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This paper presents the energy-efficient cable-actuation strategy studies of the V-Expander tensegrity subject to different shape changes based on the nonlinear tensegrity dynamics and statics. First, we introduce the topology of a two-stage V-Expander tower assembled by two elementary cells and give the equations ruling the nonlinear statics and dynamics for tensegrity structures. Then, the cable-actuation process is realized by choosing suitable sets of cables as active and passive elements among the whole set of cables. The length of the active cables decreases during actuation, while passive cables adjust their length accordingly following the motion of the structure. Five shape-change types are considered: stretching, shrinking, flexure, shear, and torsion. We analyze the nonlinear static and dynamic behaviors during the morphing process with different actuation speeds. The actuation efficiency of each particular choice of active and passive cables is also discussed. The developed approaches can also be used to design and analyze various cable-driven tensegrity structures.

Automated summary

This paper presents an energy-efficient cable-actuation strategy for the V-Expander tensegrity structure, considering different shape changes. The nonlinear statics and dynamics equations are introduced for the structure, and suitable sets of cables are chosen for the cable-actuation process. The study includes five shape-change types and analyzes the nonlinear behaviors during the morphing process with different actuation speeds. The efficiency of different cable choices is also discussed, and the developed approaches can be applied in designing and analyzing cable-driven tensegrity structures.