A Completeness of Metrics for Topological Relations in 3D Qualitative Spatial Reasoning

Qualitative Spatial Reasoning with Directional and Topological Relations

Mathematical Problems in Engineering ◽

10.1155/2015/902043 ◽

2015 ◽

Vol 2015 ◽

pp. 1-10 ◽

Cited By ~ 3

Author(s):

Sangha Nam ◽

Incheol Kim

Keyword(s):

Intelligent Systems ◽

Spatial Reasoning ◽

Cognitive Robotics ◽

Qualitative Spatial Reasoning ◽

Topological Relations ◽

Topological Relation ◽

Wide Range ◽

Spatial Entities ◽

Reasoning Algorithm ◽

Ubiquitous Computing Environments

A wide range of application domains from cognitive robotics to intelligent systems encompassing diverse paradigms such as ambient intelligence and ubiquitous computing environments require the ability to represent and reason about the spatial aspects of the environment within which an agent or a system is functional. Many existing spatial reasoners share a common limitation that they do not provide any checking functions for cross-consistency between the directional and the topological relation set. They provide only the checking function for path-consistency within a directional or topological relation set. This paper presents an efficient spatial reasoning algorithm working on a mixture of directional and topological relations between spatial entities and then explains the implementation of a spatial reasoner based on the proposed algorithm. Our algorithm not only has the checking function for path-consistency within each directional or topological relation set, but also provides the checking function for cross-consistency between them. This paper also presents an application system developed to demonstrate the applicability of the spatial reasoner and then introduces the results of the experiment carried out to evaluate the performance of our spatial reasoner.

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Qualitative spatial reasoning on topological relations by combining the semantic web and constraint satisfaction

Geo-spatial Information Science ◽

10.1080/10095020.2018.1430659 ◽

2018 ◽

Vol 21 (2) ◽

pp. 80-92 ◽

Cited By ~ 2

Author(s):

Yandong Wang ◽

Mengling Qiao ◽

Hui Liu ◽

Xinyue Ye

Keyword(s):

Semantic Web ◽

Constraint Satisfaction ◽

Spatial Reasoning ◽

Qualitative Spatial Reasoning ◽

Topological Relations

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Deriving topological relations from topologically augmented direction relation matrices

Journal of Spatial Information Science ◽

10.5311/josis.2021.23.155 ◽

2021 ◽

pp. 1-23

Author(s):

Matthew P. Dube

Keyword(s):

Spatial Reasoning ◽

Qualitative Spatial Reasoning ◽

Topological Relations ◽

Topological Relation ◽

Direction Relations ◽

Relation Matrix

Topological relations and direction relations represent two pieces of the qualitative spatial reasoning triumvirate. Researchers have previously attempted to use the direction relation matrix to derive a topological relation, finding that no single direction relation matrix can isolate a particular topological relation. In this paper, the technique of topological augmentation is applied to the same problem, identifying a unique topological relation in 28.6% of all topologically augmented direction relation matrices, and furthermore achieving a reduction in a further 40.4% of topologically augmented direction relation matrices when compared to their vanilla direction relation matrix counterpart.

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Enriching the Qualitative Spatial Reasoning System RCC8

Advances in Geospatial Technologies - Qualitative Spatio-Temporal Representation and Reasoning ◽

10.4018/978-1-61692-868-1.ch006 ◽

2012 ◽

pp. 203-254

Author(s):

Ahed Alboody ◽

Florence Sedes ◽

Jordi Inglada

Keyword(s):

Spatial Reasoning ◽

Qualitative Spatial Reasoning ◽

Topological Relations ◽

Reasoning System ◽

Gis Applications ◽

Level 1 ◽

Level 2

In this context, the authors develop definitions for the generalization of these detailed topological relations at these two levels (Level-1 and Level-2). The chapter presents two tables of these four detailed relations. Finally, examples for GIS applications are provided to illustrate the determination of the detailed topological relations studied in this chapter.

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Modeling Imprecise and Bipolar Algebraic and Topological Relations using Morphological Dilations

Mathematical Morphology - Theory and Applications ◽

10.1515/mathm-2020-0107 ◽

2021 ◽

Vol 5 (1) ◽

pp. 1-20

Author(s):

Isabelle Bloch

Keyword(s):

Information Processing ◽

Fuzzy Sets ◽

Mathematical Morphology ◽

Complete Lattice ◽

Spatial Reasoning ◽

Topological Relations ◽

Preference Modeling ◽

Logical Sense ◽

Bipolar Fuzzy Sets ◽

Core Features

Abstract In many domains of information processing, such as knowledge representation, preference modeling, argumentation, multi-criteria decision analysis, spatial reasoning, both vagueness, or imprecision, and bipolarity, encompassing positive and negative parts of information, are core features of the information to be modeled and processed. This led to the development of the concept of bipolar fuzzy sets, and of associated models and tools, such as fusion and aggregation, similarity and distances, mathematical morphology. Here we propose to extend these tools by defining algebraic and topological relations between bipolar fuzzy sets, including intersection, inclusion, adjacency and RCC relations widely used in mereotopology, based on bipolar connectives (in a logical sense) and on mathematical morphology operators. These definitions are shown to have the desired properties and to be consistent with existing definitions on sets and fuzzy sets, while providing an additional bipolar feature. The proposed relations can be used for instance for preference modeling or spatial reasoning. They apply more generally to any type of functions taking values in a poset or a complete lattice, such as L-fuzzy sets.

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