Abstract
Abstract. This paper proposes a new algorithm to generalize noisy polylines comprising a rooftop model by maximizing a shape regularity (orthogonality, symmetricity and directional simplications). The nature of remotely sensed data including airborne LiDAR often produce errors in localizing salient features (corners, lines and planes) due to weak contrast, occlusions, shadows and object complexity. A generalization or regularization process is well known algorithm for eliminating erroneous vertices while preserving significant information on rooftop shapes. Most of existing regularization methods achieves this goal base on a local process such as if-then rules due to lacking global objective functions or mainly focusing on minimising residuals between boundary observations and models. In this study, we implicitly derive rules to generate local hypothetical models. Those hypothesized models produce possible drawings of regular patterns that given rooftop vectors can possibly generate by combining global and local analysis of line directions and their connections. A final optimal model is globally selected through a gradient descent optimization. A BSP (Binary Tree Partitioning)-tree was used to produce initial rooftop vectors using ISPRS WGIII/4's benchmarking test sites in Veihngen. The proposed regularization algorithm was applied to reduce modelling errors produced by BSP-tree. An evaluation demonstrates the proposed algorithm is promising for updating of building database.
Highlights
In recent years, there has been increasing demands to have 3D rooftop models as emerging technologies such as GeoWeb, LBS (Location Based System) and MAR (Mobile Augmented Reality) have been demonstrated potential applications
This paper proposes a new generative modelling approach to reconstruct 3D building model and rectify their geometric and ISPRS Annals of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Volume I-3, 2012 XXII ISPRS Congress, 25 August – 01 September 2012, Melbourne, Australia topological errors amongst modelling features
The performance of the proposed approach was evaluated with the real data set which is provided from ISPRS Commission III, WG3/4 and used for the ISPRS test project on the urban classification and 3D building reconstruction
Summary
There has been increasing demands to have 3D rooftop models as emerging technologies such as GeoWeb, LBS (Location Based System) and MAR (Mobile Augmented Reality) have been demonstrated potential applications. Assume that a rooftop is comprised of a set of polygons (planar features), which are inter-linked with lines (linear features) It is generally unknown as a priori knowledge: how the shape of a building of interest is (shape prior); how many features (polygons and lines) are required to model it; what topological rules (relations) are associated with the model. Knowing a building shape prior would make ease all difficulties in rooftop modelling since it provides compensate the knowledge on “missing features” and “missing relations”. Obtaining such rich priors is rare case in practice: even generalizing the shape prior into a semantic level (how to describe a shape) would be hard problem. The method would be promising if right modelling templates and sufficient observations are given for reconstructing rooftop models
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