An adaptive parameterization for efficient material acquisition and rendering

Dupuy, Jonathan; Jakob, Wenzel

doi:10.1145/3272127.3275059

Cited by 75 publications

(73 citation statements)

References 30 publications

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“…Please note that, once itted to the ABC model, the appearance of some measured materials in the MERL dataset might not be faithfully reproduced [46]; similar considerations apply to any current analytical BRDF model [37]. Several works have pointed out a number of measurement artifacts in the MERL database, such as optical aberrations, discontinuities, and extrapolation artifacts for data above 75 degrees [24,45,66], which cause the measured materials in the MERL dataset to difer from the physical counterpart. Such artifacts explain in part the diiculty to faithfully reproduce the appearance of some materials in the MERL dataset, and highlight the importance of using a gamut beyond the one deined by the dataset itself.…”

Section: Brdf Modelmentioning

confidence: 99%

“…Apart from color, most of these models separate relectance into difuse (following Lambert's law [56]) and specular dimensions and have parameters controlling the their angular distributions [14,29,37]. Alternative approaches use measured BRDF data, for instance from existing datasets such as MERL [64], UTIA [27] and RGL [23], to convert BRDFs into products of compact non-parametric lower-dimensional factors [6], or to derive low-dimensional embeddings, in which the manifold representation can be used for rendering [89].…”

Section: Introductionmentioning

confidence: 99%

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Three Perceptual Dimensions for Specular and Diffuse Reflection

Toscani

Guarnera

et al. 2020

ACM Trans. Appl. Percept.

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Previous research investigated the perceptual dimensionality of achromatic relection of opaque surfaces, by using either simple analytic models of relection, or measured relection properties of a limited sample of materials. Here we aim to extend this work to a broader range of simulated materials. In a irst experiment, we used sparse multidimensional scaling techniques to represent a set of rendered stimuli in a perceptual space that is consistent with participants' similarity judgments. Participants were presented with one reference object and four comparisons, rendered with diferent material properties. They were asked to rank the comparisons according to their similarity to the reference, resulting in an eicient collection of a large number of similarity judgments. In order to interpret the space individuated by multidimensional scaling, we ran a second experiment in which observers were asked to rate our experimental stimuli according to a list of 30 adjectives referring to their surface relectance properties. Our results suggest that perception of achromatic relection is based on at least three dimensions, which we labelled łLightnessž, łGlossž and łMetallicityž, in accordance with the rating results. These dimensions are characterized by a relatively simple relationship with the parameters of the physically based rendering model used to generate our stimuli, indicating that they correspond to diferent physical properties of the rendered materials. Speciically, łLightnessž relates to difuse relections, łGlossž to the presence of high contrast sharp specular highlights and łMetallicityž to spread out specular relections.

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Section: Brdf Modelmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Three Perceptual Dimensions for Specular and Diffuse Reflection

Toscani

Guarnera

et al. 2020

ACM Trans. Appl. Percept.

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“…Our model could potentially be used as a feature extractor, or as a baseline for transferlearning [Sharif Razavian et al 2014;Yosinski et al 2014] in other material perception tasks. A larger database could translate into an improvement of our model's predictions; upcoming databases of complex measured materials (e.g., Dupuy et al [2018]) could be used to expand our training data and lead to a richer and more accurate analysis of appearance. Our methodology for data collection and model training could be useful in these cases.…”

Section: Discussionmentioning

confidence: 99%

A similarity measure for material appearance

et al. 2019

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We present a model to measure the similarity in appearance between different materials, which correlates with human similarity judgments. We first create a database of 9,000 rendered images depicting objects with varying materials, shape and illumination. We then gather data on perceived similarity from crowdsourced experiments; our analysis of over 114,840 answers suggests that indeed a shared perception of appearance similarity exists. We feed this data to a deep learning architecture with a novel loss function, which learns a feature space for materials that correlates with such perceived appearance similarity. Our evaluation shows that our model outperforms existing metrics. Last, we demonstrate several applications enabled by our metric, including appearance-based search for material suggestions, database visualization, clustering and summarization, and gamut mapping.

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“…Backscattering data can be used to extract an appropriate distribution for microfacets BRDF models [Ashikhmin and Premoze 2007;Dupuy and Jakob 2018]. Based on this observation, mobile devices equipped with a lash light, typically positioned near the back camera, represent near-coaxial setups particularly useful to capture the backscatter surface relectance to be itted in a microfacets BRDF model [Riviere et al 2015], since they allow to extract an appropriate distribution of microfacets [Ashikhmin and Premoze 2007], by observing high frequencies for specular components in the highlights areas and the difuse components in other areas .…”

Section: Flash Illumination and Other Capture Setupsmentioning

confidence: 99%