| id |
acadia07_250 |
| authors |
Wierzbicki-Neagu, Madalina; de Silva, Clarence W. |
| year |
2007 |
| title |
Development of Design Workflows for Kinetic Structures Using Fuzzy Logic |
| doi |
https://doi.org/10.52842/conf.acadia.2007.250
|
| source |
Expanding Bodies: Art • Cities• Environment [Proceedings of the 27th Annual Conference of the Association for Computer Aided Design in Architecture / ISBN 978-0-9780978-6-8] Halifax (Nova Scotia) 1-7 October 2007, 250-261 |
| summary |
Kinetic structures offer the means to significantly expand the functional and performance features of traditionally static architectural solutions. However, the added element of motion creates considerable challenges during conceptualization and introduction into existing design workflows. Rigidly foldable shells offer tremendous potential for developing kinetic architectural structures. They require few support points, eliminate sliding overlaps and are relatively easy to mock up as initial concepts. Achieving the desired motion range, however, requires a significant design effort. If performed manually, the motion optimization is tedious and unpredictable. This paper examines possible optimization algorithmic strategies with the use of fuzzy logic. Specifically the paper focuses on the application of fuzzy logic as a tool for effectively negotiating modifications of complex linked geometries while using intuitive, high level statements and directives. Highlighted is the potential of fuzzy logic-based algorithms as tools that can help the transition of existing design workflows into environments that can handle extended challenges involving kinetic geometries. |
| series |
ACADIA |
| email |
|
| full text |
 file.pdf (756,972 bytes) |
| references |
Content-type: text/plain
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Bonev, I.A. and J. Ryu (2000)
 A New Method for Solving the Direct Kinematics of General 6-6 Stewart Platforms Using Three Linear Extra Sensors
, Mechanism and Machine Theory 35(3): 423–436
|
|
|
|
|
Cross, N. (1994)
Engineering Design Methods: Strategies for Product Design
, New York: John Wiley & Sons
|
|
|
|
|
Dietmaier, P. (1998)
The Stewart–Gough platform of general geometry can have 40 real postures
, Advances in Robot Kinematics: Analysis and Control, eds. J. Lenarcic and M. L. Hust, 7–16. Norwell, MA: Kluwer
|
|
|
|
|
Eschenauer, H., J. Koski, and A. Osyczka, eds. (1990)
Multicriteria Design Optimization
, Berlin: Springer Verlag
|
|
|
|
|
Gough, V. E. (1956)
Automobile stability, control, and tire performance
, England: Institute of Mechanical Engineering, Automobile Division
|
|
|
|
|
Karray, O. F. and C. W. de Silva (2004)
Soft Computing and Intelligent System Design: Theory, Tools and Applications
, England: Addison-Wesley
|
|
|
|
|
Raghavan, M. (1991)
The Stewart platform of general geometry has 40 configurations
, Proceedings of the 17th Design Automation Conference presented at the 1991 ASME Design Technical Conferences, September 22-25, 199 Miami, FL. American Society of Mechanical Engineers, Design Engineering Division (Publication) DE: 32(2): 397-402. New York: ASME
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| last changed |
2022/06/07 07:57 |
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