-
- 16 NovHenriette Bier acts as member of the scientific committee of Oxford Journal Interacting with Computers
- 16 NovA. Liu Cheng and H. Bier publish paper on Adaptive Building-Skin Components as Context-Aware Nodes in an Extended Cyber-Physical Network for IEEE World Forum on Internet of Things 2016
- 04 NovTiantian Du and Nimish Biloria hosted the workshop "Transitional Space Design and the Concept of Architectural Thermodynamics"
- 04 NovHenriette Bier appointed as member of the scientific committee of IJAC journal
- 18 OctDr. Nimish Biloria appointed as Scientific Committee member for the CAAD Futures 2017 Conference: Future Trajectories of Computation in Design
- 23 SepHenriette Bier appointed as member of the scientific committee of CAAD Futures 2017: Future Trajectories of Computation in Design
- 23 SepHenriette Bier certified reviewer of Elsevier's Journal of Materials and Design
- 23 SepProf. Kas Oosterhuis speaker at MakeHappen! Inspiration Day 2016
- 16 SepHyperbody graduate students Ralph Cloot and Arwin Hidding in collaboration with Sina Mostafavi and supervised by Kas Oosterhuis design a building for Neurotopia
- 15 SepDr. Nimish Biloria has been appointed as Associate Partner for the LASG (Living Architecture Systems Group), University of Waterloo, Canada
-
-
A.Liu Cheng, H. Bier, G. Latorre, B. Kemper and D. Fischer publish a paper on A High-Resolution Intelligence Implementation based on Design-to-Robotic-Production and -Operation strategies in the 34th International Symposium on Automation and Robotics in Construction (ISARC 2017) (June 28 - July 1, 2017).
ABSTRACT: This paper presents an initial proof-of-concept implementation of a comprehensively intelligent built-environment based on mutually informing Design-to-Robotic-Production and -Operation (D2RP&O) strategies and methods developed at Delft University of Technology (TUD). In this implementation, D2RP is expressed via deliberately differentiated and function-specialized components, while D2RO expressions subsume an extended Ambient Intelligence (AmI) enabled by a Cyber-Physical System (CPS). This CPS, in turn, is built on a heterogeneous, scalable, self-healing, and partially meshed Wireless Sensor and Actuator Network (WSAN) whose nodes may be clustered dynamically ad hoc to respond to varying computational needs. Two principal and innovative functionalities are demonstrated in this implementation: (1) cost-effective yet robust Human Activity Recognition (HAR) via Support Vector Machine (SVM) and k-Nearest Neighbor (k-NN) classification models, and (2) appropriate corresponding reactions that promote the occupant’s spatial experience and well-being via continuous regulation of illumination with respect to colors and intensities to correspond to engaged activities. The present implementation attempts to provide a fundamentally different approach to intelligent built-environments, and to promote a highly sophisticated alternative to existing intelligent solutions whose disconnection between architectural considerations and computational services limits their operational scope and impact.