Tuning the regularization hyperparameter α in inverse problems has
been a longstanding problem. This is particularly true in the case of fetal
brain magnetic resonance imaging, where an isotropic high-resolution volume is
reconstructed from motion-corrupted low-resolution series of two-dimensional
thick slices. Indeed, the lack of ground truth images makes challenging the
adaptation of α to a given setting of interest in a quantitative manner.
In this work, we propose a simulation-based approach to tune α for a
given acquisition setting. We focus on the influence of the magnetic field
strength and availability of input low-resolution images on the ill-posedness
of the problem. Our results show that the optimal α, chosen as the one
maximizing the similarity with the simulated reference image, significantly
improves the super-resolution reconstruction accuracy compared to the generally
adopted default regularization values, independently of the selected pipeline.
Qualitative validation on clinical data confirms the importance of tuning this
parameter to the targeted clinical image setting.Comment: 11 pages. This work has been submitted to MICCAI 202