On the differential geometry of some classes of infinite dimensional manifolds

Maysam Maysami Sadr; Danial Bouzarjomehri Amnieh

Archivum Mathematicum (2024)

  • Volume: 060, Issue: 1, page 1-20
  • ISSN: 0044-8753

Abstract

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Albeverio, Kondratiev, and Röckner have introduced a type of differential geometry, which we call lifted geometry, for the configuration space Γ X of any manifold X . The name comes from the fact that various elements of the geometry of Γ X are constructed via lifting of the corresponding elements of the geometry of X . In this note, we construct a general algebraic framework for lifted geometry which can be applied to various “infinite dimensional spaces” associated to X . In order to define a lifted geometry for a “space”, one dose not need any topology or local coordinate system on the space. As example and application, lifted geometry for spaces of Radon measures on X , mappings into X , embedded submanifolds of X , and tilings on X , are considered. The gradient operator in the lifted geometry of Radon measures is considered. Also, the construction of a natural Dirichlet form associated to a random measure is discussed. It is shown that Stokes’ Theorem appears as “differentiability” of “boundary operator” in the lifted geometry of spaces of submanifolds. It is shown that (generalized) action functionals associated with Lagrangian densities on X form the algebra of smooth functions in a specific lifted geometry for the path-space of X .

How to cite

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Sadr, Maysam Maysami, and Amnieh, Danial Bouzarjomehri. "On the differential geometry of some classes of infinite dimensional manifolds." Archivum Mathematicum 060.1 (2024): 1-20. <http://eudml.org/doc/299190>.

@article{Sadr2024,
abstract = {Albeverio, Kondratiev, and Röckner have introduced a type of differential geometry, which we call lifted geometry, for the configuration space $\Gamma _X$ of any manifold $X$. The name comes from the fact that various elements of the geometry of $\Gamma _X$ are constructed via lifting of the corresponding elements of the geometry of $X$. In this note, we construct a general algebraic framework for lifted geometry which can be applied to various “infinite dimensional spaces” associated to $X$. In order to define a lifted geometry for a “space”, one dose not need any topology or local coordinate system on the space. As example and application, lifted geometry for spaces of Radon measures on $X$, mappings into $X$, embedded submanifolds of $X$, and tilings on $X$, are considered. The gradient operator in the lifted geometry of Radon measures is considered. Also, the construction of a natural Dirichlet form associated to a random measure is discussed. It is shown that Stokes’ Theorem appears as “differentiability” of “boundary operator” in the lifted geometry of spaces of submanifolds. It is shown that (generalized) action functionals associated with Lagrangian densities on $X$ form the algebra of smooth functions in a specific lifted geometry for the path-space of $X$.},
author = {Sadr, Maysam Maysami, Amnieh, Danial Bouzarjomehri},
journal = {Archivum Mathematicum},
keywords = {algebraic differential geometry; infinite dimensional manifold; smooth function; vector field; differential form},
language = {eng},
number = {1},
pages = {1-20},
publisher = {Department of Mathematics, Faculty of Science of Masaryk University, Brno},
title = {On the differential geometry of some classes of infinite dimensional manifolds},
url = {http://eudml.org/doc/299190},
volume = {060},
year = {2024},
}

TY - JOUR
AU - Sadr, Maysam Maysami
AU - Amnieh, Danial Bouzarjomehri
TI - On the differential geometry of some classes of infinite dimensional manifolds
JO - Archivum Mathematicum
PY - 2024
PB - Department of Mathematics, Faculty of Science of Masaryk University, Brno
VL - 060
IS - 1
SP - 1
EP - 20
AB - Albeverio, Kondratiev, and Röckner have introduced a type of differential geometry, which we call lifted geometry, for the configuration space $\Gamma _X$ of any manifold $X$. The name comes from the fact that various elements of the geometry of $\Gamma _X$ are constructed via lifting of the corresponding elements of the geometry of $X$. In this note, we construct a general algebraic framework for lifted geometry which can be applied to various “infinite dimensional spaces” associated to $X$. In order to define a lifted geometry for a “space”, one dose not need any topology or local coordinate system on the space. As example and application, lifted geometry for spaces of Radon measures on $X$, mappings into $X$, embedded submanifolds of $X$, and tilings on $X$, are considered. The gradient operator in the lifted geometry of Radon measures is considered. Also, the construction of a natural Dirichlet form associated to a random measure is discussed. It is shown that Stokes’ Theorem appears as “differentiability” of “boundary operator” in the lifted geometry of spaces of submanifolds. It is shown that (generalized) action functionals associated with Lagrangian densities on $X$ form the algebra of smooth functions in a specific lifted geometry for the path-space of $X$.
LA - eng
KW - algebraic differential geometry; infinite dimensional manifold; smooth function; vector field; differential form
UR - http://eudml.org/doc/299190
ER -

References

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