%0 Conference Paper %1 2020-chang %A Shu, Chang %A Yu, Kun %A Duan, Zhixiang %A Yang, Kuiyuan %B Computer Vision -- ECCV 2020 %C Cham %D 2020 %E Vedaldi, Andrea %E Bischof, Horst %E Brox, Thomas %E Frahm, Jan-Michael %I Springer International Publishing %K depth estimation feature-metric loss monocular self-supervised %P 572--588 %T Feature-Metric Loss for Self-supervised Learning of Depth and Egomotion %X Photometric loss is widely used for self-supervised depth and egomotion estimation. However, the loss landscapes induced by photometric differences are often problematic for optimization, caused by plateau landscapes for pixels in textureless regions or multiple local minima for less discriminative pixels. In this work, feature-metric loss is proposed and defined on feature representation, where the feature representation is also learned in a self-supervised manner and regularized by both first-order and second-order derivatives to constrain the loss landscapes to form proper convergence basins. Comprehensive experiments and detailed analysis via visualization demonstrate the effectiveness of the proposed feature-metric loss. In particular, our method improves state-of-the-art methods on KITTI from 0.885 to 0.925 measured by \$\$\backslashdelta \_1\$\$$\delta$1for depth estimation, and significantly outperforms previous method for visual odometry. %@ 978-3-030-58529-7

@inproceedings{2020-chang, abstract = {Photometric loss is widely used for self-supervised depth and egomotion estimation. However, the loss landscapes induced by photometric differences are often problematic for optimization, caused by plateau landscapes for pixels in textureless regions or multiple local minima for less discriminative pixels. In this work, feature-metric loss is proposed and defined on feature representation, where the feature representation is also learned in a self-supervised manner and regularized by both first-order and second-order derivatives to constrain the loss landscapes to form proper convergence basins. Comprehensive experiments and detailed analysis via visualization demonstrate the effectiveness of the proposed feature-metric loss. In particular, our method improves state-of-the-art methods on KITTI from 0.885 to 0.925 measured by {\$}{\$}{\backslash}delta {\_}1{\$}{\$}$\delta$1for depth estimation, and significantly outperforms previous method for visual odometry.}, added-at = {2021-07-06T20:49:35.000+0200}, address = {Cham}, author = {Shu, Chang and Yu, Kun and Duan, Zhixiang and Yang, Kuiyuan}, biburl = {https://www.bibsonomy.org/bibtex/2ff3fca7db4dfd1e39e71e930fdb7334d/pkoch}, booktitle = {Computer Vision -- ECCV 2020}, editor = {Vedaldi, Andrea and Bischof, Horst and Brox, Thomas and Frahm, Jan-Michael}, interhash = {f49c3a6d5c4f506cd560bbf4393b7b34}, intrahash = {ff3fca7db4dfd1e39e71e930fdb7334d}, isbn = {978-3-030-58529-7}, keywords = {depth estimation feature-metric loss monocular self-supervised}, pages = {572--588}, publisher = {Springer International Publishing}, timestamp = {2021-07-06T20:49:35.000+0200}, title = {Feature-Metric Loss for Self-supervised Learning of Depth and Egomotion}, year = 2020 }