Wave and Statistical Optics

Members of the group deal with the problems of wave optics and development of applications of measurement methods based on the principles of wave and statistical optics. Theoretical results are focused on the advances in complex theory of statistical properties of optical speckle fields including novel numerical model (Measurement 2016, 88, 271) simulating generation and propagation of speckle fields for various variants of deformation tensor characterizing the surface of the object (rigid body translation, 3D rotation or translation, elastic deformation). Suggested approach has been tested also experimentally in good agreement including determination of limits of applicability, sensitivity, and precision.

The methods of wave optics have been also used to noninvasive observation of plants exposed to wound (Plant Meth. 2018, 14, 38), or for the development of non-contact method to detect defects of polymer objects for automotive industry (Polym. Test. 2022, 116, 107802).

Next, problems of various applications of electronic speckle pattern interferometry (ESPI; Optik 2015, 126, 865) are studied, e.g., effective evaluation of highly noisy interferograms (Meas. Sci. Rev. 2014, 14, 177). As another task, the methods based on white-light interferometry are investigated (Opt. Laser Eng. 2020, 124, 105800) and applied as 3D sensors with large information potential (Appl. Optics 2022, 61, B215). With respect to industrial applicability of these methods, considerable attention is devoted to measurement uncertainties (Meas. Sci. Technol. 2016, 27, 35205; Appl. Optics 2023, 62, 1769).

Latest publications of the group

  • Horváth, P; Smíd, P; Nozková, V; Pechník, J: Non-invasive optical technique based on speckle phenomenon for application in plant stress physiology, Opt. Lasers Eng. 172 107870 (2024).
  • Pavlicek, P; Palickova, E: Measurement uncertainty of phase measuring deflectometry, Appl. Optics 62 (7) , 1769 - 1776 (2023).
  • Fujii, T; Albury, J; Bradfield, F; Bellido, JA; Chytka, L; Farmer, J; Hamal, P; Horvath, P; Hrabovsky, M; Iwasaki, H; Jilek, V; Kmec, J; Kvita, J; Malacari, M; Mandat, D; Mastrodicasa, M; Matthews, JN; Michal, S; Nagasawa, H; Namba, H; Ni, X; Nozka, L; Oka, T; Palatka, M; Pech, M; Privitera, P; Schovanek, P; Salamida, F; Smida, R; Svozilikova, Z; Thomas, SB; Taketa, A; Terauchi, K; Travnicek, P; Vacula, M: Recent results from prototypes of the Fluorescence detector Array of Single-pixel Telescopes (FAST) in both hemispheres, 283 6010 (2023).
  • Kmec, J; Pavlicek, P; Smid, P: Optical noncontact method to detect amplitude defects of polymeric objects, Polym. Test 116 107802 (2022).
  • Smid, P; Pavlicek, P; Kmec, J: Detection of decorative phase defects on a polymeric non-planar object, Polym. Test 109 107558 (2022).

Group of Wave Optics

Name Role Room Phone (++420 58 563 ...) ORCID Researcher ID
RNDr. Pavel Horváth Ph.D. researcher 209 1569, 1540 0000-0002-6710-5339 G-6334-2014
prof. RNDr. Miroslav Hrabovský DrSc. researcher / deputy head of the laboratory / head of the group 210 1501 0000-0003-4223-7316 G-6714-2014
doc. RNDr. Pavel Pavlíček Ph.D. researcher 218 1680 0000-0002-9162-4905 G-6193-2014
RNDr. Petr Šmíd Ph.D. researcher 209 1569, 1540 0000-0001-7077-6785 G-5690-2014

Tags: