Rodolà, E.Cosmo, L.Bronstein, M. M.Torsello, A.Cremers, D.Chen, Min and Zhang, Hao (Richard)2017-03-132017-03-1320171467-8659https://doi.org/10.1111/cgf.12797https://diglib.eg.org:443/handle/10.1111/cgf12797In this paper, we propose a method for computing partial functional correspondence between non‐rigid shapes. We use perturbation analysis to show how removal of shape parts changes the Laplace–Beltrami eigenfunctions, and exploit it as a prior on the spectral representation of the correspondence. Corresponding parts are optimization variables in our problem and are used to weight the functional correspondence; we are looking for the largest and most regular (in the Mumford–Shah sense) parts that minimize correspondence distortion. We show that our approach can cope with very challenging correspondence settings.In this paper, we propose a method for computing partial functional correspondence between non‐rigid shapes. We use perturbation analysis to show how removal of shape parts changes the Laplace‐Beltrami eigenfunctions, and exploit it as a prior on the spectral representation of the correspondence. Corresponding parts are optimization variables in our problem and are used to weight the functional correspondence; we are looking for the largest and most regular (in the Mumford‐Shah sense) parts that minimize correspondence distortion. We show that our approach can cope with very challenging correspondence settings.shape matchingpartial similarityfunctional mapsI.3.5 [Computational Graphics]: Computational Geometry and Object Modelling‐Shape Analysis10.1111/cgf.12797