The necessary and sufficient conditions for complete integrability of a Pfaffian system are given by the Frobenius theorem. One version states that if the ideal ${\displaystyle {\mathcal {I}}}$  algebraically generated by the collection of α_i inside the ring Ω(M) is differentially closed, in other words

${\displaystyle d{\mathcal {I}}\subset {\mathcal {I}},}$ 

then the system admits a foliation by maximal integral manifolds. (The converse is obvious from the definitions.)

Not every Pfaffian system is completely integrable in the Frobenius sense. For example, consider the following one-form on R³ − (0,0,0):

${\displaystyle \theta =z\,dx+x\,dy+y\,dz.}$ 

If dθ were in the ideal generated by θ we would have, by the skewness of the wedge product

${\displaystyle \theta \wedge d\theta =0.}$ 

But a direct calculation gives

${\displaystyle \theta \wedge d\theta =(x+y+z)\,dx\wedge dy\wedge dz}$ 

which is a nonzero multiple of the standard volume form on R³. Therefore, there are no two-dimensional leaves, and the system is not completely integrable.

On the other hand, for the curve defined by

${\displaystyle x=t,\quad y=c,\qquad z=e^{-t/c},\quad t>0}$ 

then θ defined as above is 0, and hence the curve is easily verified to be a solution (i.e. an integral curve) for the above Pfaffian system for any nonzero constant c.

In Riemannian geometry, we may consider the problem of finding an orthogonal coframe θⁱ, i.e., a collection of 1-forms forming a basis of the cotangent space at every point with ${\displaystyle \langle \theta ^{i},\theta ^{j}\rangle =\delta ^{ij}}$  which are closed (dθⁱ = 0, i = 1, 2, ..., n). By the Poincaré lemma, the θⁱ locally will have the form dxⁱ for some functions xⁱ on the manifold, and thus provide an isometry of an open subset of M with an open subset of Rⁿ. Such a manifold is called locally flat.

This problem reduces to a question on the coframe bundle of M. Suppose we had such a closed coframe

${\displaystyle \Theta =(\theta ^{1},\dots ,\theta ^{n}).}$ 

If we had another coframe ${\displaystyle \Phi =(\phi ^{1},\dots ,\phi ^{n})}$ , then the two coframes would be related by an orthogonal transformation

${\displaystyle \Phi =M\Theta }$ 

If the connection 1-form is ω, then we have

${\displaystyle d\Phi =\omega \wedge \Phi }$ 

On the other hand,

${\displaystyle {\begin{aligned}d\Phi &=(dM)\wedge \Theta +M\wedge d\Theta \\&=(dM)\wedge \Theta \\&=(dM)M^{-1}\wedge \Phi .\end{aligned}}}$ 

But ${\displaystyle \omega =(dM)M^{-1}}$  is the Maurer–Cartan form for the orthogonal group. Therefore, it obeys the structural equation ${\displaystyle d\omega +\omega \wedge \omega =0,}$  and this is just the curvature of M: ${\displaystyle \Omega =d\omega +\omega \wedge \omega =0.}$  After an application of the Frobenius theorem, one concludes that a manifold M is locally flat if and only if its curvature vanishes.

Many generalizations exist to integrability conditions on differential systems which are not necessarily generated by one-forms. The most famous of these are the Cartan–Kähler theorem, which only works for real analytic differential systems, and the Cartan–Kuranishi prolongation theorem. See Further reading for details. The Newlander-Nirenberg theorem gives integrability conditions for an almost-complex structure.

• Bryant, Chern, Gardner, Goldschmidt, Griffiths, Exterior Differential Systems, Mathematical Sciences Research Institute Publications, Springer-Verlag, ISBN 0-387-97411-3
• Olver, P., Equivalence, Invariants, and Symmetry, Cambridge, ISBN 0-521-47811-1
• Ivey, T., Landsberg, J.M., Cartan for Beginners: Differential Geometry via Moving Frames and Exterior Differential Systems, American Mathematical Society, ISBN 0-8218-3375-8
• Dunajski, M., Solitons, Instantons and Twistors, Oxford University Press, ISBN 978-0-19-857063-9