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Priority rendering with a virtual reality address recalculation pipeline

Authors:

Matthew Regan,

Ronald PoseAuthors Info & Claims

SIGGRAPH '94: Proceedings of the 21st annual conference on Computer graphics and interactive techniques

Pages 155 - 162

https://doi.org/10.1145/192161.192192

Published: 24 July 1994 Publication History

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Abstract

Virtual reality systems are placing never before seen demands on computer graphics hardware, yet few graphics systems are designed specifically for virtural reality. An address recalculation pipeline is a graphics display controller specifically designed for use with head mounted virtual reality systems, it performs orientation viewport mapping after rendering which means the users head orientation does not need to be known accurately until less than a microsecond before the first pixel of an update frame is actually sent to the head mounted display device. As a result the user perceived latency to head rotations is minimal.

Using such a controller with image composition it is possible to render different objects within the world at different rate, thus it is possible to concentrate the available rendering power on the sections of the scene that change the most. The concentration of rendering power is known as priority rendering. Reductions of one order of magnitude in the number of objects rendered for an entire scene have been observed when using priority rendering. When non interactive background scenes which are rendered with a high quality rendering algorithm such as ray tracing are added to the world, highly realistic virtual worlds are possible with little or no latency.

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Index Terms

Priority rendering with a virtual reality address recalculation pipeline
1. Computing methodologies
  1. Computer graphics
2. Hardware
  1. Communication hardware, interfaces and storage
    1. Displays and imagers

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SIGGRAPH '94: Proceedings of the 21st annual conference on Computer graphics and interactive techniques

July 1994

512 pages

ISBN:0897916670

DOI:10.1145/192161

Chairmen:
Dino Schweitzer
US Air Force Academy, Colorado
,
Andrew Glassner,
Mike Keeler

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Published: 24 July 1994

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SIGGRAPH '94 Paper Acceptance Rate 57 of 242 submissions, 24%;

Overall Acceptance Rate 1,822 of 8,601 submissions, 21%

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Arvanitis GStagakis NZacharaki EMoustakas K(2024)Cooperative Saliency-Based Pothole Detection and AR Rendering for Increased Situational AwarenessIEEE Transactions on Intelligent Transportation Systems10.1109/TITS.2023.332749425:5(3588-3604)Online publication date: May-2024
https://doi.org/10.1109/TITS.2023.3327494
Lin JHuang YLee MChen P(2024)Coded Distributed Multiplication for Matrices of Different Sparsity LevelsIEEE Transactions on Communications10.1109/TCOMM.2023.332619372:2(633-647)Online publication date: Feb-2024
https://doi.org/10.1109/TCOMM.2023.3326193
Cebeci BAskin MCapin TCelikcan U(2024)Gaze-directed and saliency-guided approaches of stereo camera control in interactive virtual realityComputers & Graphics10.1016/j.cag.2023.10.012118(23-32)Online publication date: Feb-2024
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Friston SRitschel TSteed A(2019)Perceptual rasterization for head-mounted display image synthesisACM Transactions on Graphics10.1145/3306346.332303338:4(1-14)Online publication date: 12-Jul-2019
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Pipeline rendering: interaction and realism through hardware-based multi-pass rendering

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Pipeline rendering: interaction and realism through hardware-based multi-pass rendering

Photorealistic rendering for Augmented Reality: A global illumination and BRDF solution

Non-photorealistic rendering with coherence for augmented reality

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