Determination of a Local Hybrid Geoid as a Height Reference System for 3D Cadastre

https://doi.org/10.22146/ijg.55219

Margaretha Elya Lim Putraningtyas(1*), Leni Sophia Heliani(2), Nurrohmat Widjajanti(3), Trias Aditya(4)

(1) Ph.D. candidate, Doctoral Program of Geomatics Engineering, Department of Geodetic Engineering, Faculty of Engineering, Universita Gadjah, Yogyakarta
(2) Department of Geodetic Engineering, Faculty of Engineering, Universitas Gadjah Mada, Yogyakarta
(3) Department of Geodetic Engineering, Faculty of Engineering, Universitas Gadjah Mada, Yogyakarta
(4) Department of Geodetic Engineering, Faculty of Engineering, Universitas Gadjah Mada, Yogyakarta
(*) Corresponding Author

Abstract


Use and development of vertical building(s) on land parcel(s) have been a common progress to many urban landscapes around the world. 3D cadastre has been a research area that involves legal, technical and institutional assessments to the use and development of vertical buildings. Initial Land Registration of 3D cadastre objects require a representative geometry to determine the legal boundaries of 3D objects. For that purpose, a height reference that is used to define 3D geometries of registered 3D cadastre objects is important. This study focuses in determining a height reference system by developing a local hybrid geoid for the representation of 3D cadastre. The local hybrid geoid was developed by fitting the gravimetric to the geometric geoid.  Four strategies were utilized, based on the combination of GGM’s SGG-UGM-1 and GO_CONS_GCF_2_SPW_R5, Remove-Compute-Restore method and control point distribution for geoid fitting. Based on comparison with geometric geoid at six independent control points, the local hybrid geoid from strategy 3 produces mean difference of 0.354 m, accuracy of 0.137 m and increased level of closeness of 86%, which is further applied as an alternative reference surface in 3D cadastre.


Keywords


height reference system; 3D Cadastre; local hybrid geoid

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References

Aien, A. (2013). 3D Cadastral Data Modelling (Issue March). The University of Melbourne, Victoria, Autralia.

Arana, D., Camargo, P. O., & Guimarães, G. N. (2017). Hybrid Geoid Model : Theory and Application in Brazil. 89, 1943–1959.

Cemellini, B., Thompson, R., Vres, M. De, & Oosterom, P. Van. (2018). Visualization/dissemination of 3D Cadastre. FIG Congress 2018, 9591.

Erol, B., & Çelik, R. N. (2004). Modelling Local GPS/Levelling Geoid With the Assesstment of Inverse Distance Weighting And Geostatistical Kriging Methods. ISPRS Congress.

Featherstone, W. E., Dentith, M. C., & Kirby, J. F. (1998). Strategies for the Accurate Determination of Orthometric Heights from GPS. Survey Review, 267(January), 278–296.

Forsberg, R., & Tscherning, C. C. (2008). An overview manual for the GRAVSOFT Geodetic Gravity Field Modelling Programs (2nd Edition; Issue August). National Space Institute.

Gatti, A., Reguzzoni, M., Migliaccio, F., & Sanso, F. (2016). Computation and assessment of the fifth release of the GOCE-only space-wise solution. 1st Joint Commission 2 and IGFS Meeting.

Guo, R., Luo, F., Zhao, Z., He, B., Li, L., Luo, P., & Ying, S. (2014). The Applications and Practices of 3D Cadastre in Shenzhen. International Workshop on 3D Cadastre, Dubai, Enited Arab Emirates, November, 299–312.

Heliani, L. S., Putraningtyas, M. E., & Widjajanti, N. (2013). Sistem Tinggi Dalam Realisasi Kadaster 3D Di Indonesia : Tantangan, Permasalahan dan Alternatif Solusi. Jurnal Ilmiah Pertanahan Bhumi, Yogyakarta.

Husein, S., & Srijono. (2010). Peta Geomorfologi Daerah Istimewa Yogyakarta. Simposium Geologi Yogyakarta, March 2010. https://doi.org/10.13140/RG.2.2.10627.50726

Jaljolie, R., Oosterom, P. Van, & Dalyot, S. (2018). Spatial Data Structure and Functionalities for 3D Land Management System Implementation : Israel Case Study. International Journal of Geo-Information, 1, 1–17. https://doi.org/10.3390/ijgi7010010

Karki, S. (2013). 3D Cadastre Implementation Issues in Australia (Issue June). University of Southern Queensland.

Kaufmann, J., & Steudler, D. (1998). Cadastre 2014 - A Vision for a Future Cadastral System. 1–8.

Kim, S., & Heo, J. (2019). Registration of 3D Underground Parcel in Korean Cadastral System. Cities, 89(January), 105–119. https://doi.org/10.1016/j.cities.2019.01.027

Liang, W., Xu, X., Li, J., & Zhu, G. (2018). The Determination of an Ultra High Gravity Field Model SGG-UGM-1 by Combining EGM2008 Gravity Anomaly and GOCE Observation Data. Acta Geodaeticaet Cartographica Sinica, 47(, 425–434. https://doi.org/10.11947/j.AGCS.2018.20170269

Nakagawa, H., Wada, K., Kikkawa, T., Shimo, H., Andou, H., Kuroishi, Y., Hatanaka, Y., Shigematsu, H., Tanaka, K., & Fukuda, Y. (2003). Development of a New Japanese Geoid Model , “ GSIGEO2000 .” Bulletin of the Geographical Survey Institute, 49, 1–10.

Navratil, G., & Unger, E. M. (2013). Reprint of: Requirements of 3D cadastres for height systems. Computers, Environment and Urban Systems, 40, 14–23. https://doi.org/10.1016/j.compenvurbsys.2013.04.001

Reshetyuk, Y. (2009). Self-calibration and direct georeferencing in terrestrial laser scanning (Issue January). Royal Institute of Technology (KTH), Stokholm. Swedia.

Sjöberg, L. E. (2007). The topographic bias by analytical continuation in physical geodesy. Journal of Geodesy, 81, 345–350. https://doi.org/10.1007/s00190-006-0112-2

Smart, M., & Priebbenow, R. (2018). Designing a 3D Cadastral System Demonstrator : A Case Study. 6th International FIG 3D Cadastre Workshop, October 2018, 1–16.

Stoter, J., & Gorte, B. (2003). Height in the Cadastre Integrating Point Heights and Parcel Boundaries. FIG Working Weeks 2003, Paris, France, 13-17 April 2003, 1–12.

Stoter, J., Ploeger, H., & Van Oosterom, P. (2013). 3D cadastre in the Netherlands: Developments and international applicability. Computers, Environment and Urban Systems, 40, 56–67. https://doi.org/10.1016/j.compenvurbsys.2012.08.008

Stoter, J., & Van Oosterom, P. (2006). 3D Cadastre in an International Context: Legal, Organizational, and Technological Aspects. Taylor & Francis.

Vanicek, P., & Christou, N. T. (Eds.). (1993). Geoid and Its Geophysical Interpretations. CRC Press.

Wellenhof, & Moritz, H. (2005). Physical Geodesy (Second). SpringerWienNewYork.

Wiranata, H. (2016). Pemodelan Geoid Lokal Teliti Wilayah D.I. Yogyakarta. Universitas Gadjah Mada.

Wolf, P. R., & Ghilani, C. D. (1997). Adjustment Computations Statistics and Least Squares in Surveying and GIS. Jhon Wiley and Son Inc.

Xu, X., Zhao, Y., Reubelt, T., & Tenzer, R. (2017). A GOCE only gravity model GOSG01S and the validation of GOCE related satellite gravity models. Geodesy and Geodynamics, 8(4), 260–272. https://doi.org/10.1016/j.geog.2017.03.013



DOI: https://doi.org/10.22146/ijg.55219

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