1901. Murray, John; Krueger, Arlin; Pavolonis, Michael; Matus, Alex and Williams, Earle. Next generation satellite remote sensing for the detection, characterization and tracking of the volcanic ash hazard to aviation. Raleigh, NC, National Weather Association, 2009, abstract.
1902. Murray, John; Vernier, Jean-Paul; Fairlie, T. Duncan; Pavolonis, Michael; Krotkov, Nickolay A.; Lindsay, Francis and Haynes, John. Filling the gaps: The synergistic application of satellite data for the volcanic ash threat to aviation. Reston, VA, American Institute of Aeronautics and Astronautics, 2013. Reprint # 8037.
1903. Murty, D. G. K.; Smith, W. L.; Woolf, H. M. and Hayden, C. M.. Comparison of radiances observed from satellite and aircraft with calculations by using two atmospheric transmittance models. Applied Optics, Volume: 33, Issue: 9, 1994, pp.1620-1628. Reprint # 1753.
1904. Nagle, F. W.. Meteorological FORTRAN. Boston, MA, American Meteorological Society, 1988, pp.316-322. Reprint # 818.
1905. Nagle, F. W.. The use of a simplified Kalman filter in continuously updating hemispheric analyses on a desk-top computer of modest capacity, incorporating NOAA-X and DMSP retrievals. Boston, MA, American Meteorological Society, 1992, pp.81-84. Reprint # 1925.
1906. Nagle, F. W.. The association of disparate satellite observations. Boston, MA, American Meteorological Society, 1998, pp.49-52. Reprint # 2612.
1907.
Nagle, F. W.. Satellite navigation and de-navigation. Madison, WI, University of Wisconsin-Madison, Space Science and Engineering Center, Cooperative Institute for Meteorological Satellite Studies (CIMSS), 1988, pp.197-205. Reprint # 5973. 
Link to PDF
1908. Nagle, F. W.. The use of a neural network in eigenvector retrievals. Boston, MA, American Meteorological Society, 1994, pp.512-515. Reprint # 1826.
1909. Nagle, F. W.. Satellite de-navigation. Boston, MA, American Meteorological Society, 1988, pp.361-366. Reprint # 823.
1910. Nagle, Frederick W. A description of prediction errors associated with the T-BUS-4 navigation message and a corrective procedure. Washington, DC, US Department of Commerce, National Oceanic and Atmospheric Administration (NOAA), National Environmental Satellite, Data, and Information Service (NESDIS), 1986. 28p. Call Number: C 55.13/2:NESDIS 16.
1911.
Nagle, Frederick W.. High-level Fortran. Session report from the IBM Share Fortran Project Swap Meet, 27-28 August 1987. Madison, WI, University of Wisconsin, Space Science and Engineering Center, Cooperative Institute for Meteorological Satellite Studies (CIMSS), 1987. Call Number: UW SSEC Publication no.87.08.N1. Link to PDF
1912. Nagle, Frederick W.. A numerical study in optimum track ship routing climatology. Monterey, CA, Department of the Navy, Naval Postgraduate School, Environmental Prediction Research Facility, 1972. vii, 174p. Call Number: D 208.14/8:10-72.
1913.
Nagle, Frederick W.. A description of prediction errors associated with the T-Bus-4 navigation message and a corrective procedure. Madison, WI, University of Wisconsin-Madison, Space Science and Engineering Center, Cooperative Institute for Meteorological Satellite Studies (CIMSS), 1986, pp.186-213. Reprint # 5959. Link to PDF
1914.
Nagle, Frederick W. and Holz, Robert E.. Computationally efficient methods of collocating satellite, aircraft, and ground observations. Journal of Atmospheric and Oceanic Technology, Volume: 26, Issue: 8, 2009, pp.1585-1595. Reprint # 6097. Link to PDF
1915. Nagle, Roland E. and Hayden, Christopher M.. The use of satellite-observed cloud patterns in northern-hemisphere 500-mb numerical analysis. Washington, DC, US Department of Commerce, National Oceanic and Atmospheric Administration (NOAA), National Environmental Satellite Service (NESS), 1971. iv, 25p., appendices, errata. Call Number: C 55.13:NESS 55.
1916.
Nagle, W. Frederick. A description of prediction errors associated with the T-bus-4 naviation message and a corrective procedure. Madison, WI, University of Wisconsin-Madison, Space Science and Engineering Center, Cooperative Institute for Meteorological Satellite Studies (CIMSS), 1986, pp.186-213. Link to PDF
1917. Nalli, Nicholas R. and Smith, William L.. Improved remote sensing of sea surface skin temperature using a physical retrieval algorithm. Hampton, VA, A. Deepak Publishing, 1997, pp.647-650. Reprint # 2482.
1918.
Nalli, Nicholas R. and Smith, William L.. Retrieval of ocean and lake surface temperatures from hyperspectral radiance observations. Journal of Atmospheric and Oceanic Technology, Volume: 20, Issue: 12, 2003, pp.1810-1825. Reprint # 4295. Link to PDF
1919. Nalli, Nicholas R. and Smith, William L.. Improved remote sensing of sea surface skin temperature using a physical retrieval method. Journal of Geophysical Research-Oceans, Volume: 103, 1998, pp.10,527-10,542. Reprint # 2453.
1920. Nalli, Nicholas R. and Smith, William L.. Physical retrieval and imaging of sea surface skin temperature from NAST-I: Initial results. Bellingham, WA, SPIE-International Society for Optical Engineering, 1999, pp.511-518. Reprint # 2710.
1921. Nalli, Nicholas R. and Smith, William L.. Physical retrieval of ocean and lake surface temperatures via scanning spectrometer. Hampton, VA, A. Deepak Publishing, 2001, pp.1023-1026. Reprint # 3673.
1922.
Nalli, Nicholas R.; Smith, William L. and Huang, Bormin. Quasi-specular model for calculating the reflection of atmospheric-emitted infrared radiation from a rough water surface. Applied Optics, Volume: 40, Issue: 9, 2001, pp.1343-1353. Reprint # 2915. Link to PDF
1923. Nalli, Nicholas R.; Smith, William L. and Huang, Bormin. A quasi-specular model for calculating infrared reflection at a rough water surface. Hampton, VA, A. Deepak Publishing, 2001, pp.377-380. Reprint # 3670.
1924. Nasiri, Shaima L.; Yang, P.; Baum, B. and Heidinger, A. K.. Building a framework for evaluating NPP and JPSS VIIRS cloud property retrievals. Boston, MA, American Meteorological Society, 2012, Abstract TJ25.3.
1925. Natarajan, M.; Pierce, R.; Schaack, T.; Lenzen, A.; Al-Saadi, J. A.; Soja, A. J.; Charlock. T. P. and Rose, F. G.. Radiative effects due to tropospheric ozone and carbonaceous aerosol enhancements caused by Asian wildfires during Spring, 2008. Washington, DC, American Geophysical Union, 2010, Abstract A31C-0072.