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Quantifying Dynamic Shapes in Soft Morphologies

Research output: Contribution to journalArticle

Original languageEnglish
JournalSoft Robotics
DateAccepted/In press - 10 Jun 2019


Soft materials are driving the development of a new generation of robots that are intelligent, versatile and adept at overcoming uncertainties in their everyday operation. The resulting soft robots are compliant and deform readily to change shape. In contrast to rigid-bodied robots, the shape of soft robots cannot be described easily. A numerical description is needed to enable the understanding of key features of shape and how they change as the soft body deforms. It can also quantify similarity between shapes. In this paper, we use a method based on elliptic Fourier descriptors to describe soft, deformable morphologies. We perform eigenshape analysis on the descriptors to extract key features that change during the motion of soft robots, showing the first analysis of this type on dynamic systems. We apply the method to both biological and soft robotic systems, which include the movement of a passive tentacle, the crawling movement of two species of caterpillar (Manduca sexta and Sphacelodes sp.), the motion of body segments in the Manduca sexta and a comparison of the motion of a soft robot with that of a micro-organism (euglenoid, Eutreptiella sp.). In the case of the tentacle, we show that the method captures differences in movement in varied media. In the caterpillars, the method illuminates a prominent feature of crawling, the extension of the terminal proleg. In the comparison between the robot and euglenoids, our method quantifies the similarity in shape to approx. 85%. Further, we present a possible method of extending the analysis to three dimensional shapes.



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