Smart Cities are no longer just an aspiration, they are a necessity. For a city to be smart, accurate data collection or improvement the existing ones is needed, also an infrastructure that allows ...the integration of heterogeneous geographic information and sensor networks at a common technological point. Over the past two decades, laser scanning technology, also known as LiDAR (Light Detection and Ranging), has become a very important measurement method, providing high accuracy data and information on land topography, vegetation, buildings, and so on. Proving to be a great way to create Digital Terrain Models. The digital terrain model is a statistical representation of the terrain surface, including in its dataset the elements on its surface, such as construction or vegetation. The data use in the following article is from the LAKI II project “Services for producing a digital model of land by aerial scanning, aerial photographs and production of new maps and orthophotomaps for approximately 50 000 sqKm in 6 counties: Bihor, Arad, Hunedoara, Alba, Mures, Harghita including the High Risk Flood Zone (the border area with the Republic of Hungary in Arad and Bihor)”, which are obtained through LiDAR technology with a point density of 8 points per square meter. The purpose of this article is to update geospatial data with a higher resolution digital surface model and to demonstrate the differences between a digital surface models obtain by aerial images and one obtain by LiDAR technology. The digital surface model will be included in the existing geographic information system of the city Marghita in Bihor County, and it will be used to help develop studies on land use, transport planning system and geological applications. It could also be used to detect changes over time to archaeological sites, to create countur lines maps, flight simulation programs, or other viewing and modelling applications.
This study investigates the optimal distribution and pattern of ground control points (GCPs) in aerial photogrammetric projects. Aerial triangulation (AT), also known as bundle adjustment, is the ...fundamental step in refining 3D reconstruction models and camera positions, thereby minimizing reprojection errors. The study utilizes data from a national project in Romania, employing high-resolution aerial images acquisition using photogrammetric sensors. The project has rigorous requirements of ground control points (GCP) placement and field measurements using GNSS and geometric leveling techniques. The study employs various scenarios, manipulating the number and distribution of GCPs, to assess their influence on planimetric and altimetric accuracy. Results indicate that the configuration and number of GCPs significantly affect the accuracy of photogrammetric products, such as dense image point clouds, digital surface models, and orthophotos. Moreover, the study underscores the importance of precise GCP determination methods, especially in regions lacking a precise gravimetric geoid model. In scenarios with inadequate GCP coverage the outcomes have inferior quality, emphasizing the critical role of GCPs in ensuring the quality of photogrammetric products. Overall, the research gives a clear view on the best placement patterns of GCPs and their influence on AT process evaluation performed in check points (CHKs).
Urban Classification from Aerial and Satellite Images Pârvu, Iuliana Maria; Picu, Iuliana Adriana Cuibac; Dragomir, P.I. ...
Journal of Applied Engineering Sciences,
12/2020, Letnik:
10, Številka:
2
Journal Article
Recenzirano
Odprti dostop
When talking about land cover, we need to find a proper way to extract information from aerial or satellite images. In the field of photogrammetry, aerial images are generally acquired by optical ...sensors that deliver images in four bands (red, green, blue and near-infrared). Recent researches in this field demonstrated that for the image classification process is still place for improvement. From satellites are obtained multispectral images with more bands (e.g. Landsat 7/8 has 36 spectral bands). This paper will present the differences between these two types of images and the classification results using support-vector machine and maximum likelihood classifier. For the aerial and the satellite images we used different sets of classification classes and the two methods mentioned above to highlight the importance of choosing the classes and the classification method.
Pixel Based Classification of Images Pârvu, Iuliana Maria; Cuibac - Picu, Iuliana Adriana; Dragomir, Petre Iuliu
RevCAD Journal of Geodesy and Cadastre,
2018
25
Journal Article
Odprti dostop
Nowadays, automation became a basic theme in all the fields of activity. Reducing the operator tasks from a workflow led to the need of research extensions in automation. In Photogrammetry we can ...start this process from the data collection and going to the final product generation. The main goal of this article is to facilitate the updating process of the National Geospatial Database and to ensure support for different products of our institution. The study was conducted on two types of coverage: extraurban and urban areas, both in Bihor County. The segmentation and classification process used the Single Feature Probability method, considering attributes like spectral signature, texture and shape. The results depend on the initial data, the workflow used and the samples collected.
LiDAR Applications Based on LAKI II Project Pârvu, Iuliana Maria; Cuibac - Picu, Iuliana Adriana; Pârvu, Adrian Grigore ...
RevCAD Journal of Geodesy and Cadastre,
2017
23
Journal Article
Odprti dostop
The evolution of technology has led to significant advances enabling the development of precision laser scanning technology. LiDAR technology involves scanning a surface with laser waves. The ability ...to process dense point clouds in an efficient and cost-effective manner has facilitated a multitude of 3D data acquisition applications. This paper presents the ongoing project “Geographical Information for the Environment, Climate Change and EU Integration” LAKI II and some applications derived from it. One of the applications is the flooding risk analysis using LiDAR technology based products. Another application is the fusion of data from different sensors for some historical monuments, like Oradea Fortress. Improving the final products for cities by generating higher resolution digital surface models is one of our future goals.