Mixed conditional logistic regression for habitat selection studies.
about
Data-driven discovery of the spatial scales of habitat choice by elephantsIdentifying and prioritizing greater sage-grouse nesting and brood-rearing habitat for conservation in human-modified landscapesUniting statistical and individual-based approaches for animal movement modellingApplications of step-selection functions in ecology and conservation.Disentangling woodland caribou movements in response to clearcuts and roads across temporal scales.A flexible approach for assessing functional landscape connectivity, with application to greater sage-grouse (Centrocercus urophasianus)Equivalence between Step Selection Functions and Biased Correlated Random Walks for Statistical Inference on Animal Movement.Tropical Forest Fragmentation Limits Movements, but Not Occurrence of a Generalist Pollinator Species.Robust Inference from Conditional Logistic Regression Applied to Movement and Habitat Selection Analysis.Quantifying spatial habitat loss from hydrocarbon development through assessing habitat selection patterns of mule deer.Relative Selection Strength: Quantifying effect size in habitat- and step-selection inferenceBison distribution under conflicting foraging strategies: site fidelity vs. energy maximization.The role of conservative versus innovative nesting behavior on the 25-year population expansion of an avian predator.Common Starlings (Sturnus vulgaris) increasingly select for grazed areas with increasing distance-to-nest.Generalized functional responses for species distributions.Practical guidance on characterizing availability in resource selection functions under a use-availability design.Not accounting for interindividual variability can mask habitat selection patterns: a case study on black bears.Influence of seasonality and gestation on habitat selection by northern Mexican gartersnakes (Thamnophis eques megalops).Movement reveals scale dependence in habitat selection of a large ungulate.Natural regeneration on seismic lines influences movement behaviour of wolves and grizzly bears.Raptor migration in an oceanic flyway: wind and geography shape the migratory route of grey-faced buzzards in East Asia.Habitat manipulation influences northern bobwhite resource selection on a reclaimed surface mineAntipredator responses of koomal (Trichosurus vulpecula hypoleucus) against introduced and native predatorsAt what spatial scales does resource selection vary? A case study of koalas in a semi-arid regionAssessing landscape functional connectivity in a forest carnivore using path selection functionsTopographic microclimates drive microhabitat associations at the range margin of a butterflyFunctional connectivity experiments reflect routine movement behavior of a tropical hummingbird speciesHunting exacerbates the response to human disturbance in large herbivores while migrating through a road networkIntegrated step selection analysis: bridging the gap between resource selection and animal movementHabitat selection by a large herbivore at multiple spatial and temporal scales is primarily governed by food resources
P2860
Q28654228-52C60F31-48D6-4A0C-A29B-1B0AD7CD5DA2Q28743896-609B5C07-740A-4C9C-981F-37DC8E9EBDE0Q33825503-A1A48968-44E5-4662-BAFB-77297CB09E92Q34711208-38DEA66D-BD6D-4A57-926C-B97C2AA16CA4Q35040649-26B6CDFB-09BD-4790-9AB2-EDB8FD9064C2Q35070132-5CEFA702-DB5D-4ED9-AE19-9277658D4B1BQ35515327-63CDFC4B-A9E9-4981-AF9F-BDCDCB6B24E3Q36219952-FF3E5DD6-3F60-45A2-9235-3EB44CA15EA7Q36248023-C3E565D8-CCF7-44CF-A21F-677F93724520Q38387695-5EFACF39-E890-4A14-9F4E-201018FB0420Q38645440-64AB09AB-B660-4116-AD8F-2278C8397EA1Q38963090-239DB63B-C0AE-499B-9813-066876336602Q41085668-EDD56D52-EE70-4BF0-80F7-F114CA9396F2Q41235746-13D640F6-400E-44EF-B6CE-DE04BDBD7A55Q46061882-5DDB62D3-9F99-455D-B01A-8B5C093E3ACAQ46109651-20CEB499-4582-4BB3-A62B-4A12224D55ECQ46309618-59311F7C-4C3C-4F48-B326-59CAFCD01317Q48141524-DD288360-A7E7-4E33-B67C-7D32725BF4E8Q51248884-B97368D7-6951-4804-A4A4-3749A737A04FQ53073596-22854B91-6C6B-4B1D-A294-533C3410D786Q53830100-0ED49274-3C54-4DF3-AB1E-546AD1A9B9ABQ56425304-ECE81DF7-44FF-4AFC-A283-71A25771EC2EQ56976041-44CE86A3-5DE4-44ED-B035-756FA1AEF8E6Q57199141-E183871B-5509-4AA0-9599-6A2FCC326129Q57209483-633DA28F-A765-4A1D-8C40-97C0BF392022Q57251264-9983166C-8851-402A-B8EC-0553C337D0A2Q57257398-0D0D6518-CB31-47F5-9C62-2F72CB0690F5Q58389770-D3F00863-3844-4EF7-909D-2D67DAE44206Q58389790-4E81AFE5-AA2C-492A-B343-22846DC4D737Q58478866-54AFDCF0-F8CE-4B9B-924B-363F2662CBEA
P2860
Mixed conditional logistic regression for habitat selection studies.
description
2010 nî lūn-bûn
@nan
2010年の論文
@ja
2010年学术文章
@wuu
2010年学术文章
@zh
2010年学术文章
@zh-cn
2010年学术文章
@zh-hans
2010年学术文章
@zh-my
2010年学术文章
@zh-sg
2010年學術文章
@yue
2010年學術文章
@zh-hant
name
Mixed conditional logistic regression for habitat selection studies.
@en
Mixed conditional logistic regression for habitat selection studies.
@nl
type
label
Mixed conditional logistic regression for habitat selection studies.
@en
Mixed conditional logistic regression for habitat selection studies.
@nl
prefLabel
Mixed conditional logistic regression for habitat selection studies.
@en
Mixed conditional logistic regression for habitat selection studies.
@nl
P2093
P1476
Mixed conditional logistic regression for habitat selection studies.
@en
P2093
Daniel Fortin
Nicolas Courbin
Thierry Duchesne
P304
P356
10.1111/J.1365-2656.2010.01670.X
P577
2010-02-25T00:00:00Z