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Robot dynamics modeling method based on multibody system discrete time transmission matrix method

A dynamic modeling and discrete time technology, applied in general control systems, control/regulation systems, instruments, etc., can solve problems such as difficult compensation of tracking errors, lack of non-holonomic constraints on mobile platforms, etc.

Inactive Publication Date: 2015-07-22
TIANJIN UNIVERSITY OF TECHNOLOGY
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  • Abstract
  • Description
  • Claims
  • Application Information

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Problems solved by technology

Its advantage is that it can partially overcome the influence of dynamic coupling and external disturbance, but its disadvantage is that it must meet the continuous excitation conditions; (2) Yamamoto Y uses nonlinear feedback to perform centralized compensation for coupling, but experiments have proved that this compensation is for The tracking error caused by the movement of the platform works well, but it is difficult to compensate the tracking error caused by the movement of the manipulator
[0008] At present, there are few studies on the control of tracked mobile robots using unified kinematics and dynamics modeling, and the existing methods lack effective measures for the nonholonomic constraints of mobile platforms.

Method used

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  • Robot dynamics modeling method based on multibody system discrete time transmission matrix method
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  • Robot dynamics modeling method based on multibody system discrete time transmission matrix method

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Embodiment 1

[0082] Embodiment 1, mobile robot dynamics modeling method based on multi-body system discrete time transfer matrix method

[0083] The inventive method comprises:

[0084] First, summarize the structural model of the tracked mobile robot, that is, extract the main features of the tracked mobile robot to be studied according to the traditional method, and its structural model is shown in the attached figure 1 As shown, including the car body, the manipulator rod, the rotating joint (central rigid body) and the end of the manipulator.

[0085] Second, divide the whole into parts, and number the overall mechanical structure of the robot: 0—ground, 1—car body, 2,4,6—central rigid body, 3,5,7—mechanical arm, 8—end of mechanical arm.

[0086] Third, determine the basic parameter information such as the coordinates of the center of mass, external dimensions, and quality of each component of the robot, as shown in Table 1:

[0087] Table 1

[0088]

[0089] The law of motion of...

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Abstract

The invention discloses a uniform dynamics modeling method based on a mmultibody system discrete time transmission matrix method and for a crawler-type moving robot. The method mainly includes: building a multibody system dynamics model for breaking up the whole into parts, and determining a state vector; determining a transmission matrix U and a transmission equation zO=UzI for each element; assembling the transmission matrixes of the elements to form a general transmission matrix Uall and a general transmission equation Uallzall=0 of a system; according to boundary conditions, solving the system transmission equation to acquire a boundary state vector of a moment ti; applying the transmission equations of the elements to solve a state vector of each connecting point of the system at the moment ti. By the method, the circumstance that errors caused by coupling and mutual influence are neglected during modeling of a moving platform and a mechanical arm when moving robots are studied in the past is avoided, the method is high in theoretical property, clear in thinking and easy in realization of programming, and the objective of accurate control on the moving robots can be achieved.

Description

technical field [0001] The invention relates to the technical field of dynamic modeling of mobile robots. [0002] The method mainly relates to a unified dynamics modeling method of a crawler mobile robot, especially the dynamics modeling of a class of mobile robots using the multi-body system theory, which can be used for the controller design of the mobile robot. Background technique [0003] In recent years, due to frequent natural disasters such as earthquakes and tsunamis and human factors such as terrorist organizations, huge losses of life and property have been caused to countries all over the world. With the rapid development of robot technology, rescue robots replace humans in complex and dangerous environments such as earthquake disasters and nuclear pollution to complete tasks such as detection, search and rescue. The tracked mobile robot system is composed of a manipulator fixed on a tracked mobile platform. The mobile robot has two functions of moving and ope...

Claims

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Application Information

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Patent Type & Authority Applications(China)
IPC IPC(8): G05B13/04
Inventor 陈炜郭月李浩
Owner TIANJIN UNIVERSITY OF TECHNOLOGY
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