A deep learning approach to estimate stress distribution: a fast and accurate surrogate of finite-element analysis
Structural finite-element analysis (FEA) has been widely used to study the biomechanics of
human tissues and organs, as well as tissue–medical device interactions, and treatment …
human tissues and organs, as well as tissue–medical device interactions, and treatment …
[HTML][HTML] A deep learning approach to estimate stress distribution: a fast and accurate surrogate of finite-element analysis
L Liang, M Liu, C Martin, W Sun - Journal of the Royal Society …, 2018 - ncbi.nlm.nih.gov
Structural finite-element analysis (FEA) has been widely used to study the biomechanics of
human tissues and organs, as well as tissue–medical device interactions, and treatment …
human tissues and organs, as well as tissue–medical device interactions, and treatment …
[PDF][PDF] A deep learning approach to estimate stress distribution: a fast and accurate surrogate of finite-element analysis
L Liang, M Liu, C Martin, W Sun - 2018 - researchgate.net
Structural finite-element analysis (FEA) has been widely used to study the biomechanics of
human tissues and organs, as well as tissue–medical device interactions, and treatment …
human tissues and organs, as well as tissue–medical device interactions, and treatment …
A deep learning approach to estimate stress distribution: a fast and accurate surrogate of finite-element analysis
L Liang, M Liu, C Martin, W Sun - Journal of the Royal …, 2018 - scholarship.miami.edu
Structural finite-element analysis (FEA) has been widely used to study the biomechanics of
human tissues and organs, as well as tissue-medical device interactions, and treatment …
human tissues and organs, as well as tissue-medical device interactions, and treatment …
A deep learning approach to estimate stress distribution: a fast and accurate surrogate of finite-element analysis.
L Liang, M Liu, C Martin, W Sun - Journal of the Royal Society …, 2018 - europepmc.org
Structural finite-element analysis (FEA) has been widely used to study the biomechanics of
human tissues and organs, as well as tissue–medical device interactions, and treatment …
human tissues and organs, as well as tissue–medical device interactions, and treatment …
[PDF][PDF] A deep learning approach to estimate stress distribution: a fast and accurate surrogate of finite-element analysis
L Liang, M Liu, C Martin, W Sun - 2018 - scholar.archive.org
Structural finite-element analysis (FEA) has been widely used to study the biomechanics of
human tissues and organs, as well as tissue–medical device interactions, and treatment …
human tissues and organs, as well as tissue–medical device interactions, and treatment …
A deep learning approach to estimate stress distribution: a fast and accurate surrogate of finite-element analysis
L Liang, M Liu, C Martin, W Sun - Journal of The Royal Society Interface, 2018 - cir.nii.ac.jp
抄録< jats: p> Structural finite-element analysis (FEA) has been widely used to study the
biomechanics of human tissues and organs, as well as tissue–medical device interactions …
biomechanics of human tissues and organs, as well as tissue–medical device interactions …
A deep learning approach to estimate stress distribution: a fast and accurate surrogate of finite-element analysis
L Liang, M Liu, C Martin, W Sun - Journal of the Royal …, 2018 - pubmed.ncbi.nlm.nih.gov
Structural finite-element analysis (FEA) has been widely used to study the biomechanics of
human tissues and organs, as well as tissue-medical device interactions, and treatment …
human tissues and organs, as well as tissue-medical device interactions, and treatment …