Abstract
Advances in digital design and fabrication technologies are leading toward single fabrication systems capable of producing almost any complete functional object. We are proposing a new paradigm for manufacturing, which we call Universal Desktop Fabrication (UDF), and a framework for its development. UDF will be a coherent system of volumetric digital design software able to handle infinite complexity at any spatial resolution and compact, automated, multi-material digital fabrication hardware. This system aims to be inexpensive, simple, safe and intuitive to operate, open to user modification and experimentation, and capable of rapidly manufacturing almost any arbitrary, complete, high-quality, functional object. Through the broad accessibility and generality of digital technology, UDF will enable vastly more individuals to become innovators of technology, and will catalyze a shift from specialized mass production and global transportation of products to personal customization and point-of-use manufacturing. Likewise, the inherent accuracy and speed of digital computation will allow processes that significantly surpass the practical complexity of the current design and manufacturing systems. This transformation of manufacturing will allow for entirely new classes of human-made, peer-produced, micro-engineered objects, resulting in more dynamic and natural interactions with the world. We describe and illustrate our current results in UDF hardware and software, and describe future development directions.
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References
Mach, E.: Space and Geometry in the Light of Physiological, Psychological and Physical Inquiry. In: McCormack, T.J. (ed.) Trans., The Open Court Publishing Company, Chicago (1906)
Farah, M.: Visual Agnosia. MIT Press/Bradford Books, Cambridge, MA (1990)
Bak, D.: Rapid prototyping or rapid production? 3D printing processes move industry towards the latter. Assembly Automation 23(4), 340 (2003)
Burns, M.: Automated fabrication. Prentice Hall, Englewood Cliffs, NJ (1992)
Benkler, Y.: Coase’s penguin, or, Linux and The Nature of the Firm. Yale Law Journal 112 (2002)
Von Hippel, E.: Democratizing innovation: The evolving phenomenon of user innovation. Journal für Betriebswirtschaft 55(1), 63–78 (2005)
Malone, E., Lipson, H.: Fab@Home: The Personal Desktop Fabricator Kit. Rapid Prototyping Journal 13, 245–255 (2007)
The Desktop Factory 3D Printer, http://www.desktopfactory.com/
RepRap: The Replicating Rapid-Prototyper, http://reprap.org
Goodship, V., Love, J.: Multi-material Injection Moulding. Rapra Review Reports 13(1) (2002)
Beaman, J., Marcus, H., Bourell, D., Barlow, J.: Solid Freeform Fabrication: A New Direction in Manufacturing. Kluwer Academic Publishers, Norwell, MA (1997)
Weiss, L., Merz, R., Prinz, F., Neplothink, G., Padmanabhan, P., Schultz, L., Ramaswami, K.: Shape Deposition Manufacturing of Heterogeneous Structures. Journal of Manufacturing Systems 16(4), 239–248 (1997)
Kou, X., Tan, S.: Heterogeneous object modeling: A review. Computer-Aided Design 39, 284–330 (2007)
Chandru, V., Manohar, S., Prakash, C.: Voxel-based modeling for layered manufacturing. IEEE Computer Graphics and Applications 15, 42 (1995)
Siu, Y.: Modeling and prototyping of heterogeneous solid CAD models. PhD thesis, University of Hong Kong (2003)
Kou, X., Tan, S.: A hierarchical representation for heterogeneous object modeling. Computer-Aided Design 37, 307 (2005)
Samanta, K., Koc, B.: Feature-based design and material blending for free-form heterogeneous object modeling. Computer-Aided Design 37, 287 (2005)
Baumgart, B.: Winged edge polyhedron representation. Stanford University, Stanford, CA (1972)
Braid, I.: The synthesis of solids bounded by many faces. Communications of the ACM 18(4), 209–216 (1975)
Zhu, F.: Visualized CAD modeling and layered manufacturing modeling for compo-nents made of a multiphase perfect material. PhD thesis, University of Hong Kong (2004)
Shin, K., Dutta, D.: Constructive representation of heterogeneous objects. Journal of Computing and Information Science in Engineering 1, 205 (2001)
Pasko, A., Adzhiev, V., Schmitt, B., Schlick, C.: Constructive hypervolume modeling. Graphical Models 63(6), 413–442 (2001)
Pasko, A., Adzhiev, V., Sourin, A., Savchenko, V.: Function representation in geometric modeling: concepts, implementation and applications. The Visual Computer 11(8), 429–446 (1995)
Biswas, A., Shapiro, V., Tsukanov, I.: Heterogeneous material modeling with distance fields. Computer Aided Geometric Design 21(3), 215–242 (2004)
Sellen, A., Harper, R.: The Myth of the Paperless Office. MIT Press, Cambridge, MA (2003)
Warshofsky, F.: The Patent Wars: The Battle to Own the World’s Technology. Wiley, Chichester (1994)
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Vilbrandt, T., Malone, E., Lipson, H., Pasko, A. (2008). Universal Desktop Fabrication. In: Pasko, A., Adzhiev, V., Comninos, P. (eds) Heterogeneous Objects Modelling and Applications. Lecture Notes in Computer Science, vol 4889. Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-540-68443-5_11
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DOI: https://doi.org/10.1007/978-3-540-68443-5_11
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