Saved in:
Bibliographic Details
Main Authors: Shin, Suhyun, Moon, Yunseong, Maeda, Ryota, Lindell, David, Kutulacos, Kyros, Baek, Seung-Hwan
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2605.25757
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866916044774309888
author Shin, Suhyun
Moon, Yunseong
Maeda, Ryota
Lindell, David
Kutulacos, Kyros
Baek, Seung-Hwan
author_facet Shin, Suhyun
Moon, Yunseong
Maeda, Ryota
Lindell, David
Kutulacos, Kyros
Baek, Seung-Hwan
contents Hyperspectral 3D imaging enables the capture of dense spectral information and scene geometry but has traditionally been confined to narrow spectral windows, typically the visible range. In this work, we introduce a broadband hyperspectral 3D imaging (BH3D) method to extend this capability across the full visible-near-infrared and short-wavelength infrared (SWIR) spectrum (450-1500 nm). This broad coverage is critical as it captures complementary physical cues: visible wavelengths reveal surface appearance, while SWIR bands provide insight into subsurface properties and material composition. However, realizing BH3D is challenging due to fundamental sensor constraints between visible-spectrum silicon and SWIR-spectrum InGaAs sensors, which necessitate complex multi-spectrograph designs. Here we propose a single-spectrograph BH3D system, using a stereo setup comprising visible and SWIR cameras, that reconstructs dense broadband hyperspectral reflectance together with accurate 3D geometry. Our key idea is to extend dispersed structured light to the broadband regime using a single spectrograph. We model the image formation of broadband dispersed structured light, and estimate hyperspectral reflectance and depth. We validate our approach on diverse real-world scenes, demonstrating accurate reconstruction with a mean spectral angle mapper of 0.13 rad, root mean square error of 0.03, and mean depth error of 4.5 mm. We further demonstrate identifying metameric materials, performing imaging through opaque layers, uncovering hidden features on banknotes, and revealing blood vessels.
format Preprint
id arxiv_https___arxiv_org_abs_2605_25757
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Broadband Hyperspectral 3D Imaging using Dispersed Structured Light
Shin, Suhyun
Moon, Yunseong
Maeda, Ryota
Lindell, David
Kutulacos, Kyros
Baek, Seung-Hwan
Computer Vision and Pattern Recognition
Hyperspectral 3D imaging enables the capture of dense spectral information and scene geometry but has traditionally been confined to narrow spectral windows, typically the visible range. In this work, we introduce a broadband hyperspectral 3D imaging (BH3D) method to extend this capability across the full visible-near-infrared and short-wavelength infrared (SWIR) spectrum (450-1500 nm). This broad coverage is critical as it captures complementary physical cues: visible wavelengths reveal surface appearance, while SWIR bands provide insight into subsurface properties and material composition. However, realizing BH3D is challenging due to fundamental sensor constraints between visible-spectrum silicon and SWIR-spectrum InGaAs sensors, which necessitate complex multi-spectrograph designs. Here we propose a single-spectrograph BH3D system, using a stereo setup comprising visible and SWIR cameras, that reconstructs dense broadband hyperspectral reflectance together with accurate 3D geometry. Our key idea is to extend dispersed structured light to the broadband regime using a single spectrograph. We model the image formation of broadband dispersed structured light, and estimate hyperspectral reflectance and depth. We validate our approach on diverse real-world scenes, demonstrating accurate reconstruction with a mean spectral angle mapper of 0.13 rad, root mean square error of 0.03, and mean depth error of 4.5 mm. We further demonstrate identifying metameric materials, performing imaging through opaque layers, uncovering hidden features on banknotes, and revealing blood vessels.
title Broadband Hyperspectral 3D Imaging using Dispersed Structured Light
topic Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2605.25757