Abstract
While nonlinear concepts are widely applied in analysis and generative design in architecture, they have not yet convincingly translated into the material realm of fabrication and construction. As the gap between digital design model, shop drawing, and fabricated result contnues to diminish, we seek to learn from fabrication models and natural systems that do not separate code, geometry, patern, material compliance, communication, and form, but rather operate within dynamic loops of feedback, reciprocity, and generative fabrication. Three distnct, but connected problems: 1) Robotc ink drawing; 2) Robotc wine pouring and object detection; and 3) Dynamically Adjusted Extrusion; were addressed to develop a toolkit including software, custom digital design tools, and hardware for robotc fabrication and user interaction in cyber-physical contexts. Our primary aim is to simplify and consolidate the multple platorms necessary to construct feedback networks for robotc fabrication into a central and intuitive programming environment for both the advanced to novice user. Our experimentation in prototyping feedback networks for use with robotcs in design practce suggests that the application of this knowledge often follows a remarkably consistent profile. By exploiting these redundancies, we developed a support toolkit of data structures and routnes that provide simple integrated software for the user-friendly programming of commonly used roles and functionalites in dynamic robotc fabrication, thus promoting a methodology of feedback-oriented design processes. © 2016 CURRAN-CONFERENCE. All rights reserved.
Original language | English |
---|---|
Pages | 174 – 183 |
Publication status | Published - 2016 |
Keywords
- Computer aided design
- Graphical user interfaces
- Memory architecture
- Network architecture
- Object detection
- Cyber physicals
- Digital design tools
- Digital designs
- Feedback networks
- Generative design
- Integrated software
- Intuitive programming
- User interaction
- Fabrication