A model for designing nature reserves with minimal fragmentation using a primal-dual graph approach

doi:10.3724/SP.J.1003.2011.10020

Abstract

Abstract:

Habitat fragmentation is one of the most important causes of biodiversity loss. In order to maximize a nature reserve’s effectiveness it is important to minimize habitat fragmentation during the design phase. However, due to economic or geographic constraints, it is often infeasible to acquire a large area of contiguous land for a reserve; designing a nature reserve consisting of several smaller components is often a more realistic choice. Selecting these smaller components with which to assemble a reserve with minimal fragmentation then becomes an important way to reduce fragmentation. However, reserve site selection models which incorporate spatial attributes may encounter computational difficulties. Williams (2002) presented a linear integer programming model based on primal and dual graph concepts to select contiguous sites. This paper modified this model to design a nature reserve which can protect a set of target species while incurring minimal fragmentation among selected sites. The modified model defines two variables for each site, and the difference in the value of these two variables represents the extent of fragmentation. Computational performance tests showed that the model can solve a minimal fragmentation reserve design problem involving 100 potential sites in a reasonable period of time. As an empirical application, the model was employed to design reserve networks for the endangered and threatened bird species of Illinois, USA. Several reserve networks with minimal fragmentation under different scenarios were designed. The computational efficiency of linear integer programming models needs more improvement for designing large-size optimal nature reserves. The practical use of these models requires complete and accurate data sets including species distribution, cost of site selection, etc.

Key words: nature reserve, spatial attribute, optimization, graph theory, endangered/threatened birds

Yicheng Wang. A model for designing nature reserves with minimal fragmentation using a primal-dual graph approach[J]. Biodiv Sci, 2011, 19(4): 404-413.

Add to citation manager EndNote|Ris|BibTeX

URL: https://www.biodiversity-science.net/EN/10.3724/SP.J.1003.2011.10020

https://www.biodiversity-science.net/EN/Y2011/V19/I4/404

Figures/Tables 13

Fig. 1 Representation of a nature reserve based on graph theory (comprised of 15 sites)

Fig. 2 Primal and dual graphs consisting of 9 primal nodes and 5 dual nodes, respectively, and their intersecting relation

Fig. 3 Interwoven structure of primal and dual trees (primal tree consists of black dots and bold lines, and dual tree blank circles and thin lines)

Fig. 4 A reserve with fragmentation. Nodes 1, 2, 4 and 5 consist of the reserve. Node 3 is fragmentation.

Table 1 Computational results of the minimal fragmentation model (No. of sites = 100, No. of species = 30)

α	SCP解 SCP solution	r	模型大小 Model size^a	目标值 Objective value^b	时间(秒) Time (s)^c	迭代 Iterations^d	节点 Nodes^e
0.8	2	3		0.0	3.9	11,084	61
0.7	2	3		0.1	10.0	34,150	238
0.6	3	3	952	1.6	36.2	183,910	1,810
0.5	3	4	1,241	0.9	36.4	170,883	1,313
0.4	4	6	200	0.1	54.6	245,866	1,308
0.3	5	7		1.0	98.1	480,861	3,207
0.2	7	9		2.8	194.0	1,056,830	8,873

Fig. 5 Selected solutions of the model. Dark grey cells consist of the reserve, shallow grey cells are fragmentation. α, Ratio of species that can coexist in any potential site to total number of species; r, Maximal number of selected sites.

Fig. 6 Bird distribution (only occurred in grey cells)

Fig. 7 Solution of set covering problem, no spatial constraint. ks = 1. Cost is $12,175. Fragmentation is 3.

Fig. 8 Solution of the model. ks = 1. r = $12,175. Fragmentation is the 2 cells marked with lines.

Fig. 9 Solution of the model. ks = 1. r =$(12,175$\times $1.5). Fragmentation is 0.

Fig. 10 Solution of set covering problem, no spatial constraint. ks = 2. Cost is $24,350. Fragmentation is 3.

Fig. 11 Solution of the model. ks = 2. r = $24,350. Fragmentation is the cell marked with lines.

Fig. 12 Solution of the model. ks = 2. r = $(24,350$\times $1.5). Fragmentation is 0.

References 31

[1]	Ando A, Camm JD, Polasky S, Solow A (1998) Species distribution, land values and efficient conservation. Science, 279, 2126-2128.
[2]	Bolger DT, Scott TA, Rotenberry JT (2001) Use of corridor-like structures by bird and small mammal species. Biological Conservation, 102, 213-224.
[3]	Brooke A, Kendrick D, Meeraus A, Raman R (1998) GAMS― A User’s Guide. GAMS Development Corporation, Washington, DC.
[4]	Cabeza M, Araújo MB, Wilson RJ, Thomas CD, Cowley MJR, Moilanen A (2004) Combining probabilities of occurrence with spatial reserve design. Journal of Applied Ecology, 41, 252-262.
[5]	Church RL, ReVelle C (1974) The maximal covering location problem. Papers of the Regional Science Association, 32, 101-118.
[6]	Church RL, Stoms DM, Davis FW (1996) Reserve selection as a maximal covering location problem. Biological Conservation, 76, 105-112.
[7]	Cocks KD, Baird IA (1989) Using mathematical programming to address the multiple reserve selection problem: an example from the Eyre Peninsula, South Australia. Biological Conservation, 78, 113-130.
[8]	Costello C, Polasky S (2004) Dynamic reserve site selection. Resource and Energy Economics, 26, 157-174.
[9]	Diestel R (2005) Graph Theory, 3rd edn. Springer, Berlin. URL PMID
[10]	Fischer DT, Church RL (2003) Clustering and compactness in reserve site selection: an extension of the biodiversity management area selection model. Forest Science, 49, 555-565.
[11]	Fu W (富伟), Liu SL (刘世梁), Cui BS (崔保山), Zhang ZL (张兆苓) (2009) A review on ecological connectivity in landscape ecology. Acta Ecologica Sinica (生态学报), 29, 6174-6182. (in Chinese with English abstract)
[12]	Gao ZX (高增祥), Chen S (陈尚), Li DM (李典谟), Xu RM (徐汝梅) (2007) Origin and essence of island biogeography and metapopulation theory. Acta Ecologica Sinica (生态学报), 27, 304-313. (in Chinese with English abstract)
[13]	Haight RG, ReVelle CS, Snyder SA (2000) An integer optimization approach to a probabilistic reserve site selection problem. Operations Research, 48, 697-708.
[14]	Haight RG, Travis LE (2008) Reserve design to maximize species persistence. Environmental Modeling and Assessment, 13, 243-253.
[15]	Hanski I (1998) Metapopulation dynamics. Nature, 396, 41-49.
[16]	Harrison P, Spring D, MacKenzie M, Nally RM (2008) Dynamic reserve design with the union-find algorithm. Ecological Modelling, 215, 369-376.
[17]	Hodgson JA, Moilanen A, Wintle BA, Thomas CD (2011) Habitat area, quality and connectivity: striking the balance for efficient conservation. Journal of Applied Ecology, 48, 148-152.
[18]	Li XW (李晓文), Hu YM (胡远满), Xiao DN (肖笃宁) (1999) Landscape ecology and biodiversity conservation. Acta Ecologica Sinica (生态学报), 19, 399-407. (in Chinese with English abstract)
[19]	Nalle DJ, Arthur JL, Sessions J (2002) Designing compact and contiguous reserve networks with a hybrid heuristic algorithm. Forest Science, 48, 59-68.
[20]	Önal H (2003) First-best, second-best, and heuristic solutions in conservation reserve selection. Biological Conservation, 115, 55-62.
[21]	Önal H, Briers R (2006) Optimum selection of a connected conservation reserve network. Operations Research, 54, 379-388.
[22]	Önal H, Wang Y (2008) A graph theory approach for designing conservation reserve networks with minimal fragmentation. Networks, 52, 142-152.
[23]	Possingham H, Ball I, Andelman S (2000) Mathematical methods for identifying representative reserve networks. In: Quantitative Methods for Conservation Biology (eds Ferson S, Burgman M), pp. 291-305. Springer, New York.
[24]	Tang ZY (唐志尧), Qiao XJ (乔秀娟), Fang JY (方精云) (2009) Species-area relationship in biological communities. Biodiversity Science (生物多样性), 17, 549-559. (in Chinese with English abstract)
[25]	Toregas C, Swain R, ReVelle C, Bergman L (1971) The location of emergency service facilities. Operations Research, 19, 1363-1373.
[26]	Underhill LG (1994) Optimal and suboptimal reserve selection algorithms. Biological Conservation, 70, 85-87.
[27]	Vanegas P, Cattrysse D, Van Orshoven J (2010) Compactness in spatial decision support: a literature review. Lecture Notes in Computer Science, 6016, 414-429.
[28]	Williams JC (2002) A zero-one programming model for contiguous land acquisition. Geographical Analysis, 34, 330-349.
[29]	Williams JC, ReVelle CS, Levin SA (2004) Using mathematical optimization models to design nature reserves. Frontiers in Ecology and the Environment, 2, 98-105.
[30]	Williams JC, ReVelle CS, Levin SA (2005) Spatial attributes and reserve design models: a review. Environmental Modeling and Assessment, 10, 163-181.
[31]	Xu HG (徐海根), Wang LL (王连龙), Bao HS (包浩生) (2003) Designing of nature reserve network: a case study of the red-crowned crane nature reserve. Rural Eco-Environment (农村生态环境), 19(4), 5-9. (in Chinese with English abstract)