Augmented Environment Mapping for Appearance Editing of Glossy Surfaces

We propose a novel spatial augmented reality (SAR) framework to edit the appearance of physical glossy surfaces. The key idea is utilizing the specular reflection, which was a major distractor in conventional SAR systems. Namely, we spatially manipulate the appearance of an environmental surface, which is observed through the specular reflection. We use a stereoscopic display to present two appearances with disparity on the environmental surface, by which the depth of the specularly reflected visual information corresponds to the glossy surface. We refer to this method as augmented environment mapping (AEM). The paper describes its principle, followed by three different implementation approaches inspired by typical virtual and augmented reality approaches. We confirmed the feasibility of AEM through both quantitative and qualitative experiments using prototype systems.

[1]  Kosuke Sato,et al.  Limpid desk: see-through access to disorderly desktop in projection-based mixed reality , 2006, VRST '06.

[2]  Daniel G. Aliaga,et al.  A virtual restoration stage for real-world objects , 2008, SIGGRAPH Asia '08.

[3]  Yoshifumi Kitamura,et al.  Interactive stereoscopic display for three or more users , 2001, SIGGRAPH.

[4]  Justus Thies,et al.  Real-time pixel luminance optimization for dynamic multi-projection mapping , 2015, ACM Trans. Graph..

[5]  Gordon Wetzstein,et al.  The Visual Computing of Projector‐Camera Systems , 2008, SIGGRAPH '08.

[6]  Jong-Il Park,et al.  Specularity-Free Projection on Nonplanar Surface , 2005, PCM.

[7]  Kwan H. Lee,et al.  Spatial augmented reality for product appearance design evaluation , 2015, J. Comput. Des. Eng..

[8]  Markus C. Knauer,et al.  Phase measuring deflectometry: a new approach to measure specular free-form surfaces , 2004, SPIE Photonics Europe.

[9]  Ross T. Smith,et al.  Spatial User Interfaces for Large-Scale Projector-Based Augmented Reality , 2014, IEEE Computer Graphics and Applications.

[10]  Anselm Grundhöfer,et al.  Recent Advances in Projection Mapping Algorithms, Hardware and Applications , 2018, Comput. Graph. Forum.

[11]  Anselm Grundhöfer,et al.  Projection-Based Augmented Reality in Disney Theme Parks , 2012, Computer.

[12]  Blair MacIntyre,et al.  RoomAlive: magical experiences enabled by scalable, adaptive projector-camera units , 2014, UIST.

[13]  Daisuke Iwai,et al.  HySAR: Hybrid Material Rendering by an Optical See-Through Head-Mounted Display with Spatial Augmented Reality Projection , 2017, IEEE Transactions on Visualization and Computer Graphics.

[14]  James M. Rehg,et al.  Projector-guided painting , 2006, UIST.

[15]  Feng Gao,et al.  Iterative optimization calibration method for stereo deflectometry. , 2015, Optics express.

[16]  Kun Chen,et al.  Improved system calibration for specular surface measurement by using reflections from a plane mirror. , 2016, Applied optics.

[17]  Gordon Wetzstein,et al.  Tensor displays , 2012, ACM Trans. Graph..

[18]  Ramesh Raskar,et al.  Modern approaches to augmented reality: introduction to current approaches , 2006, SIGGRAPH Courses.

[19]  Woontack Woo,et al.  Mirror Mirror: An On-Body T-shirt Design System , 2016, CHI.

[20]  Reinhard Koch,et al.  Truthful Color Reproduction in Spatial Augmented Reality Applications , 2013, IEEE Transactions on Visualization and Computer Graphics.

[21]  Takayuki Okatani,et al.  A Projector-Camera System for High-Quality Synthesis of Virtual Reflectance on Real Object Surfaces , 2010, IPSJ Trans. Comput. Vis. Appl..

[22]  Jong-Il Park,et al.  Radiometrically-Compensated Projection onto Non-Lambertian Surface Using Multiple Overlapping Projectors , 2006, PSIVT.

[23]  Kosuke Sato,et al.  Geometrically Consistent Projection-Based Tabletop Sharing for Remote Collaboration , 2018, IEEE Access.

[24]  Masatoshi Ishikawa,et al.  Extended Dot Cluster Marker for High-speed 3D Tracking in Dynamic Projection Mapping , 2017, 2017 IEEE International Symposium on Mixed and Augmented Reality (ISMAR).

[25]  Gordon Wetzstein,et al.  Radiometric Compensation through Inverse Light Transport , 2007, 15th Pacific Conference on Computer Graphics and Applications (PG'07).

[26]  Kosuke Sato,et al.  Optical superimposition of infrared thermography through video projection , 2010 .

[27]  Anselm Grundhöfer,et al.  Robust, Error-Tolerant Photometric Projector Compensation , 2015, IEEE Transactions on Image Processing.

[28]  Anselm Grundhöfer,et al.  Makeup Lamps: Live Augmentation of Human Faces via Projection , 2017, Comput. Graph. Forum.

[29]  Greg Welch,et al.  Shader Lamps: Animating Real Objects With Image-Based Illumination , 2001, Rendering Techniques.

[30]  Takeshi Naemura,et al.  EnchanTable: Displaying a Vertically Standing Mid-air Image on a Table Surface using Reflection , 2015, ITS.