The influence of spatial errors in species occurrence data used in distribution models
about
Combining climatic projections and dispersal ability: a method for estimating the responses of sandfly vector species to climate changeAn Ecological Paradox: The African Wild Dog (Lycaon Pictus) Is Not Attracted to Water Points When Water Is Scarce in Hwange National Park, ZimbabweIs the climate right for pleistocene rewilding? Using species distribution models to extrapolate climatic suitability for mammals across continentsAre we filling the data void? An assessment of the amount and extent of plant collection records and census data available for tropical South AmericaAssessing historical fish community composition using surveys, historical collection data, and species distribution modelsComparing Distribution of Harbour Porpoises (Phocoena phocoena) Derived from Satellite Telemetry and Passive Acoustic Monitoring.Global Climate Change Effects on Venezuela's Vulnerability to Chagas Disease is Linked to the Geographic Distribution of Five Triatomine Species.Use of Anecdotal Occurrence Data in Species Distribution Models: An Example Based on the White-Nosed Coati (Nasua narica) in the American Southwest.Ecological niche models of invasive seaweeds.Will climate change increase the risk of plant invasions into mountains?Bias correction in species distribution models: pooling survey and collection data for multiple speciesA gap analysis methodology for collecting crop genepools: a case study with phaseolus beansBird and mammal species composition in distinct geographic regions and their relationships with environmental factors across multiple spatial scales.The importance of data quality for generating reliable distribution models for rare, elusive, and cryptic speciesTracking a medically important spider: climate change, ecological niche modeling, and the brown recluse (Loxosceles reclusa).Protecting persistent dynamic oceanographic features: transboundary conservation efforts are needed for the critically endangered Balearic shearwater.Historical distribution of Sundaland's Dipterocarp rainforests at Quaternary glacial maxima.Combined use of systematic conservation planning, species distribution modelling, and connectivity analysis reveals severe conservation gaps in a megadiverse country (Peru).Applying various algorithms for species distribution modelling.Habitat-forming bryozoans in New Zealand: their known and predicted distribution in relation to broad-scale environmental variables and fishing effortClimatic niche conservatism and biogeographical non-equilibrium in Eschscholzia californica (Papaveraceae), an invasive plant in the Chilean Mediterranean regionThe distributional ecology of the maned sloth: environmental influences on its distribution and gaps in knowledge.Modelling Niche Differentiation of Co-Existing, Elusive and Morphologically Similar Species: A Case Study of Four Macaque Species in Nakai-Nam Theun National Protected Area, LaosUsing species distribution modeling to delineate the botanical richness patterns and phytogeographical regions of China.Improved Predictions of the Geographic Distribution of Invasive Plants Using Climatic Niche Models.Ancient human disturbances may be skewing our understanding of Amazonian forestsDelimiting priority areas for the conservation of endemic and threatened Neotropical birds using a niche-based gap analysis.Mapping monkeypox transmission risk through time and space in the Congo Basin.Quantifying the degree of bias from using county-scale data in species distribution modeling: Can increasing sample size or using county-averaged environmental data reduce distributional overprediction?Lazarus ecology: Recovering the distribution and migratory patterns of the extinct Carolina parakeet.Protected areas offer refuge from invasive species spreading under climate change.Identification of ecogeographical gaps in the Spanish Aegilops collections with potential tolerance to drought and salinityA synthesis of transplant experiments and ecological niche models suggests that range limits are often niche limits.Enhancing species distribution modeling by characterizing predator-prey interactions.Description of Events Where African Buffaloes (Syncerus caffer) Strayed from the Endemic Foot-and-Mouth Disease Zone in South Africa, 1998-2008.Squares of different sizes: effect of geographical projection on model parameter estimates in species distribution modeling.Incorporating abundance information and guiding variable selection for climate-based ensemble forecasting of species' distributional shiftsParasite biodiversity faces extinction and redistribution in a changing climate.Southern Ocean Echinoids database - An updated version of Antarctic, Sub-Antarctic and cold temperate echinoid database.The interplay of various sources of noise on reliability of species distribution models hinges on ecological specialisation.
P2860
Q24290796-1BB57807-E403-40CB-908D-4FBDCA0BEB8FQ28601907-34284387-8BFC-4F33-B62F-51F80FD06459Q28749208-8AEFBF81-6FAE-4E72-A44A-09B0C477E038Q30000343-C44AAA8D-FC9D-453B-90E3-20B60E482CF4Q30000942-61901BF2-0041-4A30-AB81-38F8F0F61984Q30376932-E14DF0E2-27F7-4966-958F-EF3D27B30A94Q30991388-CF10F9DC-B5A2-4179-881B-154CC5DD50BAQ31009039-A424A945-F8B0-460F-AA8D-2FFEBDC9976DQ31059639-7436B83C-EA90-4CE1-AD92-D3E1CEAADFA3Q31099315-2C5D6033-CA7C-43B0-A5D8-53B0AC68BDC7Q31142177-264B341A-552F-416B-864C-7D96F135931EQ33728126-7051EA77-C383-4CD9-9CA2-62A7754C3E64Q33777913-137F042A-668A-43B5-BC41-CA268CEA25F2Q33825259-738FCEB2-A537-4E5D-92EC-3101A6FFA3E1Q33862788-FCCC8609-45A3-4CFF-B557-643FE8BE25B8Q34270631-7249519B-10BC-4AA9-BC6A-09E23C72BA4FQ34447210-BC50A841-E35B-4700-AE9E-C5BEF6945505Q34640439-36B11870-15AC-4F76-BEC4-0DA5A4EA5B49Q34754078-BE8F8E05-D2BC-49A1-954F-8877CE9B3F0FQ35005417-EA59E390-D6F6-4682-832F-1F16E3B917C9Q35227982-073FDF13-5FA2-4731-A129-FE7253CA100AQ35358793-E1380769-B6FF-4B38-84D8-F2E58A66492BQ35830372-DB9FD515-412E-4B4A-B4CD-5F9DCAE54EB7Q35940382-24339073-8322-4867-9DBF-F79246C86048Q36022364-487FF5C1-7B60-415E-9006-F54DAA5E66DDQ36239052-28A19C5E-578B-4B61-BA09-EBE1507607FCQ36277069-67152F15-A662-4444-9313-F47765B337C4Q37149726-3AF98FD9-EA7A-436D-AF6F-89814AE9BB4CQ38368206-E25CECC0-C6DF-4728-B239-E0ECC1AC5E8BQ38368562-894E0E3D-E82F-4C0A-98DC-98FD4F449053Q38649513-95B66B83-8EDB-4F2E-B126-3BEB84C3A6BBQ38650315-0BA89C15-0A2A-4558-81AC-F1363ECD9A99Q38816738-63AD7109-76D7-4A73-A678-39D96BF26011Q39126454-3C494AF9-29E0-4FF3-9D51-4009B8E8E7CCQ39551925-73F036F9-FDA4-4352-B39D-A0114794382FQ40060688-26AE6C50-1921-4A4E-9D55-AE05B0F59B12Q41493428-FF7B1C5B-8AB5-4D4D-94A7-3FE761DA3D0CQ41633545-5A5663D2-6999-4BD5-BD96-F68E17E5E5D3Q42254476-005A222D-844F-4307-A165-7CE161573E49Q46262748-AB08D74F-1736-4BDD-BF02-FE281ACB6B20
P2860
The influence of spatial errors in species occurrence data used in distribution models
description
article
@en
im August 2007 veröffentlichter wissenschaftlicher Artikel
@de
wetenschappelijk artikel
@nl
наукова стаття, опублікована в серпні 2007
@uk
name
The influence of spatial errors in species occurrence data used in distribution models
@en
The influence of spatial errors in species occurrence data used in distribution models
@nl
type
label
The influence of spatial errors in species occurrence data used in distribution models
@en
The influence of spatial errors in species occurrence data used in distribution models
@nl
prefLabel
The influence of spatial errors in species occurrence data used in distribution models
@en
The influence of spatial errors in species occurrence data used in distribution models
@nl
P50
P1476
The influence of spatial errors in species occurrence data used in distribution models
@en
P2093
A Townsend Peterson
P304
P356
10.1111/J.1365-2664.2007.01408.X
P577
2007-08-03T00:00:00Z