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Abstract

This article presents the dynamic analysis and simulation for a nonlinear model of a Stewart platform with asymmetric-adjustable payload, based on Lagrangian approach. Due to the asymmetry of payload, the moment of inertia matrix is not diagonal and computing their terms is more complicated than for a symmetric load. Previous research about dynamic analysis of the Stewart platform are mostly considering static and symmetric payload, while numerous applications may have asymmetric payload such as satellite antenna trackers or surgical tables and so on.

This article considers an asymmetric-adjustable payload applied to a Stewart platform, deriving the dynamic equations of the model. Moreover, the moment of inertia matrix and Coriolis-centrifugal terms matrices, which are useful for control analysis of the robot, are obtained. In addition, to verify the correctness of the model, the system has been modelled in ADAMS engineering software and the inverse dynamic solution has been developed by both analytical (Lagrangian formulation) and simulation (ADAMS) methods. The results show that the analytical model is so reliable and accurate that it can be used for dynamic analysis in other similar problems. Finally, the singularities of the model are determined.

Keywords

Stewart platform Lagrangian formulation asymmetric-adjustable payload inverse dynamic solution ADAMS

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References

WQD

Yang

DCH

(1998) Inverse dynamic analysis and simulation of a platform type of robot. J Robot Syst. 53: 209–227.

Dasgupta

Mruthyunjaya

(1998) A Newton–Euler formulation for the inverse dynamics of the stewart platform manipulator. Mach Mech Theor. 33: 1135–1152.

Guo

(2006) Dynamic analysis and simulation of a six degree of freedom Stewart platform manipulator. Proc IMechE Part C: J Mechanical Engineering Science. 220: 61–72.

Oftadeh R, Aref MM and Taghirad HD. Explicit dynamics formulation of Stewart–Gough platform: a Newton–Euler approach. In: International conference on intelligent robots and systems, Taipei, Taiwan, 18–22 October 2010, pp.2772–2777.

Harib

Srinivasan

(2003) Kinematic and dynamic analysis of Stewart platform-based machine tool structures. Camb J Robotic. 21: 541–554.

Lee

Dharman

(1988) Dynamic analysis of a three-degrees-of-freedom in-parallel actuated manipulator. IEEE J Robot Autom. 4: 361–367.

Nguyen

Pooran

(1989) Dynamic analysis of 6 DOF CKCM robot end-effectors for dual arm telerobot systems. J Robot Autonom Syst. 5: 377–394.

Pang

Shahingpoor

(1994) Inverse dynamics of a parallel manipulator. J Robot Syst. 11: 693–702.

Lebert

Liu

Lewis

(1993) Dynamic analysis and control of a Stewart platform manipulator. J Robot Syst. 10: 629–655.

10.

Xiaoli B, James DT and John LJ. Dynamic analysis and control of a Stewart platform using a novel automatic differentiation method. In: Astrodynamics specialist conference and exhibit, Keystone, CO, USA, 21–24 August 2006, pp.571–581.

11.

Bhatti IS and Ahmed Q. Dynamic analysis and robust control design for Stewart platform with moving payload. In: 17th IFAC World Congress, COEX, South Korea, 6–11 July 2008, pp.897–1001.

12.

Hajimirzaalian H, Moosavi H and Massah M. Dynamic analysis and simulation of parallel robot Stewart platform. In: International conference on computer and automation engineering ICCAE, Singapore, 26–28 February 2010, pp.472–477.

13.

Wang

Gosselin

(1998) A new approach for the dynamic analysis of parallel manipulators. J Multibod Syst Dynam. 2: 317–334.

14.

Tsai

(2000) Solving the inverse dynamics of a Stewrat–Gough manipulator by the principle of virtual work. J Mech Des. 122: 3–9.

15.

Geike

McPhee

. Inverse dynamic analysis of parallel manipulators with full mobility. Mech Mach Theor. 38(6): 549–562.

16.

Zhao

Gao

(2009) Inverse dynamics of 6-dof parallel manipulator by means of the principle virtual work. Robotica. 27: 259–268.

17.

Liu

(2000) Dynamic analysis of the Gough–Stewart platform manipulator. J IEEE Trans Robot Autom. 16: 94–98.

18.

Paccot

Andreff

Martinet

(2009) A review on control analysis of parallel kinematic machine: theory and experiments. Int Robot Res. 28(3): 395–416.

19.

Honegger M, Brega R and Schweiter G. Application of a nonlinear adaptive controller to a 6 dof parallel manipulator. In: International conference on Robotic and Automation ICRA, San Francisco, CA, USA, 24–28 April 2000, pp.1930–1935.

20.

Eberhard

Schiehlen

(2006) Computational dynamics of multi-body systems: history, formalisms and applications. J Comput Nonlinear Dynam. 1: 115–125.

21.

Rahnejat

(1998) Multi-body dynamics: vehicles, machines and mechanisms, Warrendale, PA: Society of Automative Engineers.

22.

Brewer

(1978) Kronecker products and matrix caculas in system theory. J IEEE Trans. circuits Syst. 25: 772–781.

23.

(2000) Forward kinematic analysis for 6–3 type Stewart platform mechanism. Proc IMechE Part K: J Multi-body Dynamics. 214: 233–241.

24.

Liu

Chiu

(2005) Direct kinematic singularities of 3–3 Stewart–Gough platforms. Proc IMechE Part K: J Multi-body Dynamics. 219: 311–324.

25.

MSC Software. Adams, http://www.mscsoftware.com/product/adams.

An analytical method for the inverse dynamic analysis of the Stewart platform with asymmetric-adjustable payload

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