Low-dimensional solution-processable electronics

A novel transfer bees optimizer for reactive power optimization in a high-power system was developed in this paper. Q-learning was adopted to construct the learning mode of bees, improving the intelligence of bees through task division and cooperation. Behavior transfer was introduced, and prior knowledge of the source task was used to process the new task according to its similarity to the source task, so as to accelerate the convergence of the transfer bees optimizer. Moreover, the solution space was decomposed into multiple low-dimensional solution spaces via associated state-action chains. The transfer bees optimizer performance of reactive power optimization was assessed, while simulation results showed that the convergence of the proposed algorithm was more stable and faster, and the algorithm was about 4 to 68 times faster than the traditional artificial intelligence algorithms.

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Enhancing hierarchical surrogate-assisted evolutionary algorithm for high-dimensional expensive optimization via random projection

Complex & Intelligent Systems ◽

10.1007/s40747-021-00484-w ◽

2021 ◽

Author(s):

Xiaodong Ren ◽

Daofu Guo ◽

Zhigang Ren ◽

Yongsheng Liang ◽

An Chen

Keyword(s):

Optimization Problems ◽

Solution Space ◽

Random Projection ◽

Surrogate Models ◽

High Dimensional ◽

Local Models ◽

Dimensional Solution ◽

Training Samples ◽

Low Dimensional ◽

Expensive Optimization

AbstractBy remarkably reducing real fitness evaluations, surrogate-assisted evolutionary algorithms (SAEAs), especially hierarchical SAEAs, have been shown to be effective in solving computationally expensive optimization problems. The success of hierarchical SAEAs mainly profits from the potential benefit of their global surrogate models known as “blessing of uncertainty” and the high accuracy of local models. However, their performance leaves room for improvement on high-dimensional problems since now it is still challenging to build accurate enough local models due to the huge solution space. Directing against this issue, this study proposes a new hierarchical SAEA by training local surrogate models with the help of the random projection technique. Instead of executing training in the original high-dimensional solution space, the new algorithm first randomly projects training samples onto a set of low-dimensional subspaces, then trains a surrogate model in each subspace, and finally achieves evaluations of candidate solutions by averaging the resulting models. Experimental results on seven benchmark functions of 100 and 200 dimensions demonstrate that random projection can significantly improve the accuracy of local surrogate models and the new proposed hierarchical SAEA possesses an obvious edge over state-of-the-art SAEAs.

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Subnaphthalocyanine triimides: potential three-dimensional solution processable acceptors for organic solar cells

Journal of Materials Chemistry C ◽

10.1039/c9tc06238f ◽

2020 ◽

Vol 8 (6) ◽

pp. 2186-2195

Author(s):

Chunsheng Cai ◽

Shanshan Chen ◽

Li Li ◽

Zhongyi Yuan ◽

Xiaohong Zhao ◽

...

Keyword(s):

Solar Cells ◽

Organic Solar Cells ◽

High Performance ◽

Three Dimensional ◽

Electron Acceptors ◽

Dimensional Solution ◽

Solution Processable

Three-dimensional SubNcTIs are excellent chromophores of solution processable electron acceptors towards high performance organic solar cells.

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A Semi-Analytical Method to Calculate the Consolidation Problem of the Soilbag Filled with Mud Soil Buried with PVD

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.638-640.345 ◽

2014 ◽

Vol 638-640 ◽

pp. 345-349 ◽

Cited By ~ 1

Author(s):

Ben Niu ◽

Chao Jie Zhang ◽

Xiu Liang Chen ◽

Heng Yu Wang

Keyword(s):

Analytical Method ◽

Lab Experiment ◽

Dimensional Solution ◽

Test Base ◽

Body Model ◽

Low Dimension ◽

Rectangular Area ◽

Degree Of Consolidation ◽

Low Dimensional

A semi-analytical method to calculate the degree of consolidation of the soilbag filled with mud soil with PVD built in is proposed. First a unit-body model is founded to obtain the low-dimensional solution. Through the successive iterations of the low-dimension solution, the solution considering the situation when the physical or geometry parameters of the model vary is finally obtained. The solution of the rectangular area is obtained by summing solutions of two square area with coefficients set. A lab experiment was done in Liubao test base of Zhejiang institute of hydraulics and estuary to research the consolidation performance of soilbag filled with mud soil buried with PVD. The semi-analytical method and FEM are applied to calculate the lab experiment case. From the comparison among the lab experiment, the semi-analytical method and FEM, it shows that the semi-analytical method calculates a good result of the degree of consolidation of the lab experiment.

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Learning physics-based models from data: perspectives from inverse problems and model reduction

Acta Numerica ◽

10.1017/s0962492921000064 ◽

2021 ◽

Vol 30 ◽

pp. 445-554

Author(s):

Omar Ghattas ◽

Karen Willcox

Keyword(s):

Inverse Problems ◽

Model Reduction ◽

Large Scale ◽

Dimensional Subspace ◽

Dimensional Solution ◽

Scale Models ◽

Recent Developments ◽

Engineered Systems ◽

Low Dimensional ◽

Solution Manifold

This article addresses the inference of physics models from data, from the perspectives of inverse problems and model reduction. These fields develop formulations that integrate data into physics-based models while exploiting the fact that many mathematical models of natural and engineered systems exhibit an intrinsically low-dimensional solution manifold. In inverse problems, we seek to infer uncertain components of the inputs from observations of the outputs, while in model reduction we seek low-dimensional models that explicitly capture the salient features of the input–output map through approximation in a low-dimensional subspace. In both cases, the result is a predictive model that reflects data-driven learning yet deeply embeds the underlying physics, and thus can be used for design, control and decision-making, often with quantified uncertainties. We highlight recent developments in scalable and efficient algorithms for inverse problems and model reduction governed by large-scale models in the form of partial differential equations. Several illustrative applications to large-scale complex problems across different domains of science and engineering are provided.

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