Real-Time Dynamics of Manipulation Robots

“…Currently it is believed that the use of diverse dynamic principles will lead to similar formulations of equivalent computational complexity. This has been partially proved by applying the appropriate relationships to the L-E equations in order to obtain an equivalent formulation to that given by the N-E equations, although a greater effort is required in order to reach the final equations [14]. It is for this reason that most of the formulations that produce efficient algorithms have been developed from the N-E equations.…”

“…Surprisingly, a bibliographical review of the literature on this area reveals a limited use of the G-A equations in modern dynamics. A few years ago, the supposed relationship of the G-A equations and Kane's dynamic equations caused a great number of works and comments on the matter [14]. In the field of robotics, Popov proposed a method, later developed by Vukobratovic [14], in which the G-A equations were used to develop a closed form representation of high computational complexity.…”

“…A few years ago, the supposed relationship of the G-A equations and Kane's dynamic equations caused a great number of works and comments on the matter [14]. In the field of robotics, Popov proposed a method, later developed by Vukobratovic [14], in which the G-A equations were used to develop a closed form representation of high computational complexity. This method was used by Desoyer and Lugner [11], [14] to solve, by means of the recursive formulation O(n 2 ) (n is the number of the degree-of-freedom), an inverse dynamic problem, using the Jacobian matrix of the manipulator, with the view of avoiding the explicit development of partial derivatives.…”

“…In the field of robotics, Popov proposed a method, later developed by Vukobratovic [14], in which the G-A equations were used to develop a closed form representation of high computational complexity. This method was used by Desoyer and Lugner [11], [14] to solve, by means of the recursive formulation O(n 2 ) (n is the number of the degree-of-freedom), an inverse dynamic problem, using the Jacobian matrix of the manipulator, with the view of avoiding the explicit development of partial derivatives. Another approach was suggested by Vereshchagin [14] who proposed manipulator motion equations from Gauss' principle and Gibbs' function.…”

“…This method was used by Desoyer and Lugner [11], [14] to solve, by means of the recursive formulation O(n 2 ) (n is the number of the degree-of-freedom), an inverse dynamic problem, using the Jacobian matrix of the manipulator, with the view of avoiding the explicit development of partial derivatives. Another approach was suggested by Vereshchagin [14] who proposed manipulator motion equations from Gauss' principle and Gibbs' function. This approach was used by Rudas and Toth [11] to solve the inverse dynamic problem of robots.…”

Computer Algebra for Real-Time Dynamics of Robots with Large Numbers of Joints

“…Currently it is believed that the use of diverse dynamic principles will lead to similar formulations of equivalent computational complexity. This has been partially proved by applying the appropriate relationships to the L-E equations in order to obtain an equivalent formulation to that given by the N-E equations, although a greater effort is required in order to reach the final equations [14]. It is for this reason that most of the formulations that produce efficient algorithms have been developed from the N-E equations.…”

“…Surprisingly, a bibliographical review of the literature on this area reveals a limited use of the G-A equations in modern dynamics. A few years ago, the supposed relationship of the G-A equations and Kane's dynamic equations caused a great number of works and comments on the matter [14]. In the field of robotics, Popov proposed a method, later developed by Vukobratovic [14], in which the G-A equations were used to develop a closed form representation of high computational complexity.…”

“…A few years ago, the supposed relationship of the G-A equations and Kane's dynamic equations caused a great number of works and comments on the matter [14]. In the field of robotics, Popov proposed a method, later developed by Vukobratovic [14], in which the G-A equations were used to develop a closed form representation of high computational complexity. This method was used by Desoyer and Lugner [11], [14] to solve, by means of the recursive formulation O(n 2 ) (n is the number of the degree-of-freedom), an inverse dynamic problem, using the Jacobian matrix of the manipulator, with the view of avoiding the explicit development of partial derivatives.…”

“…In the field of robotics, Popov proposed a method, later developed by Vukobratovic [14], in which the G-A equations were used to develop a closed form representation of high computational complexity. This method was used by Desoyer and Lugner [11], [14] to solve, by means of the recursive formulation O(n 2 ) (n is the number of the degree-of-freedom), an inverse dynamic problem, using the Jacobian matrix of the manipulator, with the view of avoiding the explicit development of partial derivatives. Another approach was suggested by Vereshchagin [14] who proposed manipulator motion equations from Gauss' principle and Gibbs' function.…”

“…This method was used by Desoyer and Lugner [11], [14] to solve, by means of the recursive formulation O(n 2 ) (n is the number of the degree-of-freedom), an inverse dynamic problem, using the Jacobian matrix of the manipulator, with the view of avoiding the explicit development of partial derivatives. Another approach was suggested by Vereshchagin [14] who proposed manipulator motion equations from Gauss' principle and Gibbs' function. This approach was used by Rudas and Toth [11] to solve the inverse dynamic problem of robots.…”

Computer Algebra for Real-Time Dynamics of Robots with Large Numbers of Joints

A systematic formulation of dynamic equations for robot manipulators with elastic links

Robustness of decentralized robot controller to payload variation