Parsimony jackknifing outperforms neighbor-joining

James S. Farris; Victor A. Albert; Mari Källersjö; Diana Lipscomb; Arnold G. Kluge

doi:10.1006/clad.1996.0008

Parsimony jackknifing outperforms neighbor-joining

James S. Farris
, Victor A. Albert
, Mari Källersjö
, Diana Lipscomb
, Arnold G. Kluge

Biological Sciences

Swedish Museum of Natural History
George Washington University
University of Michigan, Ann Arbor

Research output: Contribution to journal › Article › peer-review

1461 Scopus citations

Abstract

Because they are designed to produced just one tree, neighbor-joining programs can obscure ambiguities in data. Ambiguities can be uncovered by resampling, but existing neighbor-joining programs may give misleading bootstrap frequencies because they do not suppress zero-length branches and/or are sensitive to the order of terminals in the data. A new procedure, parsimony jackknifing, overcomes these problems while running hundreds of times faster than existing programs for neighbor-joining bootstrapping. For analysis of large matrices, parsimony jackknifing is hundreds of thousands of times faster than extensive branch-swapping, yet is better able to screen out poorly-supported groups.

Original language	English
Pages (from-to)	99-124
Number of pages	26
Journal	Cladistics
Volume	12
Issue number	2
DOIs	https://doi.org/10.1006/clad.1996.0008
State	Published - Jun 1996

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10.1006/clad.1996.0008

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title = "Parsimony jackknifing outperforms neighbor-joining",

abstract = "Because they are designed to produced just one tree, neighbor-joining programs can obscure ambiguities in data. Ambiguities can be uncovered by resampling, but existing neighbor-joining programs may give misleading bootstrap frequencies because they do not suppress zero-length branches and/or are sensitive to the order of terminals in the data. A new procedure, parsimony jackknifing, overcomes these problems while running hundreds of times faster than existing programs for neighbor-joining bootstrapping. For analysis of large matrices, parsimony jackknifing is hundreds of thousands of times faster than extensive branch-swapping, yet is better able to screen out poorly-supported groups.",

author = "Farris, \{James S.\} and Albert, \{Victor A.\} and Mari K{\"a}llersj{\"o} and Diana Lipscomb and Kluge, \{Arnold G.\}",

year = "1996",

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AU - Farris, James S.

AU - Albert, Victor A.

AU - Källersjö, Mari

AU - Lipscomb, Diana

AU - Kluge, Arnold G.

PY - 1996/6

Y1 - 1996/6

N2 - Because they are designed to produced just one tree, neighbor-joining programs can obscure ambiguities in data. Ambiguities can be uncovered by resampling, but existing neighbor-joining programs may give misleading bootstrap frequencies because they do not suppress zero-length branches and/or are sensitive to the order of terminals in the data. A new procedure, parsimony jackknifing, overcomes these problems while running hundreds of times faster than existing programs for neighbor-joining bootstrapping. For analysis of large matrices, parsimony jackknifing is hundreds of thousands of times faster than extensive branch-swapping, yet is better able to screen out poorly-supported groups.

AB - Because they are designed to produced just one tree, neighbor-joining programs can obscure ambiguities in data. Ambiguities can be uncovered by resampling, but existing neighbor-joining programs may give misleading bootstrap frequencies because they do not suppress zero-length branches and/or are sensitive to the order of terminals in the data. A new procedure, parsimony jackknifing, overcomes these problems while running hundreds of times faster than existing programs for neighbor-joining bootstrapping. For analysis of large matrices, parsimony jackknifing is hundreds of thousands of times faster than extensive branch-swapping, yet is better able to screen out poorly-supported groups.

UR - https://www.scopus.com/pages/publications/0030417648

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DO - 10.1006/clad.1996.0008

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JO - Cladistics

JF - Cladistics

IS - 2

ER -

Parsimony jackknifing outperforms neighbor-joining

Abstract

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