Kim, J. Kwon, S. Moon, Y. Kim, K. 2024-01-19T13:00:45Z 2024-01-19T13:00:45Z 2022-01-10 2022-02 1083-4435 https://pubs.kist.re.kr/handle/201004/115793 Hyper-redundant manipulators (HRMs) are widely used in minimally invasive surgery (MIS) because of their flexibility, dexterity, and compactness. However, when an external load acts on an HRM, its bending motion is disturbed and the workspace decreases. In addition, the external load increases the cable tension, and thin cables may break due to their low breaking strengths. This paper proposes a cable-movable rolling joint that increases the workspace for MIS under an external load and reduces the actuating cable tension through cable movement. Further, it presents an optimized motion estimation analysis method that verifies the manipulator performance by finding the equilibrium position and predicting the shape and tip position. The simulated manipulator exhibited a shape similar to that of the prototype and an average tip position difference of 4.59% based on the prototype length. Under an external load of 150 g, the workspace and cable tension of the prototype were 27.32% larger and 1.79 N lower than those of the conventional rolling joint, respectively. The new cable-movable mechanism and estimation analysis method will help improve the bending performance and position accuracy of HRMs for MIS. IEEE English Institute of Electrical and Electronics Engineers Inc. Industrial manipulators Motion estimation Redundant manipulators Analysis method Bending performance Breaking strength Conventional rolling Equilibrium positions Hyper-redundant manipulator Minimally invasive surgery Position accuracy Cables Cable-movable rolling joint to expand workspace under high external load in a hyper-redundant manipulator Article 10.1109/TMECH.2021.3067335 1 IEEE/ASME Transactions on Mechatronics, v.27, no.1, pp.501 - 512 IEEE/ASME Transactions on Mechatronics 27 1 501 512 scie scopus 000756855400048 2-s2.0-85103232309 Automation & Control Systems Engineering, Manufacturing Engineering, Electrical & Electronic Engineering, Mechanical Automation & Control Systems Engineering Article Industrial manipulators Motion estimation Redundant manipulators Analysis method Bending performance Breaking strength Conventional rolling Equilibrium positions Hyper-redundant manipulator Minimally invasive surgery Position accuracy Cables Bending Force Hyper-redundant manipulator Load modeling Manipulators minimally invasive surgery motion estimation analysis Motion segmentation Robots Shape surgical robot under-actuated robot