Darboux derivative explained

The Darboux derivative of a map between a manifold and a Lie group is a variant of the standard derivative. It is arguably a more natural generalization of the single-variable derivative. It allows a generalization of the single-variable fundamental theorem of calculus to higher dimensions, in a different vein than the generalization that is Stokes' theorem.

Formal definition

Let

be a Lie group, and let

ak{g}

be its Lie algebra. The Maurer-Cartan form,

\omega_G

, is the smooth

ak{g}

-valued

-form on

(cf. Lie algebra valued form) defined by

\omega_G(X_g)=(T_g

	-1
L
	g)

X_g

for all

g\inG

and

X_g\inT_gG

. Here

L_g

denotes left multiplication by the element

g\inG

and

T_gL_g

is its derivative at

Let

f:M\toG

be a smooth function between a smooth manifold

and

. Then the Darboux derivative of

is the smooth

ak{g}

-valued

-form

\omega_f:=f^*\omega_G,

the pullback of

\omega_G

. The map

is called an integral or primitive of

\omega_f

More natural?

of a function

f:R\toR

assigns to each point in the domain a single number. According to the more general manifold ideas of derivatives, the derivative assigns to each point in the domain a linear map from the tangent space at the domain point to the tangent space at the image point. This derivative encapsulates two pieces of data: the image of the domain point and the linear map. In single-variable calculus, we drop some information. We retain only the linear map, in the form of a scalar multiplying agent (i.e. a number).

One way to justify this convention of retaining only the linear map aspect of the derivative is to appeal to the (very simple) Lie group structure of

under addition. The tangent bundle of any Lie group can be trivialized via left (or right) multiplication. This means that every tangent space in

may be identified with the tangent space at the identity,

, which is the Lie algebra of

. In this case, left and right multiplication are simply translation. By post-composing the manifold-type derivative with the tangent space trivialization, for each point in the domain we obtain a linear map from the tangent space at the domain point to the Lie algebra of

. In symbols, for each

x\inR

we look at the map

v\inT_xR\mapsto(T_f(x)L_f(x))^-1\circ(T_xf)v\inT₀R.

Since the tangent spaces involved are one-dimensional, this linear map is just multiplication by some scalar. (This scalar can change depending on what basis we use for the vector spaces, but the canonical unit vector field

	\partial
	\partialt

gives a canonical choice of basis, and hence a canonical choice of scalar.) This scalar is what we usually denote by

f'(x)

Uniqueness of primitives

If the manifold

is connected, and

f,g:M\toG

are both primitives of

\omega_f

, i.e.

\omega_f=\omega_g

, then there exists some constant

C\inG

such that

f(x)=C ⋅ g(x)

for all

x\inM

This constant

is of course the analogue of the constant that appears when taking an indefinite integral.

The fundamental theorem of calculus

The structural equation for the Maurer-Cartan form is:

d\omega+

	1
	2

[\omega,\omega]=0.

This means that for all vector fields

and

and all

x\inG

, we have

(d\omega)_x(X_x,Y_x)+[\omega_x(X_x),\omega_x(Y_x)]=0.

For any Lie algebra-valued

-form on any smooth manifold, all the terms in this equation make sense, so for any such form we can ask whether or not it satisfies this structural equation.

The usual fundamental theorem of calculus for single-variable calculus has the following local generalization.

If a

ak{g}

-valued

-form

\omega

satisfies the structural equation, then every point

p\inM

has an open neighborhood

and a smooth map

f:U\toG

such that

\omega_f=\omega|_U,

i.e.

\omega

has a primitive defined in a neighborhood of every point of

For a global generalization of the fundamental theorem, one needs to study certain monodromy questions in

and

References

Book: R. W. Sharpe. Differential Geometry: Cartan's Generalization of Klein's Erlangen Program. 1996. Springer-Verlag, Berlin. 0-387-94732-9.
Book: Shlomo Sternberg. Shlomo Sternberg. Lectures in differential geometry. 1964. Prentice-Hall . 529176. Chapter V, Lie Groups. Section 2, Invariant forms and the Lie algebra.. registration.