about
Extinction risk and conservation of the world's sharks and raysMapping global diversity patterns for migratory birdsPrey depletion as a threat to the world's large carnivoresNext-generation Digital EarthComplete, accurate, mammalian phylogenies aid conservation planning, but not muchProjected changes in prevailing winds for transatlantic migratory birds under global warming.Brood parasitism and the evolution of cooperative breeding in birds.Spatially explicit trends in the global conservation status of vertebrates.Fruiting Season Length Restricts Global Distribution of Female-Only Parental Care in Frugivorous Passerine BirdsDevelopment of soil compaction analysis software (SCAN) integrating a low cost GPS receiver and compactometer.Horizontal Positional Accuracy of Google Earth's High-Resolution Imagery Archive.Historical biome distribution and recent human disturbance shape the diversity of arbuscular mycorrhizal fungi.Population-level scaling of avian migration speed with body size and migration distance for powered fliers.Global aerial flyways allow efficient travelling.Convergence of broad-scale migration strategies in terrestrial birds.Citizen-science data provides new insight into annual and seasonal variation in migration patternsHexagonal connectivity maps for Digital EarthConservation opportunities across the world's anthromesMechanisms driving an unusual latitudinal diversity gradient for grassesGlobal Biodiversity Conservation and the Alleviation of PovertyThe Potential, Realised and Essential Ecosystem Service Benefits of Biodiversity ConservationThe role of atmospheric conditions in the seasonal dynamics of North American migration flywaysThe implications of mid-latitude climate extremes for North American migratory bird populationsTowards a global oil palm sample database: design and implicationsExploring the potential role of feature selection in global land-cover mappingAn SDOG-based intrinsic method for three-dimensional modelling of large-scale spatial objectsThe future of Digital Earth
P2860
Q21128792-2EA44881-0EAC-4AFD-9DB5-140288ED721AQ21559576-C12AD044-8313-45B9-AAAC-26F2723D4793Q28595817-91F20628-6008-4FC0-AE11-406AAF87F242Q28727138-6838D50A-A7EB-4B46-B238-A2E5E33A5D01Q28742374-69D80E7E-DF55-476D-B5CC-9F19DD7243F4Q31148792-0A7032F1-7394-4AC8-AD00-06553F4EF828Q34393270-EEBF07C6-FED4-4251-BB1C-EDE514DC2B1AQ34449650-3B32F419-E813-48A7-B9B0-03D8FB0B8C1FQ36009551-8D48DC2D-3215-4B73-B24E-29C42FC5C4C1Q36036875-A105C9A8-CD2C-44FC-B852-040E18C97F27Q36200848-7F1C60A5-0E36-41E6-AFA4-00A5C9DF877FQ38369122-F1163418-401C-4D9B-BA04-B510F594B585Q38564994-DD671F71-E444-4346-9008-CB15AA1F1C97Q44864370-F080A88C-F504-4409-989B-AD2B8A6575CEQ51299026-4E37D206-6C36-48AB-AA9E-91C4A08C8F13Q55451238-E8DFF644-3AFF-430E-B5C3-4C78F86D07ADQ55981477-D963A8C8-0A97-416D-837B-5EDB7D308624Q56950318-AE6D3576-625B-4D72-8BFA-AE14288BF2A6Q56984255-CF92FA07-E63B-403F-8D09-259EB7414F29Q57016384-C175D750-999E-408F-9FEF-B5AE7CC7641BQ57016400-30B9DD52-3A46-4398-A292-A0985ABE7C33Q57273013-C6ECE6A3-F682-4754-982D-CC7911C79A98Q57562624-C6EF2BB5-0908-459D-9D25-282C3835569EQ58068482-3E4EDDD4-1F1B-4544-9532-C03868155D19Q58068505-A323D213-68D8-4AF6-A0C1-3093D15719DEQ58123461-E75F7778-C1D2-480F-ACC6-5540B4CD2A19Q58186830-3778763A-8FD3-4CED-9F62-EDFD7BDB659F
P2860
description
wetenschappelijk artikel
@nl
наукова стаття, опублікована в січні 2003
@uk
name
Geodesic Discrete Global Grid Systems
@en
Geodesic Discrete Global Grid Systems
@nl
type
label
Geodesic Discrete Global Grid Systems
@en
Geodesic Discrete Global Grid Systems
@nl
prefLabel
Geodesic Discrete Global Grid Systems
@en
Geodesic Discrete Global Grid Systems
@nl
P2093
P1476
Geodesic Discrete Global Grid Systems
@en
P2093
A. Jon Kimerling
Denis White
Kevin Sahr
P304
P356
10.1559/152304003100011090
P577
2003-01-01T00:00:00Z