Considerations for Atmospheric Measurements with Small Unmanned Aircraft Systems

This paper discusses results of the CLOUD-MAP (Collaboration Leading Operational UAS Development for Meteorology and Atmospheric Physics) project dedicated to developing, fielding, and evaluating integrated small unmanned aircraft systems (sUAS) for enhanced atmospheric physics measurements. The project team includes atmospheric scientists, meteorologists, engineers, computer scientists, geographers, and chemists necessary to evaluate the needs and develop the advanced sensing and imaging, robust autonomous navigation, enhanced data communication, and data management capabilities required to use sUAS in atmospheric physics. Annual integrated evaluation of the systems in coordinated field tests are being used to validate sensor performance while integrated into various sUAS platforms. This paper focuses on aspects related to atmospheric sampling of thermodynamic parameters with sUAS, specifically sensor integration and calibration/validation, particularly as it relates to boundary layer profiling. Validation of sensor output is performed by comparing measurements with known values, including instrumented towers, radiosondes, and other validated sUAS platforms. Experiments to determine the impact of sensor location and vehicle operation have been performed, with sensor aspiration a major factor. Measurements are robust provided that instrument packages are properly mounted in locations that provide adequate air flow and proper solar shielding.

[1]  E. Salas,et al.  Facilitating Innovation in Diverse Science Teams Through Integrative Capacity , 2012 .

[2]  J. Jacob,et al.  Evaluation of Low Altitude Icing Conditions for Small Unmanned Aircraft , 2017 .

[3]  Michael D. Eilts,et al.  The Oklahoma Mesonet: A Technical Overview , 1995 .

[4]  Steven R. Evett,et al.  The Soil Moisture Active Passive Marena, Oklahoma, In Situ Sensor Testbed (SMAP‐MOISST): Testbed Design and Evaluation of In Situ Sensors , 2016 .

[5]  Adam L. Houston,et al.  The Impact of Sensor Response and Airspeed on the Representation of the Convective Boundary Layer and Airmass Boundaries by Small Unmanned Aircraft Systems , 2018, Journal of Atmospheric and Oceanic Technology.

[6]  Jamey Jacob,et al.  Vertical Sampling Scales for Atmospheric Boundary Layer Measurements from Small Unmanned Aircraft Systems (sUAS) , 2017 .

[7]  Pedro M. M. Soares,et al.  Parameterization of the atmospheric boundary layer: A View from just above the inversion , 2008 .

[8]  Tevis W. Nichols,et al.  Intercomparison of Unmanned Aircraftborne and Mobile Mesonet Atmospheric Sensors , 2016 .

[9]  David D. Turner,et al.  The ARM Southern Great Plains (SGP) Site , 2016 .

[10]  Phillip B. Chilson,et al.  Considerations for temperature sensor placement on rotary-wing unmanned aircraft systems , 2018, Atmospheric Measurement Techniques.

[11]  Steven E. Koch,et al.  Thermodynamic Profiling Technologies Workshop report to the National Science Foundation and the National Weather Service , 2012 .

[12]  Eric W. Frew,et al.  Sampling Severe Local Storms and Related Phenomena: Using Unmanned Aircraft Systems , 2012, IEEE Robotics & Automation Magazine.

[13]  Eric W. Frew,et al.  Guidelines and Best Practices for FAA Certificate of Authorization Applications for Small Unmanned Aircraft , 2011 .

[14]  Yuanfu Xie,et al.  Evaluation of the Earth Systems Research Laboratory's global Observing System Simulation Experiment system , 2013 .

[15]  C. Bretherton,et al.  Parameterization of the Atmospheric Boundary Layer , 2005 .

[16]  A. Houston,et al.  An Observational and Modeling Study of Mesoscale Air Masses with High Theta-E , 2017, Monthly Weather Review.

[17]  Optimal Strategies for Meteorological Measurements with Unmanned Aircraft , 2017 .

[18]  Derek R. Stratman,et al.  Use of Multiple Verification Methods to Evaluate Forecasts of Convection from Hot- and Cold-Start Convection-Allowing Models , 2013 .

[19]  R. Harden,et al.  The integration ladder: a tool for curriculum planning and evaluation , 2000, Medical education.

[20]  Erik N. Rasmussen,et al.  A Mobile Mesonet for Finescale Meteorological Observations , 1996 .

[21]  F. Guichard,et al.  Boundary-layer turbulent processes and mesoscale variability represented by Numerical Weather Prediction models during the BLLAST campaign , 2016 .

[22]  Steven E. Koch,et al.  THE VALUE OF WIND PROFILER DATA IN U.S. WEATHER FORECASTING , 2004 .

[23]  Cornelia Schlagenhauf,et al.  Measurement of High Reynolds Number Turbulence in the Atmospheric Boundary Layer Using Unmanned Aerial Vehicles , 2017 .

[24]  Michael A. Thamann,et al.  Fundamental Turbulence Measurement with Unmanned Aerial Vehicles (Invited) , 2016 .

[25]  R. Stull An Introduction to Boundary Layer Meteorology , 1988 .

[26]  Eric W. Frew,et al.  The NCAR / EOL Community Workshop on Unmanned Aircraft Systems for Atmospheric Research , 2017 .

[27]  Sutherland,et al.  Statewide Monitoring of the Mesoscale Environment: A Technical Update on the Oklahoma Mesonet , 2007 .