Nanometer-scale displacement measurement using a simple diffraction grating with a quadrature detection technique

T. Nuntakulkaisak; R. Bavontaweepanya; Y. Infahsaeng; P. Wongjom; W. Pijitrojana; S. Suwanna; E. Pongophas

doi:10.1364/OL.470551

Nanometer-scale displacement measurement using a simple diffraction grating with a quadrature detection technique

T. Nuntakulkaisak, R. Bavontaweepanya, Y. Infahsaeng, P. Wongjom, W. Pijitrojana, S. Suwanna, E. Pongophas

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

1 Citation (Scopus)

Abstract

A phase-sensitive transparent grating interferometer is proposed to measure small displacements. A transparent grating is inserted between a light source and a reflective mirror. The diffracted light beams of the forward and backward propagation are superposed to form the interference pattern. When two detectors are placed at two different positions of the interference fringe in such a way that the signals have quadrature phase difference, the phase variation can infer the displacement of the reflected mirror. This simple setup can measure the displacement of the mirror at nanometer scale with 98.2% accuracy, high precision with 10 nm in standard deviation, and lowest bound of 0.4 nm resolution.

Original language	English
Pages (from-to)	5156-5159
Number of pages	4
Journal	Optics Letters
Volume	47
Issue number	19
DOIs	https://doi.org/10.1364/OL.470551
Publication status	Published - 1 Oct 2022
Externally published	Yes

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title = "Nanometer-scale displacement measurement using a simple diffraction grating with a quadrature detection technique",

abstract = "A phase-sensitive transparent grating interferometer is proposed to measure small displacements. A transparent grating is inserted between a light source and a reflective mirror. The diffracted light beams of the forward and backward propagation are superposed to form the interference pattern. When two detectors are placed at two different positions of the interference fringe in such a way that the signals have quadrature phase difference, the phase variation can infer the displacement of the reflected mirror. This simple setup can measure the displacement of the mirror at nanometer scale with 98.2% accuracy, high precision with 10 nm in standard deviation, and lowest bound of 0.4 nm resolution.",

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AU - Nuntakulkaisak, T.

AU - Bavontaweepanya, R.

AU - Infahsaeng, Y.

AU - Wongjom, P.

AU - Pijitrojana, W.

AU - Suwanna, S.

AU - Pongophas, E.

PY - 2022/10/1

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N2 - A phase-sensitive transparent grating interferometer is proposed to measure small displacements. A transparent grating is inserted between a light source and a reflective mirror. The diffracted light beams of the forward and backward propagation are superposed to form the interference pattern. When two detectors are placed at two different positions of the interference fringe in such a way that the signals have quadrature phase difference, the phase variation can infer the displacement of the reflected mirror. This simple setup can measure the displacement of the mirror at nanometer scale with 98.2% accuracy, high precision with 10 nm in standard deviation, and lowest bound of 0.4 nm resolution.

AB - A phase-sensitive transparent grating interferometer is proposed to measure small displacements. A transparent grating is inserted between a light source and a reflective mirror. The diffracted light beams of the forward and backward propagation are superposed to form the interference pattern. When two detectors are placed at two different positions of the interference fringe in such a way that the signals have quadrature phase difference, the phase variation can infer the displacement of the reflected mirror. This simple setup can measure the displacement of the mirror at nanometer scale with 98.2% accuracy, high precision with 10 nm in standard deviation, and lowest bound of 0.4 nm resolution.

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Nanometer-scale displacement measurement using a simple diffraction grating with a quadrature detection technique

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