Low-Loss Wavelength-Multiplexed Optical Scanners using Volume Bragg Gratings for Transmit-Receive Lasercom Systems

Proceedings of SPIE - The International Society for Optical Engineering

Volumn 5160, Issue , 2003, Pages 369-380

  Yaqoob, Zahid ^a   Riza, Nabeel A ^a  

^a UNIVERSITY OF CENTRAL FLORIDA   (United States)

Author keywords

Bragg diffraction gratings; Free space Lasercom; Optical scanners; Wavelength multiplexing

Indexed keywords

BRAGG DIFFRACTION GRATINGS; FREE-SPACE LASERCOM; OPTICAL SCANNERS;

BANDWIDTH; DIFFRACTION; FIBER BRAGG GRATINGS; MATHEMATICAL MODELS; OPTICAL COMMUNICATION; SCANNING; WAVELENGTH DIVISION MULTIPLEXING;

SPACE OPTICS;

EID: 3142775758     PISSN: 0277786X     EISSN: None     Source Type: Conference Proceeding    
DOI: 10.1117/12.504378     Document Type: Conference Paper

References (16)

1. th Annual Meeting, Invited Paper (WD2), Glasgow, Scotland, November 10-14, 2002.
2. th Annual Meeting, Invited Paper (WL1), Glasgow, Scotland, November 10-14, 2002.
3. C. Chen, J. W. Alexender, H. Hemati, S. Monacos, T. Yan, S. Lee, J. R. Lesh, and S. Zingales, "System requirements for a deep space optical transceiver," in Free-Space Laser Communication Technologies XI, Proc. SPIE Vol. 3615, 142-152, San Jose, CA, 1999.
4. W. Klaus, "Development of LC optics for free-space laser communications," International Journal of Electronics and Communications, 56(4), 243-253 (2002).
5. R. L. Forward, "Passive beam-deflecting apparatus," US Patent No. 3,612,659, October 12, 1971.
6. K. G. Leib, "Radiation beam deflection system," US Patent No. 4,250,465, February 10, 1981.
7. Z. Yaqoob, A. A. Rizvi, and N. A. Riza, "Free-space wavelength-multiplexed optical scanner," Applied Optics-IP, 40(35), 6425-6438, December 10, 2001.
8. Z. Yaqoob and N. A. Riza, "Free-space wavelength-multiplexed optical scanner demonstration," Applied Optics-IP, 41(26), 5568-5573, September 10 (2002).
9. L. B. Glebov, N. V. Nikonorov, E. I. Panysheva, G. T. Petrovskii, V. V. Savvin, I. V. Tunimanova, and V. A. Tsekhomskii, "New ways to use photosensitive glasses for recording volume phase holograms," Opt. Spectrosc. 73, 237-241 (1992).
10. O. M. Efimov, L. B. Glebov, L. N. Glebova, K. C. Richardson, and V. I. Smirnov, "High-efficiency Bragg gratings in photothermorefractive glass," Applied Optics-OT, 38(4), 619-627 (February 1999).
11. Z. Yaqoob, M. A. Arain, and N. A. Riza, "High-speed two-dimensional laser scanner by use of Bragg gratings in photothermorefractive glass," Applied Optics-IP, 42(26), September 10, 2003.
12. L. D. Dickson, "Method for making holographic optical elements with high diffraction efficiencies," US Patent No. 4,416,505, November 22, 1983.
13. H. Kogelnik, "Coupled wave theory for thick hologram gratings," Bell System Tech. J. 48, pp. 2909-2945, 1969.
14. A. Yariv and P. Yeh, Optical Waves in Crystals: Propagation and Control of Laser Radiation, John Wiley & Sons, Inc. (1984).
15. G. Alibert, F. Delorme, P. Boulet, J. Landreau, H. Nakajima, "Subnanosecond tunable laser using a single electroabsorption tuning super structure grating," IEEE Photonics Technology Letters, 9(7), 895-897 (1997).
16. Delorme, G. Alibert, C. Ougier, S. Slempkes, and H. Nakajima, "Sampled-grating DBR lasers with 181 wavelengths over 44 nm and optimized power variation for WDM applications," in Optical Fiber Communication (OFC '98), 379-381 (1998).