A New Perspective for Urban Development Boundary Delineation Based on the MCR Model and CA-Markov Model

Yi, Siqi; Yong, Zhou; Li, Qing

doi:10.3390/land11030401

Cited by 17 publications

(16 citation statements)

References 44 publications

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“…They also provided a framework to combine the raw types of ANNs with CA to model population dynamics and economic activities [31,32]. In 2022, Kim et al [33] and Yi et al [34] also pointed out that CA models could combine with machine-learning-based algorithms to enhance simulation accuracy and provide more reliable results. From their work, in line with many other studies in the urban expansion modeling field, all simulation models need to capture the complex nonlinear relationships between various driving factors and urban expansion parcels, via the "bottom-up" model approach and different transition rules.…”

Section: Introductionmentioning

confidence: 99%

Integrating ANNs and Cellular Automata–Markov Chain to Simulate Urban Expansion with Annual Land Use Data

Zhou

2022

Land

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Accurately simulating and predicting the urban expansion process, especially in expeditious urbanization areas, is an important aspect of managing limited land resources and adjusting flawed land use policies. This research was conducted on the basis of a high-temporal-resolution land use dataset to precisely model urban expansion in a rapidly developing zone by integrating the Artificial Neural Network (ANN), cellular automata (CA), and Markov Chain (MC). An urban suitability index (USI) map was created using ANN and fed to CA–MC to identify possible changed-to-urban cells. Two ANNs, multiple-layer perceptron (MLP) and long short-term memory network (LSTM), were implemented as simulation models for comparison. Due to its ability to capture more temporal information, LSTM outperformed MLP in modeling urban expansion dynamics over a short temporal interval. The simulated results were validated by (fuzzy) kappa simulation and the results revealed that the combination of ANN and CA–MC can precisely model the urban development locations due to its strength in revealing the nonlinear relationship between the expansion process and its drivers. The same model was applied to southern Auckland, and the compared results show that the most simulated variance is caused by the land use policies implemented by different types of governments.

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Section: Introductionmentioning

confidence: 99%

Integrating ANNs and Cellular Automata–Markov Chain to Simulate Urban Expansion with Annual Land Use Data

Zhou

2022

Land

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“…Markov model and cellular automata have probable pro ts in the investigation of land use variations. The CA-Markov simulation is capable to incorporate the data of geographic information system (GIS) and remote sensing well, therefore; is a strong and appropriate technique for simulating spatiotemporal change of LU/LC (Wang et al 2018;Yi et al 2022).…”

Section: Introductionmentioning

confidence: 99%

Predicting Land Use/Land Cover Changes in the Lesser Zab River Catchment/Iraq through CA-Markov Synergy Model

Mahdi

Mohammed

2022

Preprint

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Land use/land cover is measured as one of the utmost dynamic constituents of the atmosphere that has been altering abnormally from the time when after the industrial revolution at different measures. A well understanding of the drive and strength of environments needs regular monitoring and quantifying for land use/land cover alteration changing aspects. The current research targets to predict the prospect land use/land cover (LU/LC) alterations, for the Lesser Zab catchment in the Northern part of Iraq, applying the synergy Cellular Automata-Markov simulation. Three sequential year Landsat images (1999, 2010, and 2021) were categorized by the Maximum Likelihood method. Then, three LU/LC images with numerous class classifications were created and an alteration identification examination was performed. With the categorized (1999–2010) as well as (2010–2021) LU/LC maps in the hybrid model, the corresponded LU/LC maps for 2021 and 2041 were modeled, correspondingly. The classified 2021 LU/LC map was considered to validate model output 2021. The agreement accuracy between the categorised and the modeled images were Kno = 0.864, Klocation = 0.854, Kstandard = 0.785, in that order. Prospect likelihoods validate that between 2021 and 2041, the urban area would rise by 78% (from 1118 to 5200 km2). However, bare lands/light, agricultural lands, water bodies, bare lands/dark, and forest lands would decrease by 3% (from 6983 to 6736 km2), 12% (from 7992 to 7036 km2), 15% (from 141.03 to 119.86 km2), 30% (from 7 to 4 km2), and 76% (from 3810 to 904 km2), correspondingly. This study’s conclusions are priceless for policymakers, urban managers, and ecological researchers.

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“…Furthermore, the CA model has a high spatial resolution; and computational e ciency as the model can be linked with the GIS environs (Wang et al, 2018). The Markov chain model is commonly applied to simulate and predict the LU/LC changes pattern (Yi et al, 2022). Although, the Markov chain model cannot predict changes in spatial trends.…”

Section: Introductionmentioning

confidence: 99%

“…The CA-Markov simulation can incorporate the data of geographic information systems (GIS) and remote sensing well. Therefore, it is a strong and appropriate technique for simulating spatiotemporal change of LU/LC (Wang et al, 2018;Yi et al, 2022). Recently, the CA Markov model has effectively been applied to simulate the spatiotemporal change patterns of LU/LC by numerous studies (Hailu et al, 2018;Gidado et al, 2019;Msofeet al, 2019;Dibaba et al, 2020;Hishe et al, 2020;Munthali et al, 2020;Cui et al, 2021;Wang & Zheng, 2022;Yi et al, 2022).…”

Section: Introductionmentioning

confidence: 99%

“…Therefore, it is a strong and appropriate technique for simulating spatiotemporal change of LU/LC (Wang et al, 2018;Yi et al, 2022). Recently, the CA Markov model has effectively been applied to simulate the spatiotemporal change patterns of LU/LC by numerous studies (Hailu et al, 2018;Gidado et al, 2019;Msofeet al, 2019;Dibaba et al, 2020;Hishe et al, 2020;Munthali et al, 2020;Cui et al, 2021;Wang & Zheng, 2022;Yi et al, 2022). Accordingly, considering the ability of the model to expand understanding of the di culty of spatial system components, the current study considered the CA-Markov simulation to examine prospect LU/LC variations within Lesser Zab River Catchment (LZRC), north part of Iraq.…”

Section: Introductionmentioning

confidence: 99%

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Predicting Land Use/Land Cover Changes in the Lesser Zab River Catchment/Iraq through CA-Markov Synergy Model

Mahdi

Mohammed

2022

Preprint

View full text Add to dashboard Cite

Land use/land cover is one of the utmost dynamic constituents of the atmosphere that has been altering abnormally from the time after the industrial revolution at different measures. A good understanding of the drive and strength of environments needs regular monitoring and quantifying for land use/land cover alterations. The current research targets to predict the prospect of land use/land cover (LU/LC) alterations; for the Lesser Zab catchment in the Northern part of Iraq, applying the synergy Cellular Automata-Markov simulation. The Maximum Likelihood method classified three sequential years of Landsat images (1999, 2010, and 2021). Then, three LU/LC images, with numerous class classifications, were created, and an alteration identification examination; was performed. With the categorized (1999–2010) and (2010–2021) LU/LC maps in the hybrid model, the corresponded LU/LC maps; for 2021 and 2041; were modelled, and the classified 2021 LU/LC maps; were considered to validate the model output 2021. In that order, agreement accuracy between the classified and the modelled images was Kno = 0.864, Klocation = 0.854, and Kstandard = 0.785. Prospect likelihoods validate that between 2021 and 2041, the urban area would rise by 78% (from 1118 to 5200 km2). However, bare lands/light, agricultural lands, water bodies, bare lands/dark, and forest lands would decrease by 3% (from 6983 to 6736 km2), 12% (from 7992 to 7036 km2), 15% (from 141.03 to 119.86 km2), 30% (from 7 to 4 km2), and 76% (from 3810 to 904 km2), correspondingly. This study’s conclusions are priceless for policymakers, urban managers, and ecological researchers.

show abstract

A New Perspective for Urban Development Boundary Delineation Based on the MCR Model and CA-Markov Model

Cited by 17 publications

References 44 publications

Integrating ANNs and Cellular Automata–Markov Chain to Simulate Urban Expansion with Annual Land Use Data

Integrating ANNs and Cellular Automata–Markov Chain to Simulate Urban Expansion with Annual Land Use Data

Predicting Land Use/Land Cover Changes in the Lesser Zab River Catchment/Iraq through CA-Markov Synergy Model

Predicting Land Use/Land Cover Changes in the Lesser Zab River Catchment/Iraq through CA-Markov Synergy Model

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