In mathematics, the Poincaré metric, named after Henri Poincaré, is the metric tensor describing a two-dimensional surface of constant negative curvature. It is the natural metric commonly used in a variety of calculations in hyperbolic geometry or Riemann surfaces.
There are three equivalent representations commonly used in two-dimensional hyperbolic geometry. One is the Poincaré half-plane model, defining a model of hyperbolic space on the upper half-plane. The Poincaré disk model defines a model for hyperbolic space on the unit disk. The disk and the upper half plane are related by a conformal map, and isometries are given by Möbius transformations. A third representation is on the punctured disk, where relations for q-analogues are sometimes expressed. These various forms are reviewed below.
See main article: metric tensor. A metric on the complex plane may be generally expressed in the form
ds2=λ2(z,\overline{z})dzd\overline{z}
where λ is a real, positive function of
z
\overline{z}
l(\gamma)=\int\gammaλ(z,\overline{z})|dz|
The area of a subset of the complex plane is given by
Area(M)=\intMλ2(z,\overline{z})
| i | |
| 2 |
dz\wedged\overline{z}
where
\wedge
λ4
λ2
dx\wedgedy
dz\wedged\overline{z}=(dx+idy)\wedge(dx-idy)=-2idx\wedgedy.
A function
\Phi(z,\overline{z})
| 4 | \partial |
| \partialz |
| \partial | |
| \partial\overline{z |
The Laplace–Beltrami operator is given by
\Delta=
| 4 | |
| λ2 |
| \partial | |
| \partialz |
| \partial | |
| \partial\overline{z |
The Gaussian curvature of the metric is given by
K=-\Deltalogλ.
This curvature is one-half of the Ricci scalar curvature.
Isometries preserve angles and arc-lengths. On Riemann surfaces, isometries are identical to changes of coordinate: that is, both the Laplace–Beltrami operator and the curvature are invariant under isometries. Thus, for example, let S be a Riemann surface with metric
λ2(z,\overline{z})dzd\overline{z}
\mu2(w,\overline{w})dwd\overline{w}
f:S\toT
with
f=w(z)
\mu2(w,\overline{w})
| \partialw | |
| \partialz |
| \partial\overline{w | |
Here, the requirement that the map is conformal is nothing more than the statement
w(z,\overline{z})=w(z),
that is,
| \partial | |
| \partial\overline{z |
The Poincaré metric tensor in the Poincaré half-plane model is given on the upper half-plane H as
| |||||
| ds | = |
| dzd\overline{z | |
where we write
dz=dx+idy
d\overline{z}=dx-idy
| z'=x'+iy'= | az+b |
| cz+d |
for
ad-bc=1
| x'= | ac(x2+y2)+x(ad+bc)+bd |
| |cz+d|2 |
and
| y'= | y |
| |cz+d|2 |
.
The infinitesimal transforms as
dz'=
| \partial | ( | |
| \partialz |
| az+b | |
| cz+d |
)dz=
| a(cz+d)-c(az+b) | |
| (cz+d)2 |
dz=
| acz+ad-caz-cb | |
| (cz+d)2 |
dz=
| ad-cb | |
| (cz+d)2 |
dz\overset{ad-cb=1}{=}
| 1 | |
| (cz+d)2 |
dz=
| dz | |
| (cz+d)2 |
and so
dz'd\overline{z}'=
| dzd\overline{z | |
| ^4 |
thus making it clear that the metric tensor is invariant under SL(2,R). Indeed,
| dz'd\overline{z | |
| '}{y' |
2}=
| ||||
| |cz+d|4 |
The invariant volume element is given by
| d\mu= | dxdy |
| y2 |
.
The metric is given by
\rho(z1,z
| -1 | |
| 2)=2\tanh |
| |z1-z2| | |
| |z1-\overline{z2 |
|}
\rho(z1,z
|
1-z2|}{|z1-\overline{z2}|-|z1-z2|}
for
z1,z2\inH.
Another interesting form of the metric can be given in terms of the cross-ratio. Given any four points
z1,z2,z3
z4
\hat{\Complex}=\Complex\cup\{infty\},
(z1,z2;z3,z4)=
| (z1-z3)(z2-z4) | |
| (z1-z4)(z2-z3) |
.
Then the metric is given by
\rho(z1,z2)=log\left(z1,z2;
| x , | |
| z | |
| 1 |
| x | |
| z | |
| 2 |
\right).
Here,
| x | |
| z | |
| 1 |
| x | |
| z | |
| 2 |
z1
z2
z1
| x | |
| z | |
| 1 |
z2
The geodesics for this metric tensor are circular arcs perpendicular to the real axis (half-circles whose origin is on the real axis) and straight vertical lines ending on the real axis.
The upper half plane can be mapped conformally to the unit disk with the Möbius transformation
w=ei\phi
| z-z0 | |
| z-\overline{z0 |
where w is the point on the unit disk that corresponds to the point z in the upper half plane. In this mapping, the constant z0 can be any point in the upper half plane; it will be mapped to the center of the disk. The real axis
\Imz=0
|w|=1.
\phi
The canonical mapping is
| w= | iz+1 |
| z+i |
which takes i to the center of the disk, and 0 to the bottom of the disk.
U=\left\{z=x+iy:|z|=\sqrt{x2+y2}<1\right\}
by
| |||||
| ds | = |
| 4dzd\overline{z | |
The volume element is given by
| d\mu= | 4dxdy | = |
| (1-(x2+y2))2 |
| 4dxdy | |
| (1-|z|2)2 |
.
The Poincaré metric is given by
\rho(z1,z
| -1 | ||
| \left| | ||
| 2)=2\tanh |
| z1-z2 | |
| 1-z1\overline{z2 |
for
z1,z2\inU.
The geodesics for this metric tensor are circular arcs whose endpoints are orthogonal to the boundary of the disk. Geodesic flows on the Poincaré disk are Anosov flows; that article develops the notation for such flows.
A second common mapping of the upper half-plane to a disk is the q-mapping
q=\exp(i\pi\tau)
where q is the nome and τ is the half-period ratio:
\tau=
| \omega2 | |
| \omega1 |
\Im\tau>0
The Poincaré metric on the upper half-plane induces a metric on the q-disk
| ||||
| ds |
dqd\overline{q}
The potential of the metric is
\Phi(q,\overline{q})=4loglog|q|-2
The Poincaré metric is distance-decreasing on harmonic functions. This is an extension of the Schwarz lemma, called the Schwarz–Ahlfors–Pick theorem.