Generalized phase-shifting algorithms: Error analysis and minimization of noise propagation

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

doi:10.1364/AO.55.001461

Generalized phase-shifting algorithms: Error analysis and minimization of noise propagation

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

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

25 Scopus citations

Abstract

Phase shifting is a technique for phase retrieval that requires a series of intensity measurements with certain phase steps. The purpose of the present work is threefold: first we present a new method for generating general phase-shifting algorithms with arbitrarily spaced phase steps. Second, we study the conditions for which the phase-retrieval error due to phase-shift miscalibration can be minimized. Third, we study the phase extraction from interferograms with additive random noise, and deduce the conditions to be satisfied for minimizing the phase-retrieval error. Algorithms with unevenly spaced phase steps are discussed under linear phase-shift errors and additive Gaussian noise, and simulations are presented.

Original language	English
Pages (from-to)	1461-1469
Number of pages	9
Journal	Applied Optics
Volume	55
Issue number	6
DOIs	https://doi.org/10.1364/AO.55.001461
State	Published - 20 Feb 2016
Externally published	Yes

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10.1364/AO.55.001461

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abstract = "Phase shifting is a technique for phase retrieval that requires a series of intensity measurements with certain phase steps. The purpose of the present work is threefold: first we present a new method for generating general phase-shifting algorithms with arbitrarily spaced phase steps. Second, we study the conditions for which the phase-retrieval error due to phase-shift miscalibration can be minimized. Third, we study the phase extraction from interferograms with additive random noise, and deduce the conditions to be satisfied for minimizing the phase-retrieval error. Algorithms with unevenly spaced phase steps are discussed under linear phase-shift errors and additive Gaussian noise, and simulations are presented.",

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AU - Ayubi, Gastón A.

AU - Perciante, César D.

AU - Di Martino, J. Matías

AU - Flores, Jorge L.

AU - Ferrari, José A.

PY - 2016/2/20

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N2 - Phase shifting is a technique for phase retrieval that requires a series of intensity measurements with certain phase steps. The purpose of the present work is threefold: first we present a new method for generating general phase-shifting algorithms with arbitrarily spaced phase steps. Second, we study the conditions for which the phase-retrieval error due to phase-shift miscalibration can be minimized. Third, we study the phase extraction from interferograms with additive random noise, and deduce the conditions to be satisfied for minimizing the phase-retrieval error. Algorithms with unevenly spaced phase steps are discussed under linear phase-shift errors and additive Gaussian noise, and simulations are presented.

AB - Phase shifting is a technique for phase retrieval that requires a series of intensity measurements with certain phase steps. The purpose of the present work is threefold: first we present a new method for generating general phase-shifting algorithms with arbitrarily spaced phase steps. Second, we study the conditions for which the phase-retrieval error due to phase-shift miscalibration can be minimized. Third, we study the phase extraction from interferograms with additive random noise, and deduce the conditions to be satisfied for minimizing the phase-retrieval error. Algorithms with unevenly spaced phase steps are discussed under linear phase-shift errors and additive Gaussian noise, and simulations are presented.

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Generalized phase-shifting algorithms: Error analysis and minimization of noise propagation

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