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Loopsense: low-scale, unobtrusive, and minimally invasive knitted force sensors for multi-modal input, enabled by selective loop-meshing

Roland Aigner, Mira Alida Haberfellner, Michael Haller

202411 citationsDOIOpen Access PDF

Abstract

Integrating sensors into knitted input devices traditionally comes with considerable constraints for textile and UI design freedom. In this work, we demonstrate a novel, minimally invasive method for fabricating knitted sensors that overcomes this limitation. We integrate copper wire with piezoresistive enamel directly into the fabric using weft knitting to establish strain and pressure sensing cells that consist only of single pairs of intermeshed loops. The result is unobtrusive and potentially invisible, which provides tremendous latitude for visual and haptic design. Furthermore, we present several variations of stitch compositions, resulting in loop meshes that feature distinct response with respect to direction of exerting force. Utilizing this property, we are able to infer actuation modalities and considerably expand the device’s input space. In particular, we discern strain directions and surface pressure. Moreover, we provide an in-depth description of our fabrication method, and demonstrate our solution’s versatility on three exemplary use cases.

Topics & Concepts

ModalComputer scienceLoop (graph theory)Scale (ratio)Haptic technologySimulationPhysicsMaterials scienceCombinatoricsMathematicsPolymer chemistryQuantum mechanicsTactile and Sensory InteractionsInteractive and Immersive DisplaysAdvanced Sensor and Energy Harvesting Materials
Loopsense: low-scale, unobtrusive, and minimally invasive knitted force sensors for multi-modal input, enabled by selective loop-meshing | Litcius