Editing Spacetime (section)

=== Invariant hyperbola ===
{{More citations needed section|date=March 2024}}
{{anchor|Spacelike and Timelike Invariant Hyperbolas}}
[[File:Spacelike and Timelike Invariant Hyperbolas.png|thumb|upright=1.5|Figure 2–7. (a) Families of invariant hyperbolae, (b) Hyperboloids of two sheets and one sheet]]

In Euclidean space (having spatial dimensions only), the set of points equidistant (using the Euclidean metric) from some point form a circle (in two dimensions) or a sphere (in three dimensions). In {{nowrap|(1+1)-dimensional}} Minkowski spacetime (having one temporal and one spatial dimension), the points at some constant spacetime interval away from the origin (using the Minkowski metric) form curves given by the two equations
: <math>(ct)^2 - x^2 = \pm s^2,</math>
with <math> s^2</math>some positive real constant. These equations describe two families of hyperbolae in an ''x''–''ct'' spacetime diagram, which are termed ''invariant hyperbolae''.

In Fig.&nbsp;2-7a, each magenta hyperbola connects all events having some fixed spacelike separation from the origin, while the green hyperbolae connect events of equal timelike separation.

The magenta hyperbolae, which cross the ''x'' axis, are timelike curves, which is to say that these hyperbolae represent actual paths that can be traversed by (constantly accelerating) particles in spacetime: Between any two events on one hyperbola a causality relation is possible, because the inverse of the slope—representing the necessary speed—for all secants is less than <math>c</math>. On the other hand, the green hyperbolae, which cross the ''ct'' axis, are spacelike curves because all intervals ''along'' these hyperbolae are spacelike intervals: No causality is possible between any two points on one of these hyperbolae, because all secants represent speeds larger than <math>c</math>.

Fig.&nbsp;2-7b reflects the situation in {{nowrap|(1+2)-dimensional}} Minkowski spacetime (one temporal and two spatial dimensions) with the corresponding hyperboloids. The invariant hyperbolae displaced by spacelike intervals from the origin generate [[hyperboloid]]s of one sheet, while the invariant hyperbolae displaced by timelike intervals from the origin generate hyperboloids of two sheets.

The (1+2)-dimensional boundary between space- and time-like hyperboloids, established by the events forming a zero spacetime interval to the origin, is made up by degenerating the hyperboloids to the light cone. In (1+1)-dimensions the hyperbolae degenerate to the two grey 45°-lines depicted in Fig.&nbsp;2-7a.

{{anchor|Time dilation and length contraction}}