Point Cloud Semantic Segmentation Using a Deep Learning Framework for Cultural Heritage

Pierdicca, Roberto; Paolanti, Marina; Matrone, Francesca; Martini, Massimo; Morbidoni, Christian; Malinverni, Eva Savina; Frontoni, Emanuele; Lingua, Andrea Maria

doi:10.3390/rs12061005

Cited by 179 publications

(136 citation statements)

References 66 publications

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“…The dataset needs to be manually segmented by domain experts and must be broad enough to comprise enough classes for each case study, which in the CH context is quite tricky. Recently, a Dynamic Graph Convolutional Neural Network (DGCNN) supported by meaningful features (normal and HSV colours) has been employed in [39]. The DGCNN has been trained on the ArCH dataset [40], which includes 10 manually labelled point clouds subdivided into 11 classes.…”

Section: State Of the Artmentioning

confidence: 99%

A Hierarchical Machine Learning Approach for Multi-Level and Multi-Resolution 3D Point Cloud Classification

et al. 2020

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The recent years saw an extensive use of 3D point cloud data for heritage documentation, valorisation and visualisation. Although rich in metric quality, these 3D data lack structured information such as semantics and hierarchy between parts. In this context, the introduction of point cloud classification methods can play an essential role for better data usage, model definition, analysis and conservation. The paper aims to extend a machine learning (ML) classification method with a multi-level and multi-resolution (MLMR) approach. The proposed MLMR approach improves the learning process and optimises 3D classification results through a hierarchical concept. The MLMR procedure is tested and evaluated on two large-scale and complex datasets: the Pomposa Abbey (Italy) and the Milan Cathedral (Italy). Classification results show the reliability and replicability of the developed method, allowing the identification of the necessary architectural classes at each geometric resolution.

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Section: State Of the Artmentioning

confidence: 99%

A Hierarchical Machine Learning Approach for Multi-Level and Multi-Resolution 3D Point Cloud Classification

et al. 2020

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“…The authors also released a dataset with more than 10k images including categories like Altar, Apse, Belltower, Column, Dome (inner and outer), Flying buttress, Gargoyle, Stained glass, and Vault. In this context, several researchers have started to approach the topic of semantic segmentation of cultural heritage (CH) point clouds within the machine and deep learning framework (Grilli et al, 2019a;Kharroubi et al, 2019;Murtiyoso and Grussenmeyer, 2020;Pierdicca et al, 2020). However, the lack of an appropriate 3D heritage dataset does not allow an effective comparison between methods and results.…”

Section: Previous Workmentioning

confidence: 99%

“…Moreover, as the classes included in these two standards are not enough to describe properly a CH, the AAT was perused and, within the Architectural elements class and Structural elements category, the 'Vaults', 'Arches' classes have been taken into account, whereas from Surface elements 'Moldings' have been selected. Following some studies and results of classification with the 3D features (Grilli et al, 2019b), it was decided to change the classification proposed in (Malinverni et al, 2019;Pierdicca et al, 2020), separating the class of columns and half-pilasters and inserting the latter in the new class 'Moldings' where there are also cornices and eaves. With this purpose, 9 classes have been selected (Figure 3), plus another one defined as 'Other', containing all the points not belonging to the previous classes (e.g.…”

Section: Class Definitionmentioning

confidence: 99%

“…If authors will submit the predicted results for a given point cloud (ideally for all), we will automatically compare the achieved results with the ground truth ones and provide results in terms of Overall Accuracy, F1 Score, Precision, Recall and Intersection over Union (IoU). Currently, the performances of state-of-art point cloud semantic segmentation networks are reported for PointNet (Qi et al, 2017a), PointNet++ (Qi et al, 2017b), PCNN (Atzmon et al, 2018), DGCNN (Wang et al, 2019) and modified DGCNN (Pierdicca et al, 2020). These DNNs are evaluated on 11 scenes out of 17 available.…”

Section: Aims Of the Benchmark And Evaluationmentioning

confidence: 99%

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A Benchmark for Large-Scale Heritage Point Cloud Semantic Segmentation

Matrone

Lingua

Pierdicca

et al. 2020

Int. Arch. Photogramm. Remote Sens. Spatial Inf. Sci.

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Abstract. The lack of benchmarking data for the semantic segmentation of digital heritage scenarios is hampering the development of automatic classification solutions in this field. Heritage 3D data feature complex structures and uncommon classes that prevent the simple deployment of available methods developed in other fields and for other types of data. The semantic classification of heritage 3D data would support the community in better understanding and analysing digital twins, facilitate restoration and conservation work, etc. In this paper, we present the first benchmark with millions of manually labelled 3D points belonging to heritage scenarios, realised to facilitate the development, training, testing and evaluation of machine and deep learning methods and algorithms in the heritage field. The proposed benchmark, available at http://archdataset.polito.it/, comprises datasets and classification results for better comparisons and insights into the strengths and weaknesses of different machine and deep learning approaches for heritage point cloud semantic segmentation, in addition to promoting a form of crowdsourcing to enrich the already annotated database.

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“…Secondly, they permit to geometrically describe objects of any shape and scale * Corresponding author with an adapted resolution and point density. Finally, point clouds are generated by a wide variety of sensors permitting applications spanning from robotics (Parra et al, 2020) architecture, engineering and construction (Stojanovic et al, 2019) to cultural heritage (Pierdicca et al, 2020). For these unique properties, point clouds increasingly constitute a very important support for decision-making and support for semantic integration .…”

Section: Introductionmentioning

confidence: 99%

Marker-Less Mobile Augmented Reality Application for Massive 3d Point Clouds and Semantics

Kharroubi

Billen

Poux

2020

Int. Arch. Photogramm. Remote Sens. Spatial Inf. Sci.

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Abstract. Mobile Augmented Reality (MAR) attracts significant research and development efforts from both the industry and academia, but rarely integrate massive 3D dataset’s interactions. The emergence of dedicated AR devices and powerful Software Development Kit (ARCore for android and ARKit for iOS) improves performance on mobile devices (Smartphones and tablets). This is aided by new sensor integration and advances in computer vision that fuels the development of MAR. In this paper, we propose a direct integration of massive 3D point clouds with semantics in a web-based marker-less mobile Augmented Reality (AR) application for real-time visualization. We specifically investigate challenges linked to point cloud data structure and semantic injection. Our solution consolidates some of the overarching principles of AR, of which pose estimation, registration and 3D tracking. The developed AR system is tested on mobile phones web-browsers providing clear insights on the performance of the system. Promising results highlight a number of frame per second varying between 27 and 60 for a real-time point budget of 4.3 million points. The point cloud tested is composed of 29 million points and shows how our indexation strategy permits the integration of massive point clouds aiming at the point budget. The results also gives research directions concerning the dependence and delay related to the quality of the network connection, and the battery consumption since portable sensors are used all the time.

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Point Cloud Semantic Segmentation Using a Deep Learning Framework for Cultural Heritage

Cited by 179 publications

References 66 publications

A Hierarchical Machine Learning Approach for Multi-Level and Multi-Resolution 3D Point Cloud Classification

A Hierarchical Machine Learning Approach for Multi-Level and Multi-Resolution 3D Point Cloud Classification

A Benchmark for Large-Scale Heritage Point Cloud Semantic Segmentation

Marker-Less Mobile Augmented Reality Application for Massive 3d Point Clouds and Semantics

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