The ATI Radeon HD 5770 Graphics Upgrade Kit for Mac Pro (Mid 2010) from Apple is a graphics card for use in the Mid 2010 version of Apple's Mac Pro desktop workstation. The card requires an available PCI Express 2.0 x16 slot for installation. The ATI Radeon HD 5770 GPU features 1GB of GDDR5 memory for superlative performance, making it a great choice for creative, scientific, and technical applications where 3D performance is critical. The card can drive up to three displays simultaneously. It features two Mini DisplayPort outputs and one Dual-Link DVI output.
Apple offers optional adapters to drive legacy VGA displays. Interface PCI Express 2.0 x16 Ports 2x Mini DisplayPort 1x Dual-Link DVI System Requirements Mac Pro (Mid 2010) with available PCI Express slot Mac OS X 10.6.4 or later Note: If you are using more than one Mini DisplayPort to Single-Link DVI adapter, only two displays are supported across the three ports. To connect up to two Mini DisplayPort displays and up to a 30-inch DVI display simultaneously, use the ports without any adapters. To connect two DVI displays, use the dual-link DVI port and the Apple Mini DisplayPort to DVI Adapter or the Apple Mini DisplayPort to Dual-Link DVI Adapter (sold separately). To connect three DVI displays at once, you must use two Apple Mini DisplayPort to Dual-Link DVI Adapters (sold separately).
To connect up to three VGA displays simultaneously, use the Mini DisplayPort to VGA adapter and DVI to VGA adapters (sold separately). Rated 4 out of 5 by Anonymous from Best graphics card value for the Mac With the Radeon series 5700 products, and in specific the 5770, ATI brings an intensely feature rich product to the Mac that offers plenty of performance for current and modern games for a competitive price. It has good cooling and offers less noise compared to a 4850. $200 cheaper than the simultaneously released 5870, it is obviously less powerful, but a much better value in my opinion.
So if you are in the mid-range market right now seeking a new graphics card for your Mac, I can recommend the ATI Radeon HD 5770 wholeheartedly.As a side note, despite what Apple says on their site, this card is compatible with all Mac Pros that were released in and after 2008. Rated 4 out of 5 by Evolv Media from Decent upgrade I purchased this card because my previous card was not compatible with FCPX.
This card is definitely quieter than my previous x1900xt. I'm using this on a 2006 Mac Pro 1,1 without any issues. I didn't see the amazing performance gains that other people saw.
It's faster, but not amazingly fast.Apple Motion only seems slightly smoother. The price is good and I was able to sell my previous card on @ for a good price. I didn't realize this before I bought it, but you MUST have 2 (TWO!) apple mini display to DUAL link dvi adapters to use 3 DVI monitors with this card. Those adapters are $100 a pop. Deal breaker for me. Rated 5 out of 5 by Longtime Apple User from Radeon 5770 Graphics Card for Mac I needed a graphics boost for my older MacPro 3,1.
While Apple's site says this card only works in the 5,1 MacPros, this card will work in all Intel MacPros. Best seo format. Installation can be a little tricky in the older machines since the bracket that the instructions says can move, doesn't, you have to angle the card a little bit to get the clearance needed. Don't forget to hook up the power cable for the card (it goes to a power socket on the motherboard). B&H sent the card out promptly with good packaging. They were also less expensive than other sources for this card. In hind sight I might have gotten the 5870, but this card does what I need and was well worth the money. Rated 5 out of 5 by Anonymous from Solved Video Card Problem on MacPro1,1 Computer boots up fine now after easy installation of the ATI Radeon HD 5770 card.
Running 24 and 20 LCD monitors. One connected to DVI-D, other Mini DisplayPort using Kanex iAdapt Adapter sold here. Purchased this video card to solve the problem with NVIDIA GeForce 7300 GT card. GeForce 7300 GT problem started with screen freezing watching video, audio kept going and cursor could be moved but nothing could be selected.
Had to do a force restart with the power button. On restart computer would get part way through startup, then got stuck on a blank gray screen.
Would not boot from Snow Leopard install DVD or cloned backup HD. Only be booted in Safe Mode.
B&H had great price, order went smoothly and arrived with no problems. MacPro1,1 Dual-Core Intel Xeon 2.66 GHz, Mac OS X (10.6.8). Rated 4 out of 5 by Brian from Problem Solved I had a nice Mac Pro Tower that had a lame graphics card built in, and I was seeing a strange line like a wrinkle go through the video on fast moving objects, as well as having the computer just not play with two tracks of HD video if the cameras were of different type. For a powerful computer this was just not acceptable and it made my workflow a nightmare. This card was recommended by a colleague and it solved the problem of not being able to see the two tracks play.
I do wish it had two DVI ports instead of one and two mini-D ports. DVI just feels more robust. I had it installed at a pro shop that I trust. I wouldn't put it in myself.
Rated 5 out of 5 by Anonymous from Works great with Mac Pro1,1 (2006) You need to get the Lion drivers, but once installed the card/ Mac Pro boots up normally. Excellent speed. Feels like a new Mac Pro. Only needs one power connection, not two. Comes with the correct short cord, which will have to be extended for a Mac Pro1,1.
No down side I've seen yet. Works great with Photoshop, Final Cut and other graphic intensive applications like Quark 9, InDesign, Illustrator, etc. I only have one monitor so I can't say how it works with two or three. Great for the price, which isn't that much more than the generic PC version which would require flashing or an injector, etc. Rated 5 out of 5 by Anonymous from Great card I have had his graphic card couple weeks now and I love it. I have the Mac pro 2006 1.1 and it works great.
Coming from the card that came with the computer this card flys. Main reason of getting it was so I could hook up my new 27 in apple monitor. Not a huge gamer on the computer so can't tell you how it works on the game side.
But the few games that I do have look and play great. Plus, it was easy to install and the price was well in my price range. Apple was selling of for about 60 more. So I will be looking for other stuff to buy on his site.
Rated 4 out of 5 by Anonymous from Performance upgrade for 2006 Mac Pro Purchased as direct replacement for dying ATI Radeon x1900 XT video card in 2006 2.0 GHz quad-core Mac Pro (1,1). No drivers or additional software required, even re-used the existing internal power cable. Noticeable performance improvement in boot and shutdown times and most applications. Not a game machine, so did not test 3D graphics capabilities, but this is a mid-range video card and it should deliver suitable performance for all but the most picky. Much quieter fan noise than previous card, most likely owing to the large plastic shroud. Overall, a worthy upgrade for older Mac Pros.
ATI Radeon HD 6750M Graphics Drivers Download This site maintains the list of ATI Drivers available for Download. Just browse our organized database and find a driver that fits your needs. If you has any Drivers Problem, Just, this professional drivers tool will help you fix the driver problem for Windows 10, 8, 7, Vista and XP.
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![Radeon Radeon](https://cnet2.cbsistatic.com/img/54X5ACvj4Eqee8jakdjnrQwzDpg=/770x433/2010/08/03/870a2eb1-bb7a-11e2-8a8e-0291187978f3/32036689-2-440-overview-1.gif)
Contents. Field explanations The headers in the table listed below describe the following:.
Model – The marketing name for the GPU assigned by AMD/ATI. Note that ATI trademarks have been replaced by AMD trademarks starting with the Radeon HD 6000 series for desktop and FirePro series for professional graphics. Codename – The internal engineering codename for the GPU.
Launch – Date of release for the GPU. Architecture – The microarchitecture used by the GPU. Fab – Fabrication process.
Average feature size of components of the GPU. Transistors – Number of transistors on the die. Die Size – Physical surface area of the die. Core config – The layout of the graphics pipeline, in terms of functional units. Core clock – The reference base and boost (if available) core clock frequency. Fillrate. Pixel - The rate at which pixels can be rendered by the raster operators to a display.
Measured in Pixels/s. Texture - The rate at which textures can be mapped by the texture mapping units onto a polygon mesh. Measured in Texels/s. Performance. Shader operations - How many operations the pixel shaders (or unified shaders in Direct3D 10 and newer GPUs) can perform. Measured in Operations/s.
Vertex operations - The amount of geometry operations that can be processed on the vertex shaders in one second (only applies to Direct3D 9.0c and older GPUs). Measured in Vertices/s. Memory. Bus type – Type of memory bus utilized.
Bus width – Maximum bit width of the memory bus utilized. Size – Size of the graphics memory. Clock – The reference memory clock frequency.
Bandwidth – Maximum theoretical memory bandwidth based on bus type and width. TDP (Thermal design power) – Maximum amount of heat generated by the GPU chip, measured in Watt. TBP (Typical board power) – Typical power drawn by the total board, including power for the GPU chip and peripheral equipment, such as VRM, memory, fans, etc., measured in Watt.
Bus interface – Bus by which the graphics processor is attached to the system (typically an expansion slot, such as, or ). API support – Rendering and computing supported by the GPU and driver. Video codec acceleration. R100 -. R200 - Video Immersion II.
R300 - Video Immersion II +. R410 - Video Shader HD. R420 - Video Shader HD +. R520 -. R600 - Avivo HD Video - 1.0. R700 - UVD 2, UVD 2.2.
Evergreen - UVD 2.2. Northern Islands - UVD 3 (HD 67xx UVD 2.2). Southern Islands - UVD 3.1, 1.0.
Sea Islands - UVD 4.2, VCE 2.0. Volcanic Islands - UVD 5.0, 6.0, VCE 3.0. Arctic Islands - UVD 6.3, VCE 3.4. Vega - UVD 7.0, VCE 4.0 Features Overview The following table shows features of Radeon-branded GPU microarchitectures. The Radeon 100 Series has programmable pixel shaders, but do not fully comply with DirectX 8 or Pixel Shader 1.0. See article on.
These series do not fully comply with OpenGL 2+ as the hardware does not support all types of non power of two (NPOT) textures. OpenGL 4+ compliance requires supporting FP64 shaders and these are emulated on some TeraScale chips using 32-bit hardware. ^ The UVD and VCE were replaced by the Video Core Next (VCN) ASIC in the APU implementation of Vega.
^ To play protected video content, it also requires card, operating system, driver, and application support. A compatible HDCP display is also needed for this.
HDCP is mandatory for the output of certain audio formats, placing additional constraints on the multimedia setup. More displays may be supported with native connections, or splitting the maximum resolution between multiple monitors with active converters.
^ DRM is a component of the Linux kernel. Support in this table refers to the most current version.
API Overview The following table shows the graphics and compute support across -branded GPU microarchitectures. Note that a branding series might include older generation chips. Main article: Model Launch Fab Bus interface Core clock Memory clock (MHz) Core config 1 Memory compliance MOperations/s MPixels/s MTexels/s MVertices/s Size Bandwidth (/s) Bus type Bus width Direct3D 3D Rage April 1996 500 PCI 40 40 1:0:1:1 40 40 40 0 2 0.32 EDO 64 5.0 None 2 3D Rage II September 1996 500 AGP 1x (Rage IIc only), PCI 60 83 (66 MHz with EDO) 1:0:1:1 60 60 60 0 2, 4, 8 0.664 EDO, SGRAM, SDR 64 5.0 None 2 Rage Pro March 1997 350 AGP 1x, AGP 2x, PCI 75 75 1:0:1:1 75 75 75 0 8, 16 0.6 EDO, SGRAM, SDR 64 6.0 1.1 Rage XL August 1998 350 AGP 2x, PCI 125 83 1:0:1:1 ca. Main article:.
All models include Direct3D 7.0 and 1.3. The R100 cards were originally launched without any numbering; the numbering was later added in rebrands.
Main article:. All models include Direct3D 9.0 and 2.0 Model Launch Code name Fab (nm) Bus interface Core clock (MHz) Memory clock (MHz) Core config 1 Memory MOperations/s MPixels/s MTexels/s MVertices/s Size Bandwidth (/s) Bus type Bus width Radeon 9500 Oct. 24, 2002 R300 (khan) 150 AGP 8x 275 270 4:4:4:8 1100 2200 1100 275 64, 128 8.64 DDR 128 Radeon 9500 Pro Oct. 24, 2002 R300 (khan) 150 AGP 8x 275 270 8:4:8:8 2200 2200 2200 275 128 8.64 DDR 128 Radeon 9550 2004 RV350 (shivah) 130 AGP 8x 250 200 4:2:4:4 1000 1000 1000 125 64, 128, 256 6.4 DDR 128 Radeon 9550 SE 2004 RV350 (shivah) 130 AGP 8x 250 200 4:2:4:4 1000 1000 1000 125 64, 128, 256 3.2 DDR 64 Radeon 9600 2003 RV350 (shivah) 130 AGP 8x 325 200 4:2:4:4 1300 1300 1300 162.5 128, 256 6.4 DDR 128 Radeon 9600 Pro Mar. 6, 2003 RV350 (shivah) 130 AGP 8x 400 300 4:2:4:4 1600 1600 1600 200 128, 256 9.6 DDR 128 Radeon 9600 SE 2003 RV350 (shivah) 130 AGP 8x 325 200 4:2:4:4 1300 1300 1300 162.5 64, 128, 256 3.2 DDR 64 Radeon 9600 XT Sept. 30, 2003 RV360 130 AGP 8x 500 300 4:2:4:4 2000 2000 2000 250 128, 256 9.6 DDR 128 Radeon 9700 TX 2002 R300 (khan) 150 AGP 8x 263 263 8:4:8:8 2104 2104 2104 275 128 16.83 DDR 256 Radeon 9700 Oct.
24, 2002 R300 (khan) 150 AGP 8x 275 270 8:4:8:8 2200 2200 2200 275 128 17.28 DDR 256 Radeon 9700 Pro July 18, 2002 R300 (khan) 150 AGP 8x 325 310 8:4:8:8 2600 2600 2600 325 128 19.84 DDR 256 Radeon 9800 2003 R350 150 AGP 8x 325 310 8:4:8:8 2600 2600 2600 325 128 19.84 DDR 256 Radeon 9800 XL 2003 R350 150 AGP 8x 350 310 8:4:8:8 2800 2800 2800 350 128 19.84 DDR 256 Radeon 9800 XXL Oct. 1, 2003 R360 150 AGP 8x 390 338 8:4:8:8 3120 3120 3120 390 128 21.60 DDR 256 Radeon 9800 Pro Mar. 1, 2003 R350, R360 150 AGP 8x 380 340, 350 8:4:8:8 3040 3040 3040 380 128, 256 21.76, 22.40 DDR, GDDR2 256 Radeon 9800 SE Mar. 1, 2003 R350 150 AGP 8x 325, 380 270, 340 4:4:4:4 1300, 1520 1300, 1520 1300, 1520 325, 380 128, 256 8.64, 21.76 DDR 128, 256 2 Radeon 9800 XT Sept.
9, 2003 R360 150 AGP 8x 412 365 8:4:8:8 3296 3296 3296 412 256 23.36 DDR 256 Model Launch Code name Fab (nm) Bus interface Core clock (MHz) Memory clock (MHz) Core config 1 MOperations/s MPixels/s MTexels/s MVertices/s Size Bandwidth (/s) Bus type Bus width Memory 1::: 2 The 256-bit version of the 9800 SE when unlocked to 8-pixel pipelines with third party driver modifications should function close to a full 9800 Pro. PCI-E (X3xx, X5xx, X6xx, X1000 Series). Main article:. All models include Direct3D 9.0 and 2.0. Based on the Radeon X300 Model Launch Code name Fab (nm) Bus interface Core clock (MHz) Memory clock (MHz) Core config 1 Memory MOperations/s MPixels/s MTexels/s MVertices/s Size Bandwidth (/s) Bus type Bus width Radeon Xpress X200 Nov. Main article:. All models include 8x.
All models include Direct3D 9.0b and 2.0 Model Launch Code name Fab (nm) Core clock (MHz) Memory clock (MHz) Core config 1 Memory MOperations/s MPixels/s MTexels/s MVertices/s Size Bandwidth (/s) Bus type Bus width Radeon X700 March 2005 RV410 (alto) 110 400 350 8:6:8:8 3200 3200 3200 600 128, 256 11.2 DDR 128 Radeon X700 Pro March 1, 2005 RV410 (alto) 110 425 432 8:6:8:8 3400 3400 3400 637.5 128, 256 13.824 GDDR3 128 Radeon X800 SE Oct. 2004 R420 (loki) 130 425 400 8:6:8:8 3400 6800 3400 637,5 256 25.6 GDDR3 256 Radeon X800 GT Dec. 6, 2005 R420 (loki) 130 475 490 8:6:8:16 3800 7600 3800 712.5 256 31.36 GDDR3 256 Radeon X800 Dec. 2004 R430 110 400 350 12:6: 6400 4800 600 256 22.4 GDDR3 256 Radeon X800 GTO Dec.
6, 2005 R420 (loki) 130 400 490 12:6: 6400 4800 600 256 31.36 GDDR3 256 Radeon X800 Pro May 5, 2004 R420 (loki) 130 475 450 12:6: 7600 5700 712.5 256 28.8 GDDR3 256 Radeon X800 XL Feb. 2, 2005 R430 110 400 490 16:6: 6400 6400 600 256 31.36 GDDR3 256 Radeon X800 XT May 4, 2004 R420 (loki) 130 500 500 16:6: 8000 8000 750 256 32 GDDR3 256 Radeon X800 XT PE May 4, 2004 R420 (loki) 130 520 560 16:6: 8320 8320 780 256 35.84 GDDR3 256 Radeon X850 Pro Feb.
28, 2005 R481 130 507 520 12:6: 8112 6084 760.5 256 33.28 GDDR3 256 Radeon X850 XT Feb. 28, 2005 R481 130 520 540 16:6: 8320 8320 780 256 34.56 GDDR3 256 Radeon X850 XT PE Feb. 28, 2005 R481 130 540 590 16:6: 8640 8640 810 256 37.76 GDDR3 256 1::: PCI-E (X7xx, X8xx). Main article:.
All models include x16. All models include Direct3D 9.0b and 2.0 Model Launch Code name Fab (nm) Core clock (MHz) Memory clock (MHz) Core config 1 Memory MOperations/s MPixels/s MTexels/s MVertices/s Size Bandwidth (/s) Bus type Bus width Radeon X700 SE Apr.
1, 2005 RV410 (alto) 110 400 200 250 4:6:4:8 1600 3200 1600 600 128 3.2 DDR 64 Radeon X700 LE Dec. 21, 2004 RV410 (alto) 110 400 250 8:6:8:8 3200 3200 3200 600 128 4 DDR 64 Radeon X700 Sept. 2005 RV410 (alto) 110 400 250 350 8:6:8:8 3200 3200 3200 600 128, 256 8 11.2 DDR 128 Radeon X700 Pro Dec. 21, 2004 RV410 (alto) 110 425 432 8:6:8:8 3400 3400 3400 637.5 128, 256 13.824 GDDR3 128 Radeon X700 XT Never Released RV410 (alto) 110 475 525 8:6:8:8 3800 3800 3800 712.5 128, 256 16.8 GDDR3 128 Radeon X800 GT 128MB Aug. 1, 2005 R423 R480 (thor) 130 475 175 8:6:8:16 3800 7600 3800 712.5 128 22.4 DDR 256 Radeon X800 GT 256MB Aug. 1, 2005 R423 R480 (thor) 130 475 490 8:6:8:16 3800 7600 3800 712.5 256 31.36 GDDR3 256 Radeon X800 Dec.
1, 2004 R430 (thor) 110 392 350 12:6: 6272 4704 588 128, 256 22.4 GDDR3 256 Radeon X800 GTO 128MB Sept. 15, 2005 R423 R480 R430 (thor) 130 110 400 350 12:6: 6400 4800 600 128 22.4 GDDR3 256 Radeon X800 GTO 256MB Sept. 15, 2005 R423 R480 R430 (thor) 130 110 400 490 12:6: 6400 4800 600 256 31.36 GDDR3 256 Radeon X800 Pro May 5, 2004 R423 (thor) 130 475 450 12:6: 7600 5700 712.5 256 28.8 GDDR3 256 Radeon X800 XL Dec.
1, 2004 (256 MB) May 4, 2005 (512 MB) R430 (thor) 110 400 490 16:6: 6400 6400 600 256, 512 31.36 GDDR3 256 Radeon X800 XT Dec. 1, 2004 R423 (thor) 130 500 500 16:6: 8000 8000 750 256 32 GDDR3 256 Radeon X800 XT Platinum Edition May 5, 2004 R423 (thor) 130 520 560 16:6: 8320 8320 780 256 35.84 GDDR3 256 Radeon X850 Pro Dec.
1, 2004 R480 (thor) 130 507 520 12:6: 8112 6084 760.5 256 33.28 GDDR3 256 Radeon X850 XT Dec. 1, 2004 R480 (thor) 130 520 540 16:6: 8320 8320 780 256 34.56 GDDR3 256 Radeon X850 XT CrossFire Master Sept.
29, 2004 R480 (thor) 130 520 540 16:6: 8320 8320 780 256 34.56 GDDR3 256 Radeon X850 XT Platinum Edition Dec. 21, 2004 R480 (thor) 130 540 590 16:6: 8640 8640 810 256 37.76 GDDR3 256 Model Launch Code name Fab (nm) Core clock (MHz) Memory clock (MHz) Core config 1 MOperations/s MPixels/s MTexels/s MVertices/s Size Bandwidth (/s) Bus type Bus width (bit) Fillrate Memory 1::: IGP (X12xx, 21xx). Main article:. All models include Direct3D 9.0b and 2.0. Based on Radeon X700 Model Launch Code name Fab (nm) Bus interface Core clock (MHz) Memory clock (MHz) Core config 1 Memory MOperations/s MPixels/s MTexels/s MVertices/s Size Bandwidth (/s) Bus type Bus width Radeon Xpress X1200 Feb. 28 2007 RS690C (zeus) 80 HT 2.0 350 400 - 800 4:2:4:4 1400 1400 1400 175 256 - 512 6.4 - 12.8 DDR2 128 Radeon Xpress X1250 Aug.
29, 2006 (Intel), Feb. 28, 2007 (AMD) RS600, RS690 (zeus) 80 FSB, HT 2.0 400 400 - 800 4:2:4:4 1600 1600 1600 200 256 - 512 6.4 - 12.8 DDR2 128 Radeon Xpress 2100 March 4, 2008 RS740 (titan) 55 HT 2.0 500 400 - 800 4:2:4:4 2000 2000 2000 250 256 - 512 6.4 - 12.8 DDR2 128 Radeon X1000 Series. Main article:. Note that ATI X1000 Series cards (e.g.
X1900) don't have Vertex Texture Fetch, hence they do not fully comply with the VS 3.0 model. Instead, they offer a feature called 'Render to Vertex Buffer (R2VB)' that provides functionality that is an alternative Vertex Texture Fetch. Model Launch Code name Fab (nm) Transistors (million) Die size Bus interface Clock rate Core config Memory TDP (Watts) support (version) Release Price (USD) Core (MHz) Memory (MHz) MOperations/s MPixels/s MVertices/s MTexels/s Size Bandwidth (/s) Bus type Bus width Max.
Direct3D Radeon X1300 Oct. 5, 2005 (PCI-E) Dec. 1, 2005 (AGP) RV515 90 107 100 AGP 8x PCI PCI-E x16 450 250 4:2:4:4 1800 1800 225 1800 128 256 8.00 DDR2 128 9.0c 2.0 $ Radeon X1300 HyperMemory Oct. 5, 2005 RV515 90 107 100 PCI-E x16 450 250 4:2:4:4 1800 1800 225 1800 128 256 512 8.00 DDR2 64 9.0c 2.0 $ Radeon X1300 PRO Oct. 5, 2005 (PCI-E) Nov. 1, 2006 (AGP) RV515 90 107 100 AGP 8x PCI-E x16 600 400 4:2:4:4 2400 2400 300 2400 128 256 12.8 DDR2 128 31 9.0c 2.0 $ Radeon X1300 XT Aug. 12, 2006 RV530 90 157 150 AGP 8x PCI-E x16 500 400 12:5:4:4 6000 2000 625 2000 128 256 12.8 DDR2 128 22 9.0c 2.0 $ Radeon X1550 Jan.
8, 2007 RV516 90 107 100 AGP 8x PCI PCI-E x16 550 400 4:2:4:4 2200 2200 275 2200 128 256 512 12.8 DDR2 128 27 9.0c 2.0 $ Radeon X1600 PRO Oct. 10, 2005 RV530 90 157 150 AGP 8x PCI-E x16 500 390 12:5:4:4 6000 2000 625 2000 128 256 512 12.48 DDR2 128 41 9.0c 2.0 $ Radeon X1600 XT Oct. 10, 2005 (PCI-E) RV530 90 157 150 AGP 8x PCI-E x16 590 780 12:5:4:4 7080 2360 737.5 2360 256 512 22.08 GDDR3 128 42 9.0c 2.0 $ Radeon X1650 Feb. 1, 2007 RV530 90 157 150 AGP 8x PCI-E x16 500 400 12:5:4:4 6000 2000 625 2000 256 512 12.8 DDR2 128 9.0c 2.0 $ Radeon X1650 SE RV516 90 105 PCI-E x16 635 400 4:2:4:4 256 12.8 DDR2 128 9.0c 2.0 Radeon X1650 GT May 1, 2007 (PCI-E) Oct. 1, 2007 (AGP) RV560 80 330 230 AGP 8x PCI-E x16 400 400 24:8:8:8 9600 3200 800 3200 256 512 12.8 GDDR3 128 9.0c 2.0 $ Radeon X1650 PRO Aug. 23, 2006 (PCI-E) Oct. 15, 2006 (AGP) RV535 80 330 131 AGP 8x PCI-E x16 600 700 12:5:4:4 7200 2400 750 2400 256 512 22.4 GDDR3 128 44 9.0c 2.0 $ Radeon X1650 XT Oct.
30, 2006 RV560 80 330 230 AGP 8x PCI-E x16 525 700 24:8:8:8 1050 4200 256 512 22.4 GDDR3 128 55 9.0c 2.0 $ Radeon X1800 CrossFire Edition Dec. 20, 2005 R520 90 321 288 PCI-E x16 600 700 16:8: 9600 900 9600 512 46.08 GDDR3 256 113 9.0c 2.0 $ Radeon X1800 GTO Mar. 9, 2006 R520 90 321 288 PCI-E x16 500 495 12:8:12:8 6000 6000 1000 6000 256 512 32.0 GDDR3 256 48 9.0c 2.0 $249 Radeon X1800 XL Oct. 5, 2005 R520 90 321 288 PCI-E x16 500 500 16:8: 8000 1000 8000 256 32.0 GDDR3 256 70 9.0c 2.0 $ Radeon X1800 XT Oct. 5, 2005 R520 90 321 288 PCI-E x16 625 750 16:8:0 10000 256 512 48.0 GDDR3 256 113 9.0c 2.0 $549 Radeon X1900 CrossFire Edition Jan.
24, 2006 R580 90 384 352 PCI-E x16 625 725 48:8:0 10000 512 46.4 GDDR3 256 100 9.0c 2.0 $599 Radeon X1900 GT May 5, 2006 R580 90 384 352 PCI-E x16 575 600 36:8:0 6900 1150 6900 256 38.4 GDDR3 256 75 9.0c 2.0 $ Radeon X1900 GT Rev. 7, 2006 R580 90 384 352 PCI-E x16 512 660 36:8:2 6144 1024 6144 256 42.64 GDDR3 256 9.0c 2.0 $ Radeon X1900 XT Jan.
24, 2006 R580 90 384 352 PCI-E x16 625 725 48:8:0 10000 256 512 46.4 GDDR3 256 100 9.0c 2.0 $549 Radeon X1900 XTX Jan. 24, 2006 R580 90 384 352 PCI-E x16 650 775 48:8:0 10400 512 49.6 GDDR3 256 135 9.0c 2.0 $649 Radeon X1950 CrossFire Edition Aug. 23, 2006 R580+ 80 384 352 PCI-E x16 650 1000 48:8:0 10400 512 64 GDDR4 256 9.0c 2.0 $449 Radeon X1950 GT Jan. 29, 2007 (PCI-E) Feb. 10, 2007 (AGP) RV570 80 330 230 AGP 8x PCI-E x16 500 600 36:8:0 6000 1000 6000 256 512 38.4 GDDR3 256 57 9.0c 2.0 $140 Radeon X1950 PRO Oct. 17, 2006 (PCI-E) Oct. 25, 2006 (AGP) RV570 80 330 230 AGP 8x PCI-E x16 575 690 36:8:0 6900 1150 6900 256 512 44.16 GDDR3 256 66 9.0c 2.0 $ Radeon X1950 XT Oct.
17, 2006 (PCI-E) Feb. 18, 2007 (AGP) R580+ 80 384 352 AGP 8x PCI-E 1.0 x16 625 700 (AGP) 900 (PCI-E) 48:8:0 10000 256 512 44.8 (AGP) 57.6 (PCI-E) GDDR3 256 96 9.0c 2.0 $ Radeon X1950 XTX Oct. 17, 2006 R580+ 80 384 352 PCI-E 1.0 x16 650 1000 48:8:0 10400 512 64 GDDR4 256 125 9.0c 2.0 $449 Model Launch Code name Fab (nm) Transistors (million) Die size Bus interface Core (MHz) Memory (MHz) Core config MOperations/s MPixels/s MVertices/s MTexels/s Size Bandwidth (/s) Bus type Bus width Max.
Direct3D Release Price (USD) Clock rate Memory TDP (Watts) support (version) 1::: Radeon HD 2000 Series. Main articles: and Model Launch Code name Fab (nm) Transistors (million) Die size Bus interface Clock rate Core config Memory Processing power TDP (Watts) support (version) Release Price (USD) Core (MHz) Memory (MHz) Pixel (/s) Texture (/s) Size Bandwidth (/s) Bus type Bus width Idle Max. Direct3D Radeon HD 2350 Jun 28, 2007 RV610 65 180 85 PCIe 1.0 ×16 AGP 525 400 40:4:4 2.10 2.10 256 6.40 DDR2 32 42.0 No 20 10.0 3.3 APP Stream Only? Main article: Model Launch Code name Fab (nm) Transistors (million) Die size Bus interface Clock rate Core config Memory Processing power TDP (Watts) support (version) Release Price (USD) Core (MHz) Memory (MHz) Pixel (/s) Texture (/s) Size Bandwidth (/s) Bus type Bus width Idle Max. Direct3D, ATI Stream Radeon HD 3410 May 7, 2009 RV610 65 180 85 PCIe 1.0 x16 519 396 40:4:4 2.08 2.08 256 6.34 DDR2 64 41.52 No 20 10.0 3.3 No, Yes? Radeon HD 3450 Jan 23, 2008 RV620 LE 55 181 67 PCIe 2.0 x16 PCI AGP 8x 600 500 40:4:4 2.40 2.40 256 512 8.00 DDR2 64 48.0 No 25 10.1 3.3 No, Yes? Radeon HD 3470 Jan 23, 2008 RV620 PRO 55 181 67 PCIe 2.0 x16 800 950 40:4:4 3.20 3.20 256 512 15.2 DDR2 GDDR3 64 64.0 No 30 10.1 3.3 No,Yes?
Radeon HD 3550 Aug 4, 2008 RV620 PRO 55 181 67 PCIe 2.0 x16 594 396 40:4:4 2.38 2.38 512 6.34 DDR2 64 47.52 No 30 10.1 3.3 No,Yes? Radeon HD 3570 Jul 5, 2010 RV620 PRO 55 181 67 PCIe 2.0 x16 796 495 40:4:4 3.18 3.18 512 7.92 DDR2 64 63.68 No 30 10.1 3.3 No,Yes? Radeon HD 3610 Sep 24, 2009 RV630 PRO 65 390 153 PCIe 1.0 x16 594 396 120:8:4 2.38 4.75 512 1024 12.7 DDR2 128 142.6 No 35 10.1 3.3 No,Yes? Radeon HD 3650 Jan 23, 2008 RV635 PRO 55 378 135 PCIe 2.0 x16 AGP 8x 725 405 800 120:8:4 2.90 5.80 256 512 1024 13.0 25.6 DDR2 GDDR3 GDDR4 128 174.0 No 65 10.1 3.3 No,Yes?
Radeon HD 3730 Oct 5, 2008 RV635 PRO 55 378 135 PCIe 2.0 x16 722 405 120:8:4 2.89 5.78 512 13.0 DDR2 128 173.3 No 65 10.1 3.3 No,Yes? Radeon HD 3750 Oct 5, 2008 RV635 PRO 55 378 135 PCIe 2.0 x16 796 693 120:8:4 3.18 6.37 512 22.2 GDDR3 128 191.0 No 65 10.1 3.3 No, Yes?
Main articles: and Model 4 Launch Code name Fab (nm) Transistors (million) Die size Bus interface Clock rate Core config 1 Memory 2 Processing power TDP 3 (Watts) support (version) Release Price (USD) Core (MHz) Memory (MHz) Pixel (/s) Texture (/s) Size Bandwidth (/s) Bus type Bus width Idle Max. Radeon HD 4350 Sep 30, 2008 RV710 55 242 73 PCIe 2.0 ×16 PCIe 2.0 ×1 AGP 8× 600 400 650 80:8:4 2.40 4.80 256 512 1024 6.40 10.4 DDR2 DDR3 64 92.0 No 20 10.1 3.3 1.0? Radeon HD 4550 Sep 30, 2008 RV710 55 242 73 PCIe 2.0 ×16 600 600 655 800 80:8:4 2.40 4.80 256 512 1024 10.5 12.8 DDR2 GDDR3 64 96.0 No 25 10.1 3.3 1.0? Radeon HD 4570 Nov 25, 2008 RV710 55 242 73 PCIe 2.0 ×16 650 500 80:8:4 2.60 5.20 1024 8.00 DDR2 64 104.0 No 25 10.1 3.3 1.0? Radeon HD 4580 Nov 20, 2011 RV635 PRO 55 378 135 PCIe 2.0 ×16 796 693 120:8:4 3.18 6.37 512 22.2 GDDR3 128 191.0 No 65 10.1 3.3 1.0? Radeon HD 4650 Sep 10, 2008 RV730 PRO 55 514 146 PCIe 2.0 ×16 AGP 8× 600 650 400 - 500 500 700 320:32:8 4.80 5.20 19.2 20.8 256 512 1024 12.8 - 16.0 16.0 22.4 DDR2 GDDR3 GDDR4 64 128 384.0 416.0 No 48 10.1 3.3 1.0?
Radeon HD 4670 Sep 10, 2008 RV730 XT 55 514 146 PCIe 2.0 ×16 AGP 8× 750 750 400 - 500 900 1000 320:32:8 6.00 24.0 512 1024 12.8 - 16.0 28.8 32.0 DDR2 GDDR3 GDDR4 128 480.0 No 59 10.1 3.3 1.0 79 Radeon HD 4730 Jun 8, 2009 RV770 CE 55 956 256 PCIe 2.0 ×16 700 750 900 900 640:32:8 5.60 6.00 22.4 24.0 512 57.6 GDDR5 128 896.0 960.0 179.2 192.0 110 10.1 3.3 1.0? Radeon HD 4750 Sep 9, 2009 RV740 40 826 137 PCIe 2.0 ×16 730 800 640:32:16 11.7 23.4 512 51.2 GDDR5 128 934.4 80 10.1 3.3 1.0? Radeon HD 4770 Apr 28, 2009 RV740 40 826 137 PCIe 2.0 ×16 750 800 640:32:16 12.0 24.0 512 51.2 GDDR5 128 960.0 192.0 80 10.1 3.3 1.0 109 Radeon HD 4810 May 28, 2009 RV770 CE 55 956 256 PCIe 2.0 ×16 625 750 900 900 640:32:8 5.00 6.00 20.0 24.0 512 57.6 GDDR5 128 800.0 960.0 160.0 192.0 95 10.1 3.3 1.0? Radeon HD 4830 Oct 21, 2008 RV770 LE 55 956 256 PCIe 2.0 ×16 575 900 640:32:16 9.20 18.4 512 1024 57.6 GDDR3 GDDR4 256 736.0 147.2 95 10.1 3.3 1.0 130$ Radeon HD 4850 Jun 25, 2008 RV770 PRO 55 956 256 PCIe 2.0 ×16 625 993 800:40:16 10.0 25.0 512 1024 2048 63.55 GDDR3 GDDR4 GDDR5 256 1000 200.0 110 10.1 3.3 1.0 199 (149) Radeon HD 4860 Sep 9, 2009 RV790 GT 55 959 282 PCIe 2.0 ×16 700 750 640:32:16 11.2 22.4 512 1024 96 GDDR5 256 896.0 179.2 130 10.1 3.3 1.0?.
Model Launch Code name Fab (nm) Transistors (million) Die size Bus interface Clock rate Core config Memory Processing power TDP support (version) Release Price (USD) Core (MHz) Memory (MHz) Pixel (/s) Texture (/s) Size Bandwidth (/s) Bus type Bus width Idle Max. Model Launch Transistors Die Size Core Processing power Memory TDP Bus interface Release Price (USD) Config Clock Texture (/s) Pixel (/s) Size Clock Bus type & width Bandwidth (/s) Idle Max. Texture fillrate is calculated as the number of Texture Mapping Units multiplied by the base (or boost) core clock speed. Pixel fillrate is calculated as the number of Render Output Units multiplied by the base (or boost) core clock speed. Precision performance is calculated from the base (or boost) core clock speed based on a operation. The effective data transfer rate of is quadruple its nominal clock, instead of double as it is with DDR memory.:: IGP (HD 6000). All models feature the UNB/MC Bus interface.
All models do not feature double-precision FP. With driver Update OpenGL 4.4 available (Last Catalyst 15.12). OpenGL 4.5 available with Crimson Beta (driver version 15.30 or higher).
All models feature Angle independent anisotropic filtering, UVD3, and capabilities, with up to three outputs. All models feature 3D Blu-ray Disc acceleration. Model Launch Fab Core Clock rate Config core Shared Memory Processing power compliance (version) Combined TDP Pixel (/s) Texture (/s) Bus width Bus type Bandwidth (/s) Idle Max. Radeon HD 6370D November 1, 2011 WinterPark 32 443 160:8:4 1.77 3.54 128 DDR3-1600 25.6 142 11.3 (110) 4.5 1.2 N/A Unknown 65 E2-3200 Radeon HD 6410D June 20, 2011 600 2.4 4.8 DDR3-1866 29.9 192 A4-3300, A4-3400 Radeon HD 6530D BeaverCreek 443 320:16:8 3.54 7.08 284 65–100 A6-3500, A6-3600, A6-3620, A6-3650, A6-3670K Radeon HD 6550D 600 400:20:8 4.8 12 480 A8-3800, A8-3820, A8-3850, A8-3870K. Model Launch Transistors Die Size Core Processing power Memory TDP Bus interface Release Price (USD) Config Clock Texture (/s) Pixel (/s) Size Clock Bus type & width Bandwidth (/s) Idle Max. ^ Boost values (if available) are stated below the base value in italic.
^ Texture fillrate is calculated as the number of Texture Mapping Units multiplied by the base (or boost) core clock speed. ^ Pixel fillrate is calculated as the number of Render Output Units multiplied by the base (or boost) core clock speed. ^ Precision performance is calculated from the base (or boost) core clock speed based on a operation. ^ The effective data transfer rate of is quadruple its nominal clock, instead of double as it is with DDR memory. ^:: IGP (HD 7000).
All models feature the UNB/MC Bus interface. All models do not support double-precision FP.
All models feature angle independent anisotropic filtering, UVD3.2, and capabilities, with up to four outputs. All models are based on the used in the Radeon HD 69xx Series (Cayman) GPUs. Model Released Fab Core Clock rate Config core Shared Memory Processing power compliance (version) Combined TDP Pixel (/s) Texture (/s) Bus width Bus type Bandwidth (/s) Idle Max.
Radeon HD 7340 June 6, 2012 Ontario 40 523 80:8:4 2.1 4.2 128 DDR3-1333 21.3 60 11.0 9 E2-1800 Radeon HD 7480D June 1, 2012 Scrapper 32 723 128:8:4 2.9 11.6 128 DDR3-1600 25.6 185 11.3 (110) 4.5 1.2 N/A Unknown 65 A4-4000, A4-5300 Radeon HD 7540D 760 192:12:4 Unknown DDR3-1866 29.9 292 A6-5400K Radeon HD 7560D Devastator 256:16:4 389 65–100 A8-5500, A8-5600K Radeon HD 7660D 760–800 384:24:8 2.7 16.2 584–614 A10-5700 (760 MHz), A10-5800K (800 MHz). ^ Boost values (if available) are stated below the base value in italic. ^ Texture fillrate is calculated as the number of Texture Mapping Units multiplied by the base (or boost) core clock speed. ^ Pixel fillrate is calculated as the number of Render Output Units multiplied by the base (or boost) core clock speed. ^ Precision performance is calculated from the base (or boost) core clock speed based on a operation.
^ The effective data transfer rate of is quadruple its nominal clock, instead of double as with DDR memory. ^:: Radeon R5/R7/R9 200 Series. ^ Boost values (if available) are stated below the base value in italic. ^ Texture fillrate is calculated as the number of Texture Mapping Units multiplied by the base (or boost) core clock speed. ^ Pixel fillrate is calculated as the number of Render Output Units multiplied by the base (or boost) core clock speed. ^ Precision performance is calculated from the base (or boost) core clock speed based on a operation. ^::.
The R9 285 utilizes loss-less colour compression which can increase effective memory performance (relative to GCN 1 st gen and 2 nd gen cards) in certain situations. ^ Base clock of R9 290 and R9 290X will maintain at 947 MHz and 1000 MHz before reaching 95 °C, respectively. Radeon R5/R7/R9 300 Series.
^ Boost values (if available) are stated below the base value in italic. ^ Texture fillrate is calculated as the number of Texture Mapping Units multiplied by the base (or boost) core clock speed. ^ Pixel fillrate is calculated as the number of Render Output Units multiplied by the base (or boost) core clock speed. ^ Precision performance is calculated from the base (or boost) core clock speed based on a operation.
Double precision performance of Hawaii cards is 1/8 of single precision performance, for the other it is 1/16 of single precision performance. ^::. The R9 380 utilizes loss-less color compression which can increase effective memory performance (relative to GCN 1 st gen and 2 nd gen cards) in certain situations. Radeon RX 400 Series. ^ Boost values (if available) are stated below the base value in italic.
Texture fillrate is calculated as the number of Texture Mapping Units multiplied by the base (or boost) core clock speed. Pixel fillrate is calculated as the number of Render Output Units multiplied by the base (or boost) core clock speed. Precision performance is calculated from the base (or boost) core clock speed based on a operation.::. ^ In October 2017 AMD branded an additional Polaris chip as 'RX 560', although it features less shader and texture mapping units than the first released RX 560. Radeon RX Vega Series. Main articles: and Model Launch Transistors Die Size Core Processing power Memory TBP Bus interface Release price (USD) Config Clock Texture (/s) Pixel (/s) Bus type & width Size Clock Bandwidth (/s) Radeon RX Vega 56 August 28, 2017 (14 nm) 000000000♠12.5 ×10 9 486 mm 2 3584:2 1471 258.9 329.5 74.0 94.1 8 8286 10544 518 659 HBM2 2048-bit 8 1600 410 210 W PCIe 3.0 ×16 $399 Radeon RX Vega 64 August 14, 2017 4096:2 1546 319.2 395.8 79.8 98.9 0 5 638 792 1890 483.8 295 W $499 Radeon RX Vega 64 Liquid 1406 1677 359.9 429.3 90.0 107.3 6 8 720 859 345 W $699. Main article: Model Launch Fab (nm) Core clock (MHz) Memory clock (MHz) Hardware Core config 1 Memory compliance (version) Notes Pixel (/s) Texture (/s) Size Bandwidth (/s) Bus type Bus width Rage LT (Rage II) Nov 1996 500 PCI 60 66 No 0:1:1:1 0.06 0.06 4 0.53 EDO, SDR, SGR 64 5 N/A Rage LT Pro (Rage Pro) Nov 1997 350 AGP, PCI 75 100 No 0:1:1:1 0.075 0.075 8 0.80 EDO, SDR, SGR 64 6 1.1 Motion Compensation Rage Mobility M/P (Rage 128) Nov 1998 250 AGP, PCI 90 Unknown No 0:2:2:2 0.18 0.18 8 Unknown SDR, SGR 64 Unknown Unknown M had 4 MB of integrated SDRAM, P had none.
IDCT, Motion Compensation. Rage Mobility M1 (Rage 128) Feb 1999 250, 90 90 No 0:2:2:2 0.18 0.18 8 0.72 SDR 64 6 1.2 M1 had 8 MB of integrated SDRAM, P had none. IDCT, Motion Compensation. Rage 128 GL Aug 1998 250 AGP, PCI 103 103 No 0:2:2:2 0.206 0.206 32 1.65 SDR 128 6 1.2 Rage Mobility 128 (Rage 128 Pro) Oct 1999 250 AGP, PCI 105 105 No 0:2:2:2 0.21 0.21 16 2.28 SDR 128 6 1.2 IDCT, Motion Compensation Rage Mobility M3 (AGP 4x) (Rage 128 Pro) Oct 1999 250 AGP, PCI 105 105 No 0:2:2:2 0.21 0.21 16 2.28 SDR 128 6 1.2 M3 had 8 MB of integrated SDRAM, IDCT, Motion Compensation. Rage Mobility M4 (AGP 4x) (Rage 128 Pro) Oct 1999 250 AGP, PCI 105 105 No 0:2:2:2 0.21 0.21 32 2.28 SDR 128 6 1.2 M4 had 16 MB of integrated SDRAM, IDCT, Motion Compensation.
Main article: OpenGL 3.3 is possible with latest drivers for all RV6xx. Texture fillrate is calculated as the number of Texture Mapping Units multiplied by the core clock speed. Pixel fillrate is calculated as the number of Render Output Units multiplied by the core clock speed.
Single Precision performance is calculated from the core clock speed based on a operation.:: IGP (HD 6000). All models feature the UNB/MC. All models do not feature double-precision FP. All models feature Angle independent anisotropic filtering, UVD3, and capabilities, with up to three outputs. Model Released Fab Core Clock rate Config core Shared Memory Processing power compliance (version) Combined TDP Pixel (/s) Texture (/s) Bandwidth (/s) Bus type Bus width Idle Max. Radeon HD 6250 November 9, 2010 Wrestler 40 280–400 80:8:4:2 1.12–1.6 2.24–3.2 8.525 DDR3-1066 64 44.8–64 11.3 (110) 4.5 1.2 N/A Unknown 9 C-30, C-50, Z-60 Radeon HD 6290 January 7, 2011 Ontario 276–400 C-60 Radeon HD 6310 November 9, 2010 Wrestler 492 2.0 4.0 80 18 E-240, E-300, E-350 Radeon HD 6320 August 15, 2011 508–600 2.032–2.4 4.064–4.8 10.6 DDR3-1333 82–97 E-450 Radeon HD 7340 June 6, 2012 Ontario 523 2.1 4.2 21.3 128 60 11.0 9 E2-1800.::: Compute units.
TDP specified for AMD reference designs, includes CPU power consumption. Actual TDP of retail products may vary. IGP (HD 6000G). All models include 11, 4.4 and 1.2. All models feature the UNB/MC. All models do not feature double-precision FP. All models feature Angle independent anisotropic filtering, UVD3 and capabilities, with up to three outputs.
All models feature VLIW5 Model Released Code name (nm) Core Clock (MHz) Core config 1 Shared Memory Processing power Max. ^ Boost values (if available) are stated below the base value in italic. Texture fillrate is calculated as the number of Texture Mapping Units multiplied by the base (or boost) core clock speed. Pixel fillrate is calculated as the number of Render Output Units multiplied by the base (or boost) core clock speed. Precision performance is calculated from the base (or boost) core clock speed based on a operation. The effective data transfer rate of is quadruple its nominal clock, instead of double as it is with other DDR memory.:: Radeon R5/R7/R9 M200 Series. Main article: Model Launch Core Processing power Memory Config Clock Texture (/s) Pixel (/s) Bus type & width Size Clock Band- width (/s) Radeon R5 M420 (Jet Pro) 15 May 2016 (28 nm) 320:20:8 780 855 15.6 17.1 6.24 6.84 499 547 DDR3 64-bit 2 1000 16.0 20 W Radeon R5 M430 (Exo Pro) 15 May 2016 320:20:8 1030?
20.6 8.2 659.2 659.2 DDR3 64-bit 2 1000 14.4 18 W Radeon R7 M435 (Jet Pro) 15 May 2016 320:20:8 780 855 15.6 17.1 6.24 6.84 499 547 GDDR5 64-bit 4 1000 32 20 W Radeon R7 M440 (Meso Pro) 15 May 2016 320:20:8 1021? 20.4 8.17 653 653 DDR3 64-bit 4 1000 16 20 W Radeon R7 M445 (Meso Pro) 14 May 2016 320:20:8 780 920 15.6 18.4 6.24 7.36 499 589 GDDR5 64-bit 4 1000 32 20 W Radeon R7 M460 (Meso XT) April 2016 384:24:8 1100 1125 26.4 27.0 8.8 9.00 844 864 DDR3 64-bit 2 900 14.4 Unknown Radeon RX 460 (Baffin) August 2016 (14 nm) 896:56:16 Unknown Unknown Unknown Unknown GDDR5 128-bit 2 1750 112 35 W? Radeon R7 M465 (Litho XT) May 2016 (28 nm) 384:24:8 825 960 19.8 23.0 6.6 7.68 634 737 GDDR5 128-bit 4 1150 32 Unknown Radeon R7 M465X (Tropo XT) May 2016 512:32:16 900 925 28.8 29.6 14.4 14.80 921 947 GDDR5 128-bit 4 1125 72 Unknown Radeon R9 M470 (Strato Pro) May 2016 (28 nm) 768:48:16 900 1000 43.2 48.0 14.4 1536 GDDR5 128-bit 4 1500 96 75 W Radeon R9 M470X (Strato XT) May 2016 896: 1100 56.0 61.6 16.00 1971 GDDR5 128-bit 4 1500 96 75 W Radeon RX 470 (Ellesmere Pro) August 2016 (14 nm) 2048:128:32 Unknown Unknown Unknown Unknown GDDR5 256-bit 4 1650 211 85 W?
Radeon RX 480M (Baffin) TBA 1024:xx:xx Unknown Unknown Unknown Unknown GDDR5 128-bit Unknown Unknown Unknown 35 W Radeon R9 M485X (Antigua XT) May 2016 (28 nm) 2048:128:32 723 92.5 GDDR5 256-bit 8 1250 160 100 W. Main article: Model Launch Core Core clock (MHz) Memory clock (MHz) Core config 1 (/s) Memory compliance (version) / idle (watts) Notes Size Bandwidth (/s) Bus type Bus width FireMV 2200 PCI. Jan 2006 RV280 GL 240 200 1:4:4:4 0.96 64 3.2 DDR 64 8.1 1.4 15 DMS-59 for dual DVI-D output FireMV 2200 PCIe.
Jan 2006 RV370 x16 324 196 2:4:4:4 1.296 128 3.2 DDR 64 9.0 2.1 15 DMS-59 for dual DVI-D output FireMV 2260 Jan 2008 RV620 2.0 x1/x16, PCI 600 500 40(8×5):4:4 2.4 256 32 256 10.1 3.3 15/8 Dual (with adapters: DVI-D) FireMV 2400 PCI. Jan 2008 RV380 500 500 2:4:4:4 2.0 128 16 DDR 128 9.0b 2.1 20 2x VHDCI for quad DVI-D output, VGA FireMV 2400 PCIe.
Model Launch Transistors Die Size Core Processing power Memory TBP Bus interface Graphic output Port Release Price (USD) Config Clock Texture (/s) Pixel (/s) Bus type & width Size Clock Band- width (/s) Radeon Pro WX 2100 June 2017 (14 nm) 103 mm 2 512:32:16 (8) 1219 39.0 19.5 SP 1.25 0.078 GDDR5 64 2 6000 48. ^ Boost values (if available) are stated below the base value in italic. Texture fillrate is calculated as the number of Texture Mapping Units multiplied by the base (or boost) core clock speed. Pixel fillrate is calculated as the number of Render Output Units multiplied by the base (or boost) core clock speed. Precision performance is calculated from the base (or boost) core clock speed based on a operation.:: and. To calculate driver enabled FP64 processing power see.
Radeon Vega Series. Model Launch Transistors Die Size Core Processing power Memory TBP Bus interface Release Price (USD) Config Clock Texture (/s) Pixel (/s) Bus type & width Size Clock Band- width (/s) Radeon Vega Frontier Edition (Air Cooled) 27 June 2017 (14 nm) 000000000♠12.5 ×10 9 484 mm 2 4096:2 1600 409.6 102.4 4 7 707.6 819.2 HBM2 2048-bit 16 1890 483.8 300 W PCIe 3.0 ×16 $999 Radeon Vega Frontier Edition (Liquid Cooled) 1382 1600 409.6 102.4 4 7 707.6 819.2 1890 483.8 350 W PCIe 3.0 ×16 $1499. ^ Boost values (if available) are stated below the base value in italic. Texture fillrate is calculated as the number of Texture Mapping Units multiplied by the base (or boost) core clock speed.
Pixel fillrate is calculated as the number of Render Output Units multiplied by the base (or boost) core clock speed. Precision performance is calculated from the base (or boost) core clock speed based on a operation. Texture fillrate is calculated as the number of Texture Mapping Units multiplied by the base (or boost) core clock speed. Pixel fillrate is calculated as the number of Render Output Units multiplied by the base (or boost) core clock speed. Single precision performance is calculated from the base (or boost) core clock speed based on a operation. Precision performance is calculated from the base (or boost) core clock speed based on a operation. FirePro Remote Series Model Launch Code name Fab (nm) Clock rate Core config 1 Memory Processing power compliance (version) TDP (Watts) Notes Core (MHz) Memory (MHz) Pixel (/s) Texture (/s) Size Bandwidth (/s) Bus type Bus width FirePro RG220 May 2010 RV711 55 2.0 x16 500 800 80(16×5):8:4:1 2.0 4.0 512 12.8 for GPU, RDRAM for PCoIP 64 80 No 10.1 3.3 1.0 35 Dual Ethernet ports plus DMS-59 for dual DVI-D output (no VGA host output) FirePro R5000 February 25, 2013 Pitcairn LE GL (GCN 1st gen) 28 PCIe 3.0 x16 825 800 768:48:32:12 26.4 39.6 2048 102.4 256 1267.2 79.2 11.1 4.5 1.2.:::.
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![Ati radeon premium graphics drivers for macos 10.13.5 Ati radeon premium graphics drivers for macos 10.13.5](https://www.techpowerup.com/gpu-specs/images/g/282.jpg)
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The following guide will show you how to install AMD Radeon graphics drivers on a Mac Pro 2013 running Windows. Currently the Mac Pro uses workstation graphics from the AMD FirePro D-series, which utilizes the same chipset as the Radeon 7900 / R9 series. This means that you can use those graphics drivers instead of the FirePro drivers. Why would somebody do this? Let’s say you have a Mac Pro as a professional workstation at home, you’d most likely use Mac OS X for those tasks. If not, then it would be a waste of money.
If you’re into PC gaming, you can dual-boot the Mac Pro with Windows and use it as a decent gaming rig. The AMD FirePro drivers are optimized for professional applications, and not for gaming. Thus playing a game using those drivers won’t be optimal (read: dramatic). However, by installing the AMD Radeon drivers it will be optimized for gaming.
You can use the latest gaming profiles including CrossFire, which will dramatically improve the performance. I don’t have any numbers to compare between those drivers, but on the same hardware with the FirePro drivers (dual D700) it can barely manage to run Left 4 Dead 2 (a game from 2009) on Medium quality (1920×1080).
Using the Radeon 15.11 drivers I can play Fallout 4 on High – Ultra quality (2560×1440), so the performance boost is insane. In this tutorial I will show you how to install these drivers.
I’ve written a tutorial about this in the past, but that stopped working with the Catalyst 15.x drivers The installation will fail immediately as it will complain that it can’t detect a compatible graphics card (“ We are unable to find a driver for your system. No supported AMD hardware was detected”). Installing the drivers manually will cause performance issues or even refuse to load at all. This tutorial has been updated for that purpose. Make sure you read this tutorial first, and please be advised that this procedure is not supported by AMD and I’m not responsible for any issues with your system. I’ve used the following tutorial as reference: You will need. Microsoft Windows.
I’ve used Windows 8.1 x64, but it should work with Windows 10 as well. AMD Radeon drivers for your OS. You can find them on the AMD website in the category Desktop Graphics AMD Radeon HD series AMD Radeon HD7900 series. I’ve used the AMD Radeon Software Crimson Edition 15.11. Windows Driver Toolkit: (install the Visual Studio Community Edition first, and then the Driver Toolkit) You will be performing the following steps:. Modifying the driver INF file. Rebuilding the driver CAT file.
Creating a self-signed certificate. Signing the driver files. Installing the modified driver Phase 1: Extracting the drivers and disabling the hardware detection.
Download the latest AMD Radeon drivers and run it. Choose a destination where to unpack the files. After unpacking, it will most likely show an error message that it can’t detect a graphics card.
Just click on OK to close it. In this example I will extract it to C: amdcustom. Open the folder where you’ve unpacked the driver.
From there, go to the folder Config and open the file InstallManager.cfg in Notepad ( C: amdcustom Config InstallManger.cfg). You should see the following line in the file: WorkaroundInstall=false. Create the following line below that: EnableFalcon=true. Phase 2: Acquiring the Hardware IDs for your graphics cards. Open Device Manager and expand the section Display Adapters. Open the Properties for each card, go to the tab Details and choose the section Hardware IDs.
Copy the full hardware ID (the longest string) and paste that somewhere. Now you should have 2 Hardware IDs. The hardware ID consists roughly of 2 parts: the chipset and the Subsys ID. The chipset part is used to identify the type of driver you need. On a D700 card, this chipset is PCI VEN1002&DEV6798. Make a note of the chipset from your graphics cards.
This part should be identical on both of them. Phase 3: Modifying the.INF file. Starting at the root folder where you’ve unpacked the drivers, go to the folder Packages Drivers Display WB6AINF (if you can’t find this folder, check if another folder exists in the Display folder ending with INF and open that one). Take a note of the full path of this folder. ( C: amdcustom Driver Display WB6AINF). Open the file CU296570.inf in notepad. And just like the previous step: if it doesn’t exist, check if another.inf file exists in there and open that one instead.
Search for the chipset which you’ve taken from the Hardware IDs in phase 2. There should be multiple lines starting with this chipset. Go to the last one.
Mine looked like this: '%AMD6798.36%' = ati2mtagR575, PCI VEN1002&DEV6798 These lines consist of 3 parts: the driver identifier ( AMD6798.36), which is the name of the driver and a unique number. The chipset name ( ati2mtagR575) and the hardware ID it applies to.
Replace the hardware ID on that line to the Hardware ID of your 2nd card. Go to the line above that, and replace that Hardware ID with the Hardware ID of your 1st card. The result should look something similar to this: '%AMD6798.35%' = ati2mtagR575, PCI VEN1002&DEV6798&SUBSYS0128106B&REV00 '%AMD6798.36%' = ati2mtagR575, PCI VEN1002&DEV6798&SUBSYS0127106B&REV00.
Now search for the driver identifier of one of these lines without the quotes and% character. In my case this was AMD6798.35. This should bring you to the section where the name labels are assigned to the drivers. Make sure that both lines have the same label. In my case the result looks like this: AMD6798.35 = 'AMD Radeon R9 200 Series' AMD6798.36 = 'AMD Radeon R9 200 Series'. Now search for the chipset name, surrounded by brackets. In my case I had to search for ati2mtagR575.
This will bring you to a section with configuration options for that chipset. In this section there should be a couple of lines starting with ExcludeID. Remove all of them. Then save the file. Phase 4: Rebuilding the.CAT file Make sure that you’ve installed the Windows Driver Toolkit. Open a Command Prompt as Administrator and browse to the following folder: C: Program Files (x86) Windows Kits 10 bin x86.
If you’re on a 32-bit system, it should be: C: Program Files Windows Kits 10 bin x86. For Windows 10 x64 use this command: inf2cat.exe /Driver:”C: amdcustom Driver Display WB6AINF” /OS:10X64 For Windows 8.1 x64: inf2cat.exe /Driver:”C: amdcustom Driver Display WB6AINF” /OS:63X64 If you get a Command not Found message, then the inf2cat.exe file is located somewhere else inside C: Program Files (x86) Windows Kits.
Find this file and use Command Prompt to browse to that folder. I believe it’s the x86 folder of the highest Windows version you can find in there. Then repeat this command again.
Phase 5: Creating a self-signed certificate This phase is only required if you don’t own a Code Signing certificate from a trusted CA (99% of the people reading this probably don’t) and haven’t yet installed a previous driver using this method (it should still exists on your system). While having the Command Prompt still open and in the folder from the previous phase, use the following command to create a self-signed certificate: makecert -r -pe -ss PrivateCertStore -n CN=mac.local(MacProVideoDriver) MacProVideoDriver.cer Phase 6: Signing the driver There should be a.CAT file in the same folder where the.INF file from Phase 3 is located using the same name. Take a note of the full path to this file, including the file name of the.CAT file. While having the Command Prompt still open and in the folder from the previous phase, use the following command to sign the driver: signtool sign -v -s PrivateCertStore /n mac.local(MacProVideoDriver) /t C: amdcustom Driver Display WB6AINF CU296570.cat Phase 7: Installing the driver If you’ve used the self-signed certificate from Phase 5 to sign the driver, Windows won’t let you install it because it’s not trusted.
You must configure Windows to disable Driver Signature Verification. This means that Test Mode should be activated.
On Windows 8 and Windows 10, I can do this using the following command in Command Prompt: Bcdedit.exe -set TESTSIGNING ON Make sure to reboot afterwards. Now you can install the driver by running the setup application in the root folder where you’ve unpacked the files in Phase 1: C: amdcustom setup.exe Troubleshooting Q: I can’t find the chipset in the INF file A: You’ve most likely opened the properties of the wrong display adapter or AMD has removed support for this chipset entirely. In this case you’re out of luck. Q: When I attempt to install the driver, I get an error message saying that no supported AMD hardware was detected. A: Make sure that you’ve edited the configuration file from Phase 1. Also make sure that you’re running the setup application from the extracted files, not directly running the file you’ve downloaded from the AMD website.
Ati Radeon Graphics Drivers
Q: ‘A digitally signed driver is required’ is shown during installation A: The Driver Signature Verification has not been disabled. Disable it and try again Q: The drivers aren’t loaded because they haven’t been signed A: Make sure that they are signed.
Use Phase 5 and 6 as reference. Then, fully remove the drivers and reinstall them. Don’t just reinstall the drivers, as Windows assumes it’s the same driver and skips the installation.
Q: signtool and makecert can’t be found A: Make sure that Visual Studio Community edition and Windows Driver Toolkit are both installed (in that order). This entry was posted in and tagged,.
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A brief video on how to upgrade or replace the graphics card of 2006 to 2011 Mac Pro computer models. The video card driver installs automatically and it is transparent to the user; a true plug and play behavior. Before working on the computer: 1. Shut down the computer. Wait 5 to 10 minutes to allow the computer's internal components to cool down. Unplug all external cables from the computer except the power cord.
Touch the metal chasis of the computer to discharge any static electricity from your body. Remove the power cord. IMPORTANT: BEFORE WORKING ON YOUR COMPUTER, MAKE SURE YOU ARE ESD SAFE! Just Google the word ESD and find out how to prevent electrostatic build up.
If you wash your hands with water before working on your computer, could also prevent electrostatic build up; make sure you don't have any water excess on your hands.