Spatial modeling and grade evaluation of forest and grass fire danger in Yunnan Province

doi:10.3969/j.issn.1000-2006.201808010

JOURNAL OF NANJING FORESTRY UNIVERSITY ›› 2020, Vol. 44 ›› Issue (2): 141-149.doi: 10.3969/j.issn.1000-2006.201808010

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Spatial modeling and grade evaluation of forest and grass fire danger in Yunnan Province

WANG Zhou()

Northwest Surveying, Planning and Design Institute of National Forestry and Grassland Administration, Xi’an 710048, China

Received:2018-08-04 Revised:2019-03-20 Online:2020-03-30 Published:2020-04-01

Abstract

Abstract:

【Objective】Spatial modeling and grade evaluation of forest and grass fire dangers are great significance in fire prevention. In this study, a framework of spatial non-stationarity was introduced to carry out fire danger modeling in Yunnan Province. 【Method】 Data from the Moderate Resolution Imaging Spectroradiometer(MODIS), four fire-influencing factors (vegetation status, temperature, topography, and accessibility), and geographically weighted Logistic regression (GWLR) were employed to model and evaluate the forest and grass fire danger. After checking the spatio-temporal distribution of fires during 2001 and 2014, an equal number of unburned and burned points from December to April were sampled according to the designed procedure. The sampled data were divided into seven groups (one group for two years); of these, four were selected to develop the GWLR model (i.e., training and inner validation subset) and three were used to validate the developed model (i.e., independent testing subset), which created thirty five datasets. After excluding potential multicollinearity among the independent variables, the 35 adaptive Gaussian GWLR models and 35 adaptive bi-square GWLR models were developed. Cross validation was utilized to evaluate the performance of the developed GWLR models. Statistical inference was carried out based on the optimal model. 【Result】 We concluded that attention should be paid to overfitting and spatial autocorrelation of residuals in the application of GWLR to fire danger studies as they may hamper fire prevention operations. The “extreme high” danger zone accounted for 12.7%, “very high” for 18.1%, and “high” for 19.0% of the forest and grass fires in Yunnan Province from 2001 to 2014. Together, the “extreme high” and “very high” zones accounted for 80% of these fires and could be labeled as the “key area” in the danger zone. We suggest that the locations of Wenshan, Honghe, Yuxi, Chuxiong, Lijiang, and Dali, which together account for 71.5% of the “key area,” should be recognized as the most fire-prone areas and must be given priority in receiving labor, funds, and goods for forest and grass fire prevention. High temperature was an all-important forest and grass fire-influencing factor in Yunnan Province, followed by altitude, slope, dead vegetation, and fraction of green vegetation. The accessibility of roads and villages also plays a role in controlling the spread of fire. The influence of environmental factors on the presence of fire presented significant spatial variability in this study; however, these factors are unique to the Yunnan Province. 【Conclusion】 According to the significant areas of fire-influencing factors and their relative weights, Yunnan Province can be divided into six fire prevention regions and requires the formulation of different fire prevention policies for each region.

Key words: forest and grass fire danger, geographically weighted Logistic regression (GWLR), spatial autocorrelation of residuals, cross validation, Yunnan Province

CLC Number:

S762
X43

WANG Zhou. Spatial modeling and grade evaluation of forest and grass fire danger in Yunnan Province[J]. JOURNAL OF NANJING FORESTRY UNIVERSITY, 2020, 44(2): 141-149.

Figures/Tables 6

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Table 1

Table 2

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统计量 statistics	高程 altitude	坡度 slope	到最近居民点距离 distance to the nearest village	到最近道路距离 distance to the nearest path	地表温度 land surface temperature	增强型植被指数 enhanced vegetation index	植被枯死率 degree of vegetation curing	植被湿度指数 global vegetation moisture index
最小值 min.	1.86	1.04	1.08	1.08	2.87	2.63	3.09	2.13
平均值 average	2.18	1.07	1.13	1.14	3.33	2.88	3.53	2.49
中位数 median	2.17	1.06	1.13	1.13	3.31	2.86	3.46	2.47
最大值 max.	2.46	1.12	1.17	1.20	3.97	3.62	4.87	2.90

统计量 statistics	赤池信息量 AIC		修正赤池信息量 AICc		贝叶斯信息量 BIC		均方根误差 RMSE		曲线下面积 AUC
统计量 statistics	AB-GWLR	AG-GWLR	AB-GWLR	AG-GWLR	AB-GWLR	AG-GWLR	AB-GWLR	AG-GWLR	AB-GWLR	AG-GWLR
最小值 min.	609.79	604.08	615.66	613.15	776.70	810.36	0.330 4	0.321 3	0.852 6	0.857 4
下四分位数 lower quartile	934.11	886.87	948.53	900.68	1 253.56	1 244.46	0.351 6	0.348 8	0.880 8	0.888 8
中位数 median	999.71	995.39	1 024.47	1 010.93	1 460.46	1 408.77	0.365 5	0.355 2	0.891 2	0.902 5
平均值 average	996.77	987.37	1 013.38	1 003.48	1 402.24	1 396.64	0.363 3	0.357 4	0.891 8	0.898 2
上四分位数 upper quartile	1 063.80	1 062.03	1 083.82	1 085.10	1 548.73	1 549.88	0.373 4	0.366 7	0.906 0	0.907 0
最大值 max.	1 456.37	1 310.11	1 456.51	1 320.51	1 836.94	1 777.74	0.396 1	0.386 5	0.927 8	0.935 6

Spatial modeling and grade evaluation of forest and grass fire danger in Yunnan Province

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