7 research outputs found
Simulating the Afghanistan- Pakistan Opium Supply Chain
ABSTRACT This paper outlines an opium supply chain using the Hilmand province of Afghanistan as exemplar. The opium supply chain model follows the transformation of opium poppy seed through cultivation and chemical alteration to brown heroin base. The purpose of modeling and simulating the Afghanistan-Pakistan opium supply chain is to discover and test strategies that will disrupt this criminal enterprise
Wave optics simulation of atmospheric turbulence and reflective speckle effects in CO2 lidar
Applied Optics, Volume 39, No. 12, pp. 1857-1871 (20 April 2000)Laser speckle can influence lidar measurements from a diffuse hard target. Atmospheric optical turbulence
will also affect the lidar return signal. We present a numerical simulation that models the
propagation of a lidar beam and accounts for both reflective speckle and atmospheric turbulence effects.
Our simulation is based on implementing a Huygens- Fresnel approximation to laser propagation. A
series of phase screens, with the appropriate atmospheric statistical characteristics, are used to simulate
the effect of atmospheric turbulence. A single random phase screen is used to simulate scattering of the
entire beam from a rough surface. We compare the output of our numerical model with separate CO2
lidar measurements of atmospheric turbulence and reflective speckle. We also compare the output of
our model with separate analytical predictions for atmospheric turbulence and reflective speckle. Good
agreement was found between the model and the experimental data. Good agreement was also found
with analytical predictions. Finally, we present results of a simulation of the combined effects on a
finite-aperture lidar system that are qualitatively consistent with previous experimental observations of
increasing rms noise with increasing turbulence level.This research was fully supported by the U.S. Department of Energy under contract W-7405-ENG-36
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Wave optics simulation of atmospheric turbulence and reflective speckle effects in CO2 differential absorption LIDAR (DIAL)
AEROSENSE 98 Meeting Orlando Fl, April 1998The article of record as published may be found at http://dx.doi.org/10.1117/12.323933The measurement sensitivity of C02 differential absorption LIDAR (DIAL) can be affected by a number of different processes. We will address the interaction of two of these processes: effects due to beam propagation through atmospheric turbulence and effects due to reflective speckle. Atmospheric
turbulence affects the beam distribution of energy and phase on target. These effects include beam
spreading, beam wander and scintillation which can result in increased shot-to-shot signal noise.
In addition, reflective speckle alone has a major impact on the sensitivity of C02 DIAL. The
interaction of atmospheric turbulence and reflective speckle is of great importance in the performance of a DIAL system.. A Huygens Fresnel wave optics propagation code has previously been developed at the Naval Postgraduate School that models the effects of atmospheric turbulence as propagation through a series of phase screens with appropriate atmospheric statistical characteristics. This code has been modified to include the effects of reflective speckle. The performance of this modified code with respect to the combined effects of atmospheric turbulence and reflective speckle is examined. Results are compared with a combination of experimental data and analytical models.Approved for public release; distribution is unlimited
Wave optics simulation of atmospheric turbulence and reflective speckle effects in CO{sub 2} lidar
The article of record as published may be found at https://doi.org/10.1364/AO.39.001857Laser speckle can influence lidar measurements from a diffuse hard target. Atmospheric optical turbulence will also affect the lidar return signal. We present a numerical simulation that models the propagation of a lidar beam and accounts for both reflective speckle and atmospheric turbulence effects. Our simulation is based on implementing a Huygens-Fresnel approximation to laser propagation. A series of phase screens, with the appropriate atmospheric statistical characteristics, are used to simulate the effect of atmospheric turbulence. A single random phase screen is used to simulate scattering of the entire beam from a rough surface. We compare the output of our numerical model with separate CO{sub 2} lidar measurements of atmospheric turbulence and reflective speckle. We also compare the output of our model with separate analytical predictions for atmospheric turbulence and reflective speckle. Good agreement was found between the model and the experimental data. Good agreement was also found with analytical predictions. Finally, we present results of a simulation of the combined effects on a finite-aperture lidar system that are qualitatively consistent with previous experimental observations of increasing rms noise with increasing turbulence level. (c) 2000 Optical Society of America
Huygens-Fresnel wave-optics simulation of atmospheric optical turbulence and reflective speckle in CO2 differential absorption LIDAR (DIAL)
The measurement sensitivity of C02 differential absorption lidar (DIAL) can be affected by a number
of different processes. We have previously developed a Huygens-Fresnel wave optics propagation code
to simulate the effects of two of these processes: effects caused by beam propagation through
atmospheric optical turbulence and effects caused by reflective speckle. Atmospheric optical turbulence affects the beam distribution of energy and phase on target. These effects include beam spreading, beam wander and scintillation which can result in increased shot-to-shot signal noise. In addition, reflective speckle alone has been shown to have a major impact on the sensitivity of C02 DIAL. However, in real DIAL systems it is a combination of these phenomena, the interaction of atmospheric optical turbulence and reflective speckle, that influences the results. In this work, we briefly review a description of our model including the limitations along with previous simulations of individual effects. The performance of our modified code with respect to experimental measurements affected by atmospheric optical turbulence and reflective speckle is examined. The results of computer simulations are directly compared with lidar measurements and show good agreement. In addition, advanced studies have been performed to demonstrate the utility of our model in assessing the effects for different lidar geometries on RMS noise and correlation "size" in the receiver plane.U.S. Department of EnergyW-7405-ENG-3