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140 results on '"Li, Enying"'

1. An E-PINN assisted practical uncertainty quantification for inverse problems

Author

Jiang, Xinchao, Wanga, Xin, Wena, Ziming, Li, Enying, and Wang, Hu

Subjects
Mathematics - Numerical Analysis
Abstract

How to solve inverse problems is the challenge of many engineering and industrial applications. Recently, physics-informed neural networks (PINNs) have emerged as a powerful approach to solve inverse problems efficiently. However, it is difficult for PINNs to quantify the uncertainty of results. Therefore, this study proposed ensemble PINNs (E-PINNs) to handle this issue. The E-PINN uses ensemble statistics of several basic models to provide uncertainty quantifications for the inverse solution based on the PINN framework, and it is employed to solve the inverse problems in which the unknown quantity is propagated through partial differential equations (PDEs), especially the identification of the unknown field (e.g., space function) of a given physical system. Compared with other data-driven approaches, the suggested method is more than straightforward to implement, and also obtains high-quality uncertainty estimates of the quantity of interest (QoI) without significantly increasing the complexity of the algorithm. This work discusses the good properties of ensemble learning in field inversion and uncertainty quantification. The effectiveness of the proposed method is demonstrated through several numerical experiments. To enhance the robustness of models, adversarial training (AT) is applied. Furthermore, an adaptive active sampling (AS) strategy based on the uncertainty estimates from E-PINNs is also proposed to improve the accuracy of material field inversion problems., Comment: 31 pages, 12figures, 3 tables

Published
2022

5. Variational Auto-Encoder Based Approximate Bayesian Computation Uncertian Inverse Method for Sheet Metal Forming Problem

Author

Wang, Jiaquan, Zeng, Yang, Jiang, Xinchao, Wang, Hu, Li, Enying, and Li, Guangyao

Subjects
Electrical Engineering and Systems Science - Image and Video Processing
Abstract

In this study, an image-assisted Approximate Bayesian Computation (ABC) parameter inverse method is proposed to identify the design parameters. In the proposed method, the images are mapped to a low-dimensional latent space by Variational Auto-Encoder (VAE), and the information loss is minimized by network training. Therefore, an effective trade-off between information loss and computational cost can be achieved by using the latent variables of VAE as summary statistics of ABC, which overcomes the difficulty of selecting summary statistics in the ABC. Besides, for some practical engineering problems, processing the images as objective function can effective show the response result. Meanwhile, the relationship between design parameters and the latent variables is constructed by Least Squares Support Vector Regression (LSSVR) surrogate model. With the well-constructed LSSVR model, the simulation coefficient vectors under given parameters will be determined effectively. Then, the parameters to be identified are determined by comparing the simulated and observed coefficient vectors in ABC. Finally, a sheet forming problem is investgated by the suggested method. The material parameters of the blank and the process parameters of the forming process are identified. Results show that the method is feasibility and effective for the identification of sheet forming parameters.

Published
2019

38. Fast variable stiffness composite cylinder uncertainty analysis by using reanalysis assisted Copula function

Author

Yang Zeng, Li Enying, and Wang Hu

Subjects
Engineering (General). Civil engineering (General), TA1-2040
Abstract

There are lots of uncertainties in variable-stiffness composite materials such as material properties, fibre volume fraction, geometries at various scale and matrix porosity. Commonly, these uncertainties are not always mutually independent and there exist correlations among these random input variables. These correlations may affect the output of composite significantly. To address these correlations, a novel approach for uncertainty analysis based on copula function assisted by reanalysis method is suggested. The Copula function is utilized to address the correlations of random input variables. Monte Carlo simulation (MCS) is employed to obtain the uncertainty analysis. Therefore, a large number of samples should be generated and the expensive computational cost is not feasible when the popular finite element (FE) model is utilized. To save the computational cost and make the uncertainty analysis feasible in practice, an efficient fast computation method, reanalysis method is integrated in the frame. The numerical test demonstrates that the proposed approach is an efficient uncertainty analysis tool for the practical engineering problems.

Published
2016
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44. A metamodel optimization methodology based on multi-level fuzzy clustering space reduction strategy and its applications

Author

Wang, Hu, Li, Enying, G.Y., Li, and Z.H., Zhong

Subjects
Server clustering, Clustering (Computers) -- Usage, Mathematical optimization -- Analysis
Abstract

This paper proposes metamodel optimization methodology based on multi-level fuzzy-clustering space reduction strategy with Kriging interpolation. The proposed methodology is composed of three levels. In the 1st level, the initial samples need partitioning into several clusters due to design variables by fuzzy-clustering method. Sequentially, only some of the clusters are involved in building metamodels locally in the 2nd level. Finally, the best optimized result is collected from all metamodels in the 3rd level. The nonlinear problems with multi-humps as test functions are implemented for proving accuracy and efficiency of proposed method. The practical nonlinear engineering problems are optimized by suggested methodology and satisfied results are also obtained. Keywords: Multi-level; Metamodel; Fuzzy clustering: Nonlinear; Kriging interpolation

Published
2008

45. Handling of Constraints in Efficient Global Optimization.

Author

Wang, Hu, Hu, Wei, and Li, Enying

Subjects
GLOBAL optimization, KRIGING, LEAST squares, CONSTRAINED optimization, TEST methods, ALGORITHMS
Abstract

Although the Efficient Global Optimization (EGO) algorithm has been widely used in multi-disciplinary optimization, it is still difficult to handle multiple constraint problems. In this study, to increase the accuracy of approximation, the Least Squares Support Vector Regression (LSSVR) is suggested to replace the kriging model for approximating both objective and constrained functions while the variances of these surrogate models are still obtained by kriging. To enhance the ability to search the feasible region, two criteria are suggested. First, a Maximize Probability of Feasibility (MPF) strategy to handle the infeasible initial sample points is suggested to generate feasible points. Second, a Multi-Constraint Parallel (MCP) criterion is suggested for multiple constraints handling, parallel computation and validation, respectively. To illustrate the efficiency of the suggested EGO-based method, several deterministic benchmarks are tested and the suggested methods demonstrate a superior performance compared with two other constrained algorithms. Finally, the suggested algorithm is successfully utilized to optimize the fiber path of variable-stiffness beam and lightweight B-pillar to demonstrate the performance for engineering applications. [ABSTRACT FROM AUTHOR]

Published
2021
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46. A surrogate assisted thermal optimization framework for design of pin-fin heat sink for the platform inertial navigation system.

Author

Luo, Xin, Li, Enying, and Wang, Hu

Subjects
*HEAT sinks, *INERTIAL navigation systems, *PARTICLE swarm optimization, *GLOBAL optimization, *DIFFERENTIAL evolution, *GLOBAL analysis (Mathematics)
Abstract

In this study, a thermal optimization framework for the platform inertial navigation system (PINS) is built. To reduce the local high temperature of the PINS, a pin-fin heat sink with staggered arrangement is designed. To reduce the dimension of the inputs and improve the optimization efficiency, a feasible global sensitivity analysis (GSA) based on kriging–high-dimensional model representation with DIviding RECTangles (DIRECT-KG-HDMR) sampling strategy is proposed. According to the GSA results, the filtered structural parameters are used to optimize the thermal performance of the heat sink, and several optimization algorithms (genetic algorithm, differential evolution, teaching–learning-based optimization, particle swarm optimization and efficient global optimization) are used for optimization. The steady thermal response of the PINS with the optimized heat sink is also studied, and the result shows that the maximum temperature of the high-temperature region of the platform is reduced by 1.08°C compared with the PINS without the heat sink. [ABSTRACT FROM AUTHOR]

Published
2021
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47. A global sensitivity analysis-assisted sequential optimization tool for plant-fin heat sink design.

Author

Li, Enying, Zhou, Zheng, Wang, Hu, and Cai, Kang

Subjects
*HEAT sinks, *HIGH-dimensional model representation, *GLOBAL optimization, *GLOBAL analysis (Mathematics), *FUSION reactor divertors
Abstract

Purpose: This study aims to suggest and develops a global sensitivity analysis-assisted multi-level sequential optimization method for the heat transfer problem. Design/methodology/approach: Compared with other surrogate-assisted optimization methods, the distinctive characteristic of the suggested method is to decompose the original problem into several layers according to the global sensitivity index. The optimization starts with the several most important design variables by the support vector regression-based efficient global optimization method. Then, when the optimization process progresses, the filtered design variables should be involved in optimization one by one or the setting value. Therefore, in each layer, the design space should be reduced according to the previous optimization result. To improve the accuracy of the global sensitivity index, a novel global sensitivity analysis method based on the variance-based method incorporating a random sampling high-dimensional model representation is introduced. Findings: The advantage of this method lies in its capability to solve complicated problems with a limited number of sample points. Moreover, to enhance the reliability of optimum, the support vector regression-based global efficient optimization is used to optimize in each layer. Practical implications: The developed optimization tool is built by MATLAB and can be integrated by commercial software, such as ABAQUS and COMSOL. Lastly, this tool is integrated with COMSOL and applied to the plant-fin heat sink design. Compared with the initial temperature, the temperature after design is over 49°. Moreover, the relationships among all design variables are also disclosed clearly. Originality/value: The D-MORPH-HDMR is integrated to obtain the coupling relativities among the design variables efficiently. The suggested method can be decomposed into multiplier layers according to the GSI. The SVR-EGO is used to optimize the sub-problem because of its robustness of modeling. [ABSTRACT FROM AUTHOR]

Published
2020
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48. A metamodel optimization methodology based on multi-level fuzzy clustering space reduction strategy and its applications

Author

Guo Li, Li Enying, Z. H. Zhong, and Wang Hu

Subjects
Nonlinear system, Mathematical optimization, Reduction strategy, Fuzzy clustering, General Computer Science, Kriging, General Engineering, Space (mathematics), Metamodeling, Mathematics
Abstract

This paper proposes metamodel optimization methodology based on multi-level fuzzy-clustering space reduction strategy with Kriging interpolation. The proposed methodology is composed of three levels. In the 1st level, the initial samples need partitioning into several clusters due to design variables by fuzzy-clustering method. Sequentially, only some of the clusters are involved in building metamodels locally in the 2nd level. Finally, the best optimized result is collected from all metamodels in the 3rd level. The nonlinear problems with multi-humps as test functions are implemented for proving accuracy and efficiency of proposed method. The practical nonlinear engineering problems are optimized by suggested methodology and satisfied results are also obtained.

Published
2008

49. Optimization of drawbead design in sheet metal forming based on intelligent sampling by using response surface methodology

Author

Li Guang yao, Li Enying, and Wang Hu

Subjects
Engineering, Mathematical optimization, business.industry, Design of experiments, Metals and Alloys, Sampling (statistics), Interval (mathematics), Rosenbrock function, Industrial and Manufacturing Engineering, Finite element method, Computer Science Applications, Engineering optimization, Modeling and Simulation, Ceramics and Composites, Response surface methodology, business, Sequential quadratic programming
Abstract

In this study, the response surface methodology (RSM) was applied for drawbead optimization. Compared with other RSMs, the boundary and best neighbor sampling (BBNS) scheme was introduced for design of experiment (DOE) first. This kind of intelligent method can guarantee the sampling search in right direction in pre-definite interval of design variables space. For validation of developed method, the Rosenbrock function was successfully approximated by methodology; corresponding response surface (RS) appropriateness can be well predicted by analysis of variance (ANOVA). In order to improve the efficiency and accuracy of RSM, especially for nonlinear and large scale problems, a coupled BBNS strategy was suggested for drawbead optimization. In this procedure, one step forming and incremental FEM method are combined for simulation procedures. One step forming method is applied for gathering information from design space and generating initial RS model; incremental FEM method is implemented to correct the RS constructed by samples due to one step forming and build accurate RS model. Finally, a practical engineering optimization problem was implemented with suggested coupled BBNS and obtained good results.

Published
2008

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