Summary
Due to the increased use of laser and ground-to-satellite communications the need for reliable optical turbulence information is growing. Optical turbulence information is important because it describes an atmospheric effect that can degrade the performance of electromagnetic systems and sensors, e.g., free-space optical communications and infrared imaging. However, analysis of selected past research indicates that there are some areas (i.e., data and models) in which optical turbulence information is lacking. For example, line-of-sight optical turbulence data coupled with atmospheric models in hilly terrain, coastal areas, and within cities are few in number or non-existent. In addition, the bulk of existing atmospheric computer models being used to provide estimates of optical turbulence are basically one-dimensional in nature and assume uniform turbulence conditions over large areas. As a result, current optical turbulence theory and models may be deficient and in error for inhomogeneous (nonuniform) turbulence conditions, such as those that occur in urban environments or environments with changing topography and energy budgets. While it is anticipated that theoretical advances in environmental physics (and like disciplines) will be a catalyst for much new work this area, in the interim, we suggest that some very practical computational research can be performed to extend existing low-atmospheric turbulence and micrometeorological calculations beyond current limitations.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
EL Andreas (1988) ArticleTitleEstimating C n 2 over snow and sea ice from meteorological data. J Optic Soc Am 5 481–495
Beland RR (1993) Propagation through atmospheric turbulence. In: The Infrared Electro-Optical Systems Handbook (Accetta JS, Shumaker DL, eds). SPIE Press Monograph, PM10, Bellingham, WA
FK Brunner PV Angus-Leppan (1984) Geodetic refraction–effects of electromagnetic wave propagation through the atmosphere. Springer New York 213
S Businger R McLaren R Ogasawara D Simons RJ Wainscoat (2002) ArticleTitleStarcasting. Bull Amer Meteor Soc 83 858–871 Occurrence Handle10.1175/1520-0477(2002)083<0858:S>2.3.CO;2
T Chiba (1971) ArticleTitleSpot dancing of the laser beam propagated through the turbulent atmosphere. Appl Optics 10 2456–2461
CE Coulman J Vernin A Fuchs (1995) ArticleTitleOptical seeing–mechanism of formation of thin turbulent laminae in the atmosphere. Appl Optics 34 5461–5474
Donaldson C duP (1973) Construction of a dynamic model for the production of atmospheric turbulence and the dispersion of atmospheric pollutants. In: Workshop on Micrometeorology (Haugen DA, ed). Boston: Amer Meteor Soc, 313–392
P Drobinski AM Dabas P Delville PH Flamant J Pelon RM Hardesy (1999) ArticleTitleRefractive index structure parameter in the planetary boundary layer: Comparison of measurements taken with a 10.6 micron coherent lidar, a 0.9 micron scintillometer, and in-situ sensors. Appl Optics 38 1648–1656
PA Frederickson KL Davidson CR Zeisse CS Bendall (2000) ArticleTitleEstimating the refractive index structure parameter (C n 2) over the ocean using bulk methods. J Appl Meteor 39 1770–1783
DL Fried GE Mevers MP Keister (1967) ArticleTitleMeasurements of laser beam scintillation in the atmosphere. J Opt Soc Amer 57 787–797
AS Gurvich MA Kallistratova NS Time (1968) ArticleTitleFluctuations of the parameters of laser light wave propagating in the atmosphere. Radiofizika 11 1360–1370
RJ Hill (1989) ArticleTitleStructure functions and spectra of scalar quantities in the inertial-convective and viscous- convective ranges of turbulence. J Atmos Sci 46 2245–2251 Occurrence Handle10.1175/1520-0469(1989)046<2245:SFASOS>2.0.CO;2
RJ Hughes WT Buttler PG Kwiat SK Lamoreaux GL Morgan JE Nordholt CG Peterson (2000) ArticleTitleFree-space quantum key distribution. J Mod Optic 47 549–562 Occurrence Handle10.1080/095003400148376
Ishimaru A (1978) The beam wave case and remote sensing. In: Laser beam propagation in the atmosphere (Stronbehn JW, ed). New York: Springer, pp 129–170
MA Kallistratova DF Timanovskiy (1971) ArticleTitleThe distribution of the structure constant of refractive index fluctuations in the atmospheric surface layer. Izv An SSSR Fiz Atmos 7 46–48
NS Kopeika (1998) A system engineering approach to imaging. SPIE Optical Engineering Press Bellingham, WA 679
L Mahrt (1998) ArticleTitleStratified atmospheric boundary layers and breakdown of models. Theor Comp Fluid Dyn 11 263–279 Occurrence Handle10.1007/s001620050093
GL Mellor T Yamada (1982) ArticleTitleDevelopment of a turbulence closure model for geophysical fluid problems. Rev Geophys 20 851–875
AS Monin AM Obukhov (1954) ArticleTitleBasic regularity in turbulent mixing in the surface layer of the atmosphere. Tr Akad Nauk SSSR Geofiz Inst 24 163–187
GR Ochs RJ Hill (1985) ArticleTitleOptical-scintillation method for measuring turbulence inner-scale. Appl Optics 24 2430–2432
G Parry (1981) ArticleTitleMeasurement of atmospheric turbulence induced intensity fluctuation in a laser beam. Opt Acta 28 715–728
M Roth (2000) ArticleTitleReview of turbulence over cities. QJRMS 126 941–990 Occurrence Handle10.1256/smsqj.56408
JW Strohbehn (1968) ArticleTitleLine of site wave propagation in the turbulent atmosphere. Proc IEEE 56 1301–1318
VI Tatarski (1971) The effects of the turbulent atmosphere on wave propagation. Israel Program for Scientific Translations Jerusalem 472
Thiermann V, Karipot A, Dirmhirn I, Poschl P, Czekits C (1995) Optical turbulence over paved surfaces. In: Proc. Atmospheric Propagation and Remote Sensing IV SPIE 2471 (Dainty JC, ed), pp 197–203
Tunick A (2002) A critical assessment of selected past research on optical turbulence information in diverse microclimates. ARL-MR-521, US Army Research Laboratory, 2800 Powder Mill Rd, Adelphi, MD 20783-1197 (available from DTIC at http://stinet.dtic.mil/str/)
A Tunick (2003a) ArticleTitleCN2 model to calculate the micrometeorological influences on the refractive index structure parameter. Environ Modell Softw 18 165–171 Occurrence Handle10.1016/S1364-8152(02)00052-X
A Tunick (2003b) ArticleTitleCalculating the micrometeorological influences on the speed of sound through the atmosphere in forests. J Acoust Soc Amer 114 1796–1806 Occurrence Handle10.1121/1.1608960
Tunick A (2003c) A two-dimensional meteorological computer model for the forest canopy. ARL-MR-569, US Army Research Laboratory, 2800 Powder Mill Rd, Adelphi, MD 20783-1197 (available from DTIC at http://stinet.dtic.mil/str/)
A Tunick H Rachele FV Hansen TA Howell JL Steiner AD Schneider SR Evett (1994) ArticleTitleREBAL ‘92–A cooperative radiation and energy balance field study for imagery and EM propagation. Bull Amer Meteor Soc 75 421–430 Occurrence Handle10.1175/1520-0477(1994)075<0421:RCRAEB>2.0.CO;2
ML Wesely (1976) ArticleTitleThe combined effect of temperature and humidity fluctuations on refractive index. J Appl Meteor 15 43–49 Occurrence Handle10.1175/1520-0450(1976)015<0043:TCEOTA>2.0.CO;2
Wilson KE, Lesh JR, Araki K, Arimoto Y (1997) Overview of the ground-to-orbit lasercom demonstration (GOLD). In: Proc. Free-Space Laser Communication Technologies IX, SPIE 2990 (Mecherle GS, ed), pp 23–30
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Tunick, A. Toward increasing the accuracy and realism of future optical turbulence calculations. Meteorol. Atmos. Phys. 90, 159–164 (2005). https://doi.org/10.1007/s00703-004-0091-x
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s00703-004-0091-x