Analytical target cascading (ATC), a hierarchical, multilevel, multidisciplinary coordination method, has proven to be an effective decomposition approach for large-scale engineering optimization problems. In recent years, augmented Lagrangian relaxation methods have received renewed interest as dual update methods for solving ATC decomposed problems. These problems can be solved using the subgradient optimization algorithm, the application of which includes three schemes for updating dual variables. To address the convergence efficiency disadvantages of the existing dual update schemes, this paper investigates two new schemes, the linear and the proximal cutting plane methods, which are implemented in conjunction with augmented Lagrangian coordination for ATC-decomposed problems. Three nonconvex nonlinear example problems are used to show that these two cutting plane methods can significantly reduce the number of iterations and the number of function evaluations when compared to the traditional subgradient update methods. In addition, these methods are also compared to the method of multipliers and its variants, showing similar performance.
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October 2013
Technical Briefs
Cutting Plane Methods for Analytical Target Cascading With Augmented Lagrangian Coordination
Wenshan Wang,
Wenshan Wang
Research Assistant
Department of Mechanical Engineering,
e-mail: wenshaw@clemson.edu
Department of Mechanical Engineering,
Clemson University
,Clemson, SC 29634
e-mail: wenshaw@clemson.edu
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Vincent Y. Blouin,
Vincent Y. Blouin
1
Assistant Professor
School of Materials Science and Engineering,
e-mail: vblouin@clemson.edu
School of Materials Science and Engineering,
Clemson University
,Clemson, SC 29634
e-mail: vblouin@clemson.edu
1Corresponding author.
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Melissa K. Gardenghi,
Melissa K. Gardenghi
Associate Professor
Division of Mathematical Sciences,
e-mail: mgardeng@bju.edu
Division of Mathematical Sciences,
Bob Jones University
,Greenville, SC 29614
e-mail: mgardeng@bju.edu
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Georges M. Fadel,
Georges M. Fadel
Professor
Department of Mechanical Engineering,
e-mail: fgeorge@clemson.edu
Department of Mechanical Engineering,
Clemson University
,Clemson, SC 29634
e-mail: fgeorge@clemson.edu
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Margaret M. Wiecek,
Benjamin C. Sloop
Benjamin C. Sloop
Research Assistant
e-mail: bsloop@clemson.edu
Department of Mathematical Sciences,
e-mail: bsloop@clemson.edu
Department of Mathematical Sciences,
Clemson University
,Clemson, SC 29634
Search for other works by this author on:
Wenshan Wang
Research Assistant
Department of Mechanical Engineering,
e-mail: wenshaw@clemson.edu
Department of Mechanical Engineering,
Clemson University
,Clemson, SC 29634
e-mail: wenshaw@clemson.edu
Vincent Y. Blouin
Assistant Professor
School of Materials Science and Engineering,
e-mail: vblouin@clemson.edu
School of Materials Science and Engineering,
Clemson University
,Clemson, SC 29634
e-mail: vblouin@clemson.edu
Melissa K. Gardenghi
Associate Professor
Division of Mathematical Sciences,
e-mail: mgardeng@bju.edu
Division of Mathematical Sciences,
Bob Jones University
,Greenville, SC 29614
e-mail: mgardeng@bju.edu
Georges M. Fadel
Professor
Department of Mechanical Engineering,
e-mail: fgeorge@clemson.edu
Department of Mechanical Engineering,
Clemson University
,Clemson, SC 29634
e-mail: fgeorge@clemson.edu
Margaret M. Wiecek
Professor
e-mail: wmalgor@clemson.edu
e-mail: wmalgor@clemson.edu
Benjamin C. Sloop
Research Assistant
e-mail: bsloop@clemson.edu
Department of Mathematical Sciences,
e-mail: bsloop@clemson.edu
Department of Mathematical Sciences,
Clemson University
,Clemson, SC 29634
1Corresponding author.
Contributed by the Design Automation Committee of ASME for publication in the Journal of Mechanical Design. Manuscript received November 17, 2011; final manuscript received May 14, 2013; published online August 7, 2013. Assoc. Editor: Wei Chen.
J. Mech. Des. Oct 2013, 135(10): 104502 (6 pages)
Published Online: August 7, 2013
Article history
Received:
November 17, 2011
Revision Received:
May 14, 2013
Citation
Wang, W., Blouin, V. Y., Gardenghi, M. K., Fadel, G. M., Wiecek, M. M., and Sloop, B. C. (August 7, 2013). "Cutting Plane Methods for Analytical Target Cascading With Augmented Lagrangian Coordination." ASME. J. Mech. Des. October 2013; 135(10): 104502. https://doi.org/10.1115/1.4024847
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