Sunday, 12 July 2015

EVGA GeForce GTX TITAN X 12 GB DDR5 Superclocked

EVGA GeForce GTX TITAN X Superclocked 12GB GDDR5 384bit, PCI-E 3.0 DVI-I, 3 x DP, HDMI, SLI, HDCP, G-SYNC Ready Graphics Cards 12G-P4-2992-KR

 

 http://www.dubaigamers.net/shop/evga/evga-geforce-gtx-titan-x-12-gb-ddr5-superclocked/

 

Product Description

EVGA GeForce GTX TITAN X 12 GB DDR5 Superclocked
Product Highlights
  • 1127 MHz Core – Boostable to 1216 MHz
  • 3072 CUDA Cores
  • Maxwell Architecture
  • 12GB GDDR5 vRAM
  • 7010 MHz Effective Memory Clock
  • 384-Bit Memory Interface
  • DisplayPort, HDMI, DVI Outputs
  • 4K Output Through DisplayPort and HDMI
  • Blower-Style Cooler
  • PCI Express 3.0 x16 Interface
EVGA GeForce GTX TITAN X 12 GB DDR5 Superclocked OVERVIEW
Experience overclocked “Big Maxwell” with the Superclocked TITAN X Graphics Card from EVGA. The TITAN X design offers an impressive chipset configuration inclined towards high-resolution gaming and graphics rendering. Hardware wise, this TITAN X chipset features 12GB of GDDR5 vRAM coupled to 3072 CUDA cores overclocked at 1127 MHz with a 384-bit interface for a 336.5 GB/s memory bandwidth. The CUDA cores are arranged using NVIDIA’s Maxwell architecture, allowing the GPU to operate using less power while generating less heat than the previous generation Kepler architecture. Operating at full tilt during intense gaming sequences, the card will only draw a maximum of 250 watts of power.
The front panel of the card features a variety of outputs. There are three DisplayPort outputs in addition to an HDMI output and a DVI output. 4K resolution can be output through the TITAN X’s DisplayPort and HDMI terminals. Even if the card is connected to a lower resolution display, the TITAN X can use technologies like DSR and MFAA to leverage the extra resolution for a higher quality image. The TITAN X is not just about high-resolution gaming. Computationally intensive programs can utilize the GPU’s 3072 cores to accelerate tasks using CUDA or other APIs.
For cooling, EVGA implemented NVIDIA’s blower-style cooler. This cooler uses a radial fan to force air through the card’s heatsink and out of the case through the front of the card. This cooling configuration is good for SLI or other configurations where space between computer components can be a concern.
SLI Ready
With a compatible motherboard and a connecting bracket, two or more NVIDIA GPUs of the same model can combine processing power using NVIDIA’s Scalable Link Interface (SLI). How the cards work together can be customized to suit your preferences. Alternate frame rendering has each alternating card prepare the next frame, essentially multiplying the capabilities of a single card’s maximum capable frame rate output. Each card in the configuration can also be used to improve anti-aliasing by being able to process an image in parallel with the other cards before filtering out jagged edges.
Note: The benefits of SLI will vary based on component configuration.
CUDA
NVIDIA’s parallel computing platform which enables an increase in computing performance by harnessing the parallel nature of GPU processing. CUDA compatible applications can assign intensive parallel computing tasks, such as real-time video rendering, to the GPU to process, freeing up the computer’s CPU to run other tasks.
3D Vision Support
When used with a 3D Vision compatible monitor and 3D Vision active-shutter glasses, full-HD resolution images are delivered to each eye. Additionally, with a 3D LightBoost compatible screen, image brightness will be maintained while using the glasses and ghosting will be reduced.
PhysX
NVIDIA’s hardware accelerated physics engine computes how objects move in space in real time. Having a physics engine precludes the need for programs to pre-animate rendered objects which can give an unrealistic “canned animation” feel. The PhysX engine also allows for designers to create more detailed objects, relying on the GPU’s processing power rather than a bloated programming back end.
Adaptive V-Sync
NVIDIA’s Adaptive Vertical Sync minimizes stuttering and tearing by monitoring and adjusting the card’s frame rate output. At high frame rates, Adaptive V-Sync is enabled to slow down the output frame rate to prevent tearing as a result of losing sync with your monitor. At lower frame rates, Adaptive V-Sync will automatically be disabled to minimize stuttering.
GPU Boost 2.0
Boosts the card’s clock speed in real time based on the target temperature. If the card is running below the set target temperature, GPU Boost 2.0 will increase the clock speed to improve performance. The target temperature can be reset depending on your preference so you can have the card run more quietly for everyday tasks and older games, and run at full tilt during intense high-resolution gaming sequences.
G-Sync Support
When used with a monitor that has G-Sync hardware installed, the monitor’s refresh rate will sync and lock with the graphics card’s output frame rate. Establishing this sync removes tearing and stuttering which can result from conventional fixed screen refresh rates, especially important for gaming in stereoscopic 3D. An additional benefit of G-Sync is reduced lag so gamers will benefit from the improved command response time as well.
4K
Display graphics, games, and video in UHD resolution (3840 x 2160) for increased detail on 4K resolution displays. Games which support 4K resolutions will display greater detail for enhanced realism and reduced artifacts. 4K video from services such as Netflix and YouTube can deliver full resolution video for an enhanced media experience.
Surround
With a single card you can expand your PC games across three displays in stereoscopic 3D for an “inside the game” experience. Add in a fourth accessory display to get access to your email, web, and other applications.
VXGI
Introduced with NVIDIA’s Maxwell architecture, Voxel Global Illumination can process advanced indirect lighting and reflections in real time, enabling programs to rely on the processing hardware to render reflections and shades rather than memory hogging pre-rendered textures.
MFAA
NVIDIA’s Multi-Frame Anti-Aliasing is an efficient anti-aliasing method introduced with their Maxwell architecture. MFAA leverages the processing efficiency of the GPU architecture in order to analyze textures as they change rather than preloading larger textures into the card’s memory.
DSR
NVIDIA’s Dynamic Super Resolution is a scaling utility introduced with their Maxwell architecture. DSR uses the GPU architecture in order to take advantage of 4K capabilities with lower screen resolutions by having the graphics card render at 4K and then intelligently down-sample the output to fit the smaller screen. Aliasing and jagged artifacts are reduced by having a high-quality filter applied before the image is scaled down.
EVGA GeForce GTX TITAN X 12 GB DDR5 Superclocked OVERVIEW
GPU NVIDIA GeForce GTX TITAN X:
CUDA Cores: 3072
Base Clock: 1127 MHz
Boost Clock: 1216 MHz
Memory Clock Speed: 7010 MHz Effective
Configuration: 12 GB
Interface: GDDR5
Interface Width: 384-bit
Bandwidth: 336.5 GB/s
Technologies Microsoft DirectX: 12 (12.1 ready)
OpenGL: 4.5
CUDA: Yes
Interface PCI Express 3.0 x16
Display Support Display Connectors:
1 x DVI-I DL
3 x DisplayPort
1 x HDMI
Maximum Digital Resolution: 4096 x 2160
Maximum VGA Resolution: 2048 x 1536
Multi Monitor Support: Up to 4
Power Requirements Power Consumption: 250 W
Minimum System Power Requirement: 600 W
PCI Power Connectors:
1 x 6-pin
1 x 8-pin
Dimensions Height: 4.4″ / 111.5 mm
Length: 10.5″ / 266.7 mm
Width: Dual-Slot
EVGA GeForce GTX TITAN X 12 GB DDR5 Superclocked Packaging Info
Package Weight 3.25 lb
Box Dimensions (LxWxH) 13.0 x 9.6 x 3.1″

No comments:

Post a Comment