Topology and ma- terial optimization in ultra-soft magneto-active structures: Making advantage of residual anisotropies.Advanced Materials, n/a(n/a):e18489

Carlos Perez-Garcia, Rogelio Ortigosa, Jes ´us Mart´ınez-Frutos, Daniel Garcia-Gonzalez

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Multiscale topology optimization of compressible and nearly incompressible anisotropic hyperelastic structures using physics-augmented neural networks

cs.CE · 2026-04-07 · unverdicted · novelty 7.0

Physics-augmented neural networks act as stable, thermodynamically consistent surrogates for microscale problems, enabling simultaneous optimization of macroscale material layout and microscale descriptors in nonlinear finite-strain anisotropic hyperelastic structures.

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Multiscale topology optimization of compressible and nearly incompressible anisotropic hyperelastic structures using physics-augmented neural networks cs.CE · 2026-04-07 · unverdicted · none · ref 18
Physics-augmented neural networks act as stable, thermodynamically consistent surrogates for microscale problems, enabling simultaneous optimization of macroscale material layout and microscale descriptors in nonlinear finite-strain anisotropic hyperelastic structures.

Topology and ma- terial optimization in ultra-soft magneto-active structures: Making advantage of residual anisotropies.Advanced Materials, n/a(n/a):e18489

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