Saved in:
Bibliographic Details
Main Authors: Saito, Ryouichi, Koide, Takahiro, Tanaka, Yuya, Nakashima, Yasutaka, Yamamoto, Motoji, Kanada, Ayato
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2604.01490
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866918425265176576
author Saito, Ryouichi
Koide, Takahiro
Tanaka, Yuya
Nakashima, Yasutaka
Yamamoto, Motoji
Kanada, Ayato
author_facet Saito, Ryouichi
Koide, Takahiro
Tanaka, Yuya
Nakashima, Yasutaka
Yamamoto, Motoji
Kanada, Ayato
contents Continuum robots are well suited for constrained environments but suffer from low distal stiffness, resulting in large posture errors under external loads. In this paper, we propose a novel structural primitive, the Distal-Stable Beam, which achieves a strong stiffness gradient through purely geometric design, maintaining compliance in the intermediate section while ensuring high distal rigidity. The structure consists of two parallel rods and one convergent rod constrained by guide disks, introducing geometric coupling that suppresses deformation modes and preserves distal posture. Experiments show that the distal stiffness is 12 times higher than at the center, corresponding to an approximately 100-fold improvement over a conventional cantilever beam. The proposed mechanism enables simultaneous compliance and distal stability without active stiffness modulation, providing a new design approach for continuum robots requiring both safety and precision.
format Preprint
id arxiv_https___arxiv_org_abs_2604_01490
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Distal-Stable Beam for Continuum Robots
Saito, Ryouichi
Koide, Takahiro
Tanaka, Yuya
Nakashima, Yasutaka
Yamamoto, Motoji
Kanada, Ayato
Robotics
Continuum robots are well suited for constrained environments but suffer from low distal stiffness, resulting in large posture errors under external loads. In this paper, we propose a novel structural primitive, the Distal-Stable Beam, which achieves a strong stiffness gradient through purely geometric design, maintaining compliance in the intermediate section while ensuring high distal rigidity. The structure consists of two parallel rods and one convergent rod constrained by guide disks, introducing geometric coupling that suppresses deformation modes and preserves distal posture. Experiments show that the distal stiffness is 12 times higher than at the center, corresponding to an approximately 100-fold improvement over a conventional cantilever beam. The proposed mechanism enables simultaneous compliance and distal stability without active stiffness modulation, providing a new design approach for continuum robots requiring both safety and precision.
title Distal-Stable Beam for Continuum Robots
topic Robotics
url https://arxiv.org/abs/2604.01490