EDIT1:

In  what follows I am pre-pending some  omitted considerations regarding intersection of two small circles on  a sphere  resulting in two diangles, referring to them as the minor and major diangles or lunes.

At either end of two cutting planes the it makes $\alpha,\beta$ subtended between  plane of small circles and the sphere's tangent plane.Angle $ \gamma$ is dihedral in between the planes.

The dihedral angle between the two planes is labelled with symbol  $\gamma. $

Three dihedrals  are taken in the tangent plane when considering three geodesic great circle arcs for a spherical triangle of three angles.

However it is not necessary here in lune/diangle situation. The boundaries need not be geodesics/great circles but can be small circles. 

In the next edit I shall attempt extending this to three small circle triangle general spherical trigonometry.

*The Cosine Rule in Spherical trig is equally valid here without geodesic boundaries, even when considering only small latitude /parallel circles*
 
 [![ Diangles/Lunes Dihedrals][1]][1]
                        
In the triangular pyramid shown we consider four triangles (two right triangles on a common hinge/fulcrum unit length normal to a striped triangle with a dihedral $\delta$ angle and the outer big yellow triangle containing compound angle $\gamma$).

We derive Cosine Rule in Spherical trigonometry indirectly avoiding representation of  sphere radius.

By applying Cosine Rule in striped triangle

$$ c^2= \tan^2\alpha+\tan^2\beta-2\tan\alpha \tan\beta \cos \delta $$

By applying Cosine Rule in larger yellow triangle containing compound angle $\gamma$

$$c^2= \sec^2\alpha+\sec^2\beta-2\sec\alpha \sec\beta \cos \gamma$$

Eliminate $c^2$ to simplify we get Cosine Rule in spherical trigonometry

$$\cos \gamma= \cos\alpha\cos\beta+ \sin \alpha \sin \beta  \cos \delta $$

We have used plane trig and embedded a pyramid into $\mathbb R ^3 $  without explicit reference to a sphere:

Now how can we  draw the corresponding figure in hyperbolic geometry:

$$\cos \gamma= \cosh\alpha\cosh\beta+ \sinh \alpha \sinh \beta  \cos \delta \,? $$

Considering simpler cases visualization...  We can draw for right triangle $\delta= \pi/2$ the pyramid but how to *at least* draw it for hyperbolic geometry representation and result ?

$$ \cos \gamma= \cos\alpha\cos\beta \, \rightarrow  \cos \gamma= \cosh\alpha\cosh\beta \,? $$   

Thanks in advance for geometric considerations in hyperbolic geometry  without explicitly bringing in the pseudosphere.

Regards                     


  [1]: https://i.sstatic.net/z2UtX.png