Roberto Mecca scite author profile

3D reconstruction from shading information through Photometric Stereo is considered a very challenging problem in Computer Vision. Although this technique can potentially provide highly detailed shape recovery, its accuracy is critically dependent on a numerous set of factors among them the reliability of the light sources in emitting a constant amount of light. In this work, we propose a novel variational approach to solve the so called semi-calibrated near field Photometric Stereo problem, where the positions but not the brightness of the light sources are known. Additionally, we take into account realistic modeling features such as perspective viewing geometry and heterogeneous scene composition, containing both diffuse and specular objects. Furthermore, we also relax the point light source assumption that usually constraints the near field formulation by explicitly calculating the light attenuation maps. Synthetic experiments are performed for quantitative evaluation for a wide range of cases whilst real experiments provide comparisons, qualitatively outperforming the state of the art.

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A Single-Lobe Photometric Stereo Approach for Heterogeneous Material

Mecca¹,

Quéau²,

Logothetis³

et al. 2016

SIAM J. Imaging Sci.

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Shape from shading with multiple light sources is an active research area, and a diverse range of approaches have been proposed in recent decades. However, devising a robust reconstruction technique still remains a challenging goal, as the image acquisition process is highly nonlinear. Recent Photometric Stereo variants rely on simplifying assumptions in order to make the problem solvable: light propagation is still commonly assumed to be uniform, and the Bidirectional Reflectance Distribution Function is assumed to be diffuse, with limited interest for specular materials. In this work, we introduce a well-posed formulation based on partial differential equations (PDEs) for a unified reflectance function that can model both diffuse and specular reflections. We base our derivation on ratio of images, which makes the model independent from photometric invariants and yields a well-posed differential problem based on a system of quasi-linear PDEs with discontinuous coefficients. In addition, we directly solve a differential problem for the unknown depth, thus avoiding the intermediate step of approximating the normal field. A variational approach is presented ensuring robustness to noise and outliers (such as black shadows), and this is confirmed with a wide range of experiments on both synthetic and real data, where we compare favorably to the state of the art.Reflectance. Most of the research done till now for the PS technique has assumed purely diffuse reflectance as the Bidirectional Reflectance Distribution Function (BRDF). Unlike (a) and (b), shape recovery from specular shading still remains a challenging goal since most of the common materials provide specular highlights that prevent reasonable reconstructions by the PS technique.Regarding shading models for specular highlights, several dedicated irradiance equations have been presented so far. First, Torrance and Sparrow [56] presented a physical model based on radiometry principles. Later, Phong [48] showed an empirical model which basically extended the cosine law, making it depend also on the viewer direction. The Blinn-Phong shading model [4] extended further the previous one by eliminating some limitation in the analytical formulation. Then Cook and Torrance [14] provided a well-known specular model based on a strongly nonlinear physical theory. Other important models for specular BRDFs can be found in [33], and interesting comparisons among some of them have been performed in [44].Instead of simplifying the PS problem by removing specularity, other works dealt with the images as they are, having both specular and diffuse components. Nayar, Ikeuchi, and Kanade [43] assumed hybrid surfaces by summing diffuse and specular components using the Beckmann and Spizzichino [3] reflection model, allowing them to locally reconstruct the shape of the object. Ikeuchi [28] faced the PS problem with specular reflectance by introducing a smoothness prior on the surface, which was shown to be realistic for several industrial applications, though this approach is limite...

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Uniqueness and Approximation of a Photometric Shape-from-Shading Model

Mecca¹,

Falcone²

2013

SIAM J. Imaging Sci.

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We deal with an inverse problem where we want to determine the surface of an object using the information contained in two or more pictures which correspond to different light conditions. In particular, we will examine the case where the light source direction varies between the pictures, and we will show how this additional information allows us to obtain a uniqueness result solving the wellknown convex/concave ambiguity of the shape-from-shading problem. We will prove a uniqueness result for weak (Lipschitz continuous) solutions that improves previous results in [R. Kozera, Appl.

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Roberto Mecca

Near Field Photometric Stereo with Point Light Sources

Semi-Calibrated Near Field Photometric Stereo

A Single-Lobe Photometric Stereo Approach for Heterogeneous Material

Uniqueness and Approximation of a Photometric Shape-from-Shading Model

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