Skip to content

Commit

Permalink
double ref
Browse files Browse the repository at this point in the history
  • Loading branch information
JeroenDoornbos committed Oct 11, 2024
1 parent b194205 commit 6c1b8ca
Showing 2 changed files with 1 addition and 12 deletions.
2 changes: 1 addition & 1 deletion docs/source/readme.rst
Original file line number Diff line number Diff line change
@@ -13,7 +13,7 @@
What is wavefront shaping?
--------------------------------

Wavefront shaping (WFS) is a technique for controlling the propagation of light in arbitrarily complex structures, including strongly scattering materials :cite:`kubby2019`. In WFS, a spatial light modulator (SLM) is used to shape the phase and/or amplitude of the incident light. With a properly constructed wavefront, light can be made to focus through :cite:`Vellekoop2007`, or inside :cite:`vellekoop2008demixing` scattering materials; or light can be shaped to have other desired properties, such as optimal sensitivity for specific measurements :cite:`bouchet2021maximum`, specialized point-spread functions :cite:`boniface2017transmission`, spectral filtering :cite:`Park2012`, or for functions like optical trapping :cite:`vcivzmar2010situ`.
Wavefront shaping (WFS) is a technique for controlling the propagation of light in arbitrarily complex structures, including strongly scattering materials :cite:`kubby2019`. In WFS, a spatial light modulator (SLM) is used to shape the phase and/or amplitude of the incident light. With a properly constructed wavefront, light can be made to focus through :cite:`Vellekoop2007`, or inside :cite:`vellekoop2008demixing` scattering materials; or light can be shaped to have other desired properties, such as optimal sensitivity for specific measurements :cite:`bouchet2021maximum`, specialized point-spread functions :cite:`boniface2017transmission` or spectral filtering :cite:`Park2012`.

It stands out that an important driving force in WFS is the development of new algorithms, for example, to account for sample movement :cite:`valzania2023online`, experimental conditions :cite:`Anderson2016`, to be optimally resilient to noise :cite:`mastiani2021noise`, or to use digital twin models to compute the required correction patterns :cite:`salter2014exploring,ploschner2015seeing,Thendiyammal2020,cox2023model`. Much progress has been made towards developing fast and noise-resilient algorithms, or algorithms designed specifically for the methodology of wavefront shaping, such as using algorithms based on Hadamard patterns :cite:`popoff2010measuring` or Fourier-based approaches :cite:`Mastiani2022`. Fast techniques that enable wavefront shaping in dynamic samples :cite:`Liu2017,Tzang2019` have also been developed, and many potential applications have been prototyped, including endoscopy :cite:`ploschner2015seeing`, optical trapping :cite:`Cizmar2010`, Raman scattering :cite:`Thompson2016`, and deep-tissue imaging :cite:`Streich2021`. Applications extend beyond that of microscope imaging, such as in optimizing photoelectrochemical absorption :cite:`Liew2016` and tuning random lasers :cite:`Bachelard2014`.

11 changes: 0 additions & 11 deletions docs/source/references.bib
Original file line number Diff line number Diff line change
@@ -108,17 +108,6 @@ @article{valzania2023online
publisher = {Optica Publishing Group}
}

@article{vcivzmar2010situ,
title = {In situ wavefront correction and its application to micromanipulation},
author = {{\v{C}}i{\v{z}}m{\'a}r, Tom{\'a}{\v{s}} and Mazilu, Michael and Dholakia, Kishan},
journal = {Nature Photonics},
volume = {4},
number = {6},
pages = {388--394},
year = {2010},
publisher = {Nature Publishing Group UK London}
}

@book{zandonellaMassiddaOpenScience2022,
title = {The Open Science Manual: Make Your Scientific Research Accessible and Reproducible},
author = {Zandonella Callegher, Claudio and Massidda, Davide},

0 comments on commit 6c1b8ca

Please sign in to comment.