Capacity of MIMO free space optical communications using multiple partially coherent beams propagation through non-Kolmogorov strong turbulence.

We study the average capacity performance for multiple-input multiple-output (MIMO) free-space optical (FSO) communication systems using multiple partially coherent beams propagating through non-Kolmogorov strong turbulence, assuming equal gain combining diversity configuration and the sum of multiple gamma-gamma random variables for multiple independent partially coherent beams. The closed-form expressions of scintillation and average capacity are derived and then used to analyze the dependence on the number of independent diversity branches, power law α, refractive-index structure parameter, propagation distance and spatial coherence length of source beams. Obtained results show that, the average capacity increases more significantly with the increase in the rank of MIMO channel matrix compared with the diversity order. The effect of the diversity order on the average capacity is independent of the power law, turbulence strength parameter and spatial coherence length, whereas these effects on average capacity are gradually mitigated as the diversity order increases. The average capacity increases and saturates with the decreasing spatial coherence length, at rates depending on the diversity order, power law and turbulence strength. There exist optimal values of the spatial coherence length and diversity configuration for maximizing the average capacity of MIMO FSO links over a variety of atmospheric turbulence conditions.

[1]  Peng Yue,et al.  Formula for the average bit error rate of free-space optical systems with dual-branch equal-gain combining over gamma-gamma turbulence channels. , 2013, Optics letters.

[2]  Kostas Dangakis,et al.  Simple, accurate formula for the average bit error probability of multiple-input multiple-output free-space optical links over negative exponential turbulence channels. , 2012, Optics letters.

[3]  Peng Deng,et al.  Scintillation of a laser beam propagation through non-Kolmogorov strong turbulence , 2012 .

[4]  Xu Liu,et al.  Average capacity of free-space optical systems for a partially coherent beam propagating through non-Kolmogorov turbulence. , 2011, Optics letters.

[5]  Antonio García-Zambrana,et al.  Outage performance of MIMO FSO links over strong turbulence and misalignment fading channels. , 2011, Optics express.

[6]  Peng Deng,et al.  Influence of wind speed on free space optical communication performance for Gaussian beam propagation through non Kolmogorov strong turbulence , 2011 .

[7]  Jason A. Tellez,et al.  Multibeam scintillation cumulative distribution function. , 2011, Optics letters.

[8]  Deva K. Borah,et al.  Spatially partially coherent beam parameter optimization for free space optical communications. , 2010, Optics express.

[9]  Yongxiong Ren,et al.  Influence of beam wander on uplink of ground-to-satellite laser communication and optimization for transmitter beam radius. , 2010, Optics letters.

[10]  O. Korotkova,et al.  Second-order statistics of stochastic electromagnetic beams propagating through non-Kolmogorov turbulence. , 2010, Optics express.

[11]  George K. Karagiannidis,et al.  On the Distribution of the Sum of Gamma-Gamma Variates and Application in MIMO Optical Wireless Systems , 2009, GLOBECOM 2009 - 2009 IEEE Global Telecommunications Conference.

[12]  Ranjan K. Mallik,et al.  Performance analysis of MIMO free-space optical systems in gamma-gamma fading , 2009, IEEE Transactions on Communications.

[13]  J. Kahn,et al.  Capacity of coherent free-space optical links using diversity-combining techniques. , 2009, Optics express.

[14]  S. V. Torous,et al.  Reduction of laser intensity scintillations in turbulent atmospheres using time averaging of a partially coherent beam , 2009, 0906.4576.

[15]  K. Peppas,et al.  Average Capacity of Optical Wireless Communication Systems Over Atmospheric Turbulence Channels , 2009, Journal of Lightwave Technology.

[16]  Yangjian Cai,et al.  Scintillations of partially coherent multiple Gaussian beams in turbulence. , 2009, Applied optics.

[17]  Mohsen Kavehrad,et al.  Using MIMO transmissions in free-space optical communications in presence of clouds and turbulence , 2009, LASE.

[18]  Arnold Tunick,et al.  Optical turbulence parameters characterized via optical measurements over a 2.33 km free-space laser path. , 2008, Optics express.

[19]  William G. Cowley,et al.  The Gaussian free space optical MIMO channel with Q-ary pulse position modulation , 2008, IEEE Transactions on Wireless Communications.

[20]  Mark A Neifeld,et al.  Spatial correlation and irradiance statistics in a multiple-beam terrestrial free-space optical communication link. , 2007, Applied optics.

[21]  Mohsen Kavehrad,et al.  BER Performance of Free-Space Optical Transmission with Spatial Diversity , 2007, IEEE Transactions on Wireless Communications.

[22]  Italo Toselli,et al.  Free space optical system performance for laser beam propagation through non-Kolmogorov turbulence , 2007, SPIE LASE.

[23]  Murat Uysal,et al.  Error rate performance analysis of coded free-space optical links over gamma-gamma atmospheric turbulence channels , 2006, IEEE Transactions on Wireless Communications.

[24]  Mohsen Kavehrad,et al.  Transceiver Design Concept for Cellular and Multispot Diffusing Regimes of Transmission , 2005, EURASIP J. Wirel. Commun. Netw..

[25]  L. Andrews,et al.  Model for a partially coherent Gaussian beam in atmospheric turbulence with application in lasercom , 2004 .

[26]  Helmut Bölcskei,et al.  Tight lower bounds on the ergodic capacity of Rayleigh fading MIMO channels , 2002, Global Telecommunications Conference, 2002. GLOBECOM '02. IEEE.

[27]  J. Ricklin,et al.  Atmospheric turbulence effects on a partially coherent Gaussian beam: implications for free-space laser communication. , 2002, Journal of the Optical Society of America. A, Optics, image science, and vision.

[28]  L. Andrews,et al.  Mathematical model for the irradiance probability density function of a laser beam propagating through turbulent media , 2001 .

[29]  H. Hemmati,et al.  Free-Space Optical Communications at NASA , 1999 .

[30]  Joseph M. Kahn,et al.  Imaging diversity receivers for high-speed infrared wireless communication , 1998, IEEE Commun. Mag..

[31]  M. J. Gans,et al.  On Limits of Wireless Communications in a Fading Environment when Using Multiple Antennas , 1998, Wirel. Pers. Commun..

[32]  Isaac I. Kim,et al.  Scintillation reduction using multiple transmitters , 1997, Photonics West.

[33]  Mohsen Kavehrad,et al.  Spot-diffusing and fly-eye receivers for indoor infrared wireless communications , 1992, 1992 IEEE International Conference on Selected Topics in Wireless Communications.

[34]  O. Korotkova Atmospheric Propagation of Electromagnetic Waves III , 2008 .