nLab cotangent bundle

Redirected from "covector".

Contents

Context

Differential geometry

Idea
Properties

Symplectic structure

Related concepts

Idea

Given a differentiable manifold $X$ , the cotangent bundle $T^*(X)$ of $X$ is the dual vector bundle over $X$ dual to the tangent bundle $T x$ of $X$ .

A cotangent vector or covector on $X$ is an element of $T^*(X)$ . The cotangent space of $X$ at a point $a$ is the fiber $T^*_a(X)$ of $T^*(X)$ over $a$ ; it is a vector space. A covector field on $X$ is a section of $T^*(X)$ . (More generally, a differential form on $X$ is a section of the exterior algebra of $T^*(X)$ ; a covector field is a differential 1-form.)

Given a covector $\omega$ at $a$ and a tangent vector $v$ at $a$ , the pairing $\langle{\omega,v}\rangle$ is a scalar (a real number, usually). This (with some details about linearity and universality) is basically what it means for $T^*(X)$ to be the dual vector bundle to $T_*(X)$ . More globally, given a covector field $\omega$ and a tangent vector field $v$ , the paring $\langle{\omega,v}\rangle$ is a scalar function on $X$ .

Given a point $a$ in $X$ and a differentiable (real-valued) partial function $f$ defined near $a$ , the differential $\mathrm{d}_a f$ of $f$ at $a$ is a covector on $X$ at $a$ ; given a tangent vector $v$ at $a$ , the pairing is given by

\langle{\mathrm{d}_a f, v}\rangle = v[f] ,

thinking of $v$ as a derivation on differentiable functions defined near $a$ . (It is really the germ at $a$ of $f$ that matters here.) More globally, given a differentiable function $f$ , the de Rham differential $\mathrm{d}f$ of $f$ is a covector field on $X$ ; given a vector field $v$ , the pairing is given by

\langle{\mathrm{d}f, v}\rangle = v[f] ,

thinking of $v$ as a derivation on differentiable functions.

One can also define covectors at $a$ to be germs of differentiable functions at $a$ , modulo the equivalence relation that $\mathrm{d}_a f = \mathrm{d}_a g$ if $f - g$ is constant on some neighbourhood of $a$ . In general, a covector field won't be of the form $\mathrm{d}f$ , but it will be a sum of terms of the form $h \mathrm{d}f$ . More specifically, a covector field $\omega$ on a coordinate patch can be written

\omega = \sum_i \omega_i\, \mathrm{d}x^i

in local coordinates $(x^1,\ldots,x^n)$ . This fact can also be used as the basis of a definition of the cotangent bundle.

Properties

Symplectic structure

Every cotangent bundle $T^\ast X$ carries itself a canonical differential 1-form

\theta \in \Omega^1(T^* X)

with the property that under the isomorphism

j \;\colon\; \Gamma(T^* X) \stackrel{\simeq}{\to} \Omega^1(X)

between differential 1-forms and smooth sections of the cotangent bundle we have for every smooth section $\sigma \in \Gamma(T^* X)$ the identification

\sigma^* \theta = j(\sigma)

between the pullback of $\theta$ along $\sigma$ and the 1-form corresponding to $\sigma$ under $j$ .

This unique differential 1-form $\theta \in \Omega^1(T^* X)$ is called the Liouville-Poincaré 1-form or canonical form or tautological form on the cotangent bundle.

The de Rham differential $\omega \coloneqq d \theta$ is a symplectic form. Hence every cotangent bundle is canonically a symplectic manifold.

On a coordinate chart $\mathbb{R}^n$ of $X$ with canonical coordinate functions denoted $(x^i)$ , the cotangent bundle over the chart is $T^\ast \mathbb{R}^n \simeq \mathbb{R}^n \times \mathbb{R}^n$ with canonical coordinates $((x^i), (p_j))$ . In these coordinates the canonical 1-form is (using Einstein summation convention)

\theta = p_i d x^i

and hence the symplectic form is

\omega = d p_i \wedge d q^i \,.

Related concepts

Last revised on November 23, 2017 at 12:48:04. See the history of this page for a list of all contributions to it.