Scale Effects of the Relationships between Urban Heat Islands and Impact Factors Based on a Geographically-Weighted Regression Model
"> Figure 1
<p>Location of the study area ((<b>a</b>) China, (<b>b</b>) Chongqing, and (<b>c</b>) the study area).</p> "> Figure 2
<p>The derivation results of SAVI, IBI, NDSI, LST, and the classification result of the study area at the spatial resolution of 30 m ((<b>a</b>) SAVI; (<b>b</b>) NDSI; (<b>c</b>) IBI; (<b>d</b>) LST; and (<b>e</b>) the classification result of the study area).</p> "> Figure 3
<p>The spatial distribution of the local coefficients estimated by GWR models at a spatial resolution of 30 m. (<b>a</b>–<b>c</b>) are the slope coefficients for the SAVI, IBI, and NDSI in single-factor models, respectively; and (<b>d</b>–<b>f</b>) are the coefficients for the SAVI, IBI, and NDSI in multi-factor models, respectively. Moreover, the yellow area represents water.</p> "> Figure 4
<p>The spatial distribution of the local R<sup>2</sup> in the GWR models at a spatial resolution of 30 m, (<b>a</b>) for the LST–SAVI model; (<b>b</b>) for the LST–IBI model; (<b>c</b>) for the LST–NDSI model; and (<b>d</b>) for the multi-factor model (using the SAVI, IBI, and NDSI as the explanatory variables simultaneously). Moreover, the yellow area represents water.</p> "> Figure 5
<p>The spatial distribution of the local R<sup>2</sup> in the multi-factor GWR models (using the SAVI, IBI, and NDSI as the explanatory variables simultaneously) at different spatial resolutions, (<b>a</b>–<b>f</b>) represent the spatial resolutions of 30 m, 60 m, 120 m, 240 m, 480 m, and 960 m, respectively. Moreover, the yellow area represents water.</p> "> Figure 6
<p>The spatial distribution of the local residuals in the multi-factor GWR models (using the SAVI, IBI, and NDSI as the explanatory variables simultaneously) at different spatial resolutions; (<b>a</b>)–(<b>f</b>) represent the spatial resolutions of 30 m, 60 m, 120 m, 240 m, 480 m, and 960 m, respectively. Moreover, the blue area represents water.</p> ">
Abstract
:1. Introduction
2. Study Area
3. Methods
3.1. Image Pre-Processing
3.2. Derivation of the Parameters and Data Aggregation
3.2.1. Dependent Variable: LST
3.2.2. Explanatory Variables: SAVI, IBI, and NDSI
3.2.3. Data aggregation
3.3. Geographically-Weighted Regression
4. Results
4.1. The Derivation Results of SAVI, IBI, NDSI, LST and Classification Result of the Study Area
4.2. Data Sampling
4.3. The Analysis of the Relationships between the LST and the Impact Factors at a Single Scale
4.3.1. Comparisons between the OLS and GWR Models
4.3.2. Spatial Non-Stationarity among Relationships
4.4. Scale Effects of the Relationships Based on the GWR model at Multiple Scales
5. Discussion
6. Conclusions
- Both single-factor and multi-factors GWR models have better prediction accuracies, characterized by much smaller AICc values, higher adjusted R2 values, and better F-tests, when compared with the corresponding OLS models. At the same time, both the coefficients and the local R2 of the GWR models are changing with the spatial location, and this indicates that the GWR has a good ability to characterize the non-stationarity of the relationships between the LST and the indices.
- With the increase of spatial scales, the overall fitting degree of the GWR model is gradually improved based on the distribution range, the mean value of local R2. However, the standard deviation of the local R2 and residuals are gradually reduced from 0.22 (30 m) to 0.03 (960 m) and 1.83 (30 m) to 0.52 (960 m), respectively. Meanwhile, the Moran’s I values of the residuals gradually increase from 0.19 (30 m) to 0.39 (960 m). This indicates the GWR model becomes increasingly global, revealing the relationships with more generalized geographical patterns, and then spatial non-stationarity in the relationship tends to be neglected with the increase of the spatial resolution.
- Characterized by higher R2 value and lower AICc value, GWR models have better ability than OLS models to explain the relationships between SUHI and impact factors (the SAVI, IBI, and NDSI) at small spatial scales (30 m–240 m), and when the spatial scale is increased to 480 m and 960 m, this advantage has become relatively weak because the GWR model becomes increasingly global, revealing the relationships with more generalized geographical patterns, and then spatial non-stationarity in the relationship tends to be neglected with the increase of the spatial resolution. Therefore, if the spatial resolution of remote sensing data is less than 240 m, GWR mode is recommended to be used in the monitoring and analysis of SUHI in the mountain city, and when the spatial resolution is greater than 480 m, both GWR and OLS models are suitable for the researches of SUHI because there are few performance differences between them.
Acknowledgments
Author Contributions
Conflicts of Interest
Abbreviations
GWR | Geographically weighted regression |
OLS | Ordinary least squares |
UHI | Urban heat island |
LST | Land surface temperature |
SAVI | Soil-adjusted Vegetation Index |
IBI | Index-based Built-up Index |
NDSI | Soil Brightness Index |
NDVI | Normalized Difference Vegetation Index |
NDWI | Normalized Difference Water Index |
NDBI | Normalized Difference Built-up Index |
NDBaI | Normalized Difference Bareness Index |
ANN | Artificial neural network |
TM | Thematic Mapper |
TOA | Top-of-atmospheric radiance |
AICc | Corrected Akaike Information Criterion |
R2 | Coefficient of determination |
Moran’s I | Moran’s Index |
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Spatial Resolution | Sampling Interval | Number | |
---|---|---|---|
Column | Line | ||
30 m | 8 | 8 | 13,668 |
60 m | 4 | 4 | 13,660 |
120 m | 2 | 2 | 13,730 |
240 m | 1 | 1 | 12,556 |
480 m | 1 | 1 | 4186 |
960 m | 1 | 1 | 1002 |
Explanatory Variables | Model | AICc | Adjusted R2 | F |
---|---|---|---|---|
SAVI | OLS | 31,304 | 0.56 | |
GWR | 29,299 | 0.68 | 105.27 | |
IBI | OLS | 30,968 | 0.58 | |
GWR | 28,800 | 0.70 | 108.54 | |
NDSI | OLS | 32,356 | 0.49 | |
GWR | 30,233 | 0.63 | 107.83 | |
SAVI, IBI, NDSI | OLS | 30,379 | 0.62 | |
GWR | 28,083 | 0.73 | 111.61 |
30 m | 60 m | 120 m | 240 m | 480 m | 960 m | |
---|---|---|---|---|---|---|
Minimum | −2.78 | −2.52 | −2.47 | −2.18 | −1.84 | −1.38 |
Maximum | 4.10 | 3.85 | 3.81 | 2.35 | 1.97 | 1.25 |
Std. | 1.83 | 1.73 | 1.53 | 1.1 | 0.96 | 0.52 |
Moran’s I | 0.19 | 0.2 | 0.21 | 0.31 | 0.34 | 0.39 |
Model | Evaluation Indices | 30 m | 60 m | 120 m | 240 m | 480 m | 960 m |
---|---|---|---|---|---|---|---|
GWR | AICc | 28,083 | 27,338 | 25,809 | 18,773 | 6953 | 1331 |
adjusted R2 | 0.73 | 0.76 | 0.81 | 0.86 | 0.89 | 0.88 | |
OLS | AICc | 30,379 | 29,522 | 28,549 | 23,923 | 9373 | 1465 |
adjusted R2 | 0.62 | 0.66 | 0.71 | 0.77 | 0.83 | 0.85 |
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Luo, X.; Peng, Y. Scale Effects of the Relationships between Urban Heat Islands and Impact Factors Based on a Geographically-Weighted Regression Model. Remote Sens. 2016, 8, 760. https://doi.org/10.3390/rs8090760
Luo X, Peng Y. Scale Effects of the Relationships between Urban Heat Islands and Impact Factors Based on a Geographically-Weighted Regression Model. Remote Sensing. 2016; 8(9):760. https://doi.org/10.3390/rs8090760
Chicago/Turabian StyleLuo, Xiaobo, and Yidong Peng. 2016. "Scale Effects of the Relationships between Urban Heat Islands and Impact Factors Based on a Geographically-Weighted Regression Model" Remote Sensing 8, no. 9: 760. https://doi.org/10.3390/rs8090760
APA StyleLuo, X., & Peng, Y. (2016). Scale Effects of the Relationships between Urban Heat Islands and Impact Factors Based on a Geographically-Weighted Regression Model. Remote Sensing, 8(9), 760. https://doi.org/10.3390/rs8090760