Tangent space explained

In mathematics, the tangent space of a manifold is a generalization of to curves in two-dimensional space and to surfaces in three-dimensional space in higher dimensions. In the context of physics the tangent space to a manifold at a point can be viewed as the space of possible velocities for a particle moving on the manifold.

Informal description

In differential geometry, one can attach to every point

of a differentiable manifold a tangent space—a real vector space that intuitively contains the possible directions in which one can tangentially pass through

. The elements of the tangent space at

are called the tangent vectors at

. This is a generalization of the notion of a vector, based at a given initial point, in a Euclidean space. The dimension of the tangent space at every point of a connected manifold is the same as that of the manifold itself.

For example, if the given manifold is a

-sphere, then one can picture the tangent space at a point as the plane that touches the sphere at that point and is perpendicular to the sphere's radius through the point. More generally, if a given manifold is thought of as an embedded submanifold of Euclidean space, then one can picture a tangent space in this literal fashion. This was the traditional approach toward defining parallel transport. Many authors in differential geometry and general relativity use it.^[1] ^[2] More strictly, this defines an affine tangent space, which is distinct from the space of tangent vectors described by modern terminology.

that gives a vector space with dimension at least that of

itself. The points

at which the dimension of the tangent space is exactly that of

are called non-singular points; the others are called singular points. For example, a curve that crosses itself does not have a unique tangent line at that point. The singular points of

are those where the "test to be a manifold" fails. See Zariski tangent space.

Once the tangent spaces of a manifold have been introduced, one can define vector fields, which are abstractions of the velocity field of particles moving in space. A vector field attaches to every point of the manifold a vector from the tangent space at that point, in a smooth manner. Such a vector field serves to define a generalized ordinary differential equation on a manifold: A solution to such a differential equation is a differentiable curve on the manifold whose derivative at any point is equal to the tangent vector attached to that point by the vector field.

All the tangent spaces of a manifold may be "glued together" to form a new differentiable manifold with twice the dimension of the original manifold, called the tangent bundle of the manifold.

Formal definitions

The informal description above relies on a manifold's ability to be embedded into an ambient vector space

R^m

so that the tangent vectors can "stick out" of the manifold into the ambient space. However, it is more convenient to define the notion of a tangent space based solely on the manifold itself.^[3]

There are various equivalent ways of defining the tangent spaces of a manifold. While the definition via the velocity of curves is intuitively the simplest, it is also the most cumbersome to work with. More elegant and abstract approaches are described below.

Definition via tangent curves

In the embedded-manifold picture, a tangent vector at a point

is thought of as the velocity of a curve passing through the point

. We can therefore define a tangent vector as an equivalence class of curves passing through

while being tangent to each other at

Suppose that

is a

C^k

differentiable manifold (with smoothness

k\geq1

) and that

x\inM

. Pick a coordinate chart

\varphi:U\toRⁿ

, where

is an open subset of

containing

. Suppose further that two curves

\gamma₁,\gamma₂:(-1,1)\toM

with

{\gamma₁

}(0) = x = (0) are given such that both

\varphi\circ\gamma₁,\varphi\circ\gamma₂:(-1,1)\toRⁿ

are differentiable in the ordinary sense (we call these differentiable curves initialized at
x

). Then

\gamma₁

and

\gamma₂

are said to be equivalent at

if and only if the derivatives of

\varphi\circ\gamma₁

and

\varphi\circ\gamma₂

coincide. This defines an equivalence relation on the set of all differentiable curves initialized at

, and equivalence classes of such curves are known as tangent vectors of

. The equivalence class of any such curve

\gamma

is denoted by

\gamma'(0)

. The tangent space of

, denoted by

T_xM

, is then defined as the set of all tangent vectors at

; it does not depend on the choice of coordinate chart

\varphi:U\toRⁿ

To define vector-space operations on

T_xM

, we use a chart

\varphi:U\toRⁿ

and define a map

d{\varphi}_x:T_xM\toRⁿ

(\gamma'(0)) := \left. \frac [(\varphi \circ \gamma)(t)] \right|_,

where

\gamma\in\gamma'(0)

. The map

d{\varphi}_x

turns out to be bijective and may be used to transfer the vector-space operations on

Rⁿ

over to

T_xM

, thus turning the latter set into an

-dimensional real vector space. Again, one needs to check that this construction does not depend on the particular chart

\varphi:U\toRⁿ

and the curve

\gamma

being used, and in fact it does not.

Definition via derivations

Suppose now that

is a

C^infty

manifold. A real-valued function

f:M\toR

is said to belong to

{C^infty

}(M) if and only if for every coordinate chart

\varphi:U\toRⁿ

, the map

f\circ\varphi^-:\varphi[U]\subseteqRⁿ\toR

is infinitely differentiable. Note that

{C^infty

}(M) is a real associative algebra with respect to the pointwise product and sum of functions and scalar multiplication.

A derivation at

x\inM

is defined as a linear map

D:{C^infty

}(M) \to \mathbb that satisfies the Leibniz identity

\forall f,g \in (M): \qquadD(f g) = D(f) \cdot g(x) + f(x) \cdot D(g),

which is modeled on the product rule of calculus.

(For every identically constant function

f=const,

it follows that

D(f)=0

Denote

T_xM

the set of all derivations at

Setting

(D_1+D_2)(f):={D}_1(f)+{D}_2(f)

and

(λ ⋅ D)(f):=λ ⋅ D(f)

turns

T_xM

into a vector space.

Generalizations

Generalizations of this definition are possible, for instance, to complex manifolds and algebraic varieties. However, instead of examining derivations

from the full algebra of functions, one must instead work at the level of germs of functions. The reason for this is that the structure sheaf may not be fine for such structures. For example, let

be an algebraic variety with structure sheaf

l{O}_X

. Then the Zariski tangent space at a point

p\inX

is the collection of all

-derivations

D:l{O}_X,p\tok

, where

is the ground field and

l{O}_X,p

is the stalk of

l{O}_X

Equivalence of the definitions

For

x\inM

and a differentiable curve

\gamma:(-1,1)\toM

such that

\gamma(0)=x,

define

{D_\gamma

}(f) := (f \circ \gamma)'(0) (where the derivative is taken in the ordinary sense because

f\circ\gamma

is a function from

(-1,1)

). One can ascertain that

D_\gamma(f)

is a derivation at the point

and that equivalent curves yield the same derivation. Thus, for an equivalence class

\gamma'(0),

we can define

{D_\gamma'(0)

}(f) := (f \circ \gamma)'(0), where the curve

\gamma\in\gamma'(0)

has been chosen arbitrarily. The map

\gamma'(0)\mapstoD_\gamma'(0)

is a vector space isomorphism between the space of the equivalence classes

\gamma'(0)

and that of the derivations at the point

Definition via cotangent spaces

Again, we start with a

C^infty

manifold

and a point

x\inM

. Consider the ideal

C^infty(M)

that consists of all smooth functions

vanishing at

, i.e.,

f(x)=0

. Then

and

I²

are both real vector spaces, and the quotient space

I/I²

can be shown to be isomorphic to the cotangent space

	*
T
	x

through the use of Taylor's theorem. The tangent space

T_xM

may then be defined as the dual space of

I/I²

While this definition is the most abstract, it is also the one that is most easily transferable to other settings, for instance, to the varieties considered in algebraic geometry.

is a derivation at

, then

D(f)=0

for every

f\inI²

, which means that

gives rise to a linear map

I/I²\toR

. Conversely, if

r:I/I²\toR

is a linear map, then

D(f):=r\left((f-f(x))+I^2\right)

defines a derivation at

. This yields an equivalence between tangent spaces defined via derivations and tangent spaces defined via cotangent spaces.

Properties

is an open subset of

Rⁿ

, then

is a

C^infty

manifold in a natural manner (take coordinate charts to be identity maps on open subsets of

Rⁿ

), and the tangent spaces are all naturally identified with

Rⁿ

Tangent vectors as directional derivatives

Another way to think about tangent vectors is as directional derivatives. Given a vector

Rⁿ

, one defines the corresponding directional derivative at a point

x\inRⁿ

\forallf\in{C^infty

}(\mathbb^): \qquad (D_ f)(x) := \left. \frac [f(x + t v)] \right|_= \sum_^ v^ (x).This map is naturally a derivation at

. Furthermore, every derivation at a point in

Rⁿ

is of this form. Hence, there is a one-to-one correspondence between vectors (thought of as tangent vectors at a point) and derivations at a point.

As tangent vectors to a general manifold at a point can be defined as derivations at that point, it is natural to think of them as directional derivatives. Specifically, if

is a tangent vector to

at a point

(thought of as a derivation), then define the directional derivative

D_v

in the direction

\forallf\in{C^infty

}(M): \qquad(f) := v(f).If we think of

as the initial velocity of a differentiable curve

\gamma

initialized at

, i.e.,

v=\gamma'(0)

, then instead, define

D_v

\forallf\in{C^infty

}(M): \qquad(f) := (f \circ \gamma)'(0).

Basis of the tangent space at a point

For a

C^infty

manifold

, if a chart

\varphi=(x¹,\ldots,xⁿ):U\toRⁿ

is given with

p\inU

, then one can define an ordered basis

\left\

T_pM

\foralli\in\{1,\ldots,n\},~\forallf\in{C^infty

}(M): \qquad(f) :=\left(\frac \Big(f \circ \varphi^ \Big) \right) \Big(\varphi(p) \Big) .Then for every tangent vector

v\inT_pM

, one has

	n
\sum
	i=1

vⁱ\left.

	\partial
	\partialxⁱ

\right|_p.

This formula therefore expresses

as a linear combination of the basis tangent vectors

\left. \frac \right|_ \in T_ M

defined by the coordinate chart

\varphi:U\toRⁿ

.^[4]

The derivative of a map

See main article: Pushforward (differential).

Every smooth (or differentiable) map

\varphi:M\toN

between smooth (or differentiable) manifolds induces natural linear maps between their corresponding tangent spaces:

d{\varphi}_x:T_xM\toT_\varphi(x)N.

If the tangent space is defined via differentiable curves, then this map is defined by

{d{\varphi}_x

}(\gamma'(0)) := (\varphi \circ \gamma)'(0).If, instead, the tangent space is defined via derivations, then this map is defined by

[d{\varphi}_x(D)](f):=D(f\circ\varphi).

The linear map

d{\varphi}_x

is called variously the derivative, total derivative, differential, or pushforward of

\varphi

. It is frequently expressed using a variety of other notations:

D\varphi_x, (\varphi_*)_x, \varphi'(x).

In a sense, the derivative is the best linear approximation to

\varphi

near

. Note that when

N=R

, then the map

d{\varphi}_x:T_xM\toR

coincides with the usual notion of the differential of the function

\varphi

. In local coordinates the derivative of

\varphi

is given by the Jacobian.

An important result regarding the derivative map is the following:This is a generalization of the inverse function theorem to maps between manifolds.

Notes

Book: do Carmo, Manfredo P. . Differential Geometry of Curves and Surfaces. 1976 . Prentice-Hall .
Book: Dirac, Paul A. M. . General Theory of Relativity . 1975 . 1996 . Princeton University Press . 0-691-01146-X .
Book: Chris J. Isham. Modern Differential Geometry for Physicists. 1 January 2002. Allied Publishers. 978-81-7764-316-9. 70–72.
Web site: An Introduction to Differential Geometry. Eugene. Lerman. 12.

References

External links

Tangent Planes at MathWorld

Tangent space explained

Informal description

Formal definitions

Definition via tangent curves

Definition via derivations

Generalizations

Equivalence of the definitions

Definition via cotangent spaces

Properties

Tangent vectors as directional derivatives

Basis of the tangent space at a point

The derivative of a map

See also

Notes

References

External links