Nothing Special   »   [go: up one dir, main page]

skip to main content
research-article

Computational peeling art design

Published: 12 July 2019 Publication History

Abstract

Some artists peel citrus fruits into a variety of elegant 2D shapes, depicting animals, plants, and cartoons. It is a creative art form, called Citrus Peeling Art. This art form follows the conservation principle, i.e., each shape must be created using one entire peel. Central to this art is finding optimal cut lines so that the citruses can be cut and unfolded into the desired shapes. However, it is extremely difficult for users to imagine and generate cuts for their desired shapes. To this end, we present a computational method for citrus peeling art designs. Our key insight is that instead of solving the difficult cut generation problem, we map a designed input shape onto a citrus in an attempt to cover the entire citrus and use the mapped boundary to generate the cut paths. Sometimes, a mapped shape is unable to completely cover a citrus. Consequently, we have developed five customized ways of interaction that are used to rectify the input shape so that it is suitable for citrus peeling art. The mapping process and user interactions are iteratively conducted to satisfy a user's design intentions. A large number of experiments, including a formative user study, demonstrate the capability and practicability of our method for peeling art design and construction.

Supplementary Material

ZIP File (a64-liu.zip)
Supplemental material
MP4 File (papers_338.mp4)

References

[1]
Bernd Bickel, Paolo Cignoni, Luigi Malomo, and Nico Pietroni. 2018. State of the Art on Stylized Fabrication. Comput. Graph. Forum 37 (2018).
[2]
Mario Botsch and Leif Kobbelt. 2004. A remeshing approach to multiresolution modeling. In Proceedings of the 2004 Eurographics/ACM SIGGRAPH symposium on Geometry processing. 185--192.
[3]
Mario Botsch and Olga Sorkine. 2008. On linear variational surface deformation methods. IEEE. T. Vis. Comput. Gr. 14, 1 (2008), 213--230.
[4]
Shuangming Chai, Xiao-Ming Fu, Xin Hu, Yang Yang, and Ligang Liu. 2018. Sphere-based Cut Construction for Planar Parameterizations. Computer & Graphics (SMI 2018) 74 (2018), 66--75.
[5]
Michael S. Floater and Kai Hormann. 2005. Surface parameterization: a tutorial and survey. In In Advances in Multiresolution for Geometric Modelling. Springer, 157--186.
[6]
Xiao-Ming Fu and Yang Liu. 2016. Computing Inversion-Free Mappings by Simplex Assembly. ACM Trans. Graph. (SIGGRAPH ASIA) 35, 6 (2016).
[7]
Xiao-Ming Fu, Yang Liu, and Baining Guo. 2015. Computing locally injective mappings by advanced MIPS. ACM Trans. Graph. (SIGGRAPH) 34, 4 (2015), 71:1--71:12.
[8]
Xifeng Gao, Daniele Panozzo, Wenping Wang, Zhigang Deng, and Guoning Chen. 2017. Robust Structure Simplification for Hex Re-meshing. ACM Trans. Graph. (SIGGRAPH ASIA) 36, 6 (2017), 185:1--185:13.
[9]
Akash Garg, Andrew O. Sageman-Furnas, Bailin Deng, Yonghao Yue, Eitan Grinspun, Mark Pauly, and Max Wardetzky. 2014. Wire Mesh Design. ACM Trans. Graph. (SIGGRAPH) 33, 4 (2014), 66:1--66:12.
[10]
Xianfeng Gu, Steven J. Gortler, and Hugues Hoppe. 2002. Geometry Images. ACM Trans. Graph. (SIGGRAPH) 21, 3 (2002),355--361.
[11]
Xin Hu, Xiao-Ming Fu, and Ligang Liu. 2018. Advanced Hierarchical Spherical Parameterizations. IEEE. T. Vis. Comput. Gr. 24, 6 (2018), 1930--1941.
[12]
Zhongshi Jiang, Scott Schaefer, and Daniele Panozzo. 2017. Simplicial Complex Augmentation Framework for Bijective Maps. ACM Trans. Graph. (SIGGRAPH ASIA) 36, 6 (2017), 186:1--186:9.
[13]
Conrado R. Ruiz Jr., Sang N. Le, Jinze Yu, and Kok-Lim Low. 2014. Multi-style Paper Pop-up Designs from 3D Models. Comput. Graph. Forum (EG) 33, 2 (2014), 487--496.
[14]
Dan Julius, Vladislav Kraevoy, and Alla Sheffer. 2005. D-Charts: Quasi-Developable Mesh Segmentation. In Comput. Graph. Forum, Vol. 24. 581--590.
[15]
Martin Kilian, Simon Flöry, Zhonggui Chen, Niloy J. Mitra, Alla Sheffer, and Helmut Pottmann. 2008. Curved Folding. ACM Trans. Graph. 27, 3 (2008), 75:1--75:9.
[16]
Martin Kilian, Aron Monszpart, and Niloy J. Mitra. 2017. String Actuated Curved Folded Surfaces. ACM Trans. Graph. 36, 4 (2017).
[17]
Shahar Z. Kovalsky, Noam Aigerman, Ronen Basri, and Yaron Lipman. 2015. Large-scale bounded distortion mappings. ACM Trans. Graph. (SIGGRAPH ASIA) 34, 6, Article 191 (2015), 10 pages.
[18]
Sang N. Le, Su-Jun Leow, Tuong-Vu Le-Nguyen, Conrado Ruiz, and Kok-Lim Low. 2014. Surface and Contour-Preserving Origamic Architecture Paper Pop-Ups. IEEE. T. Vis. Comput. Gr. 20, 2 (2014), 276--288.
[19]
Bruno Lévy, Sylvain Petitjean, Nicolas Ray, and Jérome Maillot. 2002. Least squares conformal maps for automatic texture atlas generation. ACM Trans. Graph. (SIGGRAPH) 21, 3 (2002), 362--371.
[20]
Minchen Li, Danny M. Kaufman, Vladimir G. Kim, Justin Solomon, and Alla Sheffer. 2018. OptCuts: Joint Optimization of Surface Cuts and Parameterization. ACM Trans. Graph. (SIGGRAPH ASIA) 37, 6 (2018).
[21]
Xin Li and SS Iyengar. 2015. On computing mapping of 3d objects: A survey. ACM Computing Surveys (CSUR) 47, 2 (2015), 34.
[22]
Xian-Ying Li, Tao Ju, Yan Gu, and Shi-Min Hu. 2011. A Geometric Study of V-style Pop-ups: Theories and Algorithms. ACM Trans. Graph. 30, 4 (2011), 98:1--98:10.
[23]
Xian-Ying Li, Chao-Hui Shen, Shi-Sheng Huang, Tao Ju, and Shi-Min Hu. 2010. Popup: Automatic Paper Architectures from 3D Models. ACM Trans. Graph. 29, 4 (2010), 111:1--111:9.
[24]
Max Limper, Nicholas Vining, and ALLA SHEFFER. 2018. Box Cutter: Atlas Refinement for Efficient Packing via Void Elimination. ACM Trans. Graph. (SIGGRAPH) 37, 4 (2018), 153:1--153:13.
[25]
Yaron Lipman. 2012. Bounded distortion mapping spaces for triangular meshes. ACM Trans. Graph. (SIGGRAPH) 31, 4 (2012), 108:1--108:13.
[26]
Hao-Yu Liu, Xiao-Ming Fu, Chunyang Ye, Shuangming Chai, and Ligang Liu. 2019. Atlas Refinement with Bounded Packing Efficiency. ACM Trans. Graph. (SIGGRAPH) 38, 4 (2019), 33:1--33:13.
[27]
Ligang Liu, Chunyang Ye, Ruiqi Ni, and Xiao-Ming Fu. 2018. Progressive Parameterizations. ACM Trans. Graph. (SIGGRAPH) 37, 4 (2018), 41:1--41:12.
[28]
Ligang Liu, Lei Zhang, Yin Xu, Craig Gotsman, and Steven J. Gortler. 2008. A local/global approach to mesh parameterization. Comput. Graph. Forum (SGP) 27, 5 (2008), 1495--1504.
[29]
Fady Massarwi, Craig Gotsman, and Gershon Elber. 2007. Papercraft models using generalized cylinders. In 15th Pacific Conference on Computer Graphics and Applications (PG'07). 148--157.
[30]
J. Mitani and H. Suzuki. 2004a. Computer aided design for Origamic Architecture models with polygonal representation. In Proceedings Computer Graphics International, 2004. 93--99.
[31]
Jun Mitani and Hiromasa Suzuki. 2004b. Making Papercraft Toys from Meshes Using Strip-based Approximate Unfolding. ACM Trans. Graph. 23, 3 (2004), 259--263.
[32]
Yoshihiro Okada. 2010. Atarashii mikan no mukikata : zennijūgoshu (1st ed.). Tokyo : Shögakukan.
[33]
Roi Poranne, Marco Tarini, Sandro Huber, Daniele Panozzo, and Olga Sorkine-Hornung. 2017. Autocuts: Simultaneous Distortion and Cut Optimization for UV Mapping. ACM Trans. Graph. (SIGGRAPH ASIA) 36, 6 (2017).
[34]
Emil Praun and Hugues Hoppe. 2003. Spherical Parametrization and Remeshing. ACM Trans. Graph. (SIGGRAPH) 22, 3 (2003), 340--349.
[35]
Michael Rabinovich, Roi Poranne, Daniele Panozzo, and Olga Sorkine-Hornung. 2017. Scalable Locally Injective Mappings. ACM Trans. Graph. 36, 2 (2017), 16:1--16:16.
[36]
Pedro V. Sander, Steven J. Gortler, John Snyder, and Hugues Hoppe. 2002. Signal-specialized Parametrization. In Proceedings of the 13th Eurographics Workshop on Rendering. 87--98.
[37]
P. V. Sander, Z. J. Wood, S. J. Gortler, J. Snyder, and H. Hoppe. 2003. Multi-chart Geometry Images. In Proceedings of the 2003 Eurographics/ACM SIGGRAPH Symposium on Geometry Processing. 146--155.
[38]
Rohan Sawhney and Keenan Crane. 2017. Boundary First Flattening. ACM Trans. Graph. 37, 1 (2017), 5:1--5:14.
[39]
Nicholas Sharp and Keenan Crane. 2018. Variational Surface Cutting. ACM Trans. Graph. (SIGGRAPH) 37, 4 (2018), 156:1--156:13.
[40]
Idan Shatz, Ayellet Tal, and George Leifman. 2006. Paper craft models from meshes. The Visual Computer 22, 9 (2006), 825--834.
[41]
Alla Sheffer. 2002. Spanning tree seams for reducing parameterization distortion of triangulated surfaces. In Shape Modeling International. 61--66.
[42]
Alla Sheffer and Eric de Sturler. 2001. Parameterization of faceted surfaces for meshing using angle-based flattening. Eng. Comput. 17, 3 (2001), 326--337.
[43]
Alla Sheffer and John C Hart. 2002. Seamster: inconspicuous low-distortion texture seam layout. In Proceedings of the conference on Visualization'02. 291--298.
[44]
Alla Sheffer, Emil Praun, and Kenneth Rose. 2006. Mesh parameterization methods and their applications. Found. Trends. Comput. Graph. Vis. 2, 2 (2006), 105--171.
[45]
Mélina Skouras, Bernhard Thomaszewski, Peter Kaufmann, Akash Garg, Bernd Bickel, Eitan Grinspun, and Markus Gross. 2014. Designing Inflatable Structures. ACM Trans. Graph. (SIGGRAPH) 33, 4 (2014), 63:1--63:10.
[46]
Jason Smith and Scott Schaefer. 2015. Bijective Parameterization with Free Boundaries. ACM Trans. Graph. (SIGGRAPH) 34, 4 (2015), 70:1--70:9.
[47]
Olga Sorkine and Marc Alexa. 2007. As-rigid-as-possible surface modeling. In Symposium on Geometry Processing. 109--116.
[48]
Tomohiro Tachi. 2009. 3D origami design based on tucking molecule. In The Fourth International Conference on Origami in Science, Mathematics, and Education, R. Lang, ed., Pasadena. 259--272.
[49]
T. Tachi. 2010. Origamizing Polyhedral Surfaces. IEEE. T. Vis. Comput. Gr. 16, 2 (2010), 298--311.
[50]
Masahito Takezawa, Takuma Imai, Kentaro Shida, and Takashi Maekawa. 2016. Fabrication of Freeform Objects by Principal Strips. ACM Trans. Graph. 35, 6 (2016), 225:1--225:12.
[51]
Zoe J. Wood, Paul Muhl, and Katelyn Hicks. 2016. Computational Art: Introducing High School Students to Computing via Art. In Proceedings of the 47th ACM Technical Symposium on Computing Science Education (SIGCSE '16). 261--266.
[52]
Eugene Zhang, Konstantin Mischaikow, and Greg Turk. 2005. Feature-based surface parameterization and texture mapping. ACM Trans. Graph. 24, 1 (2005), 1--27.
[53]
Kun Zhou, John Synder, Baining Guo, and Heung-Yeung Shum. 2004. Iso-charts: Stretch-driven Mesh Parameterization Using Spectral Analysis. In Proceedings of the 2004 Eurographics/ACM SIGGRAPH Symposium on Geometry Processing. 45--54.

Cited By

View all
  • (2024)Piecewise Developable Modeling via Implicit Neural Deformation and Feature-Guided CuttingIEEE Transactions on Visualization and Computer Graphics10.1109/TVCG.2023.331948730:9(5993-6004)Online publication date: Sep-2024
  • (2023)Polagons: Designing and Fabricating Polarized Light Mosaics with User-Defined Color-Changing BehaviorsProceedings of the 2023 CHI Conference on Human Factors in Computing Systems10.1145/3544548.3580639(1-14)Online publication date: 19-Apr-2023
  • (2023)Manifold-Constrained Geometric Optimization via Local ParameterizationsIEEE Transactions on Visualization and Computer Graphics10.1109/TVCG.2021.311289629:2(1318-1329)Online publication date: 1-Feb-2023
  • Show More Cited By

Index Terms

  1. Computational peeling art design

    Recommendations

    Comments

    Please enable JavaScript to view thecomments powered by Disqus.

    Information & Contributors

    Information

    Published In

    cover image ACM Transactions on Graphics
    ACM Transactions on Graphics  Volume 38, Issue 4
    August 2019
    1480 pages
    ISSN:0730-0301
    EISSN:1557-7368
    DOI:10.1145/3306346
    Issue’s Table of Contents
    Permission to make digital or hard copies of all or part of this work for personal or classroom use is granted without fee provided that copies are not made or distributed for profit or commercial advantage and that copies bear this notice and the full citation on the first page. Copyrights for components of this work owned by others than ACM must be honored. Abstracting with credit is permitted. To copy otherwise, or republish, to post on servers or to redistribute to lists, requires prior specific permission and/or a fee. Request permissions from [email protected]

    Publisher

    Association for Computing Machinery

    New York, NY, United States

    Publication History

    Published: 12 July 2019
    Published in TOG Volume 38, Issue 4

    Permissions

    Request permissions for this article.

    Check for updates

    Author Tags

    1. deformation
    2. mapping
    3. mesh cutting
    4. parameterizations
    5. peeling art

    Qualifiers

    • Research-article

    Funding Sources

    • Fundamental Research Funds for the Central Universities
    • One Hundred Talent Project of the Chinese Academy of Sciences
    • National Natural Science Foundation of China
    • Anhui Provincial Natural Science Foundation

    Contributors

    Other Metrics

    Bibliometrics & Citations

    Bibliometrics

    Article Metrics

    • Downloads (Last 12 months)91
    • Downloads (Last 6 weeks)8
    Reflects downloads up to 10 Nov 2024

    Other Metrics

    Citations

    Cited By

    View all
    • (2024)Piecewise Developable Modeling via Implicit Neural Deformation and Feature-Guided CuttingIEEE Transactions on Visualization and Computer Graphics10.1109/TVCG.2023.331948730:9(5993-6004)Online publication date: Sep-2024
    • (2023)Polagons: Designing and Fabricating Polarized Light Mosaics with User-Defined Color-Changing BehaviorsProceedings of the 2023 CHI Conference on Human Factors in Computing Systems10.1145/3544548.3580639(1-14)Online publication date: 19-Apr-2023
    • (2023)Manifold-Constrained Geometric Optimization via Local ParameterizationsIEEE Transactions on Visualization and Computer Graphics10.1109/TVCG.2021.311289629:2(1318-1329)Online publication date: 1-Feb-2023
    • (2022)The Promotion Effect of Computer-Aided Technology Combined with RBF Neural Network Algorithm on Art DesignAdvances in Multimedia10.1155/2022/75116302022Online publication date: 1-Jan-2022
    • (2022)An Intelligent Analysis System for Traditional Arts and Crafts Based on Digital technologyComputational Intelligence and Neuroscience10.1155/2022/57991982022Online publication date: 1-Jan-2022
    • (2022)IOT-Oriented Visual Target Tracking and Supply Chain Art Product DesignMobile Information Systems10.1155/2022/37734692022Online publication date: 1-Jan-2022
    • (2022)Developability-driven piecewise approximations for triangular meshesACM Transactions on Graphics10.1145/3528223.353011741:4(1-13)Online publication date: 22-Jul-2022
    • (2021)[Retracted] Pose Estimation under Visual Sensing Technology and Its Application in Art DesignJournal of Sensors10.1155/2021/22557302021:1Online publication date: 22-Nov-2021
    • (2021)Art Design of the Real-Time Image Interactive Interface of the Advertising Screen Based on Augmented Reality and Visual CommunicationJournal of Sensors10.1155/2021/15972362021(1-12)Online publication date: 13-Dec-2021
    • (2021)Modeling clothing as a separate layer for an animatable human avatarACM Transactions on Graphics10.1145/3478513.348054540:6(1-15)Online publication date: 10-Dec-2021
    • Show More Cited By

    View Options

    Get Access

    Login options

    Full Access

    View options

    PDF

    View or Download as a PDF file.

    PDF

    eReader

    View online with eReader.

    eReader

    Media

    Figures

    Other

    Tables

    Share

    Share

    Share this Publication link

    Share on social media