scholarly journals Drag Parameter Estimation Using Gradients and Hessian from a Polynomial Chaos Model Surrogate

2014 ◽  
Vol 142 (2) ◽  
pp. 933-941 ◽  
Author(s):  
Ihab Sraj ◽  
Mohamed Iskandarani ◽  
W. Carlisle Thacker ◽  
Ashwanth Srinivasan ◽  
Omar M. Knio
Keyword(s):  
Inverse Problem ◽  
Posterior Distribution ◽  
Polynomial Chaos ◽  
Monte Carlo Sampling ◽  
Chaos Expansion ◽  
Optimal Parameters ◽  
Computational Burden ◽  
Similarities And Differences ◽  
Polynomial Chaos Expansions ◽  
The Cost

Abstract A variational inverse problem is solved using polynomial chaos expansions to infer several critical variables in the Hybrid Coordinate Ocean Model’s (HYCOM’s) wind drag parameterization. This alternative to the Bayesian inference approach in Sraj et al. avoids the complications of constructing the full posterior with Markov chain Monte Carlo sampling. It focuses instead on identifying the center and spread of the posterior distribution. The present approach leverages the polynomial chaos series to estimate, at very little extra cost, the gradients and Hessian of the cost function during minimization. The Hessian’s inverse yields an estimate of the uncertainty in the solution when the latter’s probability density is approximately Gaussian. The main computational burden is an ensemble of realizations to build the polynomial chaos expansion; no adjoint code or additional forward model runs are needed once the series is available. The ensuing optimal parameters are compared to those obtained in Sraj et al. where the full posterior distribution was constructed. The similarities and differences between the new methodology and a traditional adjoint-based calculation are discussed.

Polynomial Chaos Based Design of Robust Input Shapers

2010 ◽  
Vol 132 (5) ◽  
Author(s):  
Tarunraj Singh ◽  
Puneet Singla ◽  
Umamaheswara Konda
Keyword(s):  
Polynomial Chaos ◽  
Probabilistic Approach ◽  
Uncertain System ◽  
Residual Energy ◽  
Model Parameters ◽  
Minimax Optimization ◽  
Stochastic Space ◽  
System States ◽  
Polynomial Chaos Expansions ◽  
The Cost

A probabilistic approach, which exploits the domain and distribution of the uncertain model parameters, has been developed for the design of robust input shapers. Polynomial chaos expansions are used to approximate uncertain system states and cost functions in the stochastic space. Residual energy of the system is used as the cost function to design robust input shapers for precise rest-to-rest maneuvers. An optimization problem, which minimizes any moment or combination of moments of the distribution function of the residual energy is formulated. Numerical examples are used to illustrate the benefit of using the polynomial chaos based probabilistic approach for the determination of robust input shapers for uncertain linear systems. The solution of polynomial chaos based approach is compared with the minimax optimization based robust input shaper design approach, which emulates a Monte Carlo process.

scholarly journals Sensitivity Analysis for the Inverse Problems of Electromagnetic Nondestructive Evaluation

2020 ◽  
Author(s):  
Sándor Bilicz
Keyword(s):  
Sensitivity Analysis ◽  
Nondestructive Evaluation ◽  
Polynomial Chaos ◽  
Magnetic Flux Leakage ◽  
Chaos Expansion ◽  
Computational Burden ◽  
Material Parameters ◽  
Different Sources ◽  
Flux Leakage ◽  
State Of Art

Sensitivity analysis of the model-based inverse problem associated to electromagnetic nondestructive evaluation is dealt with. Some uncertainty of the arrangement is inevitable present (imprecise host material parameters, sensor mispositioning, etc.), and this induces uncertainty on the reconstructed defect parameters. The aim of this work is to present a methodology for the ranking of the different sources of random error according to their contribution to the reconstruction uncertainty. To this end, state-of-art mathematical tools of sensitivity analysis are applied, including Sobol’ indices, and a polynomial chaos expansion surrogate model to reduce the computational burden of the method. A numerical example drawn from magnetic flux leakage nondestructive evaluation is presented to illustrate the proposed methodology.

scholarly journals Performance of non-intrusive uncertainty quantification in the aeroservoelastic simulation of wind turbines

2019 ◽  
Vol 4 (3) ◽  
pp. 397-406 ◽  
Author(s):  
Pietro Bortolotti ◽  
Helena Canet ◽  
Carlo L. Bottasso ◽  
Jaikumar Loganathan
Keyword(s):  
Monte Carlo ◽  
Wind Turbine ◽  
Uncertainty Quantification ◽  
Polynomial Chaos ◽  
Solution Space ◽  
Monte Carlo Sampling ◽  
Polynomial Chaos Expansion ◽  
Offshore Wind ◽  
Offshore Wind Turbine ◽  
Chaos Expansion

Abstract. The present paper characterizes the performance of non-intrusive uncertainty quantification methods for aeroservoelastic wind turbine analysis. Two different methods are considered, namely non-intrusive polynomial chaos expansion and Kriging. Aleatory uncertainties are associated with the wind inflow characteristics and the blade surface state, on account of soiling and/or erosion, and propagated throughout the aeroservoelastic model of a large conceptual offshore wind turbine. Results are compared with a brute-force extensive Monte Carlo sampling, which is used as benchmark. Both methods require at least 1 order of magnitude less simulations than Monte Carlo, with a slight advantage of Kriging over polynomial chaos expansion. The analysis of the solution space clearly indicates the effects of uncertainties and their couplings, and highlights some possible shortcomings of current mostly deterministic approaches based on safety factors.

scholarly journals Performance of non-intrusive uncertainty quantification in the aeroservoelastic simulation of wind turbines

2019 ◽  
Author(s):  
Pietro Bortolotti ◽  
Helena Canet ◽  
Carlo L. Bottasso ◽  
Jaikumar Loganathan
Keyword(s):  
Monte Carlo ◽  
Wind Turbine ◽  
Uncertainty Quantification ◽  
Surface State ◽  
Polynomial Chaos ◽  
Solution Space ◽  
Monte Carlo Sampling ◽  
Chaos Expansion ◽  
Brute Force ◽  
Blade Surface

Abstract. The paper studies the effects of uncertainties on aeroservoelastic wind turbine models. Two non-intrusive uncertainty quantification methods are considered, namely non-intrusive polynomial chaos expansion and Kriging. Uncertainties are associated with the wind inflow characteristics and the blade surface state, on account of soiling and/or erosion, and propagated throughout the aeroservoelastic model of a large conceptual off-shore wind turbine. Results are compared with a brute-force extensive Monte Carlo sampling. Both methods appear to yield similar results, with a somewhat faster convergence for Kriging. The analysis of the solution space clearly indicates the effects of uncertainties and their couplings, and highlights some possible shortcomings of current mostly deterministic approaches.

An Efficient Sampling Method for Regression-Based Polynomial Chaos Expansion

2013 ◽  
Vol 13 (4) ◽  
pp. 1173-1188 ◽  
Author(s):  
Samih Zein ◽  
Benoît Colson ◽  
François Glineur
Keyword(s):  
Finite Element ◽  
Design Of Experiments ◽  
Polynomial Chaos ◽  
Polynomial Chaos Expansion ◽  
Computational Time ◽  
Chaos Expansion ◽  
Analysis Model ◽  
Element Analysis ◽  
Analytical Functions ◽  
The Cost

AbstractThe polynomial chaos expansion (PCE) is an efficient numerical method for performing a reliability analysis. It relates the output of a nonlinear system with the uncertainty in its input parameters using a multidimensional polynomial approximation (the so-called PCE). Numerically, such an approximation can be obtained by using a regression method with a suitable design of experiments. The cost of this approximation depends on the size of the design of experiments. If the design of experiments is large and the system is modeled with a computationally expensive FEA (Finite Element Analysis) model, the PCE approximation becomes unfeasible. The aim of this work is to propose an algorithm that generates efficiently a design of experiments of a size defined by the user, in order to make the PCE approximation computationally feasible. It is an optimization algorithm that seeks to find the best design of experiments in the D-optimal sense for the PCE. This algorithm is a coupling between genetic algorithms and the Fedorov exchange algorithm. The efficiency of our approach in terms of accuracy and computational time reduction is compared with other existing methods in the case of analytical functions and finite element based functions.

scholarly journals Analysis of the Stochastic Quarter-Five Spot Problem Using Polynomial Chaos

Molecules ◽  
2020 ◽  
Vol 25 (15) ◽  
pp. 3370
Author(s):  
Hesham AbdelFattah ◽  
Amnah Al-Johani ◽  
Mohamed El-Beltagy
Keyword(s):  
Porous Media ◽  
Correlation Function ◽  
Polynomial Chaos ◽  
Monte Carlo Sampling ◽  
Model Parameters ◽  
Chaos Expansion ◽  
Stochastic Problem ◽  
First Order ◽  
Stochastic Problems ◽  
Exponential Correlation Function

Analysis of fluids in porous media is of great importance in many applications. There are many mathematical models that can be used in the analysis. More realistic models should account for the stochastic variations of the model parameters due to the nature of the porous material and/or the properties of the fluid. In this paper, the standard porous media problem with random permeability is considered. Both the deterministic and stochastic problems are analyzed using the finite volume technique. The solution statistics of the stochastic problem are computed using both Polynomial Chaos Expansion (PCE) and the Karhunen-Loeve (KL) decomposition with an exponential correlation function. The results of both techniques are compared with the Monte Carlo sampling to verify the efficiency. Results have shown that PCE with first order polynomials provides higher accuracy for lower (less than 20%) permeability variance. For higher permeability variance, using higher-order PCE considerably improves the accuracy of the solution. The PCE is also combined with KL decomposition and faster convergence is achieved. The KL-PCE combination should carefully choose the number of KL decomposition terms based on the correlation length of the random permeability. The suggested techniques are successfully applied to the quarter-five spot problem.

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