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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	Al, Bondakji, Louna, Lammich, Anne, Liese and Werner, Liss C (2019) ViBe (Virtual Berlin)-Immersive Interactive 3D Urban Data Visualization-Immersive interactive 3D urban data visualization , Proceedings of eCAADe 2019, Portugal, pp. 83-90

	Alidoost, F., Arefi, H., & Tombari, F. (2019) 2D image-to-3D model: Knowledge-based 3D building reconstruction (3DBR) using single aerial images and convolutional neural networks (CNNs) , Remote Sensing, 11(19), 2219

	Allgaier, Christoph et al. (2019) Snails as Living 3D Printers: Free Forms for the Architecture of Tomorrow , Biomimetics for Architecture (June): 126–33

	Alothman, S., Im, H.C., Jung, F., & Bechthold, M. (2019) Spatial Print Trajectory: Controlling Material Behavior with Print Speed, Feed Rate, and Complex Print Path , Willmann, J., Block, Ph., Hutter, M., Byrne, K., & Schork, T (Eds,), Robotic fabrication architecture, art & Design (pp167-18). Cham, Switzerland: Springer

	Ana Anton, Angela Yoo, Patrick Bedarf, Lex Reiter, Timothy Wangler and Benjamin Dillenburger (2019) Vertical Modulations Computational design for concrete 3D printed columns , ACADIA 19: Ubiquity and Autonomy; Proceedings of the 39th Annual Conference of the Association for Computer Aided Design in Architecture. 596–605

	Ana Anton, Angela Yoo, Patrick Bedarf, Lex Reiter, Timothy Wangler, & Benjamin Dillenburger. (2019) Vertical Modulations: Computational Design for Concrete 3D Printed Columns , ACADIA 19: Ubiquity and Autonomy. Proceedings of ACADIA 222,596-65, Available at: https://doi.org/1.52842/conf.acadia.219.596

	Aniruddha V. Shembekar, Yeo Jung Yoon, Alec Kanyuck, and Satyandra K. Gupta (2019) Generating Robot Trajectories for Conformal 3D Printing Using Nonplanar Layer , Journal of Computing and Information Science in Engineering 19(3): 031011

	Anton, A., Yoo, A., Bedarf, P., Reiter, L., Wangler, T., & Dillenburger, B. (2019) Vertical modulations: computational design for concrete 3D printed columns , Bieg, K., Briscoe, D. and Odom, C. (eds.) ACADIA2019: Ubiquity and autonomy, pp. 596-605

	Attia, S., Bilir, S., Safy, T., Struck, C., Loonen, R. & Goia, F. (2018) Current trends and future challenges in the performance assessment of adaptive faCade systems , Energy and Buildings, 179, 165–182. https://doi.org/10.1016/j.enbuild.2018.09.017Böke, J., Knaack, U., & Hemmerling, M. (2019). State-of-the-art of intelligent building envelopes in the context of intelligent technical systems. Intelligent Buildings International, 11(1), 27-45.https://doi.org/10.1080/17508975.2018.1447437Carlucci, S., Cattarin, G., Causone, F., & Pagliano, L. (2015). Multi-objective optimization ofa nearly zero-energy building based on thermal and visual discomfort minimizationusing a non-dominated sorting genetic algorithm (NSGA-II). Energy and Buildings,104, 378–394. https://doi.org/10.1016/j.enbuild.2015.06.064Hosseini, S. M., Mohammadi, M., & Guerra-santin, O. (2019). Interactive kinetic faCade: Improving visual comfort based on dynamic daylight and occupant’s positions by 2D and 3D shape changes. Building and Environment, 165, 106396. https://doi.org/10.1016/j.buildenv.2019.106396

	Barba, S, Barbarella, M, Di Benedetto, A, Fiani, M, Gujski, L and Limongiello, M (2019) Accuracy Assessment of 3D Photogrammetric Models from an Unmanned Aerial Vehicle , Drones, 3, pp. 79-97

	Bastian Wibranek, and Oliver Tessmann (2019) Digital Rubble: Compression-Only Structures with Irregular Rock and 3D Printed Connectors , Proceedings of the IASS Annual Symposium 2019,IASS 2019 Barcelona Symposium: Advanced Manufacturing andNon-conventional Materials. 1–8

	Battaglia CA, Miller MF, and Zivkovic S. (2019) Sub-additive 3D printing of optimized double curved concrete lat-tice structures , Robotic fabrication in architecture, art and design 2018, Cham: Springer

	Battaglia, C. & Miller, M. & Zivkovic, S. (2019) Sub-Additive 3D Printing of Optimized Double Curved Concrete Lattice Structures: Foreword by Sigrid Brell-Çokcan and Johannes Braumann , Association for Robots in Architecture. DOI: 10.1007/978-3-319-92294-2_19

	Battaglia, C., M. Miller, S. Zivkovic (2019) Sub-Additive 3D Printing of Optimized Double Curved Concrete Lattice Structures , Robotic Fabrication In Architecture, Art, And Design 2018, Vol. 1, ed. J. Willmann, P. Block, M. Hutter, K. Byrne, T. Schork, 245-255. Heidelberg: Springer

	Battaglia, Christopher A., Martin Fields Miller, and Sasa Zivkovic (2019) Sub-Additive 3D Printing of Optimized Double Curved Concrete Lattice Structures , Robotic Fabrication in Architecture, Art and Design 2018. Cham: Springer

	Bedarf, P., Szabo, A., Zanini, M. & Dillenburger, B. (2021) Machine Sensing for Mineral Foam 3D Printing , International Conference on Intelligent Robots and Systems: Workshop Robotic Fabrication, IROS 2021. https://doi.org/10.3929/ethz-b-000506097BubbleDeck. (2021). The Original Voided Slab. Retrieved May 11 2021, from https://www.bubbledeck.comCobiax. (2021). Voided flat plate slab technologies available worldwide. Retrieved May 11 2021, from https://www.cobiax.com/intl/en/Compas. (2020). Retrieved May 11 2021, from https://compas.dev/index.htmlFernández-Jiménez, A., & Palomo, A. (2005). Composition and microstructure of alkali activated fly ash binder: Effect of the activator. Cement and Concrete Research, 35(10), 1984–1992. https://doi.org/10.1016/j.cemconres.2005.03.003Furet, B., Poullain, P., & Garnier, S. (2019). 3D printing for construction based on a complex wall of polymer-foam and concrete. Additive Manufacturing, 28, 58–64. https://doi.org/10.1016/j.addma.2019.04.002Georgopoulos, C., & Minson, A. (2014). Sustainable concrete solutions. Wiley-Blackwell.Halpern, A. B., Billington, D. P., & Adriaenssens, S. (2013). The Ribbed Floor Slab Systems of Pier Luigi Nervi. Proceedings of the International Association for Shell and Spatial Structures (IASS), 7. http://formfindinglab.princeton.edu/wp-content/uploads/2011/09/Nervi_ribbed_floors.pdfHansemann, G., Schmid, R., Holzinger, C., Tapley, J. P., Peters, S., Trummer, A., & Kupelwieser, H. (2021). Lightweight Reinforced Concrete Slab: 130 different 3D printed voids. CPT Worldwide - Construction Printing Technology, 2021(2), 68.Jipa, A., Calvo Barentin, C., Lydon, G., Rippmann, M., Chousou, G., Lomaglio, M., Schlüter, A., Block, P., & Dillenburger, B. (2019). 3D-Printed Formwork for Integrated Funicular Concrete Slabs. Proceedings of the IASS Annual Symposium 2019, 10. https://www.researchgate.net/publication/335175125_3D-Printed_Formwork_for_Integrated_Funicular_Concrete_SlabsJipa, A., & Dillenburger, B. (2021). 3D Printed Formwork for Concrete: State-of-the-Art, Opportunities, Challenges, and Applications. 3D Printing and Additive Manufacturing, 00, 24. https://doi.org/10.1089/3dp.2021.0024Keating, S. J., Leland, J. C., Cai, L., & Oxman, N. (2017). Toward site-specific and self-sufficient robotic fabrication on architectural scales. Science Robotics, 2(5), 1-15. https://doi.org/10.1126/scirobotics.aam8986Liew, A., López, D. L., Van Mele, T., & Block, P. (2017). Design, fabrication and testing of a prototype, thin-vaulted, unreinforced concrete floor. Engineering Structures, 137, 323–335. https://doi.org/10.1016/j.engstruct.2017.01.075Palomo, A., Grutzeck, M. W., & Blanco, M. T. (1999). Alkali-activated fly ashes: A cement for the future. Cement and Concrete Research, 29(8), 1323–1329. https://doi.org/10.1016/S0008-8846(98)00243-9UN Environment Programme. (2020). Global Status Report for Buildings and Construction. Retrieved May 11 2021, from https://globalabc.org/sites/default/files/inline-files/2020%20Buildings%20GSR_FULL%20REPORT.pdfXu, H., & Van Deventer, J. S. J. (2000). The geopolymerisation of alumino-silicate minerals. International Journal of Mineral Processing, 59(3), 247–266. https://doi.org/10.1016/S0301-7516(99)00074-5Zhao, H., Gu, F., Huang, Q.-X., Garcia, J., Chen, Y., Tu, C., Benes, B., Zhang, H., Cohen-Or, D., & Chen, B. (2016). Connected fermat spirals for layered fabrication. ACM Transactions on Graphics, 35(4), 1–10. https://doi.org/10.1145/2897824.2925958

	Bendix A. (2019) These 3D-printed homes can be built for less than $4,000 in just 24 hours , New York, NY: Business Insider

	Bhooshan S., J. Ladinig, T. Van Mele, P. Block. (2019) Function Representation for Robotic 3D Printed Concrete , ROBARCH 2018. Springer, Cham

	Bhooshan, S., Ladinig, J., Van Mele, T., Block, P. (2019) Function Representation for Robotic 3D Printed Concrete , Willmann, J., Block, P., Hutter, M., Byrne, K., Schork, T. (eds) Robotic FabricationArchitecture, Art and Design 2018. ROBARCH 2018. Springer, Cham. https://doi.org/10.1007/978-3-319-92294-2_8Borg Costanzi, C., Ahmed, Z., Schipper, R.& Bos, F.,Knaack, U., Wolfs, R. (2018) 3D Printing Concrete on temporary surfaces: The design and fabrication of a concrete shell structure. AutomationConstruction. 94. 395-404. 10.1016/j.autcon.2018.06.013

	Bing Lu, Yiwei Weng, Mingyang Li, Ye Qian, Kah Fai Leong, M J Tan, and Shunzhi Qian (2019) A Systematical Review of 3D Printable Cementitious Materials , Construction and Building Materials 207 (May): 477–490

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