Application of Deep Learning for Delineation of Visible Cadastral Boundaries from Remote Sensing Imagery

Crommelinck, Sophie; Koeva, Mila; Yang, Michael Ying; Vosselman, G.

doi:10.3390/rs11212505

Cited by 33 publications

(48 citation statements)

References 44 publications

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“…In light of state-of-the-art methods in land administration, a deep-learning is becoming highly prominent for the detection of cadastral boundaries [12,19]. Recent evidence suggests that deep fully convolutional networks (FCNs) ensures the high accuracy rather than gPb and MRS, with results of 0.79 in precision, 0.37 in recall and 0.50 in F-score [19].…”

Section: Advancement Of Eo and Ai Applications In Identifying Land Tementioning

confidence: 99%

“…Recent evidence suggests that deep fully convolutional networks (FCNs) ensures the high accuracy rather than gPb and MRS, with results of 0.79 in precision, 0.37 in recall and 0.50 in F-score [19]. For optimizing image segmentation, one study by [12] not only introduced the interactive boundary delineation workflow, but also examined the better suitability of the deep learning in cadastral mapping with convolutional neural networks (CNNs) by comparing random forest (RF) in machine learning: RF-derived boundary likelihoods (accuracy: 41%, precision: 49%), CNN-derived boundary likelihoods (accuracy: 52%, precision: 76%).…”

Section: Advancement Of Eo and Ai Applications In Identifying Land Tementioning

confidence: 99%

“…Convolutional Networks (FCNs) [19] Aerial imagery and UAVs √ Automatic boundary classification: Random Forest (RF), Convolutional Neural Networks (CNN) [12] Remote Sens. 2020, 12, 255 6 of 26…”

Section: Automatic Cadastral Boundary Detection: Deep Fullymentioning

confidence: 99%

“…Literature shows applications ranging from environmental and regional studies to economics, and peace and conflict research, for example [6][7][8][9]. More specific to the interest of this paper, there is growing body of literature on methods to extract and map cadastral boundaries using EO data [10][11][12][13][14][15][16][17][18][19]. However, this literature rarely effectively bridges the knowledge gap between social land tenure and spatial descriptions of boundaries.…”

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confidence: 99%

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Bridging the Semantic Gap between Land Tenure and EO Data: Conceptual and Methodological Underpinnings for a Geospatially Informed Analysis

Lee

Vries

2020

Remote Sensing

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When spatial land tenure relations are not available, the only effective alternative data method is to rely on the agricultural census at the regional or national scale, based on household surveys and a participatory mapping at the local scale. However, what if even these are not available, which is typical for conflict-affected countries, administrations suffering from a lack of data and resources, or agencies that produce a sub-standard quality. Would it, under such circumstances, be possible to rely on remotely sensed Earth Observation (EO) data? We hypothesize that it is possible to qualify and quantify certain types of unknown land tenure relations based on EO data. Therefore, this study aims to standardize the identification and categorization of certain objects, environments, and semantics visible in EO data that can (re-)interpret land tenure relations. The context of this study is the opportunity to mine data on North Korean land tenure, which would be needed in case of a Korean (re-)unification. Synthesizing land tenure data in conjunction with EO data would align land administration practices in the respective parts and could also derive reliable land tenure and governance variables. There are still many unanswered questions about workable EO data proxies, which can derive information about land tenure relations. However, this first exploration provides a relevant contribution to bridging the semantic gap between land tenure and EO data.

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Section: Advancement Of Eo and Ai Applications In Identifying Land Tementioning

confidence: 99%

Section: Advancement Of Eo and Ai Applications In Identifying Land Tementioning

confidence: 99%

Section: Automatic Cadastral Boundary Detection: Deep Fullymentioning

confidence: 99%

mentioning

confidence: 99%

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Bridging the Semantic Gap between Land Tenure and EO Data: Conceptual and Methodological Underpinnings for a Geospatially Informed Analysis

Lee

Vries

2020

Remote Sensing

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“…These networks have the following characteristics: they are fully convolutional networks without fully connection; a skip connection structure combined with deconvolution layers and convolution layers at different depths so as to revert the accurate locations of the geographic objects and add semantic labels to each pixel of the image. The semantic segmentation networks based on CNNs are widely applied in the recognition of buildings [38][39][40][41], the extraction of cadastral boundaries [42] and the land use or land cover change [43,44]. The applications are also expanded to the recognition of the agricultural plants [45], pests and diseases [46,47], especially the Refs.…”

Section: Semantic Segmentationmentioning

confidence: 99%

Landslide Image Captioning Method Based on Semantic Gate and Bi-Temporal LSTM

Cui

Meng

et al. 2020

IJGI

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When a landslide happens, it is important to recognize the hazard-affected bodies surrounding the landslide for the risk assessment and emergency rescue. In order to realize the recognition, the spatial relationship between landslides and other geographic objects such as residence, roads and schools needs to be defined. Comparing with semantic segmentation and instance segmentation that can only recognize the geographic objects separately, image captioning can provide richer semantic information including the spatial relationship among these objects. However, the traditional image captioning methods based on RNNs have two main shortcomings: the errors in the prediction process are often accumulated and the location of attention is not always accurate which would lead to misjudgment of risk. To handle these problems, a landslide image interpretation network based on a semantic gate and a bi-temporal long-short term memory network (SG-BiTLSTM) is proposed in this paper. In the SG-BiTLSTM architecture, a U-Net is employed as an encoder to extract features of the images and generate the mask maps of the landslides and other geographic objects. The decoder of this structure consists of two interactive long-short term memory networks (LSTMs) to describe the spatial relationship among these geographic objects so that to further determine the role of the classified geographic objects for identifying the hazard-affected bodies. The purpose of this research is to judge the hazard-affected bodies of the landslide (i.e., buildings and roads) through the SG-BiTLSTM network to provide geographic information support for emergency service. The remote sensing data was taken by Worldview satellite after the Wenchuan earthquake happened in 2008. The experimental results demonstrate that SG-BiTLSTM network shows remarkable improvements on the recognition of landslide and hazard-affected bodies, compared with the traditional LSTM (the Baseline Model), the BLEU1 of the SG-BiTLSTM is improved by 5.89%, the matching rate between the mask maps and the focus matrix of the attention is improved by 42.81%. In conclusion, the SG-BiTLSTM network can recognize landslides and the hazard-affected bodies simultaneously to provide basic geographic information service for emergency decision-making.

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Blockchain, Earth Observation and Intelligent Data Systems: Implications and Opportunities for the Next Generation of Digital Services

Burzykowska

2020

Blockchain, Law and Governance

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Application of Deep Learning for Delineation of Visible Cadastral Boundaries from Remote Sensing Imagery

Cited by 33 publications

References 44 publications

Bridging the Semantic Gap between Land Tenure and EO Data: Conceptual and Methodological Underpinnings for a Geospatially Informed Analysis

Bridging the Semantic Gap between Land Tenure and EO Data: Conceptual and Methodological Underpinnings for a Geospatially Informed Analysis

Landslide Image Captioning Method Based on Semantic Gate and Bi-Temporal LSTM

Blockchain, Earth Observation and Intelligent Data Systems: Implications and Opportunities for the Next Generation of Digital Services

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