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A specimen-tracking controller for the transverse dynamic force microscope in non-contact mode.

, , , , , , , and . ACC, page 7384-7389. IEEE, (2016)

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From Natural Flyers to the Mechanical Realization of a Flapping Wing Micro Air Vehicle., , , and . ROBIO, page 439-444. IEEE Computer Society, (2006)A specimen-tracking controller for the transverse dynamic force microscope in non-contact mode., , , , , , , and . ACC, page 7384-7389. IEEE, (2016)Development of a biologically inspired multi-modal wing model for aerial-aquatic robotic vehicles., , and . IROS, page 3404-3409. IEEE, (2010)The Parallel Crank-Rocker Flapping Mechanism: an Insect-Inspired Design for Micro Air Vehicles., , and . Int. J. Humanoid Robotics, 4 (4): 625-643 (2007)Design, Simulation, Fabrication and Testing of a Bio-Inspired Amphibious Robot with Multiple Modes of Mobility., , , , , , and . J. Robotics Mechatronics, 24 (4): 629-641 (2012)Enhancing fixed-point control robustness for experimental non-contact scans with the Transverse-dynamic Force Microscope., , , , , , , and . ACC, page 4342-4347. IEEE, (2018)Flapping at resonance: Realization of an electroactive elastic thorax., , and . RoboSoft, page 327-332. IEEE, (2018)Toward a Dielectric Elastomer Resonator Driven Flapping Wing Micro Air Vehicle., , and . Front. Robotics and AI, (2019)A Multimode Transverse Dynamic Force Microscope - Design, Identification, and Control., , , , , , , and . IEEE Trans. Ind. Electron., 67 (6): 4729-4740 (2020)A bio-inspired condylar hinge joint for mobile robots., , and . IROS, page 4042-4047. IEEE, (2011)