Rapid Computation of Optimally Safe Tension Distributions for Parallel Cable-Driven Robots

Borgstrom, Per Henrik; Jordan, Brett; Sukhatme, Gaurav S.; Batalin, Maxim; Kaiser, William J.

doi:10.1109/tro.2009.2032957

Cited by 116 publications

(62 citation statements)

References 19 publications

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“…In [33,39,40], the authors, respectively, take advantage of convex method, variant of bland's pivot rule, and gradient projection to obtain the tension distribution. In the meanwhile, [41,42] address the same problem by using minimization of the Euclidean norm of the cable tensions and p-norm of the relative cable tensions to avoid the discontinuity of the cable tension in a continuous trajectory with linear-program formulation.…”

Section: Theoretical Research On Cable-drivenmentioning

confidence: 99%

An Overview of the Development for Cable-Driven Parallel Manipulator

Tang

2014

Advances in Mechanical Engineering

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In the last two decades, cable-driven parallel robots have attracted a lot of attention in robot community as a hot topic of robot research. In this paper, the development of the cable-driven parallel manipulator is first introduced in general. Second, the latest advance in theory and applications of cable-driven parallel manipulator is presented in detail, especially some notable implementations. Finally, an other probable application foresight with this cable manipulator is proposed and discussed.

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Section: Theoretical Research On Cable-drivenmentioning

confidence: 99%

An Overview of the Development for Cable-Driven Parallel Manipulator

Tang

2014

Advances in Mechanical Engineering

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“…[18][19][20][21][22] In this paper we will focus our discussion on the analysis and optimization of the tension factor T F , which is defined by 23…”

Section: Tension Analysismentioning

confidence: 99%

Tension distribution shaping via reconfigurable attachment in planar mobile cable robots

2013

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Traditional cable robots derive their manipulation capabilities using spooling winches at fixed base locations. In our previous work, we examined enhancing manipulation capabilities of cable robots by the addition of base mobility to spooling winches (allowing a group of mobile robots to cooperatively manipulate a payload using cables). Base mobility facilitated the regulation of the tension-direction (via active coordination of mobile bases) and allowed for better conditioning of the wrench-feasible workspace. In this paper we explore putting idler pulleys on the payload attachment as alternate means to simplify the design and enable practical deployment. We examine analysis of the system using ellipse geometry and develop a virtual cable-subsystem formulation (which also facilitates subsumption into the previously developed mobile cable robot analysis framework). We also seek improvement of the tension distribution by utilizing configuration space redundancy to shape the tension null space. This tension distribution shaping is implemented in the form of a tension factor optimization problem over the workspace and explored via both simulation and experimental studies.

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“…Thus, every cable tensile force of the CDPM should always be kept positive in order for the CDPM to be properly operational. Indeed, the optimization problem for the cable force distribution of the CDPM should be defined by an appropriate objective function subject to inequality conditions to secure that every cable force is kept within the range, between the minimum and maximum tensile cable forces [1][2][3][4][5]. Recently, the pseudoinverse solution equation for the redundantly actuated PM with one redundant actuation is interpreted as line equations.…”

mentioning

confidence: 99%

“…The method is effective to avoid actuator saturation and can be summarized as follows. Force equation of the n DOF CDPM with nr  cables can be expressed as follows: (2) Note that the general equation for cable force solutions can be obtained by taking the pseudo-inverse of (1) as follows: Indeed, as shown in [6], the optimal solution for the cable actuation force can be found through the search for the intersection points or intersection lines between lines and/or planes. But differently from in [6], additional planes,   f at the current searching reference point is minimal compared with ones at other intersection points is met.…”

mentioning

confidence: 99%

Cable Force-Balancing Distribution of the Cable-Driven Parallel Mechanism for Actuator Saturation Avoidance

Cho¹,

Cheong²,

Kim³

2017

Proceedings of the 4th International Conference of Control, Dynamic Systems, and Robotics (CDSR'17)

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Extended AbstractWhen any actuation cable force of the cable-driven parallel mechanism(CDPM) becomes negative during its operation, the cable goes slack losing its role of force transmission. Thus, every cable tensile force of the CDPM should always be kept positive in order for the CDPM to be properly operational. Indeed, the optimization problem for the cable force distribution of the CDPM should be defined by an appropriate objective function subject to inequality conditions to secure that every cable force is kept within the range, between the minimum and maximum tensile cable forces [1][2][3][4][5]. Recently, the pseudoinverse solution equation for the redundantly actuated PM with one redundant actuation is interpreted as line equations. Then through the search for the intersection points between lines, the computational efficiency in finding the optimal - norm solution could be improved significantly [6].In this work, an optimal cable force distribution algorithm is proposed, which can efficiently search for the minimum

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Rapid Computation of Optimally Safe Tension Distributions for Parallel Cable-Driven Robots

Cited by 116 publications

References 19 publications

An Overview of the Development for Cable-Driven Parallel Manipulator

An Overview of the Development for Cable-Driven Parallel Manipulator

Tension distribution shaping via reconfigurable attachment in planar mobile cable robots

Cable Force-Balancing Distribution of the Cable-Driven Parallel Mechanism for Actuator Saturation Avoidance

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