Polynomial representations of cyclic redundancy checks

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Supersymmetry gauge theory including supergravity is mainly developed as a Yang - Mills type theory with spontaneous breakdown of supersymmetries. There are various superextensions of pseudo-orthogonal Lie algebras and the Poincaré Lie algebra. The nonlinear realization of some Lie superalgebras have been studied. However, supergravity introduced in SUSY gauge theory has no geometric feature as a supermetric.

In gauge theory on a principal bundle PM with a structure group K, spontaneous symmetry breaking is characterized as a reduction of K to some closed subgroup H. By the well-known theorem, such a reduction takes place if and only if there exists a global section h of the quotient bundle P/HM. This section is treated as a classical Higgs field.

In particular, this is the case of gauge gravitation theory where P=FM is a principal frame bundle of linear frames in the tangent bundle TM of a world manifold M. In accordance with the geometric equivalence principle, its structure group GL(n,) is reduced to the Lorentz group O(1,3), and the associated global section of the quotient bundle FM/O(1,3) is a pseudo-Riemannian metric on M, i.e., a gravitational field in General Relativity.

Similarly, a supermetric can be defined as a global section of a certain quotient superbundle.

It should be emphasized that there are different notions of a supermanifold. Lie supergroups and principal superbundles are considered in the category of G-supermanifolds. Let P^M^ be a principal superbundle with a structure Lie supergroup K^, and let H^ be a closed Lie supersubgroup of K^ such that K^K^/H^ is a principal superbundle. There is one-to-one correspondence between the principal supersubbundles of P^ with the structure Lie supergroup H^ and the global sections of the quotient superbundle P^/H^M^ with a typical fiber K^/H^.

A key point is that underlying spaces of G-supermanifolds are smooth real manifolds, but possessing very particular transition functions. Therefore, the condition of local triviality of the quotient K^K^/H^ is rather restrictive. It is satisfied in the most interesting case for applications when K^ is a supermatrix group and H^ is its Cartan supersubgroup. For instance, let P^=FM^ be a principal superbundle of graded frames in the tangent superspaces over a supermanifold M^ of even-odd dimensione (n,2m). If its structure general linear supergroup K^=GL^(n|2m;Λ) is reduced to the orthgonal-symplectic supersubgroup H^=OS^p(n|m;Λ), one can think of the corresponding global section of the quotient superbundle FM^/H^M^ as being a supermetric on a supermanifold M^.

In particular, this is the case of a super-Euclidean metric on a superspace Bn|2m.

References

  • Deligne, P. and Morgan, J. (1999) Notes on supersymmetry (following Joseph Bernstein). In: Quantum Field Theory and Strings: A Course for Mathematicians, Vol. 1 (Providence, RI: Amer. Math. Soc.) pp. 41-97 ISBN 978-0-8218-1198-6.
  • Sardanashvily, G. (2008) Supermetrics on supermanifolds, Int. J. Geom. Methods Mod. Phys. 5, 271.

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