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引用次数: 2
摘要
摘要1962年A。Bjerhammar在物理大地测量学中引入了解析延拓方法,这意味着地表重力异常向下延续到地形团块中,直到一个内部球体(Bjerhammar球体)。该方法还包括分析向上延拓势到地球表面,以获得拟椭球面。可以证明,只要不知道地形的完整密度分布,用于大地水准面确定的常见的移除-计算-恢复技术也包括解析延拓。分析延拓表明,由于所谓的地形偏差,向下持续的重力异常和/或位势存在误差,而地形偏差是2007年用L E Sjöberg的简单公式假设的。在这里,我们将通过将假设公式与均匀椭球的外势向内球的解析向下延拓得到的偏差进行比较,从而在数值上验证该公式。结果表明,假设公式成立:在椭球的赤道处,外部电位向下持续21公里,计算和假设的地形偏差一致小于1毫米(当电位被缩放到米的单位时)。
Abstract In 1962 A. Bjerhammar introduced the method of analytical continuation in physical geodesy, implying that surface gravity anomalies are downward continued into the topographic masses down to an internal sphere (the Bjerhammar sphere). The method also includes analytical upward continuation of the potential to the surface of the Earth to obtain the quasigeoid. One can show that also the common remove-compute-restore technique for geoid determination includes an analytical continuation as long as the complete density distribution of the topography is not known. The analytical continuation implies that the downward continued gravity anomaly and/or potential are/is in error by the so-called topographic bias, which was postulated by a simple formula of L E Sjöberg in 2007. Here we will numerically test the postulated formula by comparing it with the bias obtained by analytical downward continuation of the external potential of a homogeneous ellipsoid to an inner sphere. The result shows that the postulated formula holds: At the equator of the ellipsoid, where the external potential is downward continued 21 km, the computed and postulated topographic biases agree to less than a millimetre (when the potential is scaled to the unit of metre).