These video cards are only able to handle old and resource-intensive games.
NVIDIA NVS 4200M
The business-grade graphics card based on the GeForce GT 520M has special BIOS drivers that are useful for business applications.
Core - 810 MHz, shaders - 48, DirectX 11. Memory - 800 MHz, 64-bit.
AMD Radeon HD 8350G
Integrated graphics in AMD Richland (A4) processors without dedicated video memory.
Core - 514-720 MHz, shaders - 128, DirectX 11.
AMD Radeon HD 8330
GCN-based integrated graphics with 128 stream processors, but no native video memory. Usually paired with AMD processors Richland A4-5000 "Kabini".
Core - 500 MHz, shaders - 128, DirectX 11.1.
AMD Radeon R3 (Mullins/Beema)
Integrated graphics based on the GCN architecture.
Core - 350 - 600 MHz, shaders - 128, DirectX 11.2. Memory - 64-bit.
AMD Radeon HD 6510G2
Two graphic cards, connected via asymmetric CrossFire - discrete Radeon HD 6430M/6450M/6470M and built-in 6480G A-series processors.
Shaders - 400, DirectX 11.
AMD Radeon HD 7450M
Core - 700 MHz, shaders - 160, DirectX 11. Memory - 1800 MHz, 64-bit.
NVIDIA GeForce 610M
Entry-level graphics based on the older GeForce GT 520M or GeForce GT 520MX.
Core - 672-900 MHz, shaders - 48, DirectX 11. Memory - 1800 MHz, 64-bit.
NVIDIA GeForce 705M
Entry-level graphics based on the GF119 chip, like its predecessors the GeForce GT 520M, 520MX and 610M.
Core - 775 MHz, shaders - 48, DirectX 11. Memory - 1800 MHz, 64-bit.
AMD Radeon HD 6470M
Entry-level graphics based on the Seymore XT core and including the UVD3 video processor.
Core - 700/750 MHz, shaders - 160, DirectX 11. Memory - 800 MHz, 64-bit.
AMD FirePro M3900
Entry-level graphics for mobile workstations based on the AMD Radeon 6470M.
Core - 700-750 MHz, shaders - 160, DirectX 11. Memory - 900 MHz, 64-bit.
NVIDIA GeForce GT 520M
Entry level graphics based on GF119 chip with 64-bit memory bus or GF108 chip with 128-bit but with lower clock speeds.
Core - 740/600 MHz, shaders - 160, DirectX 11. Memory - 800/900 MHz, 64/128-bit.
AMD Radeon HD 7420G
Processor-integrated graphics found on Trinity A4 series processors (such as the A4-4300M). Based on the VLIW4 architecture of the Radeon HD 6900 desktop series.
Core - 480-655 MHz, shaders - 128, DirectX 11.
Intel HD Graphics (Haswell)
Graphics integrated into Haswell Celeron and Pentium processors.
Core - 200-1000 MHz, shaders - 10, DirectX 11.1.
AMD Radeon HD 6520G
Graphics integrated into the Llano A6 series processors.
Core - 400 MHz, shaders - 320, DirectX 11.
AMD Radeon HD 8310G
Graphics embedded in AMD Richland ULV A4 series processors that do not have their own video memory.
Core - 424-554 MHz, shaders - 128, DirectX 11.
AMD Radeon HD 7400G
Graphics integrated in Trinity A4 series processors (eg A4-4355M). Based on the VLIW4 architecture of the desktop Radeon HD 6900 series.
Core - 327-423 MHz, shaders - 192, DirectX 11.
AMD Radeon HD 6480G
Graphics embedded in A4-Series Llano processors that do not have their own video memory.
Core - 444 MHz, shaders - 240, DirectX 11.
NVIDIA GeForce GT 415M
The slowest of the GT 400M series.
Core - 500 MHz, shaders - 48, DirectX 11. Memory - 800 MHz, 128-bit.
NVIDIA GeForce 410M
Entry-level graphics based on the GF119 chip and comparable in performance to the 520M, but running at lower clock speeds.
Core - 575 MHz, shaders - 48, DirectX 11. Memory - 800 MHz, 64-bit.
AMD Radeon HD 7370M
Renamed HD 6370M / HD 547.
Core - 750 MHz, shaders - 80, DirectX 11. Memory - 1600 MHz, 64-bit.
AMD Radeon HD 6370M
Renamed HD 5470.
Core - 750 MHz, shaders - 80, DirectX 11. Memory - 800 MHz, 64-bit.
AMD Radeon HD 8280
Integrated graphics based on the GCN architecture and does not have its own video memory. Usually paired with AMD E2-3000 "Kabini" processors.
Core - 450 MHz, shaders - 128, DirectX 11.1.
ATI Mobility Radeon HD 5470
Entry-level graphics with support for GDDR5 memory, but with only 80 processor cores. Supports Eyefinity (up to 4 monitors) and eight-channel HD audio via HDMI port. The performance is comparable to the older GeForce 8600M GT.
Core - 750 MHz, shaders - 80, DirectX 11. Memory - 1800 MHz, 64-bit.
AMD Radeon HD 6450M
Entry-level graphics based on the Seymore-PRO chip and supporting Eyefinity+.
Core - 600 MHz, shaders - 160, DirectX 11. Memory - 800 MHz, 64-bit.
AMD Radeon HD 7430M
Renamed Radeon HD 6450M.
Core - 600 MHz, shaders - 160, DirectX 11. Memory - 1800 MHz, 64-bit.
AMD Radeon R6 (Mullins)
Graphics integrated into some AMD Mullins processors based on the GCN architecture.
Core - 500 MHz, shaders - 128, DirectX 11.2. Memory - 64-bit.
AMD Radeon HD 8240
Integrated graphics based on the GCN architecture and does not have its own video memory. Usually paired with AMD E1-2500 "Kabini" processors.
Core - 400 MHz, shaders - 128, DirectX 11.1.
AMD Radeon HD 8250
Integrated graphics in AMD A6-1450 "Temash" processors. Based on the GCN architecture.
Core - 300-400 MHz, shaders - 128, DirectX 11.1.
ATI Mobility Radeon HD 5450
Entry-level graphics with the same frequency and performance as the HD 4570, but with lower power consumption.
Core - 675 MHz, shaders - 80, DirectX 11. Memory - 800 MHz, 64-bit.
AMD Radeon R2 (Mullins/Beema)
Graphics integrated in AMD Beema or Mullins processors. Based on the GCN architecture.
Core - 300-500 MHz, shaders - 128, DirectX 11.2. Memory - 64-bit.
Intel HD Graphics 3000
Graphics embedded in Intel processors Sandy Bridge (Core ix-2xxx).
Core - 350-1350 MHz, shaders - 12, DirectX 10.1.
NVIDIA GeForce 405M
Renamed GeForce 310M / 315M, still based on the G2xx GeForce G210M architecture.
Core - 606 MHz, shaders - 16, DirectX 10.1. Memory - 1600 MHz, 64-bit.
AMD Radeon HD 6430M
The slowest graphics based on the Seymour chip, has support for the UVD3 video processor and Eyefinity +.
Core - 480 MHz, shaders - 160, DirectX 11. Memory - 800 MHz, 64-bit.
AMD Radeon HD 6380G
Graphics embedded in E2 Llano series processors that do not have their own video memory.
Core - 400 MHz, shaders - 160, DirectX 11.
ATI Mobility Radeon HD 5430
Based on a chip codenamed Park LP, the slowest of the HD 5400 series.
Core - 550 MHz, shaders - 80, DirectX 11. Memory - 800 MHz, 64-bit.
AMD Radeon HD 8210
Integrated graphics based on GCN, usually paired with AMD A4-1250 "Temash" and E1-2100 "Kabini" processors.
Core - 300 MHz, shaders - 128, DirectX 11.1.
Intel HD Graphics 2500
Graphics integrated in Ivy Bridge (Core ix-3xxx) processors.
Core - 650-1150 MHz, shaders - 6, DirectX 11.
Intel HD Graphics (Ivy Bridge)
Graphics integrated into Ivy Bridge Celeron and Pentium processors.
Core - 350-1100 MHz, shaders - 6, DirectX 11.
10 Mar. 2016
On this page below there are links to download the latest free AMD graphics card drivers Radeon HD 8200 / R3, which is part of the Radeon HD 8000 series. The installation files are taken from the official website and are suitable for: Windows 7, 10, 8, 8.1, XP, Vista 32/64-bit (x86/x64).
For the convenience of choosing the right files, the version of your Windows and its bit depth (“bit depth”) are indicated below.
Your computer runs on:
- Download (153.5 MB / version 16.8.2 ( Crimson Edition 16.8.2 Hotfix) / release date 08/12/2016)
For Windows 7 32-bit
- Download (239.8 MB / version 16.8.2 (Crimson Edition 16.8.2 Hotfix) / release date 08/12/2016)
For Windows 7 64-bit
- Download (134.8 MB / version 16.8.2 (Crimson Edition 16.8.2 Hotfix) / release date 08/12/2016)
For Windows 10 32-bit
- Download (208.24 MB / version 16.8.2 (Crimson Edition 16.8.2 Hotfix) / release date 08/12/2016)
For Windows 10 64-bit
- Download (205 MB / version 14.4 (Catalyst Software Suite) / release date 04/25/2014)
For Windows 8 32-bit
- Download (260 MB / version 14.4 (Catalyst Software Suite) / release date 04/25/2014)
For Windows 8 64-bit
- Download (154.21 MB / version 16.8.2 (Crimson Edition 16.8.2 Hotfix) / release date 08/12/2016)
For Windows 8.1 32-bit
- Download (239.88 MB / version 16.8.2 (Crimson Edition 16.8.2 Hotfix) / release date 08/12/2016)
For Windows 8.1 64-bit
- Download (179 MB / version 14.4 (Catalyst Software Suite) / release date 04/25/2014)
For Windows XP 32 and 64-bit
- Download (151 MB / version 13.12 (Catalyst Software Suite) / release date 12/18/2013)
For Windows Vista 32-bit
- Download (209 MB / version 13.12 (Catalyst Software Suite) / release date 12/18/2013)
For Windows Vista 64-bit
Fallback - Obtain Drivers Using AMD Driver Autodetect
This option convenient because the program AMD Driver Autodetect will automatically select and download the latest working drivers that fit your AMD graphics card and your Windows version. The program does not need to be installed, it was created by AMD and the files are downloaded from their official servers.
Instruction:
- Run AMD Driver Autodetect and it will automatically pick up required files to install drivers.
- To download files, click on the "Download Now" button.
- Wait for the files to download and start the installation.
AMD produces not only high-quality and well-known for its performance (albeit energy-intensive) processors, but also video radeon cards, the characteristics of which are sufficient to run the most productive games.
This technique, especially released during the last 2 years, allows you to work with resource-intensive applications (3D graphics).
Although in order to pick suitable model and to determine if its capabilities are enough to perform your tasks, it is worth considering the parameters of GPUs in more detail.
In order to make it easier to get acquainted with the characteristics of the equipment, you can make a table indicating the main values \u200b\u200bthat affect the performance and functionality of the video card.
These include bus parameters (frequency and bit depth), memory type, manufacturing process used in the manufacture of the graphics processor, data speed and memory size.
You can stop the attention on the consumption of electricity, on which the power of the computer's power supply and the method of cooling the device depend.
Memory frequency and bus width
The frequency of the video card memory, first of all, affects the speed of its operation. The average value of this indicator is 1000 MHz for HBM memory and 6000-8000 for GDDR5.
At the same time, the dependence of the card's performance on its frequency is not always directly proportional, since the second indicator that affects the throughput of the device is the bus width.
First of all, depends on the characteristics of the tire throughput video card memory.
The larger its width, the faster the data is processed. GPU(GPU).
So, 64-bit boards are practically not used in modern computers, although they are still available for sale in online stores.
More modern models of video cards have a bit depth of 128 and 256 bits, top versions - 512 bits and higher.
The top ten AMD models to date have the following bit depths:
- RX 470, 480 and 380 series - 256-bit;
- 390th series R9 - 512 bits;
- the latest models, R9 Fury and Nano, equipped with a new type of memory - 4096 bits;
- one of the produced new technology with a manufacturing process of 18 nm models, RX has a bit depth of only 128 bits, which is why it has a low data transfer rate, although it is relatively cheap, representing a budget option for gamers.
High bit depth of the latest videos AMD cards, obtained through the use of multi-layer memory modules, allows you to have a lower frequency, providing more power.
At the same time, the specific energy consumption of the equipment (1 W of power per 1 GB / s data transfer rate) becomes lower - R9 models with HBM memory consume less electricity compared to other cards.
The main feature of the Radeon Fury and Nano is the ability to run more graphics-demanding applications and resource-intensive games with high rate FPS (Frame Rate).
Type and amount of memory
GDDR5 memory, which until recently was considered the best option for a graphics card, is starting to become obsolete.
Moreover, manufacturers say that its capabilities are approaching their limit, and begin to look for new solutions. One of them is HBM technology, which is different:
- increased productivity;
- less need for electricity;
- feature of the organization of the memory subsystem.
For this reason, modern and more expensive video cards R9 Fury, Fury X and Nano, having a low frequency of 1000 MHz, work 33% faster than the flagship of the previous generation R9 390X - 512 GB / s instead of 384.
The same relatively new, but budget model RX 460 at a good frequency of 1212 MHz has 5 times lower speed compared to the most powerful model manufacturer, as it not only has GDDR5 memory, but also a bit depth of 128 bits.
The amount of memory for modern Radeon graphics devices is at the level of 4096-8192 MB.
At the same time, modern games require at least 4 GB of memory to run with normal settings.
Although this indicator is not so important for HBM memory, attention should be paid to the bandwidth, which is higher than that of GDDR.
Process technology
The main design elements of the processor, including the graphics processor, are transistors that pass or block electricity in a certain direction.
The performance of the video card depends on their number, and this indicator, in turn, depends on the size of the transistors and the technology used in their manufacture.
Most graphics card developers, including AMD, use the 28nm transistor process technology.
All modern models have this indicator value, except for the RX 400 series.
New generation graphics processors are based on 14 nm technology. And in the future, Radeon cards will be produced using the 7nm process technology.
The 14nm technology is expected to provide graphics core 2x to 3x performance improvement and supports up to 3 independent monitors.
Bandwidth
The speed of data transfer using video cards primarily depends on the product of the effective frequency of their memory and the bit depth.
The larger this value, the faster the information is transmitted, and, therefore, the games work better.
At the same time, new memory HBM bit depth is 8 times higher, which means that the frequency can be lower.
For example, for the R9 Fury X, the throughput is (4096/8) bytes*1 GHz = 512 GB/s. This value is more than enough to run any game at maximum settings.
The 128-bit RX 460 video card can transfer only 112 GB / s of information (= 7000 * 128/8).
Power consumption and cooling
The power consumption of different video cards depends on various factors:
- the technology used to create the processor;
- memory type;
- graphics card power.
At the same time, even in the same series of cards, you can find models with high and low power consumption.
So, for example, the R9 390 and 390X models consume up to 275 W of power and require a power supply unit of at least 500 W.
The same figure for more performance cards R9 Fury and Fury X. Whereas R9 Nano consumes only 175 W, although it is not inferior to the rest in performance and even surpasses them.
And the low-cost RX 460 consumes only 75 watts, with an optimal power-to-energy ratio.
Power up to 75W provided by one PCI slot express.
Exceeding this value is compensated by additional 8-pin sockets, through each of which you can apply up to 150 watts.
This means that a single PCI slot is not enough to provide power to modern AMD cards and additional power is required.
The design of the cooling system also depends on the power consumption of the GPU:
- less productive models are cooled by a conventional fan system;
- processors capable of running modern games also require more serious cooling - liquid. For example, R9 Nano's ventilation system includes not only a cooler, but also an evaporation chamber with heat pipes. And the R9 Fury has a metal plate under the radiator.
conclusions
AMD, like its main competitor Nvidia, continues to increase most of the characteristics of its video cards.
And the Fury series surpasses the previous generation in most indicators (except for power consumption).
Although this only applies to older versions, budget RX graphics cards based on the new 14nm process are inferior to older flagships and are comparable to inexpensive models of the past generation.
Therefore, when choosing a card for your PC, the main attention will still have to be paid to the financial side of the issue - high costs will allow you to get better characteristics.