As robotic systems increasingly operate in unstructured, cluttered, and previously unseen environments, there is a growing need for manipulators that combine compliance, adaptability, and precise control. This work presents a real-time hybrid rigid–soft continuum manipulator system designed for robust open-world object reaching in such challenging environments. The system integrates vision-based perception and 3D scene reconstruction with shape-aware motion planning to generate safe trajectories. A learning-based controller drives the hybrid arm to arbitrary target poses, leveraging the flexibility of the soft segment while maintaining the precision of the rigid segment. The system operates without environment-specific retraining, enabling direct generalization to new scenes. Extensive real-world experiments demonstrate consistent reaching performance with errors below 2 cm across diverse cluttered setups, highlighting the potential of hybrid manipulators for adaptive and reliable operation in unstructured environments.
NazeerMS, LaschiC, FaloticoE. Soft dagger: Sample-efficient imitation learning for control of soft robots. Sensors (Basel)2023;23(19):8278.
2.
NazeerMS, LaschiC, FaloticoE. Rl-based adaptive controller for high precision reaching in a soft robot arm. IEEE Trans Robot2024;40:2498–2512.
3.
FangK, LiuF, AbbeelP, et al.MOKA: Open-world robotic manipulation through mark-based visual prompting. In: Proceedings of Robotics: Science and Systems. Delft, Netherlands; 2024.
4.
WangK, WangZ, NakagakiK, et al.“Push-That-There”: Tabletop Multi-robot Object Manipulation via Multimodal’Object-level Instruction’. In: Proceedings of the 2024 ACM Designing Interactive Systems Conference. ACM; 2024; pp. 2497–2513.
5.
HuangB, ZhangX, YuJ. Toward optimal tabletop rearrangement with multiple manipulation primitives. In: 2024 IEEE International Conference on Robotics and Automation (ICRA).IEEE; 2024; pp. 10860–10866.
6.
VeilC, FlaschelM, KuhlE. Shape-space graphs: Fast and collision-free path planning for soft robots. arXiv Preprint2025.
7.
KamtikarS, MarriS, WaltB, et al.Visual servoing for pose control of soft continuum arm in a structured environment. IEEE Robot Autom Lett2022;7(2):5504–5511.
8.
UppalapatiNK, KrishnanG. VaLeNS: Design of a novel variable length nested soft arm. IEEE Robot Autom Lett2020;5(2):1135–1142.
9.
XuF, KangX, WangH. Hybrid visual servoing control of a soft robot with compliant obstacle avoidance. IEEE/ASME Trans Mechatron2024;29(6):4446–4455.
10.
KoeK, MarriS, WaltB, et al.Learning-based position and orientation control of a hybrid rigid-soft arm manipulator. Journal of Mechanisms and Robotics2025;17(7):e071010.
11.
ZhangS, LiX, SuiD, et al.Design, modeling and implementation of a novel rigid-flexible hybrid robotic arm. In: International Conference on Intelligent Robotics and Applications. Springer; 2024; pp. 229–243.
12.
NazeerMS, AnsariYT, FaloticoE, et al.A comparison of model-free controllers for trajectory tracking in a plant-inspired soft arm. In: Conference on Biomimetic and Biohybrid Systems. Springer; 2024; pp. 208–220.
13.
HeS, SunL, XuY, et al.A modeling and data-driven control framework for rigid-soft hybrid robot with visual servoing. IEEE Robot Autom Lett2023:1–8.
14.
LiY, MiyazakiT, YamamotoY, et al.S-RRT*-based Obstacle Avoidance Autonomous Motion Planner for Continuum-rigid Manipulator. arXiv Preprint2024.
15.
HammoudA, KhoramshahiM, HuetQ, et al.Online object localization in a robotic hand by tactile sensing. In: 2025 IEEE/SICE International Symposium on System Integration (SII).IEEE; 2025; pp. 645–652.
16.
WangZ, ChenJ, ChenZ, et al.GenH2R: Learning generalizable human-to-robot handover via scalable simulation demonstration and imitation. In: Proceedings of the IEEE/CVF Conference on Computer Vision and Pattern Recognition. IEEE; 2024; pp. 16362–16372.
17.
YanS, TaoX, XuD. High-precision robotic assembly system using threedimensional vision. Int J Adv Robot Syst2021;18(3):17298814211027029.
18.
XuJ, LiuK, PeiY, et al.A noncontact control strategy for circular peg-in-hole assembly guided by the 6-DOF robot based on hybrid vision. IEEE Trans Instrum Meas2022;71:1–15.
19.
Ben AbdallahH, JovančevićI, OrteuJ-J, et al.Automatic inspection of aeronautical mechanical assemblies by matching the 3D CAD model and real 2D images. J Imaging2019;5(10):81.
20.
ZhuH, WangY, HuangD, et al.Point cloud matters: Rethinking the impact of different observation spaces on robot learning. Adv Neural Inf Process Syst2024;37:77799–77830.
21.
ChisariE, HeppertN, ArgusM, et al.Learning robotic manipulation policies from point clouds with conditional flow matching. arXiv Preprint2024.
22.
CongY, ChenR, MaB, et al.A Comprehensive Study of 3-D vision-based robot manipulation. IEEE Trans Cybern2023;53(3):1682–1698.
23.
GoyalA, MousavianA, PaxtonC, et al.Ifor: Iterative flow minimization for robotic object rearrangement. In: Proceedings of the IEEE/CVF Conference on Computer Vision and Pattern Recognition. IEEE; 2022; pp. 14787–14797.
24.
ChristenS, YangW, P’erez-D’ArpinoC, et al.Learning Human-to-Robot Handovers from Point Clouds. In: Proceedings of the IEEE/CVF Conference on Computer Vision and Pattern Recognition. IEEE; 2023; pp. 9654–9664.
LuoP, YaoS, YueY, et al.Efficient rrt*-based safety-constrained motion planning for continuum robots in dynamic environments. In: 2024 IEEE International Conference on Robotics and Automation (ICRA).IEEE; 2024; pp. 9328–9334.
27.
HuangH, WangH, FangC, et al.Grasping by spiraling: Reproducing elephant movements with rigid-soft robot synergy. Npj Robot2025;3(1):18.
28.
FaureF, DuriezC, DelingetteH, et al.Sofa: A multi-model framework for interactive physical simulation. Soft tissue biomechanical modeling for computer assisted surgery. Springer; 2012; pp. 283–321.
29.
NaughtonN, SunJ, TekinalpA, et al.Elastica: A compliant mechanics environment for soft robotic control. IEEE Robot Autom Lett2021;6(2):3389–3396.
30.
CaasenbroodBJ, PogromskyAY, NijmeijerH. Sorotoki: A Matlab toolkit for design, modeling, and control of soft robots. IEEE Access2024;12:17604–17638.
31.
GallowayKC, ChenY, TempletonE, et al.Fiber optic shape sensing for soft robotics. Soft Robot2019;6(5):671–684.
32.
XuF, WangH, ChenW, et al.Visual servoing of a cable-driven soft robot manipulator with shape feature. IEEE Robot Autom Lett2021;6(3):4281–4288.
33.
WebsterRJIII, JonesBA. Design and kinematic modeling of constant curvature continuum robots: A review. Int J Rob Res2010;29(13):1661–1683.
34.
ShiJ, Abad GuamanS, DaiJ, et al.Position and Orientation Control for Hyper-elastic Multi-segment Continuum Robots. IEEE/ASME Transactions on Mechatronics2023.
35.
RendaF, ArmaniniC, LebastardV, et al.A Geometric Variable-Strain Approach for Static Modeling of Soft Manipulators With Tendon and Fluidic Actuation. IEEE Robot Autom Lett2020;5(3):4006–4013.
36.
XuF, WangH, LiuZ, et al.Visual servoing pushing control of the soft robot with active pushing force regulation. Soft Robot2022;9(4):690–704.
37.
LeroyV, CabonY, RevaudJ. Grounding image matching in 3d with mast3r. In: European Conference on Computer Vision. Springer; 2024; pp. 71–91.
38.
ChengT, SongL, GeY, et al.Yolo-world: Real-time openvocabulary object detection. In: Proceedings of the IEEE/CVF Conference on Computer Vision and Pattern Recognition; 2024; pp. 16901–16911.
39.
HannanMW, WalkerID. Kinematics and the implementation of an elephant’s trunk manipulator and other continuum style robots. J Robot Syst2003;20(2):45–63.
40.
RaoP, PeyronQ, LilgeS, et al.How to model tendon-driven continuum robots and benchmark modelling performance. Front Robot AI2020;7:630245.
41.
WangX, LiY, KwokKW. A survey for machine learning-based control of continuum robots. Front Robot AI2021;8:730330.
42.
KaramanS, FrazzoliE. Sampling-based algorithms for optimal motion planning. Int J Rob Res2011;30(7):846–894.
43.
PetitL, DesbiensAL. RRT-Rope: A deterministic shortening approach for fast near-optimal path planning in large-scale uncluttered 3D environments. In: 2021 IEEE International Conference on Systems, Man, and Cybernetics (SMC).IEEE; 2021; pp. 1111–1118.
44.
ZhengT, McFarlandC, CoadM, et al.Estimating Infinite-Dimensional Continuum Robot States From the Tip. In: 2024 IEEE 7th International Conference on Soft Robotics (RoboSoft).IEEE; 2024; pp. 572–578.
45.
GruebeleAM, ZerbeAC, CoadMM, et al.Distributed sensor networks deployed using soft growing robots. In: 2021 IEEE 4th International Conference on Soft Robotics (RoboSoft). IEEE; 2021; pp. 66–73.
46.
GanY, LiP, JiangH, et al.A reinforcement learning method for motion control with constraints on an HPN arm. IEEE Robot Autom Lett2022;7(4):12006–12013.
Supplementary Material
Please find the following supplemental material available below.
For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.
For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.
