WAVEFRONT TESTER: Un nuevo laboratorio virtual para el estudio de los sensores frente de onda.
Enviado: 15-01-2016
|Aceptado: 25-01-2016
|Publicado: 27-01-2016
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Palabras clave:
aberraciones, sensores de frente de onda, MATLAB
Agencias de apoyo:
Instituto de Ciencias de la Educación
Universitat Politécnica de Valéncia
Vicerrectorat de Polítiques de Formació i Qualitat Educativa
Universitat de València.
Resumen:
Citas:
Feng F., White I. H., Wilkinson T. D. (2014). Aberration correction for free space optical communications using rectangular Zernike modal wavefront sensing. Journal of Lightwave Technology, 32, 1239-124.
Idir M., Kaznatcheev K., Dovillaire G., Legrand J., Rungsawang R. (2014). A 2D high accuracy slope measuring system based on a Stitching Shack Hartmann Optical Head. Optics Express, 22, 2770-2781.
Li C., Li B., Zhang S. (2014). Phase retrieval using a modiffied Shack-Hartmann wavefront sensor with defocus. Applied Optics, 53, 618-624.
Marino J., Wöger F. (2014). Feasibility study of a layer-oriented wavefront sensor for solar Telescopes. Applied Optics, 53, 685-693.
Micó V., Zalevsky Z., Garcia J. (2012). Superresolved common-path phase-shifting digital inline holographic microscopy using a spatial light modulator. Optics Letters, 37, 4988-4990.
Paurisse M., Hanna M., Druon F., Georges P. (2010). Wavefront control of a multicore ytterbium-doped pulse fiber amplifier by digital holography. Optics Letters, 35, 1428-1430.
Platt B. C., Shack R. (2001). History and principles of Shack-Hartmann wavefront sensing. Journal of Refractive Surgery, 17, S573-S577.