about
A jump persistent turning walker to model zebrafish locomotion.Group dynamics and landscape features constrain the exploration of herds in fusion-fission societies: the case of European roe deerMechanistic movement models to understand epidemic spread.Analyzing spatial data from mouse tracker methodology: An entropic approach.GPS measurement error gives rise to spurious 180 degree turning angles and strong directional biases in animal movement data.To migrate, stay put, or wander? Varied movement strategies in bald eagles (Haliaeetus leucocephalus).A model-driven approach to quantify migration patterns: individual, regional and yearly differences.The formation of collective silk balls in the spider mite Tetranychus urticae KochHidden Markov models: the best models for forager movements?Reaching the ball or missing the flight? Collective dispersal in the two-spotted spider mite Tetranychus urticae.Dispersal behavior of Tetranychus evansi and T. urticae on tomato at several spatial scales and densities: implications for integrated pest management.Impact assessment predicted by means of genetic agent-based modeling.Does movement behaviour predict population densities? A test with 25 butterfly species.Use, misuse and extensions of "ideal gas" models of animal encounter.The need for integrative approaches to understand and conserve migratory ungulates.Anomalous diffusion of heterogeneous populations characterized by normal diffusion at the individual levelEnvironmental and anthropogenic drivers of connectivity patterns: A basis for prioritizing conservation efforts for threatened populations.Effects of environmental features and sport hunting on caribou migration in northwestern Alaska.REVIEW: Can habitat selection predict abundance?Inferring ecological and behavioral drivers of African elephant movement using a linear filtering approach.Movement is the glue connecting home ranges and habitat selection.Random walk analysis of ranging patterns of sympatric langurs in a complex resource landscape.Sampling animal movement paths causes turn autocorrelation.Inferring the rules of social interaction in migrating caribou.Implementing a novel movement-based approach to inferring parturition and neonate caribou calf survival.Environmental and individual drivers of animal movement patterns across a wide geographical gradient.Covariates affecting spatial variability in bison travel behavior in Yellowstone National Park.Animal movement rates as behavioural bouts.Detecting an orientation component in animal paths when the preferred direction is individual-dependent.Automated analysis of long-term grooming behavior in Drosophila using a k-nearest neighbors classifier.Microsatellite DNA evidence for genetic drift and philopatry in Svalbard reindeer.At-sea distribution and scale-dependent foraging behaviour of petrels and albatrosses: a comparative studySearch paths of swans foraging on spatially autocorrelated tubersANIMAL SEARCH STRATEGIES: A QUANTITATIVE RANDOM-WALK ANALYSIS
P2860
Q27346343-98983152-6717-400F-AA3E-05B0C94A8640Q28730820-EF860164-C910-4C6B-8227-5E3E7028CC18Q30235303-49702958-AEBA-4CAB-9A2F-07EC8616EB1EQ31154307-F2903421-40F6-4423-B594-C1AD3A709FDCQ33455797-AA99420E-61C2-48B1-BA37-B0032B8DC4D1Q33640427-F8D55146-18CC-4F9C-9248-077BE21B5626Q33755329-7023E8E0-0401-42C5-9452-ED85901E47A6Q33886445-93D3B6D3-8671-4AE0-AC26-CD19BEC6D17DQ34994164-8530096B-398B-455D-AC72-B74A2FE7448DQ35021784-3EB5CEB4-4D5D-4AA8-BA5B-43E51271BA4DQ35151988-D1DCFF6A-1121-437C-92B0-ECB703B47D5CQ35989061-8E4475D3-C7C0-48EA-98A6-3B1692361FBDQ36196577-DF81C9C8-0BF3-4992-BB49-18D7AAADCCE5Q36877383-CEB7FEAB-234F-411A-AAD2-5C4A5127ADC1Q36952617-ECC5500A-2E55-4D59-9738-5D42CBEFE73AQ37029339-8C55CACC-F15A-4A93-ADA5-0A978430113BQ37597999-8FA6F4B4-72CC-4115-B299-CBE203FBC959Q37673433-99DD80A5-F4AB-4A2E-B88D-C1AEABEB84EEQ38382819-4B42A753-D598-4902-8808-7534D5136C0EQ38698105-D90EB747-5AEE-4EC6-BB73-F16979B14317Q40932839-A1995CF7-482A-4F33-89EB-2796BB326EDBQ42612335-15AC445B-52C3-457F-9166-052D286182DEQ48982914-3EF95AFD-983B-4F05-80BD-22A5F24BADE9Q51144565-81F81BD8-2D85-4813-88DB-3A7ED1DFC5C2Q51152037-7DC7520B-A505-40AB-95CD-E94D4BC3EFC7Q51549266-26A22AFC-F9CA-4310-B4E4-6F0BF5728DCAQ51703773-B458A826-DDBA-4B8A-9E5F-8C88A9CE3733Q51722820-58F628CD-0E91-4324-9458-7B7A4AA4383BQ51728519-EED1FF58-2E6D-429A-85FC-3E1DF3092DB5Q52683435-0A9F96E5-528F-4C69-BA10-44FBC2DC66CBQ52943699-73CCC605-08AD-419B-A4E2-FC8B546406E9Q56701243-2D72E66A-31F1-4614-8728-99C2D77B5549Q57126312-C868ADB7-E7F9-4B39-B8DD-AD2A0CE3372FQ57230684-06784DD1-A8FC-45FC-A80E-33251C4C1719
P2860
description
2000 nî lūn-bûn
@nan
2000年の論文
@ja
2000年学术文章
@wuu
2000年学术文章
@zh-cn
2000年学术文章
@zh-hans
2000年学术文章
@zh-my
2000年学术文章
@zh-sg
2000年學術文章
@yue
2000年學術文章
@zh
2000年學術文章
@zh-hant
name
Caribou movement as a correlated random walk.
@en
type
label
Caribou movement as a correlated random walk.
@en
prefLabel
Caribou movement as a correlated random walk.
@en
P2093
P356
P1433
P1476
Caribou movement as a correlated random walk.
@en
P2093
C M Bergman
J A Schaefer
S N Luttich
P2888
P304
P356
10.1007/S004420051023
P407
P577
2000-05-01T00:00:00Z