DefSense: Computational Design of Customized Deformable Input Devices
We present a novel optimization-based algorithm for the design and fabrication of customized, deformable input devices, capable of continuously sensing their deformation.
May 7, 2016
CHI Interactivity 2016
Authors
Moritz Baecher (Disney Research)
Benjamin Hepp (ETH Zurich)
Fabrizio Pece (ETH Zurich)
Paul Kry (McGill University)
Bernd Bickel (IST (Institute of Science and Technology Austria))
Bernhard Thomaszewski (Disney Research)
Otmar Hilliges (ETH Zurich)
DefSense: Computational Design of Customized Deformable Input Devices
We propose to embed piezoresistive sensing elements into flexible 3D printed objects. These sensing elements are then utilized to recover rich and natural user interactions at runtime. Designing such objects manually is a challenging and hard problem for all but the simplest geometries and deformations. Our method simultaneously optimizes the internal routing of the sensing elements and computes a mapping from low-level sensor readings to user-specified outputs in order to minimize reconstruction error. We demonstrate the power and flexibility of the approach by designing and fabricating a set of flexible input devices. Our results indicate that the optimization based design greatly outperforms manual routings in terms of reconstruction accuracy and thus interaction fidelity.