Back Matter

doi:10.1117/3.895041.bm

Ebook Topic:
Back Matter

Book: Field Guide to Diffractive Optics

Author(s): Yakov G. Soskind

Published: 2011

https://doi.org/10.1117/3.895041.bm

Author Affiliations +

Abstract

This section contains the bibliography, index, and author's bio.

Bibliography

1

Arieli Y. et al, ““Design of a diffractive optical element for wide spectral bandwidth,”,” Opt. Lett, 23 (11), 823–825 (1998). Google Scholar

2

Ersoy O. K., Diffraction, Fourier Optics and Imaging, John Wiley & Sons Inc., Hoboken, NJ (2007). Google Scholar

3

Farn M. W., Veldkamp W. B., Bass M., ““Binary optics,”,” Handbook of Optics, II McGraw-Hill, New York (1995). Google Scholar

4

Greisukh G. I., Bobrov S. T., Stepanov S. A., Optics of Diffractive and Gradient-Index Elements and Systems, SPIE Press, Bellingham, WA (1997). Google Scholar

5

Hutley M. C., Diffraction Gratings and Applications, Academic Press, London (1982). Google Scholar

6

Ichikawa H., Masuda K., Ueda T., ““Analysis of micro-Fresnel lenses with local grating theory and its comparison with fully electromagnetic methods,”,” J. Opt. Soc. Amer. A, 26 1938–1944 (2009). Google Scholar

7

Joannopoulos J. D., Johnson S. G., Winn J. N., Meade R. D., Photonic Crystals. Molding the Flow of Light, 2^nd ed.Princeton University Press, Princeton, NJ (2008). Google Scholar

8

Jordan J. A., Hirsch P. M., Lesem L. B., Van Rooy D. V., ““Kinoform lenses,”,” Appl. Opt., 9 1883–1887 (1970). Google Scholar

9

Koronkevich V. P., Arsenault H. H., Szoplik T., Macukow B., ““Computer synthesis of diffraction optical elements,”,” Optical Processing and Computing, 277–313 Academic Press, San Diego (1989). Google Scholar

10

Kogelnik H., ““Coupled wave theory for thick hologram gratings,”,” Bell Syst. Tech. J., 48 2909–2948 (1969). Google Scholar

11

Kress B., Meyrueis P., Digital Diffractive Optics, John Wiley & Sons Inc., Hoboken, NJ (2000). Google Scholar

12

Lalanne P., Astilean S., Chavel P., Cambril E., Launois H., ““Design and fabrication of blazed binary diffractive elements with sampling periods smaller than the structural cutoff,”,” J. Opt. Soc. Amer. A, 16 1143–1156 (1999). Google Scholar

13

Lee W.-H., Wolf E., ““Computer-generated holograms: techniques and applications,”,” Progress in Optics XVI, 119–232 North-Holland, Amsterdam (1978). Google Scholar

14

Lesem L. B., Hirsch P. M., Jordan J. A., ““The kinoformml: A new reconstruction device,”,” IBM J. Res. Dev., 13 150–155 (1969). Google Scholar

15

Lipson S. G., Lipson H., Tannhauser D. S., Optical Physics, Cambridge University Press, Cambridge, UK (2001). Google Scholar

16

Loewen E. G., Popov E., Diffraction Gratings and Applications, Marcel Dekker Inc., New York (1997). Google Scholar

17

Novotny L., Hecht B., Principles of Nano-Optics, Cambridge University Press, Cambridge, UK (2006). Google Scholar

18

Palmer C. A., Loewen E. G., Diffraction Grating Handbook, David Richardson Grating Laboratory, Rochester, NY (2000). Google Scholar

19

Pommet D. A., Moharam M. G., Grann E. B., ““Limits of scalar diffraction theory for diffractive phase elements,”,” J. Opt. Soc. Amer. A, 11 1827–1834 (1994). Google Scholar

20

Raguin D. H., Norton S., Morris G. M., Lee S. H., ““Subwavelength structured surfaces and their applications,”,” Diffractive and Miniaturized Optics, CR49 234–265 SPIE Press, Bellingham, WA (1993). Google Scholar

21

Soskind Y. G., ““Novel technique for passive athermalization of optical systems,”,” OSA Trends in Optics and Photonics, Diffractive Optics and Micro-Optics, 43 194–204 (2000). Google Scholar

22

Spencer G. H., Murty M. V. R. K., ““Generalized ray-tracing procedure,”,” J. Opt. Soc. Amer., 41 672–678 (1951). Google Scholar

23

Stone T., George N., ““Hybrid diffractive-refractive lenses and achromats,”,” Appl. Opt., 27 2960–2971 (1988). Google Scholar

24

Swanson G. L., ““Binary optics technology: The theory and design of multi-level diffractive optical elements,”,” Lincoln Laboratory Tech. Report, 854 (1989). Google Scholar

25

Swanson G. L., ““Binary optics technology: Theoretical limits on the diffraction efficiency of multilevel diffractive optical elements,”,” Lincoln Laboratory Tech. Report, 914 (1991). Google Scholar

26

Traub W. A., ““Constant-dispersion grism spectrometer for channeled spectra,”,” J. Opt. Soc. Amer., 7 (9), 1779–1791 (1990). Google Scholar

27

Veldcamp W. B., Swanson G. J., Shaver D. C., ““High efficiency binary lenses,”,” Opt. Comm., 53 353–358 (1985). Google Scholar

28

Wyrowski F., Bryngdahl O., ““Digital holography as part of diffractive optics,”,” Reports on Progress in Physics, 54 1481–1571 (1991). Google Scholar

Yakov G. Soskind is Principal Systems Engineer for DHPC Technologies, Inc., in Woodbridge, NJ. He provides innovative solutions and technical expertise to customers in the areas of laser optics, electro-optical sensors, photonics instrumentation, and system-level integration.

Dr. Soskind is a recognized expert in the fields of optical design, diffractive optics, laser systems, and illumination. For more than 30 years, he has contributed to the fields of electro-optical and photonics engineering, successfully reducing to practice numerous innovative solutions in the form of fiber optics and photonics devices, diffractive structures, laser optics, imaging, and illumination devices. His innovative work in the field of diffractive optics has led to the development of novel types of diffractive structures that have enhanced diffraction efficiency and are covered in several issued patents.

Dr. Soskind has been awarded more than 20 domestic and international patents and has authored and co-authored several publications and conference presentations. He also serves on the technical committees of two international conferences.

TOPIC
9 PAGES

DOWNLOAD PDF SAVE TO MY LIBRARY

DOWNLOAD FULL FIELD GUIDE (PDF)