Calibrating optical tweezers with Bayesian inference

Maximilian U. Richly; Silvan Türkcan; Antoine Le Gall; Nicolas Fiszman; Jean Baptiste Masson; Nathalie Westbrook; Karen Perronet; Antigoni Alexandrou

doi:10.1364/OE.21.031578

Calibrating optical tweezers with Bayesian inference

Maximilian U. Richly
, Silvan Türkcan
, Antoine Le Gall
, Nicolas Fiszman
, Jean Baptiste Masson
, Nathalie Westbrook
, Karen Perronet
, Antigoni Alexandrou

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

Abstract

We present a new method for calibrating an optical-tweezer setup that does not depend on input parameters and is less affected by systematic errors like drift of the setup. It is based on an inference approach that uses Bayesian probability to infer the diffusion coefficient and the potential felt by a bead trapped in an optical or magnetic trap. It exploits a much larger amount of the information stored in the recorded bead trajectory than standard calibration approaches. We demonstrate that this method outperforms the equipartition method and the power-spectrum method in input information required (bead radius and trajectory length) and in output accuracy.

Original language	English
Pages (from-to)	31578-31590
Number of pages	13
Journal	Optics Express
Volume	21
Issue number	25
DOIs	https://doi.org/10.1364/OE.21.031578
Publication status	Published - 16 Dec 2013

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AU - Richly, Maximilian U.

AU - Türkcan, Silvan

AU - Gall, Antoine Le

AU - Fiszman, Nicolas

AU - Masson, Jean Baptiste

AU - Westbrook, Nathalie

AU - Perronet, Karen

AU - Alexandrou, Antigoni

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AB - We present a new method for calibrating an optical-tweezer setup that does not depend on input parameters and is less affected by systematic errors like drift of the setup. It is based on an inference approach that uses Bayesian probability to infer the diffusion coefficient and the potential felt by a bead trapped in an optical or magnetic trap. It exploits a much larger amount of the information stored in the recorded bead trajectory than standard calibration approaches. We demonstrate that this method outperforms the equipartition method and the power-spectrum method in input information required (bead radius and trajectory length) and in output accuracy.

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Calibrating optical tweezers with Bayesian inference

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