%0 Journal Article %1 suzukierazo2017elasticspace %A Suzuki, Seiichi %A Knippers, Jan %D 2017 %J International Journal of Parallel, Emergent and Distributed Systems, Vol. 32, 11/2017 %K 2017 computational elastic evolving form-finding framework from:petraheim hybrid interactive itke knippers network peer-reviewed space structure suzuki textile topology %N 1 %R https://doi.org/10.1080/17445760.2017.1390101 %T ElasticSpace: A computational framework for interactive form-finding of textile hybrid structures through evolving topology networks %V Vol 32 %X Textile Hybrid Structures are a novel type of structural system referring to the coupling of tensile form- and bending-active components into a stiffer construct. For form finding its static equilibrium shape, several computational frameworks built upon the Dynamic Relaxation method have been developed for the interactive exploration of material and geometric properties. However, efforts are still required when addressing dynamic alterations of topology without completely resetting the simulation. The main problem to face is the dynamic alteration of topological data without losing consistency of connectivity. In this paper, we present the development of a computational framework for form-finding textile hybrid structures which enables dynamic explorations of complex topological configurations during solver’s execution. A so-called evolving network formulation used to model mutable assemblies of interconnected particles is presented as well as the numerical scheme adopted to find the equilibrium state of such structures. The implementation of the framework is further described through the development of ElasticSpace, an interactive form finding tool for textile hybrid structures built with Java.

@article{suzukierazo2017elasticspace, abstract = {Textile Hybrid Structures are a novel type of structural system referring to the coupling of tensile form- and bending-active components into a stiffer construct. For form finding its static equilibrium shape, several computational frameworks built upon the Dynamic Relaxation method have been developed for the interactive exploration of material and geometric properties. However, efforts are still required when addressing dynamic alterations of topology without completely resetting the simulation. The main problem to face is the dynamic alteration of topological data without losing consistency of connectivity. In this paper, we present the development of a computational framework for form-finding textile hybrid structures which enables dynamic explorations of complex topological configurations during solver’s execution. A so-called evolving network formulation used to model mutable assemblies of interconnected particles is presented as well as the numerical scheme adopted to find the equilibrium state of such structures. The implementation of the framework is further described through the development of ElasticSpace, an interactive form finding tool for textile hybrid structures built with Java.}, added-at = {2020-05-22T14:25:36.000+0200}, author = {Suzuki, Seiichi and Knippers, Jan}, biburl = {https://puma.ub.uni-stuttgart.de/bibtex/2a8fc79e24f7f2f5f53e5519d6929bd3e/itke}, doi = {https://doi.org/10.1080/17445760.2017.1390101}, interhash = {3bd33f5e2ade521b224d43067861b265}, intrahash = {a8fc79e24f7f2f5f53e5519d6929bd3e}, journal = {International Journal of Parallel, Emergent and Distributed Systems, Vol. 32, 11/2017}, keywords = {2017 computational elastic evolving form-finding framework from:petraheim hybrid interactive itke knippers network peer-reviewed space structure suzuki textile topology}, month = nov, number = 1, timestamp = {2021-07-09T08:51:52.000+0200}, title = {ElasticSpace: A computational framework for interactive form-finding of textile hybrid structures through evolving topology networks}, volume = {Vol 32}, year = 2017 }