Towards Haptic-Based Dual-Arm Manipulation

Turlapati, Sri Harsha; Campolo, Domenico

doi:10.3390/s23010376

Cited by 4 publications

(3 citation statements)

References 35 publications

(40 reference statements)

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“…Equation (2) shows the main manipulator homogeneous coordinate transformation matrix. Table 2 presents the DH parameters of the main manipulator; the mirror image of the main and slave manipulators is symmetrical and α and θ are opposite to each other, where D = 1 m, d 3 = 0.1500 m, d 4 = 0.4318 m, a 2 = 0.4318 m, and a 3 = 0.0203 m. The DH parameters of a rigid link depend on the link parameters of the member (i.e., a i and α i ) and the joint parameters of the adjacent links (i.e., d i and θ i ).…”

Section: Posture Descriptionmentioning

confidence: 99%

“…Path planning can be flexibly adjusted and optimized according to different task characteristics, thereby improving the motion accuracy and speed of the manipulator, which directly affects production efficiency and quality. Compared with a single manipulator, the form of a dual manipulator collaborative operation can meet the needs of complex, intelligent, and compliant modern industrial systems, and dual manipulators have more advantages in efficiency and performance [2,3] and are gradually gaining attention in the industry. Path planning for dual manipulators is an important work of collaborative operations [4].…”

Section: Introductionmentioning

confidence: 99%

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A Path Planning Method with a Bidirectional Potential Field Probabilistic Step Size RRT for a Dual Manipulator

Liu

Tao

et al. 2023

Sensors

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The search efficiency of a rapidly exploring random tree (RRT) can be improved by introducing a high-probability goal bias strategy. In the case of multiple complex obstacles, the high-probability goal bias strategy with a fixed step size will fall into a local optimum, which reduces search efficiency. Herein, a bidirectional potential field probabilistic step size rapidly exploring random tree (BPFPS-RRT) was proposed for the path planning of a dual manipulator by introducing a search strategy of a step size with a target angle and random value. The artificial potential field method was introduced, combining the search features with the bidirectional goal bias and the concept of greedy path optimization. According to simulations, taking the main manipulator as an example, compared with goal bias RRT, variable step size RRT, and goal bias bidirectional RRT, the proposed algorithm reduces the search time by 23.53%, 15.45%, and 43.78% and decreases the path length by 19.35%, 18.83%, and 21.38%, respectively. Moreover, taking the slave manipulator as another example, the proposed algorithm reduces the search time by 6.71%, 1.49%, and 46.88% and decreases the path length by 19.88%, 19.39%, and 20.83%, respectively. The proposed algorithm can be adopted to effectively achieve path planning for the dual manipulator.

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Section: Posture Descriptionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

A Path Planning Method with a Bidirectional Potential Field Probabilistic Step Size RRT for a Dual Manipulator

Liu

Tao

et al. 2023

Sensors

View full text Add to dashboard Cite

show abstract

“…The motion planning for the leader manipulator is completed first, and the motion trajectory of the follower manipulator is deduced through constraints [26][27][28]. By integrating perceptual information, such as vision [29,30] and haptic feedback [31], and intelligent algorithms, such as reinforcement learning [32], the motion planning of the manipulators can be achieved, especially in replicating the movement characteristics of human arms [33,34]. Due to the complexity of the space station's internal environment, obstacle avoidance in motion planning has emerged as a focal point of research in this field [35].…”

Section: Introductionmentioning

confidence: 99%

Omnidirectional Continuous Movement Method of Dual-Arm Robot in a Space Station

Zhang

Wang

Zhou

et al. 2023

Sensors

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The burgeoning complexity of space missions has amplified the research focus on robots that are capable of assisting astronauts in accomplishing tasks within space stations. Nevertheless, these robots grapple with substantial mobility challenges in a weightless environment. This study proposed an omnidirectional continuous movement method for a dual-arm robot, inspired by the movement patterns of astronauts within space stations. On the basis of determining the configuration of the dual-arm robot, the kinematics and dynamics model of the robot during contact and flight phases were established. Thereafter, several constraints are determined, including obstacle constraints, prohibited contact area constraints, and performance constraints. An optimization algorithm based on the artificial bee colony algorithm was proposed to optimize the trunk motion law, contact point positions between the manipulators and the inner wall, as well as the driving torques. Through the real-time control of the two manipulators, the robot is capable of achieving omnidirectional continuous movement across various inner walls with complex structures while maintaining optimal comprehensive performance. Simulation results demonstrate the correctness of this method. The method proposed in this paper provides a theoretical basis for the application of mobile robots within space stations.

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