Abstract
The loss of connectivity of natural areas is a major threat for wildlife dispersal and survival and for the conservation of biodiversity in general. Thus, there is an increasing interest in considering connectivity in landscape planning and habitat conservation. In this context, graph structures have been shown to be a powerful and effective way of both representing the landscape pattern as a network and performing complex analysis regarding landscape connectivity. Many indices have been used for connectivity analyses so far but comparatively very little efforts have been made to understand their behaviour and sensitivity to spatial changes, which seriously undermines their adequate interpretation and usefulness. We systematically compare a set of ten graph-based connectivity indices, evaluating their reaction to different types of change that can occur in the landscape (habitat patches loss, corridors loss, etc.) and their effectiveness for identifying which landscape elements are more critical for habitat conservation. Many of the available indices were found to present serious limitations that make them inadequate as a basis for conservation planning. We present a new index (IIC) that achieves all the properties of an ideal index according to our analysis. We suggest that the connectivity problem should be considered within the wider concept of habitat availability, which considers a habitat patch itself as a space where connectivity exists, integrating habitat amount and connectivity between habitat patches in a single measure.
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References
A.G. Bunn D.L. Urban T.H. Keitt (2000) ArticleTitleLandscape connectivity: a conservation application of graph theory J. Environ. Manag. 59 265–278 Occurrence Handle10.1006/jema.2000.0373
J.M. Calabrese W.F. Fagan (2004) ArticleTitleA comparison-shopper’s guide to connectivity metrics Front. Ecol. Environ. 2 529–536
C. Grashof-Bokdam (1997) ArticleTitleForest species in an agricultural landscape in the Netherlands:effects of habitat fragmentation J. Veg. Sci. 8 21–28 Occurrence Handle10.2307/3237238
J.A.G. Jaeger (2000) ArticleTitleLandscape division, splitting index, and effective mesh size: new measures of landscape fragmentation Landsc. Ecol. 15 115–130 Occurrence Handle10.1023/A:1008129329289
A.R. Johnson J.A. Wiens B.T. Milne T.O. Crist (1992) ArticleTitleAnimal movements and population-dynamics in heterogeneous landscapes Landsc. Ecol. 7 63–75
F. Jordan A. Baldi K.M. Orci I. Racz Z. Varga (2003) ArticleTitleCharacterizing the importance of habitat patches and corridors in maintaining the landscape connectivity of a Pholidoptera transsylvanica (Orthoptera) metapopulation Landsc. Ecol. 18 83–92 Occurrence Handle10.1023/A:1022958003528
T.H. Keitt D.L. Urban B.T. Milne (1997) ArticleTitleDetecting critical scales in fragmented landscapes Conserv. Ecol. [online] 1 4
H.B. Li J.G. Wu (2004) ArticleTitleUse and misuse of landscape indices Landsc. Ecol. 19 389–399 Occurrence Handle10.1023/B:LAND.0000030441.15628.d6
A. Moilanen M. Nieminen (2002) ArticleTitleSimple connectivity measures in spatial ecology Ecology 83 1131–1145
H.R. Pulliam (1988) ArticleTitleSources, sinks and population regulation Am. Nat. 132 652–661 Occurrence Handle10.1086/284880
C. Ricotta A. Stanisci G.C. Avena C. Blasi (2000) ArticleTitleQuantifying the network connectivity of landscape mosaics: a graph-theoretical approach Commun. Ecol. 1 89–94 Occurrence Handle10.1556/ComEc.1.2000.1.12
P. Schippers J. Verboom J.P. Knaapen R.C. van Apeldoorn (1996) ArticleTitleDispersal and habitat connectivity in complex heterogeneous landscapes: an analysis with a GIS-based random walk model Ecography 19 97–106 Occurrence Handle10.1111/j.1600-0587.1996.tb00160.x
N.H. Schumaker (1996) ArticleTitleUsing landscape indices to predict habitat connectivity Ecology 77 1210–1225 Occurrence Handle10.2307/2265590
V.M. Stevens E. Polus R.A. Wesselingh N. Schtickzelle M. Baguette (2004) ArticleTitleQuantifying functional connectivity: experimental evidence for patch-specific resistance in the Natterjack toad (Bufo calamita) Landsc. Ecol. 19 829–842 Occurrence Handle10.1007/s10980-004-0166-6
P.D. Taylor L. Fahrig K. Henein G. Merriam (1993) ArticleTitleConnectivity is a vital element of landscape structure Oikos 3 571–573
L. Tischendorf L. Fahrig (2000a) ArticleTitleHow should we measure landscape connectivity? Landsc. Ecol. 15 633–641 Occurrence Handle10.1023/A:1008177324187
L. Tischendorf L. Fahring (2000b) ArticleTitleOn the usage and measurement of landscape connectivity Oikos 90 7–19 Occurrence Handle10.1034/j.1600-0706.2000.900102.x
D. Urban T. Keitt (2001) ArticleTitleLandscape connectivity: a graph-theoretic perspective Ecology 82 1205–1218 Occurrence Handle10.2307/2679983
G. Verbeylen L. Bruyn ParticleDe F. Adriaensen E. Matthysen (2003) ArticleTitleDoes matrix resistance influence Red squirrel (Sciurus vulgaris L. 1758) distribution in an urban landscape? Landsc. Ecol. 18 791–805 Occurrence Handle10.1023/B:LAND.0000014492.50765.05
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Pascual-Hortal, L., Saura, S. Comparison and development of new graph-based landscape connectivity indices: towards the priorization of habitat patches and corridors for conservation. Landscape Ecol 21, 959–967 (2006). https://doi.org/10.1007/s10980-006-0013-z
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DOI: https://doi.org/10.1007/s10980-006-0013-z