Dynamic control of a flexible drilling robot end-effector

The minimization of the joint torques based on the ∞-norm is proposed for the dynamic control of a kinematically redundant manipulator. The ∞-norm is preferred to the 2-norm in the minimization of the joint torques since the maximum torques of the actuators are limited. To obtain the minimum ∞-norm torque solution, we devised a new algorithm that uses the acceleration polyhedron representing the end-effector's acceleration capability. Usually the minimization of the joint torques has an instability problem for the long trajectories of the end-effector. To suppress this instability problem, an inequality constraint, named the feasibility constraint, is developed from the geometrical relation between the required end-effector acceleration and the acceleration polyhedron. The minimization of the °-norm of the joint torques subject to the feasibility constraint is shown to improve the performances through the simulations of a 3-link planar redundant manipulator.

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A Robotic Drilling End-Effector and Its Sliding Mode Control for the Normal Adjustment

Applied Sciences ◽

10.3390/app8101892 ◽

2018 ◽

Vol 8 (10) ◽

pp. 1892 ◽

Cited By ~ 3

Author(s):

Laixi Zhang ◽

Jaspreet Singh Dhupia ◽

Mingliang Wu ◽

Hua Huang

Keyword(s):

Sliding Mode Control ◽

Real Time ◽

Sliding Mode ◽

Dynamic Control ◽

Variable Structure ◽

Real Time Control ◽

End Effector ◽

Mode Control ◽

Robotic Drilling ◽

Control Scheme

A robotic drilling end-effector is designed and modeled, and a sliding mode variable structure control architecture based on the reaching law is proposed for its normal adjustment dynamic control. By using a third-order nonlinear integration chain differentiator for obtaining the unmeasurable speed and acceleration signals from the position signals, this sliding mode control scheme is developed with good dynamic quality. The new control law ensures global stability of the entire system and achieves both stabilization and tracking within a desired accuracy. A real-time control experiment platform is established in xPC target environment based on MATLAB Real-Time Workshop (RTW) to verify the proposed control scheme and simulation results. Simulations and experiments performed on the designed robotic end-effector illustrate and clarify that the proposed control scheme is effective.

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Dynamic Control of Flexible Joint Robots with Constrained End-Effector Motion

IFAC Proceedings Volumes ◽

10.1016/s1474-6670(17)51085-x ◽

1991 ◽

Vol 24 (9) ◽

pp. 375-380 ◽

Cited By ~ 1

Author(s):

K.P. Jankowski ◽

H.A. ElMaraghy

Keyword(s):

Dynamic Control ◽

End Effector ◽

Flexible Joint ◽

Flexible Joint Robots

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Decentralized Dynamic Control of a Nonholonomic Mobile Manipulator Collective: A Simulation Study

ASME 2008 Dynamic Systems and Control Conference, Parts A and B ◽

10.1115/dscc2008-2194 ◽

2008 ◽

Cited By ~ 12

Author(s):

Hao Su ◽

Venkat Krovi

Keyword(s):

Control Algorithm ◽

Null Space ◽

Dynamic Control ◽

Mobile Manipulator ◽

Mobile Manipulators ◽

Level Control ◽

Individual Agent ◽

End Effector ◽

High Level ◽

Task Accomplishment

In this paper, we present a decentralized dynamic control algorithm for a robot collective consisting of multiple nonholonomic wheeled mobile manipulators (NH-WMMs) capable of cooperatively transporting a common payload. In this algorithm, the high level controller deals with motion/force control of the payload, at the same time distributes the motion/force task into individual agents by grasp description matrix. In each individual agent, the low level controller decomposes the system dynamics into decoupled task space (end-effector motions/forces) and a dynamically-consistent null-space (internal motions/forces) component. The agent level control algorithm facilitates the prioritized operational task accomplishment with the end-effector impedance-mode controller and secondary null-space control. The scalability and modularity is guaranteed upon the decentralized control architecture. Numerical simulations are performed for a 2-NH-WMM system carrying a payload (with/without uncertainty) to validate this approach.

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Decoupled Task- and Null-Space Dynamic Control of a Redundant Nonholonomic Mobile Manipulator

Dynamic Systems and Control, Parts A and B ◽

10.1115/imece2006-14703 ◽

2006 ◽

Author(s):

Glenn D. White ◽

Venkat N. Krovi

Keyword(s):

Null Space ◽

Dynamic Control ◽

Mobile Manipulator ◽

Mobile Manipulators ◽

Redundancy Resolution ◽

Task Space ◽

Dynamic Interactions ◽

End Effector ◽

Internal Motions ◽

Mobile Base

Our overall goal is to develop semi-autonomous and decentralized task performance capabilities during cooperative payload transport by a fleet of wheeled mobile manipulators (WMM). Each nonholonomic WMM consists of a planar two-link manipulator mounted on top of a differentially-driven wheeled mobile base. The nonholonomic base and the significant inherent redundancy create challenges for control of end-effector motion/force outputs. Nevertheless, realizing this capability is a critical precursor to decentralized payload manipulation operations. To this end, a dynamic redundancy resolution strategy is critical in order to control the dynamic interactions. The system dynamics are decomposed into a task space component (consisting of end-effector motions/forces) and a decoupled dynamically-consistent null-space part (of internal-motions/forces). A task-space controller is developed that allows each WMM module to be able to control its end-effector (motions/forces) interactions with respect to the payload. The surplus of actuation is then used to independently control internal-motions (of the mobile base) as long as they do not conflict with the primary goal. A variety of numerical simulations are then performed to test this capability of the end-effector and mobile base to independently track complex motion/force trajectories.

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