Data-driven Morozov regularization of inverse problems

The solution of inverse problems is central to a wide range of applications including medicine, biology, and engineering. These problems require finding a desired solution in the presence of noisy observations. A key feature of inverse problems is their ill-posedness, which leads to unstable behavior under noise when standard solution methods are used. For this reason, regularization methods have been developed that compromise between data fitting and prior structure. Recently, data-driven variational regularization methods have been introduced, where the prior in the form of a regularizer is derived from provided ground truth data. However, these methods have mainly been analyzed for Tikhonov regularization, referred to as Network Tikhonov Regularization (NETT). In this paper, we propose and analyze Morozov regularization in combination with a learned regularizer. The regularizers, which can be adapted to the training data, are defined by neural networks and are therefore non-convex. We give a convergence analysis in the non-convex setting allowing noise-dependent regularizers, and propose a possible training strategy. We present numerical results for attenuation correction in the context of photoacoustic tomography.