Abstract
Land-use change is a typical geographic evolutionary process characterized by spatial heterogeneity. As such, the driving factors, conversion rules, and rate of change vary for different regions around the world. However, most cellular automata (CA) models use the same transition rules for all cells in the model space when simulating land-use change. Thus, spatial heterogeneity change is ignored in the model, which means that these models are prone to over- or under simulation, resulting in a large deviation from reality. An effective means of accounting for the influence of spatial heterogeneity on the quality of the CA model is to establish a partitioned model based on cellular space partitioning. This study established a partitioned, dual-constrained CA model using the area-weighted frequency of land-use change (AWFLUC) to capture its spatial heterogeneity. This model was used to simulate the land-use evolution of the Dianchi Lake watershed. First, the CA space was divided into subzones using a dual-constrained spatial clustering method. Second, an artificial neural network (ANN) was used to automatically acquire conversion rules to construct an ANN-CA model of land-use change. Finally, land-use changes were simulated using the ANN-CA model based on data from 2006 to 2016, and model reliability was validated. The experimental results showed that compared with the non-partitioned CA model, the partitioned counterpart was able to improve the accuracy of land-use change simulation significantly. Furthermore, AWFLUC is an important indicator of the spatial heterogeneity of land-use change. The shapes of the division spaces were more similar to reality and the simulation accuracy was higher when AWFLUC was considered as a land-use change characteristic.
Highlights
Land-use and land-cover change (LUCC) are very important processes and represent the most direct outcome of the interaction between humans and landscapes
This study used artificial neural network (ANN) and the Cellular automata (CA) model to construct an ANN—CA model, based on the cellular-space partition theory and the dual-constrained partition method. This model was suitable for simulating the land-use change process in the Dianchi Lake watershed
Through the analysis and verification of the test results, the main conclusions are the following: (1) The partitioned CA based on dual-constrained spatial clustering significantly improved the simulation accuracy of the land-use change model
Summary
Land-use and land-cover change (LUCC) are very important processes and represent the most direct outcome of the interaction between humans and landscapes. It is often necessary to use landuse simulation models to understand the evolution of land-use change and its results [3]. It is able to simulate the spatio-temporal evolution of complex systems and is an easy model to understand and program. In recent decades, this model has been extensively used by researchers in land-use evolution and urban expansion studies [4,5,6]. The conversion rule is the dynamic basis of CA to simulate the evolution of a complex system; it has an important influence on the simulation process and results [7,8]
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