX 870M | Specifications". GeForce. Archived from the original on 19 December 2015. Retrieved 11 December 2015.
[225]
"GTX 880M | Specifications". GeForce. Archived from the original on 10 December 2015. Retrieved 11 December 2015.
[226]
"M3N930M-EN". Aetina. Archived from the original on 3 July 2015. Retrieved 11 December 2015.
[227]
"M3N940M-FN". Aetina. Archived from the original on 3 July 2015. Retrieved 11 December 2015.
[228]
"Nvidia GeForce 940MX Specs". TechPowerUp. Retrieved 27 March 2021.
[229]
"Nvidia GeForce 940MX Specs". TechPowerUp. Retrieved 22 July 2020.
[230]
"M3N950M-FN". Aetina. Archived from the original on 16 March 2015. Retrieved 11 December 2015.
[231]
"M3N960M-JN". Aetina. Archived from the original on 15 March 2015. Retrieved 11 December 2015.
[232]
"GTX 965M". GeForce. Archived from the original on 8 December 2015. Retrieved 11 December 2015.
[233]
"Eurocom Configure Model". Eurocom.com. Archived from the original on 27 November 2015. Retrieved 11 December 2015.
[234]
"GTX 970M | Specifications". GeForce. Archived from the original on 9 December 2015. Retrieved 11 December 2015.
[235]
"GTX 980M | Specifications". GeForce. Archived from the original on 13 December 2015. Retrieved 11 December 2015.
[236]
"GTX 980 | Specifications". GeForce. Archived from the original on 5 December 2015. Retrieved 11 December 2015.
[237]
"GeForce GTX 10-Series Notebooks". geforce.com. Archived from the original on 21 October 2016. Retrieved 16 August 2016.
[238]
"NVIDIA Launches GeForce GTX 1050 TI & GTX 1050 For Laptops". anandtech.com. Archived from the original on 27 December 2018. Retrieved 27 December 2018.
[239]
"Video Encode and Decode GPU Support Matrix". Nvidia. Archived from the original on 10 July 2017. Retrieved 7 May 2017.
[240]
"NVIDIA GeForce GTX 1650 Mobile Specs". TechPowerUp. Retrieved 2 March 2020.
[241]
"NVIDIA GeForce GTX 1650 Max-Q Specs". TechPowerUp. Retrieved 2 March 2020.
[242]
"NVIDIA GeForce GTX 1660 Mobile Specs". TechPowerUp. Retrieved 2 March 2020.
[243]
"NVIDIA GeForce GTX 1660 Ti Max-Q Specs". TechPowerUp. Retrieved 2 March 2020.
[244]
"NVIDIA GeForce GTX 1660 Ti Mobile Specs". TechPowerUp. Retrieved 4 February 2020.
[245]
"NVIDIA GeForce GTX 1660 Ti Mobile Specs". TechPowerUp. Retrieved 2 March 2020.
[246]
"NVIDIA GeForce MX250 i MX230 – dwie "nowe" grafiki do laptopów". Dobre Programy (in Polish). 21 February 2019.
[247]
Smith, Ryan. "NVIDIA Announces GeForce RTX 2050, MX570, and MX550 For Laptops: 2022's Entry Level GeForce". www.anandtech.com. Retrieved 18 December 2021.
[248]
"NVIDIA GeForce RTX 2050 Mobile Specs". TechPowerUp. Retrieved 18 December 2021.
[249]
"NVIDIA GeForce RTX 2060 Mobile Specs". TechPowerUp. Retrieved 17 September 2019.
[250]
"NVIDIA GeForce RTX 2060 Max-Q Specs". TechPowerUp. Retrieved 31 August 2020.
[251]
"NVIDIA GeForce RTX 2070 Mobile Specs". TechPowerUp. Retrieved 17 September 2019.
[252]
"NVIDIA GeForce RTX 2070 Max-Q Specs". TechPowerUp. Retrieved 17 September 2019.
[253]
"NVIDIA GeForce RTX 2070 SUPER Mobile Specs". TechPowerUp. Retrieved 17 April 2020.
[254]
"NVIDIA GeForce RTX 2070 SUPER Max-Q Specs". TechPowerUp. Retrieved 3 April 2020.
[255]
"NVIDIA GeForce RTX 2080 Mobile Specs". TechPowerUp. Retrieved 17 September 2019.
[256]
"NVIDIA GeForce RTX 2080 Max-Q Specs". TechPowerUp. Retrieved 17 September 2019.
[257]
"NVIDIA GeForce RTX 2080 SUPER Mobile Specs". TechPowerUp. Retrieved 17 April 2020.
[258]
"NVIDIA GeForce RTX 2080 SUPER Max-Q Specs". TechPowerUp. Retrieved 3 April 2020.
[259]
Hinum, Klaus. "NVIDIA GeForce RTX 3050 Mobile GPU - Benchmarks and Specs". Notebookcheck. Retrieved 17 January 2021.
[260]
"NVIDIA GeForce RTX 3050 Mobile Specs - TechPowerUp GPU Database". TechPowerUp. Retrieved 17 April 2021.
[261]
Hinum, Klaus. "NVIDIA GeForce RTX 3050 Ti Mobile GPU - Benchmarks and Specs". Notebookcheck. Retrieved 17 April 2021.
[262]
"NVIDIA GeForce RTX 3050 Ti Mobile Specs - TechPowerUp GPU Database". TechPowerUp. Retrieved 17 April 2021.
[263]
Hinum, Klaus. "NVIDIA GeForce RTX 3060 Mobile GPU - Benchmarks and Specs". Notebookcheck. Retrieved 17 January 2021.
[264]
"NVIDIA GeForce RTX 3060 Mobile Specs - TechPowerUp GPU Database". TechPowerUp. Retrieved 17 April 2021.
[265]
Hinum, Klaus. "NVIDIA GeForce RTX 3070 Mobile GPU - Benchmarks and Specs". Notebookcheck. Retrieved 17 January 2021.
[266]
"NVIDIA GeForce RTX 3070 Mobile Specs". TechPowerUp. Retrieved 18 January 2021.
[267]
Herter, Marc (13 August 2021). "Lenovo Legion 5 Pro 16 review: A gaming laptop with a bright 165-Hz display". Notebookcheck. Retrieved 13 September 2021.
[268]
"NVIDIA GeForce RTX 3070 Ti Mobile Specs | TechPowerUp GPU Database". TechPowerUp. Retrieved 24 September 2022.
[269]
"NVIDIA GeForce RTX 3080 Mobile Specs". TechPowerUp. Retrieved 17 January 2021.
[270]
Hinum, Klaus. "NVIDIA GeForce RTX 3080 Mobile GPU - Benchmarks and Specs". Notebookcheck. Retrieved 17 January 2021.
[271]
"NVIDIA GeForce RTX 3080 Ti Mobile Specs | TechPowerUp GPU Database". TechPowerUp. Retrieved 24 September 2022.
[272]
"Introducing NVIDIA DLSS 3". NVIDIA. Retrieved 4 January 2023.
[273]
"Improve Shader Performance and In-Game Frame Rates with Shader Execution Reordering". NVIDIA Technical Blog. 13 October 2022. Retrieved 4 January 2023.
[274]
"GeForce RTX 40 Series Laptops: NVIDIA Ada Lovelace Breaks Energy-Efficiency Barrier, Supercharges 170+ Laptop Designs For Gamers & Creators". NVIDIA. Retrieved 4 January 2023.
[275]
"NVIDIA announces GeForce RTX 40 Laptop GPU series, RTX 4090 with 9728 CUDAs and 16GB GDDR6 memory". videocardz. 3 January 2023. Retrieved 24 February 2023.
[276]
Oh, Nate (28 November 2017). "NVIDIA Releases Maxwell-Based Geforce MX130 & MX110 Mobile GPUs". AnandTech. Archived from the original on 28 November 2017. Retrieved 28 November 2017.
[277]
"Geforce MX110 Specifications". NVIDIA. Archived from the original on 24 December 2017. Retrieved 28 November 2017.
[278]
"Geforce MX130 Specifications". NVIDIA. Archived from the original on 25 December 2017. Retrieved 28 November 2017.
[279]
"NVIDIA GeForce MX130 Specs". TechPowerUp. Retrieved 30 June 2022.
[280]
"NVIDIA GeForce MX150". NotebookCheck. Archived from the original on 7 December 2017. Retrieved 8 December 2017.
[281]
"Comparison: NVIDIA GeForce MX150 vs NVIDIA GeForce 940MX". NotebookCheck. 21 August 2017. Archived from the original on 27 October 2017. Retrieved 27 October 2017.
[282]
"NVIDIA Announces GeForce MX150: Entry-Level Pascal for Laptops, Just in Time for Computex". AnandTech. Archived from the original on 27 October 2017. Retrieved 27 October 2017.
[283]
"NVIDIA GeForce MX230". NotebookCheck. Retrieved 15 October 2019.
[284]
"NVIDIA GeForce MX250". NotebookCheck. Retrieved 15 October 2019.
[285]
"NVIDIA GeForce MX250 Specs". TechPowerUp. Retrieved 3 March 2020.
[286]
Redaktion. "Graphics Card Comparison - Head 2 Head". NotebookCheck. Retrieved 17 February 2020.
[287]
Smith, Ryan (14 February 2020). "NVIDIA Quietly Reveals GeForce MX350 & MX330: 2020's Entry-Level Laptop GeForce". AnandTech. Retrieved 17 February 2020.
[288]
"NVIDIA GeForce MX450 Laptop Graphics". NVIDIA.
[289]
"NVIDIA GeForce MX450". NotebookCheck.
[290]
"NVIDIA GeForce MX550 vs NVIDIA GeForce MX570". NotebookCheck. Retrieved 23 May 2022.
[291]
"GeForce MX550 Dedicated Graphics for Laptops". NVIDIA. Archived from the original on 7 June 2022. Retrieved 30 June 2022.
[292]
Smith, Ryan (17 December 2021). "NVIDIA Announces GeForce RTX 2050, MX570, and MX550 For Laptops: 2022's Entry Level GeForce". AnandTech. Retrieved 18 December 2021.
[293]
"NVIDIA GeForce MX550 Specs". TechPowerUp. Retrieved 23 May 2022.
[294]
"GeForce MX570 Dedicated Graphics for Laptops". NVIDIA. Retrieved 30 June 2022.
[295]
"NVIDIA GeForce MX570 Specs". TechPowerUp. Retrieved 23 May 2022.
[296]
"Quadro-Powered All-In-One Workstations" (PDF). Nvidia. Archived (PDF) from the original on 24 June 2013. Retrieved 11 December 2015.
[297]
"Quadro FX series". Hgpu.org. 25 October 2010. Archived from the original on 13 January 2016. Retrieved 11 December 2015.
[298]
"Nvidia Quadro CX is the accelerator for Adobe Creative Suite 4". Nvidia.com. Archived from the original on 22 December 2015. Retrieved 11 December 2015.
[299]
"NVIDIA Quadro Plex 7000 Specs". Retrieved 26 March 2018.^{[dead link]}
[300]
"Quadro 410 Entry Level Professional Graphics Card". Nvidia. 8 December 2010. Archived from the original on 22 December 2015. Retrieved 11 December 2015.
[301]
"NVIDIA Quadro K420 2GB". Archived from the original on 3 September 2018. Retrieved 3 September 2018.
[302]
"NVIDIA Quadro K2200 Graphics Card in Review". Archived from the original on 15 August 2020. Retrieved 16 August 2020.
[303]
"【開箱】搭載24GB記憶體！？NVIDIA Quadro之最M6000 專業繪圖卡登場！". Retrieved 16 August 2020.
[304]
"【開箱】術有專攻！NVIDIA Quadro Maxwell 專業繪圖卡上市！". Retrieved 16 August 2020.
[305]
"Real Interactive Expression: Nvidia Quadro M6000" (PDF). Images.nvidia.com. Archived (PDF) from the original on 4 March 2016. Retrieved 11 December 2015.
[306]
"GPU Database". techPowerUp. Retrieved 7 May 2017.^{[dead link]}
[307]
"【開箱】專業設計領域，有你有我！麗臺NVIDIA Quadro P2200 繪圖卡新品上市。". Retrieved 16 August 2020.
[308]
"Nvidia Quadro GV100 Data Sheet" (PDF). NVIDIA. Archived (PDF) from the original on 1 April 2018. Retrieved 6 November 2018.
[309]
"NVIDIA RTX in Professional Workstations". NVIDIA.
[310]
"NVIDIA T400 datasheet" (PDF). www.nvidia.com.
[311]
"NVIDIA T400 Specs | TechPowerUp GPU Database". Retrieved 15 April 2024.
[312]
"NVIDIA T600 datasheet" (PDF). www.nvidia.com.
[313]
"NVIDIA T600 Specs | TechPowerUp GPU Database". Retrieved 15 April 2024.
[314]
"NVIDIA T1000 datasheet" (PDF). www.nvidia.com.
[315]
"NVIDIA T1000 Specs | TechPowerUp GPU Database". Retrieved 15 April 2024.
[316]
"Take Your Design Workflows to the Next Level". NVIDIA.
[317]
"NVIDIA RTX A4000 Tensor Core Product Brief" (PDF). www.nvidia.com.
[318]
"Discover NVIDIA RTX A2000 | Graphics Card | pny.com". www.pny.com.
[319]
Schilling, Andreas (22 March 2022). "NVIDIA aktualisiert sein Notebook-GPU-Lineup plus neue Desktop-Karte". Hardwareluxx.
[320]
"NVIDIA RTX A4000 Graphics Card". NVIDIA.
[321]
"NVIDIA RTX A4000 Tensor Core Product Brief" (PDF). www.nvidia.com.
[322]
"Discover NVIDIA RTX A4000 GPU | pny.com". www.pny.com.
[323]
"NVIDIA RTX A4500 Datasheet" (PDF). Retrieved 15 April 2024.
[324]
"NVIDIA RTX A5000 Graphics Card". NVIDIA.
[325]
"NVIDIA RTX A5000 Tensor Core Product Brief" (PDF). www.nvidia.com.
[326]
"Discover NVIDIA RTX A5000 | Professional GPU | pny.com". www.pny.com.
[327]
"NVIDIA RTX A6000 Powered by Ampere Architecture". NVIDIA.
[328]
"NVIDIA RTX A6000 Tensor Core Product Brief" (PDF). www.nvidia.com.
[329]
"Discover NVIDIA RTX A6000 | Graphics Card | pny.com". www.pny.com.
[330]
"NVIDIA RTX 4000 SFF Ada Generation Graphics Card" (PDF). Nvidia. Retrieved 10 October 2023.
[331]
"NVIDIA RTX 4000 Ada Generation Datasheet". NVIDIA. Retrieved 10 October 2023.
[332]
"NVIDIA RTX 4500 Ada Generation Graphics Card". NVIDIA. Retrieved 10 October 2023.
[333]
"NVIDIA RTX 5000 Ada Generation Datasheet". NVIDIA. Retrieved 10 October 2023.
[334]
"NVIDIA RTX 5880 Ada Generation". NVIDIA. Retrieved 5 January 2024.
[335]
"NVIDIA RTX 6000 Ada Generation" (PDF). NVIDIA. Retrieved 10 October 2023.
[336]
"Nvidia Quadro NVS Technical Specifications" (PDF). Nvidia press release. Archived (PDF) from the original on 14 September 2012. Retrieved 15 May 2014.
[337]
"Nvidia Quadro2 Go". Nvidia.com. 14 August 2001. Archived from the original on 8 December 2015. Retrieved 11 December 2015.
[338]
"NVIDIA Quadro2 Go Specs". TechPowerUp. Retrieved 29 April 2021.
[339]
"Press Release". 11 February 2005. Archived from the original on 11 February 2005. Retrieved 29 April 2021.
[340]
"Nvidia Mobile GPU Solutions". Nvidia.com. Archived from the original on 7 September 2008. Retrieved 11 December 2015.
[341]
"The Standard for Mobile Workstations". Nvidia.com. Archived from the original on 4 July 2008. Retrieved 11 December 2015.
[342]
"Nvidia Quadro4 Go GL". Nvidia.com. Archived from the original on 8 December 2015. Retrieved 11 December 2015.
[343]
"The Mobile Workstation GPU". Nvidia.com. Archived from the original on 15 October 2008. Retrieved 11 December 2015.
[344]
"NVIDIA Announces Quadro4 500 Go GL for Mobile Workstation". Beyond3D Forum. Archived from the original on 29 April 2021. Retrieved 29 April 2021.
[345]
"Nvidia Mobile GPU Solutions". Nvidia.com. Archived from the original on 7 October 2008. Retrieved 11 December 2015.
[346]
"Nvidia Quadro4 700 Go GL | techPowerUp GPU Database". Techpowerup.com. Retrieved 11 December 2015.^{[dead link]}
[347]
"NVIDIA Unleashes Quadro4 700 Go GL. Welcome, NV28M". Neowin. 5 February 2003. Retrieved 29 April 2021.
[348]
"Quadro4 700 Go GL, Open GL sui notebook". Hardware Upgrade (in Italian). Retrieved 29 April 2021.
[349]
"Nvidia Quadro FX Go700 | techPowerUp GPU Database". Techpowerup.com. Retrieved 11 December 2015.^{[dead link]}
[350]
"NVIDIA Quadro FX Go700 Specs". TechPowerUp. Retrieved 29 April 2021.
[351]
"Nvidia Quadro FX Go1000 | techPowerUp GPU Database". Techpowerup.com. Retrieved 11 December 2015.^{[dead link]}
[352]
Hinum, Klaus. "NVIDIA Quadro FX Go 1000". Notebookcheck. Retrieved 29 April 2021.
[353]
"NVIDIA PROFESSIONAL GRAPHICS SOLUTIONS" (PDF). Nvidia.com.
[354]
"NVIDIA Quadro RTX 3000 Max-Q Specs". TechPowerUp. Retrieved 4 March 2020.
[355]
"NVIDIA Quadro RTX 4000 Max-Q Specs". TechPowerUp. Retrieved 4 March 2020.
[356]
"NVIDIA Quadro RTX 5000 Max-Q Specs". TechPowerUp. Retrieved 4 March 2020.
[357]
"ampere-mobile-line-card-us-web.pdf". nvdam.widen.net. Archived from the original on 18 April 2023. Retrieved 18 April 2023.
[358]
"proviz-mobile-linecard-update-2653183.pdf". nvdam.widen.net. Retrieved 18 June 2023.
[359]
"NVIDIA GF117 GPU Specs". TechPowerUp. Retrieved 3 January 2022.
[360]
"Nvidia Grid K1 Graphics Board" (PDF). Nvidia.com. Archived (PDF) from the original on 3 March 2016. Retrieved 11 December 2015.
[361]
"Nvidia Grid K2 Graphics Board" (PDF). Nvidia.com. Archived (PDF) from the original on 4 March 2016. Retrieved 11 December 2015.
[362]
"Virtual GPU Technology for Hardware Acceleration | Nvidia GRID". Nvidia.com. Archived from the original on 30 June 2014. Retrieved 11 December 2015.
[363]
"Nvidia GPU Boost For Tesla" (PDF). January 2014. Retrieved 7 December 2015.
[364]
"Tesla C1060 Computing Processor Board" (PDF). Nvidia.com. Retrieved 11 December 2015.
[365]
"Difference between Tesla S1070 and S1075". 31 October 2008. Retrieved 29 January 2017. S1075 has one interface card
[366]
"Tesla C2050 and Tesla C2070 Computing Processor" (PDF). Nvidia.com. Retrieved 11 December 2015.
[367]
"Tesla M2050 and Tesla M2070/M2070Q Dual-Slot Computing Processor Modules" (PDF). Nvidia.com. Retrieved 11 December 2015.
[368]
"Tesla C2075 Computing Processor Board" (PDF). Nvidia.com. Retrieved 11 December 2015.
[369]
Hand, Randall (23 August 2010). "NVidia Tesla M2050 & M2070/M2070Q Specs OnlineVizWorld.com". VizWorld.com. Retrieved 11 December 2015.
[370]
"Tesla M2090 Dual-Slot Computing Processor Module" (PDF). Nvidia.com. Retrieved 11 December 2015.
[371]
"Tesla K10 GPU accelerator" (PDF). Nvidia.com. Retrieved 11 December 2015.
[372]
"Tesla K20 GPU active accelerator" (PDF). Nvidia.com. Retrieved 11 December 2015.
[373]
"Tesla K20 GPU accelerator" (PDF). Nvidia.com. Retrieved 11 December 2015.
[374]
"Tesla K20X GPU accelerator" (PDF). Nvidia.com. Retrieved 11 December 2015.
[375]
"Tesla K40 GPU accelerator" (PDF). Nvidia.com. Retrieved 11 December 2015.
[376]
"Tesla K80 GPU accelerator" (PDF). Images.nvidia.com. Retrieved 11 December 2015.
[377]
"Nvidia Announces Tesla M40 & M4 Server Cards - Data Center Machine Learning". Anandtech.com. Retrieved 11 December 2015.
[378]
"Accelerating Hyperscale Datacenter Applications with Tesla GPUs | Parallel Forall". Devblogs.nvidia.com. 10 November 2015. Retrieved 11 December 2015.
[379]
"Tesla M6" (PDF). Images.nvidia.com. Retrieved 28 May 2016.
[380]
"Tesla M10" (PDF). Images.nvidia.com. Retrieved 29 October 2016.
[381]
"Tesla M40" (PDF). Images.nvidia.com. Retrieved 11 December 2015.
[382]
"Tesla M60" (PDF). Images.nvidia.com. Retrieved 27 May 2016.
[383]
Smith, Ryan (13 September 2016). "Nvidia Announces Tesla P40 & Tesla P4 - Network Inference, Big & Small". Anandtech. Retrieved 13 September 2016.
[384]
"Tesla P6" (PDF). www.nvidia.com. Retrieved 7 March 2019.
[385]
"Tesla P6 Specs". www.techpowerup.com. Retrieved 7 March 2019.
[386]
Smith, Ryan (5 April 2016). "Nvidia Announces Tesla P100 Accelerator - Pascal GP100 for HPC". Anandtech.com. Anandtech.com. Retrieved 5 April 2016.
[387]
Harris, Mark. "Inside Pascal: Nvidia's Newest Computing Platform". Retrieved 13 September 2016.
[388]
Smith, Ryan (20 June 2016). "NVidia Announces PCI Express Tesla P100". Anandtech.com. Retrieved 21 June 2016.
[389]
Smith, Ryan (10 May 2017). "The Nvidia GPU Technology Conference 2017 Keynote Live Blog". Anandtech. Retrieved 10 May 2017.
[390]
Smith, Ryan (10 May 2017). "NVIDIA Volta Unveiled: GV100 GPU and Tesla V100 Accelerator Announced". Anandtech. Retrieved 10 May 2017.
[391]
Oh, Nate (20 June 2017). "NVIDIA Formally Announces V100: Available later this Year". Anandtech.com. Retrieved 20 June 2017.
[392]
"NVIDIA TESLA T4 TENSOR CORE GPU". NVIDIA. Retrieved 17 October 2018.
[393]
"NVIDIA Tesla T4 Tensor Core Product Brief" (PDF). www.nvidia.com. Retrieved 10 July 2019.
[394]
"NVIDIA TESLA A2 TENSOR CORE GPU".
[395]
"NVIDIA TESLA A10 TENSOR CORE GPU".
[396]
"NVIDIA TESLA A16 TENSOR CORE GPU".
[397]
"NVIDIA TESLA A30 TENSOR CORE GPU".
[398]
"NVIDIA TESLA A40 TENSOR CORE GPU".
[399]
"NVIDIA TESLA A100 TENSOR CORE GPU". NVIDIA. Retrieved 14 January 2021.
[400]
"NVIDIA Tesla A100 Tensor Core Product Brief" (PDF). www.nvidia.com. Retrieved 22 September 2020.
[401]
Smith, Ryan (14 May 2020). "NVIDIA Ampere Unleashed: NVIDIA Announces New GPU Architecture, A100 GPU, and Accelerator". AnandTech.
[402]
"NVIDIA H100 Tensor Core GPU". NVIDIA. Retrieved 15 April 2024.
[403]
Mujtaba, Hassan (22 March 2022). "NVIDIA Hopper GH100 GPU Unveiled: The World's First & Fastest 4nm Data Center Chip, Up To 4000 TFLOPs Compute, HBM3 3 TB/s Memory". Wccftech. Retrieved 15 April 2024.
[404]
"NVIDIA H100 PCIe 80 GB Specs". TechPowerUp. 21 March 2023. Retrieved 15 April 2024.
[405]
"NVIDIA L40 GPU for Data Center". NVIDIA. 18 May 2023. Retrieved 15 April 2024.
[406]
"NVIDIA L40 Specs". TechPowerUp. 13 October 2022. Retrieved 15 April 2024.
[407]
"NVIDIA L4 Tensor Core GPU". NVIDIA. Retrieved 15 April 2024.
[408]
"NVIDIA ADA GPU Architecture" (PDF). nvidia.com. Retrieved 15 April 2024.
[409]
"NVIDIA and Google Cloud Deliver Powerful New Generative AI Platform, Built on the New L4 GPU and Vertex AI". NVIDIA Corporation. 21 March 2023. Retrieved 15 April 2024.
[410]
"NVIDIA L4 Specs". TechPowerUp. 21 March 2023. Retrieved 15 April 2024.
[411]
"Anandtech Microsoft's Xbox". Anandtech.com. Archived from the original on 4 November 2010. Retrieved 11 November 2010.
[412]
Smith, Tony (14 February 2001). "TSMC starts fabbing Nvidia Xbox chips". The Register. Retrieved 20 November 2019.
[413]
"PLAYSTATION 3のグラフィックスエンジンRSX". Archived from the original on 17 September 2016. Retrieved 7 October 2016.
[414]
"NVIDIA Playstation 3 RSX 65nm Specs". TechPowerUp. Retrieved 21 June 2019.
[415]
"PS3 Graphics Chip Goes 65nm in Fall". Edge Online. 26 June 2008. Archived from the original on 25 July 2008.
[416]
"NVIDIA Technology Powers New Home Gaming System, Nintendo Switch". 20 October 2016. Archived from the original on 18 May 2017. Retrieved 17 May 2017.
[417]
Quilty, John (28 June 2019). "New Report Details Potential Hardware For Nintendo Switch Revision". TechRaptor. Retrieved 20 November 2019.
[418]
"Khronos Products - OpenGL". Archived from the original on 28 January 2017. Retrieved 11 June 2017.
[419]
"Khronos Products - OpenGL ES". Archived from the original on 28 January 2017. Retrieved 11 June 2017.
[420]
"Khronos Products - Vulkan". Archived from the original on 28 January 2017. Retrieved 11 June 2017.
[421]
"NVIDIA Technology Powers New Home Gaming System, Nintendo Switch". 20 October 2016. Archived from the original on 18 May 2017. Retrieved 17 May 2017.

External links

OpenGL 2.0 support on Nvidia GPUs (PDF document)
Release Notes for Nvidia OpenGL Shading Language Support (PDF document)

Share this article:

This article uses material from the Wikipedia article List_of_Nvidia_graphics_processing_units, and is written by contributors. Text is available under a CC BY-SA 4.0 International License; additional terms may apply. Images, videos and audio are available under their respective licenses.