simple torsion - определение. Что такое simple torsion
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Что (кто) такое simple torsion - определение

(1,2)-TENSOR FIELD ASSOCIATED TO AN AFFINE CONNECTION; CHARACTERIZES "TWIST" OF GEODESICS; IF NONZERO, GEODESICS WILL BE HELICES
Affine torsion; Torsion (differential geometry); Torsion of connection; Cartan tensor; Torsion form; Torsion of a connection
  • Torsion along a geodesic.

Analytic torsion         
TOPOLOGICAL INVARIANT OF MANIFOLDS THAT CAN DISTINGUISH HOMOTOPY-EQUIVALENT MANIFOLDS; COMPUTABLE AS A REGULARIZED DETERMINANT OF THE LAPLACIAN FOR AN ARBITRARY RIEMANNIAN METRIC
Torsion (topology); Reidemeister torsion; R torsion; R-torsion; Ray-Singer torsion; Ray–Singer torsion; Reidemeister-Franz torsion; De Rham torsion; Franz torsion; Franz-Reidemeister torsion
In mathematics, Reidemeister torsion (or R-torsion, or Reidemeister–Franz torsion) is a topological invariant of manifolds introduced by Kurt Reidemeister for 3-manifolds and generalized to higher dimensions by and .
torsion balance         
  • Drawing of Coulomb's torsion balance. From Plate 13 of his 1785 memoir.
  • National Bureau of Standards]] (now NIST) between 1930 and 1942.
  • Video of a model torsion pendulum oscillating
  • Animation of a torsion spring oscillating
TYPE OF SPRING
Tortion spring; Torsion coefficient; Torsion balance; Torsion Balance; Torsional torque; Torsional Torque; Torsional pendulum; Torsional Pendulum; Torsion pendulum; Torsion springs; Torsional spring; Rotational spring; Deflecting torque
¦ noun an instrument for measuring very weak forces by their effect upon a system of fine twisted wire.
torsion pendulum         
  • Drawing of Coulomb's torsion balance. From Plate 13 of his 1785 memoir.
  • National Bureau of Standards]] (now NIST) between 1930 and 1942.
  • Video of a model torsion pendulum oscillating
  • Animation of a torsion spring oscillating
TYPE OF SPRING
Tortion spring; Torsion coefficient; Torsion balance; Torsion Balance; Torsional torque; Torsional Torque; Torsional pendulum; Torsional Pendulum; Torsion pendulum; Torsion springs; Torsional spring; Rotational spring; Deflecting torque
¦ noun a pendulum that rotates rather than swings.

Википедия

Torsion tensor

In differential geometry, the notion of torsion is a manner of characterizing a twist or screw of a moving frame around a curve. The torsion of a curve, as it appears in the Frenet–Serret formulas, for instance, quantifies the twist of a curve about its tangent vector as the curve evolves (or rather the rotation of the Frenet–Serret frame about the tangent vector). In the geometry of surfaces, the geodesic torsion describes how a surface twists about a curve on the surface. The companion notion of curvature measures how moving frames "roll" along a curve "without twisting".

More generally, on a differentiable manifold equipped with an affine connection (that is, a connection in the tangent bundle), torsion and curvature form the two fundamental invariants of the connection. In this context, torsion gives an intrinsic characterization of how tangent spaces twist about a curve when they are parallel transported; whereas curvature describes how the tangent spaces roll along the curve. Torsion may be described concretely as a tensor, or as a vector-valued 2-form on the manifold. If ∇ is an affine connection on a differential manifold, then the torsion tensor is defined, in terms of vector fields X and Y, by

T ( X , Y ) = X Y Y X [ X , Y ] {\displaystyle T(X,Y)=\nabla _{X}Y-\nabla _{Y}X-[X,Y]}

where [X,Y] is the Lie bracket of vector fields.

Torsion is particularly useful in the study of the geometry of geodesics. Given a system of parametrized geodesics, one can specify a class of affine connections having those geodesics, but differing by their torsions. There is a unique connection which absorbs the torsion, generalizing the Levi-Civita connection to other, possibly non-metric situations (such as Finsler geometry). The difference between a connection with torsion, and a corresponding connection without torsion is a tensor, called the contorsion tensor. Absorption of torsion also plays a fundamental role in the study of G-structures and Cartan's equivalence method. Torsion is also useful in the study of unparametrized families of geodesics, via the associated projective connection. In relativity theory, such ideas have been implemented in the form of Einstein–Cartan theory.