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# M++
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# Abstract
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## Abstract
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M++ is designed to approximate PDEs for advanced applications in engineering and physics.
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M++ is designed to approximate PDEs for advanced applications in engineering and physics.
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It supports a wide range of modules for modern finite element discretization methods,
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It supports a wide range of modules for modern finite element discretization methods,
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including discontinuous Galerkin, space-time, multiscale, and uncertainty quantification methods.
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including discontinuous Galerkin, space-time, multiscale, and uncertainty quantification methods.
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... | @@ -9,7 +7,7 @@ large-scale problems on high-performance computing resources. |
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M++ is highly flexible, making it applicable to diverse challenges
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M++ is highly flexible, making it applicable to diverse challenges
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in scientific computing and build the basis for many [publications and PhD projects](https://www.math.kit.edu/ianm3/page/mpp_publikationen).
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in scientific computing and build the basis for many [publications and PhD projects](https://www.math.kit.edu/ianm3/page/mpp_publikationen).
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### Introduction
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# Introduction
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This wiki provides insight to get started with the software as a user in
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This wiki provides insight to get started with the software as a user in
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