Weaving and engineering might seem unrelated on the surface, but they in fact have a great deal in common. Laura Devendorf, assistant professor at the ATLAS Institute and Information Science, is determined to build bridges among practitioners across these disciplines to unlock the potential for new lines of scientific and creative innovation.
To support this work, Devendorf, who directs the Unstable Design Lab, was recently awarded a of $297,630 for phase one of a larger project entitled, “Cultivating an Ecosystem for Interdisciplinary Smart Textiles Research.”
The research builds on software Devendorf and her team developed called, , an open-source tool they describe as an “experimental workspace that applies parametric design to the domain of weave drafting. It supports algorithmic and playful approaches to developing woven structures and cloth, for shaft and jacquard looms.”
The aim of this new research, as Devendorf describes it, is to, “take this software that we built for doing complex weave drafting and transition it to a project where it is sustained and grown by a larger community of weavers and [those] who we call ‘textile-adjacent engineers’.” That way, AdaCAD can develop and adapt to the needs of a wider user-base over time as all good open source software does.
This work exemplifies the radically interdisciplinary work that the ATLAS Institute champions. By bringing together disparate experts and communities—in this case, artists, artisans, engineers and researchers—we create new approaches to discovery.
From adjacent to integrated
Textiles are pervasive, yet often misunderstood in engineering spaces. The surprising mathematical complexity, materials knowledge and innovation that have arisen over centuries of textile practice are often overlooked. At the same time, weavers who come from a tradition of craftsmanship, art and design may be unfamiliar with meaningful advances in the engineering space.
By bringing together these two worlds, Devendorf hopes to open up opportunities for breakthroughs in technology and craft, whether that is in advancing electronic-textile science or pushing the boundaries of artistic expression.
For example, an engineering team may seek ways to monitor health without the use of adhesives often required for electrodes, while weavers already have options for materials and techniques that could replace such adhesives. Yet both groups are often unaware of each other’s needs and skills. But overcoming this knowledge gap, Devendorf believes engineers and weavers could together achieve greater impact.
There are signs this is beginning to take place, and she aims to speed the process. Research labs at CalTech and MIT as well as industrial design studios around the globe have acquired digital looms to experiment with weaving advanced materials and experimental forms.
But first: listening
Phase I of this project will focus on fact-finding and planning. The team will lead community-engagement activities and trainings and gather points-of-view from craftspeople, designers, engineers and others across many communities.
Devendorf and her team have begun interviewing people from a range of overlapping disciplines. They include a weaver with a fine arts background who now works on woven implantables for a medical devices company and a textiles expert researching stronger, lighter woven materials for the aviation industry. Still others in the cohort are studying zero-waste, “whole garment” clothing manufacturing and human-computer interaction surfaces on the body. The range of applications for textiles is growing at an impressive pace.
Devendorf explains this recent uptick in interest: “Ten years ago, it was all about the maker movement and digital fabrication, and it took a while before people realized that textile machines are also fabrication machines that can do things that we're still trying to get 3D printers to do. Textiles are inherently multi-material. They are flexible, they can be made stiff, they can be soft. It's a totally different mindset to control a textile machine [compared] to a printer that is making stacks. There’s a big learning gap there, but you see a lot of fabrication people jumping in.”
The has also expanded access to advanced weaving techniques as a first-of-its-kind prototype-scale digital jacquard loom that is programmable with a bitmap image. Now you no longer need a factory-scale setup to experiment with textiles fabrication.
What’s next
For Phase II, the team will focus on cultivating the ecosystem through on-the-ground work with communities and creating opportunities for practitioners to share what they are making. Devendorf also aims to expand opportunities for craftspeople in scientific research and product design spaces.
She explains, “we have huge problems to tackle as a society. I believe that engineering can address some of those, but I don't think we can do it if we don't have access to every possible technique… We're overlooking a huge set of practices and people in communities that have knowledge we need to solve some of these bigger challenges. My hunch is that craftspeople understand materials, process and machinery where so much of engineering is happening at a simulation level [while] trying to engineer materials that behave like the simulations.”
By fostering interconnectivity between engineering and weaving communities, Devendorf and her team in the will position textiles as a leading source for innovative solutions to global challenges.