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Bibliographic Details
Main Authors: Huang, Erqi, Restrepo, John, Cao, Xun, Ihrke, Ivo
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2509.01070
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author Huang, Erqi
Restrepo, John
Cao, Xun
Ihrke, Ivo
author_facet Huang, Erqi
Restrepo, John
Cao, Xun
Ihrke, Ivo
contents Snapshot Multispectral Light-field Imaging (SMLI) is an emerging computational imaging technique that captures high-dimensional data (x, y, z, $θ$, $ϕ$, $λ$) in a single shot using a low-dimensional sensor. The accuracy of high-dimensional data reconstruction depends on representing the spectrum using neural radiance field models, which requires consideration of broadband spectral decoupling during optimization. Currently, some SMLI approaches avoid the challenge of model decoupling by either reducing light-throughput or prolonging imaging time. In this work, we propose a broadband spectral neural radiance field (BSNeRF) for SMLI systems. Experiments show that our model successfully decouples a broadband multiplexed spectrum. Consequently, this approach enhances multispectral light-field image reconstruction and further advances plenoptic imaging.
format Preprint
id arxiv_https___arxiv_org_abs_2509_01070
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle BSNeRF: Broadband Spectral Neural Radiance Fields for Snapshot Multispectral Light-field Imaging
Huang, Erqi
Restrepo, John
Cao, Xun
Ihrke, Ivo
Signal Processing
Snapshot Multispectral Light-field Imaging (SMLI) is an emerging computational imaging technique that captures high-dimensional data (x, y, z, $θ$, $ϕ$, $λ$) in a single shot using a low-dimensional sensor. The accuracy of high-dimensional data reconstruction depends on representing the spectrum using neural radiance field models, which requires consideration of broadband spectral decoupling during optimization. Currently, some SMLI approaches avoid the challenge of model decoupling by either reducing light-throughput or prolonging imaging time. In this work, we propose a broadband spectral neural radiance field (BSNeRF) for SMLI systems. Experiments show that our model successfully decouples a broadband multiplexed spectrum. Consequently, this approach enhances multispectral light-field image reconstruction and further advances plenoptic imaging.
title BSNeRF: Broadband Spectral Neural Radiance Fields for Snapshot Multispectral Light-field Imaging
topic Signal Processing
url https://arxiv.org/abs/2509.01070