Maximum-likelihood methods in wavefront sensing: Stochastic models and likelihood functions

Harrison H. Barrett; Christopher Dainty; David Lara

doi:10.1364/JOSAA.24.000391

Maximum-likelihood methods in wavefront sensing: Stochastic models and likelihood functions

Harrison H. Barrett
, Christopher Dainty
, David Lara

Physics

University of Arizona
University of Galway

Research output: Contribution to a Journal (Peer & Non Peer) › Article › peer-review

45 Citations (Scopus)

Abstract

Maximum-likelihood (ML) estimation in wavefront sensing requires careful attention to all noise sources and all factors that influence the sensor data. We present detailed probability density functions for the output of the image detector in a wavefront sensor, conditional not only on wavefront parameters but also on various nuisance parameters. Practical ways of dealing with nuisance parameters are described, and final expressions for likelihoods and Fisher information matrices are derived. The theory is illustrated by discussing Shack-Hartmann sensors, and computational requirements are discussed. Simulation results show that ML estimation can significantly increase the dynamic range of a Shack-Hartmann sensor with four detectors and that it can reduce the residual wavefront error when compared with traditional methods.

Original language	English
Pages (from-to)	391-414
Number of pages	24
Journal	Journal of the Optical Society of America A: Optics and Image Science, and Vision
Volume	24
Issue number	2
DOIs	https://doi.org/10.1364/JOSAA.24.000391
Publication status	Published - Feb 2007

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abstract = "Maximum-likelihood (ML) estimation in wavefront sensing requires careful attention to all noise sources and all factors that influence the sensor data. We present detailed probability density functions for the output of the image detector in a wavefront sensor, conditional not only on wavefront parameters but also on various nuisance parameters. Practical ways of dealing with nuisance parameters are described, and final expressions for likelihoods and Fisher information matrices are derived. The theory is illustrated by discussing Shack-Hartmann sensors, and computational requirements are discussed. Simulation results show that ML estimation can significantly increase the dynamic range of a Shack-Hartmann sensor with four detectors and that it can reduce the residual wavefront error when compared with traditional methods.",

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Maximum-likelihood methods in wavefront sensing: Stochastic models and likelihood functions

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