A Solution of the Inverse Kinematics Problem for a 7-Degrees-of-Freedom Serial Redundant Manipulator Using Gröbner Bases Theory

This article presents a solution of the inverse kinematics problem of 7-degrees-of-freedom serial redundant manipulators. A 7-degrees-of-freedom (7-DoF) redundant manipulator can avoid obstacles and thus improve operational performance. However, its inverse kinematics is difficult to solve since it has one more DoF than that necessary for reaching the whole workspace, which causes infinite solutions. In this article, Gröbner bases theory is proposed to solve the inverse kinematics. First, the Denavit–Hartenberg model for the manipulator is established. Second, different joint configurations are obtained using Gröbner bases theory. All solutions are confirmed with the aid of algebraic computing software, confirming that this method is accurate and easy to be implemented.

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Analysis of computational efficiency for the solution of inverse kinematics problem of anthropomorphic robots using Gröbner bases theory

International Journal of Advanced Robotic Systems ◽

10.1177/1729881421989542 ◽

2021 ◽

Vol 18 (1) ◽

pp. 172988142198954

Author(s):

Sérgio Ricardo Xavier da Silva ◽

Leizer Schnitman ◽

Vitalino Cesca Filho

Keyword(s):

Computational Efficiency ◽

Inverse Kinematics ◽

Gröbner Bases ◽

Grobner Bases ◽

Computationally Efficient ◽

The Matrix ◽

Inverse Kinematics Problem

This article presents an analysis of computational efficiency to solve the inverse kinematics problem of anthropomorphic robots. Two approaches are investigated: the first approach uses Paul’s method applied to the matrix obtained by the Denavit–Hartenberg algorithm and the second approach uses Gröbner bases theory. With each approach, the problem of inverse kinematics for an anthropomorphic robot will be solved. When comparing each method, this article will demonstrate that the method using Gröbner bases theory is more computationally efficient.

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Voice Recognition and Inverse Kinematics Control for a Redundant Manipulator Based on a Multilayer Artificial Intelligence Network

Journal of Robotics ◽

10.1155/2021/5805232 ◽

2021 ◽

Vol 2021 ◽

pp. 1-10

Author(s):

Mai Ngoc Anh ◽

Duong Xuan Bien

Keyword(s):

Artificial Intelligence ◽

Deep Learning ◽

Inverse Kinematics ◽

Degrees Of Freedom ◽

Voice Recognition ◽

Learning Model ◽

Redundant Manipulator ◽

Efficient Operation ◽

Inverse Kinematics Problem ◽

Deep Learning Model

This study presents the construction of a Vietnamese voice recognition module and inverse kinematics control of a redundant manipulator by using artificial intelligence algorithms. The first deep learning model is built to recognize and convert voice information into input signals of the inverse kinematics problem of a 6-degrees-of-freedom robotic manipulator. The inverse kinematics problem is solved based on the construction and training. The second deep learning model is built using the data determined from the mathematical model of the system’s geometrical structure, the limits of joint variables, and the workspace. The deep learning models are built in the PYTHON language. The efficient operation of the built deep learning networks demonstrates the reliability of the artificial intelligence algorithms and the applicability of the Vietnamese voice recognition module for various tasks.

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Computing Robust Inverse Kinematics Under Uncertainty

Volume 5A: 43rd Mechanisms and Robotics Conference ◽

10.1115/detc2019-97945 ◽

2019 ◽

Author(s):

Anirban Sinha ◽

Nilanjan Chakraborty

Keyword(s):

Inverse Kinematics ◽

Joint Space ◽

Redundant Manipulators ◽

Task Space ◽

Success Rates ◽

Redundant Manipulator ◽

Space Error ◽

Inverse Kinematics Problem ◽

Robotic Tasks ◽

Present Simulation

Abstract Robotic tasks, like reaching a pre-grasp configuration, are specified in the end effector space or task space, whereas, robot motion is controlled in joint space. Because of inherent actuation errors in joint space, robots cannot achieve desired configurations in task space exactly. Furthermore, different inverse kinematics (IK) solutions map joint space error set to task space differently. Thus for a given task with a prescribed error tolerance, all IK solutions will not be guaranteed to successfully execute the task. Any IK solution that is guaranteed to execute a task (possibly with high probability) irrespective of the realization of the joint space error is called a robust IK solution. In this paper we formulate and solve the robust inverse kinematics problem for redundant manipulators with actuation uncertainties (errors). We also present simulation and experimental results on a 7-DoF redundant manipulator for two applications, namely, a pre-grasp positioning and a pre-insertion positioning scenario. Our results show that the robust IK solutions result in higher success rates and also allows the robot to self-evaluate how successful it might be in any application scenario.

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A Closed-Loop Framework for the Inverse Kinematics of the 7 Degrees of Freedom Manipulator

Robotica ◽

10.1017/s0263574720000582 ◽

2020 ◽

pp. 1-10

Author(s):

Guoli Song ◽

Shun Su ◽

Yingli Li ◽

Xingang Zhao ◽

Huibin Du ◽

...

Keyword(s):

Inverse Kinematics ◽

Degrees Of Freedom ◽

Closed Loop ◽

Numerical Sequence ◽

Operational Flexibility ◽

Redundant Manipulator ◽

Number Of Solutions ◽

Inverse Kinematics Problem ◽

Simulation And Experiment ◽

Efficiency And Reliability

SUMMARY The 7 degrees of freedom (DOF) redundant manipulator greatly improves obstacle/singularity avoidance capability and operational flexibility. However, the inverse kinematics problem of this manipulator is very difficult to solve because it has an infinite number of solutions. This paper uses a new numerical sequence processing method with a closed-loop framework to solve the inverse kinematics of the 7-DOF redundant manipulator. Simulation and experiment show that this method has high commonality. No special structure of the robot is required, and this method has improved computational efficiency and reliability.

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Finite-Horizon Kinetic Energy Optimization of a Redundant Space Manipulator

Applied Sciences ◽

10.3390/app11052346 ◽

2021 ◽

Vol 11 (5) ◽

pp. 2346

Author(s):

Alessandro Tringali ◽

Silvio Cocuzza

Keyword(s):

Kinetic Energy ◽

Real Time ◽

Inverse Kinematics ◽

Degrees Of Freedom ◽

Computational Time ◽

Redundant Manipulators ◽

Space Robotics ◽

Optimal Method ◽

End Effector ◽

Global Optimal

The minimization of energy consumption is of the utmost importance in space robotics. For redundant manipulators tracking a desired end-effector trajectory, most of the proposed solutions are based on locally optimal inverse kinematics methods. On the one hand, these methods are suitable for real-time implementation; nevertheless, on the other hand, they often provide solutions quite far from the globally optimal one and, moreover, are prone to singularities. In this paper, a novel inverse kinematics method for redundant manipulators is presented, which overcomes the above mentioned issues and is suitable for real-time implementation. The proposed method is based on the optimization of the kinetic energy integral on a limited subset of future end-effector path points, making the manipulator joints to move in the direction of minimum kinetic energy. The proposed method is tested by simulation of a three degrees of freedom (DOF) planar manipulator in a number of test cases, and its performance is compared to the classical pseudoinverse solution and to a global optimal method. The proposed method outperforms the pseudoinverse-based one and proves to be able to avoid singularities. Furthermore, it provides a solution very close to the global optimal one with a much lower computational time, which is compatible for real-time implementation.

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Dual arm-angle parameterisation and its applications for analytical inverse kinematics of redundant manipulators

Robotica ◽

10.1017/s0263574715000284 ◽

2015 ◽

Vol 34 (12) ◽

pp. 2669-2688 ◽

Cited By ~ 7

Author(s):

Wenfu Xu ◽

Lei Yan ◽

Zonggao Mu ◽

Zhiying Wang

Keyword(s):

Inverse Kinematics ◽

Reference Plane ◽

Redundant Manipulators ◽

Redundant Manipulator ◽

Singularity Problem ◽

Human Arm ◽

Angle Method ◽

Self Motion ◽

Dual Arm ◽

Configuration Control

SUMMARYAn S-R-S (Spherical-Revolute-Spherical) redundant manipulator is similar to a human arm and is often used to perform dexterous tasks. To solve the inverse kinematics analytically, the arm-angle was usually used to parameterise the self-motion. However, the previous studies have had shortcomings; some methods cannot avoid algorithm singularity and some are unsuitable for configuration control because they use a temporary reference plane. In this paper, we propose a method of analytical inverse kinematics resolution based on dual arm-angle parameterisation. By making use of two orthogonal vectors to define two absolute reference planes, we obtain two arm angles that satisfy a specific condition. The algorithm singularity problem is avoided because there is always at least one arm angle to represent the redundancy. The dual arm angle method overcomes the shortcomings of traditional methods and retains the advantages of the arm angle. Another contribution of this paper is the derivation of the absolute reference attitude matrix, which is the key to the resolution of analytical inverse kinematics but has not been previously addressed. The simulation results for typical cases that include the algorithm singularity condition verified our method.

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Kinematics of a Fully-Decoupled Remote Center-of-Motion Parallel Manipulator for Minimally Invasive Surgery

Journal of Medical Devices ◽

10.1115/1.4006541 ◽

2012 ◽

Vol 6 (2) ◽

Cited By ~ 45

Author(s):

Chin-Hsing Kuo ◽

Jian S. Dai

Keyword(s):

Minimally Invasive Surgery ◽

Minimally Invasive ◽

Invasive Surgery ◽

Inverse Kinematics ◽

Parallel Manipulator ◽

Degrees Of Freedom ◽

Surgical Instruments ◽

End Effector ◽

Minimally Invasive Surgical ◽

Inverse Kinematics Problem

A crucial design challenge in minimally invasive surgical (MIS) robots is the provision of a fully decoupled four degrees-of-freedom (4-DOF) remote center-of-motion (RCM) for surgical instruments. In this paper, we present a new parallel manipulator that can generate a 4-DOF RCM over its end-effector and these four DOFs are fully decoupled, i.e., each of them can be independently controlled by one corresponding actuated joint. First, we revisit the remote center-of-motion for MIS robots and introduce a projective displacement representation for coping with this special kinematics. Next, we present the proposed new parallel manipulator structure and study its geometry and motion decouplebility. Accordingly, we solve the inverse kinematics problem by taking the advantage of motion decouplebility. Then, via the screw system approach, we carry out the Jacobian analysis for the manipulator, by which the singular configurations are identified. Finally, we analyze the reachable and collision-free workspaces of the proposed manipulator and conclude the feasibility of this manipulator for the application in minimally invasive surgery.

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Dynamics of redundant robots – inverse solutions

Robotica ◽

10.1017/s0263574700009954 ◽

1986 ◽

Vol 4 (4) ◽

pp. 263-267 ◽

Cited By ~ 6

Author(s):

Ronald L. Huston ◽

Timothy P. King

Keyword(s):

Inverse Kinematics ◽

Degrees Of Freedom ◽

Solution Algorithm ◽

Redundant Robot ◽

Redundant Robots ◽

Revolute Joints ◽

Inverse Kinematics Problem ◽

Inverse Solutions ◽

Natural Dynamics ◽

Least Energy

SUMMARYThe dynamics of “simple, redundant robots” are developed. A “redundant” robot is a robot whose degrees of freedom are greater than those needed to perform a given kinetmatic task. A “simple” robot is a robot with all joints being revolute joints with axes perpendicular or parallel to the arm segments. A general formulation, and a solution algorithm, for the “inverse kinematics problem” for such systems, is presented. The solution is obtained using orthogonal complement arrays which in turn are obtained from a “zero-eigenvalues” algorithm. The paper concludes with an assertion that this solution, called the “natural dynamics solution,” is optimal in that it requires the least energy to drive the robot.

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Inverse Kinematic Solution of Robot Manipulators Using Interval Analysis

Journal of Mechanical Design ◽

10.1115/1.2826667 ◽

1998 ◽

Vol 120 (1) ◽

pp. 147-150 ◽

Cited By ~ 28

Author(s):

R. S. Rao ◽

A. Asaithambi ◽

S. K. Agrawal

Keyword(s):

Computational Complexity ◽

Numerical Algorithm ◽

Interval Analysis ◽

Inverse Kinematics ◽

Inverse Kinematic ◽

Real Numbers ◽

Computational Mathematics ◽

All Solutions ◽

Inverse Kinematics Problem ◽

Kinematic Solution

Interval analysis is a growing branch of computational mathematics where operations are carried out on intervals instead of real numbers. This paper presents the first application of this method to robotic mechanisms for the solution of inverse kinematics. As shown in this paper, it is possible to potentially compute all solutions of the inverse kinematics problem using this method. This paper describes the preliminaries of interval analysis, the numerical algorithm, the computational complexity, and illustrations with examples.

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Hybrid Mutation Fruit Fly Optimization Algorithm for Solving the Inverse Kinematics of a Redundant Robot Manipulator

Mathematical Problems in Engineering ◽

10.1155/2020/6315675 ◽

2020 ◽

Vol 2020 ◽

pp. 1-13

Author(s):

Jianping Shi ◽

Yuting Mao ◽

Peishen Li ◽

Guoping Liu ◽

Peng Liu ◽

...

Keyword(s):

Optimization Algorithm ◽

Inverse Kinematics ◽

Robot Manipulator ◽

Fruit Fly ◽

Fruit Fly Optimization Algorithm ◽

Redundant Manipulators ◽

End Effector ◽

Redundant Robot ◽

Fruit Fly Optimization ◽

Inverse Kinematics Problem

The inverse kinematics of redundant manipulators is one of the most important and complicated problems in robotics. Simultaneously, it is also the basis for motion control, trajectory planning, and dynamics analysis of redundant manipulators. Taking the minimum pose error of the end-effector as the optimization objective, a fitness function was constructed. Thus, the inverse kinematics problem of the redundant manipulator can be transformed into an equivalent optimization problem, and it can be solved using a swarm intelligence optimization algorithm. Therefore, an improved fruit fly optimization algorithm, namely, the hybrid mutation fruit fly optimization algorithm (HMFOA), was presented in this work for solving the inverse kinematics of a redundant robot manipulator. An olfactory search based on multiple mutation strategies and a visual search based on the dynamic real-time updates were adopted in HMFOA. The former has a good balance between exploration and exploitation, which can effectively solve the premature convergence problem of the fruit fly optimization algorithm (FOA). The latter makes full use of the successful search experience of each fruit fly and can improve the convergence speed of the algorithm. The feasibility and effectiveness of HMFOA were verified by using 8 benchmark functions. Finally, the HMFOA was tested on a 7-degree-of-freedom (7-DOF) manipulator. Then the results were compared with other algorithms such as FOA, LGMS-FOA, AE-LGMS-FOA, IFOA, and SFOA. The pose error of end-effector corresponding to the optimal inverse solution of HMFOA is 10−14 mm, while the pose errors obtained by FOA, LGMS-FOA, AE-LGMS-FOA, IFOA, and SFOA are 102 mm, 10−1 mm, 10−2 mm, 102 mm, and 102 mm, respectively. The experimental results show that HMFOA can be used to solve the inverse kinematics problem of redundant manipulators effectively.

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