Abstract
In this paper a framework for robust optimization of mechanical design problems and process systems that have parametric uncertainty is presented using three different approaches. Robust optimization problems are formulated so that the optimal solution is robust which means it is minimally sensitive to any perturbations in parameters. The first method uses the price of robustness approach which assumes the uncertain parameters to be symmetric and bounded. The robustness for the design can be controlled by limiting the parameters that can perturb.The second method uses the robust least squares method to determine the optimal parameters when data itself is subjected to perturbations instead of the parameters. The last method manages uncertainty by restricting the perturbation on parameters to improve sensitivity similar to Tikhonov regularization. The methods are implemented on two sets of problems; one linear and the other non-linear. This methodology will be compared with a prior method using multiple Monte Carlo simulation runs which shows that the approach being presented in this paper results in better performance.
Highlights
Robust design optimization methods refers to a class of methods that can accommodate uncertainty while maintaining feasibility
The uncertainty in data is accommodated by accepting suboptimal solutions to a nominal design optimization problem
Different methodologies for robust design and optimization in mechanical systems have been extensively discussed in literature [1,2,3,4,5,6,7,8,9,10,11,12,13,14]
Summary
Robust design optimization methods refers to a class of methods that can accommodate uncertainty while maintaining feasibility. The uncertainty in data is accommodated by accepting suboptimal solutions to a nominal design optimization problem This methodology ensures that the design solution remains feasible and close to optimal even if there is a change in data. Different methodologies for robust design and optimization in mechanical systems have been extensively discussed in literature [1,2,3,4,5,6,7,8,9,10,11,12,13,14] Most of these methods assume some kind of distribution for the uncertain variable to optimize the problem. Robust designs are able to meet design objectives while taking into account aberrations that might affect the system Such designs are generally suboptimal with respect to the deterministic design but are robust under design uncertainties. Reducing the possibility of large scale design changes after the design has been fielded
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