1. Comeron A, Bara J, Belmonte A, et al. “Inter-Islands Optical Link Tests” IEEE Photonics Technology Letters 2 (5): 380-381 MAY 1990.
2. Belmonte AM, Comeron A, Bara J, et al. “Averaging of collected-power fluctuations by a multiaperture receiver system” Optical Engineering 35 (10): 2775-2778 OCT 1996 (not available in electronic format).
3. Belmonte A, Comeron A, Rubio JA, et al. ”Atmospheric-turbulence-induced power-fade statistics for a multiaperture optical receiver” Applied Optics 36 (33): 8632-8638 NOV 20 1997.
4. Rubio JA, Belmonte A, Comeron A, “Numerical simulation of long-path spherical wave propagation in three-dimensional random media“, Optical Engineering, 38 (9): 1462-1469 SEP 1999.
5. Belmonte A, Rye BJ “Heterodyne lidar returns in the turbulent atmosphere: performance evaluation of simulated systems” Applied Optics 39 (15): 2401-2411 MAY 20 2000
6. Belmonte A “Feasibility study for the simulation of beam propagation: consideration of coherent lidar performance” Applied Optics 39 (30): 5426-5445 OCT 20 2000
7. Rodriguez A, Comeron A, Garcia D “Homodyne laser radar system for surface displacement monitoring” OPTICAL ENGINEERING 40 (3): 398-405 MAR 2001.
8. Dios F, Comeron A, Garcia-Vizcaino D ”On the choice of the number of samples in laser Doppler anemometry signal processing” OPTICAL ENGINEERING 40 (5): 774-782 MAY 2001.
9. Rodriguez A, Comeron A, Mesalles E “Performance assessment of a homodyne laser radar for surface displacement monitoring” Optical Engineering 40 (12): 2812-2821 DEC 2001
10. Belmonte A “Analyzing the efficiency of a practical heterodyne lidar in the turbulent atmosphere: telescope parameters” Optics Express 11 (17): 2041-2046 AUG 25 2003
11. Belmonte A “Angular misalignment contribution to practical heterodyne lidars in the turbulent atmosphere” Optics Express 11 (20): 2525-2531 OCT 6 2003
12. Belmonte A “Coherent power measurement uncertainty resulting from atmospheric turbulence” Optics Express 12 (1): 168-175 JAN 12 2004
13. Belmonte A “Coherent DIAL profiling in turbulent atmosphere” Optics Express 12 (7): 1249-1257 APR 5 2004
14. Dios F, Rubio JA, Rodriguez A, et al.” Scintillation and beam-wander analysis in an optical ground station-satellite uplink“ Applied Optics 43 (19): 3866-3873 JUL 1 2004.
15. Belmonte A “Temporal averaging of turbulence-induced uncertainties on coherent power measurements” Optics Express 12 (16): 3770-3777 AUG 9 2004.
16. Rodriguez A, Dios F, Rubio JA, Comeron A, "Temporal statistics of the beam-wander contribution to scintillation in ground-to-satellite optical links: an analytical approach”, Applied Optics, 44 (21) 20 July 2005, pp. 4574-4581.
17. Vetelino FS, Young C, Andrews L, Recolons J, "Aperture averaging effects on the probability density of irradiance fluctuations in moderate-to-strong turbulence", APPLIED OPTICS 46 (11): 2099-2108 APR 10 2007
18. R. Barrios and F. Dios, “Reply to comments on: “The exponentiated Weibull distribution family under aperture averaging for Gaussian beam waves”,” Opt. Express, vol. 20, no. 18, pp. 20684–20687, 2012.
19. R. Barrios and F. Dios, “Probability of fade and BER performance of FSO links over the exponentiated Weibull fading channel under aperture averaging,” in Advanced Free-Space Optical Communication Techniques and Applications, L. Laycock and H. J. White, Ed., Proc. SPIE, vol. 8540, pp. 85400D, 2012.
20. R. Barrios, “Contributions to Free-Space Optical Communications through the Turbulent Atmosphere,”  in 2012 Barcelona Forum on Ph.D. Research in Communications, X. Masip, X. Aragonés, J. Forné, J. L. Balczar, A. Rodríguez-Gómez, Ed., pp. 81–82, 2012.
21. R. Barrios and F. Dios, “Exponentiated Weibull model for the irradiance probability density function of a laser beam propagating through atmospheric turbulence,” Opt. Laser Technol., vol. 41,  no. 1,  pp. 13–20, 2013.

Book Chapter

R. Barrios and F. Dios, “Wireless Optical Communications through the Turbulent Atmosphere: A review,” in Optical Communications Systems, Chapter 1,  Narottam Das, InTech, pp. 3–40, 2012.