Abstract
Soft continuum robots have been accepted as a promising category of biomedical robots, accredited to the robots’ inherent compliance that makes them safely interact with their surroundings. In its application of minimally invasive surgery, such a continuum concept shares the same view of robotization for conventional endoscopy/laparoscopy. Different from rigid-link robots with accurate analytical kinematics/dynamics, soft robots encounter modeling uncertainties due to intrinsic and extrinsic factors, which would deteriorate the model-based control performances. However, the trade-off between flexibility and controllability of soft manipulators may not be readily optimized but would be demanded for specific kinds of modeling approaches. To this end, data-driven modeling strategies making use of machine learning algorithms would be an encouraging way out for the control of soft continuum robots. In this article, we attempt to overview the current state of kinematic/dynamic model-free control schemes for continuum manipulators, particularly by learning-based means, and discuss their similarities and differences. Perspectives and trends in the development of new control methods are also investigated through the review of existing limitations and challenges.
Highlights
Bioinspired by snakes, elephant trunks, and octopus tentacles, continuum robots are designed to structurally mimic their inherent dexterity and adaptability (Webster and Jones, 2010)
With the reduced scale of continuum robots, the concerns are diverted to the delicate steering of the slim robot body
The flexible characteristics of continuum robots are appropriate for surgical field applications
Summary
Bioinspired by snakes, elephant trunks, and octopus tentacles, continuum robots are designed to structurally mimic their inherent dexterity and adaptability (Webster and Jones, 2010). In contrast to conventional rigid-link manipulators, “continuum” mechanisms leverage a series of continuous arcs without a skeletal structure to produce a bending motion (Robinson and Davies, 1999). Such design initially focuses on large-scale grasping, locomotion, and positioning in industrial applications (Robinson and Davies, 1999) or even urban search and rescue operations in confined environments (Jones and Walker, 2006a). The flexible characteristics of continuum robots are appropriate for surgical field applications. Enabling infinite degree-of-freedom (DoF) manipulations within small scales, continuum robots endow the target with flexible access and the patient with less invasion (Burgner-Kahrs et al, 2015). Besides the mechanism of a robot, proper controllers and corresponding sensors are necessary to guarantee accurate control performance
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