Uncalibrated Visual Servoing for Underwater Vehicle Manipulator Systems with an Eye in Hand Configuration Camera

Li, Jiyong; Huang, Hai; Xu, Yang; Wu, Haoyu; Wan, Lei

doi:10.3390/s19245469

Cited by 17 publications

(12 citation statements)

References 34 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Many different control strategies for UVMS to track task trajectories were designed and carried out in recent years, such as adaptive backstepping control [30][31], model predictive control [32], sliding mode impedance control [33], and so on. Furthermore, vision based dexterous manipulation is also a useful form for underwater operations [34][35][36]. However, motion planning, advance control and sensing identification need higher technical support, these are hard to implement in practice.…”

Section: •3•mentioning

confidence: 99%

Dynamics Simulation of Grasping Process of Underwater Vehicle-Manipulator System

Chang

Zhang

Zheng

et al. 2020

Preprint

View full text Add to dashboard Cite

Underwater vehicle-manipulator system (UVMS) can be applied to fulfill different complex underwater tasks such as grasping, drilling, sampling, etc. It is widely used in the field of oceanographic research, marine exploration, military and commercial applications. In this paper, the dynamic simulation of UVMS is presented in the process of grasping an object. Firstly, the dynamic model of UVMS, which considers the change of the load of manipulator when the end effector of manipulator grasps the object, is developed. To compare different control conditions, the numerical simulation of grasping processes without/with vehicle attitude control are carried out. The results show that the coupling dynamics between the vehicle and the manipulator in the grasping process are clearly illustrated. The tracking position error of end effector without vehicle control is large and UVMS cannot complete the grasping task under this condition. Vehicle control can compensate the motion of vehicle due to the coupling effect caused by the motion of manipulator. This study will contribute to underwater operation mission for UVMS with floating base.

show abstract

Section: •3•mentioning

confidence: 99%

Dynamics Simulation of Grasping Process of Underwater Vehicle-Manipulator System

Chang

Zhang

Zheng

et al. 2020

Preprint

View full text Add to dashboard Cite

show abstract

“…In addition, sliding mode control of UVMS for second-order system is common and reliable, such as sliding mode impedance control [60], terminal sliding control [43,53,[61][62][63][64], dynamic sliding mode control [65], robust sliding mode control [5], multiple sliding mode methods [66], dynamic neural network [67], double-loop sliding mode control [68][69][70], adaptive sliding mode PID control [71], fuzzy sliding mode control [72][73][74][75], and so on. Furthermore, vision-based dexterous manipulation is also a useful form for underwater operations [41,[76][77][78]. However, motion planning, advance control, and sensing identification need higher technical support, and are hard to implement in practice.…”

Section: Introductionmentioning

confidence: 99%

Dynamics Simulation of Grasping Process of Underwater Vehicle-Manipulator System

Chang

Yang

Zheng

et al. 2021

JMSE

View full text Add to dashboard Cite

Underwater vehicle-manipulator system (UVMS) can be applied to fulfill different complex underwater tasks such as grasping, drilling, sampling, etc. It is widely used in the field of oceanographic research, marine exploration, military, and commercial applications. In this paper, the dynamic simulation of UVMS is presented in the process of grasping an object. First, the dynamic model of UVMS, which considers the change of the load of manipulator when the end effector of manipulator grasps the object, is developed. To compare different conditions, numerical simulation of grasping processes without/with vehicle attitude control are carried out. The simulation results show that the coupling dynamics between the vehicle and the manipulator in the grasping process are clearly illustrated. It deteriorates the positioning accuracy of the end effector of the manipulator and is harmful to underwater precision operations. The tracking position error of end effector without vehicle control is large and UVMS cannot complete the grasping task under this condition. Vehicle control can compensate the motion of the vehicle due to the coupling effect caused by the motion of the manipulator. This study will contribute to underwater operation mission for UVMS with floating base.

show abstract

Section: Introductionmentioning

confidence: 99%

“…In terms of underwater operations, visual servoing has been mainly utilised in AUVs [1,6,32,33]. Some researchers have also used this technique in ROVs for vehicle docking [3,32], vehicle navigation [34], work-class vehicle control [35], and manipulator control [33]. Nevertheless, to the knowledge of the authors, previous research has not been as devoted as this one to utilising visual servoing for precise vehicle control at low speed and a calculated distance from the bottom in a small area.…”

Section: Introductionmentioning

confidence: 99%

Stereo Vision System for Vision-Based Control of Inspection-Class ROVs

Hożyń

Żak

2021

Remote Sensing

View full text Add to dashboard Cite

The inspection-class Remotely Operated Vehicles (ROVs) are crucial in underwater inspections. Their prime function is to allow the replacing of humans during risky subaquatic operations. These vehicles gather videos from underwater scenes that are sent online to a human operator who provides control. Furthermore, these videos are used for analysis. This demands an RGB camera operating at a close distance to the observed objects. Thus, to obtain a detailed depiction, the vehicle should move with a constant speed and a measured distance from the bottom. As very few inspection-class ROVs possess navigation systems that facilitate these requirements, this study had the objective of designing a vision-based control method to compensate for this limitation. To this end, a stereo vision system and image-feature matching and tracking techniques were employed. As these tasks are challenging in the underwater environment, we carried out analyses aimed at finding fast and reliable image-processing techniques. The analyses, through a sequence of experiments designed to test effectiveness, were carried out in a swimming pool using a VideoRay Pro 4 vehicle. The results indicate that the method under consideration enables automatic control of the vehicle, given that the image features are present in stereo-pair images as well as in consecutive frames captured by the left camera.

show abstract

Uncalibrated Visual Servoing for Underwater Vehicle Manipulator Systems with an Eye in Hand Configuration Camera

Cited by 17 publications

References 34 publications

Dynamics Simulation of Grasping Process of Underwater Vehicle-Manipulator System

Dynamics Simulation of Grasping Process of Underwater Vehicle-Manipulator System

Dynamics Simulation of Grasping Process of Underwater Vehicle-Manipulator System

Stereo Vision System for Vision-Based Control of Inspection-Class ROVs

Contact Info

Product

Resources

About