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Alzate Arias, F. A. (2022). Prospectiva de diseño de dispositivos acusticos con metamateriales. Técnicas origami. Ingenierías USBmed, 13(2), 35–47. https://doi.org/10.21500/20275846.4495 (Original work published September 27, 2022)
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Abstract
This work does a comprehensive look in academic database on projects that have to do with structures, active acoustic devices inspired by metamaterials and in forms created from patterns seen in nature, the focus of the work is to give a forward-looking look at the different scenarios that result from the different projects that innovative in architectural acoustics, also as a contribution of technological vigilance and art strait on this type of device. A detailed report of what is the current state of scientific production in this field and as is our country with review to other countries considering that architectural acoustics converge in many fields of knowledge such as materials, the civil engineering, physics and design, combining science, art, technology and innovation as the main aspects of the research group of the Faculty be Arts and Humanities of the Metropolitan Technological Institute.
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References
[1] R.Walser, “Metamaterials: What are they? What are they good for?,” ene. 2000.
[2] “WIPO - Search International and National Patent
Collections”. https://patentscope.wipo.int/search/en/result.jsf?_vid=P10-L5B9XI-82878 (accessed June 7, 2019).
[3] “Scopus - Analyze search results”. https://scopus.bibliotecaitm.elogim.com/term/analyzer.uri?sid=f92d0e0bdd5bafb137f428f41c13be35&origin=resultslist&src=s&s=TITLE-ABS-KEY%28acoustics++metamaterials+nanomaterials%29&sort=plf-f&sdt=b&sot=b&sl=53&count=7&analyzeResults=Analyze+results&txGid=16f5a0d320ad451bb028fedb0d988f15 (accessed May 16, 2019).
[4] “Scopus - Analyze search results”. https://scopus.bibliotecaitm.elogim.com/term/analyzer.uri?sid=39d348ee250df998cc73d949b8cddfc8&origin=resultslist&src=s&s=TITLE-ABS-KEY%28acoustics++materials%29&sort=plff&sdt=b&sot=b&sl=35&count=80940&analyzeResults=Analyze+results&txGid=475d8e8395612e632983b3068e786e1a (accessed May 20, 2019).
[5] “ScienceDirect Search Results - Keywords (materials acoustics)”. https://sciencedirect.bibliotecaitm.elogim.com/search?qs=materials%20acoustics&years=2003%2C2004%2C2005%2C2006%2C2007%2C2008%2C2009%2C2018%2C2017%2C2016%2C2015%2C2014%2C2013%2C2012%2C2011%2C2010&articleTypes=FLA&sortBy=relevance&publicationTitles=271440&lastSelectedFacet=publicationTitles (accessed June 7, 2019).
[6] “Scopus - Document search results”. https://scopus.bibliotecaitm.elogim.com/results/results.uri?sort=plf-f&src=s&st1=acoustics++AND+materials++AND+noise&sid=353ba33aa82f014c50e0
26dc7896c4c4&sot=b&sdt=b&sl=50&s=TITLEABS-KEY%28acoustics++AND+materials++AND+noise%29&origin=searchbasic&editSaveSea
rch=&yearFrom=Before+1960&yearTo=Present(accessed July 7, 2019).
[7] “Scopus - Analyze search results”. https://scopus.bibliotecaitm.elogim.com/term/analyzer.uri?sid=513058b33fa3cdacd83338d8f8731e8d&origin=resultslist&src=s&s=TITLE-ABS-KEY%28acoustics+panels+noise%29&sort=plf-f&sdt=b&sot=b&sl=37&count=3472&analyzeResults=Analyze+results&txGid=f0e5c2f110ccc9cbce18f68f9c383594 (accessed May 24, 2019).
[8] “Scopus - Analyze search results”. https://scopus.bibliotecaitm.elogim.com/term/analyzer.uri?sid=f432f78bb8622fb777103db09bfbedb0&origin=resultslist&src=s&s=TITLE-ABS-KEY%28Acoustics+and+panels%29&sort=plf-f&sdt=b&sot=b&sl=35&count=7906&analyzeResults=Analyze+results&txGid=8c9ba5666cab7dbc8b3cfda01
6e6f20c (accessed May 25, 2019).
[9] “Scopus - Document search results”. https://scopus.bibliotecaitm.elogim.com/results/results.uri?sort=plff&src=s&st1=origami+acoustics&sid=33d374daffc103b360e9a3ad606af6cf&sot=b&sdt=b&sl=32&s=TITLE-ABS-KEY%28origami+acoustics%29&origin=searchbasic&editSaveSearch=&yearFrom=Before+1960&yearTo=Present (accessed June 7, 2019).
[10] “Scopus - Analyze search results”. https://scopus.bibliotecaitm.elogim.com/term/analyzer.uri?sid
=60d2b163e3c397db07502e7ceb2fccf0&origin=resultslist&src=s&s=TITLE-ABS-KEY%28origami+folded+acoustics%29&sort=plf-f&sdt=b&s ot=b&sl=39&count=11&analyzeResults=Analyze+results&txGid=6d4b15dbd99a0625b6692527e055603d (accessed May 13, 2019).
[11] “Scopus - Analyze search results”. https://scopus.bibliotecaitm.elogim.com/term/analyzer.uri?sid=c7e795144faed70b5f055b88bf062332&origin=resultslist&src=s&s=TITLE-ABS-KEY%28origami+panel+acoustics%29&sort=plff&sdt=b&sot=b&sl=38&count=7&analyzeResults=Analyze+results&txGid=e185430da799838902091b86750e43a (accessed May 14, 2019).
[12] “Scopus - Document search results”. https://scopus.bibliotecaitm.elogim.com/results/results.uri?sort=plf-f&src=s&st1=origami++architectural+geometry&sid=0a16d1c1f15117de1cc89234aee6d30b&sot=b&sdt=b&sl=46&s=TITLE-ABS-KE
Y%28origami++architectural+geometry%29&origin=searchbasic&editSaveSearch=&yearFrom=Before+1960&yearTo=Present (accessed June 8, 2019).
[13] “Scopus - Analyze search results”. https://scopus.bibliotecaitm.elogim.com/term/analyzer.uri?sid=0a16d1c1f15117de1cc89234aee6d30b&origin=resultslist&src=s&s=TITLE-ABS-KEY%28origami++architectural+geometry%29&sort=plf-f&sdt=b&sot=b&sl=46&count=39&analyzeResults=Analyze+results&txGid=8de4da2290832e5ae1b2236f0c02a041 (accessed June 8, 2019).
[14] “Scopus - Document search results”. https://scopus.bibliotecaitm.elogim.com/results/results.uri?sor
t=plf-f&src=s&st1=metamaterials+acoustics&sid=715a1bca93a42908f79df5b09c9024d1&sot=b&sdt=b&sl=38&s=TITLE-ABS-KEY%28metamaterials+acoustics%29&origin=searchbasic&editSaveSearch=&yearFrom=Before+1960&yearTo=Present (accessed June 7, 2020).
[15] “Scopus - Analyze search results”. https://scopus.bibliotecaitm.elogim.com/term/analyzer.uri?sid=715a1bca93a42908f79df5b09c9024d1&origin=resultslist&src=s&s=TITLE-ABS-KEY%28metamaterials+acoustics%29&sort=plf-f&sdt=b&sot=b&sl=38&count=3460&analyzeResults=Analyze+results&txGid=73d3f72662e040249175e177eee7a6df(accessed June 7, 2020).
[16] “Scopus - Document search results”. https://scopus.bibliotecaitm.elogim.com/results/results.uri?sort=plff&src=s&st1=acoustic+metamaterials+resonator&sid=62ff9286413a9c8fd79469f1c0ca6257&sot=b&sdt=b&sl=47&s=TITLE-ABS-KEY%28acoustic+metamaterials+resonator%29&origin=searchbasic&editSaveSearch=&yearFrom=Before+1960&yearTo=Present (accessed June 9, 2020).
[17] “Scopus - Document search results”. https://scopus.bibliotecaitm.elogim.com/results/results.uri?sort=plf-f&src=s&st1=metamaterials+acoustics+origami&sid=8a446aa1d280c011d6d8903c53dc060d&sot=b&sdt=b&sl=46&s=TITLE-ABS-KEY%28metamaterials+acoustics+origami%29&origin=searchbasic&editSaveSearch=&yearFrom=Before+1960&yearTo=Present (accessed June 6, 2020).
[18] “Scopus - Analyze search results”. https://scopus.bibliotecaitm.elogim.com/term/analyzer.uri?sid=8a446aa1d280c011d6d8903c53dc060d&origin=resultslist&src=s&s=TITLE-ABS-KEY%28metamaterials+acoustics+origami%29&sort=plf-f&sdt=b&sot=b&sl=46&count=25&analyzeResult
s=Analyze+results&txGid=dfce0edd4e066583197151a673a210bf (accessed June 6, 2020).
[19] “OMPI - Búsqueda en las colecciones de patentesnacionales e internacionales”. https://patentscope.wipo.int/search/es/result.jsf?_vid=P21-L3AN78-25698 (accessed May 15, 2019).
[20] “WIPO - Search International and National Patent Collections”. https://patentscope.wipo.int/
search/en/result.jsf?_vid=P21-L3ANF7-27516 (accessed May 16, 2021).
[21] “WIPO - Search International and National Patent Collections”. https://patentscope.wipo.int/
search/en/result.jsf?_vid=P21-L3ANJT-28555 (accessed May 20, 2019).
[22] “WIPO - Search International and National Patent Collections”. https://patentscope.wipo.int/
search/en/result.jsf?_vid=P21-L3ANMC-29031 (accessed May 21, 2019).
[23] “WIPO - Search International and National Patent Collections”. https://patentscope.wipo.int/
search/en/result.jsf?_vid=P12-L3AQ1B-59073 (accessed May 22, 2019).
[24] M. Schenk y S. Guest, “Origami folding: A structural engineering approach”, presented at the 10th
International Conference on Technology of Plasticity, ICTP 2011, Asquigrán, Alemania, Sept. 25–30, 2011. Available http://www2.eng.cam. ac.uk/~sdg/preprint/5OSME.pdf.
[25] M. Schenk, J. M. Allwood y S. D. Guest, “Cold gas-pressure folding of Miura-ori sheets”, presented at the 10th International Conference on Technology of Plasticity, ICTP 2011, Asquigrán, Alemania, Sept. 25–30, 2011. Available: http://www2. eng.cam.ac.uk/~sdg/preprint/MiuraForming. pdf.
[26] T. Tachi, “Generalization of rigid foldable quadrilateral mesh origami”, presented at the International Association for Shell and Spatial Structures (ASS) Symposium 2009, Valencia, España, Sept. 28 – Oct. 2, 2009. Available: https://iam.tug raz.at/workshop_rijeka/wp-content/uploads/201 2/09/RigidFoldableQuadMeshOrigami_tachi_IA
SS2009.pdf.
[27] Tachi Lab, “Software. Freeform Origami”. Available https://origami.c.u- tokyo.ac.jp/~tachi/ software/
[28] E. Demaine y T. Tachi, “Origamizer: A practical algorithm for folding any polyhedron”, presented at the 33rd International Symposium of Computational Geometry, Brisbane, Australia, Jul. 4-7, 2017. https://doi.org/10.4230/LIPIcs.SoCG. 2017.34.
[29] M. Giodice, “Modellazione parametrica e comportamento meccanico di superfici adattive in architettura: Analisi esperimentazione”. Ph. D. dissertation, Sapienza Università di Rom, 2017. Available: https://core.ac.uk/display/127586956? recSetID=.
[30] H. Buri e Y.Weinand, “ORIGAMI - Folded Plate Structures, Architecture”, presented at the 10th World Conference on Timber Engineering, Miyazaki, Japón, June 2-5, 2017.
[31] X. Yang, “Adaptive acoustic origami”. M.S. Thesis, Universidad de Melbourne, 2017. Available: https://www.youtube.com/watch v=RKOUn-J6HL4&feature=share.
[32] Z. Y. Wei, Z. V. Guo, L. Dudte, H. Y. Liang y L. Mahadevan, “Geometric mechanics of periodic pleated origami,” Physical Review Letters, vol. 110, n◦. 21, 2013. https://doi.org/10.1103/ PhysRevLett.110.215501.
[33] C. Samuelsson y B. Vestlund, “Structural folding. A parametric design method for origami architecture”. M.S. Thesis, Chalmers University of Technology, Gotemburgo, Suecia, 2015. Available: https://odr.chalmers.se/handle/20.500.12380/222002.
[34] M. Thota y K. W. Wang, “Reconfigurable origami sonic barriers with tunable bandgaps for traffic noise mitigation,” Journal of Applied Physics, n◦ 122, 2017. https://doi.org/10.1063/1.4991026.
[35] E. Demaine y T. Tachi, “Origamizer: A practical algorithm for folding any polyhedron”, presented at the 33rd International Symposium of Computational Geometry, Brisbane, Australia, Jul. 4–7, 2017. https://doi.org/10.4230/LIPIcs.SoCG.2017.34.
[36] T. Tachi y T. C. Hull, “Self-foldability of rigid origami,” Journal of Mechanisms and Robotics, vol. 9, n◦ 2, Aprl., 2017. https : / / doi .org / 10 .1115/1.4035558.
[37] R. Resch y E. Armstrong, “The Ron Resch paper and stick film”, 1992 [Online]. Available: https://www.youtube.com/watch v=imlMspPKfNo.
[38]R. Foschi, “Algorithmic modelling of folded surfaces. Analysis and design of folded surfaces in
architecture and manufacturing”. Ph. D. dissertation, Alma Mater Studiorum, Universidad de Boloña, 2019. https://doi.org/10.6092/unibo/amsdottorato/8871.
[39] Robert J. Lang Origami TASON, “TreeMaker” [Online]. Available: https : / / langorigami .com/ article/treemaker/
[40] Tachi Lab, “Software. Freeform Origami” [Online]. Available: https://origami.c.u-tokyo.ac.jp/~tachi/software/
[41] E. Demaine y T. Tachi, “Origamizer: A ractical algorithm for folding any polyhedron”, presented at the 33rd International Symposium of Computational
Geometry, Brisbane, Australia, Jul. 4-7, 2017. https://doi.org/10.4230/LIPIcs.SoCG.2017.34.
[42] P. Wang-Inverson, R. J. Lang and M. Yim (eds.), Origami 5. Proceedings to the Fifth International Meeting of Origami Science, Mathematics and Education, Ciudad de Nueva York, NY: AK Peters / CRC Press, 2011.
[43] T. Tachi y T. C. Hull, “Self-foldability of rigid origami,” Journal of Mechanisms and Robotics, vol. 9, n◦ 2, Aprl., 2017. https : / / doi .org/ 10 .1115/1.4035558.
[44] J. Mitani y T. Igarashi, “Interactive design of planar curved folding by reection”, presented at the 19th Pacific Conference on Computer Graphics and Applications, Pacific Graphics, Kaohsiung, Taiwán, Sept. 21-23. Available: https://www.jst. go.jp/erato/igarashi/publications/001/PG2011. pdf.
[45] Origamisimulator.org [Online]. Available http:// apps.amandaghassaei.com/OrigamiSimulator/
[46] R. Foschi, “Algorithmic modelling of folded surfaces. Analysis and design of folded surfaces in
architecture and manufacturing”. Ph. D. Thesis, Alma Mater Studiorum, Universidad de Boloña,
2019. https://doi.org/10.6092/unibo/amsdottora to/8871.
[47] J. M. Gattas y Z. You, “Design and digital fabrication of folded sandwich structures,” Automation in Construction, n◦ 63, pp. 79-87, March,
2016. https://doi.org/10.1016/j.autcon.2015.12.002.
[48] G. Epps, “RoboFold and Robots.IO,” Architectural Design, vol. 84, n◦. 3, pp. 68–69, 2014. https:
//doi.org/10.1002/ad.1757.
[49] R. Foschi, “Algorithmic modelling of folded surfaces. Analysis and design of folded surfaces in
architecture and manufacturing”. P.h. D. dissertation, Alma Mater Studiorum, Universidad de
Boloña, 2019. https://doi.org/10.6092/unibo/amsdottorato/8871.
[50] M. Giodice, “Modellazione parametrica e comportamento meccanico di superfici adattive in architettura: Analisi e sperimentazione”. P.h. D. dissertation, Sapienza Università di Roma, 2017. https://core.ac.uk/display/127586956?recSetID=.
[2] “WIPO - Search International and National Patent
Collections”. https://patentscope.wipo.int/search/en/result.jsf?_vid=P10-L5B9XI-82878 (accessed June 7, 2019).
[3] “Scopus - Analyze search results”. https://scopus.bibliotecaitm.elogim.com/term/analyzer.uri?sid=f92d0e0bdd5bafb137f428f41c13be35&origin=resultslist&src=s&s=TITLE-ABS-KEY%28acoustics++metamaterials+nanomaterials%29&sort=plf-f&sdt=b&sot=b&sl=53&count=7&analyzeResults=Analyze+results&txGid=16f5a0d320ad451bb028fedb0d988f15 (accessed May 16, 2019).
[4] “Scopus - Analyze search results”. https://scopus.bibliotecaitm.elogim.com/term/analyzer.uri?sid=39d348ee250df998cc73d949b8cddfc8&origin=resultslist&src=s&s=TITLE-ABS-KEY%28acoustics++materials%29&sort=plff&sdt=b&sot=b&sl=35&count=80940&analyzeResults=Analyze+results&txGid=475d8e8395612e632983b3068e786e1a (accessed May 20, 2019).
[5] “ScienceDirect Search Results - Keywords (materials acoustics)”. https://sciencedirect.bibliotecaitm.elogim.com/search?qs=materials%20acoustics&years=2003%2C2004%2C2005%2C2006%2C2007%2C2008%2C2009%2C2018%2C2017%2C2016%2C2015%2C2014%2C2013%2C2012%2C2011%2C2010&articleTypes=FLA&sortBy=relevance&publicationTitles=271440&lastSelectedFacet=publicationTitles (accessed June 7, 2019).
[6] “Scopus - Document search results”. https://scopus.bibliotecaitm.elogim.com/results/results.uri?sort=plf-f&src=s&st1=acoustics++AND+materials++AND+noise&sid=353ba33aa82f014c50e0
26dc7896c4c4&sot=b&sdt=b&sl=50&s=TITLEABS-KEY%28acoustics++AND+materials++AND+noise%29&origin=searchbasic&editSaveSea
rch=&yearFrom=Before+1960&yearTo=Present(accessed July 7, 2019).
[7] “Scopus - Analyze search results”. https://scopus.bibliotecaitm.elogim.com/term/analyzer.uri?sid=513058b33fa3cdacd83338d8f8731e8d&origin=resultslist&src=s&s=TITLE-ABS-KEY%28acoustics+panels+noise%29&sort=plf-f&sdt=b&sot=b&sl=37&count=3472&analyzeResults=Analyze+results&txGid=f0e5c2f110ccc9cbce18f68f9c383594 (accessed May 24, 2019).
[8] “Scopus - Analyze search results”. https://scopus.bibliotecaitm.elogim.com/term/analyzer.uri?sid=f432f78bb8622fb777103db09bfbedb0&origin=resultslist&src=s&s=TITLE-ABS-KEY%28Acoustics+and+panels%29&sort=plf-f&sdt=b&sot=b&sl=35&count=7906&analyzeResults=Analyze+results&txGid=8c9ba5666cab7dbc8b3cfda01
6e6f20c (accessed May 25, 2019).
[9] “Scopus - Document search results”. https://scopus.bibliotecaitm.elogim.com/results/results.uri?sort=plff&src=s&st1=origami+acoustics&sid=33d374daffc103b360e9a3ad606af6cf&sot=b&sdt=b&sl=32&s=TITLE-ABS-KEY%28origami+acoustics%29&origin=searchbasic&editSaveSearch=&yearFrom=Before+1960&yearTo=Present (accessed June 7, 2019).
[10] “Scopus - Analyze search results”. https://scopus.bibliotecaitm.elogim.com/term/analyzer.uri?sid
=60d2b163e3c397db07502e7ceb2fccf0&origin=resultslist&src=s&s=TITLE-ABS-KEY%28origami+folded+acoustics%29&sort=plf-f&sdt=b&s ot=b&sl=39&count=11&analyzeResults=Analyze+results&txGid=6d4b15dbd99a0625b6692527e055603d (accessed May 13, 2019).
[11] “Scopus - Analyze search results”. https://scopus.bibliotecaitm.elogim.com/term/analyzer.uri?sid=c7e795144faed70b5f055b88bf062332&origin=resultslist&src=s&s=TITLE-ABS-KEY%28origami+panel+acoustics%29&sort=plff&sdt=b&sot=b&sl=38&count=7&analyzeResults=Analyze+results&txGid=e185430da799838902091b86750e43a (accessed May 14, 2019).
[12] “Scopus - Document search results”. https://scopus.bibliotecaitm.elogim.com/results/results.uri?sort=plf-f&src=s&st1=origami++architectural+geometry&sid=0a16d1c1f15117de1cc89234aee6d30b&sot=b&sdt=b&sl=46&s=TITLE-ABS-KE
Y%28origami++architectural+geometry%29&origin=searchbasic&editSaveSearch=&yearFrom=Before+1960&yearTo=Present (accessed June 8, 2019).
[13] “Scopus - Analyze search results”. https://scopus.bibliotecaitm.elogim.com/term/analyzer.uri?sid=0a16d1c1f15117de1cc89234aee6d30b&origin=resultslist&src=s&s=TITLE-ABS-KEY%28origami++architectural+geometry%29&sort=plf-f&sdt=b&sot=b&sl=46&count=39&analyzeResults=Analyze+results&txGid=8de4da2290832e5ae1b2236f0c02a041 (accessed June 8, 2019).
[14] “Scopus - Document search results”. https://scopus.bibliotecaitm.elogim.com/results/results.uri?sor
t=plf-f&src=s&st1=metamaterials+acoustics&sid=715a1bca93a42908f79df5b09c9024d1&sot=b&sdt=b&sl=38&s=TITLE-ABS-KEY%28metamaterials+acoustics%29&origin=searchbasic&editSaveSearch=&yearFrom=Before+1960&yearTo=Present (accessed June 7, 2020).
[15] “Scopus - Analyze search results”. https://scopus.bibliotecaitm.elogim.com/term/analyzer.uri?sid=715a1bca93a42908f79df5b09c9024d1&origin=resultslist&src=s&s=TITLE-ABS-KEY%28metamaterials+acoustics%29&sort=plf-f&sdt=b&sot=b&sl=38&count=3460&analyzeResults=Analyze+results&txGid=73d3f72662e040249175e177eee7a6df(accessed June 7, 2020).
[16] “Scopus - Document search results”. https://scopus.bibliotecaitm.elogim.com/results/results.uri?sort=plff&src=s&st1=acoustic+metamaterials+resonator&sid=62ff9286413a9c8fd79469f1c0ca6257&sot=b&sdt=b&sl=47&s=TITLE-ABS-KEY%28acoustic+metamaterials+resonator%29&origin=searchbasic&editSaveSearch=&yearFrom=Before+1960&yearTo=Present (accessed June 9, 2020).
[17] “Scopus - Document search results”. https://scopus.bibliotecaitm.elogim.com/results/results.uri?sort=plf-f&src=s&st1=metamaterials+acoustics+origami&sid=8a446aa1d280c011d6d8903c53dc060d&sot=b&sdt=b&sl=46&s=TITLE-ABS-KEY%28metamaterials+acoustics+origami%29&origin=searchbasic&editSaveSearch=&yearFrom=Before+1960&yearTo=Present (accessed June 6, 2020).
[18] “Scopus - Analyze search results”. https://scopus.bibliotecaitm.elogim.com/term/analyzer.uri?sid=8a446aa1d280c011d6d8903c53dc060d&origin=resultslist&src=s&s=TITLE-ABS-KEY%28metamaterials+acoustics+origami%29&sort=plf-f&sdt=b&sot=b&sl=46&count=25&analyzeResult
s=Analyze+results&txGid=dfce0edd4e066583197151a673a210bf (accessed June 6, 2020).
[19] “OMPI - Búsqueda en las colecciones de patentesnacionales e internacionales”. https://patentscope.wipo.int/search/es/result.jsf?_vid=P21-L3AN78-25698 (accessed May 15, 2019).
[20] “WIPO - Search International and National Patent Collections”. https://patentscope.wipo.int/
search/en/result.jsf?_vid=P21-L3ANF7-27516 (accessed May 16, 2021).
[21] “WIPO - Search International and National Patent Collections”. https://patentscope.wipo.int/
search/en/result.jsf?_vid=P21-L3ANJT-28555 (accessed May 20, 2019).
[22] “WIPO - Search International and National Patent Collections”. https://patentscope.wipo.int/
search/en/result.jsf?_vid=P21-L3ANMC-29031 (accessed May 21, 2019).
[23] “WIPO - Search International and National Patent Collections”. https://patentscope.wipo.int/
search/en/result.jsf?_vid=P12-L3AQ1B-59073 (accessed May 22, 2019).
[24] M. Schenk y S. Guest, “Origami folding: A structural engineering approach”, presented at the 10th
International Conference on Technology of Plasticity, ICTP 2011, Asquigrán, Alemania, Sept. 25–30, 2011. Available http://www2.eng.cam. ac.uk/~sdg/preprint/5OSME.pdf.
[25] M. Schenk, J. M. Allwood y S. D. Guest, “Cold gas-pressure folding of Miura-ori sheets”, presented at the 10th International Conference on Technology of Plasticity, ICTP 2011, Asquigrán, Alemania, Sept. 25–30, 2011. Available: http://www2. eng.cam.ac.uk/~sdg/preprint/MiuraForming. pdf.
[26] T. Tachi, “Generalization of rigid foldable quadrilateral mesh origami”, presented at the International Association for Shell and Spatial Structures (ASS) Symposium 2009, Valencia, España, Sept. 28 – Oct. 2, 2009. Available: https://iam.tug raz.at/workshop_rijeka/wp-content/uploads/201 2/09/RigidFoldableQuadMeshOrigami_tachi_IA
SS2009.pdf.
[27] Tachi Lab, “Software. Freeform Origami”. Available https://origami.c.u- tokyo.ac.jp/~tachi/ software/
[28] E. Demaine y T. Tachi, “Origamizer: A practical algorithm for folding any polyhedron”, presented at the 33rd International Symposium of Computational Geometry, Brisbane, Australia, Jul. 4-7, 2017. https://doi.org/10.4230/LIPIcs.SoCG. 2017.34.
[29] M. Giodice, “Modellazione parametrica e comportamento meccanico di superfici adattive in architettura: Analisi esperimentazione”. Ph. D. dissertation, Sapienza Università di Rom, 2017. Available: https://core.ac.uk/display/127586956? recSetID=.
[30] H. Buri e Y.Weinand, “ORIGAMI - Folded Plate Structures, Architecture”, presented at the 10th World Conference on Timber Engineering, Miyazaki, Japón, June 2-5, 2017.
[31] X. Yang, “Adaptive acoustic origami”. M.S. Thesis, Universidad de Melbourne, 2017. Available: https://www.youtube.com/watch v=RKOUn-J6HL4&feature=share.
[32] Z. Y. Wei, Z. V. Guo, L. Dudte, H. Y. Liang y L. Mahadevan, “Geometric mechanics of periodic pleated origami,” Physical Review Letters, vol. 110, n◦. 21, 2013. https://doi.org/10.1103/ PhysRevLett.110.215501.
[33] C. Samuelsson y B. Vestlund, “Structural folding. A parametric design method for origami architecture”. M.S. Thesis, Chalmers University of Technology, Gotemburgo, Suecia, 2015. Available: https://odr.chalmers.se/handle/20.500.12380/222002.
[34] M. Thota y K. W. Wang, “Reconfigurable origami sonic barriers with tunable bandgaps for traffic noise mitigation,” Journal of Applied Physics, n◦ 122, 2017. https://doi.org/10.1063/1.4991026.
[35] E. Demaine y T. Tachi, “Origamizer: A practical algorithm for folding any polyhedron”, presented at the 33rd International Symposium of Computational Geometry, Brisbane, Australia, Jul. 4–7, 2017. https://doi.org/10.4230/LIPIcs.SoCG.2017.34.
[36] T. Tachi y T. C. Hull, “Self-foldability of rigid origami,” Journal of Mechanisms and Robotics, vol. 9, n◦ 2, Aprl., 2017. https : / / doi .org / 10 .1115/1.4035558.
[37] R. Resch y E. Armstrong, “The Ron Resch paper and stick film”, 1992 [Online]. Available: https://www.youtube.com/watch v=imlMspPKfNo.
[38]R. Foschi, “Algorithmic modelling of folded surfaces. Analysis and design of folded surfaces in
architecture and manufacturing”. Ph. D. dissertation, Alma Mater Studiorum, Universidad de Boloña, 2019. https://doi.org/10.6092/unibo/amsdottorato/8871.
[39] Robert J. Lang Origami TASON, “TreeMaker” [Online]. Available: https : / / langorigami .com/ article/treemaker/
[40] Tachi Lab, “Software. Freeform Origami” [Online]. Available: https://origami.c.u-tokyo.ac.jp/~tachi/software/
[41] E. Demaine y T. Tachi, “Origamizer: A ractical algorithm for folding any polyhedron”, presented at the 33rd International Symposium of Computational
Geometry, Brisbane, Australia, Jul. 4-7, 2017. https://doi.org/10.4230/LIPIcs.SoCG.2017.34.
[42] P. Wang-Inverson, R. J. Lang and M. Yim (eds.), Origami 5. Proceedings to the Fifth International Meeting of Origami Science, Mathematics and Education, Ciudad de Nueva York, NY: AK Peters / CRC Press, 2011.
[43] T. Tachi y T. C. Hull, “Self-foldability of rigid origami,” Journal of Mechanisms and Robotics, vol. 9, n◦ 2, Aprl., 2017. https : / / doi .org/ 10 .1115/1.4035558.
[44] J. Mitani y T. Igarashi, “Interactive design of planar curved folding by reection”, presented at the 19th Pacific Conference on Computer Graphics and Applications, Pacific Graphics, Kaohsiung, Taiwán, Sept. 21-23. Available: https://www.jst. go.jp/erato/igarashi/publications/001/PG2011. pdf.
[45] Origamisimulator.org [Online]. Available http:// apps.amandaghassaei.com/OrigamiSimulator/
[46] R. Foschi, “Algorithmic modelling of folded surfaces. Analysis and design of folded surfaces in
architecture and manufacturing”. Ph. D. Thesis, Alma Mater Studiorum, Universidad de Boloña,
2019. https://doi.org/10.6092/unibo/amsdottora to/8871.
[47] J. M. Gattas y Z. You, “Design and digital fabrication of folded sandwich structures,” Automation in Construction, n◦ 63, pp. 79-87, March,
2016. https://doi.org/10.1016/j.autcon.2015.12.002.
[48] G. Epps, “RoboFold and Robots.IO,” Architectural Design, vol. 84, n◦. 3, pp. 68–69, 2014. https:
//doi.org/10.1002/ad.1757.
[49] R. Foschi, “Algorithmic modelling of folded surfaces. Analysis and design of folded surfaces in
architecture and manufacturing”. P.h. D. dissertation, Alma Mater Studiorum, Universidad de
Boloña, 2019. https://doi.org/10.6092/unibo/amsdottorato/8871.
[50] M. Giodice, “Modellazione parametrica e comportamento meccanico di superfici adattive in architettura: Analisi e sperimentazione”. P.h. D. dissertation, Sapienza Università di Roma, 2017. https://core.ac.uk/display/127586956?recSetID=.
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