Principles of Modeling Uncertainties in Spatial Data and Spatial Analyses
Auteur : Shi Wenzhong
When compared to classical sciences such as math, with roots in prehistory, and physics, with roots in antiquity, geographical information science (GISci) is the new kid on the block. Its theoretical foundations are therefore still developing and data quality and uncertainty modeling for spatial data and spatial analysis is an important branch of that theory. Principles of Modeling Uncertainties in Spatial Data and Spatial Analyses outlines the foundational principles and supplies a firm grasp of the disciplines? theoretical underpinnings.
Comprehensive, Systematic Review of Methods for Handling Uncertainties
The book summarizes the principles of modeling uncertainty of spatial data and spatial analysis, and then introduces the developed methods for handling uncertainties in spatial data and modeling uncertainties in spatial models. Building on this foundation, the book goes on to explore modeling uncertainties in spatial analyses and describe methods for presentation of data as quality information. Progressing from basic to advanced topics, the organization of the contents reflects the four major theoretical breakthroughs in uncertainty modeling: advances in spatial object representation, uncertainty modeling for static spatial data to dynamic spatial analyses, uncertainty modeling for spatial data to spatial models, and error description of spatial data to spatial data quality control.
Determine Fitness-of-Use for Your Applications
Modeling uncertainties is essential for the development of geographic information science. Uncertainties always exist in GIS and are then propagated in the results of any spatial analysis. The book delineates how GIS can be a better tool for decision-making and demonstrates how the methods covered can be used to control the data quality of GIS products.
Overview. Introduction. Sources of Uncertainty in Spatial Data and Spatial Analysis. Mathematical Foundations. Modeling Uncertainties in Spatial Data. Modeling Positional Uncertainty in Spatial Data. Modeling Attribute Uncertainty. Modeling Integrated Positional and Attribute Uncertainty. Modeling Uncertain Topological Relations. Modeling Uncertainties in Spatial Model. Uncertainty in Digital Elevation Models. Modeling Uncertainties in Spatial Analyses. Modeling Positional Uncertainties in Overlay Analysis. Modeling Positional Uncertainty in Buffer Analysis. Modeling Positional Uncertainty in Line Simplification Analysis. Quality Control of Spatial Data. Quality Control for Object-Based GIS Data. Quality Control for Field-Based GIS Data. Improved Interpolation Methods for Digital Elevation Model. Presentation of Data Quality Information. Visualization of Uncertainties in Spatial Data and Analyses. Metadata on Spatial Data Quality. Web Service-Based Spatial Data Quality Information System. Epilog.
Date de parution : 06-2020
15.6x23.4 cm
Date de parution : 10-2009
Ouvrage de 464 p.
15.6x23.4 cm
Thèmes de Principles of Modeling Uncertainties in Spatial Data and... :
Mots-clés :
Positional Uncertainties; Confidence Region Model; Topological relations; Error Propagation Law; Uncertainties; Data Set; Quality control; Spatial Data; Presentation; Fuzzy Topology; Qaulity; Spatial Data Quality; Attribute Uncertainty; Bicubic Interpolation; Natural World; Fuzzy Set; Membership Function; Spatial Data Uncertainty; Error Matrix; Land Resource Inventory; Uncertainty Indicators; Data Quality Information; Transformation Model; Error Propagation; Bilinear Interpolation; Error Band; Spatial Objects; RFM; Area Object; Predefined Confidence Level