A polynomial time heuristic for certain subgraph optimization problems with guaranteed worst case bound

We present a deterministic non-gradient based approach that uses robustness measures in multi-objective optimization problems where uncontrollable parameter variations cause variation in the objective and constraint values. The approach is applicable for cases that have discontinuous objective and constraint functions with respect to uncontrollable parameters, and can be used for objective or feasibility robust optimization, or both together. In our approach, the known parameter tolerance region maps into sensitivity regions in the objective and constraint spaces. The robustness measures are indices calculated, using an optimizer, from the sizes of the acceptable objective and constraint variation regions and from worst-case estimates of the sensitivity regions’ sizes, resulting in an outer-inner structure. Two examples provide comparisons of the new approach with a similar published approach that is applicable only with continuous functions. Both approaches work well with continuous functions. For discontinuous functions the new approach gives solutions near the nominal Pareto front; the earlier approach does not.

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Feasibility Robust Optimization via Scenario Generation and Reduction

Volume 2B: 44th Design Automation Conference ◽

10.1115/detc2018-85990 ◽

2018 ◽

Author(s):

Eliot Rudnick-Cohen ◽

Jeffrey W. Herrmann ◽

Shapour Azarm

Keyword(s):

Robust Optimization ◽

Optimization Problems ◽

Computational Cost ◽

Optimization Techniques ◽

Scenario Generation ◽

Test Problems ◽

Optimization Approach ◽

Uncertain Parameters ◽

Worst Case ◽

Robust Solution

Feasibility robust optimization techniques solve optimization problems with uncertain parameters that appear only in their constraint functions. Solving such problems requires finding an optimal solution that is feasible for all realizations of the uncertain parameters. This paper presents a new feasibility robust optimization approach involving uncertain parameters defined on continuous domains without any known probability distributions. The proposed approach integrates a new sampling-based scenario generation scheme with a new scenario reduction approach in order to solve feasibility robust optimization problems. An analysis of the computational cost of the proposed approach was performed to provide worst case bounds on its computational cost. The new proposed approach was applied to three test problems and compared against other scenario-based robust optimization approaches. A test was conducted on one of the test problems to demonstrate that the computational cost of the proposed approach does not significantly increase as additional uncertain parameters are introduced. The results show that the proposed approach converges to a robust solution faster than conventional robust optimization approaches that discretize the uncertain parameters.

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REDUCING SIMPLE GRAMMARS: EXPONENTIAL AGAINST HIGHLY-POLYNOMIAL TIME IN PRACTICE

International Journal of Foundations of Computer Science ◽

10.1142/s0129054107004930 ◽

2007 ◽

Vol 18 (04) ◽

pp. 715-725

Author(s):

CÉDRIC BASTIEN ◽

JUREK CZYZOWICZ ◽

WOJCIECH FRACZAK ◽

WOJCIECH RYTTER

Keyword(s):

Polynomial Time ◽

Experimental Analysis ◽

Time Complexity ◽

Packet Classification ◽

State Machines ◽

Worst Case ◽

Exponential Time ◽

Push Down

Simple grammar reduction is an important component in the implementation of Concatenation State Machines (a hardware version of stateless push-down automata designed for wire-speed network packet classification). We present a comparison and experimental analysis of the best-known algorithms for grammar reduction. There are two approaches to this problem: one processing compressed strings without decompression and another one which processes strings explicitly. It turns out that the second approach is more efficient in the considered practical scenario despite having worst-case exponential time complexity (while the first one is polynomial). The study has been conducted in the context of network packet classification, where simple grammars are used for representing the classification policies.

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