Cite this article as:

Kalyanov A. L., Lychagov V. V., Smirnov I. V., Ryabukho V. P. Effect of Spectral Properties of Image Sensor on Interference Experiment. Izvestiya of Saratov University. New series. Series Physics, 2011, vol. 11, iss. 2, pp. 25-30.

Heading: 
Physics
UDC: 
535.412: 535.417: 681.723.26
Language: 
Russian

Effect of Spectral Properties of Image Sensor on Interference Experiment

Authors: 
Kalyanov Aleksandr L., Saratov State University, 410012, Russia, Saratov, Astrakhanskaya street, 83, kalyanoval@yandex.ru
Lychagov V. V., Saratov State University, 410012, Russia, Saratov, Astrakhanskaya street, 83, kalyanoval@yandex.ru
Smirnov I. V., Saratov State University, 410012, Russia, Saratov, Astrakhanskaya street, 83, kalyanoval@yandex.ru
Ryabukho Vladimir Petrovich, Saratov State University, 410012, Russia, Saratov, Astrakhanskaya street, 83, rvp-optics@yandex.ru
Abstract

Influence of spectral properties of monochrome image sensor on spectrum of detecting radiation in fullfield lowcoherence microinterferometer is investigated. Dependence of interference pulse shape and period of interference fringes on the spectrum is shown. Simulated results and experimental measurements of integral transmission spectrum of Linnik microinterferometer with the silicon monochrome image sensor and thermal light source are presented.

Key words: 
coherence, lowcoherence interferometry, fullfield interferometry, interference microscopy
References

1. Optical coherence tomography : technology and applications / eds. W. Drexler, J. G. Fujimoto. New York : Springer, 2008. 1330 p.

2. Torok P., Kao F.-J. Techniques and Advanced Systems // Optical Imaging and Microscopy. New York : Springer Berlin Heidelberg, 2007. 499 p.

3. Rosen J., Takeda M. Longitudinal spatial coherence applied for surface profi lometry // Appl. Opt. 2000. Vol. 39, №. 23. P. 4107–4111.

4. Рябухо В. П., Кальянов А. Л., Лычагов В. В., Лякин Д. В. Влияние ширины контура частотного спектра на поперечную когерентность оптического поля // Опт. и спектр. 2010. Т. 108, № 6. С. 979–984.

5. Рябухо В. П., Лякин Д. В., Лычагов В. В. Продольная когерентность оптического поля протяженного пространственно некогерентного источника // Компьютерная оптика. 2009. Т. 33, № 2. С. 175–184.

6. Рябухо В. П., Лякин Д. В., Лычагов В. В. Длина продольной когерентности оптического поля // Опт. и спектр. 2009. Т. 107, № 2. С. 296–301.

7. Ohmi M., Haruna M. Ultra-high resolution optical coherence tomography (oct) using a halogen lanlp as the light source // Opt. Review. 2003. Vol. 10, № 5. P. 478– 481.

8. Brundavanam M. M., Viswanathan N. K., Rao D. N. Effect of input spectrum on the spectral switch characteristics in a white-light Michelson interferometer // J. Opt. Soc. Amer. 2009. Vol. 26, № 12. P. 2592–2599.

9. Bajraszewski T., Wojtkowski M., Szkulmowski M., Szkulmowska A., Huber R., Kowalczyk A. Improved spectral optical coherence tomography using optical frequency comb // Opt. Exp. 2008. Vol. 16, № 6. P. 4163–4176.

10. Борн Э., Вольф Э. Основы оптики. М., 1973. 760 с.

11. Мандель Л., Вольф Э. Оптическая когерентность и квантовая оптика. М. , 2000. 896 с.

Full text (in Russian):
download
(downloads: 39)