Summary

Measuring Sensitivity to Viewpoint Change with and without Stereoscopic Cues

Published: December 04, 2013
doi:

Summary

We discuss a novel method forviewpoint-rotation of visual stimuli, and demonstrate using a mirror stereoscopethe three-dimensional percept of rotation-in-depth. The technique can be used to investigate the role of stereoscopic cues in encoding viewpoint-rotated figures.

Abstract

The speed and accuracy of object recognition is compromised by a change in viewpoint; demonstrating that human observers are sensitive to this transformation. Here we discuss a novel method for simulating the appearance of an object that has undergone a rotation-in-depth, and include an exposition of the differences between perspective and orthographic projections. Next we describe a method by which human sensitivity to rotation-in-depth can be measured. Finally we discuss an apparatus for creating a vivid percept of a 3-dimensional rotation-in-depth; the Wheatstone Eight Mirror Stereoscope. By doing so, we reveal a means by which to evaluate the role of stereoscopic cues in the discrimination of viewpoint rotated shapes and objects.

Introduction

Many studies have shown that the speed and accuracy of object recognition is compromised by a change in viewpoint1-7. For example, face recognition is best when the face is viewed in the fronto-parallel plane, i.e. "front on", and declines systematically as the face is rotated in depth away from the fronto-parallel plane. Changes in viewpoint can occur either when the observer, or the viewed object, moves. Importantly, the viewpoint cost is often reduced by the introduction of stereoscopic cues to the observer1-4,6,8. It is, however, important to distinguish between the rotation of 3D and planar objects. The former may reveal new textures or structural information under rotation while this does not occur with planar objects. In this communication we discuss a method for simulating the appearance of planar shapes and objects that have been subject to rotation-in-depth, or RID. We describe an apparatus for turning the two-dimensional projection of a RID image into a vivid 3D (three-dimensional) percept of RID that is based on the Wheatstone mirror stereoscope9. Finally, we report a psychophysical method for determining whether stereoscopic (3D) cues influence our sensitivity to viewpoint change. Movie 1 demonstrates how the appearance of a shape is altered by a viewpoint change/RID.

Simulating a Viewpoint Change

When an object is subject to RID it does not of course physically change in identity or shape. However from the observer’s viewpoint, the shape does change. For instance, if you hold a sheet of paper directly in front of you in landscape view, the image of the paper in your eye, termed the retinal image, is a horizontal rectangle. If you then rotate the paper around its central vertical axis, the retinal image becomes foreshortened along the horizontal (see Figure 1 for a demonstration). Ultimately, if you rotate the paper through 90° the retinal image is a thin strip the thickness of the paper. Thus the largest change to the image of the sheet of paper that has been subject to RID is a horizontal compression of its shape. A smaller change gradient of change occurs in the vertical extent with the image being taller for the nearest edge unchanged at the axis of rotation and shorter for the farther edge.

A RID can be simulated by appropriate transformation of images using software packages or by writing one’s own code8,10. Readers wishing to know more about RID can consult relevant texts and websites concerned with viewpoint transformations, or learn about built-in functions in the image processing software of packages such as those listed in our Materials. However, when transforming an image of a stimulus on a screen to represent a particular angle of RID there is an additional consideration: which type of projection to use, orthographic or perspective? When we view a scene, nearby objects produce larger retinal images than farther away objects. For a 2D (two-dimensional) object that is subject to RID this means that the far side is compressed more than the near side, as Figure 1 illustrates (see in particular the bottom right figure which has a RID of 60°). The magnitude of the compression asymmetry is dependent upon the size of the object being subject to RID, and on our distance from it. Perspective projection incorporates this compression asymmetry whereas orthographic projection simply ignores it by assigning the same dimensions to the near and far sides of the RID object. Since an observer viewing a planar object rotate will be presented with this asymmetry we will use perspective projection here. Another advantage of our method is that the projection takes into account viewing distance from observer to screen. We have previously used our RID method to simulate viewpoint rotated shapes in both 2D perspective projection and in 3D8,10.

Simulating a 3D Viewpoint Change

In order to simulate stereoscopic RID one needs to present slightly different images to the left and right eyes. This difference between the two images is known as binocular disparity11, and is a function of both viewing distance and between-eye separation, specifically the inter-pupillary distance. Returning to the example of our sheet of paper in landscape view, if we rotate the piece of paper around the vertical center, clockwise by 45° (so the left edge is receding), each eye’s view of the paper is slightly different. The image projected onto the left eye is slightly less than 45° rotation while the image projected onto the right eye is slightly more than 45° rotation (see Figure 2 for an illustration – observers who can free fuse the top two images will perceive a RID in 3D). If the appropriate RID angles are presented separately to the left and right eyes (the stereo condition) they will produce a disparity gradient and the observer is likely to report a vivid impression of a 3D RID. However if identical images, representing a 45° rotation from the central viewing point, are presented to both eyes (the nonstereo condition) the observer will see a 2D representation of the RID stimuli. An established method for presenting separate images to the left and right eyes using a single monitor is to use a modification of the mirror stereoscope originally developed by Sir Charles Wheatstone in the mid 19th century12 – see Figure 3. When the two stereo-half-images are positioned at corresponding locations in each eye’s view, they can be binocularly fused to produce a 3D percept (see Howard and Rogers12 for an extensive review of stereo methods and limitations).

By combining a simulated viewpoint change with stereoscopic presentation we can determine, for example, the role that stereoscopic cues play in our ability to detect changes in viewpoint. The demonstration results below reveal that when the size of a planar object, in this case a curved contour, is known or familiar to the observer, the change in the 2D width of the curve (sometimes termed its sag) is used to detect the change in RID, i.e. viewpoint (see Bell et al.10 for the full manuscript on this effect). Below we describe in detail a psychophysical method for measuring sensitivity to RID change for 2D- and 3D-defined planar shapes.

Protocol

1. Prescreening Prior to testing, obtain written and informed consent from each participant. Ask the subject if they have normal or corrected-to-normal acuity (i.e. glasses). Verify the stereo acuity of the participant using a simple handheld stereo test. 2. Achieving Binocular Fusion in the Stereoscope Seat the participant at the desk in front of the mirror stereoscope and adjust the height of their chair for comfort. Turn …

Representative Results

Figure 4 plots example results obtained from such an experiment. The y-axis in each figure describes the proportion of times that the test pattern was chosen as having a greater RID. Rather than plotting the absolute number of times this occurred, this is given as a proportion. The x-axis describes the physical RID of the test pattern; remembering that here, the reference pattern was held at a constant 45° RID. The data points represent the proportion of times that the observer chose the test curve …

Discussion

The methods discussed in this communication can be used by any researcher seeking to address questions related to discrimination and/or recognition of viewpoint rotated objects. Importantly, the method of perspective projection is not limited to the stimuli demonstrated here; instead it can be applied to a wide range of experimental stimuli, from lines to pictures of complex objects. Our introduction describes ways to apply this transformation using custom software, or library software such as MATLAB.

<p class="jove_…

Divulgations

The authors have nothing to disclose.

Acknowledgements

This research was supported by the Australian Research council. ARC Grant # DP110101511 given to JB; National Sciences and Engineering Research Council, NSERC of Canada Grant # RGPIN121713-11 given to FK ; ARC grant # DP130102580 and DP110104553 to DRB.

Materials

Stereo testing http://www.stereooptical.com/products/stereotests Titmus stereofly test Handheld testing devices
Prebuilt stereo devices http://www.stereoaids.com.au prebuilt stereoscopes Suitable for desktop and laptop computers
Mirror stereoscope Custom made; or, Edmundoptics 8 mirror stereoscope www.edmundoptics.com
Graphics card NVidia NVidia or ATI recommended
Experimental control software MATLAB MATLAB, Python, C++, Visual Basic recommended
Experimental control software Psychtoolbox.org Psychtoolbox Free to download but requires MATLAB
Statistical software Graphpad Prism V5 http://www.graphpad.com/
Statistical software Palamedes Psychophysics guide http://www.palamedestoolbox.org
3D Projection documentation Wikipedia http://en.wikipedia.org/wiki/3D_projection

References

  1. Bennett, D. J., Vuong, Q. C. A stereo advantage in generalizing over changes in viewpoint on object recognition tasks. Percep. Psychophys. 68, 1082-1093 (2006).
  2. Bulthoff, H. H., Edelman, S. Y., Tarr, M. J. How are three-dimensional objects represented in the brain?. Cereb. Cortex. 5, 247-260 (1995).
  3. Burke, D. Combining disparate views of objects: Viewpoint costs are reduced by stereopsis. Vis. Cogn. 12, 705-719 (2005).
  4. Burke, D., Taubert, J., Higman, T. Are face representations viewpoint dependent? A stereo advantage for generalising across different views of faces. Vis. Res. 47, 2164-2169 (2007).
  5. Edelman, S., Bulthoff, H. H. Orientation dependence in the recognition of familiar and novel views of three-dimensional objects. Vis. Res. 32, 2385-2400 (1992).
  6. Lim Lee, Y., Saunders, J. A. Stereo improves 3D shape discrimination even when rich monocular shape cues are available. J. Vis. 11, (2011).
  7. Parr, L. A., Siebert, E., Taubert, J. Effect of familiarity and viewpoint on face recognition in chimpanzees. Perception. 40, 863-872 (2011).
  8. Bell, J., Dickinson, J. E., Badcock, D. R. Radial frequency adaptation suggests polar-based coding of local shape cues. Vis. Res. 48, 2293-2301 (2008).
  9. Wade, N. J. On the late invention of the stereoscope. Perception. 16, 785-818 (1987).
  10. Bell, J., Kanji, J., Kingdom, F. A. A. Discrimination of rotated-in-depth curves is facilitated by stereoscopic cues, but curvature is not tuned for stereoscopic rotation-in-depth. Vis. Res. 77, 14-20 (2013).
  11. Regan, D. . Human Perception of Objects. , (2000).
  12. Howard, I. P., Rogers, B. J. . Binocular Vision and Stereopsis. , (1995).
  13. Kingdom, F. A. A., Prins, N. . Psychophysics: A Practical Introduction. , (2010).
  14. Kingdom, F. A. Color brings relief to human vision. Nat. Neurosci. 6, 641-644 (2003).
  15. Ustinova, K. I., Perkins, J. Gaze and viewing angle influence visual stabilization of upright posture. Brain Behav. 1, 19-25 (1002).
  16. Shieh, K. -. K., Lee, D. -. S. Preferred viewing distance and screen angle of electronic paper displays. Appl. Ergon. 38, 601-608 (2007).

Play Video

Citer Cet Article
Bell, J., Dickinson, E., Badcock, D. R., Kingdom, F. A. A. Measuring Sensitivity to Viewpoint Change with and without Stereoscopic Cues. J. Vis. Exp. (82), e50877, doi:10.3791/50877 (2013).

View Video