Learning to set up numerical optimizations of engineering 
designs

Schwabacher, Mark; Ellman, Thomas; Hirsh, Haym

doi:10.1017/s0890060498122084

Cited by 25 publications

(19 citation statements)

References 24 publications

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“…Various statistical predictive methods have been used as the metamodels, according to the survey by Chen et al (2006), including neural networks, tree-based methods, Splines, and spatial correlation models. During the past few years, there have emerged a number of research developments, labeled as data-mining guided engineering designs (Guikema et al 2004;Huyet 2006;Liu and Igusa 2007;Kim and Ding 2005;Michalski 2000;Schwabacher et al 2001). The data-mining guided methods are basically one form of metamodel-based methods because they also use a statistical predictive model to guide the selection of design solutions.…”

Section: Metamodel-based Methodsmentioning

confidence: 99%

“…The metamodel-based method originates from the research on computer experiments (Chen et al 2006;Fang et al 2006;Sacks et al 1989;Simpson et al 1997). This strategy is also called "data-mining" guided method, especially when the predictive model used therein is a classification tree model (Liu and Igusa 2007;Kim and Ding 2005;Schwabacher et al 2001) since the tree model is a typical "data-mining" tool. For the metamodel-based or data-mining guided methods, the major shortcoming is their ineffectiveness in handling complicated response surfaces, and as a result, they only look for local optima.…”

Section: Introductionmentioning

confidence: 99%

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Adaptive evolutionary Monte Carlo algorithm for optimization with applications to sensor placement problems

2008

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In this paper, we present an adaptive evolutionary Monte Carlo algorithm (AEMC), which combines a treebased predictive model with an evolutionary Monte Carlo sampling procedure for the purpose of global optimization. Our development is motivated by sensor placement applications in engineering, which requires optimizing certain complicated "black-box" objective function. The proposed method is able to enhance the optimization efficiency and effectiveness as compared to a few alternative strategies. AEMC falls into the category of adaptive Markov chain Monte Carlo (MCMC) algorithms and is the first adaptive MCMC algorithm that simulates multiple Markov chains in parallel. A theorem about the ergodicity property of the AEMC algorithm is stated and proven. We demonstrate the advantages of the proposed method by applying it to a sensor placement problem in a manufacturing process, as well as to a standard Griewank test function.

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Section: Metamodel-based Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Adaptive evolutionary Monte Carlo algorithm for optimization with applications to sensor placement problems

2008

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“…n−m (12) wherer is the nondimensional coordinate along the blade span, which has value 0 at the rotation axis, and 1 at the blade tip. The symbol K m,n denotes is the binomial coefficient, which is defined as…”

Section: Parametrisation Techniquementioning

confidence: 99%

Tiltrotor CFD Part II - aerodynamic optimisation of tiltrotor blades

et al. 2017

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This paper presents aerodynamic optimisation of tiltrotor blades with high-fidelity computational fluid dynamics. The employed optimisation framework is based on a quasi-Newton method, and the required high-fidelity flow gradients were computed using a discrete adjoint solver. Single-point optimisations were first performed, to highlight the contrasting requirements of the helicopter and aeroplane flight regimes. It is then shown how a trade-off blade design can be obtained using a multi-point optimisation strategy. The parametrisation of the blade shape allowed to modify the twist and chord distributions, and to introduce a swept tip. The work shows how these main blade shape parameters influence the optimal performance of the tiltrotor in helicopter and aeroplane modes, and how a compromise blade shape can increase the overall tiltrotor performance. Moreover, in all the presented cases, the accuracy of the adjoint gradients resulted in a small number of flow evaluations for finding the optimal solution, thus indicating gradient-based optimisation as a viable tool for modern tiltrotor design. overall profile drag coefficientbaseline rotor torque coefficient Greek Symbols INTRODUCTIONThe aerodynamic design of tiltrotor blades is a challenging task, requiring the best compromise in performance between hover and propeller modes [1,2]. In hovering flight, the blade aerodynamics is characterised by strong interaction with the rotor wake, resulting in a significant effect of the induced drag on the total drag [3]. The propeller mode, on the other hand, is dominated by strong compressibility effects, especially at high advance ratio, resulting in a prominent contribution of the profile and wave drag components [4]. As a consequence, to accurately capture the effect of the blade shape on the optimal rotor design, the use of high-fidelity flow models is required. Unlike in the case of helicopter and propeller blades, the aerodynamic optimisation of tiltrotor blades has not been the subject of considerable research. The present work analyses the contribution of the main blade shape parameters to the optimal performance of the tiltrotor using high-fidelity computational fluid dynamics (CFD). It also demonstrates the use of gradient-based optimisation and the discrete adjoint for the efficient design of tiltrotor blades. Aerodynamic optimisation needs large computational resources, since each design point requires the solution of a set of partial differential equations. The choice of the optimisation algorithm is therefore crucial. Broadly speaking, the optimisation algorithms can be classified in gradient-based or gradient-free methods. Gradient-based methods usually require a limited number of flow evaluations [5], and this makes them particularly attractive for complex aerodynamic optimisation problems. They need, however, the computation of flow derivatives with respect to the design variables, which can be a very expensive task, unless the adjoint method is used. Also, gradient-based methods are local in nat...

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“…Optimization and networks design applications are very broad, traversing from a specific area and ranging from engineering design (Schwabacher et al 1998;Coelho and Mariani 2008;Kashan 2011), process optimization (Egea et al 2010;Joshi and Pande 2011;Kwak and Kim 2012), scheduling system (Andersson et al 2007;Frantzénl et al 2011;Skobelev 2011), routing and flow control in networks and networking (Madan et al 2007;Shakkottai and Srikant 2007;Minoux 2010), to service oriented applications in finance (He et al 2008;Leibfritz and Maruhn 2009;Pennanen 2011), healthcare (Harrell and Lange 2001;Bagirov and Churilov 2003;José et al 2011), and bioinformatics (Hernandez and Kambhampati 2004;Nebro et al 2008;Arredondo et al 2011). For example, in the formulation of the scheduling system, optimization can be used to determine the course of vehicle systems to the various destinations, to determine the scheduling of jobs in the factory, scheduling lectures at universities, creating timetable, computer network design and planning strategies for finding an optimal decision.…”

Section: Optimization and Network Designmentioning

confidence: 99%

An introduction to swarming robotics: application development trends

2013

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Animals help to sustain the environment's life cycle and ecosystem. Without human intervention, these creatures carry out their 'spontaneous routine' jobs and contribute towards balance in nature. Any natural system that congregates as a result of some form of collective intelligence of nature is also known as swarm intelligence (SI). This metaphor inspires a variety of techniques to solve the problem of calculating, in most cases dealing with optimization problems and has sparked interest amongst scientists. It is very trying for a new researcher to understand the whole concept of swarming robotics (SR) and optimization algorithm (i.e. realizing the idea from animal's perception to the SR application). In addition, the existing algorithms are computationally complicated, difficult to be understood by beginners as there are too many parameters. Thus, in this paper, we simplify the three branches of the main applications which are frequently used for SI namely: (1) optimization and networks design, (2) prediction and forecasting, and (3) SR. This paper summarizes the basic understanding overview of swarming robotics and discusses their basic concepts and principles.

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Learning to set up numerical optimizations of engineering designs

Cited by 25 publications

References 24 publications

Adaptive evolutionary Monte Carlo algorithm for optimization with applications to sensor placement problems

Adaptive evolutionary Monte Carlo algorithm for optimization with applications to sensor placement problems

Tiltrotor CFD Part II - aerodynamic optimisation of tiltrotor blades

An introduction to swarming robotics: application development trends

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