基于尾长算法的戴云山保护区优化设计

doi:10.11707/j.1001-7488.20180915

摘要/Abstract

摘要： [目的]保护区规划设计是自然保护区研究的重要内容，以数学模型为工具研究保护区设计成为新趋势。集合覆盖物种模型（SCSP）和最大集合物种模型（MCSP）等传统数学模型，仅考虑以最小代价进行保护区规划及设计，未考虑保护区的空间特征，导致选择的保护区区域过于分散，且仅考虑土地市场价格，不能完全体现保护区生态价值。本研究以生态值为衡量指标，结合连续性和紧实性的空间特征，构建有效合理的保护区规划模型，以期为自然保护区建立提供科学依据。[方法]以福建省戴云山国家级自然保护区为例，将戴云山区域划分为567个规则地块，每个地块面积为2 km×2 km，且任意地块都包含若干个小班。依据生态值赋分标准和重心算法，先后计算戴云山小班和其所属地块生态值。结合特殊空间特征与生态值，构建基于尾长法的空间集合覆盖模型（SSCP），并探讨不同紧实性权重和物种保护比例组合对保护区规划结果的影响。最后，以传统SCSP模型、系统保护规划工具Marxan模型和Zonation模型的规划结果为对照组，验证SSCP模型的有效性。[结果]从空间分布来看，用SCSP模型、Marxan模型和Zonation模型求解的保护区设计结果表现为地块分布离散，破碎度高，SSCP模型的设计结果表现出更好的连续性和紧实性；从选地数量来看，SSCP模型的选地数量与物种保护比例及紧实性权重正相关，即物种保护比例上升，或紧实性权重增大，选中的地块数增加。[结论]研究设计了新型保护区数学规划模型——SSCP模型，并以戴云山自然保护区为例验证了算法的合理性，提出规划建议：向其西北方向和东南方向扩展，其中西北方向纵向扩展6 km，横向扩展18 km，东南方向纵向扩展9 km，横向扩展8 km。本研究方法的提出为我国保护区规划设计理论与实践提供新思路。

关键词: 自然保护区, 生态值, 空间特征, 最优解, 戴云山

Abstract: [Objective] Planning and design is an important issue in nature reserve studies. It is a new trend that takes mathematical models as a tool to study the reserve design. Traditional mathematical models, such as the set covering species problem (SCSP) and the maximal covering species problem (MCSP), only consider to plan and design the reserve at the lowest cost. They do not consider spatial characteristics of the reserve, leading to over fragmentation of the selected areas for nature reserve. In addition, these methods only consider the price of land which cannot fully reflect the ecological value of the protected areas. This study uses the ecological value as indicators and associated with the spatial characteristics of continuity and compactness to construct an effective and reasonable model for nature reserve design. The proposed model was aimed to establish the nature reserve and provided a scientific basis for nature reserve establishment.[Method] Taking Daiyun Mountain national nature reserve of Fujian Province as an example, we divided the reserve into 567 regular blocks. The area of each block was 2 km×2 km and each had several sub-compartments. Firstly, according to the scoring standards for ecological values and the weighting algorithm, the ecological value of sub-compartments and its associated blocks was calculated successively. Secondly, based on the special spatial characteristics and ecological values, the space-ecology set covering problem (SSCP) based on the tail length algorithm was constructed, and the effects of various combinations between the compactness with different weights and the percentage of protected species on overall performance of protected areas were discussed. Finally, the traditional SCSP model, the system protection planning tool Marxan model and the Zoning model were used as the control group to verify the validity of the SSCP model.[Results] From the perspective of spatial distribution, the design results of the protected area solved by SCSP model, Marxan model and Zonation model were as follows:the distribution of the blocks was discrete and the degree of fragmentation was high. In contrast, the design of the SSCP model showed better continuity and compactness than previous methods. The number of selected blocks of the SSCP model was positively correlated with the proportion of species protection and the weight of compactness, indicating an increase of the proportion of species protection or an increase of the weight of density, would come up with an increase of the number of selected blocks.[Conclusion] The mathematical programming model for new type of protected area, i.e. the SSCP model, was studied. The rationality of the algorithm was verified by a case study of the Daiyunshan Nature Reserve. Following proposal was provided:The Daiyunshan Nature Reserve should be extended towards northwest and southeast, with an extension of 6 km towards the northwest and an horizontal extension of 18 km; an extension of 9 km towards the southeast and a horizontal extension of 8 km. The proposed method presents a new idea for the theory and practice of planning and design of protected areas in China.

Key words: nature reserve, ecological value, spatial characteristics, optimal solution, Daiyun Mountain

中图分类号:

S759.9

丁启禄, 林志玮, 刘金福, 涂伟豪, 黄嘉航, 兰思仁, 洪伟. 基于尾长算法的戴云山保护区优化设计[J]. 林业科学, 2018, 54(9): 125-136.

Ding Qilu, Lin Zhiwei, Liu Jinfu, Tu Weihao, Huang Jiahang, Lan Siren, Hong Wei. Optimum Design of Daiyun Mountain Nature Reserve Based on Tail Length[J]. Scientia Silvae Sinicae, 2018, 54(9): 125-136.

参考文献

黄嘉航, 刘金福, 林志玮, 等. 2017. 基于空间生态集合覆盖模型的自学习禁忌搜索算法在保护区空间选址中的应用——以戴云山为例. 应用生态学报, 28(1): 219-230.
(Huang J H, Liu J F, Lin Z W et al. 2017. Site selection of nature reserve based on the self-learning tabu search algorithm with space-ecology set covering problem: an example from Daiyun Mountain, Southeast China. Chinese Journal of Applied Ecology, 28(1): 219-230. [in Chinese])
梁美霞. 2014. 福建戴云山自然保护区生态系统服务价值评估. 西北林学院学报, 29(1): 263-268.
(Liang M X. 2014. The ecosystem service valuation of Daiyunshan Nature Reserve in Fujian. Journal of Northwest Forestry University, 29(1): 263-268. [in Chinese])
刘金福, 朱德煌, 兰思仁, 等. 2013. 戴云山黄山松群落与环境的关联. 生态学报,33(18): 5731-5736.
(Liu J F, Zhu D H, Lan S R, et al. 2013. Association between environment and community of Pinus taiwanensis in Daiyun Mountain. Acta Ecologica Sinica, 33(18): 5731-5736. [in Chinese])
刘思慧, 王应祥. 2002.中国的生物多样性保护与自然保护区. 世界林业研究, 15(4): 47-54.
(Liu S H, Wang Y X. 2002.The relationship between biodiversity conservation and nature reserve in China. World Forestry Research, 15(4): 47-54. [in Chinese])
孟宪宇. 1995. 测树学. 北京: 中国林业出版社.
(Meng X Y. 1995. Forest measurement. Beijing: China Forestry Publishing House. [in Chinese])
任国学, 刘金福, 徐道炜, 等. 2011. 戴云山国家级自然保护区黄山松群落类型与物种多样性分析. 植物资源与环境学报, 20(3): 82-88.
(Ren G X, Liu J F, Xu D W, et al. 2011. Analysis on classification and species diversity of Pinus taiwanensis community in Daiyun Mountain National Nature Reserve. Journal of Plant Resources and Environment, 20(3): 82-88. [in Chinese])
苏松锦, 刘金福, 陈文伟, 等. 2014. 戴云山黄山松林土壤水分物理性质空间变异特征与格局. 资源科学,36(11): 2423-2430.
(Su S J, Liu J F, Chen W W, et al. 2014. Spatial variability and patterns of soil moisture physical properties in Pinus taiwanensis Forest Based on geostatistics and GIS. Resources Science, 36(11): 2423-2430. [in Chinese])
唐小平. 2015. 我国自然保护区总体规划研究综述. 林业资源管理, (6): 1-9.
(Tang X P. 2015.Overview on formulation and implementation of master plans for nature reserves in china. Forest Resources Management, (6): 1-9. [in Chinese])
王京歌. 2015. 我国自然保护区的现状与问题. 生态经济,31(3): 10-13.
(Wang J G.2015. Status and problems of nature reserves in China. Ecological Economy, 31(3): 10-13. [in Chinese])
王宜成. 2011a. 最优化设计连续的自然保护区. 生态学报,31(17): 5033-5041.
(Wang Y C. 2011a. The optimal design of a connected nature reserve network. Acta Ecologica Sinica, 31(17): 5009-5016. [in Chinese])
王宜成. 2011b. 用原图-对偶图法设计内部间隔最小的自然保护区. 生物多样性, 19(4): 404-413.
(Wang Y C. 2011b. A model for designing nature reserves with minimal fragmentation using a primal-dual graph approach. Biodiversity Science, 19(4): 404-413. [in Chinese])
吴文英, 左勤, 王幼芳, 等. 2012. 福建戴云山国家级自然保护区藓类植物区系研究. 植物科学学报, 30(2): 122-132.
(Wu W Y, Zuo Q, Wang Y F, et al. 2012. Study on the moss flora of the Daiyunshan National Nature Reserve, Fujian Province. Plant Science Journal, 30(2): 122-132. [in Chinese])
徐建国. 2012. 戴云山国家级自然保护区森林生物多样性保护探讨. 林业建设, (4): 35-37.
(Xu J G. 2012. Discussion on conservation of forest biodiversity in Daiyun mountain national nature reserve. Forestry Construction, (4): 35-37. [in Chinese])
徐网谷, 王智, 钱者东, 等. 2015. 我国自然保护区范围界定和有效保护面积现状研究. 生态与农村环境学报, 31(6): 791-795.
(Xu W G, Wang Z, Qian Z D et al. 2015.Status quo of delineation of ranges of nature reserves and area of nature reserves under effective protection. Journal of ecology and rural environment, 31(6): 791-795. [in Chinese])
薛凡, 刘金福, 兰思仁, 等. 2013. 戴云山国家级自然保护区植物多样性评价与可持续发展策略研究. 武夷科学, 29(1): 6-15.
(Xue F, Liu J F, Lan S R, et al. 2013. The evaluation of plant diversity and sustainable development research in Daiyunshan National Nature Reserve. Wuyi Science Journal, 29(1): 6-15. [in Chinese])
尹峰, 朱玉雯. 2008. 我国森林资源质量的主要影响因素及其对策研究. 湖北林业科技, (2): 39-42.
(Yin F, Zhu Y W. 2008. Analysis on main influence factors and its countermeasures of forest resource quality in China. Hubei Forestry Science and Technology, (2): 39-42. [in Chinese])
赵广华, 田瑜, 唐志尧, 等.2013. 中国国家级陆地自然保护区分布及其与人类活动和自然环境的关系. 生物多样性, 21(6): 658-665.
(Zhao G H, Tian Y, Tang Z Y, et al. 2013. Distribution of terrestrial national nature reserves in relation to human activities and natural environments in China. Biodiversity Science, 21(6): 658-665. [in Chinese])
朱教君, 康宏樟, 胡理乐. 2005. 应用全天空照片估计林分透光孔隙度 (郁闭度). 生态学杂志,24(10): 1234-1240.
(Zhu J J, Kang H Z, Hu L L. 2005. Estimation on optical porosity or canopy closure for a forest stand with hemispherical images. Chinese Journal of Ecology, 24(10): 1234-1240. [in Chinese])
Ando A, Camm J, Polasky S, et al. 1998. Species distributions, land values, and efficient conservation. Science,279(5359): 2126-2128.
Beasley J E, Chu P C.1996. A genetic algorithm for the set covering problem. European Journal of Operational Research, 94(2): 392-404.
Camm J D, Polasky S, Solow A, et al. 1996. A note on optimal algorithms for reserve site selection. Biological Conservation, 78(3): 353-355.
Church R L, Stoms D M, Davis F W. 1996. Reserve selection as a maximal covering location problem. Biological conservation,76(2): 105-112.
Csuti B, Polasky S, Williams P H, et al. 1997. A comparison of reserve selection algorithms using data on terrestrial vertebrates in Oregon. Biological Conservation,80(1): 83-97.
Haight R G, Revelle C S, Snyder S A.2000. An integer optimization approach to a probabilistic reserve site selection problem. Operations Research, 48(5): 697-708.
Jafari N, Hearne J. 2013. A new method to solve the fully connected reserve network design problem. European Journal of Operational Research, 231(1): 202-209.
Margules C R, Nicholls A O, Pressey R L.1988. Selecting networks of reserves to maximise biological diversity. Biological conservation,43(1): 63-76.
Moilanen A. 2007. Landscape Zonation, benefit functions and target-based planning: unifying reserve selection strategies. Biological Conservation, 134(4):571-579.
Nicholls A O, Margules C R. 1993. An upgraded reserve selection algorithm. Biological Conservation, 64(2):165-169.
Önal H, Briers R A. 2005. Designing a conservation reserve network with minimal fragmentation: a linear integer programming approach. Environmental Modeling & Assessment,10(3): 193-202.
Pressey R L, Possingham H P, Margules C R. 1996. Optimality in reserve selection algorithms: when does it matter and how much?. Biological Conservation, 76(3): 259-267.
ReVelle C S, Williams J C, Boland J J. 2002. Counterpart models in facility location science and reserve selection science. Environmental Modeling & Assessment,7(2): 71-80.
Terborgh J, Winter B. 1983. A method for siting parks and reserves with special reference to Columbia and Ecuador. Biological Conservation,27(1): 45-58.
Underhill L G. 1994. Optimal and suboptimal reserve selection algorithms. Biological Conservation, 70(1): 85-87.
Watts M E, Ball I R, Stewart R S, et al. 2009. Marxan with Zones: Software for optimal conservation-based land- and sea-use zoning. Environmental Modelling & Software, 24(12):1513-1521.
Williams J C. 2002. A zero-one programming model for contiguous land acquisition. Geographical Analysis,34(4): 330-349.
Williams J C.2008. Optimal reserve site selection with distance requirements. Computers & Operations Research, 35(2): 488-498.

[1]	王卫, 杨俊杰, 罗晓莹, 周长江, 陈世发, 杨志军, 侯荣丰, 陈再雄, 李永生. 基于Maxent模型的丹霞山国家级自然保护区极小种群植物丹霞梧桐的潜在生境评价[J]. 林业科学, 2019, 55(8): 19-27.
[2]	贾荛祯, 王明, 王传华. 川金丝猴食源地衣长松萝生长、存活与生理学特征对模拟氮沉降的响应[J]. 林业科学, 2019, 55(7): 17-26.
[3]	刘洪霞, 管文轲, 扎依达·斯迪克, 张和钰, 吴天忠, 曹晓明, 张谱, 冯益明. 塔里木胡杨国家自然保护区湿地面积在生态输水工程前后的变化[J]. 林业科学, 2018, 54(9): 1-8.
[4]	王育鹏, 洪欣, 刘坤, 李建辉, 周守标, 张丁来, 陈文豪. 安徽牯牛降北坡种子植物区系特征及其多样性的海拔梯度变化[J]. 林业科学, 2018, 54(4): 165-173.
[5]	顾伟, 马玲, 孙虎, 王利东, 张子龙. 不同土壤环境下落叶松人工林昆虫群落结构及动态的差异[J]. 林业科学, 2017, 53(5): 97-106.
[6]	刘玉平, 刘贵峰, 达福白乙拉, 程伟燕, 陈志婧, 姜丽丽. 地形因子对大青沟自然保护区不同森林群落叶性状的影响[J]. 林业科学, 2017, 53(3): 154-162.
[7]	冯广, 艾训儒, 姚兰, 刘峻城, 黄永涛, 林勇. 鄂西南亚热带常绿落叶阔叶混交林的自然恢复动态及其影响因素[J]. 林业科学, 2016, 52(8): 1-9.
[8]	马玲, 问荣荣, 焦玥, 刘雪英, 张静, 刘哲强, 顾伟, 满子源, 张曼胤. 小兴安岭不同林型的昆虫多样性[J]. 林业科学, 2016, 52(2): 82-90.
[9]	袁维, 张杰, 周波, 王爱红, 于雷, 马珂馨. 基于层次分析法的朗乡自然保护区露营旅游环境适宜度[J]. 林业科学, 2015, 51(5): 21-27.
[10]	龙成, 杨小波, 龙文兴, 李东海. 铜鼓岭热带常绿季雨矮林5种蒲桃属植物的种群结构及空间格局[J]. 林业科学, 2015, 51(2): 18-27.
[11]	李广良, 李迪强, 薛亚东, 王秀磊, 杨敬元, 余辉亮. 利用红外相机研究神农架自然保护区野生动物分布规律[J]. 林业科学, 2014, 50(9): 97-104.
[12]	李林峰, 张金屯, 周兰, 邵丹. 自组织特征映射网络在芦芽山自然保护区青杄林分类和排序中的应用[J]. 林业科学, 2014, 50(5): 1-7.
[13]	丛静;尹华群;卢慧;宿秀江;杨敬元;李迪强;张于光. 神农架保护区典型植被的物种多样性和环境解释[J]. , 2013, 49(5): 30-35.
[14]	齐磊;胡德夫;丁长青;隋金玲;张东;杨亮;吴记贵;蒋万杰. 北京松山国家级自然保护区鼠类群落多样性与结构变动分析[J]. 林业科学, 2012, 48(9): 181-185.
[15]	朱学灵;刘晓静;崔向慧;吴明作;叶永忠. 宝天曼自然保护区栎类林群落不同火烧演替序列物种多样性特征[J]. 林业科学, 2012, 48(8): 31-38.