1. Image quality metrics for volumetric laser displays
- Author
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Daniel T. Donohoo and Rodney D. Williams
- Subjects
Computer science ,law ,Image quality ,Autostereoscopy ,Computer graphics (images) ,Human visual system model ,Stereoscopy ,Volumetric display ,Graphics ,Rendering (computer graphics) ,law.invention ,Display device - Abstract
IMAGE QUALITY METRICS FOR VOLUMETRIC LASER DISPLAYSRodney Don Williams and Daniel DonohooTexas Instruments IncorporatedComputer Systems LaboratoryUser Systems Engineering LaboratoryDallas, Texas, USAABSTRACTThis paper addresses the extensions to the image quality metrics and related human factors research that are needed to establish thebaseline standards for emerging volume display technologies. The existing and recently developed technologies for multiplanarvolume displays are reviewed with an emphasis on basic human visual issues. Human factors image quality metrics and guidelinesareneeded to firmly establish this technology inthe marketplace. Thehuman visualrequirements and the display designtradeoffs forthese prototype laser-based volume displays are addressed and several criticalimage quality issues identified for further research. TheAmerican National Standard for Human Factors Engineering ofVisual Display Terminal Workstations (ANSI HFS-100) and otherintemationalstandards (ISO, DIN) can serve as a starting point, butthis researchbase mustbe extended to providenew image qualitymetrics for this new technology for volume displays.1. INTRODUCTIONThis paper provides an overview of volumetric display technology and presents the human factors research needed for effectivevolumetric information displays. Texas Instruments has developed an autostereoscopic multiplanar volume display technology overthe last 4 ars' During the development of this technology, we conducted an extensive review of previous technologies for truevolume displays and identified numerous research issues associated with volume technology. The American National Standard forHuman Factors Engineering of Visual Display Terminal Workstations can serve as a starting point, but this research base must beextended to provide the image quality metrics for volume displays.or as a physical 3-D volume as described herein. For some tasks, the parallax cues from stereoscopic presentations are sufficient.However, for many multiple-person (team) tasks where numerous views are required, a true volume display is preferred. This articlereviews the various technologies for implementing these volume displays and the image quality issues associated withthis emergingtechnology.In this context, the term "volumetric display" refers to a display device that uses a physical volume to present images having height,depth, and width. These images occupy physical space and are not a 2-D rendering of a 3-D image. A "voxel" is a volume displaypicture element(pixel)having a physical X, Y, and Z dimensionality in a specific location in a volume display. Note that these termsare often used to describe a virtual 2-D display with additional 3-D cues such as parallax, perspective, etc. However, for the purposeof this paper, I am referring to an actual physical volume of three dimensions.While the human visual system was created to effectively perceive and comprehend the world in a full three dimensions, currentcomputer graphics displays provide only 2-D views of the real world. This incompatibility becomes most pronounced when a useris asked to monitor and control the relative position of objects in a volume of space. We need information displays that bettercommunicate the relative position of 3-D objects in real space and provide complete visual cues.Current 2-D perspective displays have limitations when used for dynamic volumetric tasks such as battle management and air
- Published
- 1991