Mathematical Methods for Identifying Representative Reserve Networks

• Andelman SJ, Meir E (2000) Breadth is better than depth: biodiversity data requirements for adequate reserve networks. Conservation Biology (in press)

  Google Scholar 

• Andelman SJ, Fagan W, Davis F, Pressey RL (2000) Tools for conservation planning in an uncertain world. BioScience (in press)

  Google Scholar 

• Bailey RG (1994) Ecoregions of the US. USDA Forest Service, Washington, DC

  Google Scholar 

• Ball IR, Smith A, Day JR, Pressey RL, Possingham H (in press) Comparison of mathematical algorithms for the design of a reserve system for nature conservation: an application of genetic algorithms and simulated annealing. Journal of Environmental Management

  Google Scholar 

• Church RL, Stoms DM, Davis FW (1996) Reserve selection as a maximal covering location problem. Biological Conservation 76:105–112

  Article  Google Scholar 

• Cocklin C (1989a) Mathematical programming and resources planning I: the limitations of traditional optimization. Journal of Environmental Management 28:127–141

  Google Scholar 

• Cocklin C (1989b) Mathematical programming and resources planning II: new developments in methodology. Journal of Environmental Management 28:143–156

  Google Scholar 

• 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 49:113–130

  Article  Google Scholar 

• Davis FW, Stoms DM, Andelman SJ (2000) Systematic reserve selection in the USA: an example from the Columbia Plateau ecoregion. Parks (in press)

  Google Scholar 

• Fagan WF, Cantrell RS, Cosner C (1999) How habitat edges change species interactions. American Naturalist 153:165–182

  Article  Google Scholar 

• Garey MR, Johnson DS (1979) Computers and intractability: a guide to the theory of NP-completeness. WH Freeman and Company, San Francisco, CA

  Google Scholar 

• Golden B, Skiscim C (1986) Using simulated-annealing to solve routing and location problems. Naval Research Logistics Quarterly 33:261–279

  Google Scholar 

• Kirkpatrick JB (1983) An iterative method for establishing priorities for selection of nature reserves: an example from Tasmania. Biological Conservation 25:127–134

  Article  Google Scholar 

• Kirkpatrick S, Gelatt CD Jr, Vecchi MP (1983) Optimization by simulated annealing. Science 220:671–680

  Google Scholar 

• MacArthur RH, Wilson EO (1963) An equilibrium theory of insular zoogeography. Evolution 17:373–387

  Article  Google Scholar 

• Margules CR, Nicholls AO, Pressey RL (1988) Selecting networks to maximise biological diversity. Biological Conservation 43:63–76

  Article  Google Scholar 

• Margules CR, Nicholls AO, Usher MB (1994) Apparent species turnover probability of extinction and the selection of nature reserves: a case study of the Ingleborough limestone pavements. Conservation Biology 8:398–409

  Article  Google Scholar 

• McNeely JA, Miller KR, Reid WV, Mittermeier RA, Werner TB (1990) Conserving the world’s biodiversity. IUCN, Gland, Switzerland

  Google Scholar 

• Metropolis NA, Rosenbluth M, Rosenbluth A, Teller E (1953) Equation of state calculations by fast computing machines. Journal of Chemical Physics 21:1087–1092

  Article  CAS  Google Scholar 

• Morton SR, Stafford Smith DM, Friedel MH, Griffen GF, Pickup G (1995) The stewardship of arid Australia: ecology and landscape management. Journal of Environmental Management 43:195–217

  Article  Google Scholar 

• Murray AT, Church RL (1996) Applying simulated annealing to location-planning models. Journal of Heuristics 2:31–53

  Article  Google Scholar 

• Nicholls AO, Margules CR (1993) An upgraded reserve selection algorithm. Biological Conservation 64:165–169

  Article  Google Scholar 

• Possingham HP, Day JR, Goldfinch M, Salzborn F (1993) The mathematics of designing a network of protected areas for conservation. In: Sutton DJ, Pearce CEM, Cousins EA (eds) Decision sciences: tools for today. Proceedings of 12th National ASOR Conference, ASOR, Adelaide, Australia, pp 536–545

  Google Scholar 

• Pressey RL, Humphries CJ, Margules CR, Vane-Wright RI, Williams PH (1993) Beyond opportunism: key principles for systematic reserve selection. TREE 8:124–128

  Google Scholar 

• Pressey RL, Possingham HP, Margules CR (1996) Optimality in reserve selection algorithms: when does it matter and how much? Biological Conservation 76:259–267

  Article  Google Scholar 

• Pressey RL, Possingham PH, Day RJ (1997) Effectiveness of alternative heuristic algorithms for identifying indicative minimum requirements for conservation reserves. Biological Conservation 80:207–219

  Article  Google Scholar 

• Rebelo AG, Siegfried WR (1992) Where should nature reserves be located in the cape floristic region South Africa? Models for the spatial configuration of a reserve network aimed at maximizing the protection of floral diversity. Conservation Biology 6:243–252

  Article  Google Scholar 

• Simberloff D (1998) Flagships umbrellas and keystones: is single species management passé in the landscape era? Biological Conservation 83:247–257

  Article  Google Scholar 

• Soulé ME (1991) Conservation: tactics for a constant crisis. Science 253:744–750

  Google Scholar 

• Underhill LG (1994) Optimal and suboptimal reserve selection algorithms. Biological Conservation 70:85–87

  Article  Google Scholar 

• Willis CK, Lombard AT, Cowling RM, Heydenrych BJ, Burgers CJ (1996) Reserve systems for limestone endemic flora of the cape lowland fynbos: iterative versus linear programming. Biological Conservation 77:53–62

  Article  Google Scholar 

Download references