Abstract
The article presents a technique for distinguishing relative deformations of buildings from the general displacement vector of deformation marks in the presence of reference points. Displacement vectors are obtained from a linear spatial notch solution. In particular, knowing the distances between the reference points and the deformation marks, we obtain the coordinates of the marks located on the building in the initial and the current observation cycles. Knowing the coordinates of the marks, we calculate the vector of displacement marks for a certain period of time. Next, they carry out the separation of the vectors of the displacement of the marks into components and determine the type of deformation. Absolute deformations are determined from the support points. In this case, the distance between any pair of deformation marks of the object does not change during the deformation, but in the general case, the distances from the points of the object to the reference points change. In case of relative deformations, the distances between the deformation marks change. This fact is used to separate absolute and relative deformations. The results can be used in assessing absolute and relative deformations, in particular, buildings of cultural heritage monuments.
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Tsareva, O., Pshchelko, N., Glazunov, V., Yugov, A. (2020). Separation of Relative Deformations of Buildings from a General Displacement Vector of Deformation Marks. In: Anatolijs, B., Nikolai, V., Vitalii, S. (eds) Proceedings of EECE 2019. EECE 2019. Lecture Notes in Civil Engineering, vol 70. Springer, Cham. https://doi.org/10.1007/978-3-030-42351-3_8
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DOI: https://doi.org/10.1007/978-3-030-42351-3_8
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