In complex analysis, de Branges's theorem, or the Bieberbach conjecture, is a theorem that gives a necessary condition on a holomorphic function in order for it to map the open unit disk of the complex plane injectively to the complex plane. It was posed by and finally proven by .
The statement concerns the Taylor coefficients
an
a0=0
a1=1
f(z)=z+\sumn\geqanzn.
Such functions are called schlicht. The theorem then states that
|an|\leqn foralln\geq2.
The Koebe function (see below) is a function for which
an=n
n
n
The normalizations
a0=0 and a1=1
mean that
f(0)=0 and f'(0)=1.
This can always be obtained by an affine transformation: starting with an arbitrary injective holomorphic function
g
| f(z)= | g(z)-g(0) |
| g'(0) |
.
Such functions
g
A schlicht function is defined as an analytic function
f
f(0)=0
f'(0)=1
| f | ||||
|
| infty | |
| =\sum | |
| n=1 |
n\alphan-1zn
with
\alpha
1
f
|an|=n
n\geq2
f
The condition of de Branges' theorem is not sufficient to show the function is schlicht, as the function
f(z)=z+z2=(z+1/2)2-1/4
|an|\leqn
n
f(-1/2+z)=f(-1/2-z)
A survey of the history is given by Koepf (2007).
proved
|a2|\leq2
|an|\leqn
|a3|\leq3
proved that
|an|\leqen
n
e=2.718\ldots
e
f(z)=z+ …
\varphi(z)=z(f(z2)/z2)1/2
bk\leq14
k
14
1
b5=1/2+\exp(-2/3)=1.013\ldots
b5
14
1.14
bk
1
f
b2k+1
1
1
The Robertson conjecture states that if
\phi(z)=b1z+b
| 5+ … | |
| 5z |
is an odd schlicht function in the unit disk with
b1=1
n
| n|b | |
| \sum | |
| 2k+1 |
|2\len.
Robertson observed that his conjecture is still strong enough to imply the Bieberbach conjecture, and proved it for
n=3
There were several proofs of the Bieberbach conjecture for certain higher values of
n
|a4|\leq4
|a6|\leq6
|a5|\leq5
proved that the limit of
an/n
1
f
f
The Milin conjecture states that for each schlicht function on the unit disk, and for all positive integers
n
| n | |
| \sum | |
| k=1 |
| 2-1/k)\le | |
| (n-k+1)(k|\gamma | |
| k| |
0
where the logarithmic coefficients
\gamman
f
log(f(z)/z)=2
| infty | |
| \sum | |
| n=1 |
| n. | |
| \gamma | |
| nz |
Finally proved
|an|\leqn
n
The proof uses a type of Hilbert space of entire functions. The study of these spaces grew into a sub-field of complex analysis and the spaces have come to be called de Branges spaces. De Branges proved the stronger Milin conjecture on logarithmic coefficients. This was already known to imply the Robertson conjecture about odd univalent functions, which in turn was known to imply the Bieberbach conjecture about schlicht functions . His proof uses the Loewner equation, the Askey–Gasper inequality about Jacobi polynomials, and the Lebedev–Milin inequality on exponentiated power series.
De Branges reduced the conjecture to some inequalities for Jacobi polynomials, and verified the first few by hand. Walter Gautschi verified more of these inequalities by computer for de Branges (proving the Bieberbach conjecture for the first 30 or so coefficients) and then asked Richard Askey whether he knew of any similar inequalities. Askey pointed out that had proved the necessary inequalities eight years before, which allowed de Branges to complete his proof. The first version was very long and had some minor mistakes which caused some skepticism about it, but these were corrected with the help of members of the Leningrad seminar on Geometric Function Theory (Leningrad Department of Steklov Mathematical Institute) when de Branges visited in 1984.
De Branges proved the following result, which for
\nu=0
\nu>-3/2
\sigman
n
0
| \rho | ||||
|
(\sigman-\sigman+1)
0
F(z)=z+ …
| F(z)\nu-z\nu | |
| \nu |
=
| infty | |
| \sum | |
| n=1 |
| \nu+n | |
| a | |
| nz |
| infty(\nu+n)\sigma | |
| \sum | |
| n|a |
| 2 | |
| n| |
z/(1-z)2
A simplified version of the proof was published in 1985 by Carl FitzGerald and Christian Pommerenke, and an even shorter description by Jacob Korevaar .