Download This PaperModelling of Orthometric Heights From Multi-Networks of GNSS/Precise Levelling in FCT, Abuja
Oluyori, P. D., Ono, M. N. and Eteje, S. O. (2019). Modelling of Orthometric heights from Multi-Networks of GNSS/Precise Levelling in FCT, Abuja. International Journal of Environment, Agriculture and Biotechnology (IJEAB), Vol. 4, No. 4, pp 1173-1180. DOI:10.22161/ijeab.4443.
8 Pages Posted: 3 Sep 2019
Date Written: August 21, 2019
Abstract
The geoid is used as a transformation linkage between ellipsoidal heights (h) determined from DGPS observations and orthometric heights (H). Widespread acceptability and adoption of GPS in local geospatial data acquisitions require the development of a local geoid model (N) for use to obtain orthometric heights in the absence of a national geoid model. Geoid model can be developed by gravimetric approach; global geopotential model (GGM); geometric technique among others. The conventional approach to GPS measurements is the use of one base reference station for field measurements. It has several drawbacks e.g. in signal range/coverage, accuracy degradation of results, etc. Based on Grashof's law of stability of triangles, this study was therefore based on dual reference base stations to improve on DGPS signal range and stability of results. Pro-online matrix solver was applied to the least squares observation equations of the two modelled FCT surfaces (multi - quadratic and bicubic) to determine polynomial coefficients. The geoid undulation was computed and orthometric height generated for production of a topographical plan at 1m contour interval for elevation data in surveying, engineering and environmental applications. Skill =1 and bias = 0 were computed to confirm the predictive capability of the models and that no bias/errors were introduced into the respective modelling exercise. Diagnostic test also confirmed the viability and feasibility of providing vertical datum surface for FCT by this approach. Standard deviation (σ) as accuracy indicator was computed and the multi-quadratic model with σ =11cm was the better geoid surface for modelling of orthometric height in the FCT by the geometric method.
Keywords: Geoid undulation, Multiquadratic, Bicubic, Grashof’s law, Orthometric height
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