Multi-Scenario Simulation of Production-Living-Ecological Space in the Poyang Lake Area Based on Remote Sensing and RF-Markov-FLUS Model
Abstract
:1. Introduction
- (1)
- To investigate regional land-use patterns and determine the development changes in regional space.
- (2)
- To simulate the territorial spatial pattern of the PYL area in 2030 under multiple scenarios using the RF-Markov-FLUS model and predict the spatial change characteristics.
- (3)
- To construct an enhancement path for sustainable development of PLE space from the perspective of the goal-problem-principle.
2. Materials and Methods
2.1. Study Area
2.2. Data
3. Methodology
3.1. The Object-Based Image Analysis (OBIA) Method
3.2. The RF-Markov-FLUS Model
3.2.1. Selecting the Drivers of Land-Use Change
3.2.2. Quantity Forecast
3.2.3. Spatial Distribution Simulation
3.3. Landscape Pattern Index
3.4. Multi-Scenario Spatial Constraints and Parameter Settings
3.5. The Space Type Dynamic Degree
4. Results
4.1. Accuracy Verification
4.2. Analysis of the Evolution of PLE Space from 1989 to 2020
4.2.1. Analysis of Spatial and Temporal Changes
4.2.2. Transfer Matrix Analysis
4.2.3. Landscape Pattern Analysis
- (a)
- The FRAC_MN index indicates the geometric complexity of each landscape type. During the study period, the production space and ecological space areas increased while the living space area decreased. This indicated that ecological and production spaces became more complex in shape, whereas living space expanded regularly from the center to the surroundings, with spatial continuity and unity. The landscape complexity decreased.
- (b)
- The IJI index reflects the overall dispersion and juxtaposition between specific landscape patch types. The production and living spaces exhibited more or less the same increase while ecological space increased and then decreased. Compared with the other two spaces, the IJI index for ecological space decreased from a maximum value in 1989 to a minimum value in 2020. Ecological space connectivity increased with the landscape patches of the other two spaces, indicating that the conservation of ecological space is easily constrained by the surrounding human activities.
- (c)
- The LSI index reflects the irregularity of landscape patches. During the study period, the production, living, and ecological space areas all increased, and for all of them, 2005 and 2010 were turning points for growth rate increases. The most significant change occurred in ecological space, which indicated that under the influence of human activities, the landscape regularity change was hindered, and fragmentation occurred.
- (d)
- The DIVISION index reflects the degree of separation of dominant landscape patches and patch integration. As Figure 7 shows, although the production and living space index values were higher, the changes were more stable compared to ecological space. Ecological space decreased and then increased, indicating that the dominant patches of ecological space decreased and were more dispersed from each other.
- (e)
- The COHESION index reflects the degree of aggregation and connectivity of each patch. The cohesion of patches decreased in production space and increased in living space, but ecological space remained stable, which indicated that the continuous expansion and protection of the landscape can improve connectivity. In general, the complexity, fragmentation, and dispersion of production and ecological space gradually increased, whereas the living space change was more steady, and the degree of connectivity and overall degree improved.
4.3. Multi-Scenario Simulation Results
5. Discussion
5.1. Discussion of the RF-Markov-FLUS Model
5.2. Comparison of Multi-Scenario Simulation Results
5.3. The Optimization of Territorial Space Pattern Enhancement
6. Conclusions
- (1)
- From 1989 to 2020, the production and ecological space areas in the study area both declined, by 717.9 and 1414.19 km2, respectively. Living space expanded from the center to the periphery with the fastest growth rate, with an area increase of 2144.72 km2, mainly dominated by the urban areas of Nanchang City and Jiujiang City, indicating the continuous expansion of urban living space.
- (2)
- Secondly, the PYL area experienced enhanced landscape fragmentation, landscape heterogeneity, landscape connectivity, and landscape dominance during the study period.
- (3)
- The overall accuracy of the RF-Markov-FLUS coupled model simulation was as high as 90.3%, and the Kappa coefficient of the model was 0.912. This showed it has strong applicability in the region and can predict the future spatial pattern of land use in all districts and counties in the PYL area.
- (4)
- According to the four scenario simulation results in 2030, production, living, and ecological spaces can be developed and protected to the greatest extent in the PSP, LSP, and ESP scenarios, respectively, but the ID scenario can more scientifically and reasonably lay out the spatial pattern of production, living, and ecology, realizing multiple functions of production, living, and ecology.
- (5)
- Based on the ID scenario and PYL area profile, we established a path framework to improve the territorial spatial function in three aspects: agricultural industry transformation, improved urban land use efficiency, and the creation of “mountain, water, forest, field, lake and grass” communities, which will help the government make more sustainable decisions in the PYL area.
Author Contributions
Funding
Data Availability Statement
Conflicts of Interest
References
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Type | Properties | Time | Data Type | Data Source |
---|---|---|---|---|
Land Use Data | Remote Sensing Images | 1989, 1995, 2000, 2005, 2010, 2015, 2020 | Raster (15 m/30 m) | USGS (https://earthexplorer.usgs.gov/) (accessed on 10 September 2021) |
Natural factors | Elevation | 2010, 2015, 2020 | Raster (30 m) | Resource and Environment Sciences and Data Center (https://www.resdc.cn/) (accessed on 30 September 2021) |
Slope | ||||
Slope orientation | ||||
Precipitation | WorldClim-Global Climate Data (http://www.worldclim.org/) (accessed on 30 September 2021) Local weather bureau and weather bulletin | |||
Average annual temperature | ||||
Socio-economic factors | Population density | 2010, 2015, 2020 | Raster (1 km) | Nanchang, Jiujiang, Shangrao City Statistical Yearbook |
GDP per capita | ||||
POI kernel density (airports, bus stations, buildings, schools, hotels, supermarkets, banks, etc.) | 2010, 2015–2021 | Vector | Baidu Map Open Platform (https://lbsyun.baidu.com/) (accessed on 20 October 2021) | |
Accessibility factors | Distance from city roads | 2010–2020 | Vector | OpenstreetMap Website (https://openstreetmap.org/) (accessed on 15 October 2021) National Catalogue Service For Geographic Information (http://www.webmap.cn) (accessed on 15 October 2021) |
Distance to railroad | ||||
Distance to the water system | ||||
Distance to urban center | ||||
Distance to rural settlements | ||||
Limiting factors | Permanent basic cropland protection red line | 2017 | Vector | Jiangxi Provincial Natural Resources Bureau |
Urban development boundary | 2019 | |||
Ecological protection red line | 2018 |
Category I | Category II | Description |
---|---|---|
Production space | Cropland | Land where crops are grown, including paddy fields, irrigated land, and dry land, which are important for agricultural production and function. |
Living space | Construction land | Land mainly used for housing and ancillary facilities, including urban and rural residential land, and land for supporting commercial services and other facilities. |
Ecological space | Water | Areas such as inland water bodies, mudflats, ditches, and marshes. Wetlands have water conservation and purification functions and are important ecological lands. |
Forest | Land where trees, bamboos, and shrubs grow. Forests play important roles in ecosystem regulation and biodiversity, and are important ecological lands. | |
Grassland | Land where herbaceous plants mainly grow, including natural pasture, marsh grassland, artificial pasture, and other grasslands. Grasslands have functions such as ecological landscape and water connotation and are important ecological lands. | |
Unused land | Land types other than those mentioned above, including saline land, sandy land, bare land, and other unused land, all of which are natural land cover types and are important ecological lands. |
Metrics | Index | Ecological Significance |
---|---|---|
Class/Landscape | FRAC_MN | Reflects the complexity of the shape in the range of spatial scales. The larger the value, the more convoluted the shape is from the regular geometry. |
IJI | IJI converges to zero when the distribution of nodes of a particular patch type in the landscape becomes uneven. | |
LSI | As the landscape shape becomes irregular and the edges lengthen, LSI increases and has no maximum limit. | |
DIVISION | The value approaches 1 when the area weight and patch size of that patch type in the landscape decreases. | |
COHESION | When the connectivity of a patch type in the landscape decreases, the value approaches 0. As the proportion of that type of patch composition in the landscape increases, the value increases. | |
Landscape | CONTAG | Reflects the degree of fragmentation of landscape patches, and the value approaches 0 when all patch types are maximally fragmented and randomly distributed. |
SHDI | Reflects landscape heterogeneity, and higher values reflect more diverse land use and higher fragmentation. | |
SHEI | Reflects the degree of uniformity in the distribution of different ecosystems in the landscape, and values close to 1 indicate more uniformity. | |
SPLIT | Reflects the degree of dispersion of landscape patches, and a maximum value occurs when the whole landscape is maximally refined. |
Production Space | Living Space | Ecological Space | ||||
---|---|---|---|---|---|---|
Year | Cropland Area | Construction Land | Water | Forest | Grassland | Unused Land |
1989 | 4695.60 | 1080.98 | 4905.83 | 4884.20 | 3839.61 | 902.39 |
1995 | 4856.34 | 1181.21 | 4183.11 | 5005.16 | 4197.74 | 898.07 |
2000 | 4679.42 | 1303.56 | 4311.90 | 4823.64 | 4047.56 | 1155.96 |
2005 | 4655.59 | 1366.57 | 4639.13 | 4780.30 | 3915.82 | 966.79 |
2010 | 4591.02 | 1893.56 | 4712.12 | 4499.16 | 3368.24 | 1260.10 |
2015 | 4547.87 | 2420.23 | 3750.40 | 4471.04 | 3760.14 | 1379.22 |
2020 | 3977.70 | 3225.70 | 4978.33 | 4407.06 | 2876.11 | 856.33 |
Area of change for each space | −717.9 | 2144.72 | −1414.19 | |||
dynamic degree (%) | −0.58 | 2.14 | −0.35 |
1989/2020 | Production Space | Living Space | Ecological Space | Total Transfers Out |
---|---|---|---|---|
Production space | 2413.36 | 996.05 | 1446.29 | 2442.34 |
Living Space | 72.63 | 600.84 | 507.11 | 579.74 |
Ecological Space | 1474.95 | 2348.33 | 10,457.85 | 3823.28 |
Total transfers in | 1547.58 | 3344.38 | 1953.4 |
Scenario | PSP | LSP | ESP | ID |
---|---|---|---|---|
Production space (km2) | 4162.01 | 3889.45 | 3819.99 | 3881.52 |
Percentage of the whole area (%) | 20.49 | 16.3 | 18.8 | 18.94 |
2020–2030 rate of change (%) | 0.91 | -3.28 | −0.77 | −0.64 |
Living space (km2) | 4343.28 | 5183.69 | 4318.21 | 4415.94 |
Percentage of the whole area (%) | 21.38 | 25.51 | 21.25 | 21.54 |
2020–2030 rate of change (%) | 5.5 | 9.63 | 5.38 | 5.67 |
Ecological Space (km2) | 11,811.95 | 11,823.39 | 12,179.04 | 12,200.01 |
Percentage of the whole area (%) | 58.14 | 58.19 | 59.94 | 59.52 |
2020–2030 rate of change (%) | −6.41 | −6.36 | −4.61 | −5.03 |
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Li, H.; Fang, C.; Xia, Y.; Liu, Z.; Wang, W. Multi-Scenario Simulation of Production-Living-Ecological Space in the Poyang Lake Area Based on Remote Sensing and RF-Markov-FLUS Model. Remote Sens. 2022, 14, 2830. https://doi.org/10.3390/rs14122830
Li H, Fang C, Xia Y, Liu Z, Wang W. Multi-Scenario Simulation of Production-Living-Ecological Space in the Poyang Lake Area Based on Remote Sensing and RF-Markov-FLUS Model. Remote Sensing. 2022; 14(12):2830. https://doi.org/10.3390/rs14122830
Chicago/Turabian StyleLi, Huizhong, Chaoyang Fang, Yang Xia, Zhiyong Liu, and Wei Wang. 2022. "Multi-Scenario Simulation of Production-Living-Ecological Space in the Poyang Lake Area Based on Remote Sensing and RF-Markov-FLUS Model" Remote Sensing 14, no. 12: 2830. https://doi.org/10.3390/rs14122830
APA StyleLi, H., Fang, C., Xia, Y., Liu, Z., & Wang, W. (2022). Multi-Scenario Simulation of Production-Living-Ecological Space in the Poyang Lake Area Based on Remote Sensing and RF-Markov-FLUS Model. Remote Sensing, 14(12), 2830. https://doi.org/10.3390/rs14122830