The accuracy of species tree estimation under simulation: a comparison of methods.
about
Data concatenation, Bayesian concordance and coalescent-based analyses of the species tree for the rapid radiation of Triturus newtsNon-monophyly and intricate morphological evolution within the avian family Cettiidae revealed by multilocus analysis of a taxonomically densely sampled datasetPhylogenomic analyses of nuclear genes reveal the evolutionary relationships within the BEP clade and the evidence of positive selection in PoaceaeMultilocus inference of species trees and DNA barcodingAssessing models of speciation under different biogeographic scenarios; an empirical study using multi-locus and RNA-seq analysesComputational Performance and Statistical Accuracy of *BEAST and Comparisons with Other MethodsSpider phylogenomics: untangling the Spider Tree of LifeResolving Evolutionary Relationships in Closely Related Species with Whole-Genome Sequencing Data.Multilocus species trees show the recent adaptive radiation of the mimetic heliconius butterfliesConcatenation and Species Tree Methods Exhibit Statistically Indistinguishable Accuracy under a Range of Simulated ConditionsA multilocus phylogeny reveals deep lineages within African galagids (Primates: Galagidae).Corolla morphology influences diversification rates in bifid toadflaxes (Linaria sect. Versicolores)Conventional simulation of biological sequences leads to a biased assessment of multi-Loci phylogenetic analysisEvaluating multiple criteria for species delimitation: an empirical example using Hawaiian palms (Arecaceae: Pritchardia)Species tree estimation for the late blight pathogen, Phytophthora infestans, and close relativesMolecular systematics of the deep-sea hydrothermal vent endemic Brachyuran family Bythograeidae: a comparison of three Bayesian species tree methodsA Bayesian Supertree Model for Genome-Wide Species Tree ReconstructionSpecies delimitation with ABC and other coalescent-based methods: a test of accuracy with simulations and an empirical example with lizards of the Liolaemus darwinii complex (Squamata: Liolaemidae).Genome-wide RAD sequence data provide unprecedented resolution of species boundaries and relationships in the Lake Victoria cichlid adaptive radiation.Poor fit to the multispecies coalescent is widely detectable in empirical data.Species delimitation using genome-wide SNP data.Estimating phylogenetic trees from genome-scale data.How Should Genes and Taxa be Sampled for Phylogenomic Analyses with Missing Data? An Empirical Study in Iguanian Lizards.The Impact of Missing Data on Species Tree Estimation.Avoiding Missing Data Biases in Phylogenomic Inference: An Empirical Study in the Landfowl (Aves: Galliformes).Simulation-Based Evaluation of Hybridization Network Reconstruction Methods in the Presence of Incomplete Lineage Sorting.Inferring species trees from gene trees in a radiation of California trapdoor spiders (Araneae, Antrodiaetidae, Aliatypus)Accuracy and precision of species trees: effects of locus, individual, and base pair sampling on inference of species trees in lizards of the Liolaemus darwinii group (Squamata, Liolaemidae).Fast and accurate methods for phylogenomic analysesThe probability of a gene tree topology within a phylogenetic network with applications to hybridization detectionAnchored hybrid enrichment for massively high-throughput phylogenomics.Digits lost or gained? Evidence for pedal evolution in the dwarf salamander complex (Eurycea, Plethodontidae)Mammal madness: is the mammal tree of life not yet resolved?BBCA: Improving the scalability of *BEAST using random binning.Unguided species delimitation using DNA sequence data from multiple Loci.Simulating gene trees under the multispecies coalescent and time-dependent migrationMultiple genome alignments facilitate development of NPCL markers: a case study of tetrapod phylogeny focusing on the position of turtles.Phage cluster relationships identified through single gene analysis.The influence of gene flow on species tree estimation: a simulation study.The influence of sampling design on species tree inference: a new relationship for the New World chickadees (Aves: Poecile).
P2860
Q21131911-BF0290D7-AAB7-4470-BFEB-7292DA8F57EDQ21284043-858F0A04-3894-491C-8DBA-B44B9C7AD009Q21559625-11772B44-5ADF-4064-8D5A-25938CB49AF5Q26740127-6BDFE06C-D7B6-46F5-B507-3E26EBF08F6AQ28601923-76E731C5-9F27-4523-9406-8C7271509644Q28603530-F153CC89-DFDB-4BCE-ABD2-506EAF7754EDQ28603676-1C0114A4-B098-4FA5-AA39-5BFA4FC05D3BQ28606356-08213301-1DDE-4315-AB0B-FB293134C4C1Q28649720-C4C01FC9-4CF1-48CD-A925-AEF6F0F3A9A8Q28649918-4C87235B-1B11-4883-951D-E05EAA983233Q28660252-39BA550F-3DBC-4878-A725-6EB36AACF19FQ28661481-7C8F1D0F-D6E7-429C-A7EA-830A03191B2DQ28681759-D7543ADF-5D88-4096-9BF6-6E2772A9249CQ28729886-E2BDC96D-AC87-4356-8DF2-F0BE051C1CF4Q28729898-75420FFA-DF09-4EA1-B1DD-157ABDF62AF7Q28731533-C71AA7A9-A3FF-4A85-8597-958CC1EB8B98Q28833759-96AECA3E-15DA-44EA-9CB8-9A2B143D774CQ30561077-0E7350C8-A752-4046-BC7F-EAD74CBE62E5Q30573040-5956CA33-1563-4B46-B9D6-EDF33312E1B2Q30663836-C8D47458-BC76-4225-A537-396E517EFE7EQ30777152-41943B3B-7EC8-48F6-914E-F1520360CBB2Q30931894-B10BA503-7CEB-4C59-BA66-4C7A19AD72EFQ30991088-F8C576AE-B58E-421D-BBD2-72847573EA97Q31026927-7E1C3BD6-F69A-4363-8A3F-2016F1EA037FQ31034417-D5A63F09-CCA1-461D-AF73-C3C084F42ACAQ33574720-4C48D4EE-77EB-49F7-AF1D-9A04E9BBDE46Q34038255-AE9E0431-F4D5-44C6-97AF-161E039C46E5Q34072777-15754EEA-2A85-4EBB-A4F4-FD49F9255802Q34094894-08D1BA6F-7DAA-42CA-81D5-3E5383747CD3Q34246929-EB899F14-DCFA-4547-AA0C-22C22325EB5FQ34273260-B091AE2B-0890-49EF-AFBA-8B6D1C799244Q34287516-4FC72363-7553-47A7-83BA-3CDD424C7DD8Q34531503-EC0BEFED-0696-4E59-9C3C-6A7DD16193C4Q34552487-81944EBC-30EA-4C53-A397-1D043F116122Q34579281-570505BF-0B1F-42F9-9EA1-31D5A793C684Q34590469-CD50A0DC-AB00-4702-8B5D-F2C7818A1412Q34630314-7E0F8E2E-D9EB-4AD9-B5AE-69D5CD87F5E4Q34777305-D6F0EA41-E004-48F4-82BB-618B19CD7A55Q34941042-775F179A-AC00-48B2-963B-F94CCCCCC4A5Q35013224-DCE7E5B6-E0CE-4FB1-8D6B-AF95C222B893
P2860
The accuracy of species tree estimation under simulation: a comparison of methods.
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-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
2010年學術文章
@zh-hant
name
The accuracy of species tree estimation under simulation: a comparison of methods.
@en
The accuracy of species tree estimation under simulation: a comparison of methods.
@nl
type
label
The accuracy of species tree estimation under simulation: a comparison of methods.
@en
The accuracy of species tree estimation under simulation: a comparison of methods.
@nl
prefLabel
The accuracy of species tree estimation under simulation: a comparison of methods.
@en
The accuracy of species tree estimation under simulation: a comparison of methods.
@nl
P2860
P356
P1433
P1476
The accuracy of species tree estimation under simulation: a comparison of methods.
@en
P2093
Adam D Leaché
Bruce Rannala
P2860
P304
P356
10.1093/SYSBIO/SYQ073
P577
2010-11-18T00:00:00Z