In functional analysis, the open mapping theorem, also known as the Banach–Schauder theorem or the Banach theorem (named after Stefan Banach and Juliusz Schauder), is a fundamental result that states that if a bounded or continuous linear operator between Banach spaces is surjective then it is an open map.
A special case is also called the bounded inverse theorem (also called inverse mapping theorem or Banach isomorphism theorem), which states that a bijective bounded linear operator
T
T-1
The proof here uses the Baire category theorem, and completeness of both
E
F
The proof is based on the following lemmas, which are also somewhat of independent interest. A linear map
f:E\toF
U
\overline{f(U)}
Proof: Shrinking
U
U
f(E)=f\left(cupnnU\right)=cupnf(nU)
\overline{f(nU)}
y
r>0
B(y,r)\subset\overline{f(nU)}.
v
F
\|v\|<r
(-1)U\subsetU
v=v-y+y\in\overline{f(-nU)}+\overline{f(nU)}\subset\overline{f(2nU)}
2n
\square
E,F
The completeness on the domain then allows to upgrade nearly open to open.
Proof: Let
y
B(0,\delta)
cn>0
\overline{B(0,\delta)}\subset\overline{f(B(0,1))}
\epsilon>0
z
F
x
\|x\|<\delta-1\|z\|
z
B(f(x),\epsilon)
z=y
x1
\|y-f(x1)\|<c1,\|x1\|<\delta-1\|y\|.
z=y-f(x1)
x2
\|y-f(x1)-f(x2)\|<c2,\|x2\|<\delta-1c1
\|x2\|<\delta-1\|z\|<\delta-1c1
c:=\sumcn<infty
xn
x=
| infty | |
| \sum | |
| 1 |
xn
f(x)=y
\|x\|\le
| infty | |
| \sum | |
| 1 |
\|xn\|\le\delta-1\|y\|+\delta-1c.
\delta-1\|y\|<1
c
\|x\|<1
\square
E,F
Proof of the theorem: By Baire's category theorem, the first lemma applies. Then the conclusion of the theorem follows from the second lemma.
\square
In general, a continuous bijection between topological spaces is not necessarily a homeomorphism. The open mapping theorem, when it applies, implies the bijectivity is enough:
Even though the above bounded inverse theorem is a special case of the open mapping theorem, the open mapping theorem in turns follows from that. Indeed, a surjective linear operator
T:E\toF
T:E\overset{p}\toE/\operatorname{ker}T\overset{T0}\toF.
T0
T
Because the open mapping theorem and the bounded inverse theorem are essentially the same result, they are often simply called Banach's theorem.
Here is a formulation of the open mapping theorem in terms of the transpose of an operator.
Proof: The idea of 1.
⇒
y\notin\overline{T(BX)} ⇒ \|y\|>\delta,
⇒
⇒
⇒
\square
Alternatively, 1. implies that
T*
T
T
Terence Tao gives the following quantitative formulation of the theorem:[1]
Proof: 2.
⇒
1.
⇒
r>0
B(0,2)\subsetT(B(0,r))
B
| f | |
| \|f\| |
=T\left(
| u | |
| \|f\| |
\right)
| u | |
| \|f\| |
B(0,r)
Tu=f
\|u\|<r\|f\|
4.
⇒
f=
| infty | |
| \sum | |
| 0 |
fj
fj
E
u=
| infty | |
| \sum | |
| 0 |
uj
\|uj\|\leC\|fj\|
Tuj=fj
⇒
\square
The open mapping theorem may not hold for normed spaces that are not complete. A quickest way to see this is to note that the closed graph theorem, a consequence of the open mapping theorem, fails without completeness. But here is a more concrete counterexample. Consider the space X of sequences x : N → R with only finitely many non-zero terms equipped with the supremum norm. The map T : X → X defined by
Tx=\left(x1,
| x2 | |
| 2 |
,
| x3 | |
| 3 |
,...\right)
is bounded, linear and invertible, but T-1 is unbounded. This does not contradict the bounded inverse theorem since X is not complete, and thus is not a Banach space. To see that it's not complete, consider the sequence of sequences x(n) ∈ X given by
x(n)=\left(1,
| 1{2}, | |
| ..., |
| 1{n}, | |
| 0, |
0,...\right)
converges as n → ∞ to the sequence x(∞) given by
x(infty)=\left(1,
| 1{2}, | |
| ..., |
| 1{n}, | |
| ... |
\right),
which has all its terms non-zero, and so does not lie in X.
The completion of X is the space c0
of all sequences that converge to zero, which is a (closed) subspace of the ℓp space ℓ∞(N), which is the space of all bounded sequences. However, in this case, the map T is not onto, and thus not a bijection. To see this, one need simply note that the sequence
x=\left(1,
| 12, | |||
|
\right),
is an element of
c0
T:c0\toc0
T
linfty
x=\left(1,1,1,...\right)
T
The open mapping theorem has several important consequences:
T:X\toY
X
Y,
T-1:Y\toX
T:X\toY
X
Y,
\left(xn\right)
X
xn\to0
Txn\toy
y=0,
T
T:E\toF
T
E
T
F
The open mapping theorem does not imply that a continuous surjective linear operator admits a continuous linear section. What we have is:
In particular, the above applies to an operator between Hilbert spaces or an operator with finite-dimensional kernel (by the Hahn–Banach theorem). If one drops the requirement that a section be linear, a surjective continuous linear operator between Banach spaces admits a continuous section; this is the Bartle–Graves theorem.[2] [3]
Local convexity of
X
Y
X
Y
(The proof is essentially the same as the Banach or Fréchet cases; we modify the proof slightly to avoid the use of convexity,)
Furthermore, in this latter case if
N
A,
A
X/N
X
N.
X\toX/N
\alpha
An important special case of this theorem can also be stated as
On the other hand, a more general formulation, which implies the first, can be given:
Nearly/Almost open linear maps
A linear map
A:X\toY
U
\operatorname{cl}A(U)
Y.
A(U)
A(X)
Y,
Webbed spaces are a class of topological vector spaces for which the open mapping theorem and the closed graph theorem hold.