A series of energy-balance experiments were performed over a winter wheat field in Southern Arizona. A Bowen ratio energy-balance system (BREB), anemometer, and thermal infrared thermometer (IRT) were placed in the center of the field on day 15 of 1988 shortly after germination. The BREB system generated 12-minute averages of net radiation, soil heat flux, latent energy, and sensible heat flux (H) throughout the season, terminating on day 152, just before harvest. On day 134, an eddy-correlation system was placed adjacent to the BREB system, where it collected H-data concurrently for 17 successive days. The data from the BREB and eddy-correlation systems were regressed against each other to quantify their field performance. The regression standard error (SE) between the two systems was ±40 W/m². BREB H-data was used as a "standard" to evaluate three different sensible heat flux models that are suitable for remote sensing applications. The three models require thermal canopy temperature, air temperature, and wind speed as input. Two of the three models use aerodynamic resistance theory, one of which is stability corrected, and the third remote-sensing model employs Monin-Obukhov turbulent transfer theory. The regression analysis between the BREB H-values and the three remote-sensing models shows that the stability corrected aerodynamic resistance model and the Monin-Obukhov model are capable of estimating H-values over a wide range of surface and atmospheric conditions.
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机译:在亚利桑那州南部的一块麦田上进行了一系列能量平衡实验。发芽后不久,1988年第15天,将鲍文比能量平衡系统(BREB),风速仪和热红外温度计(IRT)放置在田间中心。 BREB系统在整个季节产生了12分钟的净辐射,土壤热通量,潜能和显热通量(H)的平均值,直到收获前的第152天才终止。在第134天,将涡流相关系统放置在BREB系统附近,在该系统中连续17天同时收集H数据。来自BREB和涡旋相关系统的数据相互回归,以量化它们的现场性能。两个系统之间的回归标准误差(SE)为±40 W /m²。 BREB H数据被用作“标准”评估适用于遥感应用的三种不同的感热通量模型。这三个模型需要热冠层温度,空气温度和风速作为输入。这三个模型中的两个使用了空气动力学阻力理论,其中之一是经过稳定性校正的,而第三个遥感模型则使用了莫宁-奥布霍夫湍流传递理论。 BREB H值与三个遥感模型之间的回归分析表明,经稳定性校正的空气动力学阻力模型和Monin-Obukhov模型能够在广泛的地面和大气条件下估算H值。
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