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{{general relativity}}
In ], '''Regge calculus''' is a formalism for producing ] of spacetimes that are solutions to the ]. The calculus was introduced by the Italian theoretician ] in 1961.<ref>{{cite journal | author=Tullio E. Regge | title=General relativity without coordinates | journal=Nuovo Cimento | year=1961 | volume=19 | issue=3 | pages=558–571 | doi=10.1007/BF02733251| bibcode=1961NCim...19..558R | author-link=Tullio E. Regge }} Available (subscribers only) at </ref> In ], '''Regge calculus''' is a formalism for producing ] of spacetimes that are solutions to the ]. The calculus was introduced by the Italian theoretician ] in 1961.<ref>{{cite journal | author=Tullio E. Regge | title=General relativity without coordinates | journal=Nuovo Cimento | year=1961 | volume=19 | issue=3 | pages=558–571 | doi=10.1007/BF02733251| bibcode=1961NCim...19..558R | s2cid=120696638 | author-link=Tullio E. Regge }} Available (subscribers only) at </ref>


==Overview== ==Overview==
The starting point for Regge's work is the fact that every ] admits a ] into ]. Furthermore, the ] ] can be expressed in terms of ] associated with ''2-faces'' where arrangements of ''4-simplices'' meet. These 2-faces play the same role as the ] where arrangements of ''triangles'' meet in a triangulation of a ''2-manifold'', which is easier to visualize. Here a vertex with a positive angular deficit represents a concentration of ''positive'' ], whereas a vertex with a negative angular deficit represents a concentration of ''negative'' Gaussian curvature. The starting point for Regge's work is the fact that every four dimensional time orientable ] admits a ] into ]. Furthermore, the ] ] can be expressed in terms of ] associated with ''2-faces'' where arrangements of ''4-simplices'' meet. These 2-faces play the same role as the ] where arrangements of ''triangles'' meet in a triangulation of a ''2-manifold'', which is easier to visualize. Here a vertex with a positive angular deficit represents a concentration of ''positive'' ], whereas a vertex with a negative angular deficit represents a concentration of ''negative'' Gaussian curvature.


The deficit angles can be computed directly from the various ] lengths in the triangulation, which is equivalent to saying that the ] can be computed from the ] of a Lorentzian manifold. Regge showed that the ] can be reformulated as a restriction on these deficit angles. He then showed how this can be applied to evolve an initial ] according to the vacuum field equation. The deficit angles can be computed directly from the various ] lengths in the triangulation, which is equivalent to saying that the ] can be computed from the ] of a Lorentzian manifold. Regge showed that the ] can be reformulated as a restriction on these deficit angles. He then showed how this can be applied to evolve an initial ] according to the vacuum field equation.
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==See also== ==See also==
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==Notes== ==Notes==
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* {{cite journal | author= John Archibald Wheeler | title= Geometrodynamics and the Issue of the Final State, in "Relativity Groups and Topology" | publisher= Les Houches Lecture Notes 1963, Gordon and Breach | year=1965 | author-link= John Archibald Wheeler }} * {{cite journal | author= John Archibald Wheeler | title= Geometrodynamics and the Issue of the Final State, in "Relativity Groups and Topology" | publisher= Les Houches Lecture Notes 1963, Gordon and Breach | year=1965 | author-link= John Archibald Wheeler }}
* {{cite book | author=Misner, Charles W. Thorne, Kip S. & Wheeler, John Archibald | title=Gravitation | publisher=San Francisco: W. H. Freeman | year =1973 | isbn=978-0-7167-0344-0}} See ''chapter 42''. * {{cite book | author=Misner, Charles W. Thorne, Kip S. & Wheeler, John Archibald | title=Gravitation | publisher=San Francisco: W. H. Freeman | year =1973 | isbn=978-0-7167-0344-0}} See ''chapter 42''.
* {{cite book | author= Herbert W. Hamber | title= Quantum Gravitation - The Feynman Path Integral Approach | publisher = Springer Publishing | year=2009 | doi=10.1007/978-3-540-85293-3 | isbn=978-3-540-85292-6| url= http://cds.cern.ch/record/1233211 }} Chapters 4 and 6. * {{cite book | author= Herbert W. Hamber | editor1-first= Herbert W | editor1-last= Hamber | title= Quantum Gravitation - The Feynman Path Integral Approach | publisher = Springer Publishing | year=2009 | doi=10.1007/978-3-540-85293-3 | isbn=978-3-540-85292-6| url= https://cds.cern.ch/record/1233211 }} Chapters 4 and 6.
* {{cite journal | author= James B. Hartle | title= Simplicial MiniSuperSpace I. General Discussion | journal=Jour. Math. Physics | year=1985 | volume=26 | issue= 4 | pages=804–812 | doi=10.1063/1.526571|bibcode = 1985JMP....26..804H }} * {{cite journal | author= James B. Hartle | title= Simplicial MiniSuperSpace I. General Discussion | journal= Journal of Mathematical Physics| year=1985 | volume=26 | issue= 4 | pages=804–812 | doi=10.1063/1.526571|bibcode = 1985JMP....26..804H }}
* {{cite journal |author1=Ruth M. Williams |author2=Philip A. Tuckey |lastauthoramp=yes | title=Regge calculus: a brief review and bibliography | journal=Class. Quantum Grav. | year=1992 | volume=9 | issue= 5 | pages=1409–1422 | doi=10.1088/0264-9381/9/5/021|bibcode = 1992CQGra...9.1409W |url=http://cds.cern.ch/record/227081 }} Available (subscribers only) at . * {{cite journal |author1=Ruth M. Williams |author2=Philip A. Tuckey |name-list-style=amp | title=Regge calculus: a brief review and bibliography | journal=Class. Quantum Grav. | year=1992 | volume=9 | issue= 5 | pages=1409–1422 | doi=10.1088/0264-9381/9/5/021|bibcode = 1992CQGra...9.1409W |s2cid=250776873 |url=https://cds.cern.ch/record/227081 }} Available (subscribers only) at .
* {{cite journal | author= ] and Ruth M. Williams | title= Discrete Structures in Gravity | journal= Journal of Mathematical Physics| year=2000 | volume=41 | issue= 6 | pages=3964–3984 | doi=10.1063/1.533333 |arxiv = gr-qc/0012035 |bibcode = 2000JMP....41.3964R }} Available at . * {{cite journal | author= ] and Ruth M. Williams | title= Discrete Structures in Gravity | journal= Journal of Mathematical Physics | year=2000 | volume=41 | issue= 6 | pages=3964–3984 | doi=10.1063/1.533333 |arxiv = gr-qc/0012035 |bibcode = 2000JMP....41.3964R | s2cid= 118957627 }} Available at .
* {{ cite journal | author = Herbert W. Hamber | title = Simplicial Quantum Gravity, in the Les Houches Summer School on Critical Phenomena, Random Systems and Gauge Theories, Session XLIII | year = 1984 | publisher = North Holland Elsevier | pages =375–439 }} * {{ cite journal | author = Herbert W. Hamber | title = Simplicial Quantum Gravity, in the Les Houches Summer School on Critical Phenomena, Random Systems and Gauge Theories, Session XLIII | year = 1984 | publisher = North Holland Elsevier | pages =375–439 }}
* {{cite journal | author=Adrian P. Gentle | title=Regge calculus: a unique tool for numerical relativity | journal=Gen. Rel. Grav. | year=2002 | volume=34 | issue=10 | pages=1701–1718 | doi=10.1023/A:1020128425143}} * {{cite journal | author=Adrian P. Gentle | title=Regge calculus: a unique tool for numerical relativity | journal=Gen. Rel. Grav. | year=2002 | volume=34 | issue=10 | pages=1701–1718 | doi=10.1023/A:1020128425143| s2cid=119090423 | url=https://cds.cern.ch/record/784592 }}
* {{cite journal | author=Renate Loll | title=Discrete approaches to quantum gravity in four dimensions | journal=Living Rev. Relativ. | year=1998 | volume=1 | issue=1 | pages=13|arxiv = gr-qc/9805049 |bibcode = 1998LRR.....1...13L |doi = 10.12942/lrr-1998-13 | pmid=28191826 | pmc=5253799 }} Available at . See ''section 3''. * {{cite journal | author=Renate Loll | title=Discrete approaches to quantum gravity in four dimensions | journal=Living Rev. Relativ. | year=1998 | volume=1 | issue=1 | pages=13|arxiv = gr-qc/9805049 |bibcode = 1998LRR.....1...13L |doi = 10.12942/lrr-1998-13 | doi-access=free | pmid=28191826 | pmc=5253799 }} Available at . See ''section 3''.
* {{cite journal | author= J. W. Barrett | title=The geometry of classical Regge calculus | journal=Class. Quantum Grav. | year=1987 | volume=4 | issue= 6 | pages=1565–1576 | doi=10.1088/0264-9381/4/6/015|bibcode = 1987CQGra...4.1565B | url=http://cds.cern.ch/record/173023 }} Available (subscribers only) at . * {{cite journal | author= J. W. Barrett | title=The geometry of classical Regge calculus | journal=Class. Quantum Grav. | year=1987 | volume=4 | issue= 6 | pages=1565–1576 | doi=10.1088/0264-9381/4/6/015|bibcode = 1987CQGra...4.1565B | s2cid=250783980 | url=https://cds.cern.ch/record/173023 }} Available (subscribers only) at .


==External links== ==External links==
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Latest revision as of 01:24, 20 July 2024

General relativity
Spacetime curvature schematic G μ ν + Λ g μ ν = κ T μ ν {\displaystyle G_{\mu \nu }+\Lambda g_{\mu \nu }={\kappa }T_{\mu \nu }}
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In general relativity, Regge calculus is a formalism for producing simplicial approximations of spacetimes that are solutions to the Einstein field equation. The calculus was introduced by the Italian theoretician Tullio Regge in 1961.

Overview

The starting point for Regge's work is the fact that every four dimensional time orientable Lorentzian manifold admits a triangulation into simplices. Furthermore, the spacetime curvature can be expressed in terms of deficit angles associated with 2-faces where arrangements of 4-simplices meet. These 2-faces play the same role as the vertices where arrangements of triangles meet in a triangulation of a 2-manifold, which is easier to visualize. Here a vertex with a positive angular deficit represents a concentration of positive Gaussian curvature, whereas a vertex with a negative angular deficit represents a concentration of negative Gaussian curvature.

The deficit angles can be computed directly from the various edge lengths in the triangulation, which is equivalent to saying that the Riemann curvature tensor can be computed from the metric tensor of a Lorentzian manifold. Regge showed that the vacuum field equations can be reformulated as a restriction on these deficit angles. He then showed how this can be applied to evolve an initial spacelike hyperslice according to the vacuum field equation.

The result is that, starting with a triangulation of some spacelike hyperslice (which must itself satisfy a certain constraint equation), one can eventually obtain a simplicial approximation to a vacuum solution. This can be applied to difficult problems in numerical relativity such as simulating the collision of two black holes.

The elegant idea behind Regge calculus has motivated the construction of further generalizations of this idea. In particular, Regge calculus has been adapted to study quantum gravity.

See also

Notes

  1. Tullio E. Regge (1961). "General relativity without coordinates". Nuovo Cimento. 19 (3): 558–571. Bibcode:1961NCim...19..558R. doi:10.1007/BF02733251. S2CID 120696638. Available (subscribers only) at Il Nuovo Cimento

References

External links

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