Search alternatives:
structure optimization » structural optimization (Expand Search), structure determination (Expand Search)
based optimization » whale optimization (Expand Search)
final factor » fill factor (Expand Search), viral factors (Expand Search), total factor (Expand Search)
binary wave » binary image (Expand Search)
wave based » made based (Expand Search), game based (Expand Search), rate based (Expand Search)
structure optimization » structural optimization (Expand Search), structure determination (Expand Search)
based optimization » whale optimization (Expand Search)
final factor » fill factor (Expand Search), viral factors (Expand Search), total factor (Expand Search)
binary wave » binary image (Expand Search)
wave based » made based (Expand Search), game based (Expand Search), rate based (Expand Search)
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Internal structure of GRU.
Published 2024“…Features of components by decomposition are described as feature vectors based on values of fuzzy entropy and autocorrelation coefficient, through which those components are divided into two groups using cluster algorithm for prediction with two sub models. Optimized online sequential extreme learning machine and the deep learning model based on encoder-decoder structure using self-attention are developed as sub models to predict the grouped data, and the final predicted production comes from the sum of prediction values by sub models. …”
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Artificial Intelligence-Guided Inverse Design of Deployable Thermo-Metamaterial Implants
Published 2025“…We begin by generating a large database of corrugated thermo-metamaterials with various cell structures and bending stiffnesses. An artificial intelligence inverse design model is subsequently developed by integrating an evolutionary algorithm with a neural network. …”
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Artificial Intelligence-Guided Inverse Design of Deployable Thermo-Metamaterial Implants
Published 2025“…We begin by generating a large database of corrugated thermo-metamaterials with various cell structures and bending stiffnesses. An artificial intelligence inverse design model is subsequently developed by integrating an evolutionary algorithm with a neural network. …”
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Artificial Intelligence-Guided Inverse Design of Deployable Thermo-Metamaterial Implants
Published 2025“…We begin by generating a large database of corrugated thermo-metamaterials with various cell structures and bending stiffnesses. An artificial intelligence inverse design model is subsequently developed by integrating an evolutionary algorithm with a neural network. …”
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Artificial Intelligence-Guided Inverse Design of Deployable Thermo-Metamaterial Implants
Published 2025“…We begin by generating a large database of corrugated thermo-metamaterials with various cell structures and bending stiffnesses. An artificial intelligence inverse design model is subsequently developed by integrating an evolutionary algorithm with a neural network. …”
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Artificial Intelligence-Guided Inverse Design of Deployable Thermo-Metamaterial Implants
Published 2025“…We begin by generating a large database of corrugated thermo-metamaterials with various cell structures and bending stiffnesses. An artificial intelligence inverse design model is subsequently developed by integrating an evolutionary algorithm with a neural network. …”
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Artificial Intelligence-Guided Inverse Design of Deployable Thermo-Metamaterial Implants
Published 2025“…We begin by generating a large database of corrugated thermo-metamaterials with various cell structures and bending stiffnesses. An artificial intelligence inverse design model is subsequently developed by integrating an evolutionary algorithm with a neural network. …”
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