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Award ID contains: 2053760

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  1. ; ; ; ; ; ; ; ; ; ; et al (, Computer-Aided Design)
    Free, publicly-accessible full text available July 1, 2025
  2. ; ; ; ; ; ; (, Engineering with Computers)
    Free, publicly-accessible full text available April 10, 2025
  3. ; ; ; ; ; (, Computer Methods in Applied Mechanics and Engineering)
    Full Text Available 
  4. ; ; ; ; ; ; ; ; (, Chemistry of Materials)
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  5. ; ; ; ; (, 2023 IEEE International Parallel and Distributed Processing Symposium (IPDPS))
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  6. ; ; ; ; ; (, Computer Methods in Applied Mechanics and Engineering)
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  7. ; ; ; ; ; ; ; (, ACS Macro Letters)
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  8. ; ; ; ; ; (, Computer-Aided Design)
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  9. ; ; ; ; ; ; ; ; (, Advanced Functional Materials)
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  10. ; ; ; ; ; ; ; ; (, Advances in neural information processing systems)
    The paradigm of differentiable programming has significantly enhanced the scope of machine learning via the judicious use of gradient-based optimization. However, standard differentiable programming methods (such as autodiff) typically require that the machine learning models be differentiable, limiting their applicability. Our goal in this paper is to use a new, principled approach to extend gradient-based optimization to functions well modeled by splines, which encompass a large family of piecewise polynomial models. We derive the form of the (weak) Jacobian of such functions and show that it exhibits a block-sparse structure that can be computed implicitly and efficiently. Overall, we show that leveraging this redesigned Jacobian in the form of a differentiable" layer''in predictive models leads to improved performance in diverse applications such as image segmentation, 3D point cloud reconstruction, and finite element analysis. We also open-source the code at\url {https://github. com/idealab-isu/DSA}. 
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