Zusammenfassung
Topographische Techniken zur Modellierung von Gravitationsfeldern nehmen eine zentrale Rolle in der physikalischen Geodäsie und Geophysik ein. Aus der Topographie gewonnene Schwereinformation ist notwendig für (i) die Reduktion und Interpolation von Schwerefeldbeobachtungen, (ii) die Entwicklung ultra-hochauflösender Schwerefeldmodelle und (iii) die Interpretation von Schwerefeldbeobachtungen. Das vorliegende Kapitel führt in die grundlegenden Methoden der topographischen Modellierung von Gravitationsfeldern ein, wobei eine Unterteilung in numerische Integrations- und Kugelfunktionstechniken erfolgt. Es werden eine Reihe von aktuellen Anwendungsbeispielen gegeben, die von der Erstellung ultra-hochauflösender Schwerefeldmodelle, der Glättung von Schwerefelddaten bis zur Berechnung von Bouguer-Schwerekarten für Erde und Mond reichen. Der Beitrag zeigt zusammenfassend die heutige Relevanz der topographischen Gravitationsfeldmodellierung für erdbezogene und planetare geodätische Anwendungen auf.
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Danksagung
Der Autor wurde vom Australian Research Council und Institute for Advanced Study der Technischen Universität München unterstützt. Dank gilt allen Entwicklern von Schwerefeld- und Topographiemodellen, und allen Wissenschaftlern, die mit ihren Beiträgen das Forschungsfeld der topographischen Modellierung weiterentwickelt haben. Ein besonderer Dank geht an Michael Kuhn und Sten Claessens für eine sehr erfolgreiche Zusammenarbeit.
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Hirt, C. (2017). Topographische Modellierung des Gravitationsfeldes. In: Rummel, R. (eds) Erdmessung und Satellitengeodäsie. Springer Reference Naturwissenschaften . Springer Spektrum, Berlin, Heidelberg. https://doi.org/10.1007/978-3-662-47100-5_9
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