Alamin Mansouri scite author profile

In this paper we describe in detail a method for calibrating a CCD-based camera. The calibration aims to remove both temporal and systematic noises introduced by the sensor, electronics, and optics after which we can correct the non-linearity of its response. For the non-linearity correction we use a simple and powerful approach consisting on a complementary approach between a polynomial fitting and an LUT based algorithm. The proposed methodology is accurate in the sense that it takes into account individual characteristics of each pixel. In each pixel, systematic noises are measured through acquiring offset images, thermal images, and Flat-Field images. A rigorous protocol for acquiring these images based on experimentation is established. The method to acquire Flat-Field image is novel and is particularly efficient in that it can correct all defects due to non-uniform pixel responses, vignettage, blemishes on optic and/or filters, and perhaps even illumination nonuniformity. We notice that such a methodology of calibration is particularly efficient in the case of an optical filter based multispectral imaging system, although it remains valid for any imaging system based on a CCD sensor.

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Discrete Modal Decomposition: a new approach for the reflectance modeling and rendering of real surfaces

Pitard

Goïc

Mansouri

et al. 2017

Machine Vision and Applications

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International audienceReflectance Transformation Imaging is a recent technique allowing for the measurement and the modeling of one of the most influential parameters on the appearance of a surface, namely the angular reflectance, thanks to the change in the direction of the lighting during acquisition. From these photometric stereo images (discrete data), the angular reflectance is modeled to allow both interactive and continuous relighting of the inspected surface. Two families of functions, based on polynomials and on hemispherical harmonics, are cited and used in the literature at this aim, respectively, associated to the PTM and HSH techniques. In this paper, we propose a novel method called Discrete Modal Decomposition (DMD) based on a particular and appropriate Eigen basis derived from a structural dynamic problem. The performance of the proposed method is compared with the PTM and HSH results on three real surfaces showing different reflection behaviors. Comparisons are made in terms of both visual rendering and of statistical error (local and global). The obtained results show that the DMD is more efficient in that it allows for a more accurate modeling of the angular reflectance when light-matter interaction is complex such as the presence of shadows, specularities and inter-reflections

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Alamin Mansouri

Unsupervised skin tissue segmentation for remote photoplethysmography

Development of a Protocol for CCD Calibration: Application to a Multispectral Imaging System

Discrete Modal Decomposition: a new approach for the reflectance modeling and rendering of real surfaces

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