Grace–Walsh–Szegő theorem

From formulasearchengine
Revision as of 18:43, 4 October 2013 by en>David Eppstein ({{mathanalysis-stub}})
(diff) ← Older revision | Latest revision (diff) | Newer revision → (diff)
Jump to navigation Jump to search

In mathematics (differential geometry) twist denotes the rate of rotation of a smooth ribbon around the space curve X=X(s), where s is the arc-length of X and U=U(s) a unit vector perpendicular at each point to X. Since the ribbon (X,U) has edges X and X=X+εU the twist (or total twist number) Tw measures the average winding of the curve X around and along the curve X. According to Love (1944) twist is defined by

Tw=12π(dUds×U)dXdsds,

where dX/ds is the unit tangent vector to X. The total twist number Tw can be decomposed (Moffatt & Ricca 1992) into normalized total torsion T and intrinsic twist N, that is

Tw=12πτds+[Θ]X2π=T+N,

where τ=τ(s) is the torsion of the space curve X, and [Θ]X denotes the total rotation angle of U along X. The total twist number Tw depends on the choice of the vector field U (Banchoff & White 1975).

When the ribbon is deformed so as to pass through an inflectional state (i.e. X has a point of inflection) torsion becomes singular, but its singularity is integrable (Moffatt & Ricca 1992) and Tw remains continuous. This behavior has many important consequences for energy considerations in many fields of science.

Together with the writhe Wr of X, twist is a geometric quantity that plays an important role in the application of the Călugăreanu–White–Fuller formula Lk=Wr+Tw in topological fluid dynamics (for its close relation to kinetic and magnetic helicity of a vector field), physical knot theory, and structural complexity analysis.

References