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| Fourier optika× | Interferogrammi äärejoonte analüüs× | Jonesi kalkulus× | |
|---|---|---|---|
| Valdkond | Optika | Optika | Optika |
| Perekond | Process / pipeline | Process / pipeline | Process / pipeline |
| Tekkeaasta≠ | 1822 | 1801 | 1941 |
| Looja≠ | Joseph Fourier and Ernst Abbe | Thomas Young and Daniel Malus | Robert Clark Jones |
| Tüüp≠ | Spectral decomposition method | Pattern analysis algorithm | Vector-matrix formalism |
| Algallikas≠ | Goodman, J. W. (1968). Introduction to Fourier Optics. McGraw-Hill. link ↗ | Malacara, D. (Ed.). (2007). Optical Shop Testing (3rd ed.). John Wiley & Sons. link ↗ | Jones, R. C. (1941). A new calculus for the treatment of optical systems: I. Description and discussion of the calculus. Journal of the Optical Society of America, 31(7), 488-493. DOI ↗ |
| Rööpnimetused | frequency-domain optics, wave optics, diffraction theory | fringe pattern analysis, interferometry, phase extraction | Jones vector method, Jones matrix, polarization calculus |
| Seotud | 3 | 3 | 3 |
| Kokkuvõte≠ | Fourier optics is a mathematical framework that analyzes optical systems and phenomena using Fourier transforms and frequency-domain methods. Grounded in Joseph Fourier's 1822 work on heat diffusion and Ernst Abbe's microscopy theory, this approach decomposes optical fields into plane waves or spatial frequencies, revealing how optical systems manipulate and filter these components to produce images and transmit information. | Interferogram fringe analysis is a computational methodology for extracting quantitative information from interference fringe patterns recorded in optical systems. Rooted in Thomas Young's 1801 double-slit experiment and formalized in 20th-century metrology, this approach interprets the spatial patterns of constructive and destructive interference to measure surface topography, optical aberrations, refractive-index distributions, and other optical properties with high precision. | Jones calculus is a mathematical formalism for analyzing the propagation and manipulation of polarized light using vectors and matrices. Developed by Robert Clark Jones in 1941, it represents the electric field of a coherent optical beam as a two-component complex vector (Jones vector) and optical elements as matrices (Jones matrices), enabling elegant tracking of polarization through optical systems. |
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