Dinosaur classification

Dinosaur classification began in 1842 when Sir Richard Owen placed Iguanodon, Megalosaurus, and Hylaeosaurus in "a distinct tribe or suborder of Saurian Reptiles, for which I would propose the name of Dinosauria."[1] In 1887 and 1888 Harry Seeley divided dinosaurs into the two orders Saurischia and Ornithischia, based on their hip structure.[2] These divisions have proved remarkably enduring, even through several seismic changes in the taxonomy of dinosaurs.

Classification of dinosaurs

The largest change was prompted by entomologist Willi Hennig's work in the 1950s, which evolved into modern cladistics. For specimens known only from fossils, the rigorous analysis of characters to determine evolutionary relationships between different groups of animals (clades) proved incredibly useful. When computer-based analysis using cladistics came into its own in the 1990s, paleontologists became among the first zoologists to almost wholeheartedly adopt the system.[3] Progressive scrutiny and work upon dinosaurian interrelationships, with the aid of new discoveries that have shed light on previously uncertain relationships between taxa, have begun to yield a stabilizing classification since the mid-2000s. While cladistics is the predominant classificatory system among paleontology professionals, the Linnean system is still in use, especially in works intended for popular distribution.

Benton classification

As most dinosaur paleontologists have advocated a shift away from traditional, ranked Linnaean taxonomy in favor of rankless phylogenetic systems,[3] few ranked taxonomies of dinosaurs have been published since the 1980s. The following schema is among the most recent, from the third edition of Vertebrate Palaeontology,[4] a respected undergraduate textbook. While it is structured so as to reflect evolutionary relationships (similar to a cladogram), it also retains the traditional ranks used in Linnaean taxonomy. The classification has been updated from the second edition in 2000 to reflect new research, but remains fundamentally conservative.

Michael Benton classifies all dinosaurs within the Series Amniota, Class Sauropsida, Subclass Diapsida, Infraclass Archosauromorpha, Division Archosauria, Subdivision Avemetatarsalia, Infradivision Ornithodira, and Superorder Dinosauria. Dinosauria is then divided into the two traditional orders, Saurischia and Ornithischia. The dagger (†) is used to indicate taxa with no living members.

Order Saurischia

†Order Ornithischia

Weishampel/Dodson/Osmólska classification

The following is based on the second edition of The Dinosauria,[5] a compilation of articles by experts in the field that provided the most comprehensive coverage of Dinosauria available when it was first published in 1990. The second edition updates and revises that work.

The cladogram and phylogenetic definitions below reflect the current understanding of evolutionary relationships. The taxa and symbols in parentheses after a given taxa define these relationships. The plus symbol ("+") between taxa indicates the given taxa is a node-based clade, defined as comprising all descendants of the last common ancestor of the "added" taxa. The greater-than symbol (">") indicates the given taxon is a stem-based taxon, comprising all organisms sharing a common ancestor that is not also an ancestor of the "lesser" taxon.

Saurischia

(Tyrannosaurus/Allosaurus > Triceratops/Stegosaurus)

Ornithischia

(Iguanodon/Triceratops > Cetiosaurus/Tyrannosaurus)

Baron/Norman/Barrett classification

In 2017 Matthew G. Baron and his colleagues published a new analysis proposing to put Theropoda (except Herrerasauridae) and Ornithischia within a group called Ornithoscelida (a name originally coined by Thomas Henry Huxley in 1870), redefining Saurischia to cover Sauropodomorpha and Herrerasauridae. Amongst other things this would require hypercarnivory to have evolved independently for Theropoda and Herrerasauridae.[6][7] This scheme is currently debated among palaeontologists, with recent studies finding little difference between the traditional and newly proposed models. [8][9]

Cau 2018

In his paper about the stepwise evolution of the avian bauplan, Cau (2018) found in the parsimony analysis polytomy between herrerasaur-grade taxa, Sauropodomorpha and the controversial Ornithoscelida. The Bayesian analysis, however, found a weak support in the sister grouping of a Dinosauria and Herrerasauria, but show strong support in the dicotomy between Sauropodomorpha and Ornithoscelida as shown below:[10]

Dracohors

Silesauridae (including Pisanosaurus[11][10])

Dinosauria
Herrerasauria

Herrerasauridae

Tawa

Daemonosaurus

Sauropodomorpha

Eodromaeus

Ornithoscelida

Ornithischia

Theropoda

gollark: I don't actually want to do this, but I mean check which subtype a node is.
gollark: Is there some way to switch over subtypes or whatever?
gollark: ADTs? ADTs ADTs. ADTs ADTs ADTs, ADTs ADTs!
gollark: ADTs!
gollark: ```haskelldata Node = Thingy Int Int Int | Thingummy String Int | Whatsit [Node]```

See also

Footnotes

  1. Owens, 1842.
  2. Seeley, 1888. While the paper was published in 1888, it was first delivered in 1887.
  3. Brochu, C.A.; Sumrall, C.D. (2001). "Phylogenetic nomenclature and paleontology". Journal of Paleontology. 75 (4): 754–757. doi:10.1666/0022-3360(2001)075<0754:PNAP>2.0.CO;2.
  4. Benton, Michael 2004. The classification scheme is available online Archived 2008-10-19 at the Wayback Machine
  5. Weishampel, 2004
  6. Baron MG; Norman DB; Barrett PM (2017). "A new hypothesis of dinosaur relationships and early dinosaur evolution" (PDF). Nature. 543 (7646): 501–506. Bibcode:2017Natur.543..501B. doi:10.1038/nature21700. PMID 28332513.
  7. Naish, Darren (2017), "Ornithoscelida Rises: A New Family Tree for Dinosaurs", Scientific American Tetrapod Zoology blog, retrieved March 24, 2017
  8. Max C. Langer; Martín D. Ezcurra; Oliver W. M. Rauhut; Michael J. Benton; Fabien Knoll; Blair W. McPhee; Fernando E. Novas; Diego Pol; Stephen L. Brusatte (2017). "Untangling the dinosaur family tree" (PDF). Nature. 551 (7678): E1–E3. Bibcode:2017Natur.551E...1L. doi:10.1038/nature24011. hdl:1983/d088dae2-c7fa-4d41-9fa2-aeebbfcd2fa3. PMID 29094688.
  9. Matthew G. Baron; David B. Norman; Paul M. Barrett (2017). "Baron et al. reply". Nature. 551 (7678): E4–E5. Bibcode:2017Natur.551E...4B. doi:10.1038/nature24012. PMID 29094705.
  10. Andrea Cau (2018). "The assembly of the avian body plan: a 160-million-year long process". Bollettino della Società Paleontologica Italiana. 57 (1): 1–25. doi:10.4435/BSPI.2018.01.
  11. Agnolín, Federico L.; Rozadilla, Sebastián (2017). "Phylogenetic reassessment of Pisanosaurus mertii Casamiquela, 1967, a basal dinosauriform from the Late Triassic of Argentina". Journal of Systematic Palaeontology. 16 (10): 853–879. doi:10.1080/14772019.2017.1352623.

References

  • Benton, Michael J. (2004). Vertebrate Palaeontology, Third Edition. Blackwell Publishing. p. 472 pp. ISBN 9780632056378.
  • Owen, Richard (1842). "Report on British Fossil Reptiles: Part II". Report of the British Association for the Advancement of Science. 11: 60–204.
  • Seeley, Harry Govier (1888). "On the classification of the Fossil Animals commonly named Dinosauria". Proceedings of the Royal Society of London. 43 (258–265): 165–171. Bibcode:1887RSPS...43..165S. doi:10.1098/rspl.1887.0117..
  • Weishampel, David B. (2004). Dodson, Peter; Osmólska, Halszka (eds.). The Dinosauria, Second Edition. University of California Press. p. 861 pp. ISBN 0-520-24209-2.
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