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Hauptverfasser: Li, Chenhao, Ono, Taishi, Uemori, Takeshi, Nitta, Sho, Mihara, Hajime, Gatto, Alexander, Nagahara, Hajime, Moriuchi, Yusuke
Format: Preprint
Veröffentlicht: 2024
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Online-Zugang:https://arxiv.org/abs/2411.10189
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author Li, Chenhao
Ono, Taishi
Uemori, Takeshi
Nitta, Sho
Mihara, Hajime
Gatto, Alexander
Nagahara, Hajime
Moriuchi, Yusuke
author_facet Li, Chenhao
Ono, Taishi
Uemori, Takeshi
Nitta, Sho
Mihara, Hajime
Gatto, Alexander
Nagahara, Hajime
Moriuchi, Yusuke
contents Recent inverse rendering methods have greatly improved shape, material, and illumination reconstruction by utilizing polarization cues. However, existing methods only support dielectrics, ignoring conductors that are found everywhere in life. Since conductors and dielectrics have different reflection properties, using previous conductor methods will lead to obvious errors. In addition, conductors are glossy, which may cause strong specular reflection and is hard to reconstruct. To solve the above issues, we propose NeISF++, an inverse rendering pipeline that supports conductors and dielectrics. The key ingredient for our proposal is a general pBRDF that describes both conductors and dielectrics. As for the strong specular reflection problem, we propose a novel geometry initialization method using DoLP images. This physical cue is invariant to intensities and thus robust to strong specular reflections. Experimental results on our synthetic and real datasets show that our method surpasses the existing polarized inverse rendering methods for geometry and material decomposition as well as downstream tasks like relighting.
format Preprint
id arxiv_https___arxiv_org_abs_2411_10189
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle NeISF++: Neural Incident Stokes Field for Polarized Inverse Rendering of Conductors and Dielectrics
Li, Chenhao
Ono, Taishi
Uemori, Takeshi
Nitta, Sho
Mihara, Hajime
Gatto, Alexander
Nagahara, Hajime
Moriuchi, Yusuke
Computer Vision and Pattern Recognition
Recent inverse rendering methods have greatly improved shape, material, and illumination reconstruction by utilizing polarization cues. However, existing methods only support dielectrics, ignoring conductors that are found everywhere in life. Since conductors and dielectrics have different reflection properties, using previous conductor methods will lead to obvious errors. In addition, conductors are glossy, which may cause strong specular reflection and is hard to reconstruct. To solve the above issues, we propose NeISF++, an inverse rendering pipeline that supports conductors and dielectrics. The key ingredient for our proposal is a general pBRDF that describes both conductors and dielectrics. As for the strong specular reflection problem, we propose a novel geometry initialization method using DoLP images. This physical cue is invariant to intensities and thus robust to strong specular reflections. Experimental results on our synthetic and real datasets show that our method surpasses the existing polarized inverse rendering methods for geometry and material decomposition as well as downstream tasks like relighting.
title NeISF++: Neural Incident Stokes Field for Polarized Inverse Rendering of Conductors and Dielectrics
topic Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2411.10189