Precise Depth Perception in Projective Stereoscopic Display

This paper reviews much of the basic literature on stereopsis for the purpose of providing information about the ability of humans to utilize stereoscopic information under operational conditions. This review is organized around five functional topics that may be important for the design of many stereoscopic display systems: geometry of stereoscopic depth perception, visual persistence, perceptual interaction among stereoscopic stimuli, neurophysiology of stereopsis, and theoretical considerations. The paper concludes with the presentation of several basic ideas related to the design of stereoscopic displays.

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Three-Dimensional Image. Depth Perception Distortion in a Stereoscopic Display and Its Correction.

The Journal of the Institute of Television Engineers of Japan ◽

10.3169/itej1978.50.1256 ◽

1996 ◽

Vol 50 (9) ◽

pp. 1256-1267

Author(s):

Yasuo Ishigure ◽

Sakuichi Ohtsuka ◽

Yasuaki Kanatsugu ◽

Tatsuo Yoshida ◽

Shiro Usui

Keyword(s):

Depth Perception ◽

Three Dimensional ◽

Stereoscopic Display ◽

Dimensional Image ◽

Image Depth

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Depth perception in a stereoscopic display as a function of number of stimuli, depth range, and number of scale markers.

Journal of Applied Psychology ◽

10.1037/h0047517 ◽

1957 ◽

Vol 41 (6) ◽

pp. 414-418

Author(s):

John E. Murray

Keyword(s):

Depth Perception ◽

Depth Range ◽

Stereoscopic Display

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Evaluation of Adaptive Interaction Systems for Virtual Museum Development

Trends in Sciences ◽

10.48048/tis.2021.1405 ◽

2021 ◽

Vol 18 (24) ◽

pp. 1405

Author(s):

Chaowanan Khundam ◽

Frédéric Nöel

Keyword(s):

Depth Perception ◽

User Requirements ◽

Virtual Museum ◽

Stereoscopic Display ◽

Museum Visitors ◽

Cave System ◽

Holding Power ◽

Wide Range ◽

Stereoscopic System ◽

Adaptive Interaction

Virtual Museum (VM) is an application of Virtual Reality (VR) technology generating realistic visualization and sensation to convince museum visitors to interact with digital content. There are many immersive VR devices that support interactive VM applications. We investigate appropriate devices for interaction within VM. We proposed a Storytelling platform to achieve device organization without modification, the story and interaction were self-adapted to the selected device. Three types of interactive content were designed on our Storytelling platform to be applied on different interaction systems: a 2D standard display, a 3D stereoscopic display and a full immersive CAVE. The results showed different performances of each system supporting VM developers to select an appropriate interaction system. The evaluation contributes to the design of content and interaction of VM development with more efficiency based on user requirements. HIGHLIGHTS Three types of interactive content were designed on our Storytelling platform to be applied on different interaction systems: A 2D standard display, a 3D stereoscopic display, and a full immersive CAVE The 2D Powerwall system with a wide range of views provides immersion. However, with two-dimensional displays, users lack depth perception Users spent more time in selection and manipulation in the 3D stereoscopic system because depth perception is added The CAVE system has user attraction or holding power, users spent more interacting time GRAPHICAL ABSTRACT

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Stereoscopic Depth Perception in Simulated Displays: What Helps and What Hurts?

Proceedings of the Human Factors and Ergonomics Society Annual Meeting ◽

10.1177/154193129604002310 ◽

1996 ◽

Vol 40 (23) ◽

pp. 1193-1196 ◽

Cited By ~ 1

Author(s):

John W. Akers ◽

Elizabeth T. Davis ◽

Robert A. King

Keyword(s):

Depth Perception ◽

Stereoscopic Depth ◽

Stimulus Orientation ◽

Psychophysical Method ◽

Depth Information ◽

Stereoscopic Display ◽

Retinal Disparity ◽

Vertical Disparity ◽

Stereoscopic Displays ◽

Method Of Constant Stimuli

We tested the effect of direction of retinal disparity and stimulus orientation on stereoscopic depth perception to answer three questions. First, are some directions of disparity more efficient than others in providing stereoscopic depth information? Second, does the orientation of an object affect perceived stereoscopic depth? Third, are there any interactions between these parameters? Subjects were tested using a psychophysical, method of constant stimuli procedure with a modified Wheatstone stereoscopic display. Disparity threshold measurements show a significant effect of direction of retinal disparity. Contrary to expectations however, no significant effect of orientation was found if vertical retinal disparities were excluded from the analyses. Stereoacuity thresholds were measurable with obliquely-oriented stimuli and vertical disparity, however, suggesting that vertical disparities can provide useful information. The implications of these results for the graphics, calibration, and design of stereoscopic displays (e.g., HMDs) are discussed.

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Three-dimensional image analysis and visualization in confocal light microscopy

Proceedings, annual meeting, Electron Microscopy Society of America ◽

10.1017/s0424820100146631 ◽

1993 ◽

Vol 51 ◽

pp. 158-159

Author(s):

J. K. Samarabandu ◽

R. Acharya ◽

D. R. Pareddy ◽

P. C. Cheng

Keyword(s):

Depth Perception ◽

Computer Graphic ◽

Three Dimensional ◽

Cellular Organization ◽

Data Set ◽

Computational Burden ◽

Interactive Operation ◽

Cell Organization ◽

Confocal Images ◽

3D Digitization

In the study of cell organization in a maize meristem, direct viewing of confocal optical sections in 3D (by means of 3D projection of the volumetric data set, Figure 1) becomes very difficult and confusing because of the large number of nucleus involved. Numerical description of the cellular organization (e.g. position, size and orientation of each structure) and computer graphic presentation are some of the solutions to effectively study the structure of such a complex system. An attempt at data-reduction by means of manually contouring cell nucleus in 3D was reported (Summers et al., 1990). Apart from being labour intensive, this 3D digitization technique suffers from the inaccuracies of manual 3D tracing related to the depth perception of the operator. However, it does demonstrate that reducing stack of confocal images to a 3D graphic representation helps to visualize and analyze complex tissues (Figure 2). This procedure also significantly reduce computational burden in an interactive operation.

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