Litcius/Paper detail

Total Deep Variation: A Stable Regularization Method for Inverse Problems

Erich Kobler, Alexander Effland, Karl Kunisch, Thomas Pock

2021IEEE Transactions on Pattern Analysis and Machine Intelligence31 citationsDOI

Abstract

Various problems in computer vision and medical imaging can be cast as inverse problems. A frequent method for solving inverse problems is the variational approach, which amounts to minimizing an energy composed of a data fidelity term and a regularizer. Classically, handcrafted regularizers are used, which are commonly outperformed by state-of-the-art deep learning approaches. In this work, we combine the variational formulation of inverse problems with deep learning by introducing the data-driven general-purpose total deep variation regularizer. In its core, a convolutional neural network extracts local features on multiple scales and in successive blocks. This combination allows for a rigorous mathematical analysis including an optimal control formulation of the training problem in a mean-field setting and a stability analysis with respect to the initial values and the parameters of the regularizer. In addition, we experimentally verify the robustness against adversarial attacks and numerically derive upper bounds for the generalization error. Finally, we achieve state-of-the-art results for several imaging tasks.

Topics & Concepts

Computer scienceInverse problemConvolutional neural networkRegularization (linguistics)Robustness (evolution)Deep learningArtificial intelligenceMathematical optimizationAlgorithmMathematicsGeneBiochemistryChemistryMathematical analysisMedical Imaging Techniques and ApplicationsAdvanced X-ray and CT ImagingSparse and Compressive Sensing Techniques