Cumincad : CUMINCAD References : Search Results

CumInCAD is a Cumulative Index about publications in Computer Aided Architectural Design
supported by the sibling associations ACADIA, CAADRIA, eCAADe, SIGraDi, ASCAAD and CAAD futures

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	Goodyear, P. (2005) Educational design and networked learning: Patterns, pattern languages and design practice , Australasian Journal of Educational Technology, 21(1), 82-101. https://doi.org/10.14742/ajet.1344

	Gool, P, Müller, P, Wonka, P, Haegler, S, Ulmer, A and Van Gool, L (2006) Procedural Modeling of Buildings , ACM SIGGRAPH, Boston, pp. 614-623

	Goong, C., Oingang, X., Philip, J. M., Eric, G. P., Alexey, S., and Yui, C. W. (2014) Open-FOAM for Computational Fluid Dynamics , NOTICES OF THE AMS, 61(4), 354–363

	Goral, C.M., Torrace, K., Greenberg, D.P. and Battaile, B. (1984) Modeling the Interaction of Light Between Diffuse Surfaces , Computer Graphics, 18, no. 3, 213-222

	Goral, C.M., Torrace, K., Greenberg, D.P. and Battaile, B. (1984) Modeling the Interaction of Light Between Diffuse Surfaces , Computer Graphics. 18, no. 3, 213-222.

	Goral, C.M., Torrance, E.K., Greenberg, D.P. and Battaile, B. (1984) Modelling the interaction of light between diffuse surfaces , H. Christiansen, editor, Computer Graphics (Siggraphí84 proc.), pages 213-222, July 1984

	Goral, C.M., Torrance, E.K., Greenberg, D.P. and Battaile, B. (1984) Modelling the Interaction of Light between Diffuse Surface , Computer Graphics (Siggraph’84 proc.), ed. H. Christiansen, 213-222, July 1984

	Goral, C.M., Torrance, K.E., Greenberg, D.P. and Battaile, B. (1984) Modeling the Interacion of Light Between Diffuse Surfaces , Computer Graphics Proc.Siggraph, Vol. 18, No. 3, July 1984, pp. 213-222

	Goral, M., Torrance, K.E., Greenberg, D.P. and Battaile, B. (1984) Modeling the Interaction of Light Between Diffuse Surfaces , ACM Computer Graphics (Proceedings) 213-222

	Gorbet, R (2010) Revealing the Hylozoic Ground Interaction Layer , Beesley, P (eds), Hylozoic Ground: Liminal responsive architecture, Riverside Architectural Press, Toronto, pp. 112-123

	Gorbet, R. (2010) Revealing the Hylozoic Ground Interaction Layer , P. Beesley (ed.), Hylozoic Ground: Liminal Responsive Architecture, Riverside Architectural Press, Toronto, 113–123

	Gordon, J. E., and P. Ball (2006) The New Science of Strong Materials or Why You Don’t Fall through the Floor , New York: Princeton Science Library

	Gordon, P and Richardson, HW (1989) Gasoline Consumption and Cities: A Reply , Journal of the American Planning Association, 55, pp. 342-346

	Gorman, M. J. (2005) Buckminster Fuller: Designing for Mobility , Skira Editore, p.115

	Gorse, C. A. and S. Emmitt (2003) Investigating Interpersonal Communication during Construction Progress Meetings: Challenges and Opportunities , Engineering, Construction and Architectural Management 10:4, p. 234-244

	Gorti, S.R. and R.D. Sriram (1997) From symbol to form: a framework for conceptual design , Computer-Aided Design 28, p. 853-870

	Gosselin C, Duballet R, Roux P, Gaudilli?re N, Dirrenberger J, Morel P. (2016) Large-scale 3D printing of ultra-high performance concrete–a new processing route for architects and builders , Materials & Design

	Gosselin, C, Duballet, R, Roux, P, Gaudilliere, N, Dirrenberger, J and Morel, P (2016) Large-Scale 3D Printing of Ultra-High Performance Concrete - a New Processing Route for Architects and Builders , Materials & Design, 100, pp. 102-109

	Gosselin, C., Duballet, R., Roux, P., Et Al. (2016) Large-scale 3D Printing of Ultra-high Performance Concrete - a New Processing Route for Architects and Builders , Materials & Design, 1 12-19. Available at: https://doi.org/1.116/j.matdes.216.3.97

	Gosselin, C., Duballet, R., Roux, P., Gaudilliere, N., Dirrenberger, J. & Morel, P. (2016) Large-scale 3D printing of ultra-high performance concrete–a new processing route for architects and builders , Materials & Design, 100, 102-109. https://doi.org/10.1016/j.matdes.2016.03.097Khoshnevis, B. (2004). Automated construction by contour crafting—related robotics and information technologies. Automation in construction, 13(1), 5-19. https://doi.org/10.1016/j.autcon.2003.08.012Le, T. T., Austin, S. A., Lim, S., Buswell, R. A., Gibb, A. G., & Thorpe, T. (2012). Mix design and fresh properties for high-performance printing concrete. Materials and structures, 45(8), 1221-1232. https://doi.org/10.1617/s11527-012-9828-zLi, Z., Wang, L., Ma, G., Sanjayan, J., & Feng, D. (2020). Strength and ductility enhancement of 3D printing structure reinforced by embedding continuous micro-cables. Construction and Building Materials, 264, 120196. https://doi.org/10.1016/j.conbuildmat.2020.120196Lim, J. H., Weng, Y., & Pham, Q. C. (2020). 3D printing of curved concrete surfaces using Adaptable Membrane Formwork. Construction and Building Materials, 232, 117075. https://doi.org/10.1016/j.conbuildmat.2019.117075Ma, G., Li, Z., Wang, L., & Bai, G. (2019). Micro-cable reinforced geopolymer composite for extrusion-based 3D printing. Materials Letters, 235, 144-147. https://doi.org/10.1016/j.matlet.2018.09.159Masoud Akbarzadeh. Andrei Nejur.(2019). Polyframe. From https://psl.design.upenn.edu/polyframe/Mechtcherine, V., Nerella, V. N., Will, F., Näther, M., Otto, J., & Krause, M. (2019). Large-scale digital concrete construction–CONPrint3D concept for on-site, monolithic 3D-printing. Automation in Construction, 107, 102933. https://doi.org/10.1016/j.autcon.2019.102933Salet, T. A., Ahmed, Z. Y., Bos, F. P., & Laagland, H. L. (2018). Design of a 3D printed concrete bridge by testing. Virtual and Physical Prototyping, 13(3), 222-236. https://doi.org/10.1080/17452759.2018.1476064

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