Ati radeon x 1300 pro
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The Radeon X PRO was a graphics card by ATI, launched in November Built on the 80 nm process, and based on the RV graphics processor, in its RV PRO variant, the card supports DirectX c. Since Radeon X PRO does not support DirectX 11 or DirectX 12, it might not be able to run all the latest games. ATI Radeon X Pro (PCI-e, MB) overview and full product specs on CNET. Dec 19, · This package provides the AMD ATI Radeon x Graphics Driver and is supported on Dimension, Inspiron Desktop, OptiPlex and Vostro Desktop models that are running the following Windows Operating System: XP. Get the latest driver Please enter your product details to view the latest driver information for your system.
Ati radeon x 1300 pro.ATI Radeon X Pro (MB, AGP) Specs – CNET
The Radeon X PRO was a graphics card by ATI, launched in November Built on the 80 nm process, and based on the RV graphics processor, in its RV PRO variant, the card supports DirectX c. Since Radeon X PRO does not support DirectX 11 or DirectX 12, it might not be able to run all the latest games. The Radeon X PRO was a graphics card by ATI, launched in October Built on the 90 nm process, and based on the RV graphics processor, in its RV PRO variant, the card supports DirectX c. Since Radeon X PRO does not support DirectX 11 or DirectX 12, it might not be able to run all the latest games. Download Video: ATI X Pro Driver Version: A03 for Windows to display driver. Join or Sign In. Sign in to add and modify your software. MB ATI Radeon X Secondary; MB ATI Radeon Subcategory: Video Drivers.
ATI Radeon X1300 Pro (PCI-e, 256MB) Specs
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ATI Radeon X Pro (PCI-e, MB) Specs – CNET
Stanford University sensor produces volumetric images
Photography is usually associated with 2D imaging. Researchers at Stanford University have created an image sensor, which in addition, allows you to estimate the distance to objects in the frame.
The development is based on the use of technology, which scientists themselves call “multi-aperture image sensor”. Unlike conventional sensors used in digital cameras, the new sensor is split into partially overlapping 16×16 pixel arrays. The imaging in each array is assigned to a separate optical system (hence the name of the sensor).
After the photo is taken, the image processing program analyzes the differences in the position of the same elements in different arrays – for example, shirts against the background of wallpaper. These differences make it possible to calculate the distance to various elements of the image – in our case, to the shirt and to the wall covered with wallpaper.
In the resulting frame, including the “depth map”, for each pixel, not only the red, green and blue light components are stored, but also the distance. University scientists have not yet developed a specific format for the data received, but they say distance information can be stored in a JPEG file as metadata.
The new technology is said to provide several additional benefits – for example, it can reduce noise and crosstalk between pixels of different colors. In addition, some complication of the sensor design can lead to simplification of the design of lenses, which are known to make a significant contribution to the cost of cameras.
However, you have to pay for everything. Among the shortcomings of the new sensors are called a lower resolution than a conventional sensor and a significant (approximately tenfold) increase in the need for processing power for image processing, which, in turn, negatively affects the operating time from a single battery charge. In addition, not all objects are suitable for building a three-dimensional picture – for this they must have a pronounced texture or other details.
The bottom photo shows a prototype sensor with a resolution of 3 megapixels with 12 616 arrays. Pixel side size – 0.7 microns. Chip power consumption is 10.45 mW.
Source: Stanford University