A MODIFIED PARTICLE SWARM OPTIMIZATION TO IMPROVE PRECISION OF COMPLEX ASSEMBLY

Ponnaiah Peter Anand Kumar, Rathinam Maheswaran, and Mathana Singh Victor Raj

References

1. [1] X.D. Fang and Y. Zhang, A new algorithm for minimizing the surplus parts in selective assembly, Computers and Industrial Engineering, 28(2), 1995, 341–350.
2. [2] S.M. Kannan and V. Jayabalan, A new grouping method forminimizing the surplus parts in selective assembly, QualityEngineering, 14(1), 2001, 67–75.
3. [3] S.M. Kannan, A. Asha, and V. Jayabalan, A new method inselective assembly to minimize clearance variation for a radical assembly using genetic algorithm, Quality Engineering, 17(4), 2005, 595–607.
4. [4] D.E. Whitney, Mechanical assemblies: Their design, manufacture, and role in product development (New York, NY: Oxford University Press, 2004), ISBN: 0195157826.
5. [5] S.M. Kannan, V. Jayabalan, K. Jeevanantham, Genetic algorithm for minimizing assembly variation in selective assembly, International Journal of Production Research, 41(14), 2003, 3301–3313.
6. [6] A. Asha, S.M. Kannan, V. Jayabalan, Optimization of clearance variation in selective assembly for components with multiple characteristics, International Journal of Advanced Manufacturing Technology, 38(9), 2008, 1026–1044.
7. [7] M. Victor Raj, S. SaravanaSankar, and S.G. Ponnambalam,Minimizing clearance variations and surplus parts in multiple characteristic radial assembly through batch selective assembly, International Journal of Advanced Manufacturing Technology, 57(9), 2011, 1199–1222.
8. [8] M.V. Raj, S.S. Sankar, and S.G. Ponnambalam, Maximisingmanufacturing system efficiency for multi-characteristic linear assembly by using particle swarm optimisation in batch selective assembly, International Journal of Production Research, 49(21), 2011, 6491–6516.
9. [9] M.V. Raj, S.S. Sankar, and S.G. Ponnambalam, Particleswarm optimization algorithm to maximize assembly efficiency,International Journal of Advanced Manufacturing Technology,59(5–8), 2012, 719–736.
10. [10] J. Wu, D. Wang, and L. Wang, A control strategy of a two degrees of freedom heavy duty parallel manipulator, Journal of Dynamic Systems, Measurement and Control, 137(6), 2015, 061007-1-10.
11. [11] J. Wu, L. Wang, and L. Guan, A study on the effect of structure parameters on the dynamic characteristics of a PRRRP parallel manipulator, Nonlinear Dynamics, 74 (1), 2013, 227–235.
12. [12] J. Kennedy and R. Eberhart, Particle swarm optimization, Proc. IEEE International Joint Conf. on Neural Networks, IEEE Service Center 1942–1948, 1995.
13. [13] Y. Shi and R.C. Eberhart, Parameter selection in particle swarm optimization, Evolutionary Programming VII: Proceedings of the Seventh Annual Conference on Evolutionary Programming, New York, 1998, 591–600.
14. [14] Y. Shi and R.C. Eberhart, Empirical study of particle swarm optimization, Proc. IEEE Congress on Evolutionary Computation, Vol. 3, 1999, 1945–1950.
15. [15] S.M. Kannan, R. Sivasubramanian, and V. Jayabalan, Particle swarm optimization for minimizing assembly variation in selective assembly, International Journal of Advanced Manufacturing Technology, 42(7), 2009, 793–803.
16. [16] C. Yang and D. Simon, A new particle swarm optimization technique, Proc. 18th International Conf. on Systems Engineering, 2005, 164–169.
17. [17] A. Mu, D. Cao, and X. Wang, A modified particle swarmoptimization algorithm, Natural Science, 1(2), 2009, 151–155.
18. [18] Z. Talai and Y.M.B. Ali, Homography resolution using particle swarm optimization, International Journal of Robotics and Automation, 30(2), 2015, 4162–4184.
19. [19] D. Zhu, J. Liu, and S.X. Yang, Particle swarm optimization approach to thruster fault-tolerant control of unmanned underwater vehicles, International Journal of Robotics and Automation, 26(3), 2011, 3432–3438.
20. [20] H.P.H. Anh, Novel fuzzy NARX IMC control of MISO dy-namic system using particle swarm optimization, International Journal of Robotics and Automation, 29(2), 2015, 3727–3737.
21. [21] S. Matsuura and N. Shinozaki, Optimal process design in selective assembly when components with smaller variance are manufactured at three shifted means, International Journal of Production Research, 49(3), 2011, 869–882.
22. [22] D. Mease, V.N. Nair, and A. Sudjianto, Selective assembly in manufacturing: Statistical issues and optimal binning strategies, Technometrics, 46(2), 2012, 165–175.
23. [23] R.V. Ya, K.V. Mentov, and V.V. Novikov, Automatic sorting of rings by size prior to selective assembly, Measurement Technology, 22(1), 1979, 71–73.

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• Abstract
• DOI: 10.2316/Journal.206.2016.4.206-4483
• From Journal (206) International Journal of Robotics and Automation - 2016

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