Abstract
With the continuous improvement of computational performance, vehicle structural design has been addressed using computational methods, resulting in more efficient development of new vehicles. Most simulation-based optimization approaches generate deterministic optimal designs without considering variability effects in modeling, simulation, and/or manufacturing. One of the main reasons for this omission is due to the fact that the computing time of a single crash analysis for vehicle structural design still requires significant computing time using a state-of-the-art computer. This calls for the development and implementation of an efficient optimization under uncertainty method. In this paper, a new integrated stochastic optimization method, which combines the advantages of metamodeling techniques and Better Optimization of Nonlinear Uncertain Systems (BONUS), is developed for vehicle side impact design. Nonlinear metamodels are built by using a stepwise regression method to replace the expensive computational model and BONUS is employed to obtain optimal designs under uncertainty. A benchmark problem for vehicle safety design is used to demonstrate the method. The main goal of this case study is to maintain or enhance the vehicle side impact test performance while minimizing the vehicle weight under various uncertainties.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Choi, K.K. and B.D. Youn. (2001). “Hybrid Analysis Method for Reliability-Based Design Optimization.” In Proceedings of ASME Design Engineering Technical Conferences, Pittsburgh, PA, paper DETC2001/DAC-21044, pp. 1–10.
Choi, K.K., B.D. Youn, and R.J. Yang. (2001). “Moving Least Square Method for Reliability-Based Design Optimization.” In Proceedings of 4th World Congress of Structural and Multidisciplinary Optimization, Dalian, China, pp. 1–6.
Du, X. and W. Chen. (2002). “Sequential Optimization and Reliability Assessment Method for Efficient Probabilistic Design.” In Proceedings of ASME 2002 Design Automation Conference, Montreal, Canada, paper DETC2002/DAC-34127, pp. 1–14.
Fu, Y. (2003). “A New Hybrid Stochastic Optimization Method for Vehicle Structural Design.” In Proceed-ings of SAE World Congress, Detroit, MI, paper 2003-01-0881, pp. 1–10.
Fu, Y., S. Wang, U.M. Diwekar, and K.H. Sahin. (2002). “A Stochastic Optimization Application for Ve-hicle Structures.” In Proceedings of ASME 2002 Design Engineering Technical Conferences, Montreal, Canada, paper DETC2002/DAC-34075, pp. 1–10.
Gu, L. and R.J. Yang. (2002). “Large-Scale Reliability Based Optimization for Vehicle Crash Safety.” In Proceedings of the American Statistical Association, Statistical Computing Section (CD-ROM), pp. 1–10. Alexandria, VA: American Statistical Association.
Gu, L. and R.J. Yang. (2003). “Recent Applications on Reliability-Based Optimization of Automotive Structures.” In Proceedings of SAE 2003 World Congress and Exhibition, Detroit MI, paper 2003-01-0152, pp. 1–12.
Gu, L., R.J. Yang, C.H. Tho, M. Makowski, O. Faruque, and Y. Li. (2001). “Optimization and Robustness for Crashworthiness of Side Impact.” International Journal of Vehicle Design 26(4), 348–360.
Koch, P.N., R.J. Yang, and L. Gu. (2004). “Design for Six Sigma through Robust Optimization.” in Structural and Multidisciplinary Optimization 26, 235–248.
Kodiyalam, S., R.J. Yang, L. Gu, and C.H. Tho. (2004). “Multidisciplinary Design Optimization of a Vehi-cle System in a Scalable, High Performance Computing Environment.” Structural and Multidisciplinary Optimization 26, 256–263.
Sahin, K.H. and U.M. Diwekar. (2004). “Better Optimization of Nonlinear Uncertain Systems (BONUS): A New Algorithm for Stochastic Programming Using Reweighting for Density Estimation.” Annals of Operational Research 132, 47–68.
Silverman, B.W. (1998). Density Estimation for Statistics and Data Analysis. Boca Raton, FL: Chapman & Hall.
Yang, R.J. and L. Gu. (2004). “Experience with Approximate Reliability-Based Optimization Methods.” Structural and Multidisciplinary Optimization 26, 152–159.
Yang, R.J., L. Gu, L. Liaw, C. Gearhart, C.H. Tho, X. Liu, and B.P. Wang. (2000). “Approximations for Safety Optimization of Large Systems.” In Proceedings of ASME Design Engineering Technical Conferences, Baltimore, MD, paper DETC2000/DAC-14245, pp. 1–10.
Yang, R.J., L. Gu, C.H. Tho, K.K. Choi, and B.D. Youn. (2002a). “Reliability-Based Multidisciplinary.84 FU AND SAHIN Design Optimization of a Full Vehicle System.” In Proceedings of 43rd AIAA SDM Conference, Denver, CO, paper AIAA-2002-1758, pp. 1–9.
Yang, R.J., L. Gu, C.H. Tho, K.K. Choi, and B.D. Youn. (2002b). “Reliability-Based Multidisciplinary Design Optimization of Vehicle Structures.” In Proceedings of IMechE Statistics and Analytical Methods in Automotive Engineering, London, UK, pp. 1–9.
Yang, R.J., C.H. Tho, and L. Gu. (2002). “Recent Development in Multidisciplinary Design Optimization of Vehicle Structures.” In Proceedings of 9th AIAA/ISSMO Symposium on MAO, Atlanta, GA, paper AIAA-2002-5606, pp. 1–8.
Youn, B.D., K.K. Choi, and R.J. Yang. (2003). “Efficient Evaluation Approaches for Probabilistic Con-straints in Reliability-Based Design Optimization.” In Proceedings of 5th World Congress on Structural and Multidisciplinary Optimization, Venice, Italy, pp. 1–10.
Youn, B.D., K.K. Choi, R.J. Yang, and L. Gu. (2004). “Reliability-Based Design Optimization for Crash-worthiness of Vehicle Side Impact.” Structural and Multidisciplinary Optimization 26, 272–283.
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Fu, Y., Sahin, K.H. Better Optimization of Nonlinear Uncertain Systems (BONUS) for Vehicle Structural Design. Ann Oper Res 132, 69–84 (2004). https://doi.org/10.1023/B:ANOR.0000045277.22566.5f
Issue Date:
DOI: https://doi.org/10.1023/B:ANOR.0000045277.22566.5f