基于优化MaxEnt模型的重庆市罗盘山猪潜在适生区预测

doi:10.3864/j.issn.0578-1752.2026.01.015

摘要/Abstract

摘要：

【背景】重庆市罗盘山猪是国家和地方重点保护的珍稀地方猪种，当前已处于濒危状态，亟需开展抢救性保护。在原地保护的基础上，建立保种场等异地保护措施可作为有效补充以应对原生地生态破坏或非洲猪瘟等突发疫情导致的种群锐减风险。【目的】根据农业农村部《畜禽遗传资源保种场保护区和基因库管理办法》的要求，异地保种场的场址应选择与原产地自然生态条件一致或相近的区域。为明确重庆市范围内适合罗盘山猪生存与繁衍的潜在区域，指导今后异地保护和保种场选址，并为规模化养殖提供科学依据。【方法】基于重庆市现场直接监测获得的105个罗盘山猪分布位点信息，采用机器学习（scikit-learn）库构建随机森林机器学习器以分析土壤（速效磷、速效钾、速效氮、阳离子交换率、有机质组成、酸碱度）、地表温度、降水量、高程、距水系的距离等16个环境与人为因子特征重要性，通过沙普利加法解释（shapley additive explanations, SHAP）量化每个特征对模型预测结果的边际贡献。同时，利用16个环境因子构建初始模型，在Python环境中对所有因子进行皮尔逊相关系数（pearson correlation coefficient, PCC）的成对矩阵分析。综合多阶段环境因子的筛选与对比，对所得变量进行方差膨胀因子（variance inflation factor, VIF）共线性复查，最终将最后筛选的环境变量和物种分布数据加载到最大熵模型（maximum entropy model, MaxEnt）中，分析了罗盘山猪适生区的分布状况及主要环境影响因子。【结果】平均训练集的曲线下面积（area under the curve, AUC）值为0.995，预测结果达到优秀水平；影响重庆市罗盘山猪生境适宜性的主要环境因子为降水量（39.7%）、酸碱度（24.1%）、速效磷（18.9%）、地表温度（6.2%）和距建筑的距离（5.7%），总贡献值为94.6%；次要环境因子包括速效钾（1.9%）、高程（1.4%）、河流（1.2%）、阳离子交换容量（0.8%）与速效氮（0.1%），总贡献值为5.4%；罗盘山猪在重庆市的适生区主要零散分布于潼南区，合川区，大足区与荣昌等区，总面积为4 217.59 km²，占重庆市土地面积的5.1%。其中，高适生区面积为189.44 km²，具体包括潼南区的新胜镇、卧佛镇、塘坝镇，大足区的高坪镇、三驱镇、珠溪镇、邮亭镇等，荣昌区峰高街道与万灵镇，铜梁区的维新镇，永川区茶山竹海街道等。较高适生区面积为554.97 km²。较低适生区面积为1 034.78 km²，低适生区面积为2 438.39 km²。【结论】本研究不仅为重庆市罗盘山猪的异地保护时保种场选址提供决策支持，也可为其他地方珍稀畜禽的生境适宜性评估与科学管理提供参考。

关键词: 罗盘山猪, MaxEnt 模型, 适生区分布预测, 重庆市

Abstract:

【Background】The Luopanshan pig, a rare indigenous breed native to Chongqing, is recognized as a key genetic resource at both national and regional levels. However, due to factors such as changes in breeding structures and outbreaks of African swine fever, its population has declined sharply, leading to a significant loss of genetic diversity. Urgent conservation measures are required to prevent its extinction. While in situ conservation remains the primary strategy, establishing ex situ conservation farms serves as a crucial supplementary approach to mitigate risks associated with habitat degradation and disease outbreaks. 【Objective】In accordance with the Measures for the Administration of Conservation Farms, Protected Areas, and Gene Banks for Livestock and Poultry Genetic Resources issued by the Ministry of Agriculture and Rural Affairs, ex-situ conservation farms should be established in locations where the natural ecological conditions closely match those of the breed’s original habitat. To facilitate the formulation of evidence-based strategies for the ex-situ conservation of the Luopanshan pig, this study aimed to identify potential areas within Chongqing Municipality that were environmentally suitable for its survival and reproduction. The findings were expected to provide a scientific basis for future conservation farm site selection and to support the sustainable development of large-scale breeding programs. 【Method】Utilizing 105 georeferenced occurrence records of Luopanshan pigs collected through field surveys in Chongqing, a Random Forest machine learning model via the scikit-learn library was employed to assess the relative importance of 16 environmental and anthropogenic variables, including soil properties (Available Phosphorus, Available Potassium, Available Nitrogen, Cation Exchange Capacity, Soil Organic Matter and Soil pH), land surface temperature, precipitation, digital elevation model, and STREAM. SHapley Additive exPlanations (SHAP) were used to quantify the marginal contribution of each variable to the model's predictions. Pearson correlation coefficients (PCC) were calculated to evaluate multicollinearity among variables, and variance inflation factors (VIF) were applied for further collinearity diagnostics. The refined set of variables and species occurrence data were then input into the Maximum Entropy Model (MaxEnt) model to predict habitat suitability and identify key environmental factors influencing the distribution of Luopanshan pigs. 【Result】The MaxEnt model achieved a high predictive performance, with an average Area Under the Curve (AUC) value of 0.995, indicating excellent model accuracy. The primary environmental factors influencing the habitat suitability of wild boars in Luopanshan, Chongqing, were precipitation (39.7%), pH (24.1%), available phosphorus(18.9%), land surface temperature (6.2%), and distance to buildings(5.7%), with a total contribution of 94.6%. Secondary environmental factors include available potassium(1.9%), digital elevation model(1.4%), STREAM(1.2%), cation exchange capacity(0.8%), and available nitrogen(0.1%), contributing 5.4% in total. Suitable habitats for Luopanshan pigs were predominantly scattered across Tongnan, Hechuan, Dazu, and Rongchang districts, encompassing a total area of 4 217.59 km², which represented 5.1% of Chongqing's land area. Among these, highly suitable habitats covered 189.44 km², notably in Xingsheng, Wofu, and Tangba towns of Tongnan District; Gaoping, Sanqu, Zhuxi, and Youting towns of Dazu District; Fenggao Subdistrict and Wanling Town of Rongchang District; Weixin Town of Tongliang District; and Chashan Zhuhai Subdistrict of Yongchuan District. Moderately suitable habitats spanned 554.97 km², while low suitability areas covered 1 034.78 km², and marginally suitable areas accounted for 2 438.39 km². 【Conclusion】This study provided a scientific basis for the strategic planning of ex situ conservation farms for Luopanshan pigs in Chongqing. The methodology and findings also offered a reference framework for habitat suitability assessments and conservation management of other indigenous and rare livestock breeds.

Key words: Luopanshan pig, MaxEnt model, prediction of suitable habitat distribution, Chongqing City

周旗, 张世豪, 张亮, 潘雨, 张利娟, 涂志, 潘红梅, 龙熙. 基于优化MaxEnt模型的重庆市罗盘山猪潜在适生区预测[J]. 中国农业科学, 2026, 59(1): 205-219.

ZHOU Qi, ZHANG ShiHao, ZHANG Liang, PAN Yu, ZHANG LiJuan, TU Zhi, PAN HongMei, LONG Xi. Prediction of the Potential Habitat Suitability of Luopanshan Pigs in Chongqing Based on the Optimized MaxEnt Model[J]. Scientia Agricultura Sinica, 2026, 59(1): 205-219.

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https://www.chinaagrisci.com/CN/Y2026/V59/I1/205

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变量类型 Factors type	描述 Description
环境因子 Environmental factors	年降水量 Precipitation (PREC)
	地表温度 Land surface temperature (LST)
	速效钾 Available potassium (AK)
	速效磷 Available phosphorus (AP)
	速效氮 Available nitrogen (AN)
	阳离子交换率 Cation exchange capacity (CEC)
	有机质组成 Soil organic matter (SOM)
	酸碱度 pH
	坡度 Slope
	高程 Digital elevation model (DEM)
	归一化植被指数 Normalized difference vegetation index (NDVI)
人为因子 Human factor	距建筑物的距离 BUILDING
	土地利用/覆盖 Land use and land cover (LULC)
	人口密度 Population density (POP)
	距道路的距离 ROAD
	距水系的距离 STREAM

高相关变量对 Highly correlated variable pairs	系数 Coefficient	处理方式 Process mode
AP-AN	0.86	保留AP Reserve AP
AK-AN	0.86	保留AK Reserve AK
AK-AP	1	保留AP Reserve AP
pH-AN	0.86	保留pH Reserve pH
pH-AP	1	保留AP Reserve AP
pH-AK	1	保留pH Reserve pH
CEC-AN	0.86	保留CEC Reserve CEC
CEC-AP	1	保留AP Reserve AP
CEC-AK	1	保留AK Reserve AK
CEC-pH	1	保留pH Reserve pH
STREAM-DEM	0.9	保留DEM Reserve DEM
ROAD-DEM	0.93	保留DEM Reserve DEM
ROAD-STREAM	0.98	保留STREAM Reserve STREAM

环境变量 Variable	贡献率 Contribution (%)	排列重要性 Permutation importance
年降水量 PREC	39.7	73.3
酸碱度 pH	24.1	9.0
速效磷 AP	18.9	9.6
地表温度 LST	6.2	2.5
距建筑物的距离 BUILDING	5.7	0.6
速效钾 AK	1.9	2.2
高程 DEM	1.4	2.5
距水系的距离 STREAM	1.2	0.1
阳离子交换率 CEC	0.8	0.1
速效氮 AN	0.1	0.1

区县名称 Districts and Counties	高适生区 Highly suitable habitat area	较高适生区 Moderately highly suitable habitat area	区县名称 Districts and counties	高适生区 Highly suitable habitat area	较高适生区 Moderately highly suitable habitat area
潼南区 Tongnan District	新胜镇 Xinsheng town	别口镇Biekou town	荣昌区 Rongchang District	峰高街道 Fenggao district	万灵镇 Wanling town
	卧佛镇 Wofo town	小渡镇Xiaodu town			直升镇 Zhisheng town
	塘坝镇 Tagba town	五桂镇 Wugui town			直升镇 Zhisheng town
合川区 Hechuan District	太和镇 Taihe District	渭沱镇 Weituo town	永川区 Yongchuan District	双石镇 Shuangshi town	胜利路街道 Shengli Road district
		三庙镇Sanmiao town		茶山竹海街道 Chashanzhuhai district	吉安镇Ji 'an town
		三庙镇Sanmiao town		朱沱镇 Zhuduo town	大安街道Da 'an district
铜梁区 Tonglian District	维新镇 Weixin town	少云镇 Shaoyun	璧山区 Bishan District	三合镇 Sanhe town	正兴镇 Zhengxing town
	高楼镇Gaolou town
	安居镇Anju town
大足区 Dazu District	高坪镇 Gaoping town	宝兴镇 Baoxing town	江津区 Jiangjin District	油溪镇Youxi town	慈云镇 Ciyun town
	三驱镇 Sanqu town	龙石镇 Longshi town		白沙镇Baisha town	蔡家镇 Caijia town
	珠溪镇 Zhuxi town	龙岗街道 Longgang District		白沙镇Baisha town	蔡家镇 Caijia town