Cloud Physics Lidar on the Global Hawk HS3 Science Team Meeting May 7-9, 2013 Matthew McGill / GSFC Dennis Hlavka / SSAI Andrew Kupchock/ SSAI Steve Palm.

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Cloud Physics Lidar on the Global Hawk HS3 Science Team Meeting May 7-9, 2013 Matthew McGill / GSFC Dennis Hlavka / SSAI Andrew Kupchock/ SSAI Steve Palm / SSAI Dan Reed/ Sigma Space Bill Hart / SSAI

CPL for Global Hawk AV-6 (Environmental)

Global Hawk CPL Data Products cpl.gsfc.nasa.gov/hs3_2012/hs3_2012_enter.htm Outline of CPL Data Products: Global Hawk flights are broken up into ~ 6hr segments for processing, with two large binary files created for each: Products produced from the NRB (normalized relative backscatter) binary file (within ~60 hours of landing): 1.Curtain plots of attenuated backscatter for full segment 2.Curtain plots of att. backscatter for each 30-minute slice 3.Layer boundaries for PBL, elevated aerosol layers, clouds 4. Depolarization ratio profiles (1064 nm) for ice/water phase Products produced from the OP (optical properties) binary file (usually after the mission is over): 1.layer optical depth and column tot. (aerosol, cloud, total) 2.layer extinction-to-backscatter ratio (lidar ratio) used 3.extinction profiles inside identified layers 4.particulate backscatter profiles corrected for attenuation 5.Plots of extinction and optical depth for each 30-min. slice

Global Hawk CPL Data Products cpl.gsfc.nasa.gov/hs3_2012/hs3_2012_enter.htm Status of Data Products for HS3_12:  Data processing is complete, with images and text files available on the web.  The NRB and OP binary files containing backscatter profiles, layer locations, and optical properties can be ordered from the web (at the bottom of each flight segment page).  Data products are 1 second averages (~170 m horiz. X 30 m vertical) produced from the raw 10 hertz data.* * Exceptions:  During the 11Sep12 and 14Sep12 flights, condensation on the window lead to weaker signals.  We had to average the data to 6 seconds horizontally and, after manual calibration, the resulting backscatter was improved for these flights, especially for high clouds.  However, the layer detection algorithm could not use this custom calibration and missed the thin cirrus in many cases, resulting in under-analysis of the extinction profiles and optical depth for these two flights. Layers with stronger signals should be ok.

HS3 CPL Products Transect of Tropical Storm Nadine 09/27/12

HS3 CPL Products Transect of Tropical Storm Nadine 09/27/12

HS3 CPL Products Transect of Tropical Storm Nadine 09/27/12 Depol (Water Phase) Water: 0 – 0.12 Mixed: 0.12 – 0.27 Ice: > 0.27

HS3 CPL Products Transect of Tropical Storm Nadine 09/27/12

Global Hawk CPL Instrument and Real-time Product Status The instrument is ready for integration. New for 2013: 1.A new shorter, lighter mirror has been installed which gave good results during ATTREX in February. 2.The real-time backscatter image transfer to Mission Tools was improved and simplified during ATTREX. 3.The real-time CPL console program is now more automated. As a default, we will save (and transfer to MTS) an image once every 8 minutes, which covers the time span in one image. During focus periods, we can increase that rate down to 1 minute. 4.The image height scale has both km and feet.

Global Hawk CPL Instrument and Real-time Product Status Examples of real-time displays: With Ku Without Ku

ER-2 CPL Inter-comparison 23Sep12 ER-2 westbound, Global Hawk westbound Global Hawk track (red) ER-2 track (black) Exact Coincidence (G) Segment endpoints (X) X x

ER-2 CPL Inter-comparison 23Sep12 ER-2 westbound, Global Hawk westbound Global Hawk: (Sortie 12207D) Segment Time> 16:47:24-17:20:23 utc Segment Latitude> Segment Longitude> ER-2 (Sortie 12924) Segment Time> 16:53:55-17:20:44 utc Segment Latitude> Segment Longitude> (same direction) Exact Coincidence Time> 17:23: utc (3 minutes after end of segment) Global Hawk Latitude/Longitude> / ER-2 Latitude/Longitude> / Remarks: Exact coincidence occurs after the segment ends during ER-2 crossover point. At the eastern end of the coincidence, the two aircraft are ~6 minutes apart, improving to 0 minutes apart at the western end. The whole segment is useful for comparison.

ER-2 CPL Inter-comparison 1064 nm Attenuated Backscatter Profiles ER-2 Global Hawk

ER-2 CPL Inter-comparison Depolarization Ratio Retrievals ER-2 Global Hawk

ER-2 CPL Inter-comparison 1064 nm Extinction Profiles ER-2 Global Hawk

ER-2 CPL Inter-comparison 1064 nm Cumulative Optical Depth ER-2 Global Hawk

Global Hawk CPL The End

Global Hawk CPL Extras Global Hawk Instrumentation: Cloud Physics Lidar (CPL) Publications describing processing algorithms: McGill, M.J., D.L. Hlavka, W.D. Hart, E.J. Welton, and J.R. Campbell, "Airborne lidar measurements of aerosol optical properties during SAFARI-2000", J. Geophys. Res., 108, doi: /2002JD002370, Yorks, J. E., M. McGill, D. Hlavka and W. Hart (2011), Statistics of Cloud Optical Properties from Airborne Lidar Measurements, J. Atmos. Oceanic Technol., 28, , doi: /2011JTECHA Yorks, J. E., D. L. Hlavka, M. A. Vaughan, M. J. McGill, W. D. Hart, S. Rodier, and R. Kuehn (2011), Airborne validation of cirrus cloud properties derived from CALIPSO lidar measurements: Spatial properties, J. Geophys. Res., 116, D19207, doi: /2011JD Hlavka, D. L., J. E. Yorks, S. Young, M. A. Vaughan, R. Kuehn, M. J. McGill, and S. Rodier (2012), Airborne validation of cirrus cloud properties derived from CALIPSO lidar measurements: Optical properties, submitted to J. Geophys. Res.. Publications describing data quality: McGill, M., D. Hlavka, W. Hart, J. Spinhirne, V. S. Scott, B. Schmid, 2002: The Cloud Physics Lidar: Instrument Description and Initial Measurement Results, Applied Optics, 41, No. 18, Schmid, B., J. Redemann, P.B. Russell, P.V. Hobbs, D.L. Hlavka, M.J. McGill, B.N. Holben, E.J. Welton, J. Campbell, O. Torres, R. Kahn, D.J. Diner, M.C. Helmlinger, D.A. Chu, C. Robles-Gonzalez, and G. de Leeuw, “Coordinated airborne, spaceborne, and ground-based measurements of massive, thick aerosol layers during the dry season in Southern Africa”, J. Geophys. Res., 108, doi: /2002JD002297, Hlavka, D. L., S. P. Palm, W. D. Hart, J. D. Spinhirne, M. J. McGill, and E. J. Welton (2005), Aerosol and cloud optical depth from GLAS: Results and Verification for an October 2003 California fire smoke case, Geophys. Res. Lett., 32, L22S07, doi: /2005GL