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Larry B Stotts

Showing results (1-10 of 11) with videos related to

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Optics Express|May 9, 2023
Improving the Hufnagel-Andrews-Phillips refractive index structure parameter model using turbulent intensityLarry B Stotts, Larry C Andrews
Applied Optics|August 5, 2014
Statistical detection of resolved targets in background clutter using optical/infrared imageryLarry B Stotts, Lawrence E Hoff
Optics Express|July 16, 2021
Adaptive optics model characterizing turbulence mitigation for free space optical communications link budgetsLarry B Stotts, Larry C Andrews
Optics Express|February 25, 2022
Probability density function estimation for filament creation in lossy, turbulent, nonlinear mediaLarry B Stotts, Antonio Oliver, Joseph R Peñano
Optics Express|June 6, 2019
Engineering equation for filamentation self-focusing collapse distance in atmospheric turbulenceLarry B Stotts, Joseph Peñano, Vincent J Urick
Optics Express|June 7, 2011
High-sensitivity DPSK receiver for high-bandwidth free-space optical communication linksJuan C Juarez, David W Young, Joseph E Sluz, et al.
Applied Optics|October 2, 2010
Free-space optical communications link budget estimationLarry B Stotts, Paul Kolodzy, Alan Pike, et al.
Optics Express|May 3, 2018
Engineering equations for characterizing nonlinear laser intensity propagation in air with loss: erratumThomas Karr, Larry B Stotts, Jason A Tellez, et al.
Optics Express|February 25, 2018
Engineering equations for characterizing non-linear laser intensity propagation in air with lossThomas Karr, Larry B Stotts, Jason A Tellez, et al.
Optics Express|September 13, 2019
Engineering equations for the filamentation collapse distance in lossy, turbulent, nonlinear mediaLarry B Stotts, Joseph R Peñano, Jason A Tellez, et al.
Pageof 2

Showing results (1-10 of 11) with videos related to

Sort By:
Pageof 2
Optics Express|May 9, 2023
Improving the Hufnagel-Andrews-Phillips refractive index structure parameter model using turbulent intensityLarry B Stotts, Larry C Andrews
Applied Optics|August 5, 2014
Statistical detection of resolved targets in background clutter using optical/infrared imageryLarry B Stotts, Lawrence E Hoff
Optics Express|July 16, 2021
Adaptive optics model characterizing turbulence mitigation for free space optical communications link budgetsLarry B Stotts, Larry C Andrews
Optics Express|February 25, 2022
Probability density function estimation for filament creation in lossy, turbulent, nonlinear mediaLarry B Stotts, Antonio Oliver, Joseph R Peñano
Optics Express|June 6, 2019
Engineering equation for filamentation self-focusing collapse distance in atmospheric turbulenceLarry B Stotts, Joseph Peñano, Vincent J Urick
Optics Express|June 7, 2011
High-sensitivity DPSK receiver for high-bandwidth free-space optical communication linksJuan C Juarez, David W Young, Joseph E Sluz, et al.
Applied Optics|October 2, 2010
Free-space optical communications link budget estimationLarry B Stotts, Paul Kolodzy, Alan Pike, et al.
Optics Express|May 3, 2018
Engineering equations for characterizing nonlinear laser intensity propagation in air with loss: erratumThomas Karr, Larry B Stotts, Jason A Tellez, et al.
Optics Express|February 25, 2018
Engineering equations for characterizing non-linear laser intensity propagation in air with lossThomas Karr, Larry B Stotts, Jason A Tellez, et al.
Optics Express|September 13, 2019
Engineering equations for the filamentation collapse distance in lossy, turbulent, nonlinear mediaLarry B Stotts, Joseph R Peñano, Jason A Tellez, et al.
Pageof 2