In 1996, version 2.5 of the Coupled Ocean-Atmosphere Response Experiment (COARE) bulk algorithm was published, and it has become one of the most frequently used algorithms in the air-sea interaction community. This paper describes steps taken to improve the algorithm in several ways. The number of iterations to solve for stability has been shortened from 20 to 3, and adjustments have been made to the basic profile stability functions. The scalar transfer coefficients have been redefined in terms ofthe mixing ratio, which is the fundamentally conserved quantity, rather than the measured water vapor mass concentration. Both the velocity and scalar roughness lengths have been changed. For the velocity roughness, the original fixed value of the Charnock parameter has been replaced by one that increases with wind speeds of between 10 and 18 m s~(-1). The scalar roughness length parameterization has been simplified to fit both an early set of NOAA/Environmental Technology Laboratory (ETL) experimentsand the Humidity Exchange Over the Sea (HEXOS) program. These changes slightly increase the fluxes for wind speeds exceeding 10 m s~(-1). For interested users, two simple parameterizations of the surface gravity wave influence on fluxes have been added (but not evaluated). This new version of the algorithm (COARE 3.0) was based on published results and 2777 1-h covariance flux measurements in the ETL inventory. To test it, 4439 new values from field experiments between 1997 and 1999 were added, which now dominate the database, especially in the wind speed regime beyond 10 m s~(-1), where the number of observations increased from 67 to about 800. After applying various quality controls, the database was used to evaluate the algorithm in several ways. For an overall mean, the algorithm agrees with the data to within a few percent for stress and latent heat flux. The agreement is also excellent when the bulk and directly measured fluxes are averaged in bins of 10-m neutral wind speed. For a more stringent test, the average 10-m neutral transfer coefficients were computed for stress and moisture in wind speed bins, using different averaging schemes with fairly similar results. The average (mean and median) model results agreed with the measurements to within about 5 percent for moisture from 0 to 20 m s~(-1). For stress, the covariance measurements were about 10 percent higher than the model at wind speeds over 15 in s~(-1), while inertial-dissipation measurements agreed closely at all wind speeds. Thevalues for stress are between 8 percent (for inertial dissipation) and 18 percent (for covariance) higher at 20 m s~(-1) than two other classic results. Twenty years ago, bulk flux schemes were considered to be uncertain by about 30 percent; the authorsfind COARE 3.0 to be accurate within 5 percent for wind speeds of 0-10 m s~(-1) and 10 percent for wind speeds of between 10 and 20 m s~(-1).
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机译:1996年,发布了2.5版的“海洋—大气响应实验”(COARE)批量算法,它已成为海海互动社区中最常用的算法之一。本文介绍了以几种方式改进算法的步骤。解决稳定性的迭代次数已从20减少到3,并对基本轮廓稳定性函数进行了调整。标量传递系数已经根据混合比(它是基本保留量)而不是所测得的水蒸气质量浓度进行了重新定义。速度和标量粗糙度长度都已更改。对于速度粗糙度,Charnock参数的原始固定值已替换为一个随风速在10到18 m s〜(-1)之间增加的固定值。标量粗糙度长度参数化已简化,以适合早期的NOAA /环境技术实验室(ETL)实验和海上湿度交换(HEXOS)程序。这些变化会稍微增加风速超过10 m s〜(-1)时的通量。对于感兴趣的用户,添加了两个简单的表面重力波对通量影响的参数化(但未评估)。该算法的新版本(COARE 3.0)基于已发布的结果和ETL清单中的2777个1小时协方差通量测量结果。为了测试它,增加了1997年到1999年之间的4439个来自野外实验的新值,这些值现在在数据库中占主导地位,特别是在风速范围超过10 ms〜(-1)的情况下,其中观测数量从67个增加到大约800个。在应用各种质量控制后,该数据库以多种方式用于评估算法。对于总体平均值,该算法与应力和潜热通量的数据一致,误差在百分之几以内。当将总通量和直接测量的通量平均在10米中性风速的仓中时,该协议也非常好。为了进行更严格的测试,使用不同的平均方案得出了风速仓中的应力和湿度的平均10米中性传递系数,结果相当相似。对于0至20 m s〜(-1)的湿度,平均(均值和中位数)模型结果与测量值相吻合在5%之内。对于应力,在风速超过15 in s〜(-1)时,协方差测量值比模型高约10%,而在所有风速下,惯性耗散测量值均非常接近。与其他两个经典结果相比,在20 m s〜(-1)时,应力值在8%(惯性耗散)和18%(协方差)之间高。二十年前,人们认为体积通量方案的不确定性约为30%。作者发现COARE 3.0在0-10 m s〜(-1)的风速下准确度在5%之内,在10到20 m s〜(-1)的风速下准确度在10%之内。
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