UGBOWO CAMPUS MAP

Accurate topographic mapping is vital for effective land-use planning, infrastructure development, and environmental monitoring. The integration of advanced remote sensing techniques, particularly the use of Unmanned Aerial Vehicles (UAVs), is highly advantageous for creating efficient and precise terrain models. The importance of high-resolution topographic data cannot be overstated, as it is integral to engineering applications and geospatial analysis. This study aims to produce a detailed topographic map of the University of Benin's Ugbowo Campus, located along the Benin-Lagos Expressway in Benin City, Nigeria, utilizing the DJI Phantom 4 RTK drone. The methodology employed key topographic parameters, including elevation, slope, aspect, and terrain variation, to create a high-accuracy Digital Elevation Model (DEM). A UAV was operated at an altitude of 120 meters in a 3D flight mode, capturing high-resolution aerial imagery. To ensure precise geo-referencing of the orthophoto, Real-time Kinematic (RTK) GPS technology was utilized with an RTK-enabled drone, thus eliminating the need for Ground Control Points (GCPs). The acquired imagery was then processed to produce an orthophoto, which served as the basis for deriving the DEM, and contour lines were extracted at 5-meter intervals to illustrate elevation variations. The accuracy of the model was assessed through a positional accuracy analysis, revealing that the generated topographic data achieved a remarkable precision of less than 5 cm. This outcome underscores the high accuracy of UAV-based mapping techniques. The resulting topographic map provides a comprehensive representation of the terrain, facilitating improved decision- making in urban planning, construction, and geospatial analysis. In conclusion, this research showcases the effectiveness of UAV photogrammetry, particularly through the integration of RTK technology, in producing precise topographic maps. It highlights the promise of UAV-based surveys as a cost-effective and efficient alternative to traditional surveying methods, especially in challenging or inaccessible terrain. By achieving exceptional positional accuracy, these techniques not only enhance the quality of the collected data but also significantly contribute to improved decision-making across various domains, including urban planning and construction.