Geodesic
Laser speckle – neotřelý experiment ve výuce fyziky
Rozhledy matematicko-fyzikální, Tome 97 (2022) no. 2, pp. 35-40 
Šebelík, Václav. Laser speckle – neotřelý experiment ve výuce fyziky. Rozhledy matematicko-fyzikální, Tome 97 (2022) no. 2, pp. 35-40. http://geodesic.mathdoc.fr/item/RMF_2022_97_2_a5/
@article{RMF_2022_97_2_a5,
     author = {\v{S}ebel{\'\i}k, V\'aclav},
     title = {Laser speckle {\textendash} neot\v{r}el\'y experiment ve v\'yuce fyziky},
     journal = {Rozhledy matematicko-fyzik\'aln{\'\i}},
     pages = {35--40},
     year = {2022},
     volume = {97},
     number = {2},
     language = {cs},
     url = {http://geodesic.mathdoc.fr/item/RMF_2022_97_2_a5/}
}
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JO  - Rozhledy matematicko-fyzikální
PY  - 2022
SP  - 35
EP  - 40
VL  - 97
IS  - 2
UR  - http://geodesic.mathdoc.fr/item/RMF_2022_97_2_a5/
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%T Laser speckle – neotřelý experiment ve výuce fyziky
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%P 35-40
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Voir la notice de l'article provenant de la source Czech Digital Mathematics Library

[1] Maiman, T. H.: Stimulated optical radiation in ruby. Nature, 187 (1960), 493–494. | DOI

[2] Einstein, A.: Zur Quantentheorie der Strahlung. Physika Zeitschrift, 18 (1917), 121–128.

[3] Mumma, M. J., Buhl, D., Chin, G., Deming, D., Espenak, F., Kostiuk, T., Zipoy, D.: Discovery of natural gain amplification in the 10-micrometer carbon dioxide laser bands on Mars: A natural laser. Science, 212 (1981), 45–49. | DOI

[4] Mehta, D. S., Naik, D. N., Singh, R. K., Takeda, M.: Laser speckle reduction by multimode optical fiber bundle with combined temporal, spatial, and angular diversity. Applied Optics, 51 (2012), 1894–1904. | DOI

[5] Graetzel, Ch., Suter, M., Aschwanden, M.: Reducing laser speckle with electroactive polymer actuators. Proc. of SPIE, 9430 (2015), 943004.

[6] Rabal, H. J., Braga Jr., R. A.: Dynamic Laser Speckle and Applications. CRC Press, Boca Raton, 2018.

[7] PĂŠrez, A. J., González-Peña, R. J., Braga Jr., R., Perles, Á., Pérez-–Marín, E., García-Diego, F. J.: A portable dynamic laser speckle system for sensing long-term changes caused by treatments in painting conservation. Sensors, 18 (2018), 190. | DOI

[8] Daffara, C., Marini, E.: A portable compact system for laser speckle correlation imaging of artworks using projected speckle pattern. Journal of Imaging, 6 (2020), 119. | DOI

[9] Cikalova, U., Bendjus, B., Schreiber, J.: Laser-speckle-photometry – A method for non-contact evaluation of material damage, hardness and porosity. Materials Testing, 54 (2012), 80–84. | DOI

[10] Brag Jr., R. A.: When noise becam information: State-of-the-art in biospeckle laser. Ciência e Agrotecnologia, 41 (2017), 359–366. | DOI

[11] Basak, K., Manjunatha, M., Dutta, P. K.: Review of laser speckle-based analysis in medical imaging. Med. Biol. Eng. Comput., 50 (2012), 547–558. | DOI