Consider the manifold ${\displaystyle \mathrm {M} =\mathbb {R} ^{2}\setminus \{0\}}$  with the metric

${\displaystyle g={\frac {dx\,dy}{{\tfrac {1}{2}}(x^{2}+y^{2})}}}$ 

Any homothety is an isometry of ${\displaystyle M}$ , in particular including the map:

${\displaystyle \lambda (x,y)=2\cdot (x,y)}$ 

Let ${\displaystyle \Gamma }$  be the subgroup of the isometry group generated by ${\displaystyle \lambda }$ . Then ${\displaystyle \Gamma }$  has a proper, discontinuous action on ${\displaystyle M}$ . Hence the quotient ${\displaystyle T=M/\Gamma ,}$  which is topologically the torus, is a Lorentz surface that is called the Clifton–Pohl torus.^[1] Sometimes, by extension, a surface is called a Clifton–Pohl torus if it is a finite covering of the quotient of ${\displaystyle M}$  by any homothety of ratio different from ${\displaystyle \pm 1}$ .

It can be verified that the curve

${\displaystyle \sigma (t):=\left({\frac {1}{1-t}},0\right)}$ 

is a geodesic of M that is not complete (since it is not defined at ${\displaystyle t=1}$ ).^[1] Consequently, ${\displaystyle M}$  (hence also ${\displaystyle T}$ ) is geodesically incomplete, despite the fact that ${\displaystyle T}$  is compact. Similarly, the curve

${\displaystyle \sigma (t):=(\tan(t),1)}$ 

is a null geodesic that is incomplete. In fact, every null geodesic on ${\displaystyle M}$  or ${\displaystyle T}$  is incomplete.

The geodesic incompleteness of the Clifton–Pohl torus is better seen as a direct consequence of the fact that ${\displaystyle (M,g)}$  is extendable, i.e. that it can be seen as a subset of a bigger Lorentzian surface. It is a direct consequence of a simple change of coordinates. With

${\displaystyle N=\left(-\pi /2,\pi /2\right)^{2}\smallsetminus \{0\};}$ 

consider

${\displaystyle F:N\to M}$ 

${\displaystyle F(u,v):=(\tan(u),\tan(v)).}$ 

The metric ${\displaystyle F^{*}g}$  (i.e. the metric ${\displaystyle g}$  expressed in the coordinates ${\displaystyle (u,v)}$ ) reads

${\displaystyle {\widehat {g\,}}={\frac {du\,dv}{{\tfrac {1}{2}}(\cos(u)^{2}\sin(v)^{2}+\sin(u)^{2}\cos(v)^{2})}}.}$ 

But this metric extends naturally from ${\displaystyle N}$  to ${\displaystyle \mathbb {R} ^{2}\smallsetminus \Lambda }$ , where

${\displaystyle \Lambda =\left\{{\tfrac {\pi }{2}}(k,\ell )\ \mid \ (k,\ell )\in \mathbb {Z} ^{2},k+\ell \equiv 0{\pmod {2}}\right\}.}$ 

The surface ${\displaystyle (\mathbb {R} ^{2}\smallsetminus \Lambda ,{\widehat {g\,}})}$ , known as the extended Clifton–Pohl plane, is geodesically complete.^[3]

The Clifton–Pohl tori are also remarkable by the fact that they were the first known non-flat Lorentzian tori with no conjugate points. ^[3] The extended Clifton–Pohl plane contains a lot of pairs of conjugate points, some of them being in the boundary of ${\displaystyle (-\pi /2,\pi /2)^{2}}$  i.e. "at infinity" in ${\displaystyle M}$ . Recall also that, by a theorem of E. Hopf no such tori exists in the Riemannian setting.^[4]