Article Type:
Research Article

An Airborne and Wind Tunnel Evaluation of a Wind Turbulence Measurement System for Aircraft-Based Flux Measurements

K. E. Garman Department of Earth and Atmospheric Sciences, and Department of Aviation Technology, and Department of Chemistry, Purdue University, West Lafayette, Indiana

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K. A. Hill Department of Earth and Atmospheric Sciences, Purdue University, West Lafayette, Indiana

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P. Wyss Department of Earth and Atmospheric Sciences, Purdue University, West Lafayette, Indiana

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M. Carlsen Jonathan Amy Facility for Chemical Instrumentation, Purdue University, West Lafayette, Indiana

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J. R. Zimmerman Jonathan Amy Facility for Chemical Instrumentation, Purdue University, West Lafayette, Indiana

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B. H. Stirm Department of Aviation Technology, Purdue University, West Lafayette, Indiana

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T. Q. Carney Department of Aviation Technology, Purdue University, West Lafayette, Indiana

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R. Santini Jonathan Amy Facility for Chemical Instrumentation, and Department of Chemistry, Purdue University, West Lafayette, Indiana

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P. B. Shepson Department of Earth and Atmospheric Sciences, and Purdue Climate Change Research Center,

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Print Publication:
01 Dec 2006
DOI:
https://doi.org/10.1175/JTECH1940.1
Page(s):
1696–1708
Restricted access

Abstract

Although the ability to measure vertical eddy fluxes of gases from aircraft platforms represents an important capability to obtain spatially resolved data, accurate and reliable determination of the turbulent vertical velocity presents a great challenge. A nine-hole hemispherical probe known as the “Best Air Turbulence Probe” (often abbreviated as the “BAT Probe”) is frequently used in aircraft-based flux studies to sense the airflow angles and velocity relative to the aircraft. Instruments such as inertial navigation and global positioning systems allow the measured airflow to be converted into the three-dimensional wind velocity relative to the earth’s surface by taking into account the aircraft’s velocity and orientation. Calibration of the aircraft system has previously been performed primarily through in-flight experiments, where calibration coefficients were determined by performing various flight maneuvers. However, a rigorous test of the BAT Probe in a wind tunnel has not been previously undertaken.

The authors summarize the results of a complement of low-speed wind tunnel tests and in-flight calibrations for the aircraft–BAT Probe combination. Two key factors are addressed in this paper: The first is the correction of systematic error arising from airflow measurements with a noncalibrated BAT Probe. The second is the instrumental precision in measuring the vertical component of wind from the integrated aircraft-based wind measurement system. The wind tunnel calibration allows one to ascertain the extent to which the BAT Probe airflow measurements depart from a commonly used theoretical potential flow model and to correct for systematic errors that would be present if only the potential flow model were used. The precision in the determined vertical winds was estimated by propagating the precision of the BAT Probe data (determined from the wind tunnel study) and the inertial measurement precision (determined from in-flight tests). The precision of the vertical wind measurement for spatial scales larger than approximately 2 m is independent of aircraft flight speed over the range of airspeeds studied, and the 1σ precision is approximately 0.03 m s−1.

Corresponding author address: K. E. Garman, Purdue University, Purdue Climate Change Research Center, 560 Oval Dr., West Lafayette, IN 47906. Email: garman@purdue.edu

Abstract

Although the ability to measure vertical eddy fluxes of gases from aircraft platforms represents an important capability to obtain spatially resolved data, accurate and reliable determination of the turbulent vertical velocity presents a great challenge. A nine-hole hemispherical probe known as the “Best Air Turbulence Probe” (often abbreviated as the “BAT Probe”) is frequently used in aircraft-based flux studies to sense the airflow angles and velocity relative to the aircraft. Instruments such as inertial navigation and global positioning systems allow the measured airflow to be converted into the three-dimensional wind velocity relative to the earth’s surface by taking into account the aircraft’s velocity and orientation. Calibration of the aircraft system has previously been performed primarily through in-flight experiments, where calibration coefficients were determined by performing various flight maneuvers. However, a rigorous test of the BAT Probe in a wind tunnel has not been previously undertaken.

The authors summarize the results of a complement of low-speed wind tunnel tests and in-flight calibrations for the aircraft–BAT Probe combination. Two key factors are addressed in this paper: The first is the correction of systematic error arising from airflow measurements with a noncalibrated BAT Probe. The second is the instrumental precision in measuring the vertical component of wind from the integrated aircraft-based wind measurement system. The wind tunnel calibration allows one to ascertain the extent to which the BAT Probe airflow measurements depart from a commonly used theoretical potential flow model and to correct for systematic errors that would be present if only the potential flow model were used. The precision in the determined vertical winds was estimated by propagating the precision of the BAT Probe data (determined from the wind tunnel study) and the inertial measurement precision (determined from in-flight tests). The precision of the vertical wind measurement for spatial scales larger than approximately 2 m is independent of aircraft flight speed over the range of airspeeds studied, and the 1σ precision is approximately 0.03 m s−1.

Corresponding author address: K. E. Garman, Purdue University, Purdue Climate Change Research Center, 560 Oval Dr., West Lafayette, IN 47906. Email: garman@purdue.edu

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