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Spatio-Temporal Database Coupled with Spatial Statistics for Urban Land Use Change Analysis
Chenglin Xie1, Bo Huang1, Christophe Claramunt2 and Magesh Chandramouli3 1Department of Geomatics Engineering University of Calgary 2The French Navy Academy Research Institute France 3GIS center Feng Chia University
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Outline Introduction Spatio-Temporal Data Model and Query Language
Rural-Urban Land Conversion Modeling Case Study Summary
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Introduction Understanding the driving forces for urbanization is critical for proper planning and management of resources Comprehensive and consistent geographical record of land use and relative information: a prerequisite to understanding land use change Modeling the rural-urban land conversion pattern: critical to predicting urban growth
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Introduction (Cont’d)
It is necessary to bridge the gap between spatio-temporal database modeling and land use prognostic modeling Automate the process of change-tracking and predictive analysis Makes it possible to look back exploring why the change happened
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Spatio-temporal data models
Snapshot model Space-time composite model Event-based spatio-temporal data model Spatio-temporal object model in line with the Object Database Management Group (ODMG) standard Huang, B. and Claramunt, C., STOQL: An ODMG-based spatio-temporal object model and query language. In D. Richardson and P. Oosterom (eds.), Advances in Spatial Data Handling, Sringer-Verlag. Huang, B. and Claramunt, C., Spatiotemporal data model and query language for tracking land use change. Accepted for publication in Transportation Research Record, Journal of Transportation Research Board, US.
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Our spatio-temporal object model
Different properties (e.g. owner and shape) may change asynchronously owner: John (1990)–> Frank (1993) –> Martin (2000-now) shape: Different properties may be of different types (string, integer, struct etc.) owner: string shape: polygon
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Our spatio-temporal object model (cont’d)
Shape can change in different forms:
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Our spatio-temporal object model (cont’d)
Designed a parametric type to represent the changes on different properties Parametric type allows a function to work uniformly on a range of types. Temporal<T> (T is a type) {(val1, t1), (val2, t2), (val3, t3), …, (valn, tn)} val: T Class parcel { integer ID; temporal<string> owner; temporal<string> lutype; //land use type temporal<polygon> shape; }
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Tracking of complex land use changes
1984 1992 1997 2002
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Representing the complex change
’s change: { ([1984, 1991], struct(Land_use_type: “agriculture”, Gextent_ref: “G |1984”)), ([1992, now], struct(Land_use_type: “urban”, Gextent_ref: “G |1992”)) } Temporal<T> is used to represent the changes on different attributes
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Spatio-temporal Query Language
Spatio-temporal DBMS Query language Data model Interact with the database Spatio-temporal database
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Syntactical Constructs
STOQL OQL Type [time1, time2] Struct(start: time1, end: time2) TimeInterval e! e.getHistory() List es.val T (any ODMG type and basic spatial types) es.vt es.index e.getStateIndex(ev) (es in e) Unsigned Long
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Query Example 1 Query 1. Display all the parcels of land use ‘agricultural’ in 1980. Select p-geo.val From parcels As parcel, parcel.geo! As p-geo, parcel.landuse! As p-landuse Where p-landuse.vt.contains([1980]) and p-geo.vt.contains([1980]) and p-landuse.val = ‘agricultural’
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Query Example 2 Query 2. What were the owners of the parcels which intersected the protected area of the river ‘River1’ over the year 1990, while they were away from that protected area over the year 1980. Select parcel.owner From parcels As parcel, parcel.geo! As parcelgeo1 parcelgeo2, protected-areas As p-area, p-area.geo! As p-areageo1 p-areageo2 Where p-area.name = ‘River1’ and p-areageo1.vt.contains([1980]) and parcelgeo1.vt.contains([1980]) p-areageo1.val.disjoint(parcelgeo1.val) and p-areageo2.vt.contains([1990]) and parcelgeo2.vt.contains([1990]) p-areageo2.val.intersects(parcelgeo2.val)
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Rural-Urban Land Conversion Modeling
Several techniques Cellular automata (CA) Exploratory spatial data analysis Regression analysis Artificial neural networks (ANNs) The general form of logistic regression model:
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Case Study New Castle County, Delaware, USA is selected as study area
Snapshots of land use and land cover in 1984, 1992, 1997 and 2002 are used Land use classifications Urban areas Residential Commercial Industrial Agricultural Others (not suitable for development) Forest Water Barren
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Land use data
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GIS-based predictor variables
Seven predictor variables were compiled in ArcInfo 9.0 based on 50m×50m cell size Three classes of predictors were employed Site specific characteristics Proximity Neighborhoods Variable name Description Dens_Pop Population density of the cell Dist_Com Distance from the cell to the nearest commercial site Dist_Res Distance from the cell to the nearest residential area Dist_Ind Distance from the cell to the nearest industrial site Dist_Road Distance from the cell to the nearest road Per_Urb Percentage of urban land use in the surrounding area within 200m radius Per_Agr Percentage of rural land use in the surrounding area within 200m radius
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Spatial sampling Assumption of econometric model—error terms for each individual observation are uncorrelated Integration of systematic sampling and random sampling methods Land use type Owner shape
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Binary logistic regression
Variable Model Model Model Coefficient S.E. Dens_Pop Dist_Com Dist_Res Dist_Ind Dist_Road Per_Urb Per_Agr Constant G.K. Gamma 0.94 0.97 0.96 PCP 92.8% 97.9% 95.7% Note: S.E.: standard error. G.K. Gamma: Goodman-Kruskal Gamma PCP: percentage correctly predicted
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Prognostic capacity evaluation
The validation process of the model is performed for the span of The overall 81.9% correct prediction is relative high and the accuracy of correct prediction for urbanized area (62.3%) is relative satisfactory compared to the results of other researches in this field Observed Predicted Total % correct Urban Agriculture 45243 27425 72668 62.3 15775 150351 166126 90.5 Overall 61018 177776 238794 81.9
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Prognostic capacity evaluation (Cont’d)
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Summary Bridges the gap between spatio-temporal database modeling and land use change analysis Spatial-temporal data model represents complex land parcel changes dynamics over time and parcel Employs spatial land use, population and road network data to derive a predictive model of rural-urban land conversions in New Castle County, Delaware Succeeds largely in revealing the land use change
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