Binary coded linear fringes for three-dimensional shape profiling

Gastón A. Ayubi; J. Matías Di Martino; Jorge L. Flores; José A. Ferrari

doi:10.1117/1.OE.51.10.103601

Binary coded linear fringes for three-dimensional shape profiling

Gastón A. Ayubi, J. Matías Di Martino, Jorge L. Flores, José A. Ferrari

Research output: Contribution to journal › Article › peer-review

12 Scopus citations

Abstract

We present a three-dimensional (3-D) shape profiling method that involves the projection of two shifted strictly binary (square wave) fringe patterns, whose adequately weighted average allows to synthesize a sawtooth pattern. We demonstrate that the deformed fringes (after unwrapping) provide an intensity pattern proportional to the depth profile of the surface. The proposed technique overcomes the nonlinear response (i.e., the "gamma problem") of digital cameras and commercial video projectors without previous calibration. The two binary patterns can be encoded in the color components of a single color image, which allows a reliable 3-D profiling surface reconstruction at large time-rates. Validation experiments are presented.

Original language	English
Article number	103601
Journal	Optical Engineering
Volume	51
Issue number	10
DOIs	https://doi.org/10.1117/1.OE.51.10.103601
State	Published - Oct 2012
Externally published	Yes

Keywords

Fringe analysis
Image acquisition/recording

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10.1117/1.OE.51.10.103601

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title = "Binary coded linear fringes for three-dimensional shape profiling",

abstract = "We present a three-dimensional (3-D) shape profiling method that involves the projection of two shifted strictly binary (square wave) fringe patterns, whose adequately weighted average allows to synthesize a sawtooth pattern. We demonstrate that the deformed fringes (after unwrapping) provide an intensity pattern proportional to the depth profile of the surface. The proposed technique overcomes the nonlinear response (i.e., the {"}gamma problem{"}) of digital cameras and commercial video projectors without previous calibration. The two binary patterns can be encoded in the color components of a single color image, which allows a reliable 3-D profiling surface reconstruction at large time-rates. Validation experiments are presented.",

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AU - Ayubi, Gastón A.

AU - Di Martino, J. Matías

AU - Flores, Jorge L.

AU - Ferrari, José A.

PY - 2012/10

Y1 - 2012/10

N2 - We present a three-dimensional (3-D) shape profiling method that involves the projection of two shifted strictly binary (square wave) fringe patterns, whose adequately weighted average allows to synthesize a sawtooth pattern. We demonstrate that the deformed fringes (after unwrapping) provide an intensity pattern proportional to the depth profile of the surface. The proposed technique overcomes the nonlinear response (i.e., the "gamma problem") of digital cameras and commercial video projectors without previous calibration. The two binary patterns can be encoded in the color components of a single color image, which allows a reliable 3-D profiling surface reconstruction at large time-rates. Validation experiments are presented.

AB - We present a three-dimensional (3-D) shape profiling method that involves the projection of two shifted strictly binary (square wave) fringe patterns, whose adequately weighted average allows to synthesize a sawtooth pattern. We demonstrate that the deformed fringes (after unwrapping) provide an intensity pattern proportional to the depth profile of the surface. The proposed technique overcomes the nonlinear response (i.e., the "gamma problem") of digital cameras and commercial video projectors without previous calibration. The two binary patterns can be encoded in the color components of a single color image, which allows a reliable 3-D profiling surface reconstruction at large time-rates. Validation experiments are presented.

KW - Fringe analysis

KW - Image acquisition/recording

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VL - 51

JO - Optical Engineering

JF - Optical Engineering

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ER -

Binary coded linear fringes for three-dimensional shape profiling

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Keywords

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