Colorimetric research of self-luminous objects in software and hardware environments by the method of multidimensional scales implementation

It is shown that the issues of metrological traceability for extended self-luminous objects with a wide range of brightness have not yet been resolved, since the rank scales of embedded systems are used for processing digital images. For such scales, there is no “fixed” unit, which does not allow you to get reliable results and ensure the unity of measurements. An experiment is described to evaluate the accuracy of determining the intensity (coordinates) of the color of self-luminous objects. In terms of repeatability and intermediate precision compared to the reference measurement method, the color and chromaticity coordinates of self-luminous objects (reference samples) were determined by their multiple digital registration using technical vision systems. The possibilities of the developed methodology for colorimetric studies in hardware and software environments from the point of view of constructing a multidimensional conditional scale are determined.

1. Wyszecki G., International Colour Association, 1973, рp. 21–51.

2. Faircheild M. D., Modeli cvetovogo vospriyatiya, 2nd edition, Rochester Institute of technology, Mansell color science laboratory, 2006, 439 p., available in Russian at: https://mexalib.com/view/36926(accessed:05.05.2020).

3. D. A. Sorokin, Extended abstract of candidate’s dissertation in Technical Sciences (Plekhanov Russian Academy of Economics, Moscow, 2009).

4. Sendel E., Kolorimetricheskie metody opredeleniya sledov metallov, Moscow, Mir Publ., 1964, 90 p. (in Russian).

5. Parmasyan E. S., Kolorimetriya i polyarimetriya nekotoryh komentarnyh tumannostej, Byurakan Astrophysical Observatory of the Academy of Sciences of the Armenian SSR, Yerevan Yerevan State University Publ., 1963. 10 p. (in Russian).

6. D. I. Sokolov, Extended abstract of candidate’s dissertation in Geography (Lomonosov Moscow State University, Moscow, 2013).

7. A. A. Voronin, Extended abstract of candidate’s dissertation in Technical Sciences (Saint Petersburg, State University of Informatics and technologies, mechanics and optics, 2011).

8. A. I. Shapovalova, Extended abstract of candidate’s dissertation in Geography Physical and Mathematical Sciences (Yerevan, Yerevan State University, 1975).

9. L. M. Sharipova, Extended abstract of candidate’s dissertation in Geography Physical and Mathematical Sciences (Crimean astrophysical Observatory, Crimea, 2001).

10. Saukova Y., International Journal of Advanced Engineering and Technology, 2017, vol. 1, no. 4, рр. 28–33, available at: http://www.newengineeringjournal.com/archives/2017/vol1/issue4/2-1-11(accessed:05.05.2020).

11. Saukova Y., Matyush I., International Journal of Innovative Research in Electronics and Communications (IJIREC), 2016, vol. 3, no. 5, рр. 6–19. https://doi.org/10.20431/2349-4050.0305002

12. Saukova Y., Proceedings of the 11th International scientifi c and technical conference “Instrumentation-2018”, Minsk, November 14–16, 2018, Minsk, BNTU Publ., 2018, pp. 152–154.

13. Saukova Y., Mir izmerenij, 2016, no. 2, рp. 54–62 (in Russian).

14. Saukova Y., Zuikov I. E., Proceedings of the IX International scientifi c and practical conference “Modern research and development-2013”, Sofi a, Bulgaria, January 17–25, Kharkov, Kharkov National University of Radio Electronics Publ., 2013, vol. 27, pp. 38–42.

15. Saukova Y., Zuikov I. E., Proceedings of the 6th International scientifi c and technical conference “Instrumentation-2013”, Minsk, 20–22 November, Minsk, BNTU Publ., pp. 176–178.

16. Meshkov V. V., Matveev A. B., Osnovy svetotekhniki. Ucheb. posobie dlya vuzov in 2 pts. Pt. 2. Fiziologicheskaya optika i kolorimetriya Fundamentals of lighting engineering, Moscow, Energoatomizdat Publ., 1989, 432 p. (in Russian).

17. Gauden J., Kolorimetriya pri videoobrabotke, Moscow, Technosphera Publ., 2008. 328 p. (in Russian).