Repeated phase-offset measurement for error compensation in two-step triangular phase-shifting profilometry

Peirong Jia; Jonathan Kofman; Chad English

doi:10.1117/12.690735

18 October 2006 Repeated phase-offset measurement for error compensation in two-step triangular phase-shifting profilometry

Peirong Jia, Jonathan Kofman, Chad English

Author Affiliations +

Proceedings Volume 6375, Optomechatronic Sensors, Instrumentation, and Computer-Vision Systems; 63750D (2006) https://doi.org/10.1117/12.690735
Event: Optics East 2006, 2006, Boston, Massachusetts, United States

Abstract

Two-step triangular phase-shifting is a recently developed method for 3-D shape measurement. In this method, two triangular gray-level-coded patterns, which are phase-shifted by half of the pitch, are needed to reconstruct the 3-D object. The measurement accuracy is limited by gamma non-linearity and defocus of the projector and camera. This paper presents a repeated phase-offset two-step triangular-pattern phase-shifting method used to decrease the measurement error caused by the gamma non-linearity and defocus in the previously developed two-step triangularpattern phase-shifting 3-D object measurement method. Experimental analysis indicated that a sensitivity threshold based on the gamma non-linearity curve should be used as the minimum intensity of the computer-generated pattern input to the projector to reduce measurement error. In the repeated phase-offset method, two-step triangular phaseshifting is repeated with an initial phase offset of one-eighth of the pitch, and the two obtained 3-D object height distributions are averaged to generate the final 3-D object-height distribution. Experimental results demonstrated that the repeated phase-offset measurement method substantially decreased measurement error compared to the two-step triangular phase-shifting method.

Citation Download Citation

Peirong Jia, Jonathan Kofman, and Chad English "Repeated phase-offset measurement for error compensation in two-step triangular phase-shifting profilometry", Proc. SPIE 6375, Optomechatronic Sensors, Instrumentation, and Computer-Vision Systems, 63750D (18 October 2006); https://doi.org/10.1117/12.690735

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