On some algebraic identities and the exterior product of double forms

Mohammed Larbi Labbi

Archivum Mathematicum (2013)

  • Volume: 049, Issue: 4, page 241-271
  • ISSN: 0044-8753

Abstract

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We use the exterior product of double forms to free from coordinates celebrated classical results of linear algebra about matrices and bilinear forms namely Cayley-Hamilton theorem, Laplace expansion of the determinant, Newton identities and Jacobi’s formula for the determinant. This coordinate free formalism is then used to easily generalize the previous results to higher multilinear forms namely to double forms. In particular, we show that the Cayley-Hamilton theorem once applied to the second fundamental form of a hypersurface is equivalent to a linearized version of the Gauss-Bonnet theorem, and once its generalization is applied to the Riemann curvature tensor (seen as a ( 2 , 2 ) double form) is an infinitisimal version of the general Gauss-Bonnet-Chern theorem. In addition to that, we show that the general Cayley-Hamilton theorems generate several universal curvature identities. The generalization of the classical Laplace expansion of the determinant to double forms is shown to lead to new general Avez type formulas for all Gauss-Bonnet curvatures.

How to cite

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Labbi, Mohammed Larbi. "On some algebraic identities and the exterior product of double forms." Archivum Mathematicum 049.4 (2013): 241-271. <http://eudml.org/doc/260811>.

@article{Labbi2013,
abstract = {We use the exterior product of double forms to free from coordinates celebrated classical results of linear algebra about matrices and bilinear forms namely Cayley-Hamilton theorem, Laplace expansion of the determinant, Newton identities and Jacobi’s formula for the determinant. This coordinate free formalism is then used to easily generalize the previous results to higher multilinear forms namely to double forms. In particular, we show that the Cayley-Hamilton theorem once applied to the second fundamental form of a hypersurface is equivalent to a linearized version of the Gauss-Bonnet theorem, and once its generalization is applied to the Riemann curvature tensor (seen as a $(2,2)$ double form) is an infinitisimal version of the general Gauss-Bonnet-Chern theorem. In addition to that, we show that the general Cayley-Hamilton theorems generate several universal curvature identities. The generalization of the classical Laplace expansion of the determinant to double forms is shown to lead to new general Avez type formulas for all Gauss-Bonnet curvatures.},
author = {Labbi, Mohammed Larbi},
journal = {Archivum Mathematicum},
keywords = {Cayley-Hamilton theorem; cofactor; characteristic coefficients; Laplace expansion; Newton identities; Jacobi’s formula; double form; Newton transformation; exterior product; Gauss-Bonnet theorem; Cayley-Hamilton theorem; cofactor; characteristic coefficients; Laplace expansion; Newton identities; Jacobi's formula; double form; Newton transformation; exterior product; Gauss-Bonnet theorem},
language = {eng},
number = {4},
pages = {241-271},
publisher = {Department of Mathematics, Faculty of Science of Masaryk University, Brno},
title = {On some algebraic identities and the exterior product of double forms},
url = {http://eudml.org/doc/260811},
volume = {049},
year = {2013},
}

TY - JOUR
AU - Labbi, Mohammed Larbi
TI - On some algebraic identities and the exterior product of double forms
JO - Archivum Mathematicum
PY - 2013
PB - Department of Mathematics, Faculty of Science of Masaryk University, Brno
VL - 049
IS - 4
SP - 241
EP - 271
AB - We use the exterior product of double forms to free from coordinates celebrated classical results of linear algebra about matrices and bilinear forms namely Cayley-Hamilton theorem, Laplace expansion of the determinant, Newton identities and Jacobi’s formula for the determinant. This coordinate free formalism is then used to easily generalize the previous results to higher multilinear forms namely to double forms. In particular, we show that the Cayley-Hamilton theorem once applied to the second fundamental form of a hypersurface is equivalent to a linearized version of the Gauss-Bonnet theorem, and once its generalization is applied to the Riemann curvature tensor (seen as a $(2,2)$ double form) is an infinitisimal version of the general Gauss-Bonnet-Chern theorem. In addition to that, we show that the general Cayley-Hamilton theorems generate several universal curvature identities. The generalization of the classical Laplace expansion of the determinant to double forms is shown to lead to new general Avez type formulas for all Gauss-Bonnet curvatures.
LA - eng
KW - Cayley-Hamilton theorem; cofactor; characteristic coefficients; Laplace expansion; Newton identities; Jacobi’s formula; double form; Newton transformation; exterior product; Gauss-Bonnet theorem; Cayley-Hamilton theorem; cofactor; characteristic coefficients; Laplace expansion; Newton identities; Jacobi's formula; double form; Newton transformation; exterior product; Gauss-Bonnet theorem
UR - http://eudml.org/doc/260811
ER -

References

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