Quantifying variance due to temporal and spatial difference between ship and satellite winds

May, Jackie; Bourassa, Mark A.

doi:10.1029/2010jc006931

Cited by 24 publications

(18 citation statements)

References 30 publications

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“…The variance associated with buoy wind time series is translated into spatial wind variability using Taylor's hypothesis [Taylor, 1938], which allows for a temporal dimension to be converted into a spatial dimension, and vice versa. The time window (centered on the buoy measurement collocated with ASCAT acquisition) used for calculating the mean buoy winds and the subcell spatial variability is defined by May and Bourassa [2011],…”

Section: Taylor Hypothesissupporting

confidence: 70%

“…The variance associated with buoy wind time series is translated into spatial wind variability using Taylor's hypothesis [ Taylor , ], which allows for a temporal dimension to be converted into a spatial dimension, and vice versa. The time window (centered on the buoy measurement collocated with ASCAT acquisition) used for calculating the mean buoy winds and the subcell spatial variability is defined by May and Bourassa [],

t_{window} = \frac{l_{footprint}}{\bar{w}},

where l footprint is the ASCAT footprint size, and

\bar{w}

is the mean buoy wind speed within the time‐averaging window. As already mentioned, the spatial resolution of the averaged σ 0 in ASCAT 12.5 km L2 data is about 25 km and l footprint is set equal to 25 km.…”

Section: Datamentioning

confidence: 99%

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ASCAT wind quality under high subcell wind variability conditions

et al. 2015

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The assessment and validation of the quality of satellite scatterometer vector winds is challenging under increased subcell wind variability conditions, since reference wind sources such as buoy winds or model output represent very different spatial scales from those resolved by scatterometers (i.e., increased representativeness error). In this paper, moored buoy wind time series are used to assess the correlation between subcell wind variability and several Advanced Scatterometer (ASCAT)‐derived parameters, such as the wind‐inversion residual, the backscatter measurement variability factor, and the singularity exponents derived from an image processing technique, called singularity analysis. It is proven that all three ASCAT parameters are sensitive to the subcell wind variability and complementary in flagging the most variable winds, which is useful for further application. A triple collocation (TC) analysis of ASCAT, buoy, and the European Centre for Medium‐range Weather Forecasting (ECMWF) model output is then performed to assess the quality of each wind data source under different variability conditions. A novel approach is used to compute the representativeness errors, a key ingredient for the TC analysis. The experimental results show that the estimated errors of each wind source increase as the subcell wind variability increases. When temporally averaged buoy winds are used instead of 10 min buoy winds, the TC analysis results in smaller buoy wind errors (notably at increased wind variability conditions) while ASCAT and ECMWF errors do not significantly change, further validating the proposed TC approach. It is concluded that at 25 km resolution, ASCAT provides the best quality winds in general.

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Section: Taylor Hypothesissupporting

confidence: 70%

t_{window} = \frac{l_{footprint}}{\bar{w}},

where l footprint is the ASCAT footprint size, and

\bar{w}

Section: Datamentioning

confidence: 99%

ASCAT wind quality under high subcell wind variability conditions

et al. 2015

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“…Most of the parameterizations depend on U 10 and follow some form of a power law, but they were not developed for use with satellite-based winds. Satellite-based winds, which are reported as equivalent neutral 10 m winds U 10EN , differ from U 10 winds [Kara et al, 2008;May and Bourassa, 2011;Plagge et al, 2012]. Satellite winds are tuned to produce the correct stress when combined with a neutral drag coefficient.…”

Section: Whitecap Fraction Using Satellite Wind Speedsmentioning

confidence: 99%

Comparing in situ and satellite‐based parameterizations of oceanic whitecaps

2015

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The majority of the parameterizations developed to estimate whitecap fraction uses a stabilitydependent 10 m wind (U 10 ) measured in situ, but recent efforts to use satellite-reported equivalent neutral winds (U 10EN ) to estimate whitecap fraction with the same parameterizations introduce additional error. This study identifies and quantifies the differences in whitecap parameterizations caused by U 10 and U 10EN for the active and total whitecap fractions. New power law coefficients are presented for both U 10 and U 10EN parameterizations based on available in situ whitecap observations. One-way analysis of variance (ANOVA) tests are performed on the residuals of the whitecap parameterizations and the whitecap observations and identify that parameterizations in terms of U 10 and U 10EN perform similarly. The parameterizations are also tested against the satellite-based WindSat Whitecap Database to assess differences. The improved understanding aids in estimating whitecap fraction globally using satellite products and in determining the global effects of whitecaps on air-sea processes and remote sensing of the surface.

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“…For example, the TAO buoy data have long been utilized in calibrating model functions for deriving satellite wind speeds or wind vectors (e.g., Dunbar, Hsiao, & Lambrigtsen, 1991;Wentz, 1997;Stoffelen, 1998). In addition to being assimilated in model predictions and reanalyses, the buoy measurements are also valuable in evaluating products from models and satellites and providing error or uncertainty estimates for those products (e.g., Freilich & Dunbar, 1999;Mears, Smith, & Wentz, 2001;Ebuchi, Craber, & Caruso, 2002;Abdalla, Janssen, & Bidlot, 2011;May & Bourassa, 2011;Peng, Zhang, Frank, Bidlot, Higaki, Stevens, et al, 2013). This process is beneficial to both buoy array operators and data users -instrumental bias revealed by satellite data have led to TAO instrument improvement (Dickinson, Kelly, Caruso, & McPhaden, 2001;Freitag, O'Haleck, Thomas, & McPhaden, 2001 Figure 1, the WMO 51010 site is noted in the figure).…”

Section: Introductionmentioning

confidence: 99%

Directional Bias of TAO Daily Buoy Wind Vectors in the Central Equatorial Pacific Ocean from November 2008 to January 2010

et al. 2014

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This article documents a systematic bias in surface wind directions between the TAO buoy measurements at 0°, 170°W and the ECMWF analysis and forecasts. This bias was of the order 10° and persisted from November 2008 to January 2010, which was consistent with a post-recovery calibration drift in the anemometer vane. Unfortunately, the calibration drift was too time-variant to be used to correct the data so the quality flag for this deployment was adjusted to reflect low data quality. The primary purpose of this paper is to inform users in the modelling and remote-sensing community about this systematic, persistent wind directional bias, which will allow users to make an educated decision on using the data and be aware of its potential impact to their downstream product quality. The uncovering of this bias and its source demonstrates the importance of continuous scientific oversight and effective user-data provider communication in stewarding scientific data. It also suggests the need for improvement in the ability of buoy data quality control procedures of the TAO and ECMWF systems to detect future wind directional systematic biases such as the one described here.Keywords: Systematic bias, Data quality, Winds, TAO buoy, ECMWF model INTRODUCTIONThe Tropical Atmosphere Ocean (TAO)/Triangle Trans-Ocean Buoy Network (TRITON) moored buoy array in the tropical Pacific Ocean began as a major contribution to the 10-year (1985-1994) Tropical Ocean-Global Atmosphere (TOGA) Program (McPhaden, 1993; McPhaden, Busalacchi, Cheney, Donguy, Gage, Halpern, et al., 1998;McPhaden, Busalacchi, & Anderson, 2010 The versatility and utility of tropical moored buoy array data have exceeded the originally designed scope of improving detection, understanding, and prediction of climate variability on seasonal to interannual time scales related to the El Niño-Southern Oscillation (ENSO) (McPhaden, 1999;McPhaden, Delcroix, Hanawa, Kuroda, Meyers, Picaut, et al., 2001;McPhaden, Busalacchi, & Anderson, 2010). For example, the TAO buoy data have long been utilized in calibrating model functions for deriving satellite wind speeds or wind vectors (e.g., Dunbar, Hsiao, & Lambrigtsen, 1991;Wentz, 1997;Stoffelen, 1998). In addition to being assimilated in model predictions and reanalyses, the buoy measurements are also valuable in evaluating products from models and satellites and providing error or uncertainty estimates for those products (e.g., Freilich & Dunbar, 1999;Mears, Smith, & Wentz, 2001;Ebuchi, Craber, & Caruso, 2002;Abdalla, Janssen, & Bidlot, 2011;May & Bourassa, 2011;Peng, Zhang, Frank, Bidlot, Higaki, Stevens, et al., 2013). This process is beneficial to both buoy array operators and data users - Figure 1, the WMO 51010 site is noted in the figure). This wind directional bias was slightly product-dependent, ranging from 9.9 to 13.9 degrees with a mean of about 10 degrees and biases from all five products significant at the 95% confidence level (Figure 2).Winds from WMO 51010 are routinely assimilated into operational model...

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Quantifying variance due to temporal and spatial difference between ship and satellite winds

Cited by 24 publications

References 30 publications

ASCAT wind quality under high subcell wind variability conditions

ASCAT wind quality under high subcell wind variability conditions

Comparing in situ and satellite‐based parameterizations of oceanic whitecaps

Directional Bias of TAO Daily Buoy Wind Vectors in the Central Equatorial Pacific Ocean from November 2008 to January 2010

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