Thermal Spread Functions (TSF): Physics-Guided Material Classification

Aniket Dashpute; Vishwanath Saragadam; Emma Alexander; Florian Willomitzer; Aggelos Katsaggelos; Ashok Veeraraghavan; Oliver Cossairt

doi:10.1109/CVPR52729.2023.00164

Thermal Spread Functions (TSF): Physics-Guided Material Classification

Aniket Dashpute, Vishwanath Saragadam, Emma Alexander, Florian Willomitzer, Aggelos Katsaggelos, Ashok Veeraraghavan, Oliver Cossairt

Research output: Contribution to journal › Conference article › peer-review

6 Scopus citations

Abstract

Robust and non-destructive material classification is a challenging but crucial first-step in numerous vision applications. We propose a physics-guided material classification framework that relies on thermal properties of the object. Our key observation is that the rate of heating and cooling of an object depends on the unique intrinsic properties of the material, namely the emissivity and diffusivity. We leverage this observation by gently heating the objects in the scene with a low-power laser for a fixed duration and then turning it off, while a thermal camera captures measurements during the heating and cooling process. We then take this spatial and temporal 'thermal spread function' (TSF) to solve an inverse heat equation using the finite-differences approach, resulting in a spatially varying estimate of diffusivity and emissivity. These tuples are then used to train a classifier that produces a fine-grained material label at each spatial pixel. Our approach is extremely simple requiring only a small light source (low power laser) and a thermal camera, and produces robust classification results with 86% accuracy over 16 classes.

Original language	English (US)
Pages (from-to)	1641-1650
Number of pages	10
Journal	Proceedings of the IEEE Computer Society Conference on Computer Vision and Pattern Recognition
Volume	2023-June
DOIs	https://doi.org/10.1109/CVPR52729.2023.00164
State	Published - 2023
Event	2023 IEEE/CVF Conference on Computer Vision and Pattern Recognition, CVPR 2023 - Vancouver, Canada Duration: Jun 18 2023 → Jun 22 2023

Funding

This work was supported by NSF awards IIS-2107313 and IIS-1730574, and ONR award N00014-21-1-2035. We thank Manuel Ballester for his help in formulating numerical methods for the heat equation, Rishubh Parihar for discussion on optimization, and Lionel Fiske for discussion on PDE solutions. We also thank the reviewers for their valuable suggestions to improve the quality of the manuscript.

Keywords

Computational imaging

ASJC Scopus subject areas

Software
Computer Vision and Pattern Recognition

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10.1109/CVPR52729.2023.00164

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abstract = "Robust and non-destructive material classification is a challenging but crucial first-step in numerous vision applications. We propose a physics-guided material classification framework that relies on thermal properties of the object. Our key observation is that the rate of heating and cooling of an object depends on the unique intrinsic properties of the material, namely the emissivity and diffusivity. We leverage this observation by gently heating the objects in the scene with a low-power laser for a fixed duration and then turning it off, while a thermal camera captures measurements during the heating and cooling process. We then take this spatial and temporal 'thermal spread function' (TSF) to solve an inverse heat equation using the finite-differences approach, resulting in a spatially varying estimate of diffusivity and emissivity. These tuples are then used to train a classifier that produces a fine-grained material label at each spatial pixel. Our approach is extremely simple requiring only a small light source (low power laser) and a thermal camera, and produces robust classification results with 86% accuracy over 16 classes.",

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year = "2023",

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AU - Katsaggelos, Aggelos

AU - Veeraraghavan, Ashok

AU - Cossairt, Oliver

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N2 - Robust and non-destructive material classification is a challenging but crucial first-step in numerous vision applications. We propose a physics-guided material classification framework that relies on thermal properties of the object. Our key observation is that the rate of heating and cooling of an object depends on the unique intrinsic properties of the material, namely the emissivity and diffusivity. We leverage this observation by gently heating the objects in the scene with a low-power laser for a fixed duration and then turning it off, while a thermal camera captures measurements during the heating and cooling process. We then take this spatial and temporal 'thermal spread function' (TSF) to solve an inverse heat equation using the finite-differences approach, resulting in a spatially varying estimate of diffusivity and emissivity. These tuples are then used to train a classifier that produces a fine-grained material label at each spatial pixel. Our approach is extremely simple requiring only a small light source (low power laser) and a thermal camera, and produces robust classification results with 86% accuracy over 16 classes.

AB - Robust and non-destructive material classification is a challenging but crucial first-step in numerous vision applications. We propose a physics-guided material classification framework that relies on thermal properties of the object. Our key observation is that the rate of heating and cooling of an object depends on the unique intrinsic properties of the material, namely the emissivity and diffusivity. We leverage this observation by gently heating the objects in the scene with a low-power laser for a fixed duration and then turning it off, while a thermal camera captures measurements during the heating and cooling process. We then take this spatial and temporal 'thermal spread function' (TSF) to solve an inverse heat equation using the finite-differences approach, resulting in a spatially varying estimate of diffusivity and emissivity. These tuples are then used to train a classifier that produces a fine-grained material label at each spatial pixel. Our approach is extremely simple requiring only a small light source (low power laser) and a thermal camera, and produces robust classification results with 86% accuracy over 16 classes.

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Thermal Spread Functions (TSF): Physics-Guided Material Classification

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