A New Method of Adaptive Zoning for Spatial Interaction Models. Hagen-Zanker, A. & Jin, Y. Geographical Analysis, 44(4):281–301, 2012.
A New Method of Adaptive Zoning for Spatial Interaction Models [link]Paper  doi  abstract   bibtex   
Spatial interaction models commonly use discrete zones to represent locations. The computational requirements of the models normally arise with the square of the number of zones or worse. For computationally intensive models, such as land use�transport interaction models and activity-based models for city regions, this dependency of zone size is a long-standing problem that has not disappeared even with increasing computation speed in PCs�it still forces modelers to compromise on the spatial resolution and extent of model coverage as well as on the rigor and depth of model-based analysis. This article introduces a new type of discrete zone system, with the objective of reducing the time for estimating and applying spatial interaction models while maintaining their accuracy. The premise of the new system is that the appropriate size of destination zones depends on the distance to their origin zone: at short distances, spatial accuracy is important and destination zones must be small; at longer distances, knowing the precise location becomes less important and zones can be larger. The new method defines a specific zone map for every origin zone; each origin zone becomes the focus of its own map, surrounded by small zones nearby and large zones farther away. We present the theoretical formulation of the new method and test it with a model of commuting in England. The results of the new method are equivalent to those of the conventional model, despite reducing the number of zone pairs by 96% and the computation time by 70%.
@article{hagen-zanker_new_2012,
	title = {A {New} {Method} of {Adaptive} {Zoning} for {Spatial} {Interaction} {Models}},
	volume = {44},
	copyright = {� 2012 The Ohio State University},
	issn = {1538-4632},
	url = {http://onlinelibrary.wiley.com/doi/10.1111/j.1538-4632.2012.00855.x/abstract},
	doi = {10.1111/j.1538-4632.2012.00855.x},
	abstract = {Spatial interaction models commonly use discrete zones to represent locations. The computational requirements of the models normally arise with the square of the number of zones or worse. For computationally intensive models, such as land use�transport interaction models and activity-based models for city regions, this dependency of zone size is a long-standing problem that has not disappeared even with increasing computation speed in PCs�it still forces modelers to compromise on the spatial resolution and extent of model coverage as well as on the rigor and depth of model-based analysis. This article introduces a new type of discrete zone system, with the objective of reducing the time for estimating and applying spatial interaction models while maintaining their accuracy. The premise of the new system is that the appropriate size of destination zones depends on the distance to their origin zone: at short distances, spatial accuracy is important and destination zones must be small; at longer distances, knowing the precise location becomes less important and zones can be larger. The new method defines a specific zone map for every origin zone; each origin zone becomes the focus of its own map, surrounded by small zones nearby and large zones farther away. We present the theoretical formulation of the new method and test it with a model of commuting in England. The results of the new method are equivalent to those of the conventional model, despite reducing the number of zone pairs by 96\% and the computation time by 70\%.},
	language = {en},
	number = {4},
	urldate = {2014-01-10TZ},
	journal = {Geographical Analysis},
	author = {Hagen-Zanker, A. and Jin, Y.},
	year = {2012},
	pages = {281--301}
}
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